A p38 inhibitor allows to dissociate differentiation and apoptotic processes triggered upon LIF withdrawal in mouse embryonic stem cells.

Mouse embryonic stem cells remain pluripotent when maintained in the presence of leukemia inhibitory factor (LIF). Upon LIF withdrawal, most cells differentiate into various lineages, while some die by apoptosis within 3 days. We have analyzed the activation pattern of the mitogen-activated protein kinase (MAPK) families and characterized the expression profile of selected genes modulated during differentiation or apoptosis. We show that p38 MAPKs are activated first, during the apoptotic crisis, while extracellular-regulated kinases and c-Jun N-terminal kinases are induced after the apoptotic crisis in differentiated cells. However, by using both p38 kinase inhibitors (PD169316 and SB203580) and a p38alpha(-/-) cell line, we demonstrate that p38alpha activation is rather a consequence than a cause of apoptosis. We thus reveal novel properties of PD169316, which induces cell survival without impairing cell differentiation, and identify PD169316-sensitive targets like the fibroblast growth factor-5, Brachyury and bcl-2 genes. Finally, we demonstrate that overexpression of the PD169316 - regulated bcl-2 gene prevents LIF withdrawal - induced cell death.

A human RNA polymerase II subunit is encoded by a recently generated multigene family.

BACKGROUND: The sequences encoding the yeast RNA polymerase II (RPB) subunits are single copy genes. RESULTS: While those characterized so far for the human (h) RPB are also unique, we show that hRPB subunit 11 (hRPB11) is encoded by a multigene family, mapping on chromosome 7 at loci p12, q11.23 and q22. We focused on two members of this family, hRPB11a and hRPB11b: the first encodes subunit hRPB11a, which represents the major RPB11 component of the mammalian RPB complex; the second generates polypeptides hRPB11balpha and hRPB11bbeta through differential splicing of its transcript and shares homologies with components of the hPMS2L multigene family related to genes involved in mismatch-repair functions (MMR). Both hRPB11a and b genes are transcribed in all human tissues tested. Using an inter-species complementation assay, we show that only hRPB11balpha is functional in yeast. In marked contrast, we found that the unique murine homolog of RPB11 gene maps on chromosome 5 (band G), and encodes a single polypeptide which is identical to subunit hRPB11a. CONCLUSIONS: The type hRPB11b gene appears to result from recent genomic recombination events in the evolution of primates, involving sequence elements related to the MMR apparatus.

The ribosomal S6 kinases, cAMP-responsive element-binding, and STAT3 proteins are regulated by different leukemia inhibitory factor signaling pathways in mouse embryonic stem cells.

Mouse embryonic stem (ES) cells remain "pluripotent" in vitro in the continuous presence of leukemia inhibitory factor (LIF). In the absence of LIF, ES cells are irreversibly committed to differentiate into various lineages. In this study we have set up an in vitro assay based on the anti-apoptotic activity of LIF to distinguish pluripotent from "differentiation-committed" ES cells. We have examined the phosphorylation profiles of known (STAT3 and ERKs) and identified new (ribosomal S6 kinases (RSKs) and cAMP-responsive element-binding protein (CREB)) LIF-regulated targets in ES and in ES-derived neuronal cells. We have demonstrated that although STAT3, a crucial player in the maintenance of ES cell pluripotency, is induced by LIF in all cell types tested, the LIF-dependent activation of RSKs is restricted to ES cells. We have shown that LIF-induced phosphorylation of RSKs in ES cells is dependent on ERKs, whereas STAT3 phosphorylation is not mediated by any known MAPK activities. Our results also demonstrate that the LIF-dependent phosphorylation of CREB is partially under the control of the RSK2 kinase.

Functional analysis of adenovirus protein IX identifies domains involved in capsid stability, transcriptional activity, and nuclear reorganization.

The product of adenovirus (Ad) type 5 gene IX (pIX) is known to actively participate in the stability of the viral icosahedron, acting as a capsid cement. We have previously demonstrated that pIX is also a transcriptional activator of several viral and cellular TATA-containing promoters, likely contributing to the transactivation of the Ad expression program. By extensive mutagenesis, we have now delineated the functional domains involved in each of the pIX properties: residues 22 to 26 of the highly conserved N-terminal domain are crucial for incorporation of the protein into the virion; specific residues of the C-terminal leucine repeat are responsible for pIX interactions with itself and possibly other proteins, a property that is critical for pIX transcriptional activity. We also show that pIX takes part in the virus-induced nuclear reorganization of late infected cells: the protein induces, most likely through self-assembly, the formation of specific nuclear structures which appear as dispersed nuclear globules by immunofluorescence staining and as clear amorphous spherical inclusions by electron microscopy. The integrity of the leucine repeat appears to be essential for the formation and nuclear retention of these inclusions. Together, our results demonstrate the multifunctional nature of pIX and provide new insights into Ad biology.

Role of suppressors of cytokine signaling (Socs) in leukemia inhibitory factor (LIF) -dependent embryonic stem cell survival.

Mouse embryonic stem (ES) cells remain pluripotent in vitro when grown in the presence of leukemia inhibitory factor (LIF). LIF withdrawal results in progressive ES cell differentiation. Here we show that during this differentiation process, part of the cells undergo apoptosis concomitant with an activation of the p38 MAP kinase. To gain insight into events mediated by LIF in ES cells, the expression of potential candidate genes was analyzed in the absence or presence of this cytokine by using a semiquantitative RT-PCR assay. We focused on early response genes and on a new type of cytokine repressors (the Socs proteins), some of which exhibit anti-apoptotic properties. We found that expression of c-Fos, c-Jun, and JunB was induced upon LIF treatment whereas that of JunD, the tyrosine phosphatase ESP, and the components of the LIF receptor remained unaffected. Expression of Socs-3, but not Socs-1 or Socs-2, was stimulated in the presence of LIF. Finally, uncontrolled overexpression of Socs-1 and Socs-3 led to repression of LIF-dependent transcription and severely reduced cell viability, suggesting that the disturbance of a well balanced Socs protein content has adverse effects on cell survival.

A murine ATFa-associated factor with transcriptional repressing activity.

The ATFa proteins, which are members of the CREB/ATF family of transcription factors, have previously been shown to interact with the adenovirus E1a oncoprotein and to mediate its transcriptional activity; they heterodimerize with Jun, Fos or related transcription factors, possibly altering their DNA-binding specificity; they also stably bind JNK2, a stress-induced protein kinase. Here we report the identification and characterization of a novel protein isolated in a yeast two-hybrid screen using the N-terminal half of ATFa as a bait. This 1306-residue protein (mAM, for mouse ATFa-associated Modulator) is rather acidic (pHi 4.5) and contains high proportions of Ser/Thr (21%) and Pro (11%) residues. It colocalizes and interacts with ATFa in mammalian cells, contains a bipartite nuclear localization signal and possesses an ATPase activity. Transfection experiments show that mAM is able to downregulate transcriptional activity, in an ATPase-independent manner. Our results indicate that mAM interacts with several components of the basal transcription machinery (TFIIE and TFIIH), including RNAPII itself. Together, these findings suggest that mAM may be involved in the fine-tuning of ATFa-regulated gene expression, by interfering with the assembly or stability of specific preinitiation transcription complexes.

Role of the ATFa/JNK2 complex in Jun activation.

The ATFa proteins, which are members of the CREB/ATF family of transcription factors, display quite versatile properties. We have previously shown that they interact with the adenovirus E1a oncoprotein, mediating part of its transcriptional activity and heterodimerize with the Jun, Fos or related transcription factors, thereby modulating their DNA-binding specificity. In the present study, we report the sequence requirement of the N-terminal activation domain of ATFa and demonstrate the importance of specific threonine residues (Thr51 and Thr53) in addition to that of the metal-binding domain, in transcriptional activation processes. We also show that the N-terminal domain of ATFa which stably binds the Jun N-terminal kinase-2 (JNK2) (Bocco et al., 1996), is not a substrate for this kinase in vivo but, instead, serves as a JNK2-docking site for ATFa-associated partners like JunD, allowing them to be phosphorylated by the bound kinase.

Point mutations causing Bloom's syndrome abolish ATPase and DNA helicase activities of the BLM protein.

Bloom's syndrome (BS) is a rare human genetic disorder characterized by mutations within the BLM gene whose primary effects are excessive chromosome breakage and increased rates of sister chromatid interchange in somatic cells. We report the characterization of a murine protein (mBLM), highly related to the product of the human BLM gene. This protein exhibits an ATP-dependent DNA-helicase activity that unwinds DNA in a 3'-5' direction. Single amino acid substitutions found in BS cells, abolish both ATPase and helicase activities of this protein, indicating that defects in these BLM functions may be primarily responsible for BS establishment. These results provide the first evidence suggesting that the enzymatic activities of the BLM product are implicated in the upholding of genomic integrity.

The p53 tumor suppressor inhibits transcription of the TATA-less mouse DP1 promoter.

Cell cycle progression is subject to several regulatory controls, of which the p53 protein plays a major role in growth arrest, subsequent to the detection of cellular aberrations. It is well documented that p53 has the ability to inhibit transcription driven by several promoters, possibly via distinct mechanisms. In this report, we show that expression of the cell cycle regulatory transcription factor DP1 is strongly inhibited by p53, at the level of transcription and probably through the basal TATA-less promoter. This inhibitory activity has a relative specificity for the DP1 promoter compared with the functionally related E2F1 promoter or unrelated promoters such as those of the transcription factor ATFa or the thymidine kinase gene. Inhibition of DP1 transcription has implications in one of the several possible mechanisms through which p53 induces cell cycle arrest.

Leukemia inhibitory factor-dependent transcriptional activation in embryonic stem cells.

STAT transcription factors are induced by a number of growth factors and cytokines. Within minutes of induction, the STAT proteins are phosphorylated on tyrosine and serine residues and translocated to the nucleus, where they bind to their DNA targets. The leukemia inhibitory factor (LIF) mediates pleiotropic and sometimes opposite effects both in vivo and in cultured cells. It is known, for example, to prevent differentiation of embryonic stem (ES) cells in vitro. To get insights into LIF-regulated signaling in ES cells, we have analyzed protein-binding and transcriptional properties of STAT recognition sites in ES cells cultivated in the presence and in the absence of LIF. We have detected a specific LIF-regulated DNA-binding activity implicating the STAT3 protein. We show that STAT3 phosphorylation is essential for this LIF-dependent DNA-binding activity. The possibility that ERK2 or a closely related protein kinase, whose activity is modulated in a LIF-dependent manner, contributes to this phosphorylation is discussed. Finally, we show that the multimerized STAT3-binding DNA element confers LIF responsiveness to a minimal thymidine kinase promoter. This, together with our observation that overexpression of STAT3 dominant-negative mutants abrogates this LIF responsiveness, clearly indicates that STAT3 is involved in LIF-regulated transcriptional events in ES cells. Finally, stable expression of such a dominant negative mutant of STAT3 induces morphological differentiation of ES cells despite continuous LIF supply. Our results suggest that STAT3 is a critical target of the LIF signaling pathway, which maintains pluripotent cell proliferation.

Interactions between the human RNA polymerase II subunits.

As an initial approach to characterizing the molecular structure of the human RNA polymerase II (hRPB), we systematically investigated the protein-protein contacts that the subunits of this enzyme may establish with each other. To this end, we applied a glutathione S-transferase-pulldown assay to extracts from Sf9 insect cells, which were coinfected with all possible combinations of recombinant baculoviruses expressing hRPB subunits, either as untagged polypeptides or as glutathione S-transferase fusion proteins. This is the first comprehensive study of interactions between eukaryotic RNA polymerase subunits; among the 116 combinations of hRPB subunits tested, 56 showed significant to strong interactions, whereas 60 were negative. Within the intricate network of interactions, subunits hRPB3 and hRPB5 play a central role in polymerase organization. These subunits, which are able to homodimerize and to interact, may constitute the nucleation center for polymerase assembly, by providing a large interface to most of the other subunits.

The product of the adenovirus intermediate gene IX is a transcriptional activator.

We have investigated the functional properties of the product of the adenovirus type 5 gene IX. This gene, which is expressed at intermediate times postinfection, encodes a small polypeptide (pIX) of 140 residues that has previously been shown to be incorporated into the viral capsid. Here, we show that pIX, in addition to its structural contribution, exhibits transcriptional properties. In transient transfection experiments, expression of pIX stimulated adenovirus major late promoter activity. The effect was independent of other viral proteins, but the level of promoter activation appeared strongly pIX dose dependent; similar levels of induction were observed with other cellular or viral TATA-containing (but not with TATA-less) promoters. This promoter specificity could be reproduced in a cell-free transcription system by the addition of purified recombinant pIX, further stressing the transcriptional nature of the phenomenon. A preliminary structural analysis of pIX indicated that the integrity of a putative leucine zipper at the carboxy-terminal end of the molecule, as well as elements within the amino-terminal half, was critical for pIX transcriptional activity. The relevance of these findings in adenovirus infection is discussed.

Genomic structure and developmental expression of the mouse cell cycle regulatory transcription factor DP1.

The E2F/DP family of transcription factors play an important role in the control of cell cycle progression. By direct regulatory interactions with the retinoblastoma family of proteins, they integrate extracellular growth promoting signals impinging on the cyclin and cyclin dependent kinase complex during the G1 phase, with cell cycle progression. This is accomplished by direct transcriptional activation of genes required for nucleotide biosynthesis and DNA replication in the S phase. In addition, these transcription factors also play a role in the control of genes involved in regulating G1 and S phase progression including, autoregulatory control, as in the case of E2F1 itself. In this report, we describe the characterisation of the genomic locus encoding DP1, a member of this family. The DP1 gene has a TATA-less promoter and transcription initiates at multiple sites. Using transient transfection assays we have delineated sequences in the upstream region which have promoter or enhancer activity. The DP1 gene was localised to mouse chromosome 8 by metaphase chromosome analysis. We describe a dynamic pattern of DP1 expression using in situ hybridisation on cryostat sections of mouse embryos at various stages of development and a variable level of expression by Northern blot analysis of RNA from various adult tissues.

Nucleoplasmic and nucleolar distribution of the adenovirus IVa2 gene product.

Sequence elements (DE) located downstream of the adenovirus major late promoter start site have previously been shown to be essential for the activation of this promoter after the onset of viral DNA replication. Two proteins (DEF-A and DEF-B) bind to these elements in a late-phase-dependent manner and contribute to this activation. DEF-B corresponds to a dimer of the adenovirus IVa2 gene product (pIVa2, 449 residues), while DEF-A is a heteromeric protein also comprising pIVa2. As revealed by specific immunofluorescence staining of infected cells, pIVa2 is targeted to the nucleus, where it distributes to both nucleoplasmic and nucleolar structures. We have identified the pIVa2 nuclear localization signal (NLS) as a basic peptide element at the C terminus of the protein (residues 432 to 449). An element essential for nucleolar localization (NuLS) has been mapped in the N-terminal part of pIVa2 (between residues 50 and 136). While NuLS activity is dependent upon an intact NLS, we show that both NLS and NuLS functions are independent of specific DNA-binding activity. As visualized by immunoelectron microscopy, pIVa2 is detected in the nucleoplasm at the level of the fibrillogranular network which is active in viral transcription. More surprisingly, pIVa2 accumulates within electron-dense amorphous inclusions found both in the nucleoplasm and in the nucleolus. Altogether, these results suggest that, besides controlling major late promoter transcription, pIVa2 serves additional, as yet unknown functions.

In vivo association of ATFa with JNK/SAP kinase activities.

The human ATFa proteins belong to the CREB/ATF family of transcription factors. We have previously shown that the ATFa proteins may contribute to the modulation of the transcriptional activity of the Jun/Fos complexes (Chatton et al. (1994). Oncogene, 9, 375-385). We now show that a protein kinase activity is strongly associated with ATFa in vivo, as revealed by coimmunoprecipitation of ATFa/kinase complexes from whole cell extracts, with antibodies against ATFa. Two independent regions were found to be implicated in kinase binding: a major interaction site is located within the N-terminal 82 residues comprising an important metal-chelating element; a weaker binding site corresponds to the basic sequence element preceding the C-terminal leucine-zipper of ATFa. Induction experiments suggest that each of these ATFa domains may interact with different kinases. The major activity is associated with the ATFa N-terminal domain. Based on its response to various inducers, on both in vitro and in vivo binding assays, and on its immunological properties, this activity most likely corresponds to the 54/55 kDa JNK2 protein. Taken together, these observations suggest that the ATFa proteins, among other CREB/ATF proteins, may be important effectors of cell signalling pathways.

Properties of the adenovirus IVa2 gene product, an effector of late-phase-dependent activation of the major late promoter.

The adenovirus major late promoter is strongly activated after the onset of viral DNA replication. Sequence elements located downstream of the major later promoter start site have previously been shown to be essential for this activation. Two proteins (DEF-A and DEF-B) bind to these elements in a late-phase-dependent manner. DEF-B has been identified as the product of adenovirus intermediate gene IVa2 (pIVa2) (C. Tribouley, P. Lutz, A. Staub, and C. Kedinger, J. Virol. 68:4450-4457, 1994). Here we show that pIVa2, while monomeric in solution, binds to its recognition sequence as a dimer and that two 20-residue amphipathic alpha helices play an essential role in this DNA-binding activity. Attempts to purify DEF-A have failed, but its chromatographic behavior, together with its immunological properties, established that pIVa2 is also a component of this heteromeric protein. In addition, the time course of pIVa2 synthesis during infection correlated with simultaneous detection of the binding of both DEF-A and DEF-B complexes to the downstream elements. Finally, as revealed by immunomicroscopy, pIVa2 is targeted to the nucleus, where it distributes to restricted locations in the nucleoplasm, as well as to the nucleoli. Altogether, these results demonstrate that pIVa2 plays a critical role in the transition from the early to the late phase of the lytic cycle. Furthermore, pIVa2 may serve additional functions yet to be uncovered, as suggested by its presence within the cell nucleolus.

The gene (POLR2L) encoding the hRPB7.6 subunit of human RNA polymerase.

The gene (POLR2L) encoding a 7.6-kDa subunit (hRPB7.6) of human RNA polymerase has been cloned. It compromises two exons, 116 and 227 bp, respectively, interspaced with an intron of about 2.1 kb. This gene, whose localization has been assigned to the short arm of chromosome 11 (position 11p15), is transcribed in HeLa cells as one major messenger RNA, which encodes a 67-residue polypeptide (7645 Da) that shares strong homologies with the corresponding subunits of other eukaryotic and archaeal RNA polymerase subunits. Like its yeast counterpart (ABC10 beta, encoded by the RPB10 gene), the hRPB7.6 subunit may be shared by all three classes of human nuclear RNA polymerase. Cysteine residues characteristic of an atypical zinc-binding domain are conserved in the homologous sequences of all six species analyzed. A small, related RNA polymerase subunit from vaccinia virus exhibits an identical set of cysteines, suggesting that these residues may be contribute to a crucial function in the multimeric RNA polymerases.

Eukaryotic GST fusion vector for the study of protein-protein associations in vivo: application to interaction of ATFa with Jun and Fos.

We describe a multipurpose eukaryotic expression vector that incorporates the following features: restriction sites for in-frame insertion of cDNAs of interest between sequences encoding the glutathione-S-transferase (GST) and an oligohistidine element, allowing expression of the corresponding fusion proteins; a phosphorylation site for protein kinase A for in vitro labeling of the fusion protein; a T7 promoter for in vitro transcription and subsequent translation; and signals for single-stranded DNA production in bacteria. We have used this vector to demonstrate the formation in vivo of complexes between the transcription factor ATFa, a member of the family of ATF/CRE binding proteins, and the c-Jun or c-Fos proteins. Such interactions could be detected in crude extracts from cells transfected with vectors expressing the GST-ATFa fusion protein, as well as the c-Jun or c-Fos proteins. Complexes containing both ATFa and either c-Jun or c-Fos were specifically retained on glutathione (GSH)-agarose beads as revealed by immunoblot analyses. We also show that the leucine zipper domain of ATFa is essential for this interaction.

The product of the adenovirus intermediate gene IVa2 is a transcriptional activator of the major late promoter.

During the course of lytic infection, the adenovirus major late promoter (MLP) is induced to high levels after replication of viral DNA has started. We had previously shown that sequence elements located downstream of the MLP start site were implicated in this late-specific transcriptional activation (DE1, between +85 and +98; DE2, between +100 and +120). Two positive transcription factors involved in this activation have been detected. DEF-A, which specifically binds to DE1 and also to the 3' portion of DE2 (DE2a), and DEF-B, which interacts with the 5' part of DE2 (DE2b). When present together, these two proteins cooperatively assemble onto the DE2 element. We now report the purification of DEF-B and show that it is identical to the product of the adenovirus IVa2 gene product. This conclusion is based on microsequence analysis of DEF-B as well as on the inhibitory effect of antibodies against IVa2 on the DNA-binding activity of DEF-B and also on DE-dependent in vitro transcription. In addition, we show that bacterially synthesized IVa2 protein binds to the DE sequences with the same specificity as DEF-B. Finally, in transfected cells, a recombinant IVa2 protein stimulates MLP activity in a DE-dependent fashion. The physiological implications of these findings are discussed.

Chromosomal localization of human RNA polymerase II subunit genes.

The eukaryotic DNA-dependent RNA polymerase II (or B) is composed of 10 to 14 polypeptides ranging from 220 to 10 kDa. To gain further insight into the molecular structure and function of these subunits, we have undertaken the molecular cloning of nucleotide sequences corresponding to the human enzyme. The cDNAs of five subunits (hRPB220, hRPB140, hRPB33, hRPB25, and hRPB14.5) have been isolated. Using in situ hybridization, we show that the genes of these subunits have distinct chromosomal locations (17p13, 4q12, 16q13-q21, 19p13.3, and 19q12, respectively). Thus, if assembly of active polymerase molecules requires coordinated expression from these independent genes, mechanisms that ensure tight coregulation of the corresponding promoters must exist.