Hepatitis C virus upregulates B-cell receptor signaling: a novel mechanism for HCV-associated B-cell lymphoproliferative disorders.

B-cell receptor (BCR) signaling is essential for the development of B cells and has a critical role in B-cell neoplasia. Increasing evidence indicates an association between chronic hepatitis C virus (HCV) infection and B-cell lymphoma, however, the mechanisms by which HCV causes B-cell lymphoproliferative disorder are still unclear. Herein, we demonstrate the expression of HCV viral proteins in B cells of HCV-infected patients and show that HCV upregulates BCR signaling in human primary B cells. HCV nonstructural protein NS3/4A interacts with CHK2 and downregulates its activity, modulating HuR posttranscriptional regulation of a network of target mRNAs associated with B-cell lymphoproliferative disorders. Interestingly, the BCR signaling pathway was found to have the largest number of transcripts with increased association with HuR and was upregulated by NS3/4A. Our study reveals a previously unidentified role of NS3/4A in regulation of host BCR signaling during HCV infection, contributing to a better understanding of the molecular mechanisms underlying HCV-associated B-cell lymphoproliferative disorders.

Uncoupling proteins-2 and 3 influence obesity and inflammation in transgenic mice.

OBJECTIVE: To test the hypothesis that either uncoupling protein-2 UCP2 or UCP3 or both together influence obesity and inflammation in transgenic mice. DESIGN: We generated 12 lines of transgenic mice for both human UCP2 and 3 using native promoters from a human bacterial artificial chromosome (BAC) clone. The BAC expresses no genes other than UCP2 and 3. Mice used for experiments are N4 or higher of backcross to C57BL/6J (B6). Each experiment used transgenic mice and their nontransgenic littermates. RESULTS: Northern blots confirmed expression on human UCP2 in adipose and spleen, while human UCP3 expression was detectable in gastrocnemius muscle. Western blots demonstrated a four-fold increase of UCP2 protein in spleens of Line 32 transgenic animals. Heterozygous mice of four lines showing expression of human UCP2 in spleen were examined for obesity phenotypes. There were no significant differences between Lines 1 and 32, but female transgenics of both lines had significantly smaller femoral fat depots than the control (littermate) mice (P=0.015 and 0.005, respectively). In addition, total fat of transgenic females was significantly less in Line 1 (P=0.05) and almost significantly different in Line 32 (P=0.06). Male Line 1 mice were leaner (P=0.04) while male Line 32 mice were almost significantly leaner (P=0.06). Heterozygous mice of Lines 35 and 44 showed no significant differences from the nontransgenic littermate controls. Effects of the UCP2/UCP3 transgene on obesity in Line 32 mice were confirmed by crossing transgenic mice with the B6.Cg-Ay agouti obese mice. B6.Cg-Ay carrying the UCP2/UCP3 transgene from Line 32 were significantly leaner than nontransgenic B6.Cg-Ay mice. Line 32 UCP2/UCP3 transgenics showed increased hypothalamic Neuropeptide (NPY) levels and food intake, with reduced spontaneous physical activity. Transgenic baseline interleukin4 (IL-4) and interleukin6 (IL-6) levels were low with lower or later increases after endotoxin injection compared to wild-type littermates. Endotoxin-induced fever was also diminished in transgenic male animals. Low-density lipoprotein (LDL) cholesterol levels were significantly higher in both Line 1 and 32 transgenics (P=0.05 and 0.001, respectively) after they had been placed on a moderate fat-defined diet containing 32% of calories from fat for 5 weeks. CONCLUSION: Moderate overexpression of UCP2 and 3 reduced fat mass and increased LDL cholesterol in two independent lines of transgenic mice. Thus, the reduced fat mass cannot be due to insertional mutagenesis since virtually identical fat pad weights and masses were observed with the two independent lines. Line 32 mice also have altered inflammation and mitochondrial function. We conclude that UCP2 and/or 3 have small but significant effects on obesity in mice, and that their mechanism of action may include alterations of metabolic rate.

Somatic generation of antigen-receptor diversity: a reprise.

Thirty years ago, in his inaugural article entitled 'The somatic generation of immune recognition', Niels Jerne put forward the hypothesis that the primary antigen (Ag)-receptor repertoire must be restricted towards self-Ags before Ag-mediated selection. The subsequent discovery that Ag receptors are encoded by random rearrangements between discontinuous gene segments was, apparently, at odds with this hypothesis. However, recent findings have begun to reconcile these two concepts. The recombination process is, in fact, relatively precise, exhibiting marked preferences for some gene segments over others, even among members of the same gene family. The result is an intricately patterned primary repertoire that accommodates both sets of predictions, ensuring a balance between the efficiency of selection (requiring limited diversity) and the complexity of the repertoire (requiring maximum diversity).

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.

Precursor thymocyte proliferation and differentiation are controlled by signals unrelated to the pre-TCR.

In-frame rearrangement of the TCR-beta locus and expression of the pre-TCR are compulsory for the production of CD4+8+ thymocytes from CD4-8- precursors. Signals delivered via the pre-TCR are thought to induce the differentiation process as well as the extensive proliferation that accompanies this transition. However, it is equally possible that pre-TCR expression is required for the success of this transition, but does not play a direct role in the inductive process. In the present manuscript we examine this possibility using a variety of normal and genetically modified mouse models. Our evidence shows that differentiation and mitogenesis can both occur independently of pre-TCR expression. However, these processes are absolutely dependent on the presence of normal thymic architecture and cellular composition. These findings are consistent with a checkpoint role for the pre-TCR in regulating the divergence of survival and cell death fates at the CD4-8- to CD4+8+ transition. Further, our data suggest that precursor thymocyte differentiation is induced by other, probably ubiquitous, mechanisms that require the presence of normal thymic cellularity, composition, and architecture.

Characterization of TCR gene rearrangements during adult murine T cell development.

Development of the alphabeta and gammadelta T cell lineages is dependent upon the rearrangement and expression of the TCRalpha and beta or gamma and delta genes, respectively. Although the timing and sequence of rearrangements of the TCRalpha and TCRbeta loci in adult murine thymic precursors has been characterized, no similar information is available for the TCRgamma and TCRdelta loci. In this report, we show that approximately half of the total TCRdelta alleles initiate rearrangements at the CD44highCD25+ stage, whereas the TCRbeta locus is mainly in germline configuration. In the subsequent CD44lowCD25+ stage, most TCRdelta alleles are fully recombined, whereas TCRbeta rearrangements are only complete on 10-30% of alleles. These results indicate that rearrangement at the TCRdelta locus can precede that of TCRbeta locus recombination by one developmental stage. In addition, we find a bias toward productive rearrangements of both TCRdelta and TCRgamma genes among CD44highCD25+ thymocytes, suggesting that functional gammadelta TCR complexes can be formed before the rearrangement of TCRbeta. These data support a model of lineage commitment in which sequential TCR gene rearrangements may influence alphabeta/gammadelta lineage decisions. Further, because TCR gene rearrangements are generally limited to T lineage cells, these analyses provide molecular evidence that irreversible commitment to the T lineage can occur as early as the CD44highCD25+ stage of development.

Distinct effects of Jak3 signaling on alphabeta and gammadelta thymocyte development.

Janus kinase 3 (Jak3) plays a central role in the transduction of signals mediated by the IL-2 family of cytokine receptors. Targeted deletion of the murine Jak3 gene results in severe reduction of alphabeta and complete elimination of gammadelta lineage thymocytes and NK cells. The developmental blockade appears to be imposed on early thymocyte differentiation and/or expansion. In this study, we show that bcl-2 expression and in vivo survival of immature thymocytes are greatly compromised in Jak3-/- mice. There is no gross deficiency in rearrangements of the TCRdelta and certain gamma loci in pre-T cells, and a functional gammadelta TCR transgene cannot rescue gammadelta lineage differentiation in Jak3-/- mice. In contrast, a TCRbeta transgene is partially able to restore alphabeta thymocyte development. These data suggest that the signals mediated by Jak3 are critical for survival of all thymocyte precursors particularly during TCRbeta-chain gene rearrangement, and are continuously required in the gammadelta lineage. The results also emphasize the fundamentally different requirements for differentiation of the alphabeta and gammadelta T cell lineages.

Alternative splicing of rearranged T cell receptor delta sequences to the constant region of the alpha locus.

The T cell receptor (TCR) alpha/delta locus is composed of a common, shared set of variable (V) and distinct diversity (D), joining (J), and constant (C) genes. It has been recognized for several years that transcripts of the rearranged VDJdelta or VJalpha genes are spliced to the Cdelta or Calpha genes, respectively, encoding distinct TCR delta and alpha proteins. Herein, we describe the discovery of a splicing variation that allows the assembled VDJdelta genes to be fused with the Calpha gene. This variation is prominent in TCRdelta gene-deficient mice but is also detectable in wild-type mice. Furthermore, we show that several in-frame VDJdelta rearrangements in TCRdelta gene-deficient mice are strikingly underrepresented, suggesting that the alternative transcripts, with protein coding capacity, influence the development of alphabeta thymocytes. In-frame TCRgamma gene rearrangements do not appear underrepresented, indicating that the effect is not mediated by the gamma chain. Instead, indirect evidence supports the hypothesis that the delta/alpha chimeric protein acts in conjunction with the TCRbeta chain. These results have implications for the transcriptional control of the TCRalpha/delta locus and provide a novel insight into the distinct functional capacities of the TCR alpha and delta proteins during thymocyte development.

Alpha beta lineage-committed thymocytes can be rescued by the gamma delta T cell receptor (TCR) in the absence of TCR beta chain.

Commitment of the alpha beta and gamma delta T cell lineages within the thymus has been studied in T cell receptor (TCR)-transgenic and TCR mutant murine strains. TCR gamma delta-transgenic or TCR beta knockout mice, both of which are unable to generate TCR alpha beta-positive T cells, develop phenotypically alpha beta-like thymocytes in significant proportions. We provide evidence that in the absence of functional TCR beta protein, the gamma delta TCR can promote the development of alpha beta-like thymocytes, which, however, do not expand significantly and do not mature into gamma delta T cells. These results show that commitment to the alpha beta lineage can be determined independently of the isotype of the TCR, and suggest that alpha beta versus gamma delta T cell lineage commitment is principally regulated by mechanisms distinct from TCR-mediated selection. To accommodate our data and those reported previously on the effect of TCR gamma and delta gene rearrangements on alpha beta T cell development, we propose a model in which lineage commitment occurs independently of TCR gene rearrangement.

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.

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.

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.

T cell receptor gene recombination patterns and mechanisms: cell death, rescue, and T cell production.

The antigen-specific receptors of T and B lymphocytes are generated by somatic recombination between noncontiguous gene segments encoding the variable portions of these molecules. The semirandom nature of this process, while desirable for the generation of diversity, has been thought to exact a high price in terms of sterile (out-of-frame) products. Historically, the majority of T lymphocytes generated in mammals were thought to be useless, either because they generated such sterile rearrangements or because the receptors generated did not appropriately recognize self-molecules (i.e., positive and negative selection). In the studies described here, we characterize the onset of T cell receptor (TCR) alpha and beta chain gene rearrangements and quantitate their progression throughout T cell development. The results show that T cell production efficiency is enhanced through (a) rearrangement of TCR-beta chain genes early during T cell development, with selective expansion of those cells possessing in-frame rearrangements; (b) deletion of sterile rearrangements at the TCR-alpha chain locus through ordered (proximal to distal) sequential recombination; and (c) modification of nonselectable alpha/beta heterodimer specificities through generation and expression of new TCR-alpha chains. In addition, we demonstrate strict correlations between successful TCR-beta gene rearrangement, the onset of TCR-alpha gene rearrangement, rapid cell division, and programmed cell death, which together serve to maintain cell turnover and homeostasis during T cell development.

In-frame TCR delta gene rearrangements play a critical role in the alpha beta/gamma delta T cell lineage decision.

Using a quantitative multiprobe Southern blot analysis, we demonstrate the surprising result that a significant proportion of alpha beta T cells and thymocytes retain T cell receptor delta locus sequences. A substantial portion of the retained delta locus is in a fully V-to-D-to-J rearranged configuration and 20% of these delta rearrangements are functional, significantly less than the 33% predicted for random gene rearrangements. Our observations are in conflict with the idea that alpha beta and gamma delta T cells derive from distinct precursors and suggest that commitment of a common precursor to the gamma delta lineage depends upon expression of a gamma delta T cell receptor. We propose that the intrathymic T cell lineage decision is determined by a competition between the production of functional gamma delta and beta-pre-T cell receptor complexes.

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.