PEGylation of therapeutic proteins

Since the first PEGylated product was approved by the Food and Drug Administration in 1990, PEGylation has been widely used as a post-production modification methodology for improving biomedical efficacy and physicochemical properties of therapeutic proteins. Applicability and safety of this technology have been proven by use of various PEGylated pharmaceuticals for many years. It is expected that PEGylation, as the most established technology for extension of drug residence in the body, will play an important role in the next generation therapeutics, such as peptides, protein nanobodies and scaffolds, which due to their diminished molecular size need half-life extension. This review focuses on several factors important in the production of PEGylated biopharmaceuticals enabling efficient preparation of highly purified PEG-protein conjugates that have to meet stringent regulatory criteria for their use in human therapy. Areas addressed are PEG properties, the specificity of PEGylation reactions, separation and large-scale purification, the availability and analysis of PEG reagents, analysis of PEG-protein conjugates, the consistency of products and processes and approaches used for rapid screening of pharmacokinetic properties of PEG-protein conjugates.     

Interaction mechanism of mono-PEGylated proteins in electrostatic interaction chromatography

The retention and binding mechanisms in electrostatic interaction-based chromatography (ion-exchange chromatography) of PEGylated proteins (covalent attachment of polyethylene glycol chains to protein) were investigated using our previously developed model. Lysozyme and bovine serum albumin were chosen as model proteins. The retention volume of PEGylated proteins shifted to lower elution volumes with increasing PEG molecular weight compared with the non-modified (native) protein retention volume. However, PEGylation did not affect the number of binding sites appreciably. The enzyme activity of PEGylated lysozyme measured with a standard insoluble substrate in suspension decreased considerably, whereas the activity with a soluble small-molecule substrate did not drop significantly. These findings indicate that when a protein is mono-PEG-ylated, the binding site is not affected and the elution volume reduces due to the steric hindrance between PEGylated protein and ion-exchange ligand.     

PEGylated leuprolide with improved pharmacokinetic properties

Leuprolide, a gonadotropin-releasing hormone (GnRH) agonist widely used in androgen deprivation therapy for the treatment of advanced prostate cancer, suffers from a short circulating half-life like other peptide therapeutics. As an attempt to improve its pharmacokinetic properties, two PEGylated leuprolides with different molecular weight were synthesized utilizing N-hydroxysuccinimidyl (NHS) conjugation chemistry. The reaction conditions, including reaction temperature, reaction time and feed ratio of the reactants, were optimized to obtain a higher yield. Reverse-phase high performance liquid chromatography (RP-HPLC) characterization indicates a high purity of the resulting conjugates. Matrix-assisted laser desorption mass spectrometry (MALDI-MS) characterization suggests a 1:1 PEGylation. ¹H NMR study reveals that the reaction occurs on the imidazolyl group on the histidine residue and the conjugates are stable in pH7.4 aqueous solutions. The in vitro bioactivity of the conjugates was evaluated using both hormone-sensitive and hormone-insensitive cell lines. It was found that the PEGylated peptides can still counteract the stimulatory action of androgens and the mitogenic action of epidermal growth factor on cell proliferation. The in vivo bioactivity of the conjugates was also tested. Like the unmodified peptide, administration of the conjugates to male rats leads to an initial testosterone surge, followed by a suppression of testosterone secretion. Pharmacokinetics of the drugs after i.v. and s.c. administrations were determined. In both cases, a prolonged circulating half-life, an increased AUC, and a decreased Cl_F were observed for the PEGylated drugs.     

Cardiovascular effects of a PEGylated apelin

Several studies have documented cardiovascular effects of apelin, including enhanced inotropy and vasodilation. However, these cardiovascular effects are short lived due to the predicted short circulating half-life of the apelin peptide. To address this limitation of apelin, we pursued N-terminal PEGylation of apelin and examined the cardiovascular effects of the PEGylated apelin. A 40 kDa PEG conjugated apelin-36 (PEG–apelin-36) was successfully produced with N-terminal conjugation, high purity (>98%) and minimum reduction of APJ receptor binding affinity. Using an adenylate cyclase inhibition assay, comparable in vitro bioactivity was observed between the PEG–apelin-36 and unmodified apelin-36. In vivo evaluation of the PEG–apelin-36 was performed in normal rats and rats with myocardial infarction (MI). Cardiac function was assessed via echocardiography before, during a 20 min IV infusion and up to 100 min post peptide infusion. Similar increases in cardiac ejection fraction (EF) were observed during the infusion of PEG–apelin-36 and apelin-36 in normal rats. However, animals that received PEG–apelin-36 maintained significantly increased EF over the 100 min post infusion monitoring period compared to the animals that received unmodified apelin-36. Interestingly, EF increases observed with PEG–apelin-36 and apelin-36 were greater in the MI rats. PEG–apelin-36 had a prolonged circulating life compared to apelin-36 in rats. There were no changes in aortic blood pressure when PEG–apelin-36 or apelin-36 was administered. To our knowledge this is the first report of apelin PEGylation and documentation of its cardiovascular effects.     

Biosynthesis,properties and potential of natural–synthetic hybrids of polyhydroxyalkanoates and polyethylene glycols

Chemical conjugation with poly(ethylene glycols) (PEGs) are established procedures to facilitate solubilisation of hydrophobic compounds. Such techniques for PEGylation have been applied to polyhydroxybutyrate. ‘BioPEGylation’ of such polyhydroxyalkanoates (PHAs) to form natural–synthetic hybrids has been demonstrated through the addition of PEGs to microbial cultivation systems. The strategic addition of certain PEGs not only supports hybrid synthesis but may also provide a technique for control of PHA composition and molecular mass, and by extension, their physico-mechanical properties. PHA composition and molecular mass control by PEGs is dependent upon the polyethers’ molecular mass, loading in the cultivation system, time of introduction and microbial species. Hybrid characterisation studies are in their infancy, but results to date suggest that PHA–PEG hybrids have subtle, but significant, differences in their physiochemical and material properties as a consequence of the PEGylation.     

Effect of oriented or random PEGylation on bioactivity of a factor VIII inhibitor blocking peptide

Peptides as therapeutic substances are efficient agents in the treatment of several diseases. However, they often have to be chemically modified in order to be suited as therapeutic agent. Conjugation to large carrier molecules is often required. A critical step is the identification of available sites for chemical reaction, without influencing bioactivity. Peptide 238/S1 with the sequence NH(2)-PYWKWQYKYD-COOH previously selected from a combinatorial decapeptide library, has the ability to block inhibitory antibodies against blood clotting factor VIII (FVIII) and therefore, it constitutes a lead for developing a drug to treat patients suffering from development of such antibodies. The aims of this study were (i) to identify sites of the peptide, which are suited for modification without losing bioactivity and (ii) to find out the influence of molecular size of polyethylene glycol (PEG) for bioactivity of the peptide. The contribution of each amino acid residue to biological functionality was investigated by mutational analysis. This method confirmed that the N-terminus is crucial for activity, whereas both lysine residues could be exchanged by other L-amino acids. Using mutational analysis it was possible to identify peptides with higher reactivity compared to the wild type 238/S1. PEGylation experiments demonstrated that conjugation of the peptide to PEG 20,000 resulted in a loss of reactivity, while PEG 5,000 could maintain the bioactivity when conjugated in a site directed manner. The peptide lost its neutralization properties when PEG was coupled to the N-terminus, again indicating that this part of the peptide is important for functionality.     

两步连续离子交换制备色谱分离纯化聚乙二醇化重组人粒细胞集落刺激因子

建立了两步连续离子交换制备色谱分离、纯化聚乙二醇与重组人粒细胞集落刺激因子 (Recombinanthumangranulocytestimulatingfactor,rhG_CSF)偶联物的方法。首先用阳离子交换色谱将偶联蛋白质和非偶联蛋白质分开 ,然后使用阴离子交换色谱去除过量的游离聚乙二醇杂质 ,并分离纯化偶联蛋白异构体分别得到单聚乙二醇化、双聚乙二醇化和三聚乙二醇化的rhG-CSF。它们经十二烷基磺酸钠_聚丙烯酰胺凝胶电泳 (SDS-PAGE)分析均为单带。采用基质辅助激光解吸离子化-飞行时间质谱(MALDI-TOF)分析三种偶联蛋白质的分子量 ,分别为 23.8kD、28.6kD、33.8kD。用噻唑蓝 (MTT)比色法 ,以粒细胞集落刺激因子的依赖细胞株NFS_6 0为靶细胞 ,测定重组人粒细胞集落刺激因子及其与聚乙二醇的偶联物的体外细胞生物学活性 ,单聚乙二醇化、双聚乙二醇化和三聚乙二醇化的rhG_CSF体外活性保留率分别为 92 %、75 %、4 3%。     

PEG修饰有效提高热休克蛋白gp96抑制性多肽抗乳腺癌的功能

乳腺癌是女性恶性肿瘤中发病率最高的肿瘤,严重威胁女性生命健康。其中三阴性乳腺癌因其特殊的生理学特点,成为乳腺癌中预后最差的亚型,因此急需寻找新的靶点进行治疗来提高患者预后及生存率。多项研究表明,热休克蛋白gp96在多种癌细胞的膜表面过表达,且胞膜gp96与乳腺癌的恶性程度与不良预后密切相关,因此其可能是乳腺癌治疗的新靶点。前期研究根据gp96的结构,开发一种靶向胞膜gp96 ATP结合区的α螺旋肽p37。虽然p37多肽作用位点专一,但其在体内容易被降解,因此本研究将多肽的N端或C端分别偶联PEG₂₀₀₀或PEG₅₀₀₀,得到4个具有抑瘤功能的PEG多肽：mPEG₂₀₀₀CY、mPEG₅₀₀₀CY、mPEG₂₀₀₀LC和mPEG₅₀₀₀LC。它们可以抑制乳腺癌细胞SK-BR-3的增殖和侵袭,其中抑制效果最明显的是mPEG₂₀₀₀CY。经测定,mPEG₂₀₀₀CY在体内的半衰期较多肽p37明显延长,且有效抑制三阴性乳腺癌MDA-MB-231小鼠移植瘤的生长。这为研发新型抗乳腺癌尤其是三阴性乳腺癌的靶向药物提供了依据。     

聚乙二醇修饰的成纤维细胞生长因子-21的降血糖作用

成纤维细胞生长因子-21(FGF-21)是FGF家族的一员．现有大量研究表明,FGF-21是除胰岛素以外的一种新的血糖调节因子,有望成为治疗2型糖尿病的新型药物．然而,FGF-21在动物体内稳定性较差,半衰期较短,严重影响了其在临床上的应用．为解决这些问题,本实验采用分子质量为20 ku的单甲氧基聚乙二醇-丙醛(mPEG-ALD)对鼠源FGF-21(mFGF-21)进行N端定点修饰,以改善mFGF-21的性质(如提高体内半衰期、降低免疫原性等)．本文研究了反应pH、反应时间、蛋白质浓度及反应物之间的质量比对mFGF-21与聚乙二醇(PEG)合成反应的影响．采用Capto Q阴离子交换层析或Superdex 75凝胶过滤层析分离纯化聚乙二醇化mFGF-21(PEG-mFGF-21),并最终确定了mFGF-21 聚乙二醇修饰的反应条件和分离PEG-mFGF-21的纯化工艺．随后分别进行了PEG-mFGF-21的理化性质(大小、纯度和体外稳定性)、免疫原性、体内半衰期、体外葡萄糖吸收活性及体内降糖活性的研究．体外稳定性实验结果显示,mFGF-21经PEG修饰后温度稳定性和抗蛋白酶水解稳定性都显著提高．间接ELISA方法检测血清中mFGF-21抗体水平及目标蛋白含量的结果表明,PEG修饰mFGF-21可明显降低其免疫原性,延长体内半衰期．HepG2细胞的葡萄糖吸收实验结果发现,PEG-mFGF-21的细胞活性并没有下降,反而随着刺激细胞时间的延长,经PEG-mFGF-21刺激的细胞葡萄糖吸收显著高于mFGF-21刺激的细胞葡萄糖吸收．2型糖尿病db/db小鼠短期血糖调控实验结果表明,mFGF-21降糖速度快于PEG-mFGF-21,但其持续时间较PEG-mFGF-21短;长期血糖调控实验结果显示,PEG-mFGF-21长期降糖效果优于mFGF-21,作用持续时间长,并且PEG-mFGF-21在停药后控制血糖的能力也高于mFGF-21．综上所述可知,mFGF-21的PEG修饰在不影响其体外生物活性的前提下,能够提高mFGF-21的物理稳定性和抵抗蛋白酶水解的能力、降低免疫原性、增加体内稳定性、延长mFGF-21在动物体内降血糖作用的效果和时间．本实验为FGF-21化学修饰提供了重要的技术平台,对以后FGF-21的临床应用具有非常重要的意义．     

Effects of chemical modifications in the partition behavior of proteins in aqueous two‐phase systems: A case study with RNase A

Chemical modification of proteins is gaining importance due to the improvement in properties and the broader range of applications that these protein conjugates have. Once modified, several purification strategies need to be applied to isolate the conjugates of interest. Aqueous two‐phase systems (ATPS) are an attractive alternative for the primary recovery of proteins and their conjugates. However, to better understand which biochemical parameters affect in greater degree the partition behavior of these modified proteins in ATPS, it becomes necessary to characterize the partition behavior of different species. In this work, ribonuclease A (RNase A) was selected as a model protein to address the partition behavior of chemically modified proteins in ATPS. Native, mono‐PEGylated, Uniblue A, Dabsyl Chloride, and Direct Red 83 chemically modified RNase A's were partitioned in 16 different polyethylene glycol (PEG)–potassium phosphate ATPS. Results suggest that while the effects of system design parameters govern the partition of native RNase A, the behavior of the chemically modified species is more influenced by the physicochemical characteristics of the modifying molecules, that in most cases promote partition toward the top polymer‐rich phase with recovery percentages as high as 86%. It has been found that both, the hydrophobicity and molecular weight of the modifying species play a preponderant role in conjugate partition behavior since as hydrophobicity increases partition is promoted towards the PEG‐rich phase balancing the effect of the molecular weight of the modifying molecules that tends to shift partition towards the salt rich phase. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29: 378–385, 2013