单域抗体的研究和应用进展

传统IgG抗体分子一般由轻链和重链组成,轻链包含1个可变区(VL)和1个恒定区(CL),重链包含1个可变区(VH)和3个恒定区(CH1,CH2,CH3)。单域抗体(Single domain antibody,sdAb),是指缺失抗体轻链而只有重链可变区的一类抗体,因其分子量小,也被称为纳米抗体(Nanobody)。20世纪90年代,单域抗体最早在骆驼科动物中被发现,之后在护士鲨、大星鲨和鳐鱼等软骨鱼纲动物中也发现了类似的抗体。单域抗体虽然结构简单,但仍然可以达到与传统抗体相当甚至更高的与特异抗原结合的亲和力。相比于传统抗体,单域抗体具有分子量小、稳定性强、易于重组表达等优点。近年来在生物学基础研究和医学临床应用方面均备受关注并被广泛应用。文中将从单域抗体的结构特征、理化性质、筛选方法及其在生物医学领域的重要应用进展进行综述。     

基于重链抗体构建的单域抗体研究进展

在骆驼血清中存在天然的缺失轻链的重链抗体(heavy chainantibody ,HCAb) ,克隆重链抗体的可变区构建的只由一个重链可变区组成的单域抗体称为VHH抗体(variabledomainofheavychainofheavy chainantibody ,VHH)。研究发现,VHH抗体具有易表达、可溶性好、稳定性强等优点。另外,骆驼的重链抗体与人VH3家族抗体同源,对人VH3家族抗体的重链可变区进行类似VHH的特征性改造,可以使这些抗体在保持亲和力、特异性不变或者变化很小的情况下,优化抗体的其它性质。已有的研究表明VHH抗体作为一种小型化的基因工程抗体在基础研究、药物开发等领域有广阔的应用前景。     

结核分枝杆菌Rv0733 6His抗原羊驼单域重链抗体的筛选与鉴定

单域重链抗体是目前中和胞内病原体抗原的重要分子之一,研究以结核分枝杆菌Rv0733-6His融合抗原为靶标,对羊驼非免疫单域重链抗体库进行了3轮淘洗,通过ELISA和测序方法,从1024个克隆中筛选出10个独立单域重链抗体序列,继而用原核表达并鉴定了1株Rv0733-VHH-Fe-6His抗体。免疫印迹和免疫荧光结果均显示Rv0733-VHH—Fe-6His抗体可以特异性地结合Rv0733抗原。提示Rv0733-VHH抗体可能具备结合胞内菌相关抗原的潜力。     

纳米抗体研究进展

纳米抗体是由骆驼科动物缺失轻链的天然重链抗体的可变区(VHH)组成的单域抗体,其可变区的相对分子质量约为15×10~3。与传统抗体相比,纳米抗体具有相对分子质量小、亲和力高、稳定性高、溶解性好、免疫原性低、穿透力强、人源化简单等优势。基于纳米抗体的特性以及骆驼天然重链抗体的VHH单域抗体的特殊结构,使其在基础医学研究以及疾病诊断和治疗方面具有广阔的应用前景。     

基于细胞的抗单增李斯特菌单域重链抗体的筛选及鉴定

【目的】获得针对单增李斯特菌的特异性单域重链抗体,并对筛选过程中特异性克隆的富集规律进行分析,为筛选具有种属特异性的噬菌体展示抗体提供参考。【方法】采用固相筛选技术,以热灭活的单增李斯特菌菌体为抗原,通过四轮常规筛选和一轮消减筛选,从驼源天然噬菌体展示文库中筛选针对单增李斯特菌的单域重链抗体。采用Phage-ELISA法,对后四轮筛选洗脱物中随机挑选的噬菌体进行鉴定,阳性克隆进行基因测序及结合特异性分析。通过多序列比对分析将获得的基因序列进行分组和统计。【结果】成功筛选到2株单增李斯特菌特异性的单域重链抗体。【结论】在优化的筛选条件下,基于全细胞的筛选方法能够获得特异性识别单增李斯特菌的单域重链抗体,消减筛选对于去除非特异性克隆是有效的和必要的。     

抗脂多糖纳米抗体的筛选及其五聚体的制备

目的：筛选抗脂多糖（LPS）纳米单域抗体,并制备抗LPS纳米抗体五聚体。方法：以LPS为抗原,从驼源天然单域重链抗体库中筛选抗LPS纳米抗体,利用分子克隆技术将抗LPS单域抗体基因组装入志贺杆菌样毒素B亚基蛋白结构域（VTB）的五聚体特异性表达载体中进行可溶性表达,并用ELISA法鉴定所获抗体的抗原结合活性和特异性。结果：获得抗LPS纳米单域抗体及LPS纳米抗体五聚体;经鉴定,LPS纳米抗体五聚体的抗原结合活性优于抗LPS单域抗体。结论：利用驼源天然单域重链抗体库制备了抗LPS纳米单域抗体及抗LPS纳米抗体五聚体,为脓毒血症的分子诊断、预后判断及寻找生物治疗新靶点奠定了基础。     

单域抗体研究进展

近年来用基因工程方法从软骨鱼和骆驼科动物中克隆到的单域抗体（single—domain antibody,sdAb）具有无轻链、单一重链可变区保留了完整的抗原结合活性的特征。这类单域抗体具有分子小、稳定性高、体内组织渗透性好、可溶性好、易表达、抗原识别表位独特的特性,已引起生物技术研究与诊断治疗应用领域的广泛关注,取得了快速发展。综述了这类单域抗体发展历史、分子类别、结构特征、理化特征、分子演化及应用前景。     

抗人CD3单链抗体与改形单域抗体的表达

设计并化学合成含有适当酶切位点及连接肽的寡核苷酸序列,与一定的背景载体连接并改造成适用于单链抗体表达的载体:外分泌型pWAI80和融合蛋白型pROH80从分泌抗人CD3单克隆抗体的杂交瘤细胞UCHT1中,经PCR扩增出轻、重链可变区基因V_H和V_K,并插入上述表达载体中构建成单链抗体基因.通过对鼠OKT3结合位点的结构模拟,并比较人、鼠抗体家族性保守序列,设计出改形OKT3的基因序列.化学法部分合成8个寡核苷酸片段,应用重叠PCR技术扩增出完整改形重链基因V_H,并克隆、酶切和测序鉴定.将所克隆V_H基因插入表达载体pCOMB3和 pGEX-4T-1中进行表达.经 IPTG诱导表达,对表达产物进行SDS-PAGE和 Western blot分析以及 ELISA检测,结果发现分泌型表达产物及 M13基因Ⅲ-V_H改形单域抗体融合蛋白具有与CD3单抗竞争抑制的活性;而融合型单链抗体及改形单域抗体表达产物主要以包涵体形式存在,占细菌总蛋白的 30％左右.     

驼源天然单域重链抗体库的构建与鉴定

从未经主动免疫的健康羊驼(Lama pacos)外周血淋巴细胞中提取总RNA,反转录后作为第一轮PCR的模板。根据重链抗体保守区域设计引物,经巢式PCR法扩增获得了全套重链抗体可变区基因,将其克隆至噬菌粒pHEN1,电转化大肠杆菌TG1得到初级抗体库NAL,含有2×10⁷个独立克隆,菌落PCR和Hinf I酶切分析结果显示,克隆效率大于97%,文库的多样性良好。辅助噬菌体救援后,得到噬菌体展示文库命名为NA-PDL,滴度达10¹³CFU/ml。以真菌毒素人工抗原DON-MBSA为目标抗原,对NA-PDL进行了淘选,第二轮洗脱物中,阳性克隆率达36.4%,提示针对目标抗原的噬菌体颗粒得到了有效富集,文库NA-PDL多样性较好,为后续淘选针对特定抗原的单域重链抗体奠定了基础。     

纳米抗体异源表达的研究进展

羊驼体内存在天然缺失轻链的重链抗体(HcAb),其单域抗原结合片段也称为VHH或纳米抗体(nanobody,Nb),是目前已知的最小抗原结合片段。与传统抗体相比,纳米抗体具有分子量小(12~15kDa)、稳定性好和免疫原性低等特点,这些特点使得VHH在基础研究、诊断及治疗上具有极大的应用价值,目前已有多种纳米抗体进入了临床研究阶段。综述了近年来VHH在革兰氏阴性菌(大肠杆菌)、革兰氏阳性菌(芽孢杆菌和乳酸杆菌)、酵母、丝状真菌、昆虫细胞、哺乳动物细胞和植物细胞中异源表达的研究现状,包括表达系统、宿主、载体特点、载体构建方式及产量等;从分子水平、表达水平和理性设计三个层面探讨了纳米抗体产量提高的策略,以期为纳米抗体研究者提供借鉴和思路。     

Single Domain Antibodies as a Powerful Tool for High Quality Surface Plasmon Resonance Studies

Single domain antibodies are recombinantly expressed functional antibodies devoid of light chains. These binding elements are derived from heavy chain antibodies found in camelids and offer several distinctive properties for applications in biotechnology such as small size, stability, solubility, and expression in high yields. In this study we demonstrated the potential of using single domain antibodies as capturing molecules in biosensing applications. Single domain antibodies raised against green fluorescent protein were anchored onto biosensor surfaces by using several immobilization strategies based on Ni²⁺:nitrilotriacetic acid-polyhistidine tag, antibody-antigen, biotin-streptavidin interactions and amine-coupling chemistry. The interaction with the specific target of the single domain antibodies was characterized by surface plasmon resonance. The immobilized single domain antibodies show high affinities for their antigens with K_D = 3–6 nM and outperform other antibody partners as capturing molecules facilitating also the data analysis. Furthermore they offer high resistance and stability to a wide range of denaturing agents. These unique biophysical properties and the production of novel single domain antibodies against affinity tags make them particularly attractive for use in biosensing and diagnostic assays.     

Development and Evaluation of Single Domain Antibodies for Vaccinia and the L1 Antigen

There is ongoing interest to develop high affinity, thermal stable recognition elements to replace conventional antibodies in biothreat detection assays. As part of this effort, single domain antibodies that target vaccinia virus were developed. Two llamas were immunized with killed viral particles followed by boosts with the recombinant membrane protein, L1, to stimulate the immune response for envelope and membrane proteins of the virus. The variable domains of the induced heavy chain antibodies were selected from M13 phage display libraries developed from isolated RNA. Selection via biopanning on the L1 antigen produced single domain antibodies that were specific and had affinities ranging from 4×10⁻⁹ M to 7.0×10⁻¹⁰ M, as determined by surface plasmon resonance. Several showed good ability to refold after heat denaturation. These L1-binding single domain antibodies, however, failed to recognize the killed vaccinia antigen. Useful vaccinia binding single domain antibodies were isolated by a second selection using the killed virus as the target. The virus binding single domain antibodies were incorporated in sandwich assays as both capture and tracer using the MAGPIX system yielding limits of detection down to 4×10⁵ pfu/ml, a four-fold improvement over the limit obtained using conventional antibodies. This work demonstrates the development of anti-vaccinia single domain antibodies and their incorporation into sandwich assays for viral detection. It also highlights the properties of high affinity and thermal stability that are hallmarks of single domain antibodies.     

Mapping of functional domains of human high molecular weight and low molecular weight kininogens using murine monoclonal antibodies

Thirty-four monoclonal antibodies directed against human high molecular weight (HMW) and low molecular weight (LMW) kininogens and their derivatives were obtained, and the specificities of the antibodies were assayed by enzyme-linked immunosorbent assay (ELISA). By use of HMW kininogen, kinin-free HMW kininogen, kinin-free and fragment 1.2 (fr 1.2) free HMW kininogen, fr 1.2-light chain of HMW kininogen, LMW kininogen, kinin-free LMW kininogen, heavy chain of LMW kininogen, and light chain of LMW kininogen, the monoclonal antibodies were characterized and classified into four groups: (A) 20 monoclonal antibodies reacting with only the heavy chain, a common region of HMW and LMW kininogens; each of these monoclonal antibodies possessed the specificity to domain 1 (2 monoclonal antibodies), domain 2 (2 monoclonal antibodies), domain 3 (7 monoclonal antibodies), and both domains 2 and 3 (7 monoclonal antibodies) of the heavy chain; (B) 7 monoclonal antibodies reacting with fr 1.2, a unique histidine-rich region; (C) 5 monoclonal antibodies reacting with the light chain of HMW kininogen; (D) 2 monoclonal antibodies reacting with the light chain of LMW kininogen. Two monoclonal antibodies in the first group (group A), designated HKG H7 and H12, effectively suppressed the thiol proteinase inhibitor activity of HMW kininogen to papain and calpains and of LMW kininogen to papain, but the others did not affect it. Further, all the monoclonal antibodies which recognized the fr 1.2 or light chain of HMW kininogen (groups B and C) suppressed the clotting activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Recognition of antigens by single-domain antibody fragments: the superfluous luxury of paired domains

The antigen-binding site of antibodies from vertebrates is formed by combining the variable domains of a heavy chain (VH) and a light chain (VL). However, antibodies from camels and llamas are an important exception to this in that their sera contain, in addition, a unique kind of antibody that is formed by heavy chains only. The antigen-binding site of these antibodies consists of one single domain, referred to as VHH. This article reviews the mutations and structural adaptations that have taken place to reshape a VH of a VH-VL pair into a single-domain VHH with retention of a sufficient variability. The VHH has a potent antigen-binding capacity and provides the advantage of interacting with novel epitopes that are inaccessible to conventional VH-VL pairs.     

一种具有人VEGF结合活性的人源单一重链可变区的克隆与表达

为避免一种来自五特征转基因小鼠的全人VEGF单克隆IgM抗体分子量大的不足,本研究探讨了该抗体单一重链可变区的功能特性。首先,PCR获得该抗体的重链可变区,将该序列克隆至pET28a表达载体内,在大肠杆菌中进行了诱导表达。通过变性纯化和复性等方法获得了具有生物学活性的16kDa重组抗体片段——rhVVH。体外结合实验表明,rhVVH保留有完整免疫球蛋白的人VEGF结合活性。人脐静脉内皮细胞(HUVEC)增殖抑制实验表明:rhVVH可以剂量依赖性的抑制HUVEC的增殖。上述结果揭示了该抗体单一重链可变区保留有完整抗体的部分功能,为进一步开展全人源VEGF单克隆IgM抗体小型化研究奠定了基础。     

Single domain antibodies for the knockdown of cytosolic and nuclear proteins

Single domain antibodies (sdAbs) from camels or sharks comprise only the variable heavy chain domain. Human sdAbs comprise the variable domain of the heavy chain (VH) or light chain (VL) and can be selected from human antibodies. SdAbs are stable, nonaggregating molecules in vitro and in vivo compared to complete antibodies and scFv fragments. They are excellent novel inhibitors of cytosolic/nuclear proteins because they are correctly folded inside the cytosol in contrast to scFv fragments. SdAbs are unique because of their excellent specificity and possibility to target posttranslational modifications such as phosphorylation sites, conformers or interaction regions of proteins that cannot be targeted with genetic knockout techniques and are impossible to knockdown with RNAi. The number of inhibiting cytosolic/nuclear sdAbs is increasing and usage of synthetic single pot single domain antibody libraries will boost the generation of these fascinating molecules without the need of immunization. The most frequently selected antigenic epitopes belong to viral and oncogenic proteins, followed by toxins, proteins of the nervous system as well as plant‐ and drosophila proteins. It is now possible to select functional sdAbs against virtually every cytosolic/nuclear protein and desired epitope. The development of new endosomal escape protein domains and cell‐penetrating peptides for efficient transfection broaden the application of inhibiting sdAbs. Last but not least, the generation of relatively new cell‐specific nanoparticles such as polymersomes and polyplexes carrying cytosolic/nuclear sdAb‐DNA or –protein will pave the way to apply cytosolic/nuclear sdAbs for inhibition of viral infection and cancer in the clinic.     

LUZ-Y,a Novel Platform for the Mammalian Cell Production of Full-length IgG-bispecific Antibodies

The ability of bispecific antibodies to simultaneously bind two unique antigens has great clinical potential. However, most approaches utilized to generate bispecific antibodies yield antibody-like structures that diverge significantly from the structure of archetype human IgG, and those that do approach structural similarity to native antibodies are often challenging to engineer and manufacture. Here, we present a novel platform for the mammalian cell production of bispecific antibodies that differ from their parental mAbs by only a single point mutation per heavy chain. Central to this platform is the addition of a leucine zipper to the C terminus of the C_H3 domain of the antibody that is sufficient to drive the heterodimeric assembly of antibody heavy chains and can be readily removed post-purification. Using this approach, we developed various antibody constructs including one-armed Abs, bispecific antibodies that utilize a common light chain, and bispecific antibodies that pair light chains to their cognate heavy chains via peptide tethers. We have applied this technology to various antibody pairings and will demonstrate the engineering, purification, and biological activity of these antibodies herein.     

15N, 13C and 1H resonance assignments and secondary structure determination of a variable heavy domain of a heavy chain antibody

Heavy chain antibodies differ in structure to conventional antibodies lacking both the light chain and the first heavy chain constant domain (CH1). Characteristics of the antigen-binding variable heavy domain of the heavy chain antibody (VHH) including the smaller size, high solubility and stability make them an attractive alternative to more traditional antibody fragments for detailed NMR-based structural analysis. Here we report essentially complete backbone and side chain ¹⁵N, ¹³C and ¹H assignments for a free VHH. Analysis of the backbone chemical shift data obtained indicates that the VHH is comprised predominantly of β-sheets corresponding to nearly 60 % of the protein backbone.     

Constant domain-exchanged Fab enables specific light chain pairing in heterodimeric bispecific SEED-antibodies

BackgroundBispecific antibodies promise to broadly expand the clinical utility of monoclonal antibody technology. Several approaches for heterodimerization of heavy chains have been established to produce antibodies with two different Fab arms, but promiscuous pairing of heavy and light chains remains a challenge for their manufacturing.MethodsWe have designed a solution in which the C_H1 and C_L domain pair in one of the Fab fragments is replaced with a C_H3-domain pair and heterodimerized to facilitate correct modified Fab-chain pairing in bispecific heterodimeric antibodies based on a strand-exchange engineered domain (SEED) scaffold with specificity for epithelial growth factor receptor and either CD3 or CD16 (FcγRIII).ResultsBispecific antibodies retained binding to their target antigens and redirected primary T cells or NK cells to induce potent killing of target cells. All antibodies were expressed at a high yield in Expi293F cells, were detected as single sharp symmetrical peaks in size exclusion chromatography and retained high thermostability. Mass spectrometric analysis revealed specific heavy-to-light chain pairing for the bispecific SEED antibodies as well as for one-armed SEED antibodies co-expressed with two different competing light chains.ConclusionIncorporation of a constant domain-exchanged Fab fragment into a SEED antibody yields functional molecules with favorable biophysical properties.General significanceOur results show that the novel engineered bispecific SEED antibody scaffold with an incorporated Fab fragment with C_H3-exchanged constant domains is a promising tool for the generation of complete heterodimeric bispecific antibodies with correct light chain pairing.     

Inhibition of HIV-1 Tat-mediated LTR transactivation and HIV-1 infection by anti-Tat single chain intrabodies.

Genes encoding the rearranged immunoglobulin heavy and light chain variable regions of anti-HIV-1 Tat, exon 1 or exon 2 specific monoclonal antibodies have been used to construct single chain intracellular antibodies 'intrabodies' for expression in the cytoplasm of mammalian cells. These anti-Tat single chain intrabodies (anti-Tat sFvs) are additionally modified with a C-terminal human C kappa domain to increase cytoplasmic stability and/or the C-terminal SV40 nuclear localization signal to direct the nascent intrabody to the nuclear compartment, respectively. The anti-Tat sFvs with specific binding activity against the N-terminal activation domain of Tat, block Tat-mediated transactivation of HIV-1 LTR as well as intracellular trafficking of Tat in mammalian cells. As a result, the transformed lymphocytes expressing anti-Tat sFvs are resistant to HIV-1 infection. Thus, these studies demonstrate that stably expressed single chain intrabodies and their modified forms can effectively target molecules in the cytoplasm and nuclear compartments of eukaryotic cells. Furthermore, these studies suggest that anti-Tat sFvs used either alone or in combination with other genetically based strategies may be useful for the gene therapy of HIV-1 infection and AIDS.