Humanization of an anti-CD34 monoclonal antibody by complementarity-determining region grafting based on computer-assisted molecular modelling

4C8 is a new mouse anti-human CD34 monoclonal antibody (mAb), which recognizes class II CD34 epitopes and can be used for clinical hematopoietic stem/progenitor cell selection. In an attempt to improve its safety profiles, we have developed a humanized antibody of 4C8 by complementarity-determining region (CDR) grafting method in this study. Using a molecular model of 4C8 built by computer-assisted homology modelling, framework region (FR) residues of potential importance to the antigen binding were identified. A humanized version of 4C8, denoted as h4C8, was generated by transferring these key murine FR residues onto a human antibody framework that was selected based on homology to the mouse antibody framework, together with the mouse CDR residues. The resultant humanized antibody was shown to possess antigen-binding affinity and specificity similar to that of the original murine antibody, suggesting that it might be an alternative to mouse anti-CD34 antibodies routinely used clinically.     

Construction and characterization of the chimeric antibody 8C11 to the hepatitis E virus

Homodimers of the truncated hepatitis E virus (HEV) capsid proteins, E2 and p239, were conformed to model the dominant antigenic determinants of HEV. Using E2 as an immunogen, two neutralizing monoclonal antibodies (mAbs), namely 8C11 and 8H3, were produced. We constructed a mouse-human chimeric antibody derived from 8C11 and its expression in Chinese hamster ovary (CHO) cells. cDNAs encoding variable regions of heavy and light chains were isolated from hybridoma cells and inserted into mammalian expression vectors containing cDNA of human gamma-1 and kappa constant regions, respectively. The vectors were then cotransfected into CHO cells, and a stable cell line was established. Results from indirect enzyme-linked immunosorbent assay (ELISA) and Western blot analysis showed that the chimeric antibody was assembled correctly to the native IgG molecule and could be secreted from the cells. Similar to the original mAb, the expressed chimeric antibody displayed HEV antigen-binding activity and an enhancement effect on 8H3 binding to HEV antigen. The chimeric antibody could specifically inhibit the binding of p239 to HepG2 cells and compete with HEV IgG in positive serum by antibody-competitive ELISA. The chimeric antibody is expected to be less immunogenic in human and more suitable for antibody therapy of hepatitis E.     

Chimeric and humanized antibodies with specificity for the CD33 antigen.

L and H chain cDNAs of M195, a murine mAb that binds to the CD33 Ag on normal and leukemic myeloid cells, were cloned. The cDNAs were used in the construction of mouse/human IgG1 and IgG3 chimeric antibodies. In addition, humanized antibodies were constructed which combined the complementarity-determining regions of the M195 antibody with human framework and constant regions. The human framework was chosen to maximize homology with the M195 V domain sequence. Moreover, a computer model of M195 was used to identify several framework amino acids that are likely to interact with the complementarity-determining regions, and these residues were also retained in the humanized antibodies. Unexpectedly, the humanized IgG1 and IgG3 M195 antibodies, which have reshaped V regions, have higher apparent binding affinity for the CD33 Ag than the chimeric or mouse antibodies.     

The design, construction and function of a new chimeric anti-CD20 antibody

A novel murine IgM-type anti-human CD20 monoclonal antibody (mAb) 1-28 was prepared in our Lab, which can induce apoptosis and inhibit proliferation of Daudi and Raji cells. However, the efficacy of 1-28mAb in human cancer therapy is likely to be limited by human anti-mouse antibody responses. A chimeric antibody, C1-28, containing 1-28mAb variable region genes fused to human constant region genes (gamma 1, kappa) was constructed. However, C1-28 lost the antigen-binding activity. Here, using sequence similarity and known 3D structure of antibody variable regions as template, the spatial conformations of 1-28 variable regions (i.e. V(H) and V(L)) were analyzed with computer-guided homology modeling methods. According to the surface electrostatic distribution and interaction free energy analysis, the relationship between structure and stability of 1-28 variable regions was studied theoretically and a new chimeric anti-CD20 antibody scFv-Ig named 5S was designed. Expression level of 5S in the culture supernatant was determined to be around 50mug/mL using sandwich ELISA method with chimeric antibody Rituxan as reference. 5S retained its murine counterpart's binding activity by fluorescence-activated cell-sorting analysis. Furthermore, it could kill CD20 positive Daudi and Raji cells by complement-dependent cytotoxicity. For binding affinity often decreased even lost when IgM antibody was constructed into chimeric IgG1 form, our success give a hint about how to construct a IgG1-type chimeric antibody from IgM-type murine antibody to preserve its binding activity.     

Guided selection of human antibody light chains against TAG-72 using a phage display chain shuffling approach

To enhance therapeutic potential of murine monoclonal antibody, humanization by CDR grafting is usually used to reduce immunogenic mouse residues. Most humanized antibodies still have mouse residues critical for antigen binding, but the mouse residues may evoke immune responses in humans. Previously, we constructed a new humanized version (AKA) of mouse CC49 antibody specific for tumor-associated glycoprotein, TAG-72. In this study, to select a completely human antibody light chain against TAG-72, guided selection strategy using phage display was used. The heavy chain variable region (VH) of AKA was used to guide the selection of a human TAG-72-specific light chain variable region (VL) from a human VL repertoire constructed from human PBL. Most of the selected VLs were identified to be originated from the members of the human germline VK1 family, whereas the VL of AKA is more homologous to the VK4 family. Competition binding assay of the selected Fabs with mouse CC49 suggested that the epitopes of the Fabs overlap with that of CC49. In addition, they showed better antigen-binding affinity compared to parental AKA. The selected human VLs may be used to guide the selection of human VHs to get completely human anti-TAG72 antibody.     

A functional antibody mutant with an insertion in the framework region 3 loop of the VH domain: implications for antibody engineering.

We have studied the effects of a four residue insertion into the FR3 loop of the heavy chain variable region from the anti-NP antibody B1-8. The insertion mutant is obtained as secreted antibody without major defects in biosynthesis, indicating that antibody variable domains can accommodate length variation not only in complementarity determining regions (CDRs), but also in framework region (FR) loops. The B1-8 antigen binding site is not affected by the change in a neighbouring loop. FR3 insertions represent a new method of antibody engineering with a potential to obtain strong antigen binding by designing additional antigen contacting residues.     

Stability of murine, chimeric and humanized antibodies against pre-S2 surface antigen of hepatitis B virus

We have constructed a humanized antibody with specificity for the pre-S2 surface antigen of hepatitis B virus (HBV) by grafting the complementarity determining regions (CDRs) of parental murine monoclonal antibody (mAb) into human anti-Sm antibody framework regions. The humanized antibody has a substitution at position 94 in a framework region of the heavy chain variable region, and exhibits the same antigen binding affinity as the parental murine monoclonal and chimeric antibodies. In order to assess the stability of these antibodies, thermal inactivation of the parental, chimeric and humanized antibodies was analyzed. Fifty percent inactivation of the chimeric and humanized antibodies was observed at 63.7 degrees C and 68.7 degrees C, respectively, compared to 55.0 degrees C for murine antibody. The humanized antibody also exhibited increased stability against denaturant. Guanidine-induced unfolding monitored by the changes in fluorescence intensity at 360 nm showed that midpoints of the transition of the chimeric and humanized antibodies were 2.47 M and 2.56 M, respectively, whereas that of the murine antibody was 1.36 M.     

Cloning and high level expression of a chimeric antibody with specificity for human carcinoembryonic antigen

A mouse/human chimeric antibody has been constructed by using variable light and variable heavy regions from a murine hybridoma specific for human carcinoembryonic antigen (CEA) (CEM231.6.7). These V regions were combined with kappa and gamma-1 constant region genes cloned from human lymphocytes. The chimeric constructs were sequentially electroporated into murine non-Ig-producing myeloma (P3.653) and hybridoma (SP2/0) cell. Significant differences were seen in expression levels between the two cell types. High levels of expression (24 to 32 micrograms/ml/10(6) cells) were seen with several of the anti-CEA SP2/0 transfectomas but not with the P3.653 cells. The SP2/0 transfectoma lines were adapted to serum-free, chemically defined media and grown in large scale fermentation cultures where they continued to secrete high levels of antibody. The chimeric antibodies remain reactive against human CEA with affinity constants comparable to that of the parental hybridoma antibody. High level expression will make practical the production of chimeric antibodies for in vivo therapeutic and diagnostic purposes.     

Characterization of neutralizing mouse‐human chimeric and shuffling antibodies against botulinum neurotoxin A

Mouse‐human chimeric monoclonal antibodies that could neutralize botulinum neurotoxins were developed and an attempt was made to establish mouse hybridoma cell clones that produced monoclonal antibodies that neutralized botulinum neurotoxin serotype A (BoNT/A). Four clones (2–4, 2–5, 9–4 and B1) were selected for chimerization on the basis of their neutralizing activity against BoNT/A and the cDNA of the variable regions of their heavy (V_H) and light chains (V_L) were fused with the upstream regions of the constant counterparts of human kappa light and gamma 1 heavy chain genes, respectively. CHO‐DG44 cells were transfected with these plasmids and mouse‐human chimeric antibodies (AC24, AC25, AC94 and ACB1) purified to examine their binding and neutralizing activities. Each chimeric antibody exhibited almost the same capability as each parent mouse mAb to bind and neutralize activities against BoNT/A. From the chimeric antibodies against BoNT/A, shuffling chimeric antibodies designed with replacement of their V_H or V_L domains were constructed. A shuffling antibody (AC2494) that derived its V_H and V_L domains from chimeric antibodies AC24 and AC94, respectively, showed much higher neutralizing activity than did other shuffling antibodies and parent counterparts. This result indicates that it is possible to build high‐potency neutralizing chimeric antibodies by selecting and shuffling V_H and V_L domains from a variety of repertoires. A shuffling chimeric antibody might be the best candidate for replacing horse antitoxin for inducing passive immunotherapy against botulism.     

β淀粉样肽单克隆抗体可变区基因的5′RACE扩增及序列分析

目的:克隆并分析抗β淀粉样肽单克隆抗体轻链与重链可变区基因。方法:从分泌抗β淀粉样肽单克隆抗体的杂交瘤细胞株A8中提取总RNA,根据恒定区序列设计基因特异性引物,通过5′RACE法扩增抗体的轻链和重链可变区基因,测定并分析可变区基因序列,并克隆入pMD18-T载体。结果:重链可变区基因序列全长450bp,编码150个氨基酸残基;轻链可变区基因序列全长429bp,编码143个氨基酸残基。在GeneBank中对氨基酸序列进行比对分析,二者均符合小鼠IgG可变区基因的特征。根据Kabat法则对A8抗体轻链和重链可变区氨基酸序列基因进行分析并确定了3个抗原互补决定区(CDR)、4个框架区(FR)和信号肽。结论:通过5′RACE法得到了抗β淀粉样肽单克隆抗体轻链与重链可变区基因,为进一步研究抗体三维结构,以及对该抗体进行人源化改造奠定了基础。     

抗HEV嵌合抗体的构建及在CHO细胞中的表达

通过RT-PCR方法从分泌戊型肝炎(戊肝)病毒中和性鼠源单克隆抗体(单抗)8C11的杂交瘤细胞中克隆出抗体基因的重链可变区(VH)、轻链可变区(VK)序列,并分别克隆到含有人gamma 1重链和kappa轻链恒定区序列的pcDNA3.1/Hygro和pcDNA3.1( )质粒中,共转染中华仓鼠卵巢癌细胞(CHO)细胞.RT-PCR结果表明,转染的CHO细胞转录了嵌合重链及轻链基因,间接ELISA及Western blot结果表明:翻译出的两种多肽在细胞内正确组装成嵌合抗体分子,并可分泌至细胞外,表达的嵌合抗体保留了原鼠单抗的抗原结合特异性及对8H3结合抗原的增强作用.8C11嵌合抗体的成功表达可降低鼠源性,为探讨戊肝抗体治疗的可能性奠定了基础.     

Design and synthesis of germline-based hemi-humanized single-chain Fv against the CD18 surface antigen

The 6.7 murine monoclonal antibody (mAb) recognizes the human CD18 antigen and is therefore of interest as an anti-inflammatory agent. The 6.7 heavy variable chain (VH) was humanized using the closest human germline sequence as the template on to which to graft the murine complementary determining regions (CDRs). Two versions were proposed, one in which the residue proline 45 of the murine form was maintained and another in which this framework residue was changed to the leucine found in the human sequence. These VH humanized versions were expressed in the yeast Pichia pastoris as hemi-humanized single-chain Fv (scFvs), with the VL from the murine antibody. The scFv from the murine antibody was also expressed. The binding activities of the murine and both hemi-humanized scFvs were determined by flow cytometry analysis. All the constructions were able to recognize human lymphocytes harboring CD18, indicating successful humanization with transfer of the original binding capability. Some differences between the two hemi-humanized versions were observed. The method used was simple and straightforward, with no need for refined structural analyses and could be used for the humanization of other antibodies.     

抗人前列腺干细胞抗原单克隆抗体可变区基因的5＇RACE扩增及序列分析

目的：克隆并分析抗人前列腺干细胞抗原单克隆抗体轻链和重链的可变区基因。方法：从分泌抗人前列腺干细胞抗原单克隆抗体的杂交瘤细胞株中提取总RNA,根据小鼠IgG恒定区序列设计特异性引物,通过5’RACE法扩增其轻链和重链的可变区基因,克隆入pMD18-T载体,测序并分析其可变区序列。结果：3株抗人前列腺干细胞抗原单克隆抗体的重链可变区基因序列全长均为423bp,编码141个氨基酸残基;轻链可变区基因序列全长均为393bp,编码131个氨基酸残基;在GenBank中对氨基酸序列进行比对分析,均符合小鼠IgG可变区基因的特征;根据Kabat法则对3株抗体轻链和重链可变区氨基酸序列进行分析,确定了3个抗原互补决定区、4个框架区和前导肽。结论：通过5＇RACE法得到了3株抗人前列腺干细胞抗原单克隆抗体轻链与重链可变区基因,为进一步研究抗体三维结构、人源化改造奠定了基础。     

Characterization of a high-affinity human antibody with a disulfide bridge in the third complementarity-determining region of the heavy chain

Disulfide bridges are common in the antigen-binding site from sharks (new antigen receptor) and camels (single variable heavy-chain domain, VHH), in which they confer both structural diversity and domain stability. In human antibodies, cysteine residues in the third complementarity-determining region of the heavy chain (CDR-H3) are rare but naturally encoded in the IGHD germline genes. Here, by panning a phage display library designed based on human germline genes and synthetic CDR-H3 regions against a human cytokine, we identified an antibody (M3) containing two cysteine residues in the CDR-H3. It binds the cytokine with high affinity (0.4?nM), recognizes a unique epitope on the antigen, and has a distinct neutralization profile as compared with all other antibodies selected from the library. The two cysteine residues form a disulfide bridge as determined by mass spectrometric peptide mapping. Replacing the cysteines with alanines did not change the solubility and stability of the monoclonal antibody, but binding to the antigen was significantly impaired. Three-dimensional modeling and dynamic simulations were employed to explore how the disulfide bridge influences the conformation of CDR-H3 and binding to the antigen. On the basis of these results, we envision that designing human combinatorial antibody libraries to contain intra-CDR or inter-CDR disulfide bridges could lead to identification of human antibodies with unique binding profiles.     

Comparison of the three‐dimensional structures of a humanized and a chimeric Fab of an anti‐γ‐interferon antibody

The objective of this work is to compare the three‐dimensional structures of “humanized” and mouse–human chimeric forms of a murine monoclonal antibody elicited against human γ‐interferon. It is also to provide structural explanations for the small differences in the affinities and biological interactions of the two molecules for this antigen. Antigen‐binding fragments (Fabs) were produced by papain hydrolysis of the antibodies and crystallized with polyethylene glycol (PEG) 8000 by nearly identical microseeding procedures. Their structures were solved by X‐ray analyses at 2.9 Å resolution, using molecular replacement methods and crystallographic refinement. Comparison of these structures revealed marked similarities in the light (L) chains and near identities of the constant (C) domains of the heavy (H) chains. However, the variable (V) domains of the heavy chains exhibited substantial differences in the conformations of all three complementarity‐determining regions (CDRs), and in their first framework segments (FR1). In FR1 of the humanized V_H, the substitution of serine for proline in position 7 allowed the N‐terminal segment (designated strand 4‐1) to be closely juxtaposed to an adjacent strand (4‐2) and form hydrogen bonds typical of an antiparallel β‐pleated sheet. The tightening of the humanized structure was relayed in such a way as to decrease the space available for the last portion of HFR1 and the first part of HCDR1. This compression led to the formation of an α‐helix involving residues 25–32. With fewer steric constraints, the corresponding segment in the chimeric Fab lengthened by at least 1 Å to a random coil which terminated in a single turn of 3₁₀ helix. In the humanized Fab, HCDR1, which is sandwiched between HCDR2 and HCDR3, significantly influenced the structures of both regions. HCDR2 was forced into a bent and twisted orientation different from that in the chimeric Fab, both at the crown of the loop (around proline H52a) and at its base. As in HCDR1, the last few residues of HCDR2 in the humanized Fab were compressed into a space‐saving α‐helix, contrasting with a more extended 3₁₀ helix in the chimeric form. HCDR3 in the humanized Fab was also adjusted in shape and topography. The observed similarities in the functional binding activities of the two molecules can be rationalized by limited induced fit adjustments in their structures on antigen binding. While not perfect replicas, the two structures are testimonials to the progress in making high affinity monoclonal antibodies safe for human use. Copyright © 1999 John Wiley & Sons, Ltd.     

6C6鼠-人嵌合抗体的纯化及鉴定

采用基因工程技术 ,将小鼠 6C6单克隆抗体可变区基因与人抗体恒定区基因连接 ,构建了鼠 人 6C6嵌合抗体基因 ,并在CHO细胞中高效表达 .利用ProteinA亲和层析柱从细胞培养上清中分离纯化 6C6嵌合抗体 ,得到电泳纯度大于 98%的 6C6嵌合抗体 ,其重链 (5 5kD)和轻链 (2 4kD)符合IgG相对分子质量的理论值 .Western印迹、细胞免疫荧光和免疫组织化学实验结果均呈阳性 .表明6C6嵌合抗体可识别人乳腺癌细胞表面上的肿瘤相关抗原 ,保持了 6C6单克隆抗体的特性 ,为后续的研究工作奠定了基础     

A murine–human chimeric IgG antibody against vascular endothelial growth factor receptor 2 inhibits angiogenesis in vitro

Vascular endothelial growth factor receptor 2 (VEGFR2) has been reported to play an important role in angiogenesis and tumorigenesis. A murine anti-VEGFR2 mAb (A8H1) has been established in a previous study. To reduce the incompatibility of the murine mAb for human use, the chimeric anti-VEGFR2-IgG was developed by genetic recombination of the variable regions of the A8H1 antibody and the constant regions of human IgG, and was expressed in Sp2/0 cells transfected with the two recombinant vectors containing the heavy chain and the light chain regions. After screening, clone 2F12 was selected and was found to stably secrete the murine–human chimeric anti-VEGFR2-IgG (coded 2F12). This chimeric IgG maintained the specificity and the affinity of the parental murine antibody against VEGFR2, and effectively identified VEGFR2 expressed on the surface of HUVECs and BEL-7402 cells. Furthermore, the 2F12 antibody demonstrated inhibition of angiogenesis in vitro, such as proliferation, migration, invasion and tube formation of HUVECs. This murine–human chimeric IgG may be considered for further development as an anti-angiogenesis and anti-tumor agent.     

抗FGF2人鼠嵌合抗体在HEK293T细胞中的表达优化

目的：FGF2是肿瘤血管新生过程中最重要的因子之一,因此通过制备抗FGF2人鼠嵌合抗体中和其发挥作用,以达到抑制肿瘤生长的目的。方法：利用分泌抗FGF2抗体的杂交瘤细胞株IgG9B9和人B淋巴细胞,分别克隆抗体轻链可变区V_L、重链可变区V_H和人重链恒定区C_H基因,从pComb3λ载体中扩增出人λ 链恒定区C_L基因,通过重叠PCR,将V_L,V_H和C_L,C_H片段分别连接形成嵌合抗体的轻链L和重链H,将L/H链以单独构建或串联于同一载体的方式,构建抗FGF2嵌合抗体表达载体,并通过调控元件WPRE优化载体、共转染促生长因子aFGF以及调整表达温度等方式提高嵌合抗体在真核细胞中的表达。结果：成功构建了优化表达载体PLexm-WPRE、PLexm-aFGF;L、H链基因也成功构建,并以L、H或L-F2A-H（2A连接肽将L和H连接起来）的方式分别成功连接到PLexm,PLexm-WPRE载体中。转染细胞上清的ELISA鉴定结果表明,L/H链单独构建要比串联构建的方式具有更高的表达水平,WPRE能有效促进抗体的表达而aFGF并不能促进其表达,与31、37℃相比,33℃时抗体的表达量最高,同时嵌合抗体表现出了很好的结合活性及中和活性,竞争IC50=6.25μg/ml。通过亲和层析获得了高纯度的抗FGF2嵌合抗体。结论：在33℃下,人鼠嵌合抗体基因在WPRE存在下表达量最高,且与抗原FGF2有很好的结合活性及中和活性,为临床应用奠定了基础。     

Structural consequences of mutations in interfacial Tyr residues of a protein antigen-antibody complex. The case of HyHEL-10-HEL

Tyrosine is an important amino acid in protein-protein interaction hot spots. In particular, many Tyr residues are located in the antigen-binding sites of antibodies and endow high affinity and high specificity to these antibodies. To investigate the role of interfacial Tyr residues in protein-protein interactions, we performed crystallographic studies and thermodynamic analyses of the interaction between hen egg lysozyme (HEL) and the anti-HEL antibody HyHEL-10 Fv fragment. HyHEL-10 has six Tyr residues in its antigen-binding site, which were systematically mutated to Phe and Ala using site-directed mutagenesis. The crystal structures revealed several critical roles for these Tyr residues in the interaction between HEL and HyHEL-10 as follows: 1) the aromatic ring of Tyr-50 in the light chain (LTyr-50) was important for the correct ternary structure of variable regions of the immunoglobulin light chain and heavy chain and of HEL; 2) deletion of the hydroxyl group of Tyr-50 in the heavy chain (HTyr-50) resulted in structural changes in the antigen-antibody interface; and 3) the side chains of HTyr-33 and HTyr-53 may help induce fitting of the antibody to the antigen. Hot spot Tyr residues may contribute to the high affinity and high specificity of the antigen-antibody interaction through a diverse set of structural and thermodynamic interactions.     

Structure-based affinity maturation of a chimeric anti-ricin antibody C4C13

Ricin is a highly lethal toxin. Anti-ricin chimeric monoclonal antibody (mAb) C4C13 was prepared in our lab; however, its binding affinity was much weaker than that of the parent antibody 4C13. In this study, based on the computer-guided homology modeling and conformational optimization methods, the 3-D structure of C4C13 variable regions Fv was constructed and optimized. Using molecular docking and dynamics simulation methods, the 3-D complex structure of ricin and C4C13 Fv was obtained. Considering the orientation property, surface electrostatic distribution, residues chemical andphysical character and intermolecular hydrogen bond, the binding mode and key residues were predicted. According to C4C13 Fv fragment and ricin complementary binding surface, electrostatic attraction periphery and van der Waals interaction interface, three mutants (i.e., M1 (N^H102F, W^H103Y); M2 (W^H103Y) and M3 (R^L90G)) were designed, in which M1 and M2 were predicted to possess higher antigen-binding activity than C4C13, while M3 was weaker. The relative affinity assays by ELISA showed that M1 and M2 mutations had higher affinity (9.6 and 18.3?nmol/L) than C4C13 (130?nmol/L) and M3 had weaker affinity (234.5?nmol/L) than C4C13. The results showed that the modeling complex structure of the antigen (ricin) and antibody (C4C13) is reasonable. Our work offered affinity maturated antibodies by site mutations, which were beneficial for valuable anti-ricin antibody design and preparation in future.