Human and mouse T-cell receptor loci: genomics, evolution, diversity, and serendipity

The guinea pig pancreas secretes a single trypsinogen isoform, which is defective in autoactivation

OBJECTIVES

The aim of the present study was to purify and clone the trypsinogen isoforms from the guinea pig pancreas and characterize their activation properties.

METHODS

Trypsinogens from pancreatic homogenates were isolated by ecotin-affinity chromatography, followed by cation-exchange chromatography. Activation of trypsinogens was tested with enteropeptidase, cathepsin B, and trypsin. Complementary DNAs for pretrypsinogens were cloned from total RNA after reverse transcription and polymerase chain reaction amplification.

RESULTS

Purification of trypsinogens yielded a single peak with an N-terminal amino-acid sequence of LPIDD. Cloning of pretrypsinogen cDNAs revealed 2 distinct but nearly identical isoforms. At the amino acid level, the only difference between the 2 isoforms is an Ala/Ser change at position 15 within the signal peptide. Thus, both cDNA variants give rise to the same mature trypsinogen upon secretion. Guinea pig trypsinogen is readily activated by enteropeptidase and cathepsin B but exhibits essentially no autoactivation, under conditions where human cationic and anionic trypsinogens rapidly autoactivate.

CONCLUSIONS

The observations suggest that multiple trypsinogen isoforms and their ability to autoactivate are not required universally for normal digestive physiology in mammals. Furthermore, the inability of guinea pig trypsinogen to undergo autoactivation suggests that this species might be more resistant to pancreatitis than humans, where increased autoactivation of cationic trypsinogen mutants has been linked to hereditary pancreatitis.

Comparative genomics for detecting human disease genes

Originally, comparative genomics was geared toward defining the synteny of genes between species. As the human genome project accelerated, there was an increase in the number of tools and means to make comparisons culminating in having the genomic sequence for a large number of organisms spanning the evolutionary tree. With this level of resolution and a long history of comparative biology and comparative genetics, it is now possible to use comparative genomics to build or select better animal models and to facilitate gene discovery. Comparative genomics takes advantage of the functional genetic information from other organisms, (vertebrates and invertebrates), to apply it to the study of human physiology and disease. It allows for the identification of genes and regulatory regions, and for acquiring knowledge about gene function. In this chapter, the current state of comparative genomics and the available tools are discussed in the context of developing animal model systems that reflect the clinical picture.

Unravelling the world of cis-regulatory elements

Genome-wide comparisons indicate that only studying the coding regions will not be enough for explaining the biological complexity of an organism, while the genetic variants and the epigenetic differences of cis-regulatory elements are crucial to elucidate many complicated biological phenomena. Their various regulatory functions also play indispensable roles in forming organismal polymorphism. Recent studies showed that the cis-regulatory elements can regulate gene expression as nuclear organizers, and involve in functional noncoding transcription and produce regulatory noncoding RNA molecules. Novel high-throughput strategies and in silico analysis make a great amount data of cis-regulatory elements available. Particularly, the computational methods could help to combine reductionist studies with network biomedical investigations, and begin the era to understand organismal regulatory events at systems biology level.

Regional distribution of human trypsinogen 4 in human brain at mRNA and protein level

Gene PRSS3 on chromosome 9 of the human genome encodes, due to alternative splicing, both mesotrypsinogen and trypsinogen 4. Mesotrypsinogen has long been known as a minor component of trypsinogens expressed in human pancreas, while the mRNA for trypsinogen 4 has recently been identified in brain and other human tissues. We measured the amount of trypsinogen 4 mRNA and the quantity of the protein as well in 17 selected areas of the human brain. Our data suggest that human trypsinogen 4 is widely but unevenly distributed in the human brain. By immunohistochemistry, here we show that this protease is localized in neurons and glial cells, predominantly in astrocytes. In addition to cellular immunoreactivity, human trypsinogen 4 immunopositive dots were detected in the extracellular matrix, supporting the view that human trypsinogen 4 might be released from the cells under special conditions.

Interchromosomal segmental duplications explain the unusual structure of PRSS3, the gene for an inhibitor-resistant trypsinogen

Homo sapiens possess several trypsinogen or trypsinogen-like genes of which three (PRSS1, PRSS2, and PRSS3) produce functional trypsins in the digestive tract. PRSS1 and PRSS2 are located on chromosome 7q35, while PRSS3 is found on chromosome 9p13. Here, we report a variation of the theme of new gene creation by duplication: the PRSS3 gene was formed by segmental duplications originating from chromosomes 7q35 and 11q24. As a result, PRSS3 transcripts display two variants of exon 1. The PRSS3 transcript whose gene organization most resembles PRSS1 and PRSS2 encodes a functional protein originally named mesotrypsinogen. The other variant is a fusion transcript, called trypsinogen IV. We show that the first exon of trypsinogen IV is derived from the noncoding first exon of LOC120224, a chromosome 11 gene. LOC120224 codes for a widely conserved transmembrane protein of unknown function. Comparative analyses suggest that these interchromosomal duplications occurred after the divergence of Old World monkeys and hominids. PRSS3 transcripts consist of a mixed population of mRNAs, some expressed in the pancreas and encoding an apparently functional trypsinogen and others of unknown function expressed in brain and a variety of other tissues. Analysis of the selection pressures acting on the trypsinogen gene family shows that, while the apparently functional genes are under mild to strong purifying selection overall, a few residues appear under positive selection. These residues could be involved in interactions with inhibitors.

Abnormal V(D)J recombination of T cell receptor beta locus in SMAR1 transgenic mice

Scaffold/matrix-associated region-1-binding protein (SMAR1) specifically interacts with the MARbeta sequence, which is located 400-bp upstream of the murine TCRbeta enhancer and is highly expressed during the DP stage of thymocyte development. To further analyze the functions of SMAR1, transgenic mice were generated that express SMAR1 in a tissue-independent manner. SMAR1-overexpressing mice exhibit severely altered frequency of the T cells expressing commonly used Vbetas (Vbeta5.1/5.2 and Vbeta8.1/8.2/8.3). The rearrangements of Vbeta5.1/5.2, Vbeta8.1/8.2/8.3 loci are also reduced in SMAR1 transgenic mice. The T cells in SMAR1 transgenic mice exhibit a mild perturbation at the early DN stage. SMAR1 transgenic mice exhibit hypercellular lymph nodes and spleen accompanied with prominent architectural defects in these organs. These results indicate that SMAR1 plays an important role in the regulation of T cell development as well as V(D)J recombination besides maintaining the architecture of the lymphoid organs.

Comparative genomic analysis as a tool for biological discovery

The recent completion of the human genome sequence has enabled the identification of a large fraction of our gene catalogue and their physical chromosomal position. However, current efforts lag at defining the cis-regulatory sequences that control the spatial and temporal patterns of each gene's expression. This task remains difficult due to our lack of knowledge of the vocabulary controlling gene regulation and the vast genomic search space, with greater than 95% of our genome being noncoding. Recent comparative genomic-based strategies are beginning to aid in the identification of functional sequences based on their high levels of evolutionary conservation. This has proven successful for comparisons between closely related species such as human-primate or human-mouse, but also holds true for distant evolutionary comparisons, such as human-fish or human-bird. In this review we provide support for the utility of cross-species sequence comparisons by illustrating several applications of this strategy, including the identification of new genes and functional non-coding sequences. We also discuss emerging concepts as this field matures, such as how to properly select which species for comparison, which may differ significantly between independent studies.

Increase of TCR V beta accessibility within E beta regulatory region influences its recombination frequency but not allelic exclusion

Seventy percent of the murine TCRbeta locus (475 kb) was deleted to generate a large deleted TCRbeta (beta(LD)) allele to investigate a possible linkage between germline transcription, recombination frequency, and allelic exclusion of the TCR Vbeta genes. In these beta(LD/LD) mice, the TCRbeta gene locus contained only four Vbeta genes at the 5' side of the locus, and consequently, the Vbeta10 gene was located in the original Dbeta1-Jbeta1cluster within the Ebeta regulatory region. We showed that the frequency of recombination and expression of the Vbeta genes are strongly biased to Vbeta10 in these mutant mice even though the proximity of the other three 5'Vbeta genes was also greatly shortened toward the Dbeta-Jbeta cluster and the Ebeta enhancer. Accordingly, the germline transcription of the Vbeta10 gene in beta(LD/LD) mice was exceptionally enhanced in immature double negative thymocytes compared with that in wild-type mice. During double negative-to-double positive transition of thymocytes, the level of Vbeta10 germline transcription was prominently increased in beta(LD/LD) recombination activating gene 2-deficient mice receiving anti-CD3epsilon Ab in vivo. Interestingly, however, despite the increased accessibility of the Vbeta10 gene in terms of transcription, allelic exclusion of this Vbeta gene was strictly maintained in beta(LD/LD) mice. These results provide strong evidence that increase of Vbeta accessibility influences frequency but not allelic exclusion of the TCR Vbeta rearrangement if the Vbeta gene is located in the Ebeta regulatory region.

Insights from human/mouse genome comparisons

Large-scale public genomic sequencing efforts have provided a wealth of vertebrate sequence data poised to provide insights into mammalian biology. These include deep genomic sequence coverage of human, mouse, rat, zebrafish, and two pufferfish ( Fugu rubripes and Tetraodon nigroviridis) (Aparicio et al. 2002; Lander et al. 2001; Venter et al. 2001; Waterston et al. 2002). In addition, a high-priority has been placed on determining the genomic sequence of chimpanzee, dog, cow, frog, and chicken (Boguski 2002). While only recently available, whole genome sequence data have provided the unique opportunity to globally compare complete genome contents. Furthermore, the shared evolutionary ancestry of vertebrate species has allowed the development of comparative genomic approaches to identify ancient conserved sequences with functionality. Accordingly, this review focuses on the initial comparison of available mammalian genomes and describes various insights derived from such analysis.

Structural, antigenic and evolutionary analyses of immunoglobulins and T cell receptors

We have had the pleasure of collaborating with Allen Edmundson for the past 15 years on the structure, binding properties and evolution of immunoglobulins and T cell receptors. Among the most significant contributions of our joint efforts were: (1) the predictive use of structural features of immunoglobulin domains to model the three-dimensional structures of the immunoglobulin domains of human T-cell receptor alpha and beta chains as well as shark light chains and V(H) domains; (2) the finding that normal humans and other vertebrates express autoantibodies against combining site epitopes of their own T cell receptors; (3) the mapping of the peptide autoepitopes recognized in health, autoimmunity and retroviral infection; and (4) the determination that epitope recognition promiscuity is a characteristic property of the combining sites of IgM immunoglobulins ranging from those of sharks to those of humans. We briefly review the salient findings and status of these studies and indicate the future directions that we will pursue in their continuation.

Genomic strategies to identify mammalian regulatory sequences

With the continuing accomplishments of the human genome project, high-throughput strategies to identify DNA sequences that are important in mammalian gene regulation are becoming increasingly feasible. In contrast to the historic, labour-intensive, wet-laboratory methods for identifying regulatory sequences, many modern approaches are heavily focused on the computational analysis of large genomic data sets. Data from inter-species genomic sequence comparisons and genome-wide expression profiling, integrated with various computational tools, are poised to contribute to the decoding of genomic sequence and to the identification of those sequences that orchestrate gene regulation. In this review, we highlight several genomic approaches that are being used to identify regulatory sequences in mammalian genomes.

Modeling the feasibility of whole genome shotgun sequencing using a pairwise end strategy

In pairwise end sequencing, sequences are determined from both ends of random subclones derived from a DNA target. Sufficiently similar overlapping end sequences are identified and grouped into contigs. When a clone's paired end sequences fall in different contigs, the contigs are connected together to form scaffolds. Increasingly, the goals of pairwise strategies are large and highly repetitive genomic targets. Here, we consider large-scale pairwise strategies that employ mixtures of subclone sizes. We explore the properties of scaffold formation within a hybrid theory/simulation mathematical model of a genomic target that contains many repeat families. Using this model, we evaluate problems that may arise, such as falsely linked end sequences (due either to random matches or to homologous repeats) and scaffolds that terminate without extending the full length of the target. We illustrate our model with an exploration of a strategy for sequencing the human genome. Our results show that, for a strategy that generates 10-fold sequence coverage derived from the ends of clones ranging in length from 2 to 150 kb, using an appropriate rule for detecting overlaps, we expect few false links while obtaining a single scaffold extending the length of each chromosome.

Chromatin remodeling by the T cell receptor (TCR)-beta gene enhancer during early T cell development: Implications for the control of TCR-beta locus recombination

Gene targeting studies have shown that T cell receptor (TCR)-beta gene expression and recombination are inhibited after deletion of an enhancer (Ebeta) located at the 3' end of the approximately 500-kb TCR-beta locus. Using knockout mouse models, we have measured, at different regions throughout the TCR-beta locus, the effects of Ebeta deletion on molecular parameters believed to reflect epigenetic changes associated with the control of gene activation, including restriction endonuclease access to chromosomal DNA, germline transcription, DNA methylation, and histone H3 acetylation. Our results demonstrate that, in early developing thymocytes, Ebeta contributes to major chromatin remodeling directed to an approximately 25-kb upstream domain comprised of the Dbeta-Jbeta locus regions. Accordingly, treatment of Ebeta-deleted thymocytes with the histone deacetylase inhibitor trichostatin A relieved the block in TCR-beta gene expression and promoted recombination within the Dbeta-Jbeta loci. Unexpectedly, however, epigenetic processes at distal Vbeta genes on the 5' side of the locus and at the 3' proximal Vbeta14 gene appear to be less dependent on Ebeta, suggesting that Ebeta activity is confined to a discrete region of the TCR-beta locus. These findings have implications with respect to the developmental control of TCR-beta gene recombination, and the process of allelic exclusion at this locus.

T cell development in TCR beta enhancer-deleted mice: implications for alpha beta T cell lineage commitment and differentiation

T cell differentiation in the mouse thymus is an intricate, highly coordinated process that requires the assembly of TCR complexes from individual components, including those produced by the precisely timed V(D)J recombination of TCR genes. Mice carrying a homozygous deletion of the TCR beta transcriptional enhancer (E beta) demonstrate an inhibition of V(D)J recombination at the targeted TCR beta locus and a block in alpha beta T cell differentiation. In this study, we have characterized the T cell developmental defects resulting from the E beta-/- mutation, in light of previously reported results of the analyses of TCR beta-deficient (TCR beta-/-) mice. Similar to the latter mice, production of TCR beta-chains is abolished in the E beta-/- animals, and under these conditions differentiation into cell-surface TCR-, CD4+CD8+ double positive (DP) thymocytes depends essentially on the cell-autonomous expression of TCR delta-chains and, most likely, TCR gamma-chains. However, contrary to previous reports using TCR beta-/- mice, a minor population of TCR gamma delta+ DP thymocytes was found within the E beta-/- thymi, which differ in terms of T cell-specific gene expression and V(D)J recombinase activity, from the majority of TCR-, alpha beta lineage-committed DP thymocytes. We discuss these data with respect to the functional role of E beta in driving alpha beta T cell differentiation and the mechanism of alpha beta T lineage commitment.

Enhancer control of V(D)J recombination at the TCRbeta locus: differential effects on DNA cleavage and joining

Deletion of the TCRbeta transcriptional enhancer (Ebeta) results in nearly complete inhibition of V(D)J recombination at the TCRbeta locus and a block in alpha beta T cell development. This result, along with previous work from many laboratories, has led to the hypothesis that transcriptional enhancers affect V(D)J recombination by regulating the accessibility of the locus to the recombinase. Here we test this hypothesis by performing a detailed analysis of the recombination defect in Ebeta-deleted (Ebeta-/-) mice using assays that detect various reaction intermediates and products. We found double-strand DNA breaks at recombination signal sequences flanking Dbeta and Jbeta gene segments in Ebeta-/- thymuses at about one-third to one-thirtieth the level found in thymuses with an unaltered TCRbeta locus. These sites are also subject to in vitro cleavage by the V(D)J recombinase in both Ebeta-/- and Ebeta+/+ thymocyte nuclei. However, the corresponding Dbeta-to-Jbeta coding joints are further reduced (by 100- to 300-fold) in Ebeta-/- thymuses. Formation of extrachromosomal Dbeta-to-Jbeta signal joints appears to be intermediately affected and nonstandard Dbeta-to-Dbeta joining occurs at the Ebeta-deleted alleles. These data indicate that, unexpectedly, loss of accessibility alone cannot explain the loss of TCRbeta recombination in the absence of the Ebeta element and suggest an additional function for Ebeta in the process of DNA repair at specific TCRbeta sites during the late phase of the recombination reaction.

Duplication and distribution of repetitive elements and non-unique regions in the human genome

Genome mapping efforts and the initial sequencing of large segments of human DNA permit ongoing assessment of the patterns and extent of sequence duplication and divergence in the human genome. Initial sequence data indicate that the most highly repetitive sequences show isochore-related enrichment and clustering produced by successive insertional recombination and local duplication of particular repetitive elements. Regional duplication is also observed for a number of otherwise unique genomic sequences and thereby makes these segments become repetitive. The consequences of these duplication events are: (1) clustering of related genes, along with a variety of coregulatory mechanisms; and (2) recombinations between the nearby homologous sequences, which can delete genes in individuals and account for a significant fraction of human genetic disease.

X chromosome map at 75-kb STS resolution, revealing extremes of recombination and GC content

A YAC/STS map of the X chromosome has reached an inter-STS resolution of 75 kb. The map density is sufficient to provide YACs or other large-insert clones that are cross-validated as sequencing substrates across the chromosome. Marker density also permits estimates of regional gene content and a detailed comparison of genetic and physical map distances. Five regions are detected with relatively high G + C, correlated with gene richness; and a 17-Mb region with very low recombination is revealed between the Xq13.3 [XIST] and Xq21.3 XY homology loci.

Ordered shotgun sequencing of a 135 kb Xq25 YAC containing ANT2 and four possible genes, including three confirmed by EST matches

Ordered shotgun sequencing (OSS) has been successfully carried out with an Xq25 YAC substrate. yWXD703 DNA was subcloned into lambda phage and sequences of insert ends of the lambda subclones were used to generate a map to select a minimum tiling path of clones to be completely sequenced. The sequence of 135 038 nt contains the entire ANT2 cDNA as well as four other candidates suggested by computer-assisted analyses. One of the putative genes is homologous to a gene implicated in Graves' disease and it, ANT2 and two others are confirmed by EST matches. The results suggest that OSS can be applied to YACs in accord with earlier simulations and further indicate that the sequence of the YAC accurately reflects the sequence of uncloned human DNA.