Lack of N regions in antigen receptor variable region genes of TdT-deficient lymphocytes

Selective inhibitors of terminal deoxyribonucleotidyltransferase (TdT): baicalin and genistin

Studies of mammalian terminal deoxyribonucleotidyltransferase (TdT) are facilitated by use of inhibitors that selectively knock down the activity of the enzyme. We have screened for selective inhibitors of TdT and identified a natural compound with this property in the Japanese vegetable, Arctium lappa. The compound has little effect on the activities of mammalian DNA polymerases, such as alpha, beta, delta or lambda polymerase, and prokaryotic DNA polymerases, such as Taq DNA polymerase, T4 DNA polymerase and Klenow fragment. H1- and C13-NMR spectroscopic analyses showed the compound to be baicalin, a compound previously reported as an anti-inflammatory or antipyretic agent. The IC50 value of baicalin to TdT was 18.6 microM. We also found that genistin, a baicalin derivative known to be antimutagenic, more selectively inhibited TdT activity than baicalin, although its IC50 value was weaker (28.7 microM). Genistin and baicalin also inhibited the activity of truncated TdT (the so-called pol beta core domain) in which the BRCT motif was deleted in its N-terminal region. In kinetic analyses, inhibition by either genistin or baicalin was competitive with the primer and non-competitive with the dNTP substrate. The compounds may, therefore, bind directly to the primer-binding site of TdT and simultaneously disturb dNTP substrate incorporation into the primer. Genistin and baicalin should prove to be useful agents for studying TdT.

DNA Joint Dependence of Pol X Family Polymerase Action in Nonhomologous End Joining

DNA double strand breaks (DSBs) can be rejoined directly by the nonhomologous end-joining (NHEJ) pathway of repair. Nucleases and polymerases are required to promote accurate NHEJ when the terminal bases of the DSB are damaged. The same enzymes also participate in imprecise rejoining and joining of incompatible ends, important mutagenic events. Previous work has shown that the Pol X family polymerase Pol4 is required for some but not all NHEJ events that require gap filling in Saccharomyces cerevisiae. Here, we systematically analyzed DSB end configurations and found that gaps on both strands and overhang polarity are the principal factors that determine whether a joint requires Pol4. DSBs with 3'-overhangs and a gap on each strand strongly depended on Pol4 for repair, DSBs with 5'-overhangs of the same sequence did not. Pol4 was not required when 3'-overhangs contained a gap on only one strand, however. Pol4 was equally required at 3'-overhangs of all lengths within the NHEJ-dependent range but was dispensable outside of this range, indicating that Pol4 is specific to NHEJ. Loss of Pol4 did not affect the rejoining of DSBs that utilized a recessed microhomology or DSBs bearing 5'-hydroxyls but no gap. Finally, mammalian Pol X polymerases were able to differentially complement a pol4 mutation depending on the joint structure, demonstrating that these polymerases can participate in yeast NHEJ but with distinct properties.

Assembly of silent chromatin during thymocyte development

Epigenetic events that contribute to the assembly and maintenance of silent chromatin structures have been defined through genetic, molecular, and cytological studies in a variety of eukaryotic model organisms. However, the precise cascade of events responsible for converting a developmentally regulated gene from an active euchromatic state to a heritably silent heterochromatic state remains to be elucidated. To establish a molecular framework for studying this cascade, we examined the temporal order of events associated with silencing of the murine terminal transferase (Dntt) gene during thymocyte maturation. This article describes our findings in the context of current knowledge of gene silencing mechanisms.

Jα-gene segment usage and the CDR3 diversity of porcine TCRα-chain cDNA clones from the PBL of a five-month-old pig and the thymus of a one-month-old pig

Porcine T-cell receptor alpha (TCRalpha)-chain cDNA clones were isolated from libraries made from two different sources, the thymus of a 1-month-old LW strain pig and the peripheral blood lymphocytes (PBL) of a 5-month-old Clawn strain pig. Among 109 cDNA clones with the Jalpha-gene segment, 44 different Jalpha-gene segments were found out of the 61 Jalpha-gene segments previously identified in the porcine germline sequence. Among the 103 complete TCRalpha-chain cDNA clones with the rearranged Valpha- and Jalpha-gene segments, 33 different Valpha-gene segments were identified, which randomly rearranged to Jalpha-gene segments indicating lack of any specific combinations between Valpha- and Jalpha-gene segments with only one exception of the same set of Jalpha-gene segments in duplicate clones. Among the cDNA clones from PBL of an individual 5-month-old Clawn strain pig, a broad distribution of the Jalpha-gene segment usage was observed over the entire Jalpha-gene cluster. The Jalpha-gene segment usage in an individual 1-month-old thymus from a LW strain pig also gave a pattern consistent with the 5-month-old pig. These distributions of the Jalpha-gene segment usage were similar to the previously reported patterns for human T-cells and those of adult murine T-cells. Among the porcine cDNA clones isolated, TCRalpha-chain CDR3 length ranged from 4 to 14 amino acids with the average being 9.35 amino acids. Present report provides groundwork for further studies on porcine TCRalpha-chain expression.

Clonal breadth of the HIV-1-specific T-cell receptor repertoire in vivo as determined by subtractive analysis

OBJECTIVE

Although the epitopic breadth of HIV-1-specific CD8 T lymphocyte (CTL) responses has been described, the T cell receptor (TCR) diversity of virus-specific cells remains poorly defined.

DESIGN AND METHODS

To address this issue, we applied a novel technique for subtractive analysis of the HIV-1-specific CTL repertoire, combining specific deletion of peptide-specific cells by 5-fluorouracil with TCR spectratyping to identify clonal breadth of CTL recognizing individual peptides.

RESULTS

Comprehensive analysis of an infected individual reveals that nine identified HIV-1-specific responses are comprised of at least 38 distinct T-cell clones (ranging from two to 10 distinct clones per epitope).

CONCLUSION

Given the potentially crucial role of T-cell receptor breadth for viral recognition and avoidance of escape, this subepitopic analysis of CTL may offer an important measure of cellular immunity for pathogenesis and vaccine studies.

DNA polymerase lambda directly binds to proliferating cell nuclear antigen through its confined C-terminal region

DNA polymerase lambda (Pol lambda) was recently identified as a new member of the family X of DNA polymerases. Here, we show that Pol lambda directly binds to proliferating cell nuclear antigen (PCNA), an auxiliary protein for DNA replication and repair enzymes, both in vitro and in vivo. A pull-down assay using deletion mutants of Pol lambda showed that the confined C-terminal region of Pol lambda directly binds to PCNA. Furthermore, a synthetic peptide of 20-mers derived from the C-terminal region of Pol lambda competes with full-length Pol lambda for binding to PCNA. The residues between amino acids 518 and 537 of Pol lambda are required for binding to PCNA, and are different from the consensus PCNA interacting motif (PIM). Pol lambda associates with PCNA in vivo by immunoprecipitation analysis and EGFP-tagged Pol lambda co-localizes with PCNA as spots within a nucleus using fluorescent microscopy. Through direct binding, PCNA suppressed the distributive nucleotidyltransferase activity of Pol lambda. Pol micro, which also belongs to the family X of DNA polymerases, binds to PCNA by a pivotal amino acid residue.

Stochastic Modeling of T cell receptor gene rearrangement

The mechanisms controlling the recombination process of the gamma genes that encode the gamma chain of the antigen receptor of the gammadelta T lymphocytes are unclear. Based on experimental data on the recombination status of the two major TCR gamma genes expressed in V(gamma)4+ and V(gamma)1+ thymocytes, we tested the plausibility of three possible rearrangement mechanisms: (1) a time window mechanism according to which the two chromosomes are accessible to the recombination machinery during a defined period of time; (2) a feedback mechanism in which recombination stops shortly after the first in-frame rearrangement event anywhere in both chromosomes; and (3) a feedback mechanism with asynchronous chromosome accessibility, in which there is a first period when only one chromosome is accessible for recombination, followed by a second period when both chromosomes are accessible; shortly after the first in-frame rearrangement event, during any of these two periods, recombination will definitely stop. We model the time window mechanism using a pure probabilistic approach and the two feedback mechanisms using a continuous-time Markov chain formalism. We used maximum likelihood methodology to infer the goodness-of-fit of the models showing evidence for the last model, which best fits the data. Further analysis of this model suggests an evolutionary tradeoff between allelic and isotypic exclusion and the probability that a precursor differentiates into a mature gammadelta T lymphocyte.

Antigen receptor genes and the evolution of a recombinase

Antigen receptor genes exist in the germline in a "split" configuration and are assembled in developing B and T lymphocytes by V(D)J recombination. This site-specific recombination reaction is initiated by a complex containing the RAG1 and RAG2 proteins and completed by general DNA repair factors. RAG1 and RAG2, like the adaptive immune system itself, are found exclusively in jawed vertebrates, and are thought to have entered the vertebrate genome by horizontal transmission as components of a transposable element. This review discusses the structure of antigen receptor genes and the mechanisms by which they are assembled and diversified, and then goes on to consider the evolutionary implications of the arrival of the hypothetical "RAG transposon".

The unfolded protein response sensor IRE1alpha is required at 2 distinct steps in B cell lymphopoiesis

B lymphocyte differentiation is coordinated with the induction of high-level Ig secretion and expansion of the secretory pathway. Upon accumulation of unfolded proteins in the lumen of the ER, cells activate an intracellular signaling pathway termed the unfolded protein response (UPR). Two major proximal sensors of the UPR are inositol-requiring enzyme 1alpha (IRE1alpha), an ER transmembrane protein kinase/endoribonuclease, and ER-resident eukaryotic translation initiation factor 2alpha (eIF2alpha) kinase (PERK). To elucidate whether the UPR plays an important role in lymphopoiesis, we carried out reconstitution of recombinase-activating gene 2-deficient (rag2-/-) mice with hematopoietic cells defective in either IRE1alpha- or PERK-mediated signaling. IRE1alpha-deficient (ire1alpha-/-) HSCs can proliferate and give rise to pro-B cells that home to bone marrow. However, IRE1alpha, but not its catalytic activities, is required for Ig gene rearrangement and production of B cell receptors (BCRs). Analysis of rag2-/- mice transplanted with IRE1alpha trans-dominant-negative bone marrow cells demonstrated an additional requirement for IRE1alpha in B lymphopoiesis: both the IRE1alpha kinase and RNase catalytic activities are required to splice the mRNA encoding X-box-binding protein 1 (XBP1) for terminal differentiation of mature B cells into antibody-secreting plasma cells. Furthermore, UPR-mediated translational control through eIF2alpha phosphorylation is not required for B lymphocyte maturation and/or plasma cell differentiation. These results suggest specific requirements of the IRE1alpha-mediated UPR subpathway in the early and late stages of B lymphopoiesis.

The unfolded protein response sensor IRE1alpha is required at 2 distinct steps in B cell lymphopoiesis

B lymphocyte differentiation is coordinated with the induction of high-level Ig secretion and expansion of the secretory pathway. Upon accumulation of unfolded proteins in the lumen of the ER, cells activate an intracellular signaling pathway termed the unfolded protein response (UPR). Two major proximal sensors of the UPR are inositol-requiring enzyme 1alpha (IRE1alpha), an ER transmembrane protein kinase/endoribonuclease, and ER-resident eukaryotic translation initiation factor 2alpha (eIF2alpha) kinase (PERK). To elucidate whether the UPR plays an important role in lymphopoiesis, we carried out reconstitution of recombinase-activating gene 2-deficient (rag2-/-) mice with hematopoietic cells defective in either IRE1alpha- or PERK-mediated signaling. IRE1alpha-deficient (ire1alpha-/-) HSCs can proliferate and give rise to pro-B cells that home to bone marrow. However, IRE1alpha, but not its catalytic activities, is required for Ig gene rearrangement and production of B cell receptors (BCRs). Analysis of rag2-/- mice transplanted with IRE1alpha trans-dominant-negative bone marrow cells demonstrated an additional requirement for IRE1alpha in B lymphopoiesis: both the IRE1alpha kinase and RNase catalytic activities are required to splice the mRNA encoding X-box-binding protein 1 (XBP1) for terminal differentiation of mature B cells into antibody-secreting plasma cells. Furthermore, UPR-mediated translational control through eIF2alpha phosphorylation is not required for B lymphocyte maturation and/or plasma cell differentiation. These results suggest specific requirements of the IRE1alpha-mediated UPR subpathway in the early and late stages of B lymphopoiesis.

Processing of DNA for nonhomologous end-joining by cell-free extract

In mammalian cells, nonhomologous end-joining (NHEJ) repairs DNA double-strand breaks created by ionizing radiation and V(D)J recombination. We have developed a cell-free system capable of processing and joining noncompatible DNA ends. The system had key features of NHEJ in vivo, including dependence on Ku, DNA-PKcs, and XRCC4/Ligase4. The NHEJ reaction had striking properties. Processing of noncompatible ends involved polymerase and nuclease activities that often stabilized the alignment of opposing ends by base pairing. To achieve this, polymerase activity efficiently synthesized DNA across discontinuities in the template strand, and nuclease activity removed a limited number of nucleotides back to regions of microhomology. Processing was suppressed for DNA ends that could be ligated directly, biasing the reaction to preserve DNA sequence and maintain genomic integrity. DNA sequence internal to the ends influenced the spectrum of processing events for noncompatible ends. Furthermore, internal DNA sequence strongly influenced joining efficiency, even in the absence of processing. These results support a model in which DNA-PKcs plays a central role in regulating the processing of ends for NHEJ.

Valpha and Vbeta public repertoires are highly conserved in terminal deoxynucleotidyl transferase-deficient mice

T cell repertoires observed in response to immunodominant and subdominant peptides include private, i.e., specific for each individual, as well as public, i.e., common to all mice or humans of the same MHC haplotype, Valpha-Jalpha and Vbeta-Dbeta-Jbeta rearrangements. To measure the impact of N-region diversity on public repertoires, we have characterized the alphabeta TCRs specific for several CD4 or CD8 epitopes of wild-type mice and of mice deficient in the enzyme TdT. We find that V, (D), J usage identified in public repertoires is strikingly conserved in TdT(o/o) mice, even for the CDR3 loops which are shorter than those found in TdT(+/+) animals. Moreover, the 10- to 20-fold decrease in alphabeta T cell diversity in TdT(o/o) mice did not prevent T cells from undergoing affinity maturation during secondary responses. A comparison of the CDR3beta in published public and private repertoires indicates significantly reduced N-region diversity in public CDR3beta. We interpret our findings as suggesting that public repertoires are produced more efficiently than private ones by the recombination machinery. Alternatively, selection may be biased in favor of public repertoires in the context of the interactions between TCR and MHC peptide complexes and we hypothesize that MHCalpha helices are involved in the selection of public repertoires.

A biochemically defined system for mammalian nonhomologous DNA end joining

Nonhomologous end joining (NHEJ) is a major pathway in multicellular eukaryotes for repairing double-strand DNA breaks (DSBs). Here, the NHEJ reactions have been reconstituted in vitro by using purified Ku, DNA-PK(cs), Artemis, and XRCC4:DNA ligase IV proteins to join incompatible ends to yield diverse junctions. Purified DNA polymerase (pol) X family members (pol mu, pol lambda, and TdT, but not pol beta) contribute to junctional additions in ways that are consistent with corresponding data from genetic knockout mice. The pol lambda and pol mu contributions require their BRCT domains and are both physically and functionally dependent on Ku. This indicates a specific biochemical function for Ku in NHEJ at incompatible DNA ends. The XRCC4:DNA ligase IV complex is able to ligate one strand that has only minimal base pairing with the antiparallel strand. This important aspect of the ligation leads to an iterative strand-processing model for the steps of NHEJ.

Isoforms of terminal deoxynucleotidyltransferase: developmental aspects and function

The immune system develops in a series of programmed developmental stages. Although recombination-activating gene (RAG) and nonhomologous end-joining (NHEJ) proteins are indispensable in the generation of immunoglobulins and T-cell receptors (TCRs), most CDR3 diversity is contributed by nontemplated addition of nucleotides catalyzed by the nuclear enzyme terminal deoxynucleotidyltransferase (TdT) and most nucleotide deletion is performed by exonucleases at V(D)J joins. Increasing TdT expression continuing into adult life results in N region addition and diversification of the T and B cell repertoires. In several species including mice and humans, there are multiple isoforms of TdT resulting from alternative mRNA splicing. The short form (TdTS) produces N additions during TCR and B-cell receptor (BCR) gene rearrangements. Other long isoforms, TdTL1 and TdTL2, have 3' --> 5' exonuclease activity. The two forms of TdT therefore have distinct and opposite functions in lymphocyte development. The enzymatic activities of the splice variants of TdT play an essential role in the diversification of lymphocyte repertoires by modifying the composition and length of the gene segments involved in the production of antibodies and T-cell receptors.

Distinct and opposite activities of human terminal deoxynucleotidyltransferase splice variants

Evidence for potential human TdT (hTdT) isoforms derived from hTdT genomic sequences led us to identify the short isoform (hTdTS), as well as mature long transcripts containing exon XII (hTdTL1) and another including exon VII (hTdTL2) in lymphoid cells. Normal B and T lymphocytes express exclusively hTdTS and hTdTL2, whereas hTdTL1 expression appears to be restricted to transformed lymphoid cell lines. In in vitro recombination and primer assays, both long isoforms were shown to have 3'-->5' exonuclease activity. Overexpression of hTdTS or hTdTL2 greatly reduced the efficiency of recombination, which was reverted to normal levels by the simultaneous expression of both enzymes. Therefore, alternative splicing may prevent the adverse effects of unchecked elongation or diminution of coding ends during V(D)J recombination, thus affecting the survival of a B or T cell precursor during receptor gene rearrangements. Finally, the newly discovered hTdT isoforms should be considered in future screening of human leukemias.

Mutational analysis of terminal deoxynucleotidyltransferase-mediated N-nucleotide addition in V(D)J recombination

The addition of nontemplated (N) nucleotides to coding ends in V(D)J recombination is the result of the action of a unique DNA polymerase, TdT. Although N-nucleotide addition by TdT plays a critical role in the generation of a diverse repertoire of Ag receptor genes, the mechanism by which TdT acts remains unclear. We conducted a structure-function analysis of the murine TdT protein to determine the roles of individual structural motifs that have been implicated in protein-protein and protein-DNA interactions important for TdT function in vivo. This analysis demonstrates that the N-terminal portion of TdT, including the BRCA-1 C-terminal (BRCT) domain, is not required for TdT activity, although the BRCT domain clearly contributes quantitatively to N-nucleotide addition activity. The second helix-hairpin-helix domain of TdT, but not the first, is required for activity. Deletional analysis also suggested that the entire C-terminal region of TdT is necessary for N-nucleotide addition in vivo. The long isoform of TdT was found to reduce N-nucleotide addition by the short form of TdT, but did not increase nucleotide deletion from coding ends in either human or rodent nonlymphoid cells. We consider these results in light of the recently reported structure of the catalytic region of TdT.

Evidence that the long murine terminal deoxynucleotidyltransferase isoform plays no role in the control of V(D)J junctional diversity

Two TdT isoforms have been found in the mouse. The short isoform is known to add N regions to gene segment junctions during V(D)J recombination, but the role of the long (TdTL) isoform is controversial. We have shown that TdTL, although endowed with terminal transferase activity, is thermally unstable and unable to add N regions in vivo. In this study, we demonstrate that TdTL is devoid of 3'-5' exonuclease activity, and provide an analysis of nucleotide deletion and addition patterns in large series of V(D)J coding joins, arguing against a role of TdTL in the control of junctional diversity in Igs and TCRs.

In vitro and in vivo studies on the generation of the primary T-cell receptor repertoire

The primary T-cell receptor repertoire is generated by somatic rearrangement of discontinuous gene segments. The shape of the combinatorial repertoire is stereotypical and, in part, evolutionarily conserved among mammals. Rearrangement is initiated by specific interactions between the recombinase and the recombination signals (RSs) that flank the gene segments. Conserved sequence variations in the RS, which modulate its interactions with the recombinase, appear to be a major factor in shaping the primary repertoire. In vitro, biochemical studies have revealed distinct steps in these complex recombinase-RS interactions that may determine the final frequency of gene segment rearrangement. These studies offer a plausible model to explain gene segment selection, but new, more physiological approaches will have to be developed to verify and refine the mechanism by which the recombinase targets the RS in its endogenous chromosomal context in vivo.

The role of the non-homologous end-joining pathway in lymphocyte development

One of the most toxic insults a cell can incur is a disruption of its linear DNA in the form of a double-strand break (DSB). Left unrepaired, or repaired improperly, these lesions can result in cell death or neoplastic transformation. Despite these dangers, lymphoid cells purposely introduce DSBs into their genome to maximize the diversity and effector functions of their antigen receptor genes. While the generation of breaks requires distinct lymphoid-specific factors, their resolution requires various ubiquitously expressed DNA-repair proteins, known collectively as the non-homologous end-joining pathway. In this review, we discuss the factors that constitute this pathway as well as the evidence of their involvement in two lymphoid-specific DNA recombination events.

Terminal deoxynucleotidyltransferase deficiency decreases autoimmune disease in diabetes-prone nonobese diabetic mice and lupus-prone MRL-Fas(lpr) mice

The wide diversity of the T and B Ag receptor repertoires becomes even more extensive postneonatally due to the activity of TdT, which adds nontemplated N nucleotides to Ig and TCR coding ends during V(D)J recombination. In addition, complementarity-determining region 3 sequences formed in the absence of TdT are more uniform due to the use of short sequence homologies between the V, D, and J genes. Thus, the action of TdT produces an adult repertoire that is both different from, and much larger than, the repertoire of the neonate. We have generated TdT-deficient nonobese diabetic (NOD) and MRL-Fas(lpr) mice, and observed a decrease in the incidence of autoimmune disease, including absence of diabetes and decreased pancreatic infiltration in NOD TdT(-/-) mice, and reduced glomerulonephritis and increased life span in MRL-Fas(lpr) TdT(-/-) mice. Using tetramer staining, TdT(-/-) and TdT(+/+) NOD mice showed similar frequencies of the diabetogenic BDC 2.5 CD4(+) T cells. We found no increase in CD4(+)CD25(+) regulatory T cells in NOD TdT(-/-) mice. Thus, TdT deficiency ameliorates the severity of disease in both lupus and diabetes, two very disparate autoimmune diseases that affect different organs, with damage conducted by different effector cell types. The neonatal repertoire appears to be deficient in autoreactive T and/or B cells with high enough affinities to induce end-stage disease. We suggest that the paucity of autoreactive specificities created in the N region-lacking repertoire, and the resultant protection afforded to the newborn, may be the reason that TdT expression is delayed in ontogeny.

In vitro processing of the 3'-overhanging DNA in the postcleavage complex involved in V(D)J joining

The postcleavage complex involved in V(D)J joining is known to possess a transpositional strand transfer activity, whose physiological role is yet to be clarified. Here we report that RAG1 and RAG2 proteins in the signal end (SE) complex cleave the 3'-overhanging structure of the synthetic coding-end (CE) DNA in two successive steps in vitro. The 3'-overhanging structure is attacked by the SE complex imprecisely, near the double-stranded/single-stranded (ds/ss) junction, and transferred to the SE. The transferred overhang is then resolved and cleaved precisely at the ds/ss junction, generating either the linear or the circular cleavage products. Thus, the blunt-end structure is restored for the SE and variably processed ends are generated for the synthetic CE. This 3'-processing activity is observed not only with the core RAG2 but also with the full-length protein.

Surface mu heavy chain signals down-regulation of the V(D)J-recombinase machinery in the absence of surrogate light chain components

Early B cell development is characterized by stepwise, ordered rearrangement of the immunoglobulin (Ig) heavy (HC) and light (LC) chain genes. Only one of the two alleles of these genes is used to produce a receptor, a phenomenon referred to as allelic exclusion. It has been suggested that pre–B cell receptor (pre-BCR) signals are responsible for down-regulation of the VDJ_H-recombinase machinery (Rag1, Rag2, and terminal deoxynucleotidyl transferase [TdT]), thereby preventing further rearrangement on the second HC allele. Using a mouse model, we show that expression of an inducible μHC transgene in Rag2^−/− pro–B cells induces down-regulation of the following: (a) TdT protein, (b) a transgenic green fluorescent protein reporter reflecting endogenous Rag2 expression, and (c) Rag1 primary transcripts. Similar effects were also observed in the absence of surrogate LC (SLC) components, but not in the absence of the signaling subunit Ig-α. Furthermore, in wild-type mice and in mice lacking either λ5, VpreB1/2, or the entire SLC, the TdT protein is down-regulated in μHC⁺LC⁻ pre–B cells. Surprisingly, μHC without LC is expressed on the surface of pro–/pre–B cells from λ5^−/−, VpreB1^−/−VpreB2^−/−, and SLC^−/− mice. Thus, SLC or LC is not required for μHC cell surface expression and signaling in these cells. Therefore, these findings offer an explanation for the occurrence of HC allelic exclusion in mice lacking SLC components.

Early expression of two TdT isoforms in the hematopoietic system of the Mexican axolotl. Implications for the evolutionary origin of the N-nucleotide addition

Nontemplate (N)-nucleotide addition by the terminal dideoxynucleotidyl transferase (TdT) at the junctions of rearranging V( D) J gene segments greatly contribute to antigen-receptor diversity. TdT has been identified in several vertebrate species, where it is highly conserved. We report here the isolation of two forms of TdT mRNA in an amphibian, the Mexican axolotl. The isoform TdT1 shares all of the conserved structural motifs required for TdT activity and displays an average of 50-58% similarity at the amino acid level with TdT of other species. The second axolotl TdT variant ( TdT2) differs from TdT1 by a 57-amino acid deletion located between amino acids 165-222 of TdT1, including the first helix-hairpin-helix DNA-binding motif. During ontogeny, TdT products are first detected in the head of 6-week-old larvae and further in the head and trunk of 8-month-old larvae. These developmental stages correspond to the first detection of RAG1 and antigen-receptor (TCRbeta and IgHmicro) products in axolotl larvae. Our results suggest that in contrast to mammalian development, N diversity occurs early in axolotl development to diversify the primary repertoire. Phylogenetic analyses reveal that TdT and DNA polymerase mu(Pol mu) genes are closely related, and that both enzymes were already present in the common ancestor of jawed vertebrates.

TCR delta gene rearrangements revealed by fine structure of the recombination junction in mice

The standard products of V(D)J recombination of immunoglobulin and T cell receptor genes are two kinds of DNA junction, a coding joint and a signal joint. TCR delta V-D and D-D signal joints in adult mouse thymocytes were sequenced following PCR amplification. We observed differential nucleotide insertions at the V delta-D delta signal joints, depending on the V delta and D delta gene usage in the developmental stage. Nucleotide insertions at the V delta-D delta 1 signal joints were less frequent for the V delta 4, 5 genes preferentially utilized in adult thymocytes than for the V delta 3, 6 genes, infrequently rearranged to D delta 1. In addition to standard signal joints, unexpectedly, novel nonstandard products, "replacement joints" of D delta 1 substituted downstream by the recombination signal sequence of V delta were also found. However, no D delta 2-associated replacement joints other than V delta 5 were found. The other replacement joints of D delta 1-D delta 2 recombination were also observed. The mutation in TCR beta gene affected the frequency of nucleotide insertions at the V delta-D delta signal joints and inhibited the formation of replacement joint. Recombination mechanism generating the replacement joint and the possible role of TCR beta in up-regulation of TCR delta gene rearrangements are discussed.

Unraveling V(D)J recombination; insights into gene regulation

V(D)J recombination assembles antigen receptor genes from component gene segments. We review findings that have shaped our current understanding of this remarkable mechanism, with a focus on two major reports--the first detailed comparison of germline and rearranged antigen receptor loci and the discovery of the recombination activating gene-1.

Error-prone DNA polymerases: when making a mistake is the only way to get ahead

Cells have high-fidelity polymerases whose task is to accurately replicate the genome, and low-fidelity polymerases with specialized functions. Although some of these low-fidelity polymerases are exceptional in their ability to replicate damaged DNA and restore the undamaged sequence, they are error prone on undamaged DNA. In fact, these error-prone polymerases are sometimes used in circumstances where the capacity to make errors has a selective advantage. The mutagenic potential of the error-prone polymerases requires that their expression, activity, and access to undamaged DNA templates be regulated. Here we review these specialized polymerases with an emphasis on their biological roles.

T cell receptor gene usage in desmoglein-3-specific T lymphocytes from patients with pemphigus vulgaris

Pemphigus vulgaris (PV) is an autoimmune disease mediated by autoantibodies against desmoglein-3 (Dsg3). It has been documented that both humoral and cellular autoimmunity play essential roles in the development of PV. Recently, we identified that T cells from PV patients respond to three antigenic fragments on the ectodomain of Dsg3. These T cells are CD4 alpha/beta cells secreting a Th2-like cytokine profile, and responding of Dsg3 in a restriction to HLA-DRBI*0402 or 1401 alleles. Other characteristics of these cells, such as detailed epitope(s) and T cell receptors (TCRs) usage, however, have not been investigated. The purpose of this study is to determine detailed T cell epitope(s) and TCR genes utilized by Dsg3-specific T cells. Here, we found that Dsg3(AA145-192)-specific cells preferentially utilize the TCRVbeta13 gene, while Dsg3(AA240-303)- and Dsg3 (AA570-614)-specific cells utilize Vbeta7 and Vbeta17 genes, respectively. Analysis of TCRValpha gene expression, it appears that Valpha22 gene is expressed by Dsg3(AA145-192)-specific cells, whereas the Valpha10 gene is predominantly utilized by Dsg3(AA240-303)-specific T cells. There are no specific utilization of Valpha gene in the group of cells proliferate to Dsg3 (AA570-614). We believe that this information will further our understanding of the properties of autoimmune T cells in patients with PV.

Persistent alterations in the T-cell repertoires of HIV-1-infected and at-risk uninfected men

OBJECTIVE

We examined the association between immunogenic exposure and T-cell receptor (TCR) diversity to more clearly assess the impact of HIV-1 infection on the T-cell repertoire.

METHODS

: To estimate the extent of T-cell clonality attributable to HIV-1 infection, we evaluated T-cell repertoires in low-risk and at-risk seronegative men and HIV-1 seropositive men by assessment of T-cell receptor beta-chain (TCR beta) complimentary determining region 3 (CDR3) lengths.

RESULTS

The frequency of T-cell clonality in both HIV-1 infected and at-risk uninfected men was elevated in comparison to low-risk uninfected men. Among low-risk and at-risk seronegative, and HIV-1 seropositive men, clonal expansions were present in 3, 8, and 10% of CD4+ CDR3 lengths, and 18, 22, and 28% of CD8+ CDR3 lengths respectively. In addition, the longitudinal conservation of clonal expansions was observed in at-risk seronegative men. Based on comparisons to at-risk seronegative men, we estimate that at-risk seropositive men with chronic HIV-1 infection exhibit a 27% increase in the number of expanded CD8+ CDR3 lengths.

CONCLUSION

These findings provide an approximation of the magnitude of the T-cell response in individuals undergoing chronic HIV-1 infection and demonstrate a significant association between the history of immunogenic challenge and the magnitude of clonality within the T-cell repertoire. In addition, these findings underscore the necessity of selecting controls with similar antigenic exposure histories when investigating T-cell dynamics in HIV-infected individuals.

Terminal deoxynucleotidyltransferase forms a ternary complex with a novel chromatin remodeling protein with 82 kDa and core histone

BACKGROUND

Terminal deoxynucleotidyltransferase (TdT) is a DNA polymerase that enhances the Ig and TcR gene diversity in the N region at the junctions of variable (V), diversity (D) and joining (J) segments in B- and T-cells. TdT synthesizes the N region in concert with many proteins including DNA-PKcs, Ku70 and Ku86. To elucidate the molecular mechanism of the N region synthesis, we first attempted to isolate the genes with products that directly interact with TdT.

RESULTS

Using a yeast two-hybrid system, we isolated a cDNA clone encoding a novel nuclear protein that interacts with TdT. This protein was designated as TdT interacting factor 2 (TdIF2). The confined region of the C-terminal in TdIF2 is involved in specific interaction with the entire C-terminal in TdT. TdIF2 contains an acidic region comprised of 42 residues. TdIF2 was shown to bind specifically to a core histone by pull down assay using specific antibodies against TdIF2. When a TdT/TdIF2 complex was applied on to a DNA-cellulose column, only TdT bound to the column while TdIF2 passed through. TdIF2 reduces the TdT activity to 46% of its maximum value in vitro assay system using activated DNA as primer.

CONCLUSIONS

TdIF2 binds directly to TdT and core histone. Furthermore, TdT, TdIF2 and core histone form a ternary complex. TdIF2 liberates H2A/H2B from a core histone in correlation with PCNA. The enzymatic consequence of the TdIF2/TdT complex is the reduction of TdT activity in vitro. TdIF2 would function as a chromatin remodeling protein at the N region synthesis.

A new model of sheep Ig diversification: shifting the emphasis toward combinatorial mechanisms and away from hypermutation

The current model of Ig repertoire development in sheep focuses on the rearrangement of a small number (approximately 20) of Vlambda gene segments. It is believed that this limited combinatorial repertoire is then further diversified through postrearrangement somatic hypermutation. This process has been reported to introduce as many as 110 mutations/1000 nucleotides. In contrast, our data have that indicated somatic hypermutation may diversify the preimmune repertoire to a much lesser extent. We have identified 64 new Vlambda gene segments within the rearranged Ig repertoire. As a result, many of the unique nucleotide patterns thought to be the product of somatic hypermutation are actually hard-coded within the germline. We suggest that combinatorial rearrangement makes a much larger contribution, and somatic hypermutation makes a much smaller contribution to the generation of diversity within the sheep Ig repertoire than is currently acknowledged.

Substantial N diversity is generated in T cell receptor alpha genes at birth despite low levels of terminal deoxynucleotidyl transferase expression in mouse thymus

N region diversity in antigen receptors is a developmentally regulated process in B and T lymphocytes, which correlates with the differential expression of terminal deoxynucleotidyl transferase (TdT). To precisely determine the onset of TdT gene activation during T cell differentiation and thymic ontogeny, TdT expression was directly detected at the cellular level by in situ hybridization and TdT function was assessed by analyzing the distribution of N additions in alpha and beta TCR genes at early stages of development. Even though TdT transcripts were undetectable at birth, substantial N additions were observed in ValphaJalpha junctions and 3 days later in VbetaDbetaJbeta junctions, indicating that TdT expression could be induced in immature thymocytes much earlier than expected. Indeed low TdT expression level was found in TN3/4 and DP from fetal day 17, suggesting that the onset of TdT expression occurs simultaneously in both populations and may depend on microenvironmental cues. Moreover significant increase in the proportion of thymocytes expressing high levels of TdT mRNA during the first week after birth without a similar increase in the level of N diversity suggests that TdT expression and TdT function in the generation of N diversity are not strictly correlated.

V(D)J recombination: RAG proteins, repair factors, and regulation

V(D)J recombination is the specialized DNA rearrangement used by cells of the immune system to assemble immunoglobulin and T-cell receptor genes from the preexisting gene segments. Because there is a large choice of segments to join, this process accounts for much of the diversity of the immune response. Recombination is initiated by the lymphoid-specific RAG1 and RAG2 proteins, which cooperate to make double-strand breaks at specific recognition sequences (recombination signal sequences, RSSs). The neighboring coding DNA is converted to a hairpin during breakage. Broken ends are then processed and joined with the help of several factors also involved in repair of radiation-damaged DNA, including the DNA-dependent protein kinase (DNA-PK) and the Ku, Artemis, DNA ligase IV, and Xrcc4 proteins, and possibly histone H2AX and the Mre11/Rad50/Nbs1 complex. There may be other factors not yet known. V(D)J recombination is strongly regulated by limiting access to RSS sites within chromatin, so that particular sites are available only in certain cell types and developmental stages. The roles of enhancers, histone acetylation, and chromatin remodeling factors in controlling accessibility are discussed. The RAG proteins are also capable of transposing RSS-ended fragments into new DNA sites. This transposition helps to explain the mechanism of RAG action and supports earlier proposals that V(D)J recombination evolved from an ancient mobile DNA element.

Access roads for RAG-ged terrains: control of T cell receptor gene rearrangement at multiple levels

Antigen-specific immune response requires the generation of a diverse antigen (Ag)-receptor repertoire. The primary repertoire is generated through somatic gene rearrangement and molded by subsequent cellular selection. Constraints during gene recombination influence the ultimate shape of the repertoire. One major control mechanism of gene rearrangement, investigated for many years, is exerted through regulated chromosomal accessibility of the recombinase to the antigen receptor loci. More recent studies began to explore the role of interactions between the recombinase and its cognate recognition DNA sequences. The emerging results suggest that formation of the primary repertoire is controlled by two, partially independent factors: chromosomal accessibility and direct recombinase-DNA interactions.

Involvement of caspace-3 in the cleavage of terminal transferase

To investigate the in vivo role of caspase-3 in Terminal Transferase metabolism DMSO-treated RPMI-8402, a human pre-T cell line was used. In DMSO treated samples (3)H-dGTP incorporation and TdT phosphorylation occurs after 4 hours of treatment. After 8 hours cells undergo TdT proteolysis in addition to its inactivation. The cleavage of TdT into 32- and 58-KDa proteolytic fragments occurred simultaneously with the activation of Caspase-3, but preceded changes associated with the apoptotic process described after 48 hours of treatment. The Caspase-3 peptide inhibitor V, used as a specific inhibitor, prevented TdT proteolysis prolonging its activity and rescued cells from apoptosis. Our experiments suggest that TdT is a nuclear substrate for Caspase-3, the main apoptotic effector protease in many cell types, and that the cleavage of TdT represents a primary step in a signal cascade leading to pre-T cell apoptosis.

Detection of functional V(H)81X heavy chains in adult mice with an assessment of complementarity-determining region 3 diversity and capacity to form pre-B cell receptor

Recent reports have indicated that up to 50% of all H chain proteins formed cannot associate with the surrogate L chain complex and therefore fail to form a pre-B cell receptor (pBCR), which is required for allelic exclusion and, in most cases, verifies that the H chain can assemble with the L chain to form an Ab molecule. Certain V(H) genes, such as V(H)81X, appear to be particularly prone to encoding for nonpairing (dysfunctional) H chains. It has been suggested that sequence variability at complementarity-determining region 3, especially when increased by the enzyme TdT, often precludes the ability of V(H)81X-using H chains to form pBCR. To determine whether a motif exists that accounts for the ability of H chains to pair with surrogate L chain complex/L chain, we have bred a mouse line in which H chain recombination can only occur on one allele, allowing us to compile a pool of H chains capable of forming Ab molecules in the absence of dysfunctional H chains. Somewhat unexpectedly, we have found V(H)81X H chains capable of Ab formation and cell surface expression in the presence of TdT. Scrutiny of these H chains has revealed that, although highly prone to encode for dysfunctional H chains, sequence variability is not severely limited among functional V(H)81X H chains. We also demonstrate that surface Ig expression is highly indicative of the capacity of a H chain to form pBCR.

Over-expression of human DNA polymerase lambda in E. coli and characterization of the recombinant enzyme

BACKGROUND

DNA polymerase lambda (Pol lambda) was recently identified as a new member of the family X of DNA polymerases in eukaryotic cells. Pol lambda contains a nuclear localization signal (NLS), a BRCA1-C terminal (BRCT) domain, a proline-rich region, helix-hairpin-helix (HhH) and pol X motifs. Since the amino acid sequence for Pol lambda shares a high degree of homology to Pol beta, Pol lambda is considered to have a similar enzymatic nature to Pol beta.

RESULTS

Recombinant human Pol lambda was shown to possess template-directed DNA polymerase activity in its monomeric form. Pol lambda required either Mn2+ or Mg2+ as a metal co-factor to catalyse this activity, and optimal activity was detected at pH 8.5-9.0. Pol lambda was insensitive to aphidicolin, but was sensitive to dideoxynucleoside triphosphates or N-ethylmaleimide. By constructing the truncated Pol lambda, the proline rich region was shown to act in a suppression of its polymerization activity. A chimeric enzyme comprised of the Pol lambda N-terminal region and Pol beta also showed a reduced Pol beta activity. Proliferating cell nuclear antigen (PCNA) directly interacts with Pol lambda through its Pol beta like region in vitro.

CONCLUSIONS

Pol lambda possesses similar enzymatic nature to Pol beta; requirements of cations and optimal conditions for pH and NaCl concentration, aside from sensitivity to N-ethylmaleimide and template preference. The proline rich region of Pol lambda functions as a suppressor domain for its polymerization activity (SDPA). Pol lambda interacts directly with PCNA through its Pol beta like region. The functional consequence of this interaction is the negative regulation of Pol lambda activity.

MaGiK method of T-Cell receptor repertoire analysis

T-cell receptor diversity enables the cellular immune response to recognize a broad range of viral and other pathogenic agents. An increasingly common method of characterizing T-cell receptor diversity and usage in response to antigenic challenges involves the identification of clonal expansions by PCR amplification of the CDR3 region of distinct TCRVbeta families. Though clonal expansions often appear evident upon visual inspection of the results, a systematic method is needed for the valid enumeration of these expansions. Here, we describe a novel analysis method, termed the MaGiK method, for systematically identifying and enumerating clonal T-cell expansions and for applying the results to investigations of the T-cell receptor repertoire.

Distinct and opposite diversifying activities of terminal transferase splice variants

The short splice variant of mouse terminal deoxynucleotidyl transferase (TdTS) catalyzes the addition of nontemplated nucleotides (N addition) at the coding joins of B cell and T cell antigen receptor genes. However, the activity and function of the long isoform of TdT (TdTL) have not been determined. We show here, in vitro and in vivo, that TdTL is a 3'-->5' exonuclease that catalyzes the deletion of nucleotides at coding joins. These findings suggest that the two TdT isoforms may act in concert to preserve the integrity of the variable region of antigen receptors while generating diversity.

Immunoglobulin diversification in B cell malignancies: internal splicing of heavy chain variable region as a by-product of somatic hypermutation

In this study we describe alternative splicing of somatically mutated immunoglobulin (Ig) variable heavy chain (V(H)) genes in three distinct primary B cell non-Hodgkin's lymphomas (B-NHL). In two V4-34 expressing lymphomas, ie a post-germinal center type B cell chronic lymphocytic leukemia (B-CLL) and a follicular lymphoma (FL), internally spliced V(H) gene transcripts were found in which a sequence stretch of 116 bp between the framework region 1 (FR1) and complementarity determining region 2 (CDR2) had been deleted. We provide evidence that for this alternative IgV(H) mRNA processing a known cryptic 5' splice donor site and a previously unidentified cryptic 3' splice acceptor site were used. Site-directed mutagenesis showed that the cryptic 3' splice acceptor site had been activated by specific somatic point mutations. The B-CLL further harbored a triplication of the rearranged JH3 gene segment including the putative N region and part of the JH3-JH4 intron sequence. This triplication probably took place via a repeated mechanism of DNA double strand break followed by homologous recombination, a mechanism which was recently proposed also involved in the somatic hypermutation process and is compatible with the post-germinal center derivation of this B-CLL. Finally, in a V4-34 expressing diffuse large B cell lymphoma, we observed alternative IgV(H) mRNA processing using the same cryptic 5' splice donor site and the normal splice acceptor site of the CH1-C(mu) exon. The significance of alternative IgV(H) processing in B cell malignancies and as a potential mechanism of somatic Ig diversification is discussed.

The mechanism and regulation of chromosomal V(D)J recombination

V(D)J recombination is of fundamental importance to the generation of diverse antigen receptor repertoires. We review our current understanding of the V(D)J recombination reaction and how it is regulated during lymphocyte development. We also discuss how defects in the mechanism or regulation of V(D)J recombination can lead to human disease.

Crystal structures of a template-independent DNA polymerase: murine terminal deoxynucleotidyltransferase

The crystal structure of the catalytic core of murine terminal deoxynucleotidyltransferase (TdT) at 2.35 A resolution reveals a typical DNA polymerase beta-like fold locked in a closed form. In addition, the structures of two different binary complexes, one with an oligonucleotide primer and the other with an incoming ddATP-Co(2+) complex, show that the substrates and the two divalent ions in the catalytic site are positioned in TdT in a manner similar to that described for the human DNA polymerase beta ternary complex, suggesting a common two metal ions mechanism of nucleotidyl transfer in these two proteins. The inability of TdT to accommodate a template strand can be explained by steric hindrance at the catalytic site caused by a long lariat-like loop, which is absent in DNA polymerase beta. However, displacement of this discriminating loop would be sufficient to unmask a number of evolutionarily conserved residues, which could then interact with a template DNA strand. The present structure can be used to model the recently discovered human polymerase mu, with which it shares 43% sequence identity.

RAG1 and RAG2 in V(D)J recombination and transposition

RAG1 and RAG2 are the key components of the V(D)J recombinase machinery that catalyses the somatic gene rearrangements of antigen receptor genes during lymphocyte development. In the first step of V(D)J recombination--DNA cleavage--the RAG proteins act together as an endonuclease to excise the DNA between two individual gene segments. They are also thought to be involved in the subsequent DNA joining step. In vitro, the RAG proteins catalyze the integration of the excised DNA element into target DNA completing a process similar to bacterial transposition. In vivo, this reaction is suppressed by an unknown mechanism. The individual roles of RAG1 and RAG2 in V(D)J recombination and transposition reactions are discussed based on mutation analyses and structure predictions.

Most alpha/beta T cell receptor diversity is due to terminal deoxynucleotidyl transferase

The contribution of template-independent nucleotide addition to antigen receptor diversity is unknown. We therefore determined the size of the T cell receptor (TCR)alpha/beta repertoire in mice bearing a null mutation on both alleles of the terminal deoxynucleotidyl transferase (Tdt) gene. We used a method based upon polymerase chain reaction amplification and exhaustive sequencing of various AV-AJ and BV-BJ combinations. In both wild-type and Tdt degrees / degrees mice, TCRAV diversity is one order of magnitude lower than the TCRBV diversity. In Tdt degrees / degrees animals, TCRBV chain diversity is reduced 10-fold compared with wild-type mice. In addition, in Tdt degrees / degrees mice, one BV chain can associate with three to four AV chains as in wild-type mice. The alpha/beta repertoire size in Tdt degrees / degrees mice is estimated to be 10(5) distinct receptors, approximately 5-10% of that calculated for wild-type mice. Thus, while Tdt activity is not involved in the combinatorial diversity resulting from alpha/beta pairing, it contributes to at least 90% of TCRalpha/beta diversity.

Molecular determinants of the human antibody response to HIV-1: implications for disease control

Various aspects of the immune response to HIV-1 infection remain unclear. While seropositive subjects generally mount a strong humoral response, the antibodies produced are not effective in halting disease progression. Molecular characterization of the antibody repertoire specific for HIV-1 antigens represents an approach to further our understanding of the mechanisms involved in mounting a humoral immunity in this infection. Recently, the content, structure, and organization of the human immunoglobulin-variable gene loci have been elucidated and a number of laboratories have characterized the variable gene elements of human anti-HIV-1 antibodies derived from infected persons by cell fusion or by Epstein-Barr virus transformation. The results show evidence for extensive somatic mutations that lead to preferential amino acid substitutions in the hypervariable regions, an indication of an antigen-driven process. Multiple other molecular events also are engaged in generating antibody diversity, including various types of fusions of variable genes, usage of inverted diversity genes, and addition of extragenomic nucleotides. Most importantly, there is a paucity of antibodies expressing the major V(H)3 gene family, which could result from the capacity of gp120 to act as superantigen for human B cells. This V(H)3+ antibody deficit also has been observed in B cells isolated ex vivo from the patients. Since V(H)3+ antibodies play an essential role in immune defense against infections, the abnormalities observed in HIV-1 infection may predispose to opportunistic infections and further compromise the immune defense mechanisms of the subjects.

Terminal deoxynucleotidyl transferase deficiency decreases autoimmune disease in MRL-Fas(lpr) mice

The neonatal Ab and TCR repertoires are much less diverse, and also very different from, the adult repertoires due to the delayed onset of terminal deoxynucleotidyl transferase (TdT) expression in ontogeny. TdT adds nontemplated N nucleotides to the junctions of Igs and TCRs, and thus its absence removes one of the major components of junctional diversity in complementarity-determining region 3 (CDR3). We have generated TdT-deficient MRL/lpr, Fas-deficient (MRL-Fas(lpr)) mice, and show that they have an increased lifespan, decreased incidence of skin lesions, and much lower serum levels of anti-dsDNA, anti-chromatin, and IgM rheumatoid factors. The generalized hypergammaglobulinemia characteristic of MRL-Fas(lpr) mice is also greatly reduced, as is the percentage of CD4(-)CD8(-)B220(+) (double-negative) T cells. IgG deposits in the kidney are significantly reduced, although evidence of renal disease is present in many mice at 6 mo. CDR3 regions of both IgH and TCR from peripheral lymphocytes of MRL-Fas(lpr) mice are shorter in the absence of TdT, and there is a paucity of arginines in the IgH CDR3 regions of the MRL-Fas(lpr) TdT(-/-) mice. Because the amelioration of symptoms is so widespread, it is likely that the absence of N regions has more of an affect than merely decreasing the precursor frequency of anti-dsDNA B cells. Hence, either the T or B cell repertoires, or more likely both, require N region diversity to produce the full spectrum of autoimmune lupus disease.

T cell immunity in neonates

Typically, neonates exhibit decreased or aberrant cellular immune responses when compared to adults, resulting in increased susceptibility to infection. However, it is clear that newborns are able to generate adult-like protective T cell responses under certain conditions. The focus of our research is to understand the deficiencies within the neonatal immune system that lead to improper cellular responses and how priming conditions can be altered to elicit the appropriate T cell response necessary to protect against development of pathogen-induced disease. With these goals in mind, we are exploring the attributes of neonatal T cells and their development, as well as the conditions during priming that influence the resulting response to immune challenge during the neonatal period.

DNA double strand break repair and chromosomal translocation: lessons from animal models

The maintenance of genomic stability is one of the most important defenses against neoplastic transformation. This objective must be accomplished despite a constant barrage of spontaneous DNA double strand breaks. These dangerous lesions are corrected by two primary pathways of double strand break repair; non homologous end joining and homologous recombination. Recent studies employing mouse models have shown that absence of either pathway leads to genomic instability, including potentially oncogenic translocations. Because translocations involve the union of different chromosomes, cellular machinery must exist that creates these structures in the context of unrepaired double strand breaks. Evidence is mounting that the pathways of double strand break repair that are so important for survival may themselves be the culprits that generate potentially fatal translocations. Evidence and models for the dual roles of double strand break repair in both preventing, and generating, oncogenic karyotypic changes are discussed.