Rationally designed anti-HER2/neu peptide mimetic disables P185HER2/neu tyrosine kinases in vitro and in vivo

Monoclonal antibodies specific for the p185HER2/neu growth factor receptor represent a significant advance in receptor-based therapy for p185HER2/neu-expressing human cancers. We have used a structure-based approach to develop a small (1.5 kDa) exocyclic anti-HER2/neu peptide mimic (AHNP) functionally similar to an anti-p185HER2/neu monoclonal antibody, 4D5 (Herceptin). The AHNP mimetic specifically binds to p185HER2/neu with high affinity (KD=300 nM). This results in inhibition of proliferation of p185HER2/neu-overexpressing tumor cells, and inhibition of colony formation in vitro and growth of p185HER2/neu-expressing tumors in athymic mice. In addition, the mimetic sensitizes the tumor cells to apoptosis when used in conjunction with ionizing radiation or chemotherapeutic agents. A comparison of the molar quantities of the Herceptin antibody and the AHNP mimetic required for inhibiting cell growth and anchorage-independent growth showed generally similar activities. The structure-based derivation of the AHNP represents a novel strategy for the design of receptor-specific tumor therapies.     

Direct detection of herceptin/trastuzumab binding on breast tissue sections.

The protooncogene product HER-2/neu is the target of the humanized monoclonal antibody trastuzumab (Herceptin). Several tests are used clinically to identify patients with HER-2/neu overexpression based on evaluation by pathologists of gene amplification by fluorescence in situ hybridization or protein expression using immunohistochemistry (IHC). A simple technique has been developed for staining formalin-fixed, paraffin-embedded breast cancer tissue using unmodified Herceptin/trastuzumab as the primary antibody. Results were compared with staining with the commercial kit, HercepTest, as well as with polyclonal anti-HER-2/neu antibodies and with biotinylated trastuzumab. These procedures were tested using four breast cancer microarrays. There were 854 cores that were stained with all four antibodies, representing 325 cases. A standard 4-point scoring system (0-3) was used. A total of 156 cases (48%) were scored as 0 by all the methods used and 31 (9.5%) were positive (3+) by all methods. Of interest, three cases scored negative using polyclonal anti-HER-2/neu antibodies but were positive using unmodified trastuzumab. To clarify this discrepancy, whole sections of tumors were examined with both antibodies using double labeling. There were some tumors that demonstrated a mosaic pattern of staining with neighboring cells or groups of cells stained exclusively with one antibody or the other. These results demonstrate that unmodified humanized or human therapeutic antibodies could be used for preclinical testing or in a clinical laboratory setting for IHC-based selection of patients for treatment, and results of such selection could be different from those obtained using polyclonal antibody-based IHC procedure.     

A high-throughput hybridoma selection method using fluorometric microvolume assay technology

Monoclonal antibodies (mAb) are not only useful reagents but also represent a promising type of therapeutics due to their high affinity and exquisite specificity for their antigens. A critical step in mAb generation is to identify antigen-specific antibodies. Although enzyme-linked immunosorbent assay (ELISA) has been broadly applied for antibody selection against secreted antigens, an inherent disadvantage for ELISA is the difficulty in identifying antibodies that recognize the native conformation of cell surface antigens. To overcome this drawback, the authors have developed a high-throughput cell-based antibody binding assay using fluorometric microvolume assay technology (FMAT). This method offers a homogeneous assay for detection of antibody binding to its antigen on the cell surface. To distinguish antibodies that bind to antigen on the cell surface from those that bind nonspecifically to cells, the binding is assessed using both antigen-expressing cells and related cells devoid of the antigen expression. This assay can detect antibodies at a concentration as low as 5 ng/mL and cell surface antigen as low as 9000 copies per cell. Results demonstrate that the FMAT method provides a sensitive and homogeneous assay to detect antibody binding to cell surface antigens and is amenable for high-throughput hybridoma selection.     

Quantitative analysis of glycation and its impact on antigen binding

Glycation has been observed in antibody therapeutics manufactured by the fed-batch fermentation process. It not only increases the heterogeneity of antibodies, but also potentially affects product safety and efficacy. In this study, non-glycated and glycated fractions enriched from a monoclonal antibody (mAb1) as well as glucose-stressed mAb1 were characterized using a variety of biochemical, biophysical and biological assays to determine the effects of glycation on the structure and function of mAb1. Glycation was detected at multiple lysine residues and reduced the antigen binding activity of mAb1. Heavy chain Lys100, which is located in the complementary-determining region of mAb1, had the highest levels of glycation in both stressed and unstressed samples, and glycation of this residue was likely responsible for the loss of antigen binding based on hydrogen/deuterium exchange mass spectrometry analysis. Peptide mapping and intact liquid chromatography-mass spectrometry (LC-MS) can both be used to monitor the glycation levels. Peptide mapping provides site specific glycation results, while intact LC-MS is a quicker and simpler method to quantitate the total glycation levels and is more useful for routine testing. Capillary isoelectric focusing (cIEF) can also be used to monitor glycation because glycation induces an acidic shift in the cIEF profile. As expected, total glycation measured by intact LC-MS correlated very well with the percentage of total acidic peaks or main peak measured by cIEF. In summary, we demonstrated that glycation can affect the function of a representative IgG1 mAb. The analytical characterization, as described here, should be generally applicable for other therapeutic mAbs.     

Kinetic analysis of a monoclonal therapeutic antibody and its single-chain homolog by surface plasmon resonance

Monoclonal antibodies (mAbs) and antibody fragments have become an emerging class of therapeutics since 1986. Their versatility enables them to be engineered for optimal efficiency and decreased immunogenicity, and the path to market has been set by recent regulatory approvals. One of the initial criteria for success of any protein or antibody therapeutic is to understand its binding characteristics to the target antigen. Surface plasmon resonance (SPR) has been widely used and is an important tool for ligand-antigen binding characterization. In this work, the binding kinetics of a recombinant mAb and its single-chain antibody homolog, single-chain variable fragment (scFv), was analyzed by SPR. These two proteins target the same antigen. The binding kinetics of the mAb (bivalent antibody) and scFv (monovalent scFv) for this antigen was analyzed along with an assessment of the thermodynamics of the binding interactions. Alternative binding configurations were investigated to evaluate potential experimental bias because theoretically experimental binding configuration should have no impact on binding kinetics. Self-association binding kinetics in the proteins’ respective formulation solutions and antigen epitope mapping were also evaluated. Functional characterization of monoclonal and single-chain antibodies has become just as important as structural characterization in the biotechnology field.     

Monoclonal antibodies directed against human FcRn and their applications

The MHC class I-like Fc receptor (FcRn) is an intracellular trafficking Fc receptor that is uniquely responsible for the extended serum half-life of antibodies of the IgG subclass and their ability to transport across cellular barriers. By performing these functions, FcRn affects numerous facets of antibody biology and pathobiology. Its critical role in controlling IgG pharmacokinetics has been leveraged for the design of therapeutic antibodies and related biologics. FcRn also traffics serum albumin and is responsible for the enhanced pharmacokinetic properties of albumin-conjugated therapeutics. The understanding of FcRn and its therapeutic applications has been limited by a paucity of reliable serological reagents against human FcRn. Here, we describe the properties of a new panel of highly specific monoclonal antibodies (mAbs) directed against human FcRn with diverse epitope specificities. We show that this antibody panel can be used to study the tissue expression pattern of human FcRn, to selectively block IgG and serum albumin binding to human FcRn in vitro and to inhibit FcRn function in vivo. This mAb panel provides a powerful resource for probing the biology of human FcRn and for the evaluation of therapeutic FcRn blockade strategies.Key words: FcRn, IgG, monoclonal antibody, albumin, therapy     

Cellular Uptake of α-Synuclein Oligomer-Selective Antibodies is Enhanced by the Extracellular Presence of α-Synuclein and Mediated via Fcγ Receptors

Immunotherapy targeting aggregated α-synuclein has emerged as a potential treatment strategy against Parkinson’s disease and other α-synucleinopathies. We have developed α-synuclein oligomer/protofibril selective antibodies that reduce toxic α-synuclein in a human cell line and, upon intraperitoneal administration, in spinal cord of transgenic mice. Here, we investigated under which conditions and by which mechanisms such antibodies can be internalized by cells. For this purpose, human neuroglioma H4 cells were treated with either monoclonal oligomer/protofibril selective α-synuclein antibodies, linear epitope monoclonal α-synuclein antibodies, or with a control antibody. The oligomer/protofibril selective antibody mAb47 displayed the highest cellular uptake and was therefore chosen for additional analyses. Next, α-synuclein overexpressing cells were incubated with mAb47, which resulted in increased antibody internalization as compared to non-transfected cells. Similarly, regular cells exposed to mAb47 together with media containing α-synuclein displayed a higher uptake as compared to cells incubated with regular media. Finally, different Fcγ receptors were targeted and we then found that blockage of FcγRI and FcγRIIB/C resulted in reduced antibody internalization. Our data thus indicate that the robust uptake of the oligomer/protofibril selective antibody mAb47 by human CNS-derived cells is enhanced by extracellular α-synuclein and mediated via Fcγ receptors. Altogether, our finding lend further support to the belief that α-synuclein pathology can be modified by monoclonal antibodies and that these can target toxic α-synuclein species in the extracellular milieu. In the context of immunotherapy, antibody binding of α-synuclein would then not only block further aggregation but also mediate internalization and subsequent degradation of antigen–antibody complexes.     

Design of humanized antibodies: from anti-Tac to Zenapax

Since the introduction of hybridoma technology, monoclonal antibodies have become one of the most important tools in the biosciences, finding diverse applications including their use in the therapy of human disease. Initial attempts to use monoclonal antibodies as therapeutics were hampered, however, by the potent immunogenicity of mouse (and other rodent) antibodies in humans. Humanization technology has made it possible to remove the immunogenicity associated with the use of rodent antibodies, or at least to reduce it to an acceptable level for clinical use in humans, thus facilitating the application of monoclonal antibodies to the treatment of human disease. To date, nine humanized monoclonal antibodies have been approved for use as human therapeutics in the United States. In this paper, we describe procedures for antibody humanization with an emphasis on strategies for designing humanized antibodies with the aid of computer-guided modeling of antibody variable domains, using as an example the humanized anti-CD25 monoclonal antibody, Zenapax.     

单克隆抗体在抗病毒感染中的研究进展

单克隆抗体(monoclonal antibody, m Ab),指同一种抗原决定簇的细胞克隆所产生的均一性抗体。m Ab已成功应用以诊疗各种疾病,尤其是癌症和免疫性疾病。近些年来,m Ab逐渐用于治疗病毒性疾病,针对急性和慢性病毒感染研发的抗病毒m Ab数量逐渐增长。m Ab的组合疗法可同时靶向病毒多个表位,从而克服病毒免疫逃逸的问题,多价m Ab的设计开发能够更加有效的作用于病毒。本文比较了不同m Ab制备方法的优缺点,总结了m Ab近期在抗病毒感染领域的研究进展,并讨论了m Ab作为治疗病毒性疾病药物的前景。     

Phage antibody display libraries: a powerful antibody discovery platform for immunotherapy

Phage display technology (PDT), a combinatorial screening approach, provides a molecular diversity tool for creating libraries of peptides/proteins and discovery of new recombinant therapeutics. Expression of proteins such as monoclonal antibodies (mAbs) on the surface of filamentous phage can permit the selection of high affinity and specificity therapeutic mAbs against virtually any target antigen. Using a number of diverse selection platforms (e.g. solid phase, solution phase, whole cell and in vivo biopannings), phage antibody libraries (PALs) from the start point provides great potential for the isolation of functional mAb fragments with diagnostic and/or therapeutic purposes. Given the pivotal role of PDT in the discovery of novel therapeutic/diagnostic mAbs, in the current review, we provide an overview on PALs and discuss their impact in the advancement of engineered mAbs.     

A monoclonal antibody against peripheral benzodiazepine receptor activities the human neutrophil NADPH-oxidase.

A murine monoclonal antibody, mAb 8523, raised against whole human pro-monocytic U937 cells recognizes an 18 kDa antigen in human neutrophils (PMN), as determined by immunoprecipitation and by immunodetection on Western blots of SDS-PAGE of PMN membrane fractions. That is 18 kDa antigen corresponds to the phagocyte peripheral benzodiazepine receptor (PBZDR) is evidenced by its co-migration with the 18 kDa covalently labeled PBZDR, detected by autoradiography, and their co-modulation upon phorbol-myristate-acetate activation of PMN. Purified mAb 8523 (IgG2b) is able to dose-dependently and specifically stimulate both the basal and the FMLP-induced oxidative burst of intact human PMN, assessed by luminol-amplified chemiluminescence. This property of the first described monoclonal antibody against PBZDR supports the implication of this receptor in NADPH-oxidase activation and consequently in phagocyte-dependent host defense mechanisms.     

Engineering the variable region of therapeutic IgG antibodies

Since the first generation of humanized IgG1 antibodies reached the market in the late 1990s, IgG antibody molecules have been extensively engineered. The success of antibody therapeutics has introduced severe competition in developing novel therapeutic monoclonal antibodies, especially for promising or clinically validated targets. Such competition has led researchers to generate so-called second or third generation antibodies with clinical differentiation utilizing various engineering and optimization technologies. Parent IgG antibodies can be engineered to have improved antigen binding properties, effector functions, pharmacokinetics, pharmaceutical properties and safety issues. Although the primary role of the antibody variable region is to bind to the antigen, it is also the main source of antibody diversity and its sequence affects various properties important for developing antibody therapeutics. Here we review recent research activity in variable region engineering to generate superior antibody therapeutics.Key words: antibody therapeutics, variable region, engineering, affinity, pharmacokinetics, stability, immunogenicity     

Mapping of functional epitopes of osteopontin by monoclonal antibodies raised against defined internal sequences.

Osteopontin (OPN) is a secreted protein that has been implicated in diverse physiological and pathological processes. OPN can bind to integrins, via GRGDS or SVVYGLR amino acid sequences, and to other cell surface receptors, and many of OPN's functions are likely mediated via cell adhesion and subsequent signaling. Here we developed and characterized a series of five monoclonal antibodies, raised to distinct internal peptide sequences of human OPN, and have used these sequence-specific reagents, along with the previously described anti-OPN monoclonal antibody mAb53, to map functional epitopes of OPN that are important to cell adhesion and migration. All antibodies were reactive with native as well as recombinant human OPN. One antibody (2K1) raised against the peptide VDTYDGRGDSVVYGLRS could inhibit RGD-dependent cell binding to OPN, with an efficacy comparable to that of mAb53. Furthermore, 2K1 could inhibit alpha9 integrin-dependent cell binding to OPN. The epitope recognized by 2K1 was not destroyed by thrombin digestion, whereas mAb53 has been shown to be unable to react with OPN following thrombin cleavage. The two distinct epitopes defined by 2K1 and mAb53 antibodies are closely related to the SVVYGLR cell-binding domain and the GLRSKS containing thrombin cleavage site, respectively, and are involved in cell binding and cell migration.     

人生长分化因子15单克隆抗体制备、鉴定及药用价值初探

目的:制备稳定分泌抗人生长分化因子15(GDF15)单克隆抗体(m Ab)的杂交瘤细胞系,并对其分泌的m Ab进行鉴定。方法:根据人GDF15氨基酸序列特征,设计合成了8条能够免疫产生GDF15特异性抗体的抗原多肽,与VLP载体偶联后,免疫雌性BALB/c小鼠,利用杂交瘤技术制备鼠源抗人GDF15的m Ab,用间接ELISA检测m Ab腹水效价。结果:获得针对7个抗原多肽的12株稳定分泌抗人GDF15的杂交瘤细胞系,腹水m Ab效价可达1×104~1×109。结论:获得了针对不同抗原多肽的抗人GDF15的特异性m Ab,为进一步研发以GDF15为靶点的单克隆抗体抗肿瘤药物奠定了基础。     

单克隆抗体及其抗感染作用的研究进展

骨髓瘤细胞和单个B细胞可融合形成杂交瘤细胞,这种细胞分离并克隆后可产生针对单一表位,且结构和功能相同的抗体,即单克隆抗体(monoclonal antibody, mAb)。单克隆抗体发展历程经历了四个阶段。其制备技术也在不断革新与发展。目前单克隆抗体技术发展日益成熟,在疾病治疗与诊断中发挥着关键的作用。单克隆抗体与天然抗体不同,具有效价高、特异性强、交叉反应少、可大量制备,靶向性高等特点。mAb可用于诊断及治疗感染性疾病、自身免疫病以及癌症等。对mAb的发展历程及mAb在抗感染性疾病中的应用进行简要阐述。     

Syngeneic monoclonal anti-idiotype antibodies that bear the internal image of a human cytomegalovirus neutralization epitope

Two glycoproteins have been identified on human CMV that induce neutralizing antibody; an 86,000-Da glycoprotein and a 130,000-, 92,000-, and 50,000-Da glycoprotein coimmunoprecipitating complex that appears to be the gB homologue of HSV. We have produced syngeneic monoclonal anti-Id antibodies (mAb2) of the IgM isotype to a CMV-neutralizing monoclonal antibody (mAb1) that is known to bind to the 86,000-Da glycoprotein on the virion envelope. These mAb2 bear the internal image of the original viral antigen as shown by their ability to 1) recognize an interspecies idiotype in CMV-positive human antisera, 2) block mAb1 binding to CMV antigen, and 3) block CMV neutralization by mAb1 in vitro. Immunization of mice with both of these affinity chromatography-purified mAb2 stimulated the production of anti-anti-Id monoclonal antibodies (which we termed mAb3), which bound to the mAb2 by ELISA and neutralized CMV infectivity.     

Engineering the variable region of therapeutic IgG antibodies

Since the first generation of humanized IgG1 antibodies reached the market in the late 1990s, IgG antibody molecules have been extensively engineered. The success of antibody therapeutics has introduced severe competition in developing novel therapeutic monoclonal antibodies, especially for promising or clinically validated targets. Such competition has led researchers to generate so-called second or third generation antibodies with clinical differentiation utilizing various engineering and optimization technologies. Parent IgG antibodies can be engineered to have improved antigen binding properties, effector functions, pharmacokinetics, pharmaceutical properties and safety issues. Although the primary role of the antibody variable region is to bind to the antigen, it is also the main source of antibody diversity and its sequence affects various properties important for developing antibody therapeutics. Here we review recent research activity in variable region engineering to generate superior antibody therapeutics.     

Monoclonal antibodies to human tumor necrosis factor alpha: in vitro and in vivo application.

Three stable murine hybridoma cell lines, which secrete monoclonal antibodies (mAb) to human tumor necrosis factor alpha (TNF alpha), were established. None of the monoclonal antibodies cross-reacted with lymphotoxin, interleukin 2 (IL 2) or Interferon gamma (IFN gamma). The highly species-specific monoclonal antibody, designated as mAb 195, neutralizes the cytotoxic activity of human and chimpanzee TNF alpha. This antibody was further used during in vivo studies to neutralize human TNF alpha in a murine animal model. The mAb 114 is a weakly neutralizing antibody that binds to a different epitope of TNF alpha than mAb 195. mAb 114 shows a wide range of cross-reactivity with TNF alpha of the following species: dog, pig, cynomolgus, rhesus, baboon and chimpanzee. The mAb 199 binds to human TNF alpha, but does not neutralize the cytotoxic activity. The epitope recognized by this mAb is in close proximity to mAb 114. A reproducible, sensitive immunoassay for human TNF7 alpha has been developed using the antibodies mAb 199 and mAb 195. The test is performed within 6 hr and detects TNF7 alpha in serum samples, with a limit of detection of 5 to 10 pg/mL.     

Expression, Purification, and In Vivo Administration of a Promising Anti-Idiotypic HIV-1 Vaccine

To date only a few neutralizing antibodies against HIV-1 exist. Since these neutralizing antibodies are only rarely found in sera of HIV-1 infected individuals an active vaccine is required. We recently developed murine anti-idiotypic antibody Ab2/3H6 against monoclonal antibody (mAb) 2F5, which is one of the most prominent neutralizing antibodies. Anti-idiotypic antibody Ab2/3H6 has been partially humanized and expressed as whole immunoglobulin G in Chinese hamster ovary cells in order to minimize the human anti-mouse antibody response. Here we describe the expression, purification, and immunohistochemical characterization of the chimeric Ab2/3H6 Fab fragment, which was finally used beside the whole IgG1 as an antigen for immunization of guinea pigs. The crude sera were screened for specific antibodies against the epitope of mAb 2F5 ELDKWA as well as for reactivity against HIV-1 gp41.     

Epitope mapping and structural analysis of an anti-ErbB2 antibody A21: Molecular basis for tumor inhibitory mechanism

Anti-ErbB2 antibodies targeting distinct epitopes can have different biological functions on cancer cells. A21 prepared by surface epitope masking (SEM) method is a tumor-inhibitory anti-ErbB2 monoclonal antibody. Previously we engineered a single chain chimeric antibody chA21 with potential for therapy of ErbB2-overexpressing tumors. Here, we mapped the A21 epitope on ErbB2 extracellular domain (ECD) by screening a combinatorial phage display peptide library, serial subdomain deletion, and mutagenesis scanning. X-ray crystal structure of the A21 scFv fragment at 2.1 A resolution was also determined. A molecular model of Ag-Ab complex was then constructed based on the crystal structures of the A21 scFv and ErbB2 ECD. Some of biological functions of the A21 mAb and its derivative antibodies including their tumor cell growth inhibition and effects on the expression, internalization, and phosphorylation of ErbB2 receptor were also investigated. The results showed that A21 recognized a conformational epitope comprising a large region mostly from ErbB2 extracellular subdomain I with several surface-exposed residues important for the binding affinity. These data provide unique functional properties of A21 that are quite different from two broadly used anti-ErbB2 mAbs, Herceptin and 2C4. It suggested that the A21 epitope may be another valuable target for designing new anti-ErbB2 therapeutics.