EP4334338A1 - Conception moléculaire de capteurs de glucose dans des analogues d'insuline sensibles au glucose - Google Patents

Conception moléculaire de capteurs de glucose dans des analogues d'insuline sensibles au glucose

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Publication number
EP4334338A1
EP4334338A1 EP22799444.9A EP22799444A EP4334338A1 EP 4334338 A1 EP4334338 A1 EP 4334338A1 EP 22799444 A EP22799444 A EP 22799444A EP 4334338 A1 EP4334338 A1 EP 4334338A1
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European Patent Office
Prior art keywords
chain
insulin
amino acid
diol
glucose
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German (de)
English (en)
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Michael A. Weiss
Mark A. Jarosinski
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Indiana University
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Indiana University
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Publication of EP4334338A1 publication Critical patent/EP4334338A1/fr
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    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K14/00Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
    • C07K14/435Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from animals; from humans
    • C07K14/575Hormones
    • C07K14/62Insulins

Definitions

  • ELECTRONICALLY Incorporated by reference in its entirety is a computer-readable nucleotide/amino-acid sequence listing submitted concurrently herewith and identified as follows: 65 kilobytes ACII (text) file named “354919_ST25.txt,” created on May 3, 2022.
  • Naturally occurring proteins as encoded in the genomes of human beings, other mammals, vertebrate organisms, invertebrate organisms, or eukaryotic cells in general — may have evolved to function optimally within a cellular context but may be suboptimal for therapeutic applications.
  • Analogues of such proteins may exhibit improved biophysical, biochemical, or biological properties.
  • a benefit of protein analogues would be to achieve enhanced activity (such as metabolic regulation of metabolism leading to reduction in blood-glucose concentration under conditions of hyperglycemia) with decreased unfavorable effects (such as induction of hypoglycemia or its exacerbation).
  • a therapeutic protein is provided by insulin. Wild-type human insulin and insulin molecules encoded in the genomes of other mammals bind to insulin receptors in multiple organs and diverse types of cells, irrespective of the receptor isoform generated by alternative modes of RNA splicing or by alternative patterns of post-translational glycosylation.
  • An example of a medical benefit would be the non-standard design of a soluble insulin analogue whose intrinsic affinity for insulin receptors on the surface of target cells, and hence whose biological potency, would depend on the concentration of glucose in the blood stream.
  • Such an analogue may have a three-dimensional conformation that changes as a function of glucose concentration and/or may have a covalent bond to an inhibitory molecular entity that is detached at high glucose concentrations.
  • this long-sought class of protein analogues or protein derivatives is collectively designated “glucose -responsive insulins” (GRIs).
  • the insulin molecule contains two chains, an A chain, containing 21 residues, and a B chain containing 30 residues.
  • the mature hormone is derived from a longer single-chain precursor, designated proinsulin, as outlined in Fig. 1A.
  • Fig. IB depicts a structural model of proinsulin, consisting of an insulin- like moiety and a disordered connecting peptide (C-domain). While, Fig. 1C is a schematic representation of the sequence of human insulin including the A-chain and the B -chain disulfide connectivity.
  • Amino acids are chiral, and the configurations are designated L or D; L is presumed unless otherwise stated D- Amino acids are designated “D-Cys” or “D-Ala” (and so forth) in three-letter code; the small capital “D” (D) is used to avoid ambiguity with “D” as code for Asp. Alternatively D- amino acids are designated “dC” or “dA” (and so forth) in one-letter code, generally within brackets in sequence string.
  • the insulin hormone is stored in the pancreatic b-cell as a Zn 2+ - stabilized hexamer, it functions as a Zn 2+ -free monomer in the bloodstream.
  • the three-dimensional structure of an insulin monomer is shown as a ribbon model in Fig. 2.
  • Pertinent to the logic of the present invention is the proximity of the C terminus of the B chain (B30) to the N terminus of the A chain (Al), often engaged in a salt bridge (Fig. 3A).
  • Covalent tethering of the B-chain C-terminus (either from B30 or from neighboring residues B28, B29, B31 or B32) to A-chain B terminus blocks binding of the hormone to the insulin receptor (Fig.
  • An aspect of the present invention pertains to the chirality of amino acids.
  • Glycine is achiral
  • biosynthetic proteins ordinarily are comprised of t -amino acids, where the chiral center is the alpha-carbon of the amino acid.
  • the elements of the glucose-regulated conformational switch namely, the glucose-binding element attached to one chain and the diol or set of diols attached to the other — may be attached to D-amino acids, such that the positions in space of the switch elements is optimized and, on binding glucose, with least perturbation to receptor-binding affinity.
  • D-amino-acid substitutions known in the art to perturb receptor binding is provided by the substitution of GlyB8 by D-Ala (Nakagawa, S., et al., Biochemistry 44(13), 4984-99 (2005)).
  • An example of a D-amino-acid substitution known in the art to enhance receptor binding is provided by the substitution of PheB24 by D-Phe (Mirmira, R., and Tager, H.S. J. Biol. Chem. 264(11), 6349-54 (1989)).
  • substitution of GlyAl by D-amino acids generally preserves receptor-binding affinity whereas substitution of GlyA1 by L- amino acids generally impairs receptor-binding affinity (Wan, Z.L. and Liang, D.C. Scientia Sinica 31(12), 1426-38 (1988); Wan, Z.L. and Liang, D.C. Scientia Sinica 33(7), 810-20 (1990)).
  • Administration of insulin has long been established as a treatment for diabetes mellitus.
  • a major goal of conventional insulin replacement therapy in patients with diabetes mellitus is tight control of the blood-glucose concentration to prevent its excursion above or below the normal range characteristic of healthy human subjects.
  • Excursions above the normal range are associated with increased long-term risk of microvascular disease, including retinopathy, blindness, and renal failure.
  • Hypoglycemia in patients with diabetes mellitus is a frequent complication of insulin replacement therapy and when severe can lead to significant morbidity (including altered mental status, loss of consciousness, seizures, and death). Indeed, fear of such complications poses a major barrier to efforts by patients (and physicians) to obtain rigorous control of blood-glucose concentrations (i.e., exclusions within or just above the normal range), and in patients with long-established Type 2 diabetes mellitus such efforts (“tight control”) may lead to increased mortality.
  • mild hypoglycemia may activate counter-regulatory mechanisms, including over-activation of the sympathetic nervous system leading to turn to anxiety and tremulousness (symptoms designated adrenergic).
  • Patients with diabetes mellitus may not exhibit such warning signs, however, a condition known as hypoglycemic unawareness.
  • the absence of symptoms of mild hypoglycemia increases the risk of major hypoglycemia and its associated morbidity and mortality.
  • Multiple and recurrent episodes of hypoglycemia are also associated with chronic cognitive decline, a proposed mechanism underlying the increased prevalence of dementia in patients with long-standing diabetes mellitus.
  • glucose-responsive materials for co-administration with an insulin analogue or modified insulin molecule such that the rate of release of the hormone from the subcutaneous depot depends on the interstitial glucose concentration.
  • Such systems in general contain a glucose-responsive polymer, gel or other encapsulation material; and may also require a derivative of insulin containing a modification that enables binding of the hormone to the above material.
  • An increase in the ambient concentration of glucose in the interstitial fluid at the site of subcutaneous injection may displace the bound insulin or insulin derivative either by competitive displacement of the hormone or by physical-chemical changes in the properties of the polymer, gel or other encapsulation material.
  • the goal of such systems is to provide an intrinsic autoregulation feature to the encapsulated or gel-coated subcutaneous depot such that the risk of hypoglycemia is mitigated through delayed release of insulin when the ambient concentration of glucose is within or below the normal range.
  • glucose-responsive systems are in clinical use.
  • a recent technology exploits the structure of a modified insulin molecule, optionally in conjunction with a carrier molecule such that the complex between the modified insulin molecule and the carrier is soluble and may enter into the bloodstream. This concept differs from glucose-responsive depots in which the polymer, gel or other encapsulation material remains in the subcutaneous depot as the free hormone enters into the bloodstream.
  • insulin analogues of the present invention thus conform to one of four design schemes sharing the properties that (a) in the absence of glucose the modified insulin exhibits marked impairment in binding to the insulin receptor whereas (b) in the presence of a high concentration of glucose breakage of a covalent bond to a diol-modified B chain either leads to an active hormone conformation or liberates an active hormone analogue (Fig.4).
  • the presently disclosed design modifications of the insulin molecule are in each case smaller than the native A or B chains.
  • the present disclosure relates to polypeptide hormone analogues that contain a glucose-regulated molecular structure or glucose-detachable molecular moiety, designed respectively to either (a) confer glucose-responsive binding to cognate cellular receptors and/or (b) enable glucose-mediated liberation of an active insulin analogue. More particularly, in one embodiment the present disclosure focuses on novel combinations of modified A chains by incorporation of bis-boron-containing glucose-binding elements (GBE) that provide increase opportunity for selective binding to glucose through interaction(s) of two boronic acid moieties binding to one glucose molecule (Fig.6B), thereby allowing for the design and discovery of novel glucose responsive insulins (GRIs).
  • GBE bis-boron-containing glucose-binding elements
  • the present disclosure is directed to the use of the insulin analogues disclosed herein for use in the treatment of patients and non-human mammals with Type 1 or Type 2 diabetes mellitus by subcutaneous, intraperitoneal or intravenous injection.
  • the insulin analogues of the present invention may also exhibit other enhanced pharmaceutical properties, such as increased thermodynamic stability, augmented resistance to thermal fibrillation above room temperature, decreased mitogenicity, and/or altered pharmacokinetic and pharmacodynamic properties.
  • this invention relates to insulin analogues that may confer either rapid action (relative to wild-type insulin in its regular soluble formulation), intermediate action (comparable to NPH insulin formulations known in the art) or protracted action (comparable to basal insulins known in the art as exemplified by insulin detemir and insulin glargine), such that the affinity of the said analogues for the insulin receptor is higher when dissolved in a solution containing glucose at a concentration above the physiological range (> 140 mg/dL; hyperglycemia) than when dissolved in a solution containing glucose at a concentration below the physiological range ( ⁇ 80 mg/dL; hypoglycemia).
  • the analogues of the present invention contain two essential elements.
  • the first element is a diol-containing side chain in the B chain C- terminal segment (residues B27-B30 or as attached to extended B-chain residues B31 or B32) and/or a C-terminal main chain diol in the B chain;
  • the second is a glucose- binding element (GBE) attached at or near the N terminus of the A chain.
  • the diol-containing side chain is located at or near the N terminus of the A chain and the GBE is attached to an amino acid located at or near the C terminus of the B chain as in Fig. 6D.
  • One embodiment of the present disclosure pertains to the design and synthesis of glucose-responsive insulins (GRIs) containing modified A chains such that paired boron-containing moieties (BCMs) are tethered at or near the N-terminal residue (position Al); the B chains are modified to comprise diol adducts of arbitrary chemical composition at or near its C terminus.
  • BCMs may include phenyl-boronic acid (PBA)-based monomeric diol binders (illustrated in Fig.
  • BCMs may also include boronate esters such as benzoxaborole (Bxb), or a combination of PBA and Bxb elements.
  • Bxb benzoxaborole
  • Such inputs will be reacted with bifunctional scaffolds either built out separately, or prepared by solid-phase peptide synthesis using linker-based chemistries, to produce paired BCMs thus provide bis- boronic acid GBEs (Figs. 6B-6D, 8).
  • GBEs are specifically positioned at or near the N terminus of the A chain, optionally including modifications of D configuration of amino-acid side chains at position A1 and/or modifications of side chains at one- residue, two-residue or three-residue N-terminal extensions of the A chain (respectively designated positions Ao, A-i and A-2).
  • the A chain of the present invention can thus be the standard 21 residues in length or contain an N-terminal extension of one residue (Ao), two residues (A-1-A0), or three residues (A-2-A-1-A0) as illustrated in Fig. 5; or contain (as in insulin-like growth factors; IGFs) a C-terminal extension of 1-5 residues as might enhance the biophysical or biochemical properties of the insulin analogue.
  • the B chain of the present invention can likewise be the standard 30 residues in length or can contain deletion of residues B30, B29-B30, B28-B30 or B27-B30; or can contain an extension to contain additional residue B31 or additional residues B31-B32 as is known in the art.
  • the C-termini of these B chains can carry a carboxylate (as in a conventional peptide) or be modified to contain a main-chain diol.
  • an insulin analogue comprising an insulin A chain and an insulin B chain
  • the insulin A chain comprises a D-amino acid at position A1 or Ao and a glucose-binding element covalently linked at or near the insulin A-chain N terminus, optionally attached to the side chain of the amino acid at position A1 or Ao
  • the insulin B chain comprises a diol group at or near the C terminus of the insulin B chain, optionally wherein a diol- bearing moiety is linked to the side chain of the amino acid at position B28, B29 or B30 or wherein the diol group is a modified C-terminal amino acid (a) bearing a side chain hydroxyl group and (b) having the C-terminal carboxyl group replaced with CH2OH, such that the two hydroxyl groups together may bind to an A-chain-linked GBE.
  • the glucose -binding element is covalently linked to the side chain of an amino acid of the A chain, optionally wherein the glucose-binding element-bearing amino acid is a D-amino acid.
  • the glucose- binding element comprises two or more boron-containing moieties.
  • the glucose-binding element comprises two boron-containing moieties wherein the two boron-containing moieties are linked to one another (extrinsic to the polypeptide), wherein the paired boron-containing moieties are the same or different.
  • the boron-containing diol-binding element is selected from any of those disclosed in Fig.
  • the boron- containing moiety is selected from phenylboronic acid (BCM1) elements and benzoboroxole (Bxb) as in BCMs 2-4. While not wishing to be constrained by theory, we envisage that pairwise and higher-order combinations of boron-containing diol- binding moieties, each containing one or more boron atoms, would enhance (a) avidity and the affinity of this combination of boron-containing moieties and the glucose molecule and (b) the cooperativity of glucose-dependent activation of hormonal activity as a function of ambient glucose concentration.
  • Enhanced cooperativity would in turn confer more effective switch- like regulation of glycemia as a function of blood-glucose concentration, a favorable property to mitigate the risk of hypoglycemia in patients with diabetes mellitus.
  • Individual boron-containing diol- binding moieties as isolated small molecules, are known in the art (for review, see Williams, G.T., Kedge, J.L., and Fossey, J.S. Molecular Boronic Acid- Based Saccharide Sensors. ACS Sens. 6(4), 1508-28 (2021)).
  • the glucose-binding element bearing insulin A chains of the present disclosure comprises a single amino acid at the N-terminus linked via a peptide bond to the alpha-amino group of the amino acid bearing the glucose-binding element disclosed in Fi-s. 5 and 6A.
  • the amino acid positioned at the N-terminus of the glucose-binding-element-bearing A chain is any of the L or D configurations standard 20 amino acids, in another embodiment the N-terminal amino acid is an aliphatic amino acid selected from alanine, glycine, isoleucine, leucine, proline, and valine, and in yet another embodiment the N-terminal amino acid of the glucose-binding element bearing A chain is glycine.
  • the N-terminal amino acid of the glucose-binding-element-bearing A chain is in the D- configuration, as depicted in Figs.10B, 11A and 12C.
  • the insulin analogue of the present disclosure comprises a B chain that is truncated, lacking residue B30, residues B29-B30, residues B28-B30, residues B27-B30 or residues B26-B30, with a diol group located at the C terminus of the truncated B chain.
  • the native B chain is extended by one or two amino acids with a diol group located at the C terminus of the extended B chain, optionally in conjunction with a diol-modified side chain.
  • an insulin analogue wherein the insulin A chain is a polypeptide selected from the group consisting of X -1 X 0 X 1 IVEQX 6 CX 8 SIX 11 SLYQLENYCN (SEQ ID NO: 4) X0X1IVEQX6CX8SIX11SLYQLENYCN (SEQ ID NO: 5), and X70IVEQX6CX8SIX11SLYQLENYCN (SEQ ID NO: 83) wherein X -1 is any amino acid, optionally wherein X -1 is Gly; X0 is any amino acid or a modified amino acid comprising a glucose- binding element linked to its side chain; X1 is any amino acid or a modified amino acid comprising a glucose- binding element linked to its side chain; X6 and X11 are each Cys or selenocysteine; and X 8 is Thr, His, Lys, Arg, or Glu; X70 is a D- amino
  • the insulin B chain is a polypeptide comprising the sequence of FVX24QHLCGSHLVEALYLVCGERGFFYTX49X50X51 (SEQ ID NO: 6), wherein X24 is Lys or Asn; X 49 is a modified amino acid comprising a diol bearing moiety linked to the side chain of the amino acid; X 50 is Orn, Lys or Pro; and X51 is Thr or a diol bearing amino acid. In a further embodiment both X 49 and X 51 are modified amino acids comprising a diol.
  • FIG.1A is a schematic representation of the sequence of human proinsulin (SEQ ID NO: 1) including the A- and B-chains and the connecting region shown with flanking dibasic cleavage sites (filled circles) and C-peptide (open circles).
  • FIG.1B is a structural model of proinsulin, consisting of an insulin-like moiety and a disordered connecting peptide (dashed line).
  • FIG.1C is a schematic representation of the sequence of human insulin including the A-chain (SEQ ID NO: 2) and the B-chain (SEQ ID NO: 3) and indicating the position of residues B27 and B30 in the B-chain.
  • FIG.2 is cylinder model of insulin in which the side chains of TyrB16, PheB25 and TyrB26 are shown.
  • the A- and B-chain ribbons are shown in light gray and dark gray, respectively.
  • FIG.3A provides a ribbon/cylinder diagram highlighting a potential salt bridge between the C-terminal carboxylate of the B chain (its negative charge is depicted as a minus – within circle at B30) and alpha-amino group of the A chain (its positive charge is depicted as a plus + within circle) as observed in a subset of wild- type insulin crystallographic protomers.
  • FIG. 3B provides a ribbon/cylinder diagram highlighting a peptide amide bond (box) between the C-terminal carboxylate of the B chain and alpha-amino group of the A chain as observed in inactive single-chain insulin analogues.
  • FIG. 3C provides a generic scheme in which a diol-modified B chain containing a main-chain hydroxyl group (boxed) in combination with a neighboring hydroxyl group (which may be on a side chain or attached via one or more intervening atoms to the main-chain nitrogen) binds to a glucose-binding element at or near the N terminus of the A chain (horseshoe).
  • FIG. 4 provides a design scheme of monosaccharide-responsive insulin.
  • the ribbon model of closed inactive insulin (T-state monomer, left) is shown (with a free glucose molecule adjacent to it); the gray box highlights sites of modification (horseshoe shape indicates glucose-binding element; diamond indicates internal diol).
  • the envisioned glucose-regulated conformational cycle in which a monosaccharide acts as a competitive ligand to regulate a conformational switch between the closed state (inactive in absence of ligand) and the open state (active in presence of ligand).
  • FIG. 5 illustrates sequence of insulin showing A-chain (light; SEQ ID NO: 2) and B-chain (dark; SEQ ID NO: 3) with sites of chemical modification (underlined) including A-chain N-terminal residues A-i, Ao, and GlyAl and B-chain residues Y B26- T B30 to affect monosaccharide responsivity. Amino acid residues are labelled using their standard single letter codes.
  • Glucose-binding element (horseshoe) is installed at the A-chain N-terminal (positions Ao, Al) as well as at A8.
  • the poly-ol binding group (diamond shape) is installed at the B-chain C-terminal (positions B26- B30) either modified through side chain positions or the main-chain amide nitrogen atom(s).
  • FIG. 6 A depicts the reversible interaction between 3-fluoro phenylboronic acid (3fPBA) placed at or near the A-chain N-terminal with dihydroxybenzoic acid (DHBA) placed in the B-chain Cterminus.
  • 3fPBA 3-fluoro phenylboronic acid
  • DHBA dihydroxybenzoic acid
  • FIG. 6B depicts basis for preferential glucose-binding of /Av-boronic acids when attached through appropriately placed linker(s) (curved line) (Norrlid, 1995).
  • FIG. 6C provides a molecular representation of GRI- 1 and its conformational switch between the closed state (left) and open state (right).
  • FIG. 6D illustrates a “flipped” embodiment in which the GBE is attached at or near the C terminus of the B chain whereas the diol moiety or moieties are attached at or near the N terminus of the A chain.
  • FIG. 7 illustrates phenyl-boronic acid (PBA) based monomeric structures containing carboxylate group (top row, BCMl-4), amino group (middle row, BCM5- 8), and aldehyde group (bottom row, BCM9-12) handles to be used as monomeric library inputs.
  • PBA phenyl-boronic acid
  • Such inputs will be reacted with bifunctional linkers and linker-based chemistries to produce paired boron-containing monomers (BCMs) to provide bis- boronic acid glucose-binding elements (GBEs).
  • FIG. 8 Illustrates two distinct and novel strategies for glucose-binding element optimization and frameworks that incorporate either a branchmer-based linker scaffold approach or a Tandem backbone design configuration.
  • FIG. 9 Illustrates incorporation of aldehyde containing BCMs (9-12) onto the backbone amide nitrogens of A-i, Ao, A1 positions in the insulin A-chain as an alternate approach to tandem backbone modification that directly modifies the backbone amide bonds of these preferred positions.
  • FIG. 10A depicts potential glucose sensors prepared on solid phase resins (see Fig. 12A) containing symmetrically paired boron-containing monomer (BCM2,) attached through linkers having four (4), six (6), and six (6) atom spacer respectively.
  • BCM2 symmetrically paired boron-containing monomer
  • Each paired BCMs has a thiol-based handle for chemoselective conjugation reaction onto specifically designed and positioned SH reactive group on an insulin framework as in Figs 12B, 13, 14 and applied to the synthesis of GRIs 1- 4.
  • Each paired BCM containing structures design for the inherent selectivity of boronic acids toward monosaccharides and how two phenyl-boronic acids can provide a path for glucose selectivity thru spatial disposition and molecular complementarity.
  • Fig. 10B provides a general scheme for the combinatorial design of paired BCMs illustrating three (3) different branch-mer configurations carrying a C-terminal Cys residue which provides a “thiol handle” (via nitropyridyl-sulfenyl-based activation, Fig.
  • the middle and right two panels illustrate a similar design strategy but also include an N-terminal amino acid insertion (center right) or side-chain amino acid insertion (far right), where R represents single-chain of any proteogenic L -amino acid or D- amino acid.
  • R represents single-chain of any proteogenic L -amino acid or D- amino acid.
  • Such changes are useful for optimizing the GBE to specific polyol groups of interest (i.e., glucose or fructose selectivities).
  • the right two panels illustrate modifications of the A-Chain N-terminal with BCMs 1-4 while the single-chain amino group at A0 or A1 is extended on the B-chain N-terminal by a single residue comprising any proteogenic L- amino acid or D- amino acid. In all cases BCMs 1 thru 5 can be selectively and unambiguously coupled to any of position indicated.
  • the left panel illustrates either the N-terminal amino-acid insertion (far left) or side-chain amino acid insertion (second left), where R represents single-chain of any proteogenic L- amino acid or D- amino acid or non-natural amino acids.
  • Such changes are useful for optimizing the GBE to specific polyol groups of interest (i.e., glucose or fructose selectivities).
  • the center two panels illustrate modifications of the A-chain N-terminal with BCMs 1-4 while the side-chain amino group at Ao or A1 is extended by one residue via any proteogenic t -amino acid or D-amino acid.
  • the far right structure illustrate elaboration of both Ao and Ai positions with basic amino acids to install GBE1-4 in both positions where A-i is any t -amino acid.
  • BCMs 1-4 can be selectively and unambiguously coupled to any of these five amino position.
  • FIG. 11B provides explicit structures of the glucose-binding elements (GBEs) that are defined as GBE1, GBE2, GBE3, GBE4, GBE5, and GBE6 containing paired BCM2 groups attached to the branch-mers (Dap and Dab).
  • GBEs 1 and 4 the BCMs are directly linked to both amino groups of the Dap or Dab amino groups to as exemplified in the left panel.
  • BCM2-Xxx-Dab(BCM2)-OH BCM2-Dab(BCM2-Xxx)-OH
  • Xxx glycine, prior to paired BCM2 coupling.
  • the use of Xxx recognizes the substitution by any other L-AAS, D-AAS , or non-natural AAs would create unique GBEs thus allowing for modulation of binding properties of each GBE with respect to affinity and selectivities toward glucose, other monosaccharides, or polysaccharide.
  • FIG. 12A depicts reaction schemes used for solid phase synthesis of Glucose- binding element (GBE) GBEs 1-6 herein explicitly built out to connect (1) GBEs 4,
  • FIG. 12B depicts resultant molecule GBEl-Cys(SH)-OH prepared on H- Cys(Trt)-0-Wang or H-Cys(Trt)-0-Cl-Trt- resins employing the reaction scheme shown in Fig. 12A but using Fmoc-Dap(Fmoc)-OH in place of Fmoc-Dab(Fmoc)-OH in far left column.
  • the free SH group of GBEl-Cys(SH)-OH is activated using DBNP (2,2 -Dithiobis(5-nitropyridine)) in TFA to produce GBEl-C(Npys)-OH which then allows for conjugation to Cys(SH)Ao or dCys(SH)Al synthetic insulin precursors to produce the disulfide linked GBE-insulin intermediates.
  • FIG. 13 depicts the synthetic reaction scheme to prepare GA-i, Cys(SH)Ao or GAo, dCys(SH)Al modified DesDi-insulin and the coupling of GBEl-C(Npys)-OH to form the disulfide linked GBE intermediates onto their respective frameworks.
  • Specific examples include four single-chain insulins (B1-B28-A1A21) frameworks carrying native disulfide pairing and the Selenocysteine (SecA6-SecAll) bridge substitutions as precursors to GRIs 1-4.
  • FIG. 14 depicts GlyA-i, Cys(GBE-1)A 0 , SecA6, SecAll, Lys(DHBA)B29- lispro and GAo, dC(GBE-l)Al, SecA6-SecAll, Lys(DHBA)B29 -lispro insulin synthetic scheme to prepare disulfide linked (GBE 1C) GBEs onto the L-CysAo or D- CysAl modified DesDi-insulin frameworks (single-chain insulins (B1-B28-A1A21) containing selenocysteine (SecA6-SecAll) diselenide -bridge substitution.
  • Desoctapeptide (DOI) precursors were used in Trypsin mediated coupling reaction using Lys(DHBA)B28 modified octapeptides (SEQ ID NO: 10), an N-terminally modified A chain comprising a GBE-1 at position A0 (SEQ ID NO: 8) linked via disulfide bonds to a C-terminally truncated B chain (SEQ ID NO: 9).
  • Lys(DHBA)B28 modified octapeptides SEQ ID NO: 10
  • an N-terminally modified A chain comprising a GBE-1 at position A0 SEQ ID NO: 8 linked via disulfide bonds to a C-terminally truncated B chain
  • a similar scheme was used for the native disulfide bridge containing analogues and for frameworks modified with GBE2-C and GBE3-C disulfide bond connections.
  • FIG. 15 depicts the generalized solid phase synthetic scheme to prepare and install amide bond linked glucose-binding elements (GBEs 1-6). Illustrated here for GlyA0, [ D -Dap(GBE4)]A1, and GlyA0, [ D -Dap(GBE5)]A1,-DesDI single-chain insulin intermediates. The same scheme was also used to prepare additional DesDi single-chain analogues carrying GBEs 1-6.
  • FIG.16 depicts the generalized solid phase synthetic scheme to prepare and install amide bond linked glucose-binding elements (GBEs 1-6) as a GlyA -1 , [Dap(GBE1)]A1, HisA8 and GA-1, [Dap(GBE3)]A1, HisA8 DesDi single-chain insulin intermediates (SEQ ID NO: 11). The same scheme was also used to prepare additional DesDi single-chain analogues carrying GBEs 1-6.
  • FIG. 17 provides control studies of insulin lispro (“KP” in inset legends) demonstrating absence of glucose dependence ( ⁇ 50 mM glucose; upper) and absence of fructose dependence ( ⁇ 50 mM fructose; lower).
  • FIG. 18 demonstrates monosaccharide-dependent biological activity of a derivative of insulin lispro (GRI-2, in inset legends) where GRI-2 is defined as analogue GlyA-1,Cys(GBE1-C)A0, Lys(DHBA)B28-lispro.
  • the A chain contains a two-residue N-terminal extension (Gly at position A-1 and Cysteine at position A 0 ), and modification of the CysA0 side-chain thiol group by a paired BCM2 in the form of GBE1-C (see Fig.14).
  • the B chain is modified at the epsilon-amino group of LysB28 by 2,3-dihydroxybenzoic acid (DHBA).
  • the two-panel format is as in Fig. 17, respectively testing glucose dependence ( ⁇ 50 mM glucose; upper) and absence of fructose dependence ( ⁇ 50 mM fructose; lower).
  • FIG. 1 In each panel extent of pIR/IR phosphorylation is shown (vertical axis; normalized to initial pIR/IR ratio in absence of hormone) as a function of insulin analogue concentration in nanomolar units (horizontal axis). Data obtained in the absence (or presence) of a monosaccharide are shown as blue diamonds (or orange squares). Abbreviations: IR and pIR, insulin receptor and phosphorylated insulin receptor, respectively.
  • FIG. 1 In each panel extent of pIR/IR phosphorylation is shown (vertical axis; normalized to initial pIR/IR ratio in absence of hormone) as a function of insulin analogue concentration in nanomolar units (horizontal axis). Data obtained in the absence (or presence) of a monosaccharide are shown as blue diamonds (or orange squares). Abbreviations: IR and pIR, insulin receptor and phosphorylated insulin receptor, respectively.
  • GRI-3 is defined as analogue GlyA-i, Cys(GBEl-C)Ao, SecA6, SecAll, Lys(DHBA)B28-/Apro.
  • the A chain contains a two-residue N-terminal extension (Gly at position A-i and Cysteine at position Ao), and modification of the CysAo side-chain thiol group by a paired BCM2 2 in the form of GBE1-C (see Fig. 14.
  • the B chain is modified at the epsilon-amino group of LysB28 by 2,3-dihydroxybenzoic acid (DHBA).
  • the two-panel format is as in Fig. 17, respectively testing glucose dependence ( ⁇ 50 mM glucose; upper) and absence of fructose dependence ( ⁇ 50 mM fructose; lower).
  • glucose dependence ⁇ 50 mM glucose; upper
  • fructose dependence ⁇ 50 mM fructose; lower
  • pIR/IR phosphorylation is shown (vertical axis; normalized to initial pIR/IR ratio in absence of hormone) as a function of insulin analogue concentration in nanomolar units (horizontal axis).
  • Data obtained in the absence (or presence) of a monosaccharide are shown as blue diamonds (or orange squares).
  • FIG. 20 demonstrates monosaccharide-dependent biological activity of a derivative of insulin lispro (GRI-4 in inset legends) where GRI-4 is defined as insulin analogue GlyAo, D-Cys(GBEl-C)Al, SecA6, SecAll, Ly s ( D H B A ) B 28 Pro - //.s/vv .
  • GRI-4 is defined as insulin analogue GlyAo, D-Cys(GBEl-C)Al, SecA6, SecAll, Ly s ( D H B A ) B 28 Pro - //.s/vv .
  • the A chain contains a one -residue N-terminal extension (Gly at position Ao), substitution of Glycine at A 1 by D-Cysteine, and modification of the D-CysAl side- chain thiol group by a paired BCM2 in the form of GBE1-C (see Fig. 14).
  • the B chain is modified at the epsilon-amino group of LysB28 by 2,3-dihydroxybenzoic acid (DHBA).
  • the two-panel format is as in Fig. 17, respectively testing glucose dependence ( ⁇ 50 mM glucose; upper) and absence of fructose dependence ( ⁇ 50 mM fructose; lower).
  • FIGs. 21A-21C depicts cell signaling assay for GRI-3, defined as insulin analogue GlyAo, D-Cys(GBEl-C)Al, SecA6, SecAll, Lys( DHB A)B28-//.syw and glucose-dependent IR phosphorylation (Fig. 21A) and glucose-dependent gene regulation in HepG2 cells in culture with respect to a representative glucogenogenic gene (PEPCK; Fig. 2 IB) and genes regulating lipid biosynthesis (ChREBP and SREBP; Fig. 21C).
  • Data in (Fig. 21A) are remarkable for Time in range (TIR) and interconversion of glucose units (mg/dL and mM) are shown in schematic form at right.
  • FIG. 22 illustrates potency comparison following intravenous injection of insulin lispro versus GRI-1 (composition GlyAo, D-Cys(GBEl-C)Al,
  • Lys( DHBA)B28-//.syw potency is approximately one half that of insulin lispro.
  • Panel B Area over the curve (AOC) is calculated. Mean ⁇ SEM; *denotes p ⁇ 0.05.
  • FIGS. 24A-24C illustrate the glucose clamp protocol and graphical results using insulin lispro, GRI-1, and diluent.
  • Fig. 24B provides an example of the glucose infusion rate (GIR) protocol using 2.8 nmol/kg of insulin lispro or diluent aimed at a blood-glucose target concentration of 250 mg/dL.
  • GIR glucose infusion rate
  • the difference between the glucose infusion rate (GIR) for insulin lispro (purple wavy line) and diluent (blue line) represents the GIR attributable to the effect of insulin.
  • Fig. 24C depicts results of GIR attributable to insulin lispro (left) and GRI- 1 (right) are shown.
  • Data from 60 separate experiments using insulin lispro, GRI-1, and diluent clamped at different glucose levels are summarized in the bar graphs and FIG. 25.
  • the GIR values using insulin lispro at different glucose levels is not significantly different from each other, while GIR values using GRI-1 are significantly higher at elevated glucose levels.
  • FIG. 25 lists the data calculation from Fig. 24C in the euglycemic and hyperglycemic clamp protocol.
  • A. In the absence of any insulin injection (diluent- injected), the Glucose Infusion Rate (GIR) necessary to maintain blood-glucose concentrations at several pre-selected targets is shown (mg glucose/kg/h).
  • B. The GIR necessary to maintain blood-glucose concentrations at several pre-selected target levels following subcutaneous injection of 5.0 Fg insulin lispro (2.8 nmol/kg) is shown. The GIR attributable to the effect of insulin lispro is calculated as the difference in the GIR using insulin lispro and diluent.
  • GIR necessary to maintain blood-glucose concentrations at several pre-selected target levels following subcutaneous injection of 12.5 Fg of GRI-1 (7.0 nmol/kg) is shown; the GIR attributable to the effect of GRI- 1 is calculated as the difference in the GIR between use of GRI-1 insulin and diluent (from panel A). Data are shown as mean ⁇ SEM.
  • Phase A glucose infusion rate was adjusted to a target blood-glucose concentration of 85 mg/dL.
  • Phase B 40-70 min: at 30 min, glucose infusion was increased to reach the goal of 200 mg/dL by 40 min; glucose infusion was then continued to maintain the blood- glucose concentration of 200 mg/dL.
  • Lig. 26B Results of GIR attributable to GRI-1 at blood-glucose concentrations of 85 and 200 mg/dL are shown. Data from 16 separate experiments using diluent or GRI-1 are summarized in the bar graphs (LIG. 27). Mean ⁇ SEM; *denotes p ⁇ 0.05.
  • LIG. 27 lists the data calculations from Lig. 26B in the bi-phasic glucose clamp protocol and results using GRI-1 and diluent.
  • purified and like terms relate to the isolation of a molecule or compound in a form that is substantially free of contaminants normally associated with the molecule or compound in a native or natural environment. As used herein, the term “purified” does not require absolute purity; rather, it is intended as a relative definition.
  • isolated requires that the referenced material be removed from its original environment (e.g., the natural environment if it is naturally occurring).
  • a naturally-occurring polynucleotide present in a living animal is not isolated, but the same polynucleotide, separated from some or all of the coexisting materials in the natural system, is isolated.
  • the term “pharmaceutically acceptable carrier” includes any of the standard pharmaceutical carriers, such as a phosphate buffered saline solution, water, emulsions such as an oil/water or water/oil emulsion, and various types of wetting agents.
  • the term also encompasses any of the agents approved by a regulatory agency of the US Federal government or listed in the US Pharmacopeia for use in animals, including humans.
  • treating includes alleviation of the symptoms associated with a specific disorder or condition and/or preventing or eliminating said symptoms.
  • an "effective” amount or a “therapeutically effective amount” of a drug refers to a nontoxic but enough of the drug to provide the desired effect.
  • the amount that is "effective” will vary from subject to subject or even within a subject overtime, depending on the age and general condition of the individual, mode of administration, and the like. Thus, it is not always possible to specify an exact “effective amount.” However, an appropriate “effective” amount in any individual case may be determined by one of ordinary skill in the art using routine experimentation.
  • patient without further designation is intended to encompass any warm blooded vertebrate domesticated animal (including for example, but not limited to livestock, horses, cats, dogs and other pets) and humans receiving a therapeutic treatment with or without physician oversight.
  • inhibitor defines a decrease in an activity, response, condition, disease, or other biological parameter. This can include but is not limited to the complete ablation of the activity, response, condition, or disease. This may also include, for example, a 10% reduction in the activity, response, condition, or disease as compared to the native or control level. Thus, the reduction can be a 10, 20, 30, 40, 50, 60, 70, 80, 90, 100%, or any amount of reduction in between as compared to native or control levels.
  • Diol-bearing amino acids comprise natural or unnatural amino acids whose side chains are modified by linkage of a diol moiety to an attachment point located on the amino acid side chain.
  • side chain attachment points are provided by a thiol function, amino function or carboxylate function.
  • Amino-containing side chains may be provided by the natural amino acid Lysine or by unnatural amino acids Ornithine (Orn), Diaminobutyric Acid (Dab) and Diaminoproprionic acid (Dap), each in either the L- or D configuration.
  • Thiol-containing amino acids may be the natural amino acid Cysteine or the unnatural amino acid Homocysteine, each either in the L- or D configuration.
  • Diol-bearing amino acids represent the covalent combination of (a) the above recited amino acids and (b) a diol moiety exemplified (but not restricted to) those listed in Table 2.
  • the term “threoninol” absent any further elaboration encompasses L-allo-threoninol, D-threoninol and D-allo-threoninol.
  • main-chain defines the backbone portion of a polypeptide, and distinguishes the atoms comprising the backbone from those that comprise the amino acid side chains that project from the main-chain.
  • the term “pharmaceutically acceptable salt” refers to those salts with counter ions which may be used in pharmaceuticals. See, generally, S.M. Berge, et ak, “Pharmaceutical Salts,” J. Pharm. Sci., 1977, 66, 1-19.
  • Preferred pharmaceutically acceptable salts are those that are pharmacologically effective and suitable for contact with the tissues of subjects without undue toxicity, irritation, or allergic response.
  • a compound described herein may possess a sufficiently acidic group, a sufficiently basic group, both types of functional groups, or more than one of each type, and accordingly react with a number of inorganic or organic bases, and inorganic and organic acids, to form a pharmaceutically acceptable salt.
  • Such salts include:
  • acid addition salts which can be obtained by reaction of the free base of the parent compound with inorganic acids such as hydrochloric acid, hydrobromic acid, nitric acid, phosphoric acid, sulfuric acid, and perchloric acid and the like, or with organic acids such as acetic acid, oxalic acid, (D)- or (L)-malic acid, maleic acid, methane sulfonic acid, ethanesulfonic acid, -toluenesul Ionic acid, salicylic acid, tartaric acid, citric acid, succinic acid or malonic acid and the like; or
  • a metal ion e.g., an alkali metal ion, an alkaline earth ion, or an aluminum ion
  • organic base such as ethanolamine, diethanolamine, triethanolamine, trimethamine, N-methylglucamine, and the like.
  • Acceptable salts are well known to those skilled in the art, and any such acceptable salt may be contemplated in connection with the embodiments described herein.
  • acceptable salts include sulfates, pyrosulfates, bisulfates, sulfites, bisulfites, phosphates, monohydrogen-phosphates, dihydrogenphosphates, metaphosphates, pyrophosphates, chlorides, bromides, iodides, acetates, propionates, decanoates, caprylates, acrylates, formates, isobutyrates, caproates, heptanoates, propiolates, oxalates, malonates, succinates, suberates, sebacates, fumarates, maleates, butyne-l,4-dioates, hexyne-l,6-dioates, benzoates, chlorobenzoates, methylbenzoates, dinitrobenzoates, hydroxybenzoates, methoxy
  • the term “native insulin peptide” is intended to designate the 51 amino acid heterodimer comprising the A chain of SEQ ID NO: 2 and the B chain of SEQ ID NO: 3, as well as single-chain insulin analogues that comprise SEQ ID NOS: 2 and 3.
  • insulin peptide as used herein, absent further descriptive language is intended to encompass the 51 amino acid heterodimer comprising the A chain of SEQ ID NO: 2 and the B chain of SEQ ID NO: 3, as well as heterodimers and that comprise modified derivatives of the native A chain and/or B chain.
  • an “insulin A chain” is defined as the 21 amino acid sequence of SEQ ID NO: 2 as well as any modified derivatives of the native A chain
  • an insulin B chain is defined as the 30 amino acid sequence of SEQ ID NO: 3 as well as any modified derivatives of the native B chain.
  • Modified derivatives of the “insulin peptide”, “insulin A chain” and “insulin B chain” included one or more amino-acid substitutions at positions selected from A1,A5, A8, A9, A10, A12, A14, A15, A17, A18, A21, Bl, B2, B3, B4, B5, B9, B10, B13, B14, B17, B20, B21, B22, B23, B26, B27, B28, B29 and B30, or deletions of any or all of positions Bl-4 and B26-30, or the addition of 1-3 amino acids to the N-terminus of the A chain or at the C-terminus of the B chain.
  • Additional amino acids linked to the insulin A chain peptide at the N-terminus are numbered starting with 0 and increasing in negative integer value as they are further removed from the native insulin A chain sequence.
  • the position of an amino acid within an N-terminal extension of the A chain is designated A-i or Ao, wherein Ao represents the position of an amino acid added directly through the use of a standard amide-bond connectivity to the native N-terminal amino acid of the insulin A chain, and A-i represents the position of an amino acid having a single amino acid intervening between the A-i amino acid and the native N-terminal A1 amino acid of the insulin A chain.
  • an amino acid “modification” refers to a substitution, addition or deletion of an amino acid through amide bond coupling or other amide bond isosteric mimetice bond connectivity, or the derivation of an amino acid by the addition and/or removal of chemical groups to/from the amino acid, and includes substitution with or addition of any of the 20 amino acids commonly found in human proteins, as well as atypical or non-naturally occurring amino acids.
  • Commercial sources of atypical amino acids include Sigma- Aldrich (Milwaukee, WI), ChemPep Inc. (Miami, FL), and Genzyme Pharmaceuticals (Cambridge, MA).
  • Atypical amino acids may be purchased from commercial suppliers, synthesized de novo, or chemically modified or derivatized from naturally occurring amino acids.
  • amino acid substitution refers to the replacement of one amino acid residue by a different amino acid residue.
  • all references to a particular amino acid position by letter and number refer to the amino acid at that position of either the A chain (e.g. position A5) or the B chain (e.g. position B5) in the respective native human insulin A chain (SEQ ID NO: 2) or B chain (SEQ ID NO: 3), or the corresponding amino acid position in any analogues thereof.
  • a reference herein to “position B28” absent any further elaboration would mean the corresponding position B27 of the B chain of an insulin analogue in which the first amino acid of SEQ ID NO: 3 has been deleted.
  • linker is a bond, molecule or group of molecules that binds two separate entities to one another. In one embodiment the linker provides optimal spacing of the two entities.
  • GBE glucose -binding elements
  • BCMs boron-containing moieties
  • a bis-boronic acid GBE is a GBE comprising two boron-containing moieties wherein the two boron-containing moieties are linked to one another either directly or through a linker.
  • boron-containing moiety is a chemical structure comprising a boron molecule covalently linked to two oxygen atoms, wherein the boron-containing moiety is capable of interacting with a diol containing entity to form a reversible covalent link between the diol and the boron atom (see Figs. 6A-6D).
  • a glucose responsive insulin is an insulin analogue that comprises a glucose-binding elements (GBEs).
  • GRIs are inactive or exhibit reduced activity relative to native insulin under hypoglycemic conditions but become activated at elevated glucose concentrations, optionally at blood-glucose concentrations greater than 150 mg/dL after 8 hours of fasting, and bind the insulin receptor with high affinity.
  • analogues of native insulin have been prepared that are biological sensors that activate only under hyperglycemic conditions.
  • the insulin analogue comprises an insulin A chain peptide modified by the linkage of a glucose-binding element at or near its N terminus and a B chain modified by the linkage of one or more diol adducts at or near its C terminus, wherein the glucose-binding element comprises two or more boron-containing diol-binding elements disclosed in Figs. 4, 5, 6A, 6C .
  • the insulin analogue comprises an insulin B chain peptide modified by the linkage of a glucose binding element at or near its C terminus comprising two or more boron-containing diol-binding elements and containing an A chain modified by linkage of (i) one or more diol adducts at or near its N terminus and/or (ii) one or more glucose-binding elements (together or singly containing two or more boron atoms) at or near its N terminus disclosed in Fig. 6D.
  • the boron- containing diol-binding element is selected from any of those disclosed in Fig. 7.
  • the boron-containing diol-binding element of the glucose-binding element is selected from phenylboronic acid and benzoboroxole.
  • the N-terminus of the insulin A chain peptide is modified to comprise two glucose binding elements wherein the boron containing moieties comprising the glucose binding elements are the same or different.
  • the modified A chain may also contain a broad molecular diversity of paired BCMs, either as branched adducts attached at one site of the modified A chain (e.g. at a single amino acid side chain) or as separate adducts attached at two or more peptide sites (e.g. at the side chain of two separate amino acids) as exemplified in Fig. 11 A (far right panel) .
  • the paired boron-containing moieties of the present invention may thus contain combinations of individual BCMs such as phenylboronic acid (BCM1) elements and benzoboroxole (BCM2, BCM3) elements linked by a scaffold that is small relative to the size of insulin itself ( ⁇ 50 atoms) as illustrated in Fig.
  • the BCM elements may contain halogen substituents to optimize its monosaccharide-binding properties at neutral pH. In the case of A chains modified at two or more sites, this scaffold would include intervening residues of the peptide as illustrated in fig. 8 (tandem backbone design).
  • the present invention thus encompasses novel combinations of (i) a modified A-chain peptide sequence, (ii) one or more attachment points at or near residue A1 and (iii) a set of boron-containing moieties (BCM where PBA and/or BXB are examples) such that such combinations provide an insulin- specific glucose-responsive or glucose-cleavable “switch.”
  • BCM boron-containing moieties
  • the molecular purpose of the paired boron-containing A-chain modifications is to provide a glucose-binding element capable of forming an intramolecular bond or bonds with B -chain- attached diol adducts such that the conformation of insulin is “closed” and so impaired in binding to the insulin receptor.
  • element 1 is defined by the composition and chemical nature of the GBEs (e.g., mono-boronic acid, /Av-boronic acid [with subclasses symmetrical and asymmetrical, each incorporating various BCMs as illustrated in Figs.
  • GBEs e.g., mono-boronic acid, /Av-boronic acid [with subclasses symmetrical and asymmetrical, each incorporating various BCMs as illustrated in Figs.
  • GBEs have dual roles to (i) competitively bind glucose while at the same time binding a B -chain- tethered diol or poly-ol (design element 2) and thereby (ii) in constrain an intramolecular switch (design element 3). Binding of the GBE to glucose competes with its binding to the internal diol component(s) ( Figures 4 and 5).
  • Design element 2 is defined by the composition and chemical nature of B- chain-tethered diol moieties.
  • the element functions as a glucose-competable “lock” to stabilize an inactive conformation of the hormone analogue.
  • the modified A chains of the present invention can be combined with a combination of side-chain and main- chain diol modifications of the B chain at or near its C terminus as previously disclosed (USPTO Provisional Application 63/104,196, entitled “Molecular Designs of Glucose-Responsive and Glucose-Cleavable Insulin Analogues”; incorporated by reference herein).
  • Design element 3 specifies the placement of the intramolecular switch that effects a glucose-dependent conformational transition between active and inactive states.
  • Optimal placement of the A-chain modifications depends on the location of the B- chain diol(s) and vice versa.
  • the present invention focuses on the combination of (a) A-chain analogues modified by pairs of boron-containing moieties (BCMs) at or near its N terminus and (b) B-chain analogues modified by diol moieties at or near its C terminus.
  • BCMs boron-containing moieties
  • BCMs boron-containing moieties
  • diol moieties at or near its C terminus.
  • Such co-modifications permit a ligand-regulated reversible conformational cycle between active and inactive states of insulin, where the ligand is preferably glucose (Fig. 5 and 6B).
  • This scheme is in accordance with structural models of the complex between insulin and the insulin receptor as determined by X-
  • SEQ IDs offer the unique advantage of a closed state that mirrors that ultra-stable structure of a “mini-proinsulin” in which a direct peptide bond connects a C-terminal B chain residue (B28, B29, or B30) to GlyAl or in which 1-3 intervening residues are placed between residues B30 and A1 as foreshortened connecting domains.
  • a novel design scheme that reduces to practice a glucose-cleavable tether between the C terminus of the B chain and N terminus of the A chain, thereby providing a novel class of insulin analogues that would be closed and inactive at low glucose concentration but open and active at high glucose concentration.
  • the resulting cycle of conformational states (Fig. 4) would in principle be reversible (depending on a patient’s metabolic state), and its implementation would be consistent with the structure of the insulin- IR ectodomain complex.
  • Sequence IDs, molecular compositions and protein sequences for specific and critical GBE-linked DOI intermediates and preferred GBE-containing K(DHBA)B28-KP GRIs are provided in the SEQ ID section.
  • Table 1 contains a list of valuable on-resin synthetic intermediates, purified single-chain insulin analogues that are useful for further design and elaboration commensurate with the spirit of this invention, and two groups of putative GRIs designated as; A-Chain GBE, B-Chain (Diol)B28 Analogues (16 embodiments) and A-Chain DHBA, B- Chain (GBE)B28 Analogues (13 embodiments).
  • an insulin analogue comprising a first and second glucose-binding element, wherein the first and second glucose-binding element each comprises a boron-containing diol-binding moiety.
  • the insulin analogue comprises any of the known analogues of the native insulin A chain and B chain.
  • an insulin A chain peptide and an insulin B chain peptide are provided, wherein said insulin A chain and B chain peptides are linked to each other by disulfide bonds, further wherein either the insulin A chain peptide comprises the first and second glucose-binding elements covalently linked to one or more N-terminal amino acids located at positions selected from A-i, Ao, and Ai; and the insulin B chain peptide comprises a modified amino acid located at a position selected from B23-B31, said modified amino acid comprising a diol adduct; or the insulin B chain peptide comprises said first and second glucose-binding elements covalently linked to one or more amino acids located at positions selected from B26-B32 (inclusive of a potential two-residue C-terminal extension); and the insulin A chain peptide comprises a modified amino acid located at a position selected from A-i, Ao, and Ai, said modified amino acid comprising a diol adduct.
  • the boron-containing diol-binding moiety of the first and second glucose-binding elements are independently selected from any of the boron- containing diol-binding moieties selected from the group consisting of BCM1- BCM12 as shown in Fig. 7.
  • the insulin analogue comprises a first and second glucose binding elements linked to a first and second amino acid, respectively, of the insulin A chain peptide, wherein the first and second amino acids are located at positions i and i+1 or i and i+2 relative to each other.
  • the first and second glucose-binding elements are bound to each other via a linker to form a complex, wherein the complex is covalently linked to a single amino acid of the insulin A chain peptide.
  • the first and second glucose-binding elements are linked to the side chains of one or more amino acids of the insulin A chain peptide.
  • the first and second glucose-binding elements are linked to the backbone amide nitrogens of one or more amino acids of the insulin A chain peptide.
  • first and second glucose-binding elements are covalently linked to the side chain of an amino acid selected from the group consisting of L-Cys, L-Lys, D-Lys, L-Orn, D-Orn, L-Dab, and D-Dab.
  • the analogues of the present invention may optionally contain an additional saccharide-binding element attached to residue B 1 as a mechanism intended to provide glucose-sensitive binding of the insulin analogue to surface lectins in the subcutaneous depot.
  • the analogues of the present invention may optionally contain substitutions known in the art to confer rapid action (such as Asp B28 , a substitution found in insulin aspart (the active component of Novolog ® ); [Lys B28 , Pro B29 ], pairwise substitutions found in insulin lispro (the active component of Humalog ® ); Glu B29 or the combination [Lys B3 , Glu B29 ] as the latter is found in insulin glulisine (the active component of Apridra ® ), or modifications at position B24 associated with accelerated disassembly of the insulin hexamer (e.g., substitution of Phe B24 by Cyclohexanylalanine or by a derivative of Phenylalanine containing a single substitution
  • the analogues of the present invention may optionally contain modifications known in the art to confer protracted action, such as modification of the e-amino group of Lys B29 by an acyl chain or acyl-glutamic acid adduct as respectively illustrated by insulin detemir (the active component of Levemir ® ) and insulin degludec (the active component of Tresiba ® ); or contain basic amino-acid substitutions or basic chain extensions designed to shift the isoelectric point (pi) to near neutrality as exemplified by the Arg B31 -Arg B32 extension of insulin glargine (the active component of Lantus®).
  • modifications known in the art to confer protracted action such as modification of the e-amino group of Lys B29 by an acyl chain or acyl-glutamic acid adduct as respectively illustrated by insulin detemir (the active component of Levemir ® ) and insulin degludec (the active component of Tresiba ® );
  • Analogues of the present invention designed to exhibit such a shifted pi may also contain a substitution of Asn A21 , such as by Glycine, Alanine or Serine.
  • Analogues of the present invention may optionally also contain non-beta-branched amino-acid substitutions of Thr A8 associated with increased affinity for the insulin receptor and/or increased thermodynamic stability as may be introduced to mitigate deleterious effects of the primary two above design elements (a phenylboronic acid derivative at or near the N-terminus of the A chain and one or more saccharide derivatives at or near the C-terminus of the B chain) on receptor-binding affinity and/or thermodynamic stability.
  • A8 substitutions known in the art are His A8 , Lys A8 , Arg A8 , and Glu A8 .
  • the insulin analogues of the present invention may exhibit an isoelectric point (pi) in the range 4.0-6.0 and thereby be amenable to pharmaceutical formulation in the pH range 6.8-7.8; alternatively, the analogues of the present invention may exhibit an isoelectric point in the range 6.8-7.8 and thereby be amenable to pharmaceutical formulation in the pH range 4.0-4.2.
  • pi isoelectric point
  • the latter conditions are known in the art to lead to isoelectric precipitation of such a pi-shifted insulin analogue in the subcutaneous depot as a mechanism of protracted action.
  • an example of such a pi-shifted insulin analogue is provided by insulin glargine, in which a basic two-residue extension of the B chain (Arg B31 -Arg B32 ) shifts the pi to near-neutrality and thus enables prolonged pharmacokinetic absorption from the subcutaneous depot.
  • the pi of an insulin analogue may be modified through the addition of basic or acidic chain extensions, through the substitution of basic residues by neutral or acidic residues, and through the substitution of acidic residues by neutral or basic residues; in this context we define acidic residues as Aspartic Acid and Glutamic Acid, and we define basic residues as Arginine, Lysine, and under some circumstances, Histidine.
  • absolute in vitro affinities of the insulin analogue for insulin receptor are in the range 5-100% relative to wild-type human insulin and so unlikely to exhibit prolonged residence times in the hormone-receptor complex; such prolonged residence times are believed to be associated with enhanced risk of carcinogenesis in mammals or more rapid growth of cancer cell lines in culture.
  • IGF-1R insulin-like growth factor receptor
  • the insulin analogues of the present invention consist of two polypeptide chains that contain a novel paired PBA-PBA, PBA-BXB, BXB-PBA and/or BXB- BXB modifications in the A chain such that the analogue, in the absence of glucose or other exogenous saccharide, contains covalent bonds the paired boron-containing elements and diol adducts in the B chain.
  • these two design elements form a covalent interaction in the absence of exogenous glucose such that the structure of the hormone is stabilized in a less active conformation.
  • Two alternative design schemes are envisioned that would follow the same principles to provide a glucose-responsive insulin.
  • the first switches the positions of the glucose-binding elements and diol modifications such that the former are attached at or near the C terminus of the B chain whereas the latter are attached at or near the N terminus of the A chain.
  • the second embodiment replaces diol modifications by glucose-binding elements such that both chains are modified by pairs of boron-containing moieties.
  • an insulin analogue formulation would be compatible with multiple devices (such as insulin vials, insulin pens, and insulin pumps) and could be integrated with modifications to the insulin molecule known in the art to confer rapid-, intermediate-, or prolonged insulin action.
  • the present glucose-regulated conformational switch in the insulin molecule engineered between the C-terminus of the B chain and N-terminus of the A chain, could be combined with other glucose-responsive technologies (such as closed- loop systems or glucose- responsive polymers) to optimize their integrated properties.
  • glucose-responsive technologies such as closed- loop systems or glucose- responsive polymers
  • a method of treating a diabetic patient while decreasing the risk of hypoglycemia comprising administering a physiologically effective amount of any of the insulin analogues disclosed herein that comprise a glucose-binding elements, or a physiologically acceptable salt thereof, to the patient.
  • a glucose responsive insulin analogue comprising a first and second glucose-binding element, said first and second glucose binding element each comprising a boron-containing diol-binding moiety; an insulin A chain peptide; an insulin B chain peptide; wherein said insulin A and B chain peptides are linked to each other by disulfide bonds; further wherein either
  • said insulin A chain peptide comprises said first and second glucose binding elements covalently linked to one or more N-terminal amino acids located at positions selected from A-i, Ao, and Ai; and said insulin B chain peptide comprises a modified amino acid located at a position selected from B23-B31, said modified amino acid comprising a diol adduct; or
  • said insulin B chain peptide comprises said first and second glucose binding elements covalently linked to one or more amino acids located at positions selected from B23-B31; and said insulin A chain peptide comprises a modified amino acid located at a position selected from A-i, Ao, and Ai, said modified amino acid comprising a diol adduct.
  • the boron-containing diol-binding moiety of said first and second glucose-binding elements of the insulin analogue are independently selected from the group consisting of BCM1-BCM12 as shown in Fig. 7, optionally wherein the boron-containing diol-binding moiety is phenylboronic acid or benzoboroxole.
  • the first and second glucose-binding elements are covalently linked to a first and second amino acid, respectively, of said insulin A chain peptide, wherein the first and second amino acids are located at positions i and i+1 or i and i+2 relative to each other.
  • first and second glucose-binding elements are bound to each other via a linker to form a complex, wherein the complex is covalently linked to a single amino acid.
  • first and second glucose-binding elements are covalently linked to amino acids located at a position selected from A-i , Ao and Ai and one or more a diol adducts are linked to an amino acid located at a position selected from B 28 or B -9 .
  • first and second glucose binding elements are covalently linked to the side chain or the or backbone amide of the insulin A chain peptide, optionally wherein the first and second glucose-binding elements are covalently linked to the side chain of an amino acid selected from the group consisting of L-Cys, L-Lys, D-Lys, L-Orn, D-Orn, L-Dab and D-Dab.
  • amino acid comprising a diol adduct has the structure of linked to the side chain or backbone amide of the insulin B
  • first and second glucose-binding elements are bound to each other via a linker to form a complex having the general structure wherein BCMi and BCM2 are boron-containing moieties; n and m are independently an integer selected from the range of 1 to 3;
  • R is any amino acid side chain of the L or D configurations of the standard 20 proteogenic amino acids or non-proteogenic amino acids known in the art.
  • R is selected from the group consisting of H, C 1 -C 18 alkyl, C 2 -C 18 alkenyl, (C 1 -C 18 alkyl)OH, (C 1 -C 18 alkyl)SH, (C 2 -C 3 alkyl)SCH 3 , (C 1 -C 4 alkyl)CONH 2 , (C 1 -C 4 alkyl)COOH, (C 1 -C 4 alkyl)NH 2 , (C 1 -C 4 alkyl)NHC(NH 2 + )NH 2 , (C0-C4 alkyl)(C 3 -C 6 cycloalkyl), (C0-C4 alkyl)(C 2 -C 5 heterocyclic), (C0-C4 alkyl)(C 6 - C10 aryl)R7, (C 1 -C 4 alkyl
  • R is H, C 1 -C 6 alkyl, (C 1 -C 4 alkyl)C(0)NH 2 , (C 1 -C 4 alkyl)OH, (C 1 -C 4 alkyl)CH 3 OH, (C 1 -C 4 alkyl)S, (C 1 -C 4 alkyl)SCH 3 , (C 1 -C 4 alkyl)COOH and (C 1 -C 4 alkyl)NH 2 ,
  • GXoGIVEQX 6 CX 8 SIXiiSLYQLENYCX2i (SEQ ID NO: 13); X O GIVEQX 6 CX 8 SIX 11 SLY QLENY CX 21 (SEQ ID NO: 14); GXiIVEQX 6 CX 8 SIXiiSLYQLENYCX2i (SEQ ID NO: 15); or XIIVEQX 6 CX8SIXIISLYQLENYCX 2I (SEQ ID NO: 16), and the insulin B chain peptide comprises a sequence of
  • X 0 and Xi are independently a modified amino acid selected from D-Cys, L-Asp, D-Asp, D-G1U, L-G1U, D-homocys, L-homocys, L-Dap, D-Dap L-Cys, L-Lys, D-Lys, L-Orn, D- Orn, L-Dab, and D-Dab, wherein the modified amino acid comprises the first and second glucose-binding elements linked to the side chain or the backbone amide of the modified amino acid.
  • Xo is a modified L-Cys, L-Lys, D-Lys, L- Orn, D-Orn, L-Dab, and D-Dab, wherein the modified amino acid comprises a glucose- binding elements linked to the side chain of the amino acid.
  • X 6 and X 11 are independently Cys or Selenocysteine;
  • Xx is selected from the group consisting of threonine, lysine, arginine, glutamic acid, and histidine;
  • X 21 is selected from the group consisting of asparagine, serine, glycine and alanine;
  • X 23 is asparagine or lysine;
  • X 25 is selected from the group consisting of histidine and threonine;
  • X 29 is selected from the group consisting of alanine, glycine and serine;
  • X 30 is selected from the group consisting of histidine, aspartic acid, glutamic acid, homocysteic acid and cysteic acid; and
  • R 23 is selected from the group consisting of YTX 28 KT (SEQ ID NO: 18), YTX 28 KP (SEQ ID NO: 19), YTKPT (SEQ ID NO: 20), YTKPTR (
  • the insulin analog comprises an insulin A chain peptide comprising a sequence of GXoGIVEQX 6 CX 8 SIXnSLYQLENYCX 2i (SEQ ID NO: 13);
  • FVX23QHLCGSHLVEALYLVCGERGFFYTX28KP (SEQ ID NO: 26), wherein X 0 and Xi are independently a modified amino acid selected from L-Cys, L-Lys, D-Lys, L- Orn, D-Orn, L-Dab, and D-Dab, wherein the modified amino acid comprises said first and second glucose-binding elements linked to the side chain or the or backbone amide of the modified amino acid; X 6 and X 11 are independently Cys or Selenocysteine; Cc is selected from the group consisting of threonine, lysine, arginine, glutamic acid, and histidine; X 21 is selected from the group consisting of asparagine, serine, glycine and alanine; X 23 is asparagine or lysine; and X 28 is proline, aspartic acid or glutamic acid, and wherein the side chain or backbone amide of an
  • the glucose sensing insulin analog comprises an insulin A chain peptide comprising a sequence of GIVEQCCX8SICSLYQLENYCX21 (SEQ ID NO: 27); and said B chain comprises the sequence the sequence FVKQX 25 LCGSHLVEALYLVCGERGFFYTEKT (SEQ ID NO: 28), FVNQX 25 LCGSHLVEALYLVCGERGFFYTDKT (SEQ ID NO: 29), FVNQX 25 LCGSHLVEALYLVCGERGFFYTKPT (SEQ ID NO: 30), FVN QHLCGSHL VEALYL V CGERGFFYTKKP (SEQ ID NO: 31) or
  • FVNQX 25 LCGSHLVEALYLVCGERGFFYTPKT (SEQ ID NO: 32) wherein X 8 is selected from the group consisting of threonine and histidine; X 21 is selected from the group consisting of asparagine, glycine and alanine; X 25 is selected from the group consisting of histidine and threonine, and a lysine at position 28 or 29 of said B chain has been modified to comprise a diol adduct.
  • any of the glucose-sensing insulin analogues disclosed herein can be provided with two or more glucose-binding moieties that comprise the same boron-containing diol-binding motif.
  • the boron-containing diol-binding moiety is phenylboronic acid, a halogen-modified fluorophenylboronic acid or benzoboroxole.
  • the glucose-binding elements of the present invention contain two or more boron atoms, and so this encompasses pairs, triplets or high-order combinations of single boron-containing moieties (such as PBA and Bxb); these can be respectively attached to different amino acids selected from positions A-i, Ao and/or Ai; or they can be moieties within a single complex adduct attached to only one of these peptide sites (see Fig. 11 A, right).
  • PBA and Bxb single boron-containing moieties
  • glucose-responsive insulin analogues of the present invention were prepared for functional testing in mammalian cell culture in the context of insulin lispro such that the epsilon-amino group of LysB28 was modified by 2, 3-dihydroxybenzoic acid (DHBA), thereby providing a diol at or near the C terminus of the B chain.
  • the A chain was modified by a D-Cysteine at position A1 by a symmetrical pair of benzoboroxole moieties as known in the art to bind diols, including glucose and less favorably fructose.
  • the glucose-dependence and fructose- dependence of biological activity were measured in human liver-derived HepG2 cells in culture.
  • the parent analogue insulin lispro exhibited no changes in biological activity on addition of either monosaccharide (Fig. 17)
  • the insulin analogues of the present invention exhibited the targeted glucose dependence (in upper panels found in Figs. 19-21) and to a less marked degree, fructose dependence (in lower panels found in Figs. 19-21).
  • the range of effective glucose concentration was in accordance with therapeutic goals for the treatment of diabetes mellitus (Fig. 21).
  • Levemir contains four times the hormone concentration in molar units as other clinical insulin products, but is nonetheless labeled as “U-100” in strength. This is because the per molecule activity of insulin detemir (the active component of Levemir) is fourfold reduced relative to human insulin. By the same token, the per-molecule activity of the present insulin analogues are typically reduced by the A-chain modifications or by the B-chain modifications. U-100 strength can nonetheless be achieved by increasing the analogue’s protein concentration by analogy to Levemir.
  • GRI- 1 highlighted its Levemir like reduction in per-molecule potency, whose precise value was observed to depend on the blood-glucose concentration.
  • experimental design exploited prior baseline studies of intrinsic potency to equalize activities rather than to equalize molar concentrations (see Figs. 24A-24C).
  • Control studies of “partial analogues” i.e., containing only an A-chain-linked GBE or only a B -chain- linked diol moiety
  • the closed-open transition of the present GRI analogues was further validated by cryo-EM single-particle image reconstruction employing the isolated ectodomain of the human insulin receptor. Complexes were made either in the absence of glucose or in the presence of 50 mM glucose. Whereas addition of glucose led to an ectodomain-hormone structure essentially identical to that of the wild-type complex in its signaling conformation (Weis, F., et al. The signalling conformation of the insulin receptor ectodomain. Nature Communications 9(1), 4420 (2018)), in the absence of glucose the structure was of lower resolution and without binding of the insulin analogue to “Site 1” of the receptor; the overall ectodomain conformation was not in the active, signaling state. Thus, the predicted mechanism underlying the present class of GRI analogues was explicitly visualized in these studies.
  • GRI-2 Another, related prototype GRI (designated GRI- 2) was prepared that differed from GRI-1 in one respect: the same dual-boron-containing GBE (GBE1-C) was attached to L-CysAo; the diol-modified Lysine at B28 was retained. GRI-5 was tested in HepG2 cells in culture (as described in Chen, Y.-S., et al. (2021) and observed to exhibit glucose-dependent activity.
  • GBE1-C dual-boron-containing GBE
  • L-CysAo the diol-modified Lysine at B28 was retained.
  • GRI-5 was tested in HepG2 cells in culture (as described in Chen, Y.-S., et al. (2021) and observed to exhibit glucose-dependent activity.
  • GRI-3 Yet another related prototype GRI (designated GRI-3) was prepared that differed from GRI-1 in only by substitution of cystine A6-A11 by a diselenide bridge (SecA6 and SecAll). This modification stabilizes insulin as described by Weil- Ktorza, O., et al. (Substitution of an Internal Disulfide Bridge with a Diselenide Enhances both Foldability and Stability of Human Insulin. Chemistry: a European Journal 25(36), 8513-21 (2019)). GRI-3 was tested in HepG2 cells in culture (as described in Chen, Y.-S., et al. (2021) and observed to exhibit glucose-dependent activity.
  • GRI-4 Yet another related prototype GRI (designated GRI-4) was prepared that differed from GRI-2 in only by substitution of cystine A6-A11 by a diselenide bridge (SecA6 and SecAll). This modification stabilizes insulin as described by Weil- Ktorza, O., et al. (Substitution of an Internal Disulfide Bridge with a Diselenide Enhances both Foldability and Stability of Human Insulin. Chemistry: a European Journal 25(36), 8513-21 (2019)). GRI-4 was tested in HepG2 cells in culture (as described in Chen, Y.-S., et al. (2021) and observed to exhibit glucose-dependent activity.
  • GRI-5 A related prototype GRI (designated GRI-5) was prepared that differed from GRI-1 in two respects: (i) the aromatic diol moiety (DHBA) was attached to an Ornithine side chain at position B28, as substituted for LysB28 in insulin lispw, and (ii) the same dual-boron-containing moiety (GBE1-C) was attached to L-CysAo instead of D-CysAl as in GRI-1. GRI-5 was tested in STZ rats and in normal rats as an initial screen for glucose-dependent biological activity. Its functional properties in these animal models were similar to those of GRI-1.
  • DHBA aromatic diol moiety
  • GOE1-C dual-boron-containing moiety
  • a fructose-responsive insulin was prepared to demonstrate proof of principle as described in Chen, Y.-S., et al. (2021) and incorporated by reference herein. This provided a model for Examples 1-5 above.
  • a switchable insulin analogue designated FRI; fructose-responsive insulin
  • FRI fluoro-PBA*
  • DHBA aromatic diol (3,4-dihydroxybenzoic acid
  • fructose and glucose each contain diols
  • the sensor preferentially binds to aligned 1,2-diol groups as found in ⁇ -D-fructofuranose and ⁇ -D-glucofuranose.
  • Affinity of meta-fPBA is higher for fructose than glucose due to salient differences in respective conformational; binding is covalent but reversible.
  • Thr A8 was substituted by His a favorable substitution found in avian insulins.
  • Control analogues were provided by 1) insulin KP, 2) a KP derivative containing an A1-linked meta- fPBA but not the B28 diol (diol-free control; DFC), and 3) a peptide bond between Lys B28 and Gly A1 in a des-[B29, B30] (“DOI”) template.
  • DFC diol-free control
  • DOI des-[B29, B30]
  • WBs demonstrated fructose-dependent signaling by FRI and fructose-independent signaling by KP and DFC.
  • the activity of FRI in the absence of fructose is low.
  • Plate Assays Demonstrated Ligand-Selective Signaling. Quantitative dose- dependent and ligand-selective IR autophosphorylation were evaluated in a 96-well plate assay. FRI triggered a robust signal on addition of 50 mM fructose whereas baseline activity in the absence of fructose was low. As expected, KP and DFC exhibited high signaling activity in the presence or absence of fructose, respectively).
  • Ligand-dependent activation of FRI is specific to fructose as addition of 50 mM glucose did not influence its activity (nor the activities of KP and DFC). These data indicate that in 50 mM fructose FRI is almost as active as KP.
  • PCR Assays Demonstrated Ligand-Selective Metabolic Gene Regulation. Insulin-signaling in hepatocytes extends to metabolic transcriptional regulation as recapitulated in HepG2 cells. At hypoglycemic conditions, the cells exhibited stronger gluconeogenesis-related responses following insulin stimulation than at hyperglycemic conditions.
  • FRI when activated by fructose, regulated downstream expression of the gene encoding phosphoenolpyruvate carboxykinase (PEPCK; a marker for hormonal control of gluconeogenesis).
  • PEPCK phosphoenolpyruvate carboxykinase
  • FRI when activated by fructose, regulated the genes encoding carbohydrate-response–element and sterol response–element binding proteins (ChREBP and SREBP; markers for hormonal control of lipid biosynthesis).
  • ChREBP and SREBP markers for hormonal control of lipid biosynthesis
  • High-resolution NMR spectroscopy [as enabled by the monomeric KP template] corroborate essential elements of the intended fructose-selective switch 1 9 F-NMR spectra monitored fructose sensor.
  • the fluorine atom in meta-fPBA provided an NMR-active nucleus.
  • Addition of 0 to 100 mM fructose led to an upfield change in 19F-NMR chemical shift in slow exchange on the NMR time scale. This upfield shift presumably reflects displacement of an aromatic diol by a nonaromatic ligand.
  • No change in FRI 19 F chemical shift was observed on addition of glucose.
  • an analogous 19 F resonance was observed in the NMR spectrum of DFC, its chemical shift did not change on addition of glucose or fructose.
  • 1 H- 13 C HSQC spectra provide probes of aromatic resonances in FRI’s DHBA/meta- fPBA adducts in the absence of fructose and in the presence of 100 mM fructose. Significant chemical shift changes in both 1 H/ 13 C dimensions were observed. Resonance assignments were corroborated by model studies of meta-fPBA– and DHBA-modified peptides. DHBA chemical shifts in fructose-free FRI are similar to those in the complex of model peptides, whereas such chemical shifts in fructose bound FRI are similar to that of free DHBA-modified octapeptide.
  • methyl resonances sensitive to addition of fructose exhibited a trend toward corresponding chemical shifts observed in spectra of insulin lispro and ligand-free DFC.
  • these NMR features provide evidence that in FRI the Lys B28 -attached DHBA binds Gly A1 -linked meta-fPBA in absence of fructose, but this tether is displaceable by fructose.
  • Methyl 1 H- 13 C 2D HSQC spectra monitor protein core. Aliphatic 1 H- 13 C spectra reflect tertiary structure as probed by upfield-shifted methyl resonances.
  • the peptides were synthesized starting with Pre-loaded Fmoc-Asn(Trt)-HMBA-CM resins using traditional Fmoc/tBu chemistry with repetitive DIC/6-Cl-HOBt activation / coupling cycles using DIC/6-Cl-HOBt activation (10 Equivalents) and IR or induction heating at 60°C for 10 min per cycle and 50°C for Fmoc deprotection (20% piperidine / DMF, 2 x 5min). Tribute or Chorus automated peptide synthesizers (Gyros Protein Technology, Arlington, AZ) were used.
  • SCIs were chemically synthesized using Fmoc/OtBu solid-phase chemistry on a Pre-loaded H-Asn(Trt)-HMBP-Chemmatrix resin, with repetitive coupling cycles using DIC/6-Cl-HOBt or DIC/ Oxyma Pure (Ethyl cyano(hydroxyimino)acetate) activation (10 Equivalents) and IR or induction heating at 60°C for 10 min per cycle and 50°C for Fmoc deprotection (20% piperidine / DMF, 2 x 5min). Tribute or Chorus automated peptide synthesizers (Gyros Protein Technology, Arlington, AZ) were used.
  • Pre-loaded Fmoc-Asn(Trt)-Chemmatrix resin was used. All amino acids, DIC and 6-Cl-HOBt and Oxyma Pure were purchased from Gyros Protein Technology (Tucson, AZ).
  • the peptide was cleaved and deprotected by treatment with trifluoroacetic acid (TFA) containing 2.5% triisopropylsilane (TIS), 2.5% water, 2.5% DODT (ethylenedioxy)-diethenethiol), and 2.5% of anisole.
  • TTA trifluoroacetic acid
  • TIS triisopropylsilane
  • DODT ethylenedioxy)-diethenethiol
  • anisole ethylenedioxy-diethenethiol
  • Preparative HPLC was carried out using a C8 column was used for purification. Crude reaction was acidified (HCl, 5M to pH 3) filtered (0.2 ⁇ M) and then purified identity of the SCI was confirmed by LC-MS (Finnigan LCQ Advantage, Thermo) on a TARGA C8 (4.6 ⁇ 250 mm, 5 ⁇ m, Higgins Analytical) with 0.1% TFA/H 2 O (A) and 0.1% TFA/CH 3 CN as eluents.
  • LC-MS Fenigan LCQ Advantage, Thermo
  • the dried single-chain DesDI precursor was treated with Trypsin-TPCK (10% w/w) in 1 M urea and 0.1 M ammonium bicarbonate for 24 h at room temperature. After completion of the cleavage as indicated by HPLC, the DOI was purified by preparative RP-HPLC on a C4 or C8 (20 ⁇ 250 mm, 5 ⁇ m, Higgins Analytical) column with 0.1% TFA/H 2 O (A) and 0.1% TFA/CH3CN (B) as elution buffers.
  • a 1:5 molecular ratio was used for trypsin-mediated ligation, typically 3-9 mg of DOI were dissolved along with similar 3-9 mg of octapeptide in 200 ⁇ l of a mixed solvent system containing Tris-acetate (pH 8.5), 1,4-butanediol and dimethylacetamide. pH was adjusted to 7.5 with 2 ⁇ l of 4-Methylmorpholine and the reaction was carried out for 24-48 h. Full-length insulin product proteins was purified by preparative RP- HPLC on a C8 column with 0.1% TFA/H 2 O (A) and 0.1% TFA/CH 3 CN (B) as elution buffers. Identity was confirmed by LC-MS.
  • the DOI precursor and resultant GRI candidate compounds are given in the SEQ ID section.
  • reaction mixtures were purified by RP-HPLC as described above.
  • the general disulfide conjugation method is as follows: GBE-1-C(NPYS)-OH, 1.5 equivalents were reacted with an SCI containing a free thiol group (2-4 mg/ml).
  • the reaction are performed in a buffer consisting of ammonium bicarbonate (0.1 M), urea (1M) at pH 8.5 and at room temperature for 15-60 min.
  • the reaction mixture was re-purified by RP-HPLC. Cell culture.
  • Human hepatocellular carcinoma cell line HepG2 was cultured in Dulbecco's Modified Eagle Medium (DMEM), supplemented with 10% fetal bovine serum (FBS), 1% penicillin/streptomycin as recommended by the American Type Culture Collection. A protocol employing 24-h serum starvation wherein FBS was applied at 70-75% confluence. After starvation, cells were treated in parallel with a set of insulin analogues in serum-free medium. Real-time qPCR assays. Following serum starvation, HepG2 cells were treated with medium containing an insulin analogue (50 nM) for 8 h.
  • DMEM Dulbecco's Modified Eagle Medium
  • FBS fetal bovine serum
  • PBS penicillin/streptomycin
  • mRNA messenger ribonucleic acid abundances were measured in triplicate by quantitative polymerase chain reaction (qPCR). Samples were prepared as described by the vendor (One-Step rt-PCR reagent kits; Bio-Rad).
  • primers were used: (PEPCK), GTTCAATGCCAGGTTCCCAG (SEQ ID NO: 33) and TTGCAGGCCAGTTGTTGAC (SEQ ID NO: 34); (ChREBP), AGAGACAAGATCCGCCTGAA (SEQ ID NO: 35) and CTTCCAGTAGTTCCCTCCA (SEQ ID NO: 36); (SREBP), CGACATCGAAGACATGCTTCAG (SEQ ID NO: 37) and GGAAGGCTTCAAGAGAGGAGC (SEQ ID NO: 38); and (GAPDH), ATGGTTTACATGTTCCAATAT (SEQ ID NO: 39) and ATGAGGTCCACCACCCTGGTTG (SEQ ID NO: 40). In-cell pIR immunoblotting.
  • This cell-based assay probed insulin-dependent IR activation via fluorescent readouts.
  • HepG2 cells were seeded ( ⁇ 8000 cells/well) into a 96-well black plate with clear bottom and cultured (Fisher). After serum starvation in 100- ⁇ l plain Hanks' Balanced Salt Solution (HBSS) for 2 h at 37 °C, serial analogue dilutions (100 ⁇ l) were applied to each well; cells were then incubated for 20 min at 37 °C.
  • HBSS Hanks' Balanced Salt Solution
  • pTyr was detected via 800 nm emission.
  • DRAQ5 (Fisher) was also applied to enable measurement of cell number via 700 nm emission.
  • the fluorescence signals were detected on a LI-COR Infrared Imaging system (Odyssey) under settings as follows: offset 4 mm with setting “Intensity- Auto.” Signaling assays in a mammalian cell line. HepG2 cell line (ATCC) were cultured in DMEM with 10% FBS, 1% penicillin/streptomycin per vendor’s instruction.
  • samples were probed by insulin receptor ⁇ (4B8) antibody (CST antibodies unless otherwise stated) or an equal mixture of anti- phospho-insulin receptor ⁇ (Tyr1150/1151); phospho-insulin receptor (Tyr1158) antibody (Thermo); phospho-insulin receptor (Tyr1334) antibody (Thermo); phospho- insulin receptor ⁇ (Tyr1345) monoclonal antiserum; and anti-phospho-insulin receptor (phospho-Tyr972) antibody (Abcam). Dilutions for these antibodies were 1:5000 in 5% bovine serum albumin.
  • Antibodies for AKT blotting were p-AKT antibody (Ser473) (1:400) and AKT1/2/3 antiserum (H-136) (1:1000).
  • p-AKT antibody Ser473
  • AKT1/2/3 antiserum H-136
  • samples were probed by phospho-FoxO1 (Thr24)/FoxO3a (Thr32) antibody, FOXO1 antibody, phospho-GSK-3 ⁇ / ⁇ (Ser21/9), and GSK-3 ⁇ / ⁇ antibody (purchased from CST; dilution 1:1000).
  • GBE-1 is defined in Fig.10A-10B; GBE-2, GBE-3, GBE-4 are defined in Fig.11A-11C.
  • SEQ ID NO: 1 human proinsulin
  • NAMES AND SEQUENCES are summarized in Table 1 as follows. GRI-1, 2, 3, 4 and 5 are labeled in appropriate rows. "Single-chain sequences" and des- octapeptide[B23-B30]-insulin analogue fragments ("DOF's) pertain to synthetic intermediates and not to GRIs of the present invention. TABLE 1
  • the present disclosure relates to polypeptide hormone analogues that contain a glucose-regulated molecular structure or glucose-detachable molecular moiety, designed respectively either (a) to confer glucose-responsive binding to cognate cellular receptors and/or (b) to enable glucose-mediated liberation of an active insulin analogue. More particularly, the present disclosure is directed to insulin analogues that are responsive to blood-glucose concentrations and their use in the treatment of patients and non-human mammals with Type 1 or Type 2 diabetes mellitus by subcutaneous, intraperitoneal or intravenous injection of the insulin analogues disclosed herein.
  • the insulin analogues of the present invention may also exhibit other enhanced pharmaceutical properties, such as increased thermodynamic stability, augmented resistance to thermal fibrillation above room temperature, decreased mitogenicity, and/or altered pharmacokinetic and pharmacodynamic properties. More particularly, this disclosure relates to insulin analogues that may confer either rapid action (relative to wild-type insulin in its regular soluble formulation), intermediate action (comparable to NPH insulin formulations known in the art) or protracted action (comparable to basal insulins known in the art as exemplified by insulin detemir and insulin glargine) such that the affinity of the said analogues for the insulin receptor is higher when dissolved in a solution containing glucose at a concentration above the physiological range (> 140 mg/dL; hyperglycemia) than when dissolved in a solution containing glucose at a concentration below the physiological range ( ⁇ 80 mg/dL; hypoglycemia).
  • an insulin analogue comprising an A chain modified by a glucose-binding element at or near its N terminus and a variant B chain comprising a diol group at the C terminus of the B chain such that the polypeptide chain ends with a hydroxyl group rather than with a carboxylate group.
  • Reduced or absent activity is associated with formation of a cova e t bo d betwee t e u que d o o ety t e c a a d a seco d o ecu a entity located at the N-terminus of the A chain and that contains a glucose-binding element.
  • the modified B chain may contain a broad molecular diversity of diol-containing moieties (or adducts containing an ⁇ - hydroxycarboxylate group as an alternative binding motif that might bind to a glucose-binding element), whether a saccharide or a non-saccharide reagent.
  • Possibilities include an N-linked or O-linked saccharide or any organic moiety of similar molecular mass that contains a diol function that mimics the diol function of a monosaccharide and hence confers reversible PBA-binding activity (or adducts containing an ⁇ -hydroxycarboxylate group as an alternative PBA-binding function; PBA in the present invention may equivalently be substituted by other boron- containing diol-binding elements as known in the art to bind glucose).
  • non- saccharide diol-containing organic compounds span a broad range of chemical classes, including acids, alcohols, thiol reagents containing aromatic and non-aromatic scaffolds; adducts containing an ⁇ -hydroxycarboxylate group may provide an alternative function able to bind PBA or other boron-containing diol-binding elements able to bind glucose.
  • Convenient modes of attachment to the B chain also span a broad range of linkages in addition to the above N-linked and O-linked saccharide derivatives described above; these additional modes of attachment include (i) the side- chain amino function of Lysine, ornithine, diamino-butyric acid, diaminopropionic acid (with main-chain chirality L or D ) and (ii) the side-chain thiol function of Cysteine or homocysteine (with main-chain chirality L or D).
  • a preferred embodiment at sites of native aromatic acids is provided by L-Dopa.
  • the molecular purpose of the diol-modified B chain is to form an intramolecular bond or bonds with the A-chain-attached glucose-binding element such that the conformation of insulin is “closed” and so impaired in binding to the insulin receptor.
  • Use of a main-chain-directed diol recapitulates the inactive structure of a single-chain insulin analogue. We envision that at high glucose concentrations, the diol-glucose -binding element bond or bonds will be broken due to competitive binding of the glucose to the glucose-binding element.
  • Preferred embodiments contain two or more diol groups in an effort to introduce cooperativity.
  • the main-chain element can be via substitution of the C-terminal carboxylate by a hydroxyl group together with an appropriately positioned side-chain hydroxyl group and/or via a moiety attached to the main-chain nitrogen atom.
  • the analogues of the present invention may optionally contain an additional saccharide-binding element attached to residue B1 as a mechanism intended to provide glucose-sensitive binding of the insulin analogue to surface lectins in the subcutaneous depot.
  • analogues of the present invention may optionally contain substitutions known in the art to confer rapid action (such as Asp B28 , a substitution found in insulin aspart (the active component of Novolog®); [Lys B28 , Pro B29 ], pairwise substitutions found in insulin lispro (the active component of Humalog®); Glu B29 or the combination [Lys B3 , Glu B29 ] as the latter is found in insulin glulisine (the active component of Apridra®), or modifications at position B24 associated with accelerated disassembly of the insulin hexamer (e.g., substitution of Phe B24 by Cyclohexanylalanine or by a derivative of Phenylalanine containing a single halogen substitution within the aromatic ring).
  • substitutions known in the art to confer rapid action such as Asp B28 , a substitution found in insulin aspart (the active component of Novolog®); [Lys B28 , Pro B29 ], pairwise substitutions found
  • the analogues of the present invention may optionally contain modifications known in the art to confer protracted action, such as modification of the e-amino group of Lys B29 by an acyl chain or acyl-glutamic acid adduct as respectively illustrated by insulin detemir (the active component of Levemir®) and insulin degludec (the active component of Tresiba®); or contain basic amino-acid substitutions or basic chain extensions designed to shift the isoelectric point (pi) to near neutrality as exemplified by the Arg B31 -Arg B32 extension of insulin glargine (the active component of Lantus®).
  • modifications known in the art to confer protracted action such as modification of the e-amino group of Lys B29 by an acyl chain or acyl-glutamic acid adduct as respectively illustrated by insulin detemir (the active component of Levemir®) and insulin degludec (the active component of Tresiba®); or contain basic amino-acid substitution
  • Analogues of the present invention designed to exhibit such a shifted pi may also contain a substitution of Asn A21 , such as by Glycine, Alanine or Serine.
  • Analogues of the present invention may optionally also contain non-beta-branched amino-acid substitutions of Thr A8 associated with increased affinity for the insulin receptor and/or increased thermodynamic stability as may be introduced to mitigate deleterious effects of the primary two above design elements (a phenylboronic acid derivative at or near the N-terminus of the A chain and one or more saccharide derivatives at or near the C-terminus of the B chain) on receptor-binding affinity and/or thermodynamic stability.
  • A8 substitutions known in the art are His A8 , Lys A8 , Arg A8 , and Glu A8 .
  • the insulin analogues of the present invention may exhibit an isoelectric point (pi) in the range 4.0-6.0 and thereby be amenable to pharmaceutical formulation in the pH range 6.8-7.8; alternatively, the analogues of the present invention may exhibit an isoelectric point in the range 6.8-7.8 and thereby be amenable to pharmaceutical formulation in the pH range 4.0-4.2.
  • pi isoelectric point
  • the latter conditions are known in the art to lead to isoelectric precipitation of such a pi-shifted insulin analogue in the subcutaneous depot as a mechanism of protracted action.
  • an example of such a pi-shifted insulin analogue is provided by insulin glargine, in which a basic two-residue extension of the B chain (Arg B31 -Arg B32 ) shifts the pi to near-neutrality and thus enables prolonged pharmacokinetic absorption from the subcutaneous depot.
  • the pi of an insulin analogue may be modified through the addition of basic or acidic chain extensions, through the substitution of basic residues by neutral or acidic residues, and through the substitution of acidic residues by neutral or basic residues; in this context we define acidic residues as Aspartic Acid and Glutamic Acid, and we define basic residues as Arginine, Lysine, and under some circumstances, Histidine.
  • absolute in vitro affinities of the insulin analogue for insulin receptor are in the range 5-100% relative to wild-type human insulin and so unlikely to exhibit prolonged residence times in the hormone-receptor complex; such prolonged residence times are believed to be associated with enhanced risk of carcinogenesis in mammals or more rapid growth of cancer cell lines in culture.
  • IGF-1R insulin-like growth factor receptor
  • the insulin analogues of the present invention consist of two polypeptide chains that contain a novel modifications in the B chain such that the analogue, in the absence of glucose or other exogenous saccharide, contains covalent bonds between the side-chain diol in the B chain and a molecular entity containing PBA, a halogen- derivative of PBA, or any boron-containing diol-binding element able to bind glucose.
  • the latter entity may be a C-terminal extension of the B chain or be a separate molecule prior to formation of the diol-PBA bonds.
  • Table 2 presents diol- or a-hydroxycarboxylate-containing precursors.
  • an insulin analogue comprising an A chain modified by a glucose-binding element at or near its N terminus and a variant B chain comprising a diol group at the C terminus of the B chain such that the polypeptide chain ends with a hydroxyl group rather than with a carboxylate group.
  • an insulin analogue of first embodiment 1 wherein the A chain contains a substitution at position A8 that enhances affinity of the insulin analogue for the insulin receptor, optionally wherein the substitution at position A8 is histidine.
  • an insulin analogue of first embodiment 1 or 2 wherein the A chain contains a substitution at position A8 or position A14 that enhances thermodynamic stability of the insulin analogue for the insulin receptor, optionally wherein the substitution at position A8 or A14 is independently selected from the group consisting of His A8 , Lys A8 , Arg A8 , and Glu A8 .
  • an insulin analogue of any one of first embodiments 1-3 wherein the A chain contains a substitution at position A21 that protects the insulin analogue from chemical degradation.
  • an insulin analogue of any one of first embodiments 1-4 is provided wherein said diol group at the C terminus of the B chain is an aliphatic (1, 2) diol.
  • an insulin analogue of any one of first embodiments 1-5 is provided wherein said diol group at the C terminus of the B chain is an aliphatic (1, 3) diol.
  • an insulin analogue of any one of first embodiments 1-6 is provided further comprising a modified amino acid at a position 1, 2, 3, or 4 residues N-terminal to the C-terminal amino acid, wherein said modified amino acid is an L or D amino acid comprising a side-chain diol.
  • an insulin analogue of any one of first embodiments 1-7 is provided wherein the modified amino acid is thiol-containing L or D amino acid.
  • an insulin analogue of any one of first embodiments 1-8 is provided further comprising an L Dopa at position B26 or an L or D Dopa located at 1-3 residues N-terminal to the C-terminal amino acid.
  • an insulin analogue of any one of first embodiments 1-9 wherein said B chain is a truncated B chain lacking residue B30, residues B29-B30, residues B28-B30, residues B27-B30 or residues B26-B30, with a diol group located at the C terminus of the truncated B chain.
  • an insulin analogue of any one of first embodiments 1-9 is provided wherein said B chain is extended by one or two amino acids with a diol group located at the C terminus of the extended B chain.
  • an insulin analogue of any one of first embodiments 1-9 wherein the B chain is a polypeptide selected from the group consisting of FVKQHLCGSHLVEALYLVCGERGFFYTEKX30 (SEQ ID NO: 62), FVNQHLCGSHLVEALYLVCGERGFFYTDKX 30 (SEQ ID NO: 63), FVNQHLCGSHLVEALYLVCGERGFFYTKPX30 (SEQ ID NO: 64), FVNQHLCGSHLVEALYLVCGERGFFYTPKX 30 (SEQ ID NO: 65) FVNQHLCGSHLVEALYLVCGERGFFYTKX30 (SEQ ID NO: 66); FVNQHLCGSHLVEALYLVCGERGFFYTPX 29 X 30 (SEQ ID NO: 67); FVNQHLCGSHLVEALYLVCGERGFFYTPX30 (SEQ ID NO: 68) FVNQHLCG
  • an insulin analogue of any one of first embodiments 1-9 wherein the B chain is a polypeptide selected from the group consisting of FVNQHLCGSHLVEALYLVCGERGFF[Sar][APD] (SEQ ID NO: 72), FVNQHLCGSHLVEALYLVCGERGFF[dA][APD] (SEQ ID NO: 73), and FVNQHLCGSHLVEALYLVCGERGFFYG[APD] (SEQ ID NO: 74).
  • an insulin analogue of any one of first embodiments 1-9 is provided wherein the B chain is a polypeptide selected from the group consisting of
  • FVNQHLCGSHLVEALYLVCGERGFFYTDKX31X30 (SEQ ID NO: 75)
  • FVNQHLCGSHLVEALYLVCGERGFFYTKPX31X30 (SEQ ID NO: 76)
  • FVNQHLCGSHLVEALYLVCGERGFFYTPKX31X30 (SEQ ID NO: 77), FVNQHLCGSHLVEALYLVCGERGFFYTDKX31X32X30 (SEQ ID NO: 78), FVNQHLCGSHLVEALYLVCGERGFFYTKPX3 1X32X30 (SEQ ID NO: 79) and FVNQHLCGSHLVEALYLVCGERGFFYTPKX31X32X30 (SEQ ID NO: 80), wherein
  • X 31 and X 32 are independently any amino acid
  • X 30 is a diol bearing amino acid derivative, optionally threoninol.
  • an insulin analogue of any one of first embodiments 1-14 wherein the A chain is a polypeptide selected from the group consisting of
  • a method of preparing an analogue of any one of First embodiments 1-15 is provided by means of trypsin- mediated semi synthesis wherein (a) any optional A-chain modification (i.e., by a monomeric glucose-binding moiety) is introduced within a i/c.v-octapeptide
  • any optional A-chain modification i.e., by a monomeric glucose-binding moiety
  • the diol-containing B-chain modification is introduced within a synthetic peptide of length 5-10 amino-acid residues whose N- terminal residue is Glycine and which upon modification contains no tryptic cleavage site.
  • first embodiment 17 the method of first embodiment 16 is provided wherein the i/c.v-octapeptide
  • the method of first embodiment 16 is provided wherein the des-octapeptide[B23-B30] fragment of insulin or insulin analogue is obtained by trypsin digestion of a single-chain polypeptide (such as proinsulin, a proinsulin analogue or a corresponding mini-proinsulin containing a foreshortened or absent C domain) as expressed in Escherichia coli, Saccharomyces cerevisiae, Pichia pastoris or other microbial system for the recombinant expression of proteins.
  • a single-chain polypeptide such as proinsulin, a proinsulin analogue or a corresponding mini-proinsulin containing a foreshortened or absent C domain
  • the method of first embodiment 16 is provided wherein the des-octapeptide[B23-B30] fragment of insulin or insulin analogue is obtained by trypsin digestion of single-chain polypeptide (such as proinsulin, a proinsulin analogue or a corresponding mini-proinsulin containing a foreshortened or absent C domain) as prepared by solid-phase chemical peptide synthesis, optionally including native fragment-ligation steps.
  • single-chain polypeptide such as proinsulin, a proinsulin analogue or a corresponding mini-proinsulin containing a foreshortened or absent C domain
  • a method of treating a diabetic patient is provided wherein the patient is administered a physiologically effective amount of an insulin analogue of any one of first embodiments 1-15, or a physiologically acceptable salt thereof via any standard route of administration.
  • an insulin analogue comprising an insulin A chain and an insulin B chain
  • said insulin A chain comprises a D-amino acid at position A 1 or A 0 and a glucose-binding element covalently linked at or near the insulin A chain N terminus, optionally at position A 1 or A 0 ; and said insulin B chain comprising a diol group at or near the C terminus of the insulin B chain.
  • an insulin analogue of second embodiment 1 is provided wherein said glucose-binding element is covalently linked to the side chain of an amino acid in the D- configuration.
  • an insulin analogue of second embodiment 1 or 2 is provided further comprising an amino acid added to the N- terminus of the insulin A chain, wherein said N-terminal amino acid is located at position A0 or A-1.
  • an insulin analogue of any one of second embodiments 1-3 is provided wherein said N-terminal amino acid is glycine.
  • second embodiments 1-4 is provided wherein said diol group is linked to the side chain of one of the three most C-terminal amino acids of the insulin B chain, optionally at any of positions B26, B27, B30 or B31, B32 or B33 of a C-terminally extended B chain, optionally at B28, B29 or B30, optionally at B28.
  • an insulin analogue of any one of second embodiments 1-5 wherein said diol group is a main chain diol, having the -COOH group of the C-terminal amino acid replaced with -CH 2 OH and a side chain bearing an hydroxyl group.
  • an insulin analogue of any one of second embodiments 1-6 is provided wherein the A chain contains a substitution at position A8 that enhances affinity of the insulin analogue for the insulin receptor, optionally wherein the substitution at position A8 is histidine.
  • an insulin analogue of any one of second embodiments 1-7 wherein the A chain contains a substitution at position A8 or position A14 that enhances thermodynamic stability of the insulin analogue for the insulin receptor, optionally wherein the substitution at position A8 or A14 is independently selected from the group consisting of His, Lys, Arg, and Glu.
  • an insulin analogue of any one of second embodiments 1-6 is provided wherein the A chain contains a substitution at position A21 that protects the insulin analogue from chemical degradation.
  • an insulin analogue of any one of second embodiments 1-9 is provided wherein said diol group at the C terminus of the B chain is an aliphatic (1, 2) diol.
  • an insulin analogue of any one of second embodiments 1-10 wherein said diol group at the C terminus of the B chain is an aliphatic (1, 3) diol.
  • an insulin analogue of any one of second embodiments 1-11 is provided further comprising a modified amino acid at a position 1, 2, 3, or 4 residues N-terminal to the C-terminal amino acid of the B chain, wherein said modified amino acid is an L or D amino acid comprising a side-chain diol.
  • an insulin analogue of any one of second embodiments 1-13 is provided further comprising an L Dopa at position B26 or an L or D Dopa located at 1-3 residues N-terminal to the C-terminal amino acid of the B chain.
  • an insulin analogue of any one of second embodiments 1-14 wherein said B chain is a truncated B chain lacking residue B30, residues B29-B30, residues B28-B30, residues B27-B30 or residues B26-B30, with a diol group located at the C terminus of the truncated B chain.
  • an insulin analogue of any one of second embodiments 1-15 is provided wherein said B chain is extended by one or two amino acids with a diol group located at the C terminus of the extended B chain.
  • an insulin analogue of any one of second embodiments 1-16 wherein the insulin A chain is a polypeptide selected from the group consisting of X-1X0X1IVEQX6CX8SIX11SLYQLENYCN (SEQ ID NO: 4) and X 0 X 1 IVEQX 6 CX 8 SIX 11 SLYQLENYCN (SEQ ID NO: 5), wherein X-1 is any amino acid, optionally X-1 is Gly; X 0 is any amino acid or a modified amino acid comprising a glucose- binding element linked to its side chain; and X 1 is any amino acid or a modified amino acid comprising a glucose- binding element linked to its side chain; X 6 and X 11 are each Cys or selenocysteine; and X8 is Thr, His, Lys, Arg, or Glu; further wherein at least one of X -1 , X 0 and X 1 is in the D conformation; and the insulin B chain
  • X 50 is Orn, Lys, Pro, or a modified amino acid comprising a diol bearing moiety linked to the side chain of the amino acid; and X 51 is Thr or a diol bearing amino acid.
  • an insulin analogue of any one of second embodiments 1-17 wherein the insulin B chain is a polypeptide comprising the sequence of FVX24QHLCGSHLVEALYLVCGERGFFYTX49X50X51 (SEQ ID NO: 6), wherein
  • X24 is Lys or Asn
  • X 49 is a modified amino acid comprising a diol bearing moiety linked to the side chain of the amino acid;
  • X 50 is Orn, Lys or Pro
  • X51 is Thr or a diol bearing amino acid.
  • X24 is Lys or Asn
  • X 49 is a modified amino acid comprising a diol bearing moiety linked to the side chain of the amino acid;
  • X50 is Orn, Lys or Pro
  • X51 is diol bearing amino acid, optionally wherein the diol bearing amino acid comprises a diol bearing moiety linked to the side chain of the amino acid or the diol bearing amino acid is a main chain.
  • X 24 is Lys or Asn
  • X 49 is a modified amino acid comprising a diol bearing moiety linked to the side chain of the amino acid;
  • X 50 is Pro
  • X51 is Thr.
  • an insulin analogue of any one of second embodiments 1-20 wherein the insulin A chain is a polypeptide comprising the sequence of X0X1IVEQX6CX8SIX11SLYQLENYCN (SEQ ID NO: 5), wherein X 0 is any amino acid, optional Gly; and X1 is a modified D-amino acid comprising a glucose-binding element linked to its side chain; X6 and X11 are each Cys or selenocysteine; and X 8 is Thr, His, Lys, Arg, or Glu.
  • an insulin analogue of any one of second embodiments 1-21 wherein the diol bearing amino acid is selected from L -Cys, L -Lys, D -Lys, L -Orn, D -Orn, L -Dab, and D -Dab further modified to comprise a diol bearing moiety linked to the side chain of the amino acid or further modified to replace the carboxyl group with CH2OH.
  • an insulin analog of any one of second embodiments 1-22 wherein diol bearing amino acid comprises a OH diol moiety having the structure o linked to the side chain or backbone amide of the insulin B
  • diol bearing amino acid comprises a OH diol moiety having the structure o linked to the side chain or backbone amide of the insulin B
  • an insulin analog of any one of second embodiments 1-23 is provided wherein the glucose-binding elements are linked to the A chain and comprise a complex having the general structure BCM 2 BCM 1 BCM NH 2 BCM 1 H BCM 2 NH N , wherein BCM1 and BCM2 are boron-containing endently an integer selected from the range of 1 to 3; and R is any amino acid side chain of the L or D configurations standard 20 essential amino acids.
  • R is selected from the group consisting of H, C 1 -C 18 alkyl, C2-C18 alkenyl, (C1-C18 alkyl)OH, (C1-C18 alkyl)SH, (C2-C3 alkyl)SCH3, (C1-C4 alkyl)CONH 2 , (C 1 -C 4 alkyl)COOH, (C 1 -C 4 alkyl)NH 2 , (C 1 -C 4 alkyl)NHC(NH 2 + )NH 2 , (C0-C4 alkyl)(C3-C6 cycloalkyl), (C0-C4 alkyl)(C2-C5 heterocyclic), (C0-C4 alkyl)(C6- C 10 aryl)R 7 , (C 1 -C 4 alkyl)(C 3 -C 9 heteroaryl), and C 1 -C 12 alkyl(W 1 )C 1 -C 12 alkyl, wherein W1 is a heteroatom selected
  • R is H, C 1 -C 6 alkyl, (C 1 -C 4 alkyl)C(O)NH 2 , (C 1 -C 4 alkyl)OH, (C 1 -C 4 alkyl)CH3OH, (C1-C4 alkyl)S, (C1-C4 alkyl)SCH3, (C1-C4 alkyl)COOH and (C1-C4 alkyl)NH 2 .
  • an insulin analogue of any one of second embodiments 1-22 wherein the insulin B chain is a polypeptide selected from the group consisting of FVKQHLCGSHLVEALYLVCGERGFFYTEKX 51 (SEQ ID NO: 62), FVNQHLCGSHLVEALYLVCGERGFFYTDKX51 (SEQ ID NO: 63), FVNQHLCGSHLVEALYLVCGERGFFYTKPX51 (SEQ ID NO: 64), FVNQHLCGSHLVEALYLVCGERGFFYTPKX51 (SEQ ID NO: 65) FVNQHLCGSHLVEALYLVCGERGFFYTKPX51 (SEQ ID NO: 66); FVNQHLCGSHLVEALYLVCGERGFFYTPX50X51 (SEQ ID NO: 67); FVNQHLCGSHLVEALYLVCGERGFFYTPX51 (SEQ ID NO: 68) FVNQHLCGSHLVEALYLVC
  • FVNQHLCGSHLVEALYLVCGERGFF[Sar][APD] (SEQ ID NO: 72)
  • FVN QHLCGSHLVEALYLVCGERGFF[dA] [ APD] (SEQ ID NO: 73)
  • the diol-bearing amino acids comprises a natural or unnatural amino acids whose side chains are modified by linkage of a diol moiety to an attachment point located on the amino acid side chain, optionally wherein the amino acid is selected from the group consisting of Cysteine Homocysteine, Lysine, Ornithine (Orn), Diaminobutyric Acid (Dab) and Diaminoproprionic acid (Dap), each in either the L- or D configuration with the covalent linkage of a diol moiety, exemplified (but not restricted to) those listed in Table 2, to the amino acid side chain; and the glucose binding element is a compound selected from those listed in Figs. lOA-11C.

Abstract

L'invention concerne un analogue d'insuline à deux chaînes contenant (a) une chaîne B modifiée par l'addition d'un élément diol C-terminal en combinaison avec (b) un élément de liaison au glucose fixé à la chaîne au niveau ou à proximité de son extrémité N, éventuellement lié à un acide aminé D. L'invention concerne également un ensemble "retourné" d'analogues d'insuline, la chaîne A étant modifiée par addition d'un élément diol N-terminal alors que l'élément de liaison au glucose est fixé au niveau ou à proximité de l'extrémité C de la chaîne B. Des compositions comprenant de tels analogues d'insuline sont utilisées dans des méthodes de traitement d'un patient atteint du diabète sucré.
EP22799444.9A 2021-05-03 2022-05-03 Conception moléculaire de capteurs de glucose dans des analogues d'insuline sensibles au glucose Pending EP4334338A1 (fr)

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