DNA replication progresses on the periphery of nuclear aggregates formed by the BCL6 transcription factor.

The BCL6 proto-oncogene, frequently alterated in non-Hodgkin lymphoma, encodes a POZ/zinc finger protein that localizes into discrete nuclear subdomains. Upon prolonged BCL6 overexpression in cells bearing an inducible BCL6 allele (UTA-L cells), these subdomains apparently coincide with sites of DNA synthesis. Here, we explore the relationship between BCL6 and replication by both electron and confocal laser scanning microscopy. First, by electron microscope analyses, we found that endogenous BCL6 is associated with replication foci. Moreover, we show that a relatively low expression level of BCL6 reached after a brief induction in UTA-L cells is sufficient to observe its targeting to mid, late, and at least certain early replication foci visualized by a pulse-labeling with bromodeoxyuridine (BrdU). In addition, when UTA-L cells are simultaneously induced for BCL6 expression and exposed to BrdU for a few hours just after the release from a block in mitosis, a nuclear diffuse BCL6 staining indicates cells in G(1), while cells in S show a more punctate nuclear BCL6 distribution associated with replication foci. Finally, ultrastructural analyses in UTA-L cells exposed to BrdU for various times reveal that replication progresses just around, but not within, BCL6 subdomains. Thus, nascent DNA is localized near, but not colocalized with, BCL6 subdomains, suggesting that they play an architectural role influencing positioning and/or assembly of replication foci. Together with its previously function as transcription repressor recruiting a histone deacetylase complex, BCL6 may therefore contribute to link nuclear organization, replication, and chromatin-mediated regulation.

Nonrandom 4p13 rearrangements of the RhoH/TTF gene, encoding a GTP-binding protein, in non-Hodgkin's lymphoma and multiple myeloma.

We recently isolated the RhoH/TTF gene by its fusion to the LAZ3/BCL6 gene, in a non-Hodgkin's lymphoma (NHL) cell line, which bore a t(3;4)(q27;p11-13) translocation. This gene encodes a novel Rho GTP-binding protein and is specifically expressed in hematopoietic tissues. We made its precise mapping at band 4p13, and described its partial genomic structure. Using fluorescence in situ hybridization and molecular analyses, we report here on the rearrangement of the RhoH/TTF gene, at band 4p13, in four cases of NHL with t(3;4)(q27;p13) translocation and its fusion to the LAZ3/BCL6 gene at band 3q27, in three of these cases. RT-PCR analysis of two cases allowed the detection of variable fusion transcripts emerging from the rearranged alleles, and in one case, a deregulated expression of both RhoH/TTF and LAZ3/BCL6 genes, by promoter substitution, was observed. We also show here another rearrangement of the RhoH/TTF gene in a patient with multiple myeloma and t(4;14)(p13;q32) translocation, with breakage within the IGH gene. It is the first report which describes the recurrent chromosomal alteration of a GTP-binding protein encoding gene, in patients with hematopoietic malignancies.

Colocalization and heteromerization between the two human oncogene POZ/zinc finger proteins, LAZ3 (BCL6) and PLZF.

Most acute promyelocytic leukemia (APL) cases are associated with recurrent translocations between the gene of retinoic receptor alpha and that of PML (t(15;17)) or PLZF (t(11;17)). PML localizes onto discrete intranuclear domains, the PML-nuclear bodies, and displays anti-oncogenic and pro-apoptotic properties. PLZF encodes a transcription factor belonging to the POZ/domain and Krüppel zinc finger (POK) family which interacts directly with PML. PLZF is related to another POK protein, LAZ3(BCL6), which is structurally altered, and presumably misexpressed, in many non-Hodgkin lymphoma (NHL) cases. PLZF and LAZ3 share many functional properties: both inhibit cell growth, concentrate into punctated nuclear subdomains and are sequence-specific transcriptional repressors recruiting a histone deacetylase-repressing complex. Given these similarities, we tested whether both proteins could be targeted by each other. Here, LAZ3 and PLZF are shown to colocalize onto nuclear dots. Moreover, truncated derivatives of one protein, which display a diffuse nuclear localization, are recruited onto nuclear dots by the full-length other. The colocalization and the reciprocal 'rescue' is the result of a direct interaction between LAZ3 and PLZF, as indicated by yeast two hybrid assays, in vitro immunoprecipitations, and GST pull down experiments. In contrast to LAZ3 homomerization, LAZ3/PLZF heteromerization in yeast does not solely depend on POZ/POZ contacts but rather also relies on interactions between the two zinc finger regions and 'cross' contacts between the zinc finger region and the POZ domain of each partner. Likewise, LAZ3 shows some colocalization with the PLZF partner PML upon stable overexpression of both proteins in CHO cells and interacts with PML in yeast. Finally, endogenous LAZ3 and PLZF are co-induced and partially colocalized in myeloid MDS cells. These data indicate that a physical interaction between LAZ3 and PLZF underlies their simultaneous recruitment onto multiproteic nuclear complexes, presumably involved in transcriptional silencing and whose integrity (for APL) and/or function (for APL and NHL) may be altered in oncogenesis.

Overexpressed BCL6 (LAZ3) oncoprotein triggers apoptosis, delays S phase progression and associates with replication foci.

One of the most frequent genetic abnormalities associated with non Hodgkin lymphoma is the structural alteration of the 5' non coding/regulatory region of the BCL6 (LAZ3) protooncogene. BCL6 encodes a POZ/Zn finger protein, a structure similar to that of many Drosophila developmental regulators and to another protein involved in a human hematopoietic malignancy, PLZF. BCL6 is a sequence specific transcriptional repressor controlling germinal center formation and T cell dependent immune response. Although the expression of BCL6 negatively correlates with cellular proliferation in different cell types, the influence of BCL6 on cell growth and survival is currently unknown so that the way its deregulation may contribute to cancer remains elusive. To directly address this issue, we used a tetracycline-regulated system in human U2OS osteosarcoma cells and thus found that BCL6 mediates growth suppression associated with impaired S phase progression and apoptosis. Interestingly, overexpressed BCL6 can colocalize with sites of ongoing DNA synthesis, suggesting that it may directly interfere with S phase initiation and/or progression. In contrast, the isolated Zn finger region of BCL6, which binds BCL6 target sequence but lacks transcriptional repression activity, slows, but does not suppress, U2OS cell growth, is less efficient at delaying S phase progression, and does not trigger apoptosis. Thus, for a large part, the effects of BCL6 overexpression on cell growth and survival depend on its ability to engage protein/protein interactions with itself and/or its transcriptional corepressors. That BCL6 restricts cell growth suggests that its deregulation upon structural alterations may alleviate negative controls on the cell cycle and cell survival.

The LAZ3(BCL-6) oncoprotein recruits a SMRT/mSIN3A/histone deacetylase containing complex to mediate transcriptional repression.

Recent works demonstrated that some transcriptional repressors recruit histone deacetylases (HDACs) either through direct interaction, or as a member of a multisubunit repressing complex containing other components referred to as corepressors. For instance, the bHLH-Zip transcriptional repressors MAD/MXI recruit HDACs together with the mSIN3 corepressors, whereas unliganded nuclear receptors contact another corepressor, SMRT (or its relative N-CoR), which, in turn, associates with both mSIN3 and HDACs to form the repressor complex. Recently, we reported that SMRT also directly associates with LAZ3(BCL-6), a POZ/Zn finger transcriptional repressor involvedin the pathogenesis of non-Hodgkin lymphomas. However, whether LAZ3 recruits the HDACs-containing repression complex is currently unknown. We report here that LAZ3 associates with corepressor mSIN3A both in vivo and in vitro , and found that a central region, which harbours autonomous repression activity, is mainly responsible for this interaction. Conversely, the N-terminal half of mSIN3A is both necessary and sufficient to bind LAZ3. Moreover, we show that LAZ3 also interacts with an HDAC (HDAC-1) through its POZ domain in vitro while the immunoprecipitation of LAZ3 results in the coretention of an endogenous HDAC activity in vivo . Finally, inhibitors of HDACs significantly reduce the LAZ3-mediated repression. Taken together, we conclude that LAZ3 recruits a repressing complex containing SMRT, mSIN3A and a HDAC, and that its full repressing potential on transcription requires HDACs activity. Our results identify HDACs as molecular targets of LAZ3 oncogene and further strengthen the connection between aberrant chromatin acetylation and human cancers.

Increased expression of the LAZ3 (BCL6) proto-oncogene accompanies murine skeletal myogenesis.

The structural alterations of the LAZ3 (BCL6) gene are one of the most frequent events found in non-Hodgkin lymphoma. LAZ3 encodes a transcriptional repressor with a POZ/zinc finger structure similar to several Drosophila development regulators and to the human promyelocytic leukemia-associated PLZF gene. Consistent with the origin of LAZ3-associated malignancies, LAZ3 is expressed in mature B-cells and required for germinal center formation. However, its ubiquitous expression, with predominant levels in skeletal muscle, suggests that it may act outside the lymphoid system. To study how LAZ3 could be involved in skeletal muscle differentiation, we examined its expression in the C2 muscle cells. We report here that LAZ3 is upregulated at both mRNA and protein levels during the differentiation of proliferating C2 myoblasts into post-mitotic myotubes. This rise in LAZ3 expression is both precocious and sustained, and is not reversed when myotubes are re-exposed to mitogen-rich medium, suggesting that irreversible evens occurring upon myogenic terminal differentiation contribute to lock LAZ3 upregulation. In addition, using two different models, we found that a "simple" growth-arrest upon serum starvation is not sufficient to induce LAZ3 upregulation which rather appears as a feature of myogenic commitment and/or differentiation. Finally, BrdU incorporation assays in C2 cells entering the differentiation pathway indicate that "high" LAZ3 expression strongly correlates with their exit from the cell cycle. Taken as a whole, these findings suggest that LAZ3 could play a role in muscle differentiation. Together with some results reported in other cell types, we propose that LAZ3 may contribute to events common to various differentiation processes, possibly the induction and stabilization of the withdrawal from the cell cycle.

The LAZ3/BCL6 oncogene encodes a sequence-specific transcriptional inhibitor: a novel function for the BTB/POZ domain as an autonomous repressing domain.

Rearrangements and mutations of the LAZ3/BCL6 gene are the most frequent events associated with diffuse large-cell lymphoma, a particular class of non-Hodgkin's lymphomas. This gene encodes a putative regulatory protein with six COOH-terminal Krüppel-like zinc fingers and a NH2-terminal hydrophobic region, the so-called BTB/POZ domain, which mediates homo- as well as heterotypic interactions in other related proteins. Recently, a consensus binding sequence has been defined using the isolated LAZ3/BCL6 zinc finger region produced in bacteria. To understand the normal and oncogenic functions of LAZ3/BCL6, we examined its properties as a transcription factor. We thus demonstrated that its full-length product binds to the same consensus sequence, although the BTB/POZ domain decreases this activity, at least in vitro. In transient transfection experiments, the LAZ3/BCL6 protein exerts a repressive effect, both as a wild-type protein on its own target sequence and as a GAL-4 fusion protein. Furthermore, our results indicate that the BTB/POZ domain plays a prominent role in the mediation of this activity. Indeed, on the LAZ3/BCL6 cognate sequence, deletion of the BTB/POZ domain diminishes the repressive function. Conversely, as a GAL-4 chimera, the isolated LAZ3/BCL6 BTB/POZ domain appears nearly as efficient as the entire protein at inducing transcriptional repression. Taken together, these findings demonstrate that the LAZ3/BCL6 is a sequence-specific transcriptional repressor and point to a novel function for the BTB/POZ region, at least in LAZ3/BCL6, as an autonomous transcriptional inhibitory domain.

The BTB/POZ domain targets the LAZ3/BCL6 oncoprotein to nuclear dots and mediates homomerisation in vivo.

The LAZ3/BCL6 gene was identified by its disruption in 3q27 translocations associated with diffuse large cell lymphomas. It is predicted to be a transcription factor as it contains six Krüppel-like Zinc finger motifs and a N-terminal BTB/POZ domain, a protein/protein interaction interface that is widely conserved in Metazoans. Using two antisera raised against non overlapping regions of the predicted ORF, we demonstrate that the LAZ3/BCL6 protein appears as a close ca. 79 kDa doublet in B lymphoid cell lines with either a rearranged or a non rearranged LAZ3/BCL6 locus. By immunofluorescence experiments on transiently transfected COS-1 or NIH3T3 cells, we show that the LAZ3/BCL6 protein displays a punctuated nuclear localisation. This appears to rely on LAZ3/BCL6 proper folding and/or activities as it is impaired in a hormone reversible-fashion through fusion of LAZ3/BCL6 to the ligand-binding domain of the oestrogen receptor. Moreover, deletion of its BTB/POZ domain leads to the disappearance of the nuclear dots although the protein remains nuclear. In addition, by using the yeast two-hybrid system, we show that the LAZ3/BCL6 BTB/POZ domain homomerises in vivo. Thus, the LAZ3/BCL6 BTB/POZ domain has the capability to self-interact and target the protein to discrete nuclear substructures.

TTF, a gene encoding a novel small G protein, fuses to the lymphoma-associated LAZ3 gene by t(3;4) chromosomal translocation.

We have previously shown that the LAZ3/BCL6 gene encoding a potential transcription factor, is disrupted in B-diffuse large cell non-Hodgkin's lymphomas (NHL) with 3q27 chromosomal abnormalities involving the immunoglobulin (IG) genes. However, LAZ3 rearrangement also occurs in NHL bearing 3q27 translocations without involvement of the IG genes: for example the VAl cell line exhibits t(3;4)(q27;p11). In the present work we have used a RT-PCR method to detect and to sequence the LAZ3 mRNA products from the VAL cell line. We report that the consequence of the t(3;4) is the expression of a chimeric transcript of LAZ3 with a new gene encoding a small G-like protein, termed TTF (Translocation Three Four). Nucleotide sequence analysis of a 1.4 kb cDNA predicts that the TTF gene encodes a protein of 191 amino-acids similar to members of the RAS superfamily including HRAS (27% identical), RAB1A (30% identical) and RHO proteins: the human RAC1, RHOB and CDC42Hs proteins (respectively 43, 44 and 45% identical) and the yeast RHO2 protein (44% identical). Unlike most other small G proteins which are expressed ubiquitously, TTF was transcribed only in hemopoietic cells as a 2.2 kb transcript. TTF may define a new subgroup of RHO-like proteins.

Expression of a tumor-suppressor gene and of various protooncogenes in human and murine adriamycin-resistant and sensitive cell-lines.

Besides established mechanisms involved in cellular drug resistance including P-glycoprotein overexpression, topoisomerase alterations and xenobiotic detoxification, the hypothesis that proto-oncogene activation might also play a role in cell resistance has been postulated. This hypothesis has been tested by comparing the expression of various proto-oncogenes involved in signal transduction pathways (c-H-ras, c-g-ras, c-mil, c-myc, c-myb, c-fos), as well as the mdr gene and a tumor suppressor gene (p53) in different adriamycin-resistant (acquired or de novo) or sensitive cell lines, The implication of these variations in the process of chemoresistance is discussed.

Quantitative and qualitative variation of ETS-1 transcripts in hematologic malignancies.

The ETS family proteins have a conserved DNA-binding domain and act as transcription factors. Three domains have been recently defined in human ETS-1 proteins and their role could depend upon the nature of alternative transcripts according to whether they possess or lack DNA binding and/or transcriptional activation domain and also point mutation that could affect these important domains. Expression of ETS-1 gene is very complex and is controlled at several levels: the initiation of transcription, alternative splicing, post-translational modification, and protein stability. As a selection apparently exists for ETS-1 gene activation in hematopoietic cells, we investigated a relation between quantitative and qualitative ETS-1 expression and leukemogenesis. Using Northern blot, polymerase chain reaction (PCR), and single strand conformation polymorphism (SSCP) methods, we analyzed quantitative and qualitative ETS-1 expression in a variety of hematological pathologies and cell lines of different origin. Two ETS-1 transcripts of 6.8 and 2.7 kb, resulting from differential polyadenylation site utilization and exhibiting different stability, were observed. We identified, in a great number of patients, the four alternative ETS-1 products, but the relative extent significance of the four transcripts was very different from one patient to another. A non-conservative mutation observed in one case of T-cell acute lymphoblastic leukemia (T-ALL) and in the ETS-1 transactivation domain raised the question of suppressor activity for some ETS-1 products, as it is now known that activators and repressors can be encoded by the same gene and consistently co-expressed in vivo.

Biological activity and molecular interaction of a netropsin-acridine hybrid ligand with chromatin and topoisomerase II.

A hybrid molecule, which combines an anilinoacridine chromophore related to the antitumour drug amsacrine (m-AMSA) and a bispyrrole moiety analogous to the antiviral agent netropsin, has been examined for its ability to bind chromatin and to modulate the activity of topoisomerase II. The results show that the presence of histones does not alter the bimodal DNA binding process. Intercalation of the acridine and groove binding of the netropsin part of the drug are both observed with chromatin preparations. Moreover, the hybrid has a clear topoisomerase II-DNA cleavable complex-inducing activity close to that of m-AMSA. The role of the two parts of the hybrid ligand is discussed in relation to ternary complex formation. Two cell lines (L1210 leukemia and MCF7 mammary carcinoma) were compared in their sensitivity to the tested ligand. The drug, which appears to be an efficient growth inhibitor of leukemic cells in vitro, reveals moderate activity against P388 leukemia in vivo. The biological activity of the hybrid may derive from a mechanism that involves DNA binding and topoisomerase II inhibition. This study demonstrates that agents which intercalate and bind to the minor groove of DNA simultaneously represent a new class of drugs interfering with topoisomerase II and provide opportunities for the development of new antitumour agents.

C-myc overexpression, c-mil, c-myb expression in a breast tumor cell line. Effects of estrogen and antiestrogen.

In breast tumor cell lines, c-myc amplification is frequently associated with estrogen unresponsiveness. We, however, succeeded in characterizing an estrogen-responsive cell line VHB1 derived from a duct cell carcinoma, which exhibits c-myc amplification and overexpression. We therefore studied the effects of estrogen and antiestrogen on c-myc expression in this particular cell line. We also investigated these effects on the expression of c-mil and c-myb oncogenes, also expressed but not amplified in VHB1 cells. Short-(1 h) and long-(72 h) term stimulations were performed. Our experiments showed that estradiol (E2 10(-8) M) was still able to stimulate c-myc expression equally either after short or long-term treatment. In the same way, the antiestrogen 4-hydroxytamoxifen equally decreased c-myc expression but the reversal effect of E2 after long-term antiestrogen treatment was more pronounced than after short-term treatment. The effects of E2 and 4-OH Tam on the expression of the not-amplified c-mil and c-myb oncogenes were stronger than those observed on c-myc expression; however, the E2 reversal effect was identical either after short or long-term antiestrogen treatment. Our results may enlighten some aspects of the complex action of some of the early- and late-growth regulated genes in breast cancer.

Expression of the interleukin 6 gene in acute myeloid leukemia and myelodysplastic syndromes: a report on 49 cases.

We studied the expression of IL 6 gene in 49 patients, including 21 chronic myelomonocytic leukemias (CML), 9 other myelodysplastic syndromes (MDS), 18 acute myeloid leukemias (11 M2 or M3 and 7 M4 or M5) and 1 case of acute biphenotypic lymphoid monocytic leukemia. IL 6 was found expressed only in the latter patient and in one patient with M5 acute myeloid leukemia. DNA analysis by Southern blot revealed no rearrangement in these 2 patients and in 10 of the other patients who showed no IL 6 expression. These results do not support an autocrine role for IL 6 in CMML or in other MDS. In acute myeloid leukemias, if expressed by leukemic cells, IL 6 seems to be restricted to cases with a monocytic component, although the number of patients was too small to draw any definite conclusion.