Multiple rearrangements in T cell receptor alpha chain genes maximize the production of useful thymocytes.

Peripheral T lymphocytes each express surface T cell receptor (TCR) alpha and beta chains of a single specificity. These are produced after random somatic rearrangements in TCR alpha and beta germline genes. Published model systems using mice expressing TCR alpha and/or beta chain transgenes have shown that allelic exclusion occurs conventionally for TCR-beta. TCR alpha chain expression, however, appears to be less strictly regulated, as endogenous TCR alpha chains are often found in association with transgenic TCR beta chains in TCR alpha/beta transgenic mice. This finding, coupled with the unique structure of the TCR alpha locus, has led to the suggestion that unlike TCR beta and immunoglobulin heavy chain genes, TCR alpha genes may make multiple rearrangements on each chromosome. In the current study, we demonstrate that the majority of TCR-, noncycling thymocytes spontaneously acquire surface expression of CD3/TCR. Further, we show that cultured immature thymocytes originally expressing specific TCR alpha and beta chains may lose surface expression of the original TCR alpha, but not beta chains. These data provide evidence that not only must multiple rearrangements occur, but that TCR alpha gene rearrangement continues even after surface expression of a TCR alpha/beta heterodimer, apparently until the recombination process is halted by positive selection, or the cell dies. Sequential rearrangement of TCR alpha chain genes facilitates enhanced production of useful thymocytes, by increasing the frequency of production of both in-frame rearrangements and positively selectable TCR alpha/beta heterodimers.

The half-life of RAG-1 protein in precursor B cells is increased in the absence of RAG-2 expression.

Site-specific recombination of immunoglobulin and T cell receptor gene segments in B and T lymphocytes is dependent on the expression of two recombinant activation genes, Rag-1 and Rag-2. Here, we show that RAG-1 protein turnover in pre-B cells depends on the expression of RAG-2. The apparent half-life of RAG-1 protein is increased when RAG-2 is not expressed in differentiating pre-B cells.

Genetic modulation of T cell receptor gene segment usage during somatic recombination.

Lymphocyte antigen receptors are not encoded by germline genes, but rather are produced by combinatorial joining between clusters of gene segments in somatic cells. Within a given cluster, gene segment usage during recombination is thought to be largely random, with biased representation in mature T lymphocytes resulting from protein-mediated selection of a subset of the total repertoire. Here we show that T cell receptor D beta and J beta gene segment usage is not random, but is patterned at the time of recombination. The hierarchy of gene segment usage is independent of gene segment proximity, but rather is influenced by the ability of the flanking recombination signal sequences (RSS) to bind the recombinase and/or to form a paired synaptic complex. Importantly, the relative frequency of gene segment usage established during recombination is very similar to that found after protein-mediated selection, suggesting that in addition to targeting recombinase activity, the RSS may have evolved to bias the naive repertoire in favor of useful gene products.

Transient restoration of gene rearrangement at multiple T cell receptor loci in gamma-irradiated scid mice.

The developmental arrest of thymocytes from scid mice, deficient in variable, (diversity), and joining, or V(D)J recombination, can be overcome by sublethal gamma-irradiation. Since previous studies focused on restoration of rearrangement of the T cell receptor (TCR) beta locus, productive rearrangement of which is selected for, we sought to examine to what extent locus specificity and cellular selection contributed to the observed effects. We report here that irradiation of newborn scid mice induces normal V-D-J rearrangements of the TCR delta locus, which like TCR beta, is also actively rearranged in CD(4-)CD(8-) (double negative) thymocytes. In contrast, no complete V-J alpha rearrangements were detected. Instead, we detected substantial levels of hairpin-terminated coding ends at the 5' end of the J alpha locus, demonstrating that TCR alpha rearrangements manifest the effects of the scid mutation. Irradiation, therefore, transiently compensates for the effects of the scid mutation in a locus-nonspecific manner in thymocytes, resulting in a burst of normal TCR beta and delta rearrangements. Irradiation also allows the development of cells that can initiate but fail to complete V(D)J recombination events at the TCR alpha locus, which is normally inaccessible in scid thymocytes.

RAG-1 and RAG-2, adjacent genes that synergistically activate V(D)J recombination.

The vast repertoire of immunoglobulins and T cell receptors is generated, in part, by V(D)J recombination, a series of genomic rearrangements that occur specifically in developing lymphocytes. The recombination activating gene, RAG-1, which is a gene expressed exclusively in maturing lymphoid cells, was previously isolated. RAG-1 inefficiently induced V(D)J recombinase activity when transfected into fibroblasts, but cotransfection with an adjacent gene, RAG-2, has resulted in at least a 1000-fold increase in the frequency of recombination. The 2.1-kilobase RAG-2 complementary DNA encodes a putative protein of 527 amino acids whose sequence is unrelated to that of RAG-1. Like RAG-1, RAG-2 is conserved between species that carry out V(D)J recombination, and its expression pattern correlates precisely with that of V(D)J recombinase activity. In addition to being located just 8 kilobases apart, these convergently transcribed genes are unusual in that most, if not all, of their coding and 3' untranslated sequences are contained in single exons. RAG-1 and RAG-2 might activate the expression of the V(D)J recombinase but, more likely, they directly participate in the recombination reaction.

Neoteny in lymphocytes: Rag1 and Rag2 expression in germinal center B cells.

The products of the Rag1 and Rag2 genes drive genomic V(D)J rearrangements that assemble functional immunoglobulin and T cell antigen receptor genes. Expression of the Rag genes has been thought to be limited to developmentally immature lymphocyte populations that in normal adult animals are primarily restricted to the bone marrow and thymus. Abundant RAG1 and RAG2 protein and messenger RNA was detected in the activated B cells that populate murine splenic and Peyer's patch germinal centers. Germinal center B cells thus share fundamental characteristics of immature lymphocytes, raising the possibility that antigen-dependent secondary V(D)J rearrangements modify the peripheral antibody repertoire.

Thymocyte expression of RAG-1 and RAG-2: termination by T cell receptor cross-linking.

The expression of the V(D)J [variable (diversity) joining elements] recombination activating genes, RAG-1 and RAG-2, has been examined during T cell development in the thymus. In situ hybridization to intact thymus and RNA blot analysis of isolated thymic subpopulations separated on the basis of T cell receptor (TCR) expression demonstrated that both TCR- and TCR+ cortical thymocytes express RAG-1 and RAG-2 messenger RNA's. Within the TCR+ population, RAG expression was observed in immature CD4+CD8+ (double positive) cells, but not in the more mature CD4+CD8- or CD4-CD8+ (single positive) subpopulations. Thus, although cortical thymocytes that bear TCR on their surface continue to express RAG-1 and RAG-2, it appears that the expression of both genes is normally terminated during subsequent thymic maturation. Since thymocyte maturation in vivo is thought to be regulated through the interaction of the TCR complex with self major histocompatibility complex (MHC) antigens, these data suggest that signals transduced by the TCR complex might result in the termination of RAG expression. Consistent with this hypothesis, thymocyte TCR cross-linking in vitro led to rapid termination of RAG-1 and RAG-2 expression, whereas cross-linking of other T cell surface antigens such as CD4, CD8, or HLA class I had no effect.

Developmental neurobiology: Alternative ends for a familiar story?

Somatic DNA recombination is essential for production of functional antigen receptor genes of T and B lymphocytes, but it is thought to be unique to the immune system. Recent studies have now shown that recombination-related genes are also necessary for normal neuronal development.

T-cell receptor alpha locus V(D)J recombination by-products are abundant in thymocytes and mature T cells.

In addition to the assembled coding regions of immunoglobulin and T-cell receptor (TCR) genes, the V(D)J recombination reaction can in principle generate three types of by-products in normal developing lymphocytes: broken DNA molecules that terminate in a recombination signal sequence or a coding region (termed signal or coding end molecules, respectively) and DNA molecules containing fused recombination signal sequences (termed reciprocal products). Using a quantitative Southern blot analysis of the murine TCR alpha locus, we demonstrate that substantial amounts of signal end molecules and reciprocal products, but not coding end molecules, exist in thymocytes, while peripheral T cells contain substantial amounts of reciprocal products. At the 5' end of the J alpha locus, 20% of thymus DNA exists as signal end molecules. An additional 30 to 40% of the TCR alpha/delta locus exists as remarkably stable reciprocal products throughout T-cell development, with the consequence that the TCR C delta region is substantially retained in alpha beta committed T cells. The disappearance of the broken DNA molecules occurs in the same developmental transition as termination of expression of the recombination activating genes, RAG-1 and RAG-2. These findings raise important questions concerning the mechanism of V(D)J recombination and the maintenance of genome integrity during lymphoid development.

DNA hairpin opening mediated by the RAG1 and RAG2 proteins.

The lymphoid cell-specific proteins RAG1 and RAG2 initiate V(D)J recombination by cleaving DNA adjacent to recombination signals, generating blunt signal ends and covalently sealed, hairpin coding ends. A critical next step in the reaction is opening of the hairpins, but the factor(s) responsible has not been identified and had been thought to be a ubiquitous component(s) of the DNA repair machinery. Here we demonstrate that RAG1 and RAG2 possess an intrinsic single-stranded nuclease activity capable of nicking hairpin coding ends at or near the hairpin tip. In Mn2+, a synthetic hairpin is nicked 5 nucleotides (nt) 5' of the hairpin tip, with more distant sites of nicking suppressed by HMG2. In Mg2+, hairpins generated by V(D)J cleavage are nicked whereas synthetic hairpins are not. Cleavage-generated hairpins are nicked at the tip and predominantly 1 to 2 nt 5' of the tip. RAG1 and RAG2 may therefore be responsible for initiating the processing of coding ends and for the generation of P nucleotides during V(D)J recombination.

rag-1 and rag-2 are components of a high-molecular-weight complex, and association of rag-2 with this complex is rag-1 dependent.

Despite the essential and synergistic functions of the rag-1 and rag-2 proteins in V(D)J recombination and lymphocyte development, little is known about the biochemical properties of the two proteins. We have developed cell lines expressing high levels of the rag proteins and specific, sensitive immunological reagents for their detection, and we have examined the physical properties of the rag proteins in vitro and their subcellular localizations in vivo. rag-1 is tightly associated with nuclear structures, requires a high salt concentration to maintain its solubility, and is a component of large, heterogeneously sized complexes. Furthermore, the presence of rag-1 alters the behavior of rag-2, conferring on it properties similar to those of rag-1 and changing its distribution in the nucleus. We demonstrate that rag-1 and rag-2 are present in the same complex by coimmunoprecipitation, and we provide evidence that these complexes contain more molecules of rag-2 than of rag-1. The demonstration of intracellular complexes containing rag-1 and rag-2 raises the possibility that interaction between these proteins is necessary for their biological function.

Detection of RAG protein-V(D)J recombination signal interactions near the site of DNA cleavage by UV cross-linking.

V(D)J recombination is initiated by double-strand cleavage at recombination signal sequences (RSSs). DNA cleavage is mediated by the RAG1 and RAG2 proteins. Recent experiments describing RAG protein-RSS complexes, while defining the interaction of RAG1 with the nonamer, have not assigned contacts immediately adjacent to the site of DNA cleavage to either RAG polypeptide. Here we use UV cross-linking to define sequence- and site-specific interactions between RAG1 protein and both the heptamer element of the RSS and the coding flank DNA. Hence, RAG1-DNA contacts span the site of cleavage. We also detect cross-linking of RAG2 protein to some of the same nucleotides that cross-link to RAG1, indicating that, in the binding complex, both RAG proteins are in close proximity to the site of cleavage. These results suggest how the heptamer element, the recognition surface essential for DNA cleavage, is recognized by the RAG proteins and have implications for the stoichiometry and active site organization of the RAG1-RAG2-RSS complex.

Increased frequency of N-region insertion in a murine pre-B-cell line infected with a terminal deoxynucleotidyl transferase retroviral expression vector.

The role of terminal deoxynucleotidyl transferase (TdT) in the insertion of N regions into the junctional sites of immunoglobulin genes was investigated. Pre-B-cell lines capable of continuous rearrangement of immunoglobulin light-chain genes and differing only in the presence or apparent absence of TdT were derived by infecting cells with a TdT retroviral expression vector or a control vector. The cell lines were then superinfected with a retrovirus-based artificial immunoglobulin gene rearrangement substrate. The substrate was allowed to rearrange in the cell lines and the rearranged proviruses were rescued from the cell lines. Nucleotide sequence analysis of the V-J junctions of the proviral rearranged genes showed a fivefold greater frequency of N-region insertion in proviruses rescued from the TdT+ cell lines than in those rescued from the TdT- cell lines, so that at least 50% of the rearrangements that occurred in the presence of TdT had N regions. It is thus evident that TdT can stimulate N-region insertion, and the enzyme is presumably directly responsible for adding nucleotides at V-J and other immunoglobulin and T-cell receptor gene junctions.

A basic motif in the N-terminal region of RAG1 enhances V(D)J recombination activity.

The variable portions of antigen receptor genes are assembled from component gene segments by a site-specific recombination reaction known as V(D)J recombination. The RAG1 and RAG2 proteins are the critical lymphoid cell-specific components of the recombination enzymatic machinery and are responsible for site-specific DNA recognition and cleavage. Previous studies had defined a minimal, recombinationally active core region of murine RAG1 consisting of amino acids 384 to 1008 of the 1,040-residue RAG1 protein. No recombination function has heretofore been ascribed to any portion of the 383-amino-acid N-terminal region that is missing from the core, but it seems likely to be of functional significance, based on its evolutionary conservation. Using extrachromosomal recombination substrates, we demonstrate here that the N-terminal region enhances the recombination activity of RAG1 by up to an order of magnitude in a variety of cell lines. Deletion analysis localized a region of the N terminus critical for this effect to amino acids 216 to 238, and further mutagenesis demonstrated that a small basic amino acid motif (BIIa) in this region is essential for enhancing the activity of RAG1. Despite the fact that BIIa is important for the interaction of RAG1 with the nuclear localization factor Srp-1, it does not appear to enhance recombination by facilitating nuclear transport of RAG1. A variety of models for how this region stimulates the recombination activity of RAG1 are considered.

Biochemistry of V(D)J recombination.

The genes that encode immunoglobulin and T cell receptor proteins are assembled from component gene segments in a reaction known as V(D)J recombination. The reaction, and its crucial mediators RAG1 and RAG2, are essential for lymphocyte development and hence for adaptive immunity. Here we consider the biochemistry of this reaction, focusing on the DNA transactions and the proteins involved. We discuss how the RAG proteins interact with DNA and how coordinate cleavage of the DNA at two sites might be achieved. Finally, we consider the RAG proteins and V(D)J recombination from an evolutionary point of view.

Identification of V(D)J recombination coding end intermediates in normal thymocytes.

Diversity of vertebrate antigen receptors is accomplished in large part by a somatic gene rearrangement process known as V(D)J recombination. The first step of the reaction appears to be the creation of a double strand break immediately between the recombination signal sequence (RSS) and the coding gene segment to generate a signal end and a coding end. Signal ends have been shown, both in vitro and in vivo, to be precise and blunt, while coding ends generated in vitro are covalently sealed hairpins. It has been difficult to document the existence of coding ends in vivo in normal lymphoid precursors, presumably because of their low abundance. To date, they have been identified in vivo only in a transformed pre-B cell line and in cells from the mutant scid mouse, where they largely conform to the hairpin structure found in vitro. Here, we identify T cell receptor J alpha gene coding ends in normal murine thymocytes. We demonstrate that these ends are processed, not blunt, and that most are not hairpin terminated, in sharp contrast to previous in vivo and in vitro observations. These results provide the first direct demonstration of this important intermediate of V(D)J recombination in normal lymphoid precursors and have implications for the mechanism of coding joint formation in vivo.

A zinc-binding domain involved in the dimerization of RAG1.

Recombination-activating gene 1 (RAG1), as well as RAG2, are the only lymphoid-specific genes required for V(D)J recombination. RAG1 protein contains a C3HC4 zinc-binding motif (zinc ring finger) that binds two zinc ions. We have found that RAG1 contains additional zinc-binding motifs in the form of two separate C2H2 zinc finger sequences. One of the zinc fingers, in combination with the C3HC4 subdomain, forms a highly specific dimerization domain. A combination of biophysical techniques has been used to determine the energetics of association, the overall shape of the dimerization domain, and the relative orientation of the monomeric subunits within the dimer. These results provide direct evidence that a C3HC4 motif is involved in a protein-protein interaction, in this case via homodimer formation. In addition, the observation that the dimerization domain includes multi-class zinc binding motifs, namely both a zinc finger and a C3HC4 subdomain, has important implications for other C3HC4-containing proteins. The position of this dimerization domain in the N-terminal third of the RAG1 sequence of 1040 amino acid residues may have a significant influence on the activities associated with the C-terminal domains of the protein.

Transposition mediated by RAG1 and RAG2 and the evolution of the adaptive immune system.

The RAG1 and RAG2 proteins together initiate V(D)J recombination by performing cleavage of chromosomal DNA adjacent to antigen receptor gene segments. Like the adaptive immune system itself, RAG1 and RAG2 are found only in jawed vertebrates. The hypothesis that RAG1 and RAG2 arose in evolution as components of a transposable element has received dramatic support from our recent finding that the RAG proteins are a fully functional transposase in vitro. This result strongly suggests that antigen receptor genes acquired their unusual structure as a consequence of the insertion of a transposable element into an ancestral receptor gene by RAG1 and RAG2 approx 450 million years ago.