Constitutive STAT5 activation specifically cooperates with the loss of p53 function in B-cell lymphomagenesis.

Signal transducers and activator of transcription 5 (STAT5) A and B are transcriptional regulators that play a central role in cytokine signaling in the hematopoietic lineage and which are frequently activated in a persistent manner in human leukemia/lymphoma, as assessed by their constitutive tyrosine phosphorylation and DNA-binding activity. To study the intrinsic oncogenic properties of persistent STAT5 activation, we generated transgenic mice in which a constitutively activated point mutant of STAT5A, STAT5A(S711F), was expressed at physiological level in their lymphoid compartment. In this model, persistent STAT5 activation is weakly oncogenic, leading to the late emergence of clonal B-cell lymphoma/leukemia at a low incidence. In contrast, STAT5(S711F) was found to cooperate with the loss of function of the p53 tumor suppressor gene to both accelerate disease onset and to skew the large tumor spectrum that normally characterize p53-deficient mice to strongly favor B-cell lymphoma/leukemia. The emergence of STAT5A(S711F)-induced B-cell tumors is associated with the activation of STAT5 tyrosine phosphorylation and DNA-binding activity, indicating that activation of STAT5 oncogenic properties in transgenic STAT5A (TgSTAT5A) (S711F) mice involves the deregulation of STAT5 phosphorylation dynamics.

Proviral rearrangements and overexpression of a new cellular gene (nov) in myeloblastosis-associated virus type 1-induced nephroblastomas.

Histological and anatomopathological studies performed on 152 independent myeloblastosis-associated virus type 1 (MAV1)-induced nephroblastomas allowed us to precisely define the chronology of tumor development in chickens. Three tumors representing increasing developmental stages were used to construct genomic libraries and to study both the state of proviral genomes and the sites of MAV1 integration in genomic DNA. We established that increasing levels of proviral rearrangement, eventually leading to the elimination of infectious MAV genomes, were associated with tumor progression and that 22 individual tumors, representative of different developmental stages, did not contain any common MAV1 integration site. Cloning of cellular fragments flanking the MAV1-related proviruses in tumor DNA showed that each one of eight nephroblastomas tested expressed a high level of an as yet unidentified cellular gene (nov) whose transcription is normally arrested in adult kidney cells. Cloning of the normal nov gene established that in one tumor, fused long terminal repeat-truncated nov mRNA species were expressed, indicating that at least in that case, the high level of nov expression was under the control of the MAV long terminal repeat promoter. The normal nov gene encodes a putative 32-kDa secreted polypeptide, which is a member of a new family of proteins likely to be involved in cell growth regulation. We also showed that the expression of an amino-terminal-truncated nov product in chicken embryo fibroblasts was sufficient to induce their transformation.

A human immunodeficiency virus Env inducible transcription system to examine consequences of gp120 expression.

According to several studies, the HIV-1 envelope gp120 protein and the co-receptor CXCR4 play an essential role in HIV-1 induced cell toxicity. Characterisation of the CD4-independent m7NDK isolate provided the opportunity of studying the effects of direct interactions between m7NDK gp120 and CXCR4. Therefore, an inducible expression system was designed enabling synthesis of HIV-1 Env proteins upon doxycycline induction. Analysis of the expression of the env gene of the m7NDK HIV-1 isolate revealed, unexpectedly, that even long-term expression of m7NDK gp120 did not result in cytotoxycity in CXCR4-positive or -negative cell lines. This is the first report of a CD4-independent HIV-1-protein inducible expression regulated through the Tet-On system and by an alternative splicing. Env inducible expression cell lines could constitute a useful cellular tool to undertake analysis of HIV Env protein expression.

Role of transcription factor TFIIF in serum response factor-activated transcription.

We have found that the general transcription factor TFIIF has an important role in serum response factor (SRF)-activated transcription in vitro. A low amount of TFIIF was sufficient for basal transcription, whereas higher amounts were required for SRF, but not Sp1, activation. High TFIIF levels also increased activation by GAL4-VP16, whereas none of the other general transcription factors had these properties. TFIIF could also relieve squelching by SRF in vitro, suggesting that SRF may directly bind TFIIF. We found more direct evidence for SRF-TFIIF interaction by DNA binding assays where the RAP74 subunit of TFIIF bound DNA in conjunction with SRF, but not alone. RAP74 also bound DNA with GAL4-VP16, but not with Sp1 or the DNA binding domain of GAL4. These results suggest that the mechanism of transcriptional activation by SRF, and perhaps some other activators, involves their interaction with TFIIF.

Interaction with RAP74 subunit of TFIIF is required for transcriptional activation by serum response factor.

A few general transcription factors, in particular TFIID and TFIIB, have been found to bind transcriptional activators. Here we show that the general transcription factor TFIIF is also a target for a transcriptional activator, namely serum response factor (SRF), which binds to the c-fos promoter. Using a yeast interaction assay, we find that SRF binds the RAP74 subunit of TFIIF and that SRF's transcriptional activation domain is the region involved in this binding. Further, RAP74's central charged cluster domain is required for binding to SRF's activation domain. Deletion of this domain impairs RAP74's ability to support SRF-activated transcription in vitro but has little effect on the protein's basal transcription activity or its ability to support SP1-activated transcription. The correlation of SRF-RAP74 binding with transcriptional activation suggests that RAP74 is a critical target for SRF-activated transcription.

The noncoding and surface envelope coding sequences of myeloblastosis-associated virus are respectively responsible for nephroblastoma development and renal hyperplasia.

The use of chimeric viruses allowed us to establish that myeloblastosis-associated virus long terminal repeat sequences are necessary and sufficient for induction of nephroblastoma in chickens and that the blastemal hyperplasia induced by env SU is not a prerequisite for tumor development but rather constitutes a predisposing stage.

Determination of essential amino acids involved in the CD4-independent tropism of the X4 human immunodeficiency virus type 1 m7NDK isolate: role of potential N glycosylations in the C2 and V3 regions of gp120.

Seven mutations in the C2, V3, and C3 regions of gp120 are implicated in the tropism of the first CD4-independent human immunodeficiency virus type 1 isolate, m7NDK. Site-directed mutagenesis revealed that three amino acids are essential to maintain this tropism, one in the C2 region and two in the V3 loop. Two mutations implied N glycosylation modifications.

Pathogenic potential of myeloblastosis-associated virus: implication of env proteins for osteopetrosis induction.

To identify the nucleotide sequences responsible for the tumorigenic specificity of myeloblastosis-associated virus (MAV) we have established the complete nucleotide sequences of three infectious clones inducing either both osteopetrosis and nephroblastoma [MAV2(O)/2 and MAV2(O)p9] or only nephroblastoma [MAV1(N)], and compared their biological properties in the same chicken host strain. The MAV2(O)p9 originally described as a type 2 strain was found to carry a hybrid env gene containing sequences of both the types 1 and 2, and it induced milder and less rapid osteopetrosis than the original MAV2(O) clone when injected into Brown Leghorn chickens. These results, together with sequence comparisons between the MAV strains examined, suggest that subtle changes in the primary structure of the TM env protein's extracellular domain are likely to affect the tumorigenic potential of MAV.