Protein profiling comes of age.

Ever since DNA microarrays were first applied to the quantitation of RNA levels, there has been considerable interest in generating a protein homolog that can be used to assay cellular protein expression. A recent paper describes the first microarray that can be used for such protein profiling.

The use of recombinant antibodies in proteomics.

Recombinant antibodies are becoming increasingly important in the field of proteomics. Recent advances include the development of large phage-antibody libraries that contain high-affinity binders to almost any target protein, and new methods for high-throughput selection of antibody-antigen interactions. Coupled with a range of new screening technologies that use high-density antibody arrays to identify differentially expressed proteins, these antibody libraries can be applied to whole proteome analysis.

Antibody arrays for high-throughput screening of antibody-antigen interactions.

We have developed a novel technique for high-throughput screening of recombinant antibodies, based on the creation of antibody arrays. Our method uses robotic picking and high-density gridding of bacteria containing antibody genes followed by filter-based enzyme-linked immunosorbent assay (ELISA) screening to identify clones that express binding antibody fragments. By eliminating the need for liquid handling, we can thereby screen up to 18,342 different antibody clones at a time and, because the clones are arrayed from master stocks, the same antibodies can be double spotted and screened simultaneously against 15 different antigens. We have used our technique in several different applications, including isolating antibodies against impure proteins and complex antigens, where several rounds of phage display often fail. Our results indicate that antibody arrays can be used to identify differentially expressed proteins.

By-passing selection: direct screening for antibody-antigen interactions using protein arrays.

We have developed a system to identify highly specific antibody-antigen interactions by protein array screening. This removes the need for selection using animal immunisation or in vitro techniques such as phage or ribosome display. We screened an array of 27 648 human foetal brain proteins with 12 well-expressed antibody fragments that had not previously been exposed to any antigen. Four highly specific antibody-antigen pairs were identified, including three antibodies that bind proteins of unknown function. The target proteins were expressed at a very low copy number on the array, emphasising the unbiased nature of the screen. The specificity and sensitivity of binding demonstrates that this 'naive' screening approach could be applied to the high throughput isolation of specific antibodies against many different targets in the human proteome.

Comparable heavy and light chain pairings in normal and systemic lupus erythematosus IgG(+) B cells.

Systemic lupus erythematosus (SLE) is an autoimmune disease that is characterized by the presence of high immunoglobulin serum titers, but the mechanism by which these arise remains unclear. It has been suggested that the disease is associated with specific antibody features, including variable gene use, the presence of charged complementarity-determining region residues and/or an aberrant process of secondary light chain rearrangement. To study this in more detail, we compared variable, diversity and joining gene segment use, somatic mutation, and heavy and light chain pairings in single peripheral IgG(+) B cells between one normal (209 B cells) and two SLE (156 B cells) donors. In contrast to others, we found no systematic differences, indicating that the memory B cell repertoires in normal and SLE donors are shaped in a similar way.

Dominance of intrinsic genetic factors in shaping the human immunoglobulin Vlambda repertoire.

The expressed human immunoglobulin Vlambda repertoire demonstrates a strong bias in the use of individual Vlambda segments. Mechanisms that underlie such biases can be divided into two categories: intrinsic genetic processes that lead to the preferential rearrangement and/or expression of certain segments; and selection following light chain expression. Here, we have used two approaches to investigate the factors that shape the human Vlambda repertoire. Firstly, we characterised 136 Vlambda rearrangements (59 productive and 77 non-productive) amplified from the human genomic DNA of peripheral blood cells. Secondly, we analysed Vlambda segment use in a library of 2000 cDNA clones from a transgenic mouse containing a 380 kb region (including 15 functional Vlambda segments) from the human immunoglobulin lambda locus. By hybridisation and sequencing we found that the patterns of use of human Vlambda segments in the transgenic mouse were similar to those found in the expressed human peripheral blood repertoire and in productive and non-productive genomic DNA rearrangements. These data indicate the importance of intrinsic genetic factors in shaping the human Vlambda repertoire and highlight the remarkable conservation of the molecular mechanisms involved in the production of the antibody repertoire in mouse and man. Therefore, transgenic mice represent a good model for analysis of the human antibody repertoire and for the production of human antibodies.

Somatic insertions and deletions shape the human antibody repertoire.

We have sequenced the heavy and light chain genes from 365 IgG(+) B cells and found that 24 (6.5 %) contain somatically introduced insertions or deletions. These insertions and deletions are clustered at "hot-spots" in the antigen-binding site and frequently result in the creation of new combinations of canonical loop structures or entirely new loops that are not present in the human germline repertoire, but are similar to those seen in other species. Somatic insertion and deletion therefore provides a further mechanism for introducing structural diversity into antibodies in addition to somatic point mutation and receptor editing, which have small (single amino acid changes) and large (chain replacement) impacts on structural diversity, respectively.

Analysis of heavy and light chain pairings indicates that receptor editing shapes the human antibody repertoire.

In the bone marrow, diversity in the primary antibody repertoire is created by the combinatorial rearrangement of different gene segments and by the association of different heavy and light chains. During the secondary response in the germinal centres, antibodies are diversified by somatic mutation and possibly by further rearrangements, or "receptor editing". Here, we have analysed the pairings of heavy and light chain variable domains (VH and VL) in 365 human IgG+ B cells from peripheral blood, and established that these pairings are largely random. The repertoire is dominated by a limited number of pairings of segments and folds. Among these pairings we identified two identical mutated heavy chains in combination with two different mutated light chains (one kappa and one lambda). This shows that receptor editing occurs in the human periphery and that the same antibody lineage can be subjected to both receptor editing and somatic hypermutation. This suggests that receptor editing may be used together with somatic mutation for the affinity maturation of antibodies. We also propose that receptor editing has shaped variable gene segment use and the evolution of V gene families.

Sequence of the human immunoglobulin diversity (D) segment locus: a systematic analysis provides no evidence for the use of DIR segments, inverted D segments, "minor" D segments or D-D recombination.

We have determined the complete nucleotide sequence of the human immunoglobulin D segment locus on chromosome 14q32.3 and identified a total of 27 D segments, of which nine are new. Comparison with a database of rearranged heavy chain sequences indicates that the human antibody repertoire is created by VDJ recombination involving 25 of these 27 D segments, extensive processing at the V-D and D-J junctions and use of multiple reading frames. We could find no evidence for the proposed use of DIR segments, inverted D segments, "minor" D segments or D-D recombination. Conventional VDJ recombination, which obeys the 12/23 rule, is therefore sufficient to explain the wealth of lengths and sequences for the third hypervariable loop of human heavy chains.

The creation of diversity in the human immunoglobulin V(lambda) repertoire.

Sequence diversity in the human antibody repertoire is generated in two steps: by the combinatorial assembly of V gene segments and by somatic hypermutation. Here, we have characterised these processes for the lambda (lambda) light chain using a library of 7600 lambda cDNA clones from peripheral blood lymphocytes. By hybridisation and sequencing we found that most lambda chains are derived from the cluster of V(lambda) segments closest to the J(lambda)-C(lambda) pairs and that there is considerable variation in the use of individual V(lambda) segments (ranging from 0.02% to 27%): three of the 30 functional V(lambda) segments encode half the expressed V(lambda) repertoire. As a result of these biases, sequence diversity in the primary repertoire is focused at the centre of the antigen binding site. By contrast, somatic hypermutation spreads diversity to the periphery. Comparison with the human kappa (kappa) light chain indicates that both kappa and lambda use the same strategy for searching sequence space and have almost identical patterns of diversity in the mature antibody repertoire.

Sequence and evolution of the human germline V lambda repertoire.

We recently completed a map of the human immunoglobulin lambda (IGL) locus on chromosome 22q11.2 and showed that the V lambda genes are arranged in three distinct clusters, each containing members of different V lambda families. We have now sequenced each of these V lambda genes and determined which are functional by comparison with the expressed repertoire. Our analysis indicates that there are approximately 30 functional V lambda genes, depending on the haplotype, that belong to ten V lambda families (five V lambda 1, five V lambda 2, eight V lambda 3, three V lambda 4, three V lambda 5, one V lambda 6, two V lambda 7, one V lambda 8, one V lambda 9 and one V lambda 10). V lambda genes related to the major human V lambda families (V lambda 1, V lambda 2 and V lambda 3) predominate in species that express mainly lambda light chains.

The imprint of somatic hypermutation on the repertoire of human germline V genes.

In the human immune system, antibodies with high affinities for antigen are created in two stages. A diverse primary repertoire of antibody structures is produced by the combinatorial rearrangement of germline V gene segments and antibodies are selected from this repertoire by binding to the antigen. Their affinities are then improved by somatic hypermutation and further rounds of selection. We have dissected the sequence diversity created at each stage in response to a wide range of antigens. In the primary repertoire, diversity is focused at the centre of the binding site. With somatic hypermutation, diversity spreads to regions at the periphery of the binding site that are highly conserved in the primary repertoire. We propose that evolution has favoured this complementarity as an efficient strategy for searching sequence space and that the germline V gene families evolved to exploit the diversity created by somatic hypermutation.

The structural repertoire of the human V kappa domain.

In humans, the gene for the V kappa domain is produced by the recombination of one of 40 functional V kappa segments and one of five functional J kappa segments. We have analysed the sequences of these germline segments and of 736 rearranged V kappa genes to determine the repertoire of main chain conformations, or canonical structures, they encode. Over 96% of the sequences correspond to one of four canonical structures for the first antigen binding loop (L1) and one canonical structure for the second antigen binding loop (L2). Junctional diversity produces some variation in the length of the third antigen binding loop (L3) and in the identity of residues at the V kappa-J kappa join. However, this is limited and 70% of the rearranged sequences correspond to one of three known canonical structures for the L3 region. Furthermore, we show that the canonical structures selected during the primary response are conserved during affinity maturation: the key residues that determine the conformations of the antigen binding loops are unmutated or undergo conservative mutation. The implications of these results for immune recognition are discussed.

Organization of the human immunoglobulin lambda light-chain locus on chromosome 22q11.2.

The maps of the human immunoglobulin heavy-chain and kappa light-chain loci have recently been completed. We have now completed a map of the human lambda locus (IGL) located on chromosome 22q11.2. We mapped 52 V lambda genes from 10 V lambda families and 7 J lambda and C lambda genes on a 1140 kb contig constructed from eight YACs and 129 cosmid clones. The V lambda genes are arranged within 800 kb. Genes of the different V lambda families are organized in three clusters, V lambda II and III families (cluster A); V lambda I, V, VII and IX families (cluster B); V lambda IV, VI, VIII and X families (cluster C), in contrast to the dispersed organization of the different VH and V kappa families within the human VH and V kappa loci. We note that the most frequently used V lambda families (V lambda II and III) are proximal to the J lambda and C lambda genes. The VpreB gene, encoding part of the surrogate light chain, the GGT2 gene and the BCRL4 pseudogene were also mapped within the lambda locus.

The human immunoglobulin VH repertoire.

A complete map of the human immunoglobulin VH locus on chromosome 14 has recently been constructed. The locus is 1100kb in length and contains 51 functional VH segments interspersed amongst a similar number of pseudogenes. Here, Graham Cook and Ian Tomlinson review the organization of the locus, its polymorphism and the repertoire it encodes.

Isolation of high affinity human antibodies directly from large synthetic repertoires.

Antibody fragments of moderate affinity (approximately microM) can be isolated from repertoires of approximately 10(8) immunoglobulin genes by phage display and rounds of selection with antigen, and the affinities improved by further rounds of mutation and selection. Here, as an alternative strategy, we attempted to isolate high affinity human antibodies directly from large repertoires. We first created highly diverse repertoires of heavy and light chains entirely in vitro from a bank of human V gene segments and then, by recombination of the repertoires in bacteria, generated a large (close to 6.5 x 10(10)) synthetic repertoire of Fab fragments displayed on filamentous phage. From this repertoire we isolated Fab fragments which bound to a range of different antigens and haptens, and with affinities comparable with those of antibodies from a secondary immune response in mice (up to 4 nM). Although the VH-26 (DP-47) segment was the most commonly used segment in both artificial and natural repertoires, there were also major differences in the pattern of segment usage. Such comparisons may help dissect the contributions of biological mechanisms and structural features governing V gene usage in vivo.

A map of the human immunoglobulin VH locus completed by analysis of the telomeric region of chromosome 14q.

Analysis of the telomeric region of chromosome 14q has enabled us to complete a map of the immunoglobulin VH locus which accounts for almost all VH segments known to rearrange in B-lymphocytes. The human germline VH repertoire consists of approximately 50 functional VH segments--the exact number depending on the haplotype--spanning 1,100 kilobases upstream of the JH segments. A yeast artificial chromosome used to map these segments was isolated by its ability to provide telomere activity in yeast, suggesting that the VH locus may be located within a few kilobases of the 14q telomere. The limited structural diversity encoded by the functional VH segments demonstrates the importance of combinatorial diversity produced by VDJ joining and the association of heavy and light chains in producing the human antibody repertoire.