[When chromosomal dynamics control cell division]. / Quand la dynamique chromosomique contrôle la division cellulaire.

In most tumor cells a chromosomal instability leads to an abnormal chromosome number (aneuploidy). The mitotic checkpoint is essential for ensuring accurate chromosome segregation by allowing mitotic delay in response to a spindle defect. This checkpoint delays the onset of anaphase until all the chromosomes are correctly aligned on the mitotic spindle. When unattached kinetochores are present, the metaphase/anaphase transition is not allowed and the time available for chromosome-microtubule capture increases. Genes required for this delay were first identified in Saccharomyces cerevisiae (the MAD, BUB and MPS1 genes) and subsequently, homologs have been identified in higher eucaryotes showing that the spindle checkpoint pathway is highly conserved. The checkpoint functions by preventing an ubiquitin ligase called the anaphase-promoting complex/cyclosome (APC) from ubiquitinylating proteins whose destruction is required for anaphase onset.

Cyclin B/cdc2 induces c-Mos stability by direct phosphorylation in Xenopus oocytes.

The c-Mos proto-oncogene product plays an essential role during meiotic divisions in vertebrate eggs. In Xenopus, it is required for progression of oocyte maturation and meiotic arrest of unfertilized eggs. Its degradation after fertilization is essential to early embryogenesis. In this study we investigated the mechanisms involved in c-Mos degradation. We present in vivo evidence for ubiquitin-dependent degradation of c-Mos in activated eggs. We found that c-Mos degradation is not directly dependent on the anaphase-promoting factor activator Fizzy/cdc20 but requires cyclin degradation. We demonstrate that cyclin B/cdc2 controls in vivo c-Mos phosphorylation and stabilization. Moreover, we show that cyclin B/cdc2 is capable of directly phosphorylating c-Mos in vitro, inducing a similar mobility shift to the one observed in vivo. Tryptic phosphopeptide analysis revealed a practically identical in vivo and in vitro phosphopeptide map and allowed identification of serine-3 as the largely preferential phosphorylation site as previously described (Freeman et al., 1992). Altogether, these results demonstrate that, in vivo, stability of c-Mos is directly regulated by cyclin B/cdc2 kinase activity.

Mps1 is a kinetochore-associated kinase essential for the vertebrate mitotic checkpoint.

The mitotic checkpoint acts to inhibit entry into anaphase until all chromosomes have successfully attached to spindle microtubules. Unattached kinetochores are believed to release an activated form of Mad2 that inhibits APC/C-dependent ubiquitination and subsequent proteolysis of components needed for anaphase onset. Using Xenopus egg extracts, a vertebrate homolog of yeast Mps1p is shown here to be a kinetochore-associated kinase, whose activity is necessary to establish and maintain the checkpoint. Since high levels of Mad2 overcome checkpoint loss in Mps1-depleted extracts, Mps1 acts upstream of Mad2-mediated inhibition of APC/C. Mps1 is essential for the checkpoint because it is required for recruitment and retention of active CENP-E at kinetochores, which in turn is necessary for kinetochore association of Mad1 and Mad2.

The APC is dispensable for first meiotic anaphase in Xenopus oocytes.

Here we show that segregation of homologous chromosomes and that of sister chromatids are differentially regulated in Xenopus and possibly in other higher eukaryotes. Upon hormonal stimulation, Xenopus oocytes microinjected with antibodies against the anaphase-promoting complex (APC) activator Fizzy or the APC core subunit Cdc27, or with the checkpoint protein Mad2, a destruction-box peptide or methylated ubiquitin, readily progress through the first meiotic cell cycle and arrest at second meiotic metaphase. However, they fail to segregate sister chromatids and remain arrested at second meiotic metaphase when electrically stimulated or when treated with ionophore A34187, two treatments that mimic fertilization and readily induce chromatid segregation in control oocytes. Thus, APC is required for second meiotic anaphase but not for first meiotic anaphase.

Part of Xenopus translin is localized in the centrosomes during mitosis.

During oogenesis, maternal mRNAs are synthesised and stored in a translationally dormant form due to the presence of regulatory elements at the 3' untranslated regions (3'UTR). In Xenopus oocytes, several studies have described the presence of RNA-binding proteins capable to repress maternal-mRNA translation. The testis-brain RNA-binding protein (TB-RBP/Translin) is a single-stranded DNA- and RNA-binding protein which can bind the 3' UTR regions (Y and H elements) of stored mRNAs and can suppress in vitro translation of the mRNAs that contain these sequences. Here we report the cloning of the Xenopus homologue of the TB-RBP/Translin protein (X-translin) as well as its expression, its localisation, and its biochemical association with the protein named Translin associated factor X (Trax) in Xenopus oocytes. The fact that this protein is highly present in the cytoplasm from stage VI oocytes until 48 h embryos and that it has been described as capable to inhibit paternal mRNA translation, indicates that it could play an important role in maternal mRNA translation control during Xenopus oogenesis and embryogenesis. Moreover, we investigated X-translin localisation during cell cycle in XTC cells. In interphase, although a weak and diffuse nuclear staining was observed, X-translin was mostly present in the cytoplasm where it exhibited a prominent granular staining. Interestingly, part of X-translin underwent a remarkable redistribution throughout mitosis and associated with centrosomes, which may suggest a new unknown role for this protein in cell cycle.

RbAp48 belongs to the histone deacetylase complex that associates with the retinoblastoma protein.

The retinoblastoma susceptibility gene product, the Rb protein, is a key regulator of mammalian cell proliferation. One of the major targets of Rb is the S phase inducing E2F transcription factor. Once bound to E2F, Rb represses the expression of E2F-regulated genes. Transcriptional repression by Rb is believed to be crucial for the proper control of cell growth. Recently, we and others showed that Rb represses transcription through the recruitment of a histone deacetylase. Interestingly, we show here that the Rb-associated histone deacetylase complex could deacetylate polynucleosomal substrates, indicating that other proteins could be present within this complex. The Rb-associated protein RbAp48 belongs to many histone deacetylase complexes. We show here that the histone deacetylase HDAC1 is able to mediate the formation of a ternary complex containing Rb and RbAp48. Moreover, less deacetylase activity was found associated with Rb in cell extracts depleted for RbAp48 containing complexes, demonstrating that Rb, histone deacetylase, and RbAp48 are physically associated in live cells. Taken together, these data indicate that RbAp48 is a component of the histone deacetylase complex recruited by Rb. Finally, we found that E2F1 and RbAp48 are physically associated in the presence of Rb and HDAC1, suggesting that RbAp48 could be involved in transcriptional repression of E2F-responsive genes.

Histone acetylation and the control of the cell cycle.

The critical steps of the cell cycle are generally controlled through the transcriptional regulation of specific subsets of genes. Transcriptional regulation has been recently linked to acetylation or deacetylation of core histone tails: acetylated histone tails are generally associated with active chromatin, whereas deacetylated histone tails are associated with silent parts of the genome. A number of transcriptional co-regulators are histone acetyl-transferases or histone deacetylases. Here, we discuss some of the critical cell cycle steps in which these enzymes are involved.

Autonomously binding protein detected on ets box of c-fos serum response element in proliferating cells.

The serum response element (SRE) in the c-fos promoter contains an ets box whose integrity is required for full activation of this proto-oncogene by nerve growth factor (NGF) in PC12 rat pheochromocytoma cells. Electrophoretic mobility shift assays (EMSA) detect a protein in nuclear extracts that binds to the wild-type SRE, but not to an SRE containing a mutated ets box. Competition studies using unlabeled probes, and supershift experiments using antibodies and in vitro translated core serum response factor (SRF) indicate that the protein in question is not YY1, SAP-1, nor Elk-1 and that it does not exhibit ternary complex factor (TCF) activity, so that it may correspond to an autonomously binding Ets family protein. The complete disappearance of this "Ets-like autonomous binding factor" upon terminal differentiation of both L6alpha2 myoblastic and PC12 pheochromocytoma cells points to a possible role in the proliferation/differentiation process.

Histone acetylation in signal transduction by growth regulatory signals.

Cell fate is determined by extracellular signals which are transmitted to the nucleus and result in the transcriptional regulation of specific subsets of genes. Transcriptional regulation has been recently linked to enzymatic activities which are able to acetylate or deacetylate core histone tails. A number of transcriptional co-regulators are histone acetyl-transferases or histone deacetylases. Here, we discuss the involvement of these enzymes in critical steps of cell proliferation or cell differentiation control

Histone acetyltransferase activity of CBP is controlled by cycle-dependent kinases and oncoprotein E1A.

Transforming viral proteins such as E1A force cells through the restriction point of the cell cycle into S phase by forming complexes with two cellular proteins: the retinoblastoma protein (Rb), a transcriptional co-repressor, and CBP/p300, a transcriptional co-activator. These two proteins locally influence chromatin structure: Rb recruits a histone deacetylase, whereas CBP is a histone acetyltransferase. Progression through the restriction point is triggered by phosphorylation of Rb, leading to disruption of Rb-associated repressive complexes and allowing the activation of S-phase genes. Here we show that CBP, like Rb, is controlled by phosphorylation at the G1/S boundary, increasing its histone acetyltransferase activity. This enzymatic activation is mimicked by E1A.

[Histone deacetylase and retinoblastoma protein]. / Histone désacétylase et protéine du rétinoblastome.

The balance between cellular proliferation and differentiation is strictly controlled in the cell and the deregulation of this balance can lead to tumour formation. The tumour suppressor protein Rb plays a key role in this balance essentially by repressing progression through the cell cycle and thereby it blocks the cell in G1 phase. Rb represses S phase genes through the recruitment of an enzyme which modifies DNA structure, the histone deacetylase HDAC1. The Rb/HDAC1 complex is a key element in the control of cell proliferation and differentiation. Moreover, this complex is likely to be a target for transforming viral proteins.

The three members of the pocket proteins family share the ability to repress E2F activity through recruitment of a histone deacetylase.

The transcription factor E2F plays a major role in cell cycle control in mammalian cells. E2F binding sites, which are present in the promoters of a variety of genes required for S phase, shift from a negative to a positive role in transcription at the commitment point, a crucial point in G1 that precedes the G1/S transition. Before the commitment point, E2F activity is repressed by members of the pocket proteins family. This repression is believed to be crucial for the proper control of cell growth. We have previously shown that Rb, the founding member of the pocket proteins family, represses E2F1 activity by recruiting the histone deacetylase HDAC1. Here, we show that the two other members of the pocket proteins family, p107 and p130, also are able to interact physically with HDAC1 in live cells. HDAC1 interacts with p107 and Rb through an "LXCXE"-like motif, similar to that used by viral transforming proteins to bind and inactivate pocket proteins. Indeed, we find that the viral transforming protein E1A competes with HDAC1 for p107 interaction. We also demonstrate that p107 is able to interact simultaneously with HDAC1 and E2F4, suggesting a model in which p107 recruits HDAC1 to repress E2F sites. Indeed, we demonstrate that histone deacetylase activity is involved in the p107- or p130-induced repression of E2F4. Taken together, our data suggest that all members of the E2F family are regulated in early G1 by similar complexes, containing a pocket protein and the histone deacetylase HDAC1.

Retinoblastoma protein represses transcription by recruiting a histone deacetylase.

The retinoblastoma tumour-suppressor protein Rb inhibits cell proliferation by repressing a subset of genes that are controlled by the E2F family of transcription factors and which are involved in progression from the G1 to the S phase of the cell cycle. Rb, which is recruited to target promoters by E2F1, represses transcription by masking the E2F1 transactivation domain and by inhibiting surrounding enhancer elements, an active repression that could be crucial for the proper control of progression through the cell cycle. Some transcriptional regulators act by acetylating or deacetylating the tails protruding from the core histones, thereby modulating the local structure of chromatin: for example, some transcriptional repressors function through the recruitment of histone deacetylases. We show here that the histone deacetylase HDAC1 physically interacts and cooperates with Rb. In HDAC1, the sequence involved is an LXCXE motif, similar to that used by viral transforming proteins to contact Rb. Our results strongly suggest that the Rb/HDAC1 complex is a key element in the control of cell proliferation and differentiation and that it is a likely target for transforming viruses.

Activation of the c-fos SRE through SAP-1a.

TCFs, which are members of the Ets family of transcription factors, are recruited to the Serum Response Element (SRE) in the c-fos promoter by SRF. These Ets proteins, which are substrates for the MAP kinases, are direct targets of the Ras/MAP kinase signal transduction pathway. In this paper, we demonstrate that one of the TCFs, SAP-1a, displays a significant level of autonomous binding to the SRE Ets box. In contrast to previous observations, deletion of the SRF binding domain did not modulate the autonomous binding of SAP-1a. Also, the autonomous binding was not modulated by the phosphorylation of SAP-1a by MAP kinases. The autonomous binding was also detected in live cells: transfected SAP-1a was able to restore the response of a CArG-less SRE in PC12 cells. The response occurred in the absence of SRF recruitment since a mutant of SAP-1a in which the B-box, a domain required for interaction with SRF, had been deleted was still able to transactivate the CArG-less SRE. The transactivation was repressed by a Ras transdominant negative mutant, indicating the involvement of the Ras/MAP kinase pathway. Taken together, these data demonstrate that SAP-1a is capable of binding to the c-fos SRE in the absence of SRF.

Analysis of SRF, SAP-1 and ELK-1 transcripts and proteins in human cell lines.

We have analysed the expression of the genes encoding transcription factors involved in c-fos transcriptional regulation, i.e. the serum response factor (SRF) and the ETS-related proteins ELK-1 and SAP-1, in a variety of human cell lines. RNA was determined by Northern blot analysis, and proteins were detected on Western blots: the two analyses gave essentially identical results. SRF was expressed at similar levels in all cell lines tested. In contrast, SAP-1 and ELK-1 expression varied from one cell line to another. Interestingly, in any given cell line, high levels of one protein were accompained by low levels of the other. Similar results were obtained by electro-mobility shift assays (EMSA), using antibodies directed against the proteins. Thus, our data raise the possibility of a coordinated regulation of the expression of these two Ets genes, at both RNA and protein levels.

SRE elements are binding sites for the fusion protein EWS-FLI-1.

EWS-FLI-1 is a chimeric protein produced in most Ewing's sarcomas. It results from the fusion of the N-terminal-encoding region of the EWS gene to the C-terminal DNA-binding domain (the ETS domain) encoded by the FLI-1 ets family gene. Both EWS-FLI-1 and FLI-1 proteins function as transcription factors that bind specifically to ets sequences (the ets boxes) present in promoter elements. EWS- FLI-1 is a powerful transforming protein, whereas FLI-1 is not. In a search for potential DNA binding sites for these two proteins, we have tested their ability to recognize the serum responsive element (SRE) in the c-fos promoter. This cis element contains an ets box which can be occupied by members of the ETS protein family which do not bind DNA autonomously but form a ternary complex with a second protein, p67SRF (serum responsive factor). We demonstrate here that EWS-FLI-1, but not FLI-1, is able to form a ternary complex on the c-fos SRE. Using a GST pull-down assay, we show that both FLI-1 and EWS-FLI-1 interact in vitro with SRF in the absence of DNA. In electromobility shift assays, EWS-FLI-1 binding to the SRE is detectable in the absence of SRF whereas the binding of FLI-1 is not, suggesting that the interaction with DNA is the step which limits ternary complex formation by FLI-1. Deletion of the N-terminal portion of FLI-1 resulted in a protein which behaved as EWS-FLI-1, suggesting the existence of an N- terminal inhibitory domain in the normal protein. Taken together, our data indicate that there are intrinsic differences in the binding of EWS-FLI-1 and FLI-1 proteins to distinct ets sequences.