KR20040066712A - The conjugate of human growth hormone - Google Patents

Abstract

PURPOSE: A conjugate of PEG-human growth hormone is provided, thereby increasing retention time of human growth hormone, reducing antigenicity of human growth hormone and maintaining biological activity of human growth hormone. CONSTITUTION: The conjugate of PEG-human growth hormone is prepared by binding one molecule of polyethylene glycol(PEG) to the amino terminal of human growth hormone or derivatives thereof, wherein the amino terminal has phenylalanine; the PEG is bound to alpha-amino group in the amino terminal of human growth hormone; and the PEG has molecular weight of 2 kDa to 100 kDa, preferably 10 kDa to 40 kDa.

Description

THE CONJUGATE OF HUMAN GROWTH HORMONE}

Human growth hormone is an unglycosylated peptide hormone secreted from the anterior pituitary gland, and is known to bind to receptors of various tissues of the human body to promote the secretion of other growth factors or directly act to promote the growth of various parts of the human body. After the growth hormone extracted from the human pituitary gland was found to be effective in the treatment of pituitary dysplasia, the demand for human growth hormone increased explosively, but the amount of the growth hormone extracted from the human pituitary gland is very limited. In the US Food and Drug Administration (FDA), a child who received human growth hormone extracted from a dead human pituitary gland died of a fatal nervous system disease (Creutsfelt-Jacob Disease) caused by a virus contaminated during growth hormone extraction. The use of hormones purified from the pituitary gland was prohibited ( Science 234 , 22 (1986)).

Human growth hormone biosynthesized in E. coli by Genentech was approved by FDA as a rare drug, and then recombinant human growth was carried out by Eli Lilly, Nordisk, Denmark, etc. Hormones are commercialized and sold. Currently, it is used to treat dwarfism caused by growth hormone deficiency and Turner syndrome, and to treat growth hormone deficiency in adults and chronic renal failure (Chronic Renal Insufficiency (CRI)), but osteoporosis, wounds, burns and infertility. As clinical trials are being conducted on the back of the body, it is expected that the number of diseases applying human growth hormone will increase significantly. Human growth hormone must be administered to the patient three times a week or once daily to maintain proper serum levels. For patients chronically receiving human growth hormone, administration due to frequent subcutaneous injections reduces the patient's quality of life and leads to problems of complex diseases such as complex disease (antibody formation or differential organ growth). (Haffner D., Schaefer, F., Girard, J., Ritz, E. and Mehls, J. Clin. Invest , O. 93 , 1163 (1994)).

To address the problems associated with repeated infusions of human growth hormone, several studies have been conducted to increase the in vivo retention time while maintaining the biological activity of human growth hormone. Among them, human growth hormone is encapsulated in a biocompatibility and biodegradable polymer matrix such as polylactide and polyglycolide to prepare a sustained release composition that is released in vivo over one week or more. Has been tried and the combination and encapsulation studies of various biodegradable polymers have been conducted, Genentech (Nutropin Depot) is sold under the trade name. However, these controlled release devices must be administered in excess of human growth hormone, and are often released in vivo at a high initially and then less, and as the concentration of human growth hormone in these controlled release devices increases, It has the disadvantage of being aggregated after several days to reduce biological activity and become an immunogen in vivo.

In order to increase the in vivo retention of protein drugs, including human growth hormone, methods have been attempted to combine proteins with synthetic polymers such as PEG. Combining protein drugs with synthetic polymers can alter the surface properties of protein molecules to increase their solubility in water or organic solvents, increase biocompatibility, reduce immune responsiveness, increase in vivo stability, intestinal tract Clearance by the system, kidneys, spleen or liver can be made more slowly. If the molecular weight of the protein is small, it is lost by filtration in the intestinal system or kidneys, and it is prevented by binding a polymer such as PEG (Knauf, MJ et al, J. Biol. Chem. 263 , 15064 (1988)). Thus, modifying polymers in protein pharmaceuticals can increase the stability of protein molecules in solution, and can effectively protect the intrinsic surface properties of the protein, thus preventing nonspecific protein adsorption. Research has been conducted on the effect of binding PEG to biologically active peptides or proteins to prolong half-life in the body, increase solubility, and reduce immune responses in the body, which is described in US Pat. No. 4,179,337 (Duration of 1996). First reported). Although it is true that side effects are greatly reduced due to the above-mentioned advantages when the protein and PEG are combined, it shows a disadvantage that the bioactivity of the protein is greatly reduced after binding to PEG.

PEG, which is widely used to date, covalently bonds with one or more free lysine residues on the surface of the protein, so that PEG is attached to the surface of the protein. When bound, their activity is reduced. In addition, the binding of PEG and lysine residues usually occurs randomly, so that many kinds of PEGylated protein binders exist in a mixture, resulting in a complicated and difficult process of purely separating the desired binder. For example, in the case of human growth hormone, there are 10 free lysine residues on its surface, and the focus of recent research has been on which of these residues retains the biological activity of human growth hormone when PEG binds to it. Genentech's paper [Clark et al., The Journal of Biological Chemistry , 271 , 21969 (1996)] and International Publication No. WO 93/00109 disclose that PEG is formulated with PEG when human growth hormone is used as an immune response promoter. A variety of known pegylation methods (P. McGoff et al., Chem. Pharm. Bull. , 36 , 3070 (1988); Chamow, SM et al., Bioconjugate) Chem. , 5 , 133 (1994); and Teh, LC and Chapman, GE, Biochem. Biophys. Res. Comm. , 150 , 391 (1988)). The PEG used in the test had a molecular weight of 5,000 kDa and the cell proliferation assay using FDC-P1, a premyeloid cell line, decreased its activity as the number of PEG molecules bound per molecule of human growth hormone increased. Confirmed. U.S. Pat.No. 5,766,897 and WO 00/42175 disclose the use of PEG-maleimide to prevent PEG from reacting with the active site of human growth hormone in binding PEG with human growth hormone. It was allowed to react selectively with cysteine. However, this type of PEG requires human growth hormone to have free cysteine residues that are not involved in disulfide bonds, but since all four cysteine residues present in human growth hormone participate in disulfide bonds, Pegylation reactions were performed using human growth hormone variants with cysteine residues inserted. However, this method has a problem in that it is difficult to obtain a raw material because the human growth hormone used in the PEGylation reaction is not a natural type, and the process of expressing and purifying a protein in which free cysteine is present is not usually easy.

In order to overcome the above problems, the present inventors have completed the present invention by preparing and separating a conjugate in which one PEG molecule is bonded to an amino terminus of a natural human growth hormone.

It is an object of the present invention to selectively bind a molecule of PEG to a specific site of human growth hormone, specifically to an amino terminus, thereby minimizing degradation of biological activity while increasing the stability and retention time of human growth hormone to sustain in vivo activity. To provide a PEG-human growth hormone conjugate.

1 is a SDS-polyacrylamide gel photograph, lanes 1 to 5 refer to standard proteins and 10 kDa, 20 kDa, 30 kDa and 40 kDa mono-PEG-hGH, respectively.

2 shows the peaks of size exclusion chromatography, peaks 1 to 5 relate to 40 kDa, 30 kDa, 20 kDa and 10 kDa mono-PEG-hGH, and unmodified hGH, respectively.

3A is a peptide map of unmodified hGH and FIG. 3B is a peptide map of 30 kDa mono-PEG-hGH.

Figure 4 shows the in vitro activity of the cell growth over time by administering NIBSC, unmodified hGH, 10 kDa, 20 kDa, 30 kDa, 40 kDa mono-PEG-hGH to Nb2 cells .

FIG. 5 is a measure of in vivo activity as it relates to weight gain over time by administering a solvent control, standard hGH, 10 kDa, 20 kDa, 30 kDa and 40 kDa mono-PEG-hGH to rats without pituitary gland.

In accordance with the above object, the present invention provides a PEG-human growth hormone conjugate in which one water-soluble PEG molecule is selectively bonded to the amino terminus of human growth hormone.

Hereinafter, the present invention will be described in detail.

The present invention relates to a conjugate obtained by chemical modification of human growth hormone (PEG), which is currently widely used as a therapeutic protein. In order for human growth hormone to play its role in vivo, it has to bind to human growth hormone receptors present in the membrane of the target cell, and the binding of human growth hormone to receptors is carried out at two receptor binding sites in human growth hormone. (Cunninghum et al., Proc. Natl. Acad. Sci. USA 88 , 3401 (1991)). It is known that the amino terminus of human growth hormone does not affect binding to the receptor ( Recent Progress In Hormone Research , 48 , 253 (1992)).

Human growth hormone useful in the present invention is extracted from mammals or chemically synthesized. It may also be obtained from prokaryotic or eukaryotic organisms transformed with DNA encoding human growth hormone using genetic recombination techniques. When using E. coli or yeast as a host, the human growth hormone expression product contains an initial methionine amino acid residue ( Position -1).

In the present application, additionally including methionine at the amino terminal of the human growth hormone is referred to as a human growth hormone analog.

The PEG polymer molecules used in the present invention may be selected from water soluble PEG polymers, and typically will bind to the ε-amino group, cysteine residue or histidine residue of the lysine residue depending on the activation group of the PEG when chemically modifying the protein with the PEG polymer. Can be. However, using PEG polymers with these activating groups, one or more PEG molecules bind to human growth hormone. PEG molecules bound to various sites may lose their activity by structurally interfering with the binding of human growth hormone and its receptor.

Therefore, the PEG polymer of the present invention selected to bind only one molecule of PEG to one molecule of human growth hormone must be aqueous so as not to precipitate in an aqueous environment such as a physiological environment and specific for the α-amino group of the amino terminus of the human growth hormone. It must have a single reaction aldehyde group so that it can be bound to each other. In addition, the molecular weight of the PEG polymer is not limited, but is preferably 2 to 100 kDa, particularly preferably 10 to 40 kDa. PEG may or may not be branched.

PEG performs a PEGylation reaction in which human growth hormone is reacted with alkoxy-PEG-aldehyde in the presence of a reducing agent to bind human growth hormone. Preferably, the alkoxy-PEG-aldehyde is methoxy-PEG-aldehyde and the reducing agent is NaCNBH ₃ . After the PEGylation reaction, SDS-PAGE can be used to determine whether PEG and human growth hormone are bound.

Then, in order to obtain a mono-PEG-human growth hormone conjugate, a cation exchange chromatography was first used to separate the mono-PEG-human growth hormone conjugate and its equivalent apparent charge at the amino terminus by the difference in the apparent charge. Serve

The cation exchange chromatography separated above separates the mono-PEG-human growth hormone conjugate from the poly-PEG-human growth hormone conjugate using size exclusion chromatography.

To determine whether PEG specifically binds to the amino terminus of human growth hormone in mono-PEG-human growth hormone conjugates, peptide maps have already been prepared ( Journal of chromatography A , 808 , 121 (1998); Analytical Biochemistry , 122 , 348 (1982); and Biotechnology and Applied Biochemistry , 10 , 326 (1988)) to determine the position of PEG as compared to the peak pattern of peptide maps of human growth hormone. In other words, when PEG is bound, the HPLC peak pattern of the protein cleaved by the protease is different from that when unmodified human growth hormone is cleaved with the same protease. This difference is due to the binding of PEG to any one of the protease cleavage, and the difference in the peak pattern can confirm whether the PEG is bound and the binding position. Proteases may use trypsin, subtilisin or endoproteinase Glu-C, with trypsin being preferred.

In order to determine the biological activity of the mono-PEG-human growth hormones described herein, several studies have already been made (Baldwin et al., Acta Endocrinologica. , 119 , 326 (1988); Clark et al., J. Biol. Chem. , 271 (36) , 21969 (1996); and Bozzola et al., J. endocrinol. Invest. , 21 , 768 (1998). For example, a cell proliferation assay with an Nb2 cell line may be used to measure activity in vitro, or through weight gain testing with rats to see if the activity is sustained in vivo compared to unmodified human growth hormone. You can see that it lasts.

Hereinafter, the present invention will be described in detail with reference to the following examples, but the following examples are not intended to limit the scope of the present invention only by exemplifying the present invention in detail.

Example 1 Preparation of Recombinant Human Growth Hormone

Recombinant human growth hormone was prepared according to the method of Korean Patent No. 316347, which the inventors have already obtained a patent from the Korean Patent Office. Human growth hormone used in the present invention is in its native form.

Example 2: Preparation of human growth hormone conjugates PEGylated at the amino terminus

Four activated methoxy-s having an average molecular weight of 10, 20, 30, and 40 kDa of average molecular weight were prepared by adding 3 mg of human growth hormone to a final volume of 5 ml in 100 mM potassium phosphate buffer solution (pH 6.0). PEG-aldehyde (Shearwater, USA) was added to the solution so that the molar ratio of human growth hormone: methoxy-PEG-aldehyde was 1: 4. The reaction solution was added with NaCNBH ₃ (Sigma, USA) as a reducing agent to a final 20 mM, and then reacted with gentle stirring at 4 ° C. for 18 hours. Ethanolamine was added to a final concentration of 50 mM to inactivate PEG that did not respond to human growth hormone.

Sephadex G-25 column (Pharmacia) was used to separate unreacted PEG. The column was first equilibrated with 2 CV (column volume) of 10 mM Tris-HCl (pH 7.5) buffer solution and then the reaction mixture was dropped. When detected by an ultraviolet absorber with a wavelength of 260 nm and eluted with the same buffer solution, human growth hormone modified with larger PEG was eluted first, and unreacted PEG was eluted later.

Example 3: Isolation of Mono-PEG-Human Growth Hormone Conjugate at the Amino Terminal

In order to purify and purify human growth hormone modified with PEG from the elution solution obtained in Example 2, the following was performed. 3 ml of PolyWAX LP (PolyWAX LP, Polywax Inc., USA) column was equilibrated with 10 mM Tris-HCl, pH 7.5 buffer solution. The PEGylated reaction mixture was loaded onto the column at a flow rate of 1 mL / min and then washed with 5 CV, ie 15 mL of equilibration buffer solution. Elution with 10 CV (30 mL) 1 M NaCl buffer solution in tri-, di-, mono-PEG-human growth hormone sequence, using salt concentration gradient method with automatic concentration gradient method from 0 to 100% for 30 minutes. I was.

Size exclusion chromatography was performed with the mono-PEG-human growth hormone conjugate elution fraction obtained above to separate the more pure mono-PEG human growth hormone. The eluate was concentrated and dropped into Superdex 200 (Superdex 200, Pharmacia) equilibrated with 10 mM sodium phosphate buffer solution (pH 7.0) and eluted with the same buffer solution. The flow rate was flowed at 1 ml / min. Since tri-, di-PEG-human growth hormone has a relatively higher elution time than mono-PEG-human growth hormone, it was removed to obtain only pure mono-PEG-human growth hormone.

Concentration and purity of mono-PEG-human growth hormone conjugates were measured using Coomassie-stained SDS-PAGE gel and size exclusion chromatography (high pressure liquid chromatography), and Beer-Lambert Protein concentration was measured at 280 nm according to the law (Bollag et al., Protein Methods Chapter 3, press in Wiley-Liss). The apparent molecular weights of each of the 10 kDa, 20 kDa, 30 kDa and 40 kDa mono-PEG-human growth hormone conjugates were about 40 kDa, 62 kDa, 80 kDa and 150 kDa.

1 is a SDS-PAGE gel photograph of 10 kDa, 20 kDa, 30 kDa and 40 kDa mono-PEG-human growth hormone conjugates. As a gel, a 15% cryterion gel purchased from Bio-Rad was used. Lane 1 is 3.0 μg of molecular weight standard protein (Invitron's benchmark, 40, 50, 60, 70, 80, 90, 100, 120, 160, and 220 kDa from the bottom band), lanes 2 to 5 are 10 kDa, 20, respectively. 10 μg of kDa, 30 kDa and 40 kDa mono-PEGylated human growth hormone conjugates. As can be seen in each lane, the larger the size of the PEG modified for human growth hormone, the shorter the distance on the gel, and a single band without proteins other than the mono-PEG-human growth hormone shows a single band. It was confirmed that it is high purity.

Figure 2 shows the results of size exclusion chromatogram analysis of each sample. The HPLC column (Hewlett-Packard HP1101) was used to equilibrate the analytical column (Biocept SEC-S3000, Pinomedex) with a buffer solution consisting of a mixture of 100 mM sodium phosphate (pH 6.9) and 20% ethanol, and then the same buffer solution The absorbance signal was monitored at 214 nm flowing at a rate of 0.6 ml / min. The retention times of unmodified human growth hormone, 10 kDa, 20 kDa, 30 kDa and 40 kDa mono-PEG-human growth hormone were 9.79, 8.45, 7.61, 7.08, 6.08 and 6.59 minutes, respectively. As it grew, it eluted quickly. In addition, the peaks containing human growth hormone modified with each PEG have a single peak, which confirms that the isolated fractions of PEG-human growth hormone have significant purity.

Example 4: Peptide Mapping

In order to confirm that the PEG binding site of the mono-PEG-human growth hormone conjugate prepared in Example 3 is the amino terminus, peptide maps of the unmodified human growth hormone and the 30 kDa mono-PEGylated human growth hormone conjugate were prepared and compared to the peaks. It was. The peaks of peptide maps of human growth hormone have already been described in detail in the literature (see Journal of chromatography A , 808 , 121 (1998); Analytical Biochemistry , 122 , 348 (1982); and Biotechnology and Applied Biochemistry , 10). , 326 (1988). The 30 kDa mono-PEG-human growth hormone and the unmodified human growth hormone prepared in the above examples were prepared such that the concentration in the 0.5M Tris-HCl pH 7.0 buffer solution was 2 mg / ml. 30 μl of 1 mg / ml trypsin (Roche, Switzerland) in the buffer solution as described above was mixed with 1 ml of each of the growth hormone solutions and reacted for 4 hours in a 37 ° C. thermostat to cleave each protein. Protein cleavage was injected into a Vydac 218TP C4 column (4.6 × 250 mm, 5 μm particle size, 300 mm pore size). Peptide mapping was by HPLC using acetonitrile linear slope in 0.1% trifluoroacetic acid.

Since human growth hormone has 20 sites that can be cleaved in trypsin, theoretically 21 peaks may be formed, but cleavage by trypsin does not actually occur at all sites, and all peaks are not formed due to differences in column resolution. Do not. However, peaks containing amino termini are well defined in the literature ( Journal of Pharmaceutical & Biomedical Analysis , 7 (2), 173 (1989)), which may confirm the difference.

As shown in FIG. 3, it can be seen that the peak (T1) eluting at about 24 minutes on the peptide map of the unmodified human growth hormone does not exist in the peptide map of the mono-PEG-human growth hormone conjugate. The T1 peak is the peak corresponding to the amino terminus of human growth hormone, which is due to the change in the elution time of the peak as the sample passes through the column, indicating that PEG molecules bound to the amino terminus of human growth hormone.

Experimental Example 1: In Vitro Activity Measurement

In vitro activity measurements of amino-terminated mono-PEG-human growth hormone were measured in Nb2 (ECACC) cells (ECACC), a rat node lymphoma cell line that is a human growth hormone-dependent mitosis cell. ECACC # 97041101) was used for in vitro analysis. To cultivate the cells to be used for analysis, 10% fetal bovine serum (FBS), 0.075% NaCO ₃ , 0.05 mM 2-mercapnoethanol and 2 mM glutamine were added to Fischer`s medium. After incubation, the cells were re-incubated for 24 hours in the same culture except 10% fetal bovine serum for analysis. After counting the number of cells cultured in the assay culture solution, about 20,000 cells were put in each well of a 96 well plate, and the human growth hormone mono-PEGylated at each amino terminal isolated in Example 3, an international standard (control) National Institute for Biological Standards and Control (NIBSC) and unmodified human growth hormone (HM-hGH) were each diluted and added to each concentration, followed by incubation in a 37 ° C., CO ₂ incubator for 48 hours. Afterwards, 25 μl of cell titer 96 Aqueous One Solution (promega, USA), which is a cell dye, was added to each well to measure the growth of cells (the number of cells in each well), followed by incubation for 4 hours. Thereafter, the absorbance was measured at 490 nm to calculate the titer of each sample. 4 shows the results of in vitro activity experiments. As can be seen in Figure 4 all the samples used in the test was shown to promote the growth of human growth hormone-sensitive cells, all were found to be active.

As shown in Table 1 below, human growth hormone modified by PEG can be confirmed that its activity is lower than that of unmodified. In particular, it can be seen that the activity of the modified PEG decreases gradually, and the PEG of 30K has about 9.8% of the activity of the unmodified human growth hormone.

Concentration (ng / ml) ED ₅₀ Specific activity (U / mg) % Relative activity on unmodified hGH Unmodified hGH 100 0.171 5.85E + 06 - NIBSC 100 0.130 5.02E + 06 88.9 10kDa mono-PEG-hGH 100 0.75 1.33E + 06 22.7 20kDa Mono-PEG-hGH 100 1.453 6.88 11.8 30kDa Mono-PEG-hGH 100 1.739 5.75 9.8 40kDa Mono-PEG-hGH 100 2.150 4.65E + 05 7.8

Experimental Example 2: In vivo Activity Measurement

In vivo activity of amino-terminated PEG-human growth hormone conjugates was measured by weight gain test using 5-week-old male rats (hypsectomized Sprague Dawley rat, SLC, Japan). Solvent control, unmodified human growth hormone, and each PEG-human growth hormone conjugate were administered in a 26G syringe (1 ml, Korea vaccine) under the subcutaneous portion of the rat at the dosages and doses shown in Table 1 below. Body weights were measured before and 16 hours after administration and visually examined for remaining pituitary gland after death by ether anesthesia 24 hours after the final administration.

group Medication gender The number of animals Dosage Dosing method One Solvent control M 5 PBS (0.5 ml) Once / day, 4 days 2 Standard product hGH (S1) M 5 240 mIU (120 μg / time) Single dose 3 Standard product hGH (S2) M 5 60 mIU (30 μg / time) Once / day, 4 days 4 10kDa mono-PEG-hGH M 5 240 mIU (120 μg / time) Single dose 5 20kDa Mono-PEG-hGH M 5 240 mIU (120 μg / time) Single dose 6 30kDa Mono-PEG-hGH M 5 240 mIU (120 μg / time) Single dose 7 40kDa Mono-PEG-hGH M 5 240 mIU (120 μg / time) Single dose

The results of weight increase and decrease after administration of each sample are shown in FIG. 5. The unmodified human growth hormone used as a standard, when administered only once (S1), showed a slight increase in body weight for one day after administration, but there was no continuous activity, but the unmodified standard was administered once daily for four days. When (S2), weight gain was observed during the administration period. These results indicate that unmodified human growth hormone should be administered daily in order to have continuous in vivo activity. One dose of the PEG-human growth hormone conjugate was found to increase weight continuously until three days after administration and slowed down after three days. In addition, it can be seen that the larger the size of the PEG modified in human growth hormone, the greater the increase in weight. These results indicate that binding of a single PEG molecule can sustain the protein's activity in vivo and dramatically change the therapeutic aspects of the protein.

The PEG-human growth hormone conjugate according to the present invention is one molecule of polyethylene glycol bound to the amino terminus of human growth hormone or an analog thereof, and exhibits effects such as increased residence time and reduced antigenicity in vivo, and also has biological activity. Can be maintained at a high level.

Claims (5)

PEG-human growth hormone conjugate wherein only one molecule of polyethylene glycol (PEG) is bound to the amino terminus of a human growth hormone or analogue thereof. The method of claim 1, A conjugate wherein the amino terminus of the amino terminus is phenylalanine. The method of claim 2, A conjugate characterized by the binding of PEG to the α-amino group of an amino acid which is the amino terminus of human growth hormone. The method according to any one of claims 1 to 3, And the PEG has a molecular weight of 2 kDa to 100 kDa. The method of claim 4, wherein And the PEG has a molecular weight of 10 kDa to 40 kDa.