Quantitative and qualitative approaches to GOD: the first 10 years of the clonal selection theory

Of the contentious issues surrounding the clonal selection theory, one of the most influential was that of the mechanism for the generation of diversity of antibody specificity. While Burnet's qualitative theory assumed a very large antibody repertoire, Talmage provided a detailed quantitative argument supporting only 5000 individual globulin patterns that provided an antiserum its specificity through combinatorial action. This methodological difference between the two men, and the mechanistic difference between their models, is key to the understanding of the clonal selection theory, its later acceptance and the proportion of credit paid to Burnet.     

Junctional diversity is essential to antibody activity

Many mechanisms of antibody diversification have been shown to exist, including combinatorial pairings of heavy and light chains, the use of multiple gene segments (combinatorial diversity), and the imprecise joining of these gene segments (junctional diversity). The contributions of each of these mechanisms to functional antibody activity has not been fully explored, especially in the case of junctional diversity. A chain recombination experiment between an anti-arsonate monoclonal antibody and an anti-oxazolone molecule in which light chains differ essentially only at the V/J junctional position show that junctional diversity may play an important role in antigen binding.     

Antibody binding loop insertions as diversity elements

In the use of non-antibody proteins as affinity reagents, diversity has generally been derived from oligonucleotide-encoded random amino acids. Although specific binders of high-affinity have been selected from such libraries, random oligonucleotides often encode stop codons and amino acid combinations that affect protein folding. Recently it has been shown that specific antibody binding loops grafted into heterologous proteins can confer the specific antibody binding activity to the created chimeric protein. In this paper, we examine the use of such antibody binding loops as diversity elements. We first show that we are able to graft a lysozyme-binding antibody loop into green fluorescent protein (GFP), creating a fluorescent protein with lysozyme-binding activity. Subsequently we have developed a PCR method to harvest random binding loops from antibodies and insert them at predefined sites in any protein, using GFP as an example. The majority of such GFP chimeras remain fluorescent, indicating that binding loops do not disrupt folding. This method can be adapted to the creation of other nucleic acid libraries where diversity is flanked by regions of relative sequence conservation, and its availability sets the stage for the use of antibody loop libraries as diversity elements for selection experiments.     

Reflections on the clonal-selection theory

How do we account for the immune system's ability to produce antibodies in response to new antigens? It has been 50 years since F. Macfarlane Burnet published his answer to this question: the clonal-selection theory of antibody diversity. The idea that specificity for diverse antigens exists before these antigens are encountered was a radical notion at the time, but one that became widely accepted. In this article, Nature Reviews Immunology asks six key scientists for their thoughts and opinions on the clonal-selection theory, from its first proposal to their views of it today.     

催化抗体研究新进展

催化抗体也叫抗体酶,是具有催化活性的免疫球蛋白.由于它兼具抗体的高度选择性和酶的高效催化性,因而催化抗体制备技术的开发预示着可以人为生产适应各种用途的,特别是自然界不存在的高效催化剂,对生物学、化学和医学等多种学科有重要的理论意义和实用价值.综述了催化抗体研究的最新进展,讨论了该领域目前存在的问题,提出了解决这些问题的可能办法.     

Diverse structural solutions to catalysis in a family of antibodies

BACKGROUND: Small organic molecules coupled to a carrier protein elicit an antibody response on immunisation. The diversity of this response has been found to be very narrow in several cases. Some antibodies also catalyse chemical reactions. Such catalytic antibodies are usually identified among those that bind tightly to an analogue of the transition state (TSA) of the relevant reaction; therefore, catalytic antibodies are also thought to have restricted diversity. To further characterise this diversity, we investigated the structure and biochemistry of the catalytic antibody 7C8, one of the most efficient of those which enhance the hydrolysis of chloramphenicol esters, and compared it to the other catalytic antibodies elicited in the same immunisation. RESULTS: The structure of a complex of the 7C8 antibody Fab fragment with the hapten TSA used to elicit it was determined at 2.2 A resolution. Structural comparison with another catalytic antibody (6D9) raised against the same hapten revealed that the two antibodies use different binding modes. Furthermore, whereas 6D9 catalyses hydrolysis solely by transition-state stabilisation, data on 7C8 show that the two antibodies use mechanisms where the catalytic residue, substrate specificity and rate-limiting step differ. CONCLUSIONS: Our results demonstrate that substantial diversity may be present among antibodies catalysing the same reaction. Therefore, some of these antibodies represent different starting points for mutagenesis aimed at boosting their activity. This increases the chance of obtaining more proficient catalysts and provides opportunities for tailoring catalysts with different specificities.     

The expression of antibody diversity in natural and laboratory-made polyploid individuals of the clawed toad Xenopus

Antibody diversity, as measured by isoelectric focusing of dinitrophenol-specific antibodies, was compared in different polyploid species of the clawed toad Xenopus. Antibody heterogeneity increased with chromosome number and DNA content from Xenopus tropicalis (2n=20 chromosomes) to Xenopus ruwenzoriensis (2n=108 chromosomes). Laboratory allopolyploids made by hybridization between two species showing different antibody diversities and different chromosome numbers gave antibody patterns intermediate between the two parents. On the other hand, autopolyploid individuals showed no increase in antibody diversity, showing that increased polyploidy alone cannot be responsible for increased heterogeneity. In contrast to the increase in antibody diversity following polyploidization, the number of expressed major histocompatibility complex alleles, as measured by a mixed lymphocyte reaction, did not increase. This locus appeared to be diploid or in the process of rediploidization in all the Xenopus species studied. Selection has thus operated differentially on the polyploid immunoglobulin and major histocompatibility loci. It apparently preserved the additional heterogeneity acquired for immunoglobulins favoring the expression of an expanded antibody repertoire in polyploid species.     

人源天然ScFv噬菌体抗体库的构建及鉴定

噬菌体抗体库技术是获得治疗性抗体的一条重要途径。以20份健康人外周血为样本,通过提取淋巴细胞、逆转录－PCR（RT PCR）、抗体可变区基因的扩增、重叠PCR获得单链抗体（ScFv）基因,将ScFv克隆入噬粒载体,通过近300次的电转化获得了库容量为1.3×109的全人源天然ScFv噬菌体抗体库。通过随机挑克隆测序和用5种不同抗原筛选对抗体库进行了初步验证。随机测序表明抗体库具有较好的多样性,用5种不同抗原对其进行筛选,均获得了特异性噬菌体抗体的不同富集,表明成功构建了一个多样性良好的人源天然ScFv噬菌体抗体库。     

In vivo recombination as a tool to generate molecular diversity in phage antibody libraries

The creation of diversity in populations of polypeptides has become an important tool in the derivation of polypeptides with useful characteristics. This requires efficient methods to create diversity coupled with methods to select polypeptides with desired properties. In this review we describe the use of in vivo recombination as a powerful way to generate diversity. The novel principles for the recombination process and several applications of this process for the creation of phage antibody libraries are described. The advantage and disadvantages are discussed and possible future exploitation presented.     

In vivo recombination as a tool to generate molecular diversity in phage antibody libraries

The creation of diversity in populations of polypeptides has become an important tool in the derivation of polypeptides with useful characteristics. This requires efficient methods to create diversity coupled with methods to select polypeptides with desired properties. In this review we describe the use of in vivo recombination as a powerful way to generate diversity. The novel principles for the recombination process and several applications of this process for the creation of phage antibody libraries are described. The advantage and disadvantages are discussed and possible future exploitation presented.     

Construction and characterization of a pseudo-immune human antibody library using yeast surface display

Lymphocytes from eight individuals out of 60 healthy donors, whose plasmas showed relatively higher antibody titer for a target antigen of death receptor 5 (DR5), were selected for the source of antibody genes to construct so called an anti-DR5 pseudo-immune human single-chain fragment variable (scFv) library on the yeast cell surface (approximately 2x10(6) diversity). Compared with a large nonimmune human scFv library (approximately 1x10(9) diversity), the repertoire of the pseudo-immune scFv library was significantly biased toward the target antigen, which facilitated rapid enrichments of the target-specific high affinity scFvs during selections by fluorescence activated cell sortings. Isolated scFvs, HW5 and HW6, from the pseudo-immune library showed much higher specificity and affinity for the targeted antigen than those from the nonimmune library. Our results suggest that a pseudo-immune antibody library is very efficient to isolate target-specific high affinity antibody from a relatively small sized library.     

Low human immunodeficiency virus envelope diversity correlates with low in vitro replication capacity and predicts spontaneous control of plasma viremia after treatment interruptions

Genetic diversity of viral isolates in human immunodeficiency virus (HIV)-infected individuals varies substantially. However, it remains unclear whether HIV-related disease progresses more rapidly in patients harboring virus swarms with low or high diversity and, in the same context, whether high or low diversity is required to induce potent humoral and cellular immune responses. To explore whether viral diversity predicts virologic control, we studied HIV-infected patients who received antiretroviral therapy (ART) for years before undergoing structured treatment interruptions (STI). Viral diversity before initiation of ART and the ability of the patients to contain viremia after STI and final cessation of treatment was evaluated. Seven out of 21 patients contained plasma viremia at low levels after the final treatment cessation. Clonal sequences encompassing the envelope C2V3C3 domain derived from plasma prior to treatment, exhibited significantly lower diversity in these patients compared to those derived from patients with poor control of viremia. Viral diversity pre-ART correlated with the viral replication capacity of rebounding virus isolates during STI. Neutralizing antibody activity against autologous virus was significantly higher in patients who controlled viremia and was associated with lower pretreatment diversity. No such association was found with binding antibodies directed to gp120. In summary, lower pretreatment viral diversity was associated with spontaneous control of viremia, reduced viral replication capacity and higher neutralizing antibody titers, suggesting a link between viral diversity, replication capacity, and neutralizing antibody activity.     

Interspecies and interantigenic evaluation of a crossreactive rat idiotype

An interstrain crossreactive idiotype (ID 1), present on rat antibodies to streptococcal group A carbohydrate (SACHO), was examined for both antigen and species specificity. In a test employing a sensitive radioimmunoassay, ID 1 was undetectable in both preimmunization sera and on rat antibodies to poly-glutamic acid⁵⁰-alanine⁵⁰ obtained from animals which subsequently expressed ID 1 on anti-SACHO antibodies. Antigenically distinct from lambda light (L)-chain isotypic determinants, ID 1 was found to require antibody heavy-chain and L-chain interaction for complete expression. The inability to detect ID 1 on anti-SACHO antibodies produced by goats, rabbits, chickens, and nurse sharks suggests the species specificity of ID 1. These and previous observations on idiotypy favor the theory that germline genes are important in coding for rat antibody diversity to SACHO.     

A Novel Human scFv Library with Non-Combinatorial Synthetic CDR Diversity

The present work describes the construction and validation of a human scFv library with a novel design approach to synthetic complementarity determining region (CDR) diversification. The advantage of synthetic antibody libraries includes the possibility of exerting fine control over factors like framework sequences, amino acid and codon usage, and CDR diversity. However, random combinatorial synthesis of oligonucleotides for CDR sequence diversity also produces many clones with unnatural sequences and/or undesirable modification motifs. To alleviate these issues, we designed and constructed a novel semi-synthetic human scFv library with non-combinatorial, pre-designed CDR diversity and a single native human framework each for heavy, kappa, and lambda chain variable domains. Next-generation sequencing analysis indicated that the library consists of antibody clones with highly nature-like CDR sequences and the occurrence of the post-translational modification motifs is minimized. Multiple unique clones with nanomolar affinity could be isolated from the library against a number of target antigens, validating the library design strategy. The results demonstrate that it is possible to construct a functional antibody library using low, non-combinatorial synthetic CDR diversity, and provides a new strategy for the design of antibody libraries suitable for demanding applications.     

Island theory, matrix effects and species richness patterns in habitat fragments

Island biogeography theory, created initially to study diversity patterns on islands, is often applied to habitat fragments. A key but largely untested assumption of this application of theory is that landscape matrix species composition is non‐overlapping with that of the islands. We tested this assumption in successional old field patches in a closely mowed matrix, and because our patches are appropriately viewed as sets of contiguous habitat units we studied patterns of species richness per unit area. Previous studies at our site did not find that diversity patterns on patch ‘islands’ conformed to predictions of island biogeography theory. Our results indicate that when matrix species are removed from the patch samples, diversity patterns conform better to theory. We suggest that classical island theory remains an appropriate tool to study diversity patterns in fragmented habitats, but that allowances should be made for spill‐over colonization of ‘islands’ from the ‘sea’.     

鱼类免疫球蛋白基因结构及抗体多样性的遗传机制

本文对鱼类免疫球蛋白的基因结构以及抗体多样性产生的遗传机制作一综述。免疫球蛋白重链和轻链是由不同染色体上的多基因座编码的,在鱼类的不同分类单元中具有不同的基因组织方式。鱼类抗体可以识别外界为数众多的抗原,其多样性主要是由以下遗传机制产生的：种系V区编码区段的多样性、V (D) J区段组合的多样性、基因重组的不精确性、基因转换、体细胞突变以及H和L链的随机组合等。 Gene Structure and Genetic Diversity of Immunoglobulins in Fish ZHANG Yong-an,NIE Pin,ZHU Zuo-yan State Key Laboratory of Freshwater Ecology and Biotechnology,Institute of Hydrobiology,Chinese Academy of Sciences,Wuhan 430072,China Abstract:The current knowledge concerning the structure of fish immunoglobulin (Ig) genes and the genetic mechanisms in generating fish antibody diversities is reviewed.The heavy (H-) and light (L-) chains of the immunoglobulin are encoded by multigenic loci on separate chromosomes.In different taxa of fish,the Ig genes are organized in different patterns.Fish antibody can recognize various foreign antigens,and the antibody diversity is generated by the following genetic mechanisms:the sequence diversity within the segments encoding the variable domain,the combinatorial diversity of V (D) J segments,the imprecision of rearrangements,gene conversion,somatic hypermutation,and the combination of H- and L-chain. Key words：immunoglobulin; gene; antibody; diversity; fish     

Engineering antibodies by yeast display

Since its first application to antibody engineering 15years ago, yeast display technology has been developed into a highly potent tool for both affinity maturing lead molecules and isolating novel antibodies and antibody-like species. Robust approaches to the creation of diversity, construction of yeast libraries, and library screening or selection have been elaborated, improving the quality of engineered molecules and certainty of success in an antibody engineering campaign and positioning yeast display as one of the premier antibody engineering technologies currently in use. Here, we summarize the history of antibody engineering by yeast surface display, approaches used in its application, and a number of examples highlighting the utility of this method for antibody engineering.     

Island phytophagy: explaining the remarkable diversity of plant-feeding insects

Plant-feeding insects have undergone unparalleled diversification among different plant taxa, yet explanations for variation in their diversity lack a quantitative, predictive framework. Island biogeographic theory has been applied to spatially discrete habitats but not to habitats, such as host plants, separated by genetic distance. We show that relationships between the diversity of gall-inducing flies and their host plants meet several fundamental predictions from island biogeographic theory. First, plant-taxon genetic distinctiveness, an integrator for long-term evolutionary history of plant lineages, is a significant predictor of variance in the diversity of gall-inducing flies among host-plant taxa. Second, range size and structural complexity also explain significant proportions of the variance in diversity of gall-inducing flies among different host-plant taxa. Third, as with other island systems, plant-lineage age does not predict species diversity. Island biogeographic theory, applied to habitats defined by genetic distance, provides a novel, comprehensive framework for analysing and explaining the diversity of plant-feeding insects and other host-specific taxa.     

Crystallization and preliminary X-ray diffraction studies of antigen--antibody complexes

Monoclonal antibodies of predefined specificity have been purified and crystallized as single components or complexed with their specific antigens. The intersegmental flexibility of antibody molecules has imposed the strategy of attempting to crystallize their Fab fragments separately. Intrasegmental mobility in Fabs has rarely been an obstacle to their crystallization. The immune system, however, provides a large functional and structural diversity of antibody molecules suitable for crystallization and X-ray diffraction studies.     

Length of the antibody heavy chain complementarity determining region 3 as a specificity-determining factor

The antigen binding site of an antibody is made up of residues residing in six hypervariable loops of the heavy and light chains. In most cases several or all of these loops are required for the establishment of the antigen-binding surface. Five of these loops display a limited diversity in length and sequence while the third complementarity determining region (CDR) of the heavy chain is highly different between antibodies not only with respect to sequence but also with respect to length. Its extensive diversity is a key component in the establishment of binding sites allowing for the recognition of essentially any antigen by humoral immunity. The relative importance of its sequence vs its length diversity in this context is however, not very well established. To investigate this matter further we have used an approach employing combinatorial antibody libraries and antigen-specific selection in the search for CDRH3 length and sequence diversity compatible with a given antigen specificity, the major antigenic determinant on the tumour-associated antigen mucin-1. In this way we have now defined heavy chain CDR3 length as a critical parameter in the creation of an antigen-specific binding site. We also propose that this may reflect a dependence of a particular structure of this hypervariable loop, the major carrier of diversity in the binding site, for establishment of a given specificity.