Alternative origin of p13MTCP1-encoding transcripts in mature T-cell proliferations with t(X;14) translocations.

The MTCP1 gene is involved in the t(X;14)(q28;q11) translocation associated with T-cell prolymphocytic leukemia and related conditions. This gene is unusual in that it codes for two distinct proteins: a small mitochondrial protein, p8MTCP1, and a putative oncogenic protein, p13MTCP1. Scarcity of material from t(X;14)-associated proliferations and very low levels of mRNA expression have so far prevented a thorough description of p13MTCP1-encoding transcripts. Here, we characterize two additional t(X;14) bearing leukemias allowing this analysis. In one case, with a breakpoint located 5' to the MTCP1 gene, the level of transcription of previously described p13MTCP1-encoding transcripts is enhanced. In the second case, with a breakpoint within the MTCP1 intron I, an alternative transcription initiation site is demonstrated in the tumor cells at 229 bp upstream to exon II. The identification of this internal promoter, together with the similarity between TCL1 and MTCP1 genomic structures, allow us to propose a model in which the duplication of an ancestral gene was followed by the insertion of one copy within the intron of a p8-encoding gene, accounting for the unusual feature of the MTCP1 gene.

Expression of p13MTCP1 is restricted to mature T-cell proliferations with t(X;14) translocations.

T-cell prolymphocytic leukemia (T-PLL), a rare form of mature T-cell leukemias, and ataxia telangiectasia clonal proliferation, a related condition occurring in patients suffering from ataxia telangiectasia, have been associated to translocations involving the 14q32.1 or Xq28 regions, where are located the TCL1 and MTCP1 putative oncogenes, respectively. The MTCP1 gene is involved in the t(X;14)(q28;q11) translocation associated with these T-cell proliferations. Alternative splicing generates type A and B transcripts that potentially encode two entirely distinct proteins; type A transcripts code for a small mitochondrial protein, p8MTCP1, and type B transcripts, containing an additional open reading frame, may code for 107 amino-acid protein, p13MTCP1. The recently cloned TCL1 gene, also involved in translocations and inversions associated with T-cell proliferations, codes for a 14-kD protein that displays significant homology with p13MTCP1. We have generated rabbit antisera against this putative p13MTCP1 protein and screened for expression of p13MTCP1 normal lymphoid tissues and 33 cases of immature and mature lymphoid T-cell proliferations using a sensitive Western blot assay. We also investigated the MTCP1 locus configuration by Southern blot analysis. The p13MTCP1 protein was detected in the three T-cell proliferations with MTCP1 rearrangements because of t(X;14) translocations, but neither in normal resting and activated lymphocytes nor in the other T-cell leukemias. Our data support the hypothesis that p13MTCP1 and p14TCL1 form a new protein family that plays a key role in the pathogenesis of T-PLL and related conditions.

Significance of highly positive c22-3 "indeterminate" second-generation hepatitis C virus (HCV) recombinant immunoblot assay (RIBA) and resolution by third-generation HCV RIBA.

Second-generation recombinant immunoblot assay (RIBA) is widely used for the validation of anti-hepatitis C virus (HCV) antibody detection. The aims of this work were (i) to determine, in terms of liver disease and HCV replication, the significance of a peculiar "indeterminate" second-generation RIBA pattern characterized by the presence of high titers of antibodies directed to c22-3, a protein bearing core epitopes and (ii) to determine whether a more advanced version of the same strip assay, namely a third-generation RIBA, may solve the problem of such indeterminate patterns. Sixty patients for which c22-3 indeterminate second-generation RIBAs were highly positive were studied. Forty-two of them (70%) were immunocompromised. Serum transaminases were increased in 46 cases (77%), and HCV RNA was detected by PCR in 50 cases (83%). Third-generation RIBA remained highly positive c22 indeterminate for 9 patients (15%) but was positive for 51 (85%), mostly because of increased sensitivity for the detection of both anti-c100 and anti-c33c antibodies. These results suggest that third-generation RIBA may achieve resolution of most of these cases but that highly positive c22 indeterminate third-generation RIBA may persist when used with some patients with very low titers of anti-HCV nonstructural protein antibodies.

Two distinct regions of the mouse beta Fc gamma R gene control its transcription.

The low-affinity receptors for the Fc portion of IgG (Fc gamma RII and Fc gamma RIII) are born by most of the immunocompetent cells and mediate a wide spectrum of biological activities. Macrophages, mast cells and lymphocytes express the type II Fc gamma R whereas the type III Fc gamma R is expressed on macrophages, mast cells and NK cells. In mice, the beta Fc gamma R gene codes for Fc gamma RII and the alpha Fc gamma R gene codes for the ligand-binding Fc gamma RIII alpha-chain. We have previously demonstrated that the methylation of the 5' region of these genes control their expression. In the present paper, we investigate the role of two unmethylated regions of the beta gene, the promoter and the third intron, in the control of its transcription. We show, by using two cell lines representative of B and mast cells, that different promoter fragments determine, in these two cell types, the transcription of the beta Fc gamma R gene. The third intron of the beta Fc gamma R gene contains sequences, which, introduced upstream to homologous or heterologous promoter, inhibit the transcriptional activity of these promoter. Thus, in B cells and in mast cells, the transcription of the beta Fc gamma R gene is controlled by two distinct regions of the gene.

Role of associated gamma-chain in tyrosine kinase activation via murine Fc gamma RIII.

Type III receptors for the Fc portion of IgG (Fc gamma RIII), initially characterized on macrophages and NK cells, are also expressed on several pre-B cell lines. Surface expression of Fc gamma RIII requires the association of the ligand binding alpha-chain with homodimeric gamma-chains. Type II Fc gamma R is homologous to Fc gamma RIII alpha-chain in the extracellular portion and differs in the transmembrane and cytoplasmic domains. The role of Fc gamma R in cell activation was investigated by expressing Fc gamma RIII and the lymphocyte-specific b1 isoform of Fc gamma RII (Fc gamma RIIb1) in an Fc gamma R-negative, sIgG-positive B-cell line. We found that, in contrast to Fc gamma RIIb1, Fc gamma RIII triggers the same events of cell activation as sIG i.e. Ca2+ mobilization, tyrosine phosphorylation and IL-2 secretion. By expressing cytoplasmic domain-lacking Fc gamma RIII alpha-chain in the absence or in the presence of gamma-chains, we demonstrated that cell activation via Fc gamma RIII requires the co-expression of gamma-chains, and is independent of the cytoplasmic portion of the alpha-chain. Furthermore, the cytoplasmic portion of the gamma-chain, fused to the extracellular and transmembrane domains of Fc gamma RII confers on the chimeric receptor the ability to trigger cell activation. Mutation of one tyrosine residue in the cytoplasmic domain of the gamma-chain prevented triggering of cytoplasmic signals. We therefore demonstrate that a tyrosine-containing motif, present in the cytoplasmic domain of the associated gamma-chain, is necessary and sufficient to trigger cell activation via Fc gamma RIII.