链替换技术提高噬菌体抗体亲和力的研究进展

高亲和力抗体基因的克隆是噬菌体抗体在基础研究、临床诊断治疗研究等重要领域中应用的基础。链替换技术已逐步广泛用于噬菌体抗体的性能改造。该技术不仅可以促进噬菌体的体外亲和力成熟,提高抗体亲和力,有助于低剂量抗体达到实际应用所需要的抗原结合效应,拓宽抗体的应用开发前景,而且可应用于减少抗体人抗鼠抗体反应,分析重链或轻链基因对抗原抗体结合的影响,有助于较好的理解免疫化学。就链替换的原理、策略及其应用进行综述。     

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。     

纳米抗体技术应用的最新进展北大核心CSCD

纳米抗体作为一种可塑性强、较为新颖的抗原识别和调控的工具,具备小尺寸、易表达和筛选及改造、高亲性和稳定性等优势,能够识别传统抗体难以识别的较为隐匿的抗原表位,在诊断治疗各种疾病及检测方面的应用不断深入,且在基础研究中也发挥着不可替代的作用。文中主要介绍了纳米抗体及其衍生结构在小分子化合物及病原微生物检测和疾病的诊断,以及在疾病靶向治疗,细胞、分子成像领域的相关进展,此外还综述了在蛋白质构象研究领域展现的广阔前景。     

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。     

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。     

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。     

纳米抗体技术及其在疾病诊断和治疗中的应用

单克隆抗体具有特异性结合抗原的能力,已被广泛应用于疾病诊断及治疗领域.但因单克隆抗体的组织渗透能力较差、体内的保留时间较长以及制备过程繁琐,从而限制了其在临床中的应用.自1993年首次报道在骆驼体内天然存在的单链抗体(HCAb)以来,由于其可变区间VHH(纳米抗体)具有体积小、溶解度高、特异性强以及可在细菌中大量表达等优点,较之传统单克隆抗体,VHH在疾病的诊断治疗及药物开发等医学领域具有更广阔的应用前景.本文综述了:纳米抗体的骨架区及互补决定区与传统抗体重链相应区间的结构比较;纳米抗体库的构建以及运用噬菌体展示技术对VHH库的筛选;纳米抗体技术在疾病诊断中的应用及其用于分子显像的优势,以及纳米抗体作为抗肿瘤免疫偶联物的靶向组分在癌症治疗领域中的最新进展.     

鲨源单域抗体的研究进展

单克隆抗体是重要的生物大分子,在免疫检测、体外诊断以及药物开发等领域获得广泛的应用。但是单克隆抗体的分子量大、结构复杂等固有属性正日益成为制约其进一步发展的关键因素。因此,当前迫切需要开发单克隆抗体的替代品。鲨源单域抗体即鲨源新抗原受体可变区(Variabledomainofimmunoglobulinnew antigenreceptor,VNAR),是基于鲨总目鱼类天然存在的新抗原受体(Immunoglobulinnewantigenreceptor,IgNAR)并通过基因工程技术获得的抗原结合域,其分子量仅为12kDa,是目前已知脊椎动物中尺寸最小的抗原结合域。鲨源单域抗体具有分子量小、亲和力高、稳定性强、溶解度好、组织穿透性强以及可识别隐藏抗原表位等优点,在免疫试剂以及药物开发等领域受到广泛的关注。文中综述了鲨源单域抗体的结构及功能特性、制备及人源化改造技术、亲和力成熟策略以及应用领域,并系统性分析了鲨源单域抗体的优缺点,最后对其发展前景进行了展望。     

纳米抗体在传染病的预防、诊断和治疗中的应用 *

传染病是一种由致病性微生物引起,能够影响人类身体健康甚至引发严重社会危机的传播性疾病。近年来,新冠、埃博拉等传染病的恶性暴发促使人们寻找更为高效便捷的防治手段以遏制疾病的进程。抗体在传染病防治中的应用引起了广泛关注,palivizumab是目前唯一被批准应用于呼吸道合胞病毒在免疫力低下人群的预防的单克隆抗体。纳米抗体(nano-antibody, Nb)是目前已知的能与抗原稳定结合的最小功能性单域抗体,具有稳定性高、亲水性强、易于表达和改造等优势。独特的分子特性使其在病毒、细菌、寄生虫等引发的传染病的预防、诊断和治疗中展现出良好的应用前景,相关研究显示纳米抗体对艾滋、流感、新型冠状病毒等都有很好的治疗效果。重点叙述纳米抗体的结构特点及其在传染性疾病中的研究进展。     

治疗性单克隆抗体研究进展

杂交瘤技术使鼠源单克隆抗体（鼠单抗）被广泛用于人类疾病的诊断和研究,建立了治疗性抗体的第一个里程碑。但随后出现的人抗鼠抗体等副作用极大地限制了鼠单抗的临床应用。随着生物学技术的发展和抗体基因结构的阐明,应用DNA重组技术和抗体库技术对鼠单抗进行人源化改造,先后出现了嵌合抗体、改型抗体和全人抗体,同时也涌现了各种单抗衍生物,它们从不同角度克服了鼠单抗临床应用的不足,未人类疾病治疗带来新的曙光。我们就上述治疗性抗体人源化的研究进展做简要综述。     

Neutralization of human papillomavirus by specific nanobodies against major capsid protein L1

The human papillomavirus (HPV) is the main cause of cervical cancer in developing countries. Rapid diagnosis and initiation of treatment of the HPV infection are critical. Various methods have been employed to reduce the immunogenicity of antibodies targeting HPV serotypes. Nanobodies are the smallest fragments of naturally occurring single-domain antibodies with their antigenbinding site compromised into a single domain. Nanobodies have remarkable properties such as high stability, solubility, and high homology to the human VH3 domain. In this study, a phagemid library was employed to enrich for nanobodies against the L1 protein of the human papilloma virus. Binding reactivity of the selected clones was evaluated using phage enzyme-linked immunosorbent assay (phage-ELISA). Finally, two nanobodies (sm5 and sm8) with the best reactivity against the Gardasil vaccine and the purified HPV-16 L1 protein were expressed and purified using a Ni(+)-NTA column. The accuracy of expression and purification of the nanobodies was confirmed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting assays. In vitro studies demonstrated that neutralization was achieved by the selected nanobodies. The ease of generation and unique features of these molecules make nanobodies promising molecules for the new generation of HPV diagnosis and therapy.     

Single-domain antibodies: a versatile and rich source of binders for breast cancer diagnostic approaches

Noninvasive early detection of breast cancer through the use of biomarkers is urgently needed since the risk of recurrence, morbidity, and mortality is closely related to disease stage at the time of primary surgery. A crucial issue in this approach is the availability of relevant markers and corresponding monoclonal antibodies suitable for the development of effective immunodiagnostic modalities. The identification of such markers from human pathological lesions and the isolation of specific antibodies using conventional approaches remain major challenges. Camelids produce functional antibodies devoid of light chains in which the single N-terminal domain of the heavy chain is fully capable of antigen binding. When produced as an independent domain, these so-called single-domain antibody fragments (sdAbs) or nanobodies have several advantages for biotechnological applications owing to their unique properties of size (13 kDa), stability, solubility, and expression yield. In this work, we have generated phage display libraries from animals immunized with breast cancer biopsies. These libraries were used to isolate sdAbs against known and relevant antigens such as HER2, or several cancer-specific sdAbs against unknown targets. We describe the identification of one these targets, cytokeratin 19, using affinity purification in combination with mass spectrometry. Some of these sdAbs were used in several straightforward diagnostic applications such as immunohistochemical analysis of tumor samples, multiplexed cytometric bead array analysis of crude samples, or an immune enrichment procedure of rare cells. Here, we demonstrate that phage display-based selection of single-domain antibodies is an efficient and high-throughput compatible approach to generate binders with excellent characteristics for the fast development of diagnostic and prognostic modalities.     

A novel VHH nanobody against the active site (the CA domain) of tumor-associated, carbonic anhydrase isoform IX and its usefulness for cancer diagnosis

Expression of carbonic anhydrase IX (CAIX) significantly increases under hypoxic conditions in tumor cells. CAIX activity is executed by the catalytic domain (CA) located on the extracellular part of the enzyme. Neutralization of CAIX enzymatic activity reduces malignancy and survival of tumor cells. To inhibit the enzymatic activity, a VHH nanobody was developed against the CA domain of CAIX using phage display technology. Following immunization of a camel with the recombinant CAIX, VHH fragments were isolated by nested PCR on lymphocyte cDNA. Binding affinity of isolated nanobodies was tested by ELISA. A clone (K24) with the highest binding affinity was expressed in a soluble form. Affinity of K24 nanobody was determined to be approx. 2.3 × 10^?5. K24 nanobody recognized the expressed CAIX in the HeLa cell lines with high selectivity and specificity. These findings thus have usefulness for the diagnosis and treatment of cancers.     

Thermodynamic consequences of mutations in vernier zone residues of a humanized anti-human epidermal growth factor receptor murine antibody, 528

To investigate the role of Vernier zone residues, which are comprised in the framework regions and underlie the complementarity-determining regions (CDRs) of antibodies, in the specific, high affinity interactions of antibodies with their targets, we focused on the variable domain fragment of murine anti-human epidermal growth factor receptor antibody 528 (m528Fv). Grafting of the CDRs of m528Fv onto a selected framework region of human antibodies, referred to as humanization, reduced the antibody's affinity for its target by a factor of 1/40. The reduction in affinity was due to a substantial reduction in the negative enthalpy change associated with binding. Crystal structures of the ligand-free antibody fragments showed no noteworthy conformational changes due to humanization, and the loop structures of the CDRs of the humanized antibodies were identical to those of the parent antibodies. Several mutants of the CDR-grafted (humanized) variable domain fragment (h528Fv), in which some of the Vernier zone residues in the heavy chain were replaced with the parental murine residues, were constructed and prepared using a bacterial expression system. Thermodynamic analyses of the interactions between the mutants and the soluble extracellular domain of epidermal growth factor receptor showed that several single mutations and a double mutation increased the negative enthalpy and heat capacity changes. Combination of these mutations, however, led to somewhat reduced negative enthalpy and heat capacity changes. The affinity of each mutant for the target was within the range for the wild-type h528Fv, and this similarity was due to enthalpy-entropy compensation. These results suggest that Vernier zone residues make enthalpic contributions to antigen binding and that the regulation of conformational entropy changes upon humanization of murine antibodies must be carefully considered and optimized.     

Generation of VHH antibodies against the Arabidopsis thaliana seed storage proteins

Antibodies and antibody derived fragments are excellent tools for the detection and purification of proteins. However, only few antibodies targeting Arabidopsis seed proteins are currently available. Here, we evaluate the process to make antibody libraries against crude protein extracts and more particularly to generate a VHH phage library against native Arabidopsis thaliana seed proteins. After immunising a dromedary with a crude Arabidopsis seed extract, we cloned the single-domain antigen-binding fragments from their heavy-chain only antibodies in a phage display vector and selected nanobodies (VHHs) against native Arabidopsis seed proteins. For 16 VHHs, the corresponding antigens were identified by affinity purification and MS/MS analysis. They were shown to bind the major Arabidopsis seed storage proteins albumin and globulin (14 to albumin and 2 to globulin). All 16 VHHs were suitable primary reagents for the detection of the Arabidopsis seed storage proteins by ELISA. Furthermore, several of the anti-albumin VHHs were used successfully for storage protein localisation via electron microscopy. The easy cloning, selection and production, together with the demonstrated functionality and applicability, strongly suggest that the VHH antibody format will play a more prominent role in future protein research, in particular for the study of native proteins.     

Applications of nanobodies in plant science and biotechnology

Key message

Present review summarizes the current applications of nanobodies in plant science and biotechnology, including plant expression of nanobodies, plant biotechnological applications, nanobody-based immunodetection, and nanobody-mediated resistance against plant pathogens.

Abstract

Nanobodies (Nbs) are variable domains of heavy chain-only antibodies (HCAbs) isolated from camelids. In spite of their single domain structure, nanobodies display many unique features, such as small size, high stability, and cryptic epitopes accessibility, which make them ideal for sophisticated applications in plants and animals. In this review, we summarize the current applications of nanobodies in plant science and biotechnology, focusing on nanobody expression in plants, plant biotechnological applications, determination of plant toxins and pathogens, and nanobody-mediated resistance against plant pathogens. Prospects and challenges of nanobody applications in plants are also discussed.

     

Nanobodies as novel therapeutic agents in envenomation

Background

An effective therapy against envenoming should be a priority in view of the high number scorpion stings and snakebites. Serum therapy is still widely applied to treat the envenomation victims; however this approach suffers from several shortcomings. The employment of monoclonal antibodies might be an outcome as these molecules are at the core of a variety of applications from protein structure determination to cancer treatment. The progress of activities in the twilight zone between genetic and antibody engineering have led to the development of a unique class of antibody fragments. These molecules possess several benefits and lack many possible disadvantages over classical antibodies. Within recombinant antibody formats, nanobodies or single domain antigen binding fragments derived from heavy chain only antibodies in camelids occupy a privileged position.

纳米抗体在癌症治疗中的应用

骆驼科动物的体内会产生一种缺失轻链的抗体,被称为重链抗体,又叫做nanobody。这种抗体只包含一个可变区,具有高亲和力、高稳定性、强组织穿透性、高效表达等优点,同时具有低毒性和低免疫原性等特性,适用于诊断、治疗和充当多种领域的实验研究工具。文中将主要讨论nanobody在癌症治疗中的应用,为nanobody的进一步研发提供思路。