A role for MAPK in feedback inhibition of Tcrb recombination

The Tcrb locus is subject to a host of regulatory mechanisms that impart a strict cell and developmental stage-specific order to variable (V), diversity (D), and joining (J) gene segment recombination. The Tcrb locus is also regulated by allelic exclusion mechanisms, which restrict functional rearrangements to a single allele. The production of a functional rearrangement in CD4-CD8- double-negative (DN) thymocytes leads to the assembly of a pre-TCR and initiates signaling cascades that allow for DN to CD4+CD8+ double-positive (DP) differentiation, proliferation, and feedback inhibition of further Vbeta to DJbeta rearrangement. Feedback inhibition is believed to be controlled, in part, by the loss of Vbeta gene segment accessibility during the DN to DP transition. However, the pre-TCR signaling pathways that lead to the inactivation of Vbeta chromatin have not been determined. Because activation of the MAPK pathway is documented to promote DP differentiation in the absence of allelic exclusion, we characterized the properties of Vbeta chromatin within DP thymocytes generated by a constitutively active Raf1 (Raf-CAAX) transgene. Consistent with previous reports, we show that the Raf-CAAX transgene does not inhibit Tcrb recombination in DN thymocytes. Nevertheless, DP thymocytes generated by Raf-CAAX signals display normal down-regulation of Vbeta segment accessibility and normal feedback inhibition of the Vbeta to DJbeta rearrangement. Therefore, our results emphasize the distinct requirements for feedback inhibition in the DN and DP compartments. Although MAPK activation cannot impose feedback in DN thymocytes, it contributes to feedback inhibition through developmental changes that are tightly linked to DN to DP differentiation.     

Regulation of TCRβ allelic exclusion by gene segment proximity and accessibility

Ag receptor loci are regulated to promote allelic exclusion, but the mechanisms are not well understood. Assembly of a functional TCR β-chain gene triggers feedback inhibition of V(β)-to-DJ(β) recombination in double-positive (DP) thymocytes, which correlates with reduced V(β) chromatin accessibility and a locus conformational change that separates V(β) from DJ(β) gene segments. We previously generated a Tcrb allele that maintained V(β) accessibility but was still subject to feedback inhibition in DP thymocytes. We have now further analyzed the contributions of chromatin accessibility and locus conformation to feedback inhibition using two novel TCR alleles. We show that reduced V(β) accessibility and increased distance between V(β) and DJ(β) gene segments both enforce feedback inhibition in DP thymocytes.     

Assessing the role of the T cell receptor beta gene enhancer in regulating coding joint formation during V(D)J recombination

To assess the role of the T cell receptor (TCR) beta gene enhancer (Ebeta) in regulating the processing of VDJ recombinase-generated coding ends, we assayed TCRbeta rearrangement of Ebeta-deleted (DeltaEbeta) thymocytes in which cell death is inhibited via expression of a Bcl-2 transgene. Compared with DeltaEbeta, DeltaEbeta Bcl-2 thymocytes show a small accumulation of TCRbeta standard recombination products, including coding ends, that involves the proximal Dbeta-Jbeta and Vbeta14 loci but not the distal 5' Vbeta genes. These effects are detectable in double negative pro-T cells, predominate in double positive pre-T cells, and correlate with regional changes in chromosomal structure during double negative-to-double positive differentiation. We propose that Ebeta, by driving long range nucleoprotein interactions and the control of locus expression and chromatin structure, indirectly contributes to the stabilization of coding ends within the recombination processing complexes. The results also illustrate Ebeta-dependent and -independent changes in chromosomal structure, suggesting distinct modes of regulation of TCRbeta allelic exclusion depending on the position within the locus.     

The requirement for pre-TCR during thymic differentiation enforces a developmental pause that is essential for V-DJβ rearrangement

T cell development occurs in the thymus and is critically dependent on productive TCRβ rearrangement and pre-TCR expression in DN3 cells. The requirement for pre-TCR expression results in the arrest of thymocytes at the DN3 stage (β checkpoint), which is uniquely permissive for V-DJβ recombination; only cells expressing pre-TCR survive and develop beyond the DN3 stage. In addition, the requirement for TCRβ rearrangement and pre-TCR expression enforces suppression of TCRβ rearrangement on a second allele, allelic exclusion, thus ensuring that each T cell expresses only a single TCRβ product. However, it is not known whether pre-TCR expression is essential for allelic exclusion or alternatively if allelic exclusion is enforced by developmental changes that can occur in the absence of pre-TCR. We asked if thymocytes that were differentiated without pre-TCR expression, and therefore without pause at the β checkpoint, would suppress all V-DJβ rearrangement. We previously reported that premature CD28 signaling in murine CD4(-)CD8(-) (DN) thymocytes supports differentiation of CD4(+)CD8(+) (DP) cells in the absence of pre-TCR expression. The present study uses this model to define requirements for TCRβ rearrangement and allelic exclusion. We demonstrate that if cells exit the DN3 developmental stage before TCRβ rearrangement occurs, V-DJβ rearrangement never occurs, even in DP cells that are permissive for D-Jβ and TCRα rearrangement. These results demonstrate that pre-TCR expression is not essential for thymic differentiation to DP cells or for V-DJβ suppression. However, the requirement for pre-TCR signals and the exclusion of alternative stimuli such as CD28 enforce a developmental "pause" in early DN3 cells that is essential for productive TCRβ rearrangement to occur.     

Productive coupling of accessible Vbeta14 segments and DJbeta complexes determines the frequency of Vbeta14 rearrangement

To elucidate mechanisms that regulate Vbeta rearrangement, we generated and analyzed mice with a V(D)J recombination reporter cassette of germline Dbeta-Jbeta segments inserted into the endogenous Vbeta14 locus (Vbeta14(Rep)). As a control, we first generated and analyzed mice with the same Dbeta-Jbeta cassette targeted into the generally expressed c-myc locus (c-myc(Rep)). Substantial c-myc(Rep) recombination occurred in both T and B cells and initiated concurrently with endogenous Dbeta to Jbeta rearrangements in thymocytes. In contrast, Vbeta14(Rep) recombination was restricted to T cells and initiated after endogenous Dbeta to Jbeta rearrangements, but concurrently with endogenous Vbeta14 rearrangements. Thus, the local chromatin environment imparts lineage and developmental stage-specific accessibility upon the inserted reporter. Although Vbeta14 rearrangements occur on only 5% of endogenous TCRbeta alleles, the Vbeta14(Rep) cassette underwent rearrangement on 80-90% of alleles, supporting the suggestion that productive coupling of accessible Vbeta14 segments and DJbeta complexes influence the frequency of Vbeta14 rearrangements. Strikingly, Vbeta14(Rep) recombination also occurs on TCRbeta alleles lacking endogenous Vbeta to DJbeta rearrangements, indicating that Vbeta14 accessibility per se is not subject to allelic exclusion.     

Inhibition of T-cell receptor beta-chain gene rearrangement by overexpression of the non-receptor protein tyrosine kinase p56lck.

The variable region genes of the T cell receptor (TCR) alpha and beta chains are assembled by somatic recombination of separate germline elements. During thymocyte development, gene rearrangements display both an ordered progression, with beta chain formation preceding alpha chain, and allelic exclusion, with each cell containing a single functional beta chain rearrangement. Although considerable evidence supports the view that the individual loci are regulated independently, signaling molecules that may participate in controlling TCR gene recombination remain unidentified. Here we report that the lymphocyte-specific protein tyrosine kinase p56lck, when overexpressed in developing thymocytes, provokes a reduction in V beta--D beta rearrangement while permitting normal juxtaposition of other TCR gene segments. Our data support a model in which p56lck activity impinges upon a signaling process that ordinarily permits allelic exclusion at the beta-chain locus.     

Changes in histone acetylation are associated with differences in accessibility of V(H) gene segments to V-DJ recombination during B-cell ontogeny and development

Although V(D)J recombination is thought to be regulated by changes in the accessibility of chromatin to the recombinase machinery, the mechanisms responsible for establishing "open" chromatin are poorly understood. We performed a detailed study of the acetylation status of histones associated with 11 V(H) gene segments, their flanking regions, and various intergenic elements during B-cell development and ontogeny, when V(D)J recombination is highly regulated. Histone H4 shows higher and more-regulated acetylation than does histone H3 in the V(H) locus. In adult pro-B cells, V(H) gene segments are acetylated prior to V(D)J rearrangement, with higher acetylation associated with J(H)-distal V(H) gene segments. While large regions of the V(H) locus have similar patterns of histone acetylation, acetylation is narrowly confined to the gene segments, their flanking promoters, and recombinase signal sequence elements. Thus, histone acetylation in the V(H) locus is both locally and globally regulated. Increased histone acetylation accompanies preferential recombination of J(H)-proximal V(H) gene segments in early B-cell ontogeny, and decreased histone acetylation accompanies inhibition of V-DJ recombination in a transgenic model of immunoglobulin heavy-chain allelic exclusion. Thus, changes in histone acetylation appear to be important for both promotion and inhibition of V-DJ rearrangement during B-cell ontogeny and development.     

Allelic exclusion of a T cell receptor-beta minilocus.

A TCR-beta minilocus in germline configuration (beta M) has previously been shown to undergo rearrangement and expression in transgenic mice. To study allelic exclusion of TCR miniloci, several beta M transgenic mouse lines were generated and crossed with mice transgenic for a functionally rearranged TCR V beta 2 gene (beta R). PCR analysis of beta M beta R double transgenic mice revealed almost complete suppression of endogenous TCR V beta gene rearrangements, but blockage of minilocus V beta rearrangements was achieved with only one of five minilocus transgenic lines. This result cannot be explained by copy number or arrangement of the multiple miniloci integrated. It appears that the minilocus is not autonomously regulated which suggests that sequences flanking the integration sites influence accessibility of the minilocus for rearrangement and allelic exclusion. However, although productively rearranged genes were formed in double transgenic mice, surface expression of minilocus-encoded beta chains was not detected. This indicates that allelic exclusion may operate at a level after gene rearrangement.     

Expression of TCR alpha beta partly rescues developmental arrest and apoptosis of alpha beta T cells in Bcl11b-/- mice

Bcl11b(-/-) mice show developmental arrest at the CD44(-)CD25(+) double-negative 3 (DN3) or immature CD8(+)single-positive stage of alphabeta T cell. We have performed detailed analysis of sorted subsets of Bcl11b(-/-) thymocytes, DN3 and CD44(-)CD25(-) double-negative 4 (DN4) cells. Surface expression of TCRbeta proteins was not detected in DN3 thymocytes and markedly reduced in DN4 thymocytes, whereas expression within the cell was detected in both, suggesting some impairment in processing of TCRbeta proteins from the cytoplasm to the cell surface. This lack of expression, resulting in the absence of pre-TCR signaling, could be responsible for the arrest, but the transgenic TCRbeta or TCRalphabeta expression on the cell surface failed to promote transition from the DN3 to CD4(+)CD8(+) double-positive stage of development. This suggests that the pre-TCR signal cannot compensate the deficiency of Bcl11b for development. Bcl11b(-/-) DN3 thymocytes showed normal DNA rearrangements between Dbeta and Jbeta segments but limited DNA rearrangements between Vbeta and DJbeta without effect of distal or proximal positions. Because this impairment may be due to chromatin accessibility, we have examined histone H3 acetylation in Bcl11b(-/-) DN3 cells using chromatin immunoprecipitation assay. No change was observed in acetylation at the Vbeta and Dbeta gene locus. Analysis of Bcl11b(-/-) DN4 thymocytes showed apoptosis, accompanied with lower expression of anti-apoptotic proteins, Bcl-x(L) and Bcl-2, than wild-type DN4 thymocytes. Interestingly, the transgenic TCRalphabeta in those cells reduced apoptosis and raised their protein expression without increased cellularity. These results suggest that Bcl11b deficiency affects many different signaling pathways leading to development arrests.     

Phenotype, ontogeny, and repertoire of CD4-CD8- T cell receptor alpha beta + thymocytes. Variable influence of self-antigens on T cell receptor V beta usage

We have characterized CD4-CD8- double negative (DN) thymocytes that express TCR-alpha beta and represent a minor thymocyte subpopulation expressing a markedly skewed TCR repertoire. We found that DN TCR-alpha beta + thymocytes resemble mature T cells in that they (a) are phenotypically CD2hiCD5hiQa2+HSA-, (b) appear late in ontogeny, and (c) are susceptible to cyclosporin A-induced maturation arrest. In addition, we found that DNA sequences 5' to the CD8 alpha gene were demethylated relative to their germline state, suggesting that DN TCR-alpha beta + thymocytes are derived from cells that had at one time expressed their CD8 alpha gene locus. Because DN TCR-alpha beta + thymocytes are known to express an unusual TCR repertoire with significant overexpression of V beta 8, we were interested in examining the possible role played by self-Ag in shaping their TCR repertoire. It has been suggested that DN TCR-alpha beta + thymocytes are derived from potentially self-reactive thymocytes that have escaped clonal deletion by down-regulating their surface expression of CD4 and/or CD8 determinants. However, apparently inconsistent with such an hypothesis, we found that the frequency of DN thymocytes expressing various anti-self TCR (V beta 6, V beta 8.1, V beta 11, V beta 17a) were not increased in strains expressing their putative self-Ag, but instead were either unaffected or significantly reduced in those strains. With regard to V beta 8 expression among DN TCR-alpha beta + thymocytes, V beta 8 overexpression in DN TCR-alpha beta + thymocytes appeared to be independent of, and superimposed on, the developmental appearance of the basic DN thymocyte repertoire. Even though V beta 8 overexpression appeared to be generated by a mechanism distinct from that generating the rest of the DN TCR-alpha beta + thymocyte repertoire, we found that super-Ag against which V beta 8 TCR react introduced into the neonatal differentiation environment also significantly reduced, rather than increased, the frequency of DN TCR-alpha beta + V beta 8+ thymocytes. Thus, the present study is consistent with DN TCR-alpha beta + thymocytes being mature cells derived from CD8+ precursors, and documents that their TCR repertoire can be influenced, at least negatively, by either self-Ag or Ag introduced into the neonatal differentiation environment. However, we found no evidence to support the hypothesis that DN TCR-alpha beta + thymocytes are enriched in cells expressing TCR reactive against self-Ag.