A METHOD OF MODtJLATING THE ACTIVITY OF A NUCLEIC ACID MOLECULE
This application claims priority from U.S. Provisional Application No. 60/920,807, filed March 30, 2007, the entire content of which is hereby incorporated by reference.
This invention was made with government support under Grant No. ROl HL65222 awarded by the National Institutes of Health. The government has certain rights in the invention.
TECHNICAL FIELD
The present invention relates, in general, to agents that modulate the pharmacological activity of nucleic acid molecules and, in particular, to agents that bind therapeutic or diagnostic nucleic acid molecules in a sequence independent manner and modulate (e.g., inhibit or reverse) their activity. The invention also relates to compositions comprising such agents and to methods of using same.
BACKGROUND
Aptamers are single-stranded nucleic .acid (DNA or RNA) ligands that possess a number of features that render them useful as therapeutic agents. They are relatively small (8 kDa to 15 kDa) synthetic compounds that possess high affinity and specificity for their
target molecules (equilibrium dissociation constants ranging from, for example, 0.05-1000 nM) . Thus, they embody the affinity properties of monoclonal antibodies and single chain antibodies (scFv's) with the chemical production properties of small peptides . While initial studies demonstrated the in vitro use of aptamers for studying protein function, more recent studies have demonstrated the utility of these compounds for studying in vivo protein function
(Floege et al , Am J Pathol 154:169-179 (1999), Ostendorf et al , J Clin Invest 104:913-923 (1999), Dyke, Circulation 114 (23 ): 2490-7 (2006), Group, Retina 22(2):143-52 (2002), Group, Ophthalmology 110 ( 5) : 979- 86 (2003), Nimjee et al , Mol.Ther. 14(3):408-15
(2006), Nimjee et al , Trends Cardiovasc Med. 15(1) :41- 5 (2005), Nimjee et al, Annu. Rev. Med. 56:555-83
(2005), Rusconi et al, Nat. Biotechnol . 22 (11) : 1423-8
(2004)). In addition, animal studies to date have shown that aptamers and compounds of similar composition are well tolerated, exhibit low or no immunogenicity, and are thus suitable for repeated administration as therapeutic compounds (Floege et al , Am J Pathol 154:169-179 (1999), Ostendorf et al , J Clin Invest 104:913-923 (1999), Griffin et al , Blood 81:3271-3276 (1993), Hicke et al , J Clin Invest 106:923-928 (2000), Dyke, Circulation 114 (23 ): 2490-7
(2006), Group, Retina 22(2):143-52 (2002), Group, Ophthalmology 110 (5) : 979-86 (2003), Nimjee et al , MoI.
Ther. 14(3):408-15 (2006), Nimjee et al , Trends Cardiovasc Med. 15(l):41-5 (2005), Nimjee et al, Annu. Rev. Med. 56:555-83 (2005), Rusconi et al , Nat. Biotechnol. 22 (11 ): 1423-8 (2004)).
As synthetic compounds, site specific modifications can be made to aptamers to rationally alter their bioavailability and mode of clearance. For example, it has been found that 2'fluoro pyrimidine-modified aptamers in the 10 kDa to 12 kDa size range have a short circulating half-life (-10 minutes) following bolus intravenous administration but that simple chemical modification of the aptamer or conjugation of the aptamer to a high molecular weight inert carrier molecule (e.g., PEG) increases circulating half-life substantially (6-12 hours)
(Willis et al, Bioconjug Chem 9:573-582 (1998), Tucker et al, J Chromatogr Biomed Sci Appl 732:203-212
(1999), Watson et al, Antisense Nucleic Acid Drug Dev 10:63-75 (2000)). Bioactive and nuclease resistant single-stranded nucleic acid ligands comprising L- nucleotides have been described (Williams et al, Proc . Natl. Acad. Sci. 94:11285 (1997); USP 5,780,221; Leva et al, Chem. Biol. 9:351 (2002)). These "L-aptamers" are reportedly stable under conditions in which aptamers comprising nucleotides of natural strandedness (D-nucleotides) (that is, "D-aptamers " ) are subject to degradation.
Aptamers can be generated by in vitro screening of complex nucleic-acid based combinatorial shape libraries (>1014 shapes per library) employing a process termed SELEX (for Systematic Evolution of Ligands by Exponential Enrichment) (Tuerk et al, Science 249:505-10 (1990)). The SELEX process consists of iterative rounds of affinity purification and amplification of oligonucleotides from combinatorial libraries to yield high affinity and high specificity ligands. Combinatorial libraries employed in SELEX can be front-loaded with 2 'modified RNA nucleotides (e.g., 2 ' fluoro-pyrimidines) such that the aptamers generated are highly resistant to nuclease-mediated degradation and amenable to immediate activity screening in cell culture or bodily fluids. (See also USP 5,670,637, USP 5,696,249, USP 5,843,653, USP 6,110,900, USP 5,686,242, USP 5,475,096, USP 5,270,163 and WO 91/19813.)
Over the past decade, the SELEX technology has enabled the generation of high affinity and high specificity antagonists to a myriad of proteins including reverse transcriptases, proteases, cell adhesion molecules, infectious viral particles and growth factors (see Gold et al , Annu Rev Biochem 64:763-97 (1995)). In particular, this technology has been employed to generate potent antagonists of coagulation factors, including factors Vila, IXa, Xa and thrombin, transcription factors, autoimmune
antibodies, cell surface receptors, as well as Von Willebrand factor and GPIIb-IIIa (see, for example, Rusconi et al , Thrombosis and Haemostasis 83:841-848 (2000), White et al, J. Clin Invest 106:929-34 (2000), Ishizaki et al, Nat Med 2:1386-1389 (1996), Lee et al , Nat Biotechnol 15:41-45 (1997), Nimjee et al, Annu. Rev. Med. 56:555-83 (2005)). (See also Published U.S. Application No. 20030083294 and documents cited therein, which documents are incorporated herein by reference as is Published U.S. Application No. 20030083294.)
It has been shown previously that the activity of aptamers can be reversed by using matched antidote oligonucleotides (Dyke, Circulation 114 (23 ): 2490-7 (2006), Rusconi et al, Nat Biotechnol. 22 (11) : 1423-8 (2004), Rusconi et al , Nature 419 (6902 ): 90-4 (2002)); Published U.S. Application No. 20030083294). The present invention results from the identification of agents (referred to below as "universal antidotes") that can bind therapeutic or diagnostic nucleic acid molecules, such as aptamers, siRNAs, etc., in a sequence independent manner and modulate (e.g., inhibit or reverse their activity) . The universality of the antidotes disclosed herein translates into significant savings in time and cost from the standpoint of drug development. Further, the nature of these antidotes (detailed below) is such that the formation of double-stranded RNA helices is avoided
and, therefore, the potential inflammatory response associated therewith.
SUMMARY OF THE INVENTION
The present invention relates to agents that modulate (e.g., inhibit or reverse) the pharmacological activity of nucleic acid molecules (e.g., aptamers (D or L), siRNAs, microRNAs, antisense RNAs, including modified forms of such molecules (e.g., 2 'F, 2'0Me, 2'B, 2'I, 2'NH, etc.)). More specifically, the invention relates to agents that bind therapeutic or diagnostic nucleic acid molecules in a sequence independent manner and modulate (e.g., inhibit or reverse) their activity. The invention also relates to compositions comprising such agents and to methods of using same.
Objects and advantages of the present invention will be clear from the description that follows.
BRIEF DESCRIPTION OF THE DRAWINGS
Figures IA and IB. Protamine reverses Factor IXa aptamer and Factor X aptamer activity in APTT assay. Effect of protamine (2.5μg) on clotting time of human plasma anti-coagulated with an aptamer ("Ch-9.3t") to human factor IXa (Fig. IA) or with an aptamer ("Ilf7t") to human factor Xa (Fig. IB).
Figure 2. Protamine reverses both aptamers ' activity.
Figure 3. PPA-DPA reverses Von Willebrand R9.3 aptamer activity.
Figures 4A-4C. Protamine reverses Factor IXa aptamer in pig anticoagulation model .
DETAILED DESCRIPTION OF THE INVENTION
The present invention relates generally to agents ("universal antidotes") (UAs) that can modulate the pharmacological activity of nucleic acid molecules (NAMs), including therapeutic and diagnostic NAMs. The invention further relates to methods of modulating (e.g., reversing/inhibiting) the effect of pharmacological NAMs by administering such UAs to human or non-human mammals . Additionally, the invention relates to methods of using UAs of the invention to assess the activity of NAMs.
Pharmacological NAMs include, but are not limited to, aptamers, siRNAs, microRNAs, antisense RNAs, aptamer-siRNA chimeras, mRNAs , ribozymes and antagomirs, that bind a desired target molecule.
Aptamer target molecules include, generally, peptides, proteins, glycoproteins, polysaccharides and nucleic acids, as well as small molecular weight
(organic) compounds. More specifically, aptamer target molecules can include enzymes (e.g., proteases, including factors Vila, IXa, Xa, XIa, thrombin and protein C) as well as zymogens thereof. Aptamer target molecules can also include hormones, receptors (including platelet receptors, e.g., glycoprotein (gp) HbIIIa, GPIb-IX-V, GPVI, P2Yi2, and PARs), adhesion molecules (e.g, Von Willebrand factor and collagens) metabolites, cofactors (e.g., Tissue Factor, or coagulation factors Va and Villa) , transition state analogs, as well as drugs, dyes and toxins. Aptamers can be made using SELEX methodology (see, for example, USPs 5,270,163, 5,817,785, 5,595,887, 5,496,938, 5,475,096, 5,861,254, 5,958,691, 5,962,219, 6,013,443, 6,030,776, 6,083,696, 6,110,900, 6,127,119, and 6,147,204, see also Published U.S. Application No. 20030083294 and documents cited therein)). Aptamers specific for a wide variety of target molecules are presently available (see, for example, Gold et al , Ann. Rev. Biochem. 64:763 (1995), Nimjee et al, Annu. Rev. Med. 56:555-83 (2005)).
Details of the production of, for example, siRNAs, microRNAs, and antisense RNAs and of methods of using these NAMs in modifying gene expression are described, for example, in Dorsett and Tuschl, Nat Rev Drug Discov. 3(4):318-29 (2004), Fire et al, Nature 391(6669) :806-ll (1998), Grishok et al , Cell 106(1) :23-34 (2001), Lagos-Quintana, et al , Rna
9(2):175-9 (2003), Leaman et al , Cell 121 (7) : 1097-108 (2005), Martinez et al , Cell 110 (5) : 563-74 (2002), Meister et al , Rna 10(3): 544-50 (2004), Meister and Tuschl, Nature 431 (7006 ): 343-9 (2004), Pfeffer et al , Science 304 (5671) : 734-6 (2004), Tuschl, Nat Biotechnol. 20(5):446-8 (2002), and Tuschl and Borkhardt, MoI Interv. 2(3):158-67 (2002).
The present invention relates to a method of modulating (e.g., reversing or inhibiting) the activity of a NAM, for example, by altering its conformation and thus its function and/or by sterically blocking binding of the NAM to its target molecule. In accordance with the invention, the UA can be contacted with the targeted NAM, for example, under conditions such that it binds to the NAM and modifies the interaction between the NAM and its target molecule. The UA can also interfere with the binding of the NAM to its target molecule through charge interaction. Modification of the interaction between the NAM and its target molecule can result from, for example, modification of the NAM structure as a result of binding by the UA. The UA can bind the free NAM and/or the NAM bound to its target molecule.
UAs of the invention include pharmaceutically acceptable member (s) of a group of positively charged compounds, including proteins, lipids, and natural synthetic polymers that can bind NAM in, for example, biologically fluids . Protamines are a group of
proteins that yield basic amino acids on hydrolysis and that occur combined with nucleic acid in the sperm of fish, such as salmon. Protamines are soluble in water, are not coagulated by heat, and comprise arginine, alanine and serine (most also contain proline and valine and many contain glycine and isoleucine) . In purified form, protamine has been used for decades to neutralize the anticoagulant effects of heparin. UAs of the invention also include protamine variants (e.g., the +18RGD variant (Wakefield et al, J. Surg. Res. 63:280 (1996)) and modified forms of protamine, including those described in Published U.S. Application No. 20040121443. Other UAs of the invention include protamine fragments, such as those described in USP 6,624,141 and U.S. Published Application No. 20050101532. UAs of the invention also include, generally, peptides that modulate the activity of heparin, other glycosaminoglycans or proteoglycans (see, for example, USP 5,919,761). The invention further includes pharmaceutically acceptable salts of the above-described UAs, as appropriate, including sulfate salts.
Examples of UAs of the invention can include compounds of types described in Table 1, several of which contain cationic-NH groups permitting stabilizing charge-charge interactions with a phosphodiester backbone.
TABLE l
Compound Abbreviation Molecular structure Remark
Poly-L-lysine PLL 1. Commercially
(H2C)4 NH2 available.
O 2. Carbonyl moiety (-
Il C=O) which could -NH CH C permit additional stabilization to the complex through hydrogen bonds with DNA.
Poly-L-ornithine PLO 1. Commercially
(H2C)3- — NH2 available.
O 2. Carbonyl moiety (-
Il C=O) which could
Il
-NH CH- -C permit additional stabilization to the complex through hydrogen bonds with DNA.
Polyphosphoramidate PPA-SP Polymers with an polymer series PPA-BA identical backbone
PPA-EA but different side
PPA-MEA chains ranging from
PPA-DMA PPA primary to
PPA-DEA quaternary amines.
PPA-TMA Provide a platform fo
PPA-DPA a systematic study.
PPA-SP 2. Lower cytotoxicity compared with
-NH (CH2)4 NH2 PPA-BA polyethylenimine
-NH (CH2)2 NH2 (PEI) and poly-L- PPA-EA lysine (PLL).
-NH (CH2)2 NH CH3 PPA-MEA
-CH3
-NH (CH2J2 N: PPA-DMA ~CH3
-CH2CH3
-NH (CH2J2 N= PPA-DEA "CH2CH3
Polyphosphoramidate PPA-DPA-b- 1. a copolymer of PPA- diprophylamine- poly PEG2000 DPA and PEG. ethylene glycol copolymer
Polyethyleneimine PEI 1. Commercially available.
2. PEI with branched structure condenses
-CH2 CH2 NH- DNA to a greater extent than linear ones.
3. high cytotoxicity.
Ionene 1. Commercially available. e.g. polybrene
2. Have high charge density.
θ
2 Br
Natural polyamine 1. Commercially available. e g- H5N- -(CH2J4 -NH,
Putrescine 2. The most extensive Spermine work Spermidine H2N (CH2J3 NH (CH2)4 NH (CH2)3 NH2 on their binding with DNA has been carried out and have remarkable effects
H2N (CH2)4 NH (CH2)3 NH2 on the DNA condensation.
Poly(allylamine) PAL 1. Commercially available.
2. Highly positive charged
3. Low toxicity.
Peptide nucleic acid PNA 1. Commercially available.
2. Binding through Watson-crick base pairing, thus binding is typically stronger and more rapid.
-N+(CHj) TAPP with the
of TAPP of
e.g. polyamidoamine PAMAM 1. Commercially dendπmer Deπdrimer G2 available.
2. Branched spherical shape and a high density surface charge.
3. Low cytotoxicity.
e.g. polypropyieneimine PPI dendrimer 1. A class of amine- dendrimer terminated polymers, demonstrated to be efficient gene delivery vectors.
2. Low cytotoxicity in a wide range of mammalian cell lines.
3. Unique molecular structures, with defined molecular weight, surface charge and surface functionality. These properties of dendrimers provide
a platform for a systematic study.
Partially deacetylated 1. Commercially Chi tin available.
Cyclodextrin grafted CD-bPEI 1. Their ICso's are 2-3 branched PEI or linear PEI CD-IPEI \ / = cyclodextrin orders of magnitude higher than the
(α-CD: six sugar ring corresponding non- cyclodextrin-based β-CD: seven sugar ring polymer.
γ-CD:eight sugar ring)
Certain UAs of the invention, for example, protamine, can be isolated from natural sources (Kossel, The Protamines and Histones (Longmans, NY (1928); Felix et Ia, Z. Physiol. Chem. 330:205 (1963); Ando et al, Int. J. Prot . Res. 1 :-221-=- (1969)-; Felix, Adv. Prot. Chem. 15:1 (1960). Alternatively, proteinaceous UAs can be produced recombinantly, chemically, or synthetically. The UAs described in Table 1 are available commercially and/or can be produced using art-recognized techniques .
Standard binding assays, for example, can be used to screen for preferred UAs of the invention (e.g., using BIACORE and isothermal microcalorimetric assays). That is, test compounds (e.g., protamine fragments or variants or modified forms of protamine) can be contacted with the NAM (e.g., aptamer, etc.) to be targeted under conditions favoring binding and a determination made as to whether the test compound in fact binds the NAM. Test compounds that are found to bind the NAM can then be analyzed in an appropriate bioassay (which will vary depending on the NAM and its target molecule) to determine if the test compound can affect the binding of the NAM to its target molecule and/or modulate (e.g., reverse) the activity of the NAM or modify the NAM and its activity in a functional assay.
The UAs of the invention can be used, for example, to reverse the anticoagulant and
antithrombotic effects of NAMs (e.g, aptamers, etc.) that target components of the coagulation pathway, particularly antagonists of the tissue factor (TF) /factor Vila (FVIIa), factor Villa (FVIIIa) /factor IXa (FIXa), factor Va (FVa) /factor Xa (Fxa) enzyme - complexes and platelet receptors such as GPIIb-IIIa and GPVI, factors involved in promoting platelet activation such as Gas6, Von Willebrand factor, collagen, factors involved in promoting or maintaining fibrin clot formation such as PAI-I (plasminogen activator inhibitor 1) or coagulation factor XIIIa (FXIIIa) , and additional factors involved in promoting or preventing fibrin clot formation such as ATIII (anti-thrombin III), thrombin or coagulation factor XIa (FXIa) .
UAs of the invention are administered in an amount sufficient to modulate (e.g., reverse) the NAM activity. Several clinical scenarios exist in which the ability to rapidly reverse the activity of an antithrombotic or anticoagulant NAM is desirable. A first case is when anticoagulant or antithrombotic treatment leads to hemorrhage, including intracranial or gastrointestinal hemorrhage. A second case is when emergency surgery is required for patients who have received antithrombotic treatment. This clinical situation arises in a low percentage of patients who require emergency coronary artery bypass grafts while undergoing percutaneous coronary intervention under
the coverage of GPIIb/IIIa inhibitors. Current practice in this situation is to allow for clearance of the compound (for small molecule antagonists such as eptifibatide) , which may take 2-4 hours, or platelet infusion (for Abciximab treatment). A third case is when an anticoagulant NAM is used during a cardiopulmonary bypass procedure. Bypass patients are predisposed to post operative bleeding. In each case, acute reversal of the anticoagulant effects of a compound via an antidote (e.g., a proteinaceous modulator of the invention) allows for improved, and likely safer, medical control of the anticoagulant or antithrombotic compound. Similarly, the UAs of the invention can be used when a patient on an anthrombotic is involved in an accident or suffers intracranial hemorrhage and blood loss cannot otherwise be stopped.
UAs of the invention can be used in any of a variety of situations where control of NAM activity is desired. The targeting of antithrombotic and anticoagulant NAMs is only one example. UAs of the invention can also be used, for example, to modulate (e.g., reverse) the immunosuppressive effect of NAMs that target interleukin, for example, in patients subject to infection. The present UAs can be used, for example, to reverse the immunostimulatory effects of NAMs that target CTLA4 in patients at risk of developing autoimmunity.
The UAs of the invention can also be used to inhibit NAMs that activate the immune system. If, for example, a patient goes into systemic shock because of over activated immune response due to NAMs binding to immune activating cells, UAs of the invention can be used to reverse the effect.
UAs of the invention can be used to modulate (e.g. reverse) the effects of NAMs that target receptors involved in the transmission of the nerve impulse at the neuromuscular junction of skeletal muscle and/or autonomic ganglia (e.g., nicotinic acetylcholine or nicotinic cholinergic receptors). Such NAMs can be made to produce muscular relaxation or paralysis during anesthesia. Agents that block the activity of acetylcholine receptors (agents that engender neuromuscular blockade) are commonly used during surgical procedures, and it is preferred that the patients regain muscular function as soon as possible after the surgical procedure is complete to reduce complications and improve patient turnover in the operating arenas. Therefore, much effort has been made to generate agents with predictable pharmacokinetics to match the duration of the drug activity to the anticipated duration of the surgical procedure. Alternatively, UAs of the invention can be used to provide the desired control of the activity of the neuromuscular blocker, and thus reduce the
dependence on the patient's physiology to provide reversal of the neuromuscular blocking agent.
UAs of the invention can be used to modulate (e.g. reverse) the effects of NAMs that target growth factors (e.g., PDGF or VEGF) . Such NAMs can be used in the treatment of tumors and in the treatment of inflammatory proliferative diseases. Since growth factors play systemic roles in normal cell survival and proliferation, NAM treatment can result in a breakdown of healthy tissue if not tightly regulated (e.g., patients receiving NAM that target angiopoietin I can be subject to hemorrhaging) . UAs of the invention can be used to provide the necessary regulation.
UAs of the invention can be used to modulate (e.g. reverse) the effect of NAMs that target small molecules, such as glucose. Hypoglycemia can be avoided in patients receiving glucose-targeted NAMs to regulate glucose uptake using the modulators of the invention. The present UAs can also be used to regulate the activity of NAMs directed against members of the E2F family, certain of which are pro- proliferative, certain of which are repressive. The UAs of the invention can be used to "turn off" such NAMs at desired points in the cell cycle.
UAs of the invention can also be used to reverse the binding of NAMs bearing radioactive or cytotoxic moieties to target tissue (e.g., neoplastic tissue)
and thereby, for example, facilitate clearance of such moiety's from a patient's system. Similarly, the UAs of the invention can be used to reverse the binding of NAMs labeled with detectable moieties (used, for example, in imaging or cell isolation or sorting) to target cells or tissues (see, generally, Hicke et al , J. Clin. Invest. 106:923 (2000); Ringquist et al, Cytometry 33:394 (1998)) . This reversal can be used to expedite clearance of the detectable moiety from a patient's system.
The UAs of the invention can also be used in in vitro settings to modulate (e.g., inhibit) the effect of a NAM (e.g., aptamer, etc.) on a target molecule. For example, a UA of the invention can be used to modulate (e.g., reverse) the effect of a NAM on a particular target molecule, present in a mixture of target molecules .
The UAs of the invention can be formulated into pharmaceutical compositions that can include, in addition to the UA, a pharmaceutically acceptable carrier, diluent or excipient. The precise nature of the composition will depend, at least in part, on the nature of the UA and the route of administration. Optimum dosing regimens can be readily established by one skilled in the art and can vary with the UA, the patient and the effect sought. Generally, the UA can be administered IV, IM, IP, SC, or topically, as appropriate. Furthermore, because the antidote
activity is durable, once the desired level of modulation of the NAM by the antidote is achieved, infusion of the antidote can be terminated, allowing residual antidote to clear the human or animal. This allows for- subsequent re-treatment of the human or animal with the NAM as needed.
Proteinaceous UAs of the invention can also be produced in vivo following administration of a construct comprising a sequence encoding the proteinaceous UA (Harrison, Blood Rev. 19(2):lll-23
(2005) ) .
Certain aspects of the invention are described in greater detail in the non-limiting Examples that follows. Incorporated by reference is the following citation that describes APTT and other clotting assays: Quinn et al, J. Clin. Lab. Sci . 13 (4) : 229-238
(2000). This review describes the properties and biochemistry of various clotting assays including APTT, PT and thrombin time assays, and their use in diagnosing coagulopathies .
EXAMPLE I
Millions of individuals have received protamine, a group of positively charged proteins, to reverse the blood thinning effects of heparin, particularly following cardiopulmonary bypass surgery. A crystal structure study on an RNA aptamer that binds human thrombin showed that the aptamer bound to thrombin in
a similar location as heparin. To test the hypothesis that aptamers may have other properties similar to heparin, studies were undertaken to determine if aptamer activity could be neutralized with protamine, since heparin activity can be reversed using protamine.
To test this possibility, human plasma was anticoagulated with two different aptamers, one to human factor IXa (termed CH-9.3 t (37nt, 2 ' fluoropyrimidine modified ssRNA molecule with a cholesterol moiety on the 5' end, 3'idt) 9.3t (same as CH-9.3t except no carrier))- and a second one to human factor Xa (termed Ilf7t (37nt long, 2 ' fluoropyrimidine modified RJSIA molecule) ) .
As shown in Figure 1, addition of the aptamers to human plasma (15OnM for Ch9.3t and 25OnM Ilf7t) significantly increased the clotting time as measured in an aPTT assay. In the case of the factor IXa aptamer, clotting time increased from a baseline of approximately 34 seconds to approximately 87 seconds (Figure IA). Addition of protamine (2.5μg) to the plasma after it had been anticoagulated with the factor IXa aptamer returned the clotting time to normal within 5 minutes following addition. This reversal was maintained for at least an hour. Similarly, the factor Xa aptamer (25OnM) increased the clotting time of normal human plasma in the aPPT assay from approximately 28 seconds to approximately 97
seconds. As shown in Figure IB, administration of protamine (2.5μg) totally reversed the activity of the factor Xa aptamer within 5 minutes. (See also Figure 2. )
EXAMPLE II
Table 2 includes a summary of data resulting from UA vs aptamer experiments (see Example I above (Bi- 9.3t (37nt, 2 ' fluoropyrimidine modified ssRNA with biotin on the 5' end) ) .
ιaϋie - Universal Antidote vs A tamer Ex eriments
EXAMPLE III
The Platelet Function Analyzer (PFA-100) . The PFA-100 is a bench top instrument that uses whole blood and simulates platelet function under high shear stress conditions. In this experiment, disposable cartridges coated with Collagen/ADP were filled with 840 microliters of whole human blood (collected in 10ml sodium heparin tubes) and placed into the PFA- 100. The standard test protocol is followed and each dilution point is done in duplicates. For antidote experiments, 5OnM of vWF aptamer R9.3 was incubated with the whole blood for 5 minutes followed by the addition of antidote. The blood was than placed in PFA-100 and the test was run.
During the test, blood in the cartridge is aspirated under constant negative pressure from the reservoir, through a capillary, passing a microscopic aperture cut into the membrane. The shear stress rate during this process reaches 5000-6000 s"1 and along with the platelet activators (i.e. Collagen/ADP) present on the membrane, initiates platelet activation, adhesion and aggregation. These processes cause the formation of a platelet plug on the microscopic aperture and blood flow through the capillary ceases. The platelet function is measured as the time it takes to form the aperture occlusion.
Although the PFA-100 is sensitive to many variables that affect platelet function, a number of studies revealed that it is most sensitive to certain platelet receptor defects (mainly GPIb-IX-V and GP HbIIIa) and VWF defects. (See Figure 3.)
Example IV
Experimental details
Swine (2.5-3.5 kg) were randomly assigned to treatment groups. For all groups, anesthesia was induced by intramuscular injection of ketamine (22 mg/kg) and acepromazine (1.1 mg/kg) . A catheter was then placed in the ear vein, through which anesthesia was maintained with fentanyl, first with a 100 μg/kg bolus, and then with a continuous infusion of 60 μg • kg"1 • h"1. The swine were then intubated and mechanically ventilated. Following placement of the esophageal or rectal temperature probe and SPθ2_monitor, the femoral artery and vein were cannulated. The arterial line was used as a means to continuously monitor mean arterial blood pressure and heart rate, as well as removal of blood samples for evaluation of ACT. After determining baseline ACT values, the venous line was used to administer the Factor IXa aptamer (0.5 mg/kg) . Blood samples were then drawn from the arterial line at 5, 15, and 30 minutes post aptamer administration. The ACT values
were measured by using Hemochron Jr. Signature Microcoagulation System (ITC, Edison N.J.). For experiments involving antidote administration, 40 mg protamine (lOmg/mL) was given over five minutes via the femoral vein catheter at 30 minutes post aptamer injection. For all animals, subsequent blood samples were at taken at 35, 40, 55, 60, 75, and 90 minutes post aptamer administration. All data points are done in duplicate per animal. At the closure of the experiment, swine were euthanized with Euthasol (175 mg/kg) via femoral vein.
All animals received humane treatment in accordance with the Guide for the Care and Use of Laboratory Animals published by the National Institutes of Health, as approved by the Duke University Animal Care and Use Committee.
Results
Immediate anticoagulation and prompt reversal is necessary during several cardiovascular procedures, the most common being cardiopulmonary bypass (CPB) , as employed during coronary artery bypass grafting (CABG) . Without potent anticoagulation, blood clots would form and blood would not circulate in an extracorporeal circuit. However, following the procedure, these values must return to pretreatment levels to prevent massive hemorrhage from the surgical site. After successfully determining the ability of
protamine to reverse the activity of the Factor IXa and Factor Xa aptamers for at least 60 minutes in vitro using APTT, the ability of protamine to reverse aptamer anticoagulation in vivo was examined. As shown in Figure 4A, pigs were successfully anticoagulated with 0.5 mg/kg of the Factor IXa aptamer, as demonstrated by an immediate increase in the ACT from 105 s. to approximately 170 s. When no antidote was administered, the level of anticoagulation gradually decreased in accordance with the 90-minute half-life of the molecule (Rusconi et al, Nat. Biotechnol. 22 ( 1) : 1423-1428 (2004)). However, following administration of 10mg/kg of protamine (approx. 40 mg per animal), clotting times as measured by ACT quickly returned to pretreatment baseline levels within five minutes, indicating complete reversal of anticoagulation (Figure 4B) . In addition, this reversal was sustained for the duration of the experiment (at least one hour) ; all ACT values attained post reversal are below the level needed for adequate anticoagulation (Figure 4C) . Therefore, a bolus injection of the Factor IXa aptamer resulted in immediate anticoagulation that was successfully reversed with protamine.
EXAMPLE V
In order to reverse the aptamer function, an antidote has to be able to compete with the target
protein by binding to the aptamer with high affinity. Binding affinities of aptamer 9.3t with a number of polymers and polycationic molecules have been studied by isothermal titration calorimetry (ITC) . In the measurements, UA solution was titrated into the aptamer 9.3t by a computer-controlled microsyringe at 298K in PBS. Binding constants and some thermodynamic parameters are summarized in Table 3. Among the chosen polymers, PAMAM dendrimer, PPA-DPA 30k and PLL demonstrated significant affinity with aptamer 9.3t; whereas, the binding constant of aptamer 9.3t to PPA- DPA 8k is much lower, at 8.47 x 105 M"1. No significant binding was observed for the natural polyamines, spermine and spermidine. These results are consistent with the in vitro and in vivo studies which showed that having a strong affinity towards aptamers is a primary criterion as a universal antidote.
Table 3
Host Potential Binding ΔG ΔH TΔS Antidotes constant (kj mol"1) (kj mol"1) (kJ mol'1) (M"1)
Polybrene 1.6 x 105 - 29.6 + 71.3 + 101.0
PAMAM 1.7 x 106 - 35.5 — 198.5 + 163.0
Aptamer Ch-9.3t Spermine 8.8 x 103 - 22.5 — 1.18 + 21.3
PPA-DPA 8k 2.7 x 105 - 31.0 + 24.7 + 55.7
PPA-DPA 30k 1.3 x 107 - 40.5 + 138.24 + 178.8
The isothermal calorimetry measurements (ITC) were conducted by using a thermostatic and fully computer-operated MCS-ITC calorimeter from MicroCal, LLC. Aliquots of 10 μL were titrated into the calorimetric cell every 5 min over a 2 hours period at 298K. A blank run was carried out for each system studied where the titrant was titrated into a cell containing only PBS to allow corrections for the heat effects due to dilution to be made. Data analysis was performed using the customized ITC module of the Origin 5.0 software package and a least squares fitting procedure to fit the data to the appropriate binding model .