A new transcript in the TCRB locus unveils the human ortholog of the mouse pre-Dß1 promoter.

INTRODUCTION: While most transcripts arising from the human T Cell Receptor locus reflect fully rearranged genes, several germline transcripts have been identified. We describe a new germline transcript arising from the human TCRB locus. METHODS: cDNA sequencing, promoter, and gene expression analyses were used to characterize the new transcript. RESULTS: The new germline transcript encoded by the human TCRB locus consists of a new exon of 103 bp, which we named TRBX1 (X1), spliced with the first exon of gene segments Cß1 or Cß2. X1 is located upstream of gene segment Dß1 and is therefore deleted from a V-DJ rearranged TCRB locus. The X1-Cß transcripts do not appear to code for a protein. We define their transcription start and minimal promoter. These transcripts are found in populations of mature T lymphocytes from blood or tissues and in T cell clones with a monoallelic TCRB rearrangement. In immature thymocytes, they are already detectable in CD1a- CD34+ CD4- CD8- cells, therefore before completion of the TCRB rearrangements. CONCLUSIONS: The X1 promoter appears to be the ortholog of the mouse pre-Dß1 promoter (PDß1). Like PDß1, its activation is regulated by Eß in T cells and might facilitate the TCRB rearrangement process by contributing to the accessibility of the Dß1 locus.

Chromatin loop organization of the junb locus in mouse dendritic cells.

The junb gene behaves as an immediate early gene in bacterial lipopolysaccharide (LPS)-stimulated dendritic cells (DCs), where its transient transcriptional activation is necessary for the induction of inflammatory cytokines. junb is a short gene and its transcriptional activation by LPS depends on the binding of NF-κB to an enhancer located just downstream of its 3' UTR. Here, we have addressed the mechanisms underlying the transcriptional hyper-reactivity of junb. Using transfection and pharmacological assays to complement chromatin immunoprecipitation analyses addressing the localization of histones, polymerase II, negative elongation factor (NELF)-, DRB sensitivity-inducing factor (DSIF)- and Positive Transcription Factor b complexes, we demonstrate that junb is a RNA Pol II-paused gene where Pol II is loaded in the transcription start site domain but poorly active. Moreover, High salt-Recovered Sequence, chromosome conformation capture (3C)- and gene transfer experiments show that (i) junb is organized in a nuclear chromatin loop bringing into close spatial proximity the upstream promoter region and the downstream enhancer and (ii) this configuration permits immediate Pol II release on the junb body on binding of LPS-activated NF-κB to the enhancer. Thus, our work unveils a novel topological framework underlying fast junb transcriptional response in DCs. Moreover, it also points to a novel layer of complexity in the modes of action of NF-κB.

A crucial role for infected-cell/antibody immune complexes in the enhancement of endogenous antiviral immunity by short passive immunotherapy.

Antiviral monoclonal antibodies (mAbs) represent promising therapeutics. However, most mAbs-based immunotherapies conducted so far have only considered the blunting of viral propagation and not other possible therapeutic effects independent of virus neutralization, namely the modulation of the endogenous immune response. As induction of long-term antiviral immunity still remains a paramount challenge for treating chronic infections, we have asked here whether neutralizing mAbs can, in addition to blunting viral propagation, exert immunomodulatory effects with protective outcomes. Supporting this idea, we report here that mice infected with the FrCas(E) murine retrovirus on day 8 after birth die of leukemia within 4-5 months and mount a non-protective immune response, whereas those rapidly subjected to short immunotherapy with a neutralizing mAb survive healthy and mount a long-lasting protective antiviral immunity with strong humoral and cellular immune responses. Interestingly, the administered mAb mediates lysis of infected cells through an antibody-dependent cell cytotoxicity (ADCC) mechanism. In addition, it forms immune complexes (ICs) with infected cells that enhance antiviral CTL responses through Fc gammaR-mediated binding to dendritic cells (DCs). Importantly, the endogenous antiviral antibodies generated in mAb-treated mice also display the same properties, allowing containment of viral propagation and enhancement of memory cellular responses after disappearance of the administered mAb. Thus, our data demonstrate that neutralizing antiviral mAbs can act as immunomodulatory agents capable of stimulating a protective immunity lasting long after the end of the treatment. They also show an important role of infected-cells/antibody complexes in the induction and the maintenance of protective immunity through enhancement of both primary and memory antiviral T-cell responses. They also indicate that targeting infected cells, and not just viruses, by antibodies can be crucial for elicitation of efficient, long-lasting antiviral T-cell responses. This must be considered when designing antiviral mAb-based immunotherapies.

An NF-kappaB-dependent role for JunB in the induction of proinflammatory cytokines in LPS-activated bone marrow-derived dendritic cells.

BACKGROUND: Dendritic cells (DCs) play a key role in the induction of adaptive and memory immune responses. Upon encounter with pathogens, they undergo a complex maturation process and migrate toward lymphoid organs where they stimulate immune effector cells. This process is associated with dramatic transcriptome changes, pointing to a paramount role for transcription factors in DC activation and function. The regulation and the role of these transcription factors are however ill-defined and require characterization. Among those, AP-1 is a family of dimeric transcription complexes with an acknowledged role in the control of immunity. However, it has not been studied in detail in DCs yet. METHODOLOGY/PRINCIPAL FINDINGS: Here, we have investigated the regulation and function of one of its essential components, JunB, in primary bone marrow-derived DCs induced to maturate upon stimulation by Escherichia coli lipopolysaccharide (LPS). Our data show fast and transient NF-kappaB-dependent transcriptional induction of the junb gene correlating with the induction of the TNFalpha, IL-6, and IL-12 proinflammatory cytokines. Inhibition of JunB protein induction by RNA interference hampered the transcriptional activation of the TNF-alpha, IL-6, and IL-12p40 genes. Consistently, chromatin immunoprecipitation experiments showed LPS-inducible binding of JunB at AP-1-responsive sites found in promoter regions of these genes. Concomitant LPS-inducible NF-kappaB/p65 binding to these promoters was also observed. CONCLUSIONS/SIGNIFICANCE: We identified a novel role for JunB--that is, induction of proinflammatory cytokines in LPS-activated primary DCs with NF-kappaB acting not only as an inducer of JunB, but also as its transcriptional partner.

Fos family protein degradation by the proteasome.

c-Fos proto-oncoprotein defines a family of closely related transcription factors (Fos proteins) also comprising Fra-1, Fra-2, FosB and DeltaFosB, the latter two proteins being generated by alternative splicing. Through the regulation of many genes, most of them still unidentified, they regulate major functions from the cell level up to the whole organism. Thus they are involved in the control of proliferation, differentiation and apoptosis, as well as in the control of responses to stresses, and they play important roles in organogenesis, immune responses and control of cognitive functions, among others. Fos proteins are intrinsically unstable. We have studied how two of them, c-Fos and Fra-1, are degraded. Departing from the classical scenario where unstable key cell regulators are hydrolysed by the proteasome after polyubiquitination, we showed that the bulk of c-Fos and Fra-1 can be broken down independently of any prior ubiquitination. Certain conserved structural domains suggest that similar mechanisms may also apply to Fra-2 and FosB. Computer search indicates that certain motifs shared by the Fos proteins and putatively responsible for instability are found in no other protein, suggesting the existence of degradation mechanisms specific for this protein family. Under particular signalling conditions, others have shown that a part of cytoplasmic c-Fos requires ubiquitination for fast turnover. This poses the question of the multiplicity of degradation pathways that apply to proteins depending on their intracellular localization.

Ubiquitin-independent- versus ubiquitin-dependent proteasomal degradation of the c-Fos and Fra-1 transcription factors: is there a unique answer?

The Fos family of transcription factors comprises c-Fos, Fra-1, Fra-2 and FosB, which are all intrinsically unstable proteins. Fos proteins heterodimerize with a variety of other transcription factors to control genes encoding key cell regulators. Their best known partners are the Jun family proteins (c-Jun, JunB, and JunD). At the cellular level, Fos-involving dimers control proliferation, differentiation, apoptosis and responses to environmental cues. At the organism level, they play paramount parts in organogenesis, immune responses and cognitive functions, among others. fos family genes are subjected to exquisite, complex and intermingled transcriptional and post-transcriptional regulations, which are necessary to avoid pathological effects. In particular, the Fos proteins undergo to numerous post-translational modifications, such as phosphorylations and sumoylation, regulating their transcriptional activity, their subcellular localization and their turnover. The mechanisms whereby c-Fos and Fra-1 are degraded have been studied in detail. Contrasting with the classical scenario, according to which most unstable key cell regulators are hydrolyzed by the proteasome after conjugation of polyubiquitin chains, the bulk of c-Fos and Fra-1 can be hydrolyzed independently of any prior ubiquitylation in different situations. c-Fos and Fra-1 share a common destabilizing domain whose primary sequence is conserved in Fra-2 and FosB, suggesting that similar breakdown mechanisms might be at play in the latter two proteins. However, a database search indicates that this domain is not found in any other protein, suggesting that the mechanisms underlying Fos protein destruction may be specific to this family. Interestingly, under particular conditions, a fraction of cytoplasmic c-Fos is ubiquitylated, leading to faster turnover. This poses the question of the multiplicity of degradation pathways that can target the same substrate depending on its activation state, its protein partnership and/or its intracellular localization. This issue is discussed here together with the, thus far, overlooked roles of the various proteasomal complexes found in all cells.