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We have studied the transcription factors SCIP and Krox-20 in differentiating Schwann cells-during normal development, in experimentally induced degenerating and regenerating peripheral nerves, and in cell culture-and have compared the expression of these regulators to a battery of genes that mark distinct stages in Schwann cell differentiation. In the myelinating Schwann cell lineage, we find that SCIP is initially induced by contact with axons and first appears near the last round of cell division in immature cells. This expression is transient--it is maximal in "promyelinating" cells and is then extinguished as Schwann cells overtly differentiate and myelinate axons. In contrast, Krox-20 appears in cells 24-36 h after they become SCIP+ and continues to be expressed in mature myelinating cells. These differences in regulation are seen in normal development, in regenerating nerves following nerve crush, and in cultured Schwann cells stimulated to adopt a myelination phenotype by elevation of intracellular cyclic AMP. Importantly, transient SCIP expression is also observed in the nonmyelinating Schwann cell lineage, but Krox-20 expression is not. Together with the myelination phenotypes exhibited by SCIP and Krox-20 mutant mice, these results suggest that SCIP preferentially acts during the predifferentiated phases of Schwann cell development, while in contrast, Krox-20 is associated with the later commitment to myelination and may therefore function as a direct transactivator of myelination genes.
Mol Cell Neurosci 1996
PMID:The transcription factors SCIP and Krox-20 mark distinct stages and cell fates in Schwann cell differentiation. 891 30

Vanadate and insulin both function as unique complete mitogens for SV40-transformed 3T3T cells, designated CSV3-1, but not for nontransformed 3T3T cells. The mitogenic effects induced by vanadate and insulin in CSV3-1 cells are mediated by different signaling mechanisms. For example, vanadate does not stimulate the tyrosine phosphorylation of the insulin receptor beta-subunit nor the 170 kDa insulin receptor substrate-1. Instead, vanadate induces a marked increase in tyrosine phosphorylation of 55 and 64 kDa proteins that is not observed in insulin-stimulated CSV3-1 cells. Perhaps most interestingly, vandate-induced mitogenesis is associated with the selective induction of c-jun and junB expression without significantly inducing c-fos or c-myc. Furthermore, treatment of CSV3-1 cells with genistein abolishes the effects of vanadate on protein tyrosine phosphorylation and c-jun induction. These and related data suggest that modulation of protein tyrosine phosphorylation and c-jun and junB expression may serve the critical roles in mediating vandate-induced mitogenesis in SV40-transformed cells.
Mol Cell Biochem
PMID:Unique and selective mitogenic effects of vanadate on SV40-transformed cells. 892 49

The expression of c-ets2 is rapidly induced in a variety of myelomonocytic cell lines as they differentiate into macrophages. We find that constitutive expression of c-ets2 in the M1D+ myeloblast leukemic cell line (M1ets2) is sufficient to push these cells to a more differentiated state. The expression of several differentiation-specific genes is upregulated in M1ets2 cells, including those encoding macrophage-specific lysozyme M and tumor necrosis factor alpha, which are involved in bacteriolytic and inflammatory processes, respectively. Transcription factors c-jun and junB, previously shown to induce partial macrophage differentiation when overexpressed in myelomonocytic leukemia cell lines, are also upregulated in M1ets2 cells. The upregulation of junB is the result of a direct interaction of Ets2 with ets binding sites of the junB promoter, since transient or constitutive Ets2 expression in M1D+ cells activates junB transcription via ets binding sites. In addition, transfection of a dominant negative mutant of Ets2, devoid of its transcriptional activation domain, greatly reduces transcriptional activities of the junB promoter in M1ets2 cells. Finally, unlike their parental M1D+ counterparts, M1ets2 cells secrete the macrophage colony-stimulating factor, CSF-1, and are able to phagocytize. Taken together, these results show that when the immature myeloid M1D+ cell line constitutively expresses c-ets2, these cells acquire different functions of mature macrophages.
Mol Cell Biol 1996 Dec
PMID:Constitutive c-ets2 expression in M1D+ myeloblast leukemic cells induces their differentiation to macrophages. 894 40

We have studied the transcription factors SCIP and Krox-20 in differentiating Schwann cells-during normal development, in experimentally induced degenerating and regenerating peripheral nerves, and in cell culture-and have compared the expression of these regulators to a battery of genes that mark distinct stages in Schwann cell differentiation. In the myelinating Schwann cell lineage, we find that SCIP is initially induced by contact with axons and first appears near the last round of cell division in immature cells. This expression is transient-it is maximal in "promyelinating" cells and is then extinguished as Schwann cells overtly differentiate and myelinate axons. In contrast, Krox-20 appears in cells 24-36 h after they become SCIP+ and continues to be expressed in mature myelinating cells. These differences in regulation are seen in normal development, in regenerating nerves following nerve crush, and in cultured Schwann cells stimulated to adopt a myelination phenotype by elevation of intracellular cyclic AMP. Importantly, transient SCIP expression is also observed in the nonmyelinating Schwann cell lineage, but Krox-20 expression is not. Together with the myelination phenotypes exhibited by SCIP and Krox-20 mutant mice, these results suggest that SCIP preferentially acts during the predifferentiated phases of Schwann cell development, while in contrast, Krox-20 is associated with the later commitment to myelination and may therefore function as a direct transactivator of myelination genes.
Mol Cell Neurosci 1996 Aug
PMID:The Transcription Factors SCIP and Krox-20 Mark Distinct Stages and Cell Fates in Schwann Cell Differentiation 895 28

The formation of cell membrane following CSF-1 stimulation of a macrophage cell line is coordinated with cell cycle progression. The majority of membrane phospholipid accumulates during the S phase and results from cell-cycle dependent oscillations in the rates of phosphatidylcholine biosynthesis and degradation. Both synthesis and degradation are enhanced during the G1 phase, resulting in a high rate of phosphatidylcholine turnover. Degradation of phosphatidylcholine after CSF-1 stimulation is mediated by a phospholipase C, and the release of diacylglycerol during G1 phase is biphasic. The degradation essentially stops during the S phase, thus allowing biosynthesis to supply the necessary membrane for cell division and doubling. The degradation of phosphatidylcholine during G1 signals the downstream activation of c-fos and junB transcription and can be mimicked by incubation of the macrophage cells with exogenous bacterial phospholipase C. In contrast, the expression of c-myc transcripts normally associated with CSF-1 stimulation is severely compromised in phospholipase C-treated cells, indicating that the diacylglycerol signals a pathway distinct from the pathway that governs c-myc activation. Constitutive expression of c-myc complements phospholipase C activity and permits the growth of cells in the presence of exogenous bacterial enzyme and the absence of CSF-1. Protein kinase C is not required to mediate the diacylglycerol signal that supports cell growth. GTP exchange on Ras is not enhanced, and MAP kinase activity is not stimulated in response to phosphatidylcholine degradation by exogenous phospholipase C. The 85 kDa cytoplasmic phospholipase A2 is activated, however, as well as a novel protein we have called p96. Rapid serine phosphorylation of p96 follows stimulation of cells with either CSF-1 or exogenous phospholipase C. Analysis of the murine cDNA encoding p96 reveals an amino-terminal domain with significant similarity to the amino-terminal domain of the Drosophila-disabled gene product and a carboxy-terminal domain containing proline-rich sequences characteristic of SH3 binding regions. The sequence of p96 suggests an interactive role for this unique protein in the CSF-1 signal transduction cascade.
Mol Reprod Dev 1997 Jan
PMID:Phosphatidylcholine signaling in response to CSF-1. 898 60

The transcription factor hepatocyte nuclear factor 4 (HNF4) is an orphan member of the nuclear receptor superfamily expressed in mammals in liver, kidney, and the digestive tract. Recently, we isolated the Xenopus homolog of mammalian HNF4 and revealed that it is not only a tissue-specific transcription factor but also a maternal component of the Xenopus egg and distributed within an animal-to-vegetal gradient. We speculate that this gradient cooperates with the vegetally localized embryonic induction factor activin A to activate expression of HNF1alpha, a tissue-specific transcription factor with an expression pattern overlapping that of HNF4. We have now identified a second Xenopus HNF4 gene, which is more distantly related to mammalian HNF4 than the previously isolated gene. This new gene was named HNF4beta to distinguish it from the known HNF4 gene, which is now called HNF4alpha. By reverse transcription-PCR, we detected within the 5' untranslated region of HNF4beta two splice variants (HNF4beta2 and HNF4beta3) with additional exons, which seem to affect RNA stability. HNF4beta is a functional transcription factor acting sequence specifically on HNF4 binding sites known for HNF4alpha, but it seems to have a lower DNA binding activity and is a weaker transactivator than the alpha isoform. Furthermore, the two factors differ with respect to tissue distribution in adult frogs: whereas HNF4alpha is expressed in liver and kidney, HNF4beta is expressed in addition in stomach, intestine, lung, ovary, and testis. Both factors are maternal proteins and present at constant levels throughout embryogenesis. However, using reverse transcription-PCR, we found the RNA levels to change substantially: whereas HNF4alpha is expressed early during oogenesis and is absent in the egg, HNF4beta is first detected in the latest stage of oogenesis, and transcripts are present in the egg and early cleavage stages. Furthermore, zygotic HNF4alpha transcripts appear in early gastrula and accumulate during further embryogenesis, whereas HNF4beta mRNA transiently appears during gastrulation before it accumulates again at the tail bud stage. All of these distinct characteristics of the newly identified HNF4 protein imply that the alpha and beta isoform have different functions in development and in adult tissues.
Mol Cell Biol 1997 Feb
PMID:HNF4beta, a new gene of the HNF4 family with distinct activation and expression profiles in oogenesis and embryogenesis of Xenopus laevis. 900 Dec 22

An in vitro, cell-free transcription system, based on prostate-derived transcriptional machinery and very powerful androgen response elements (AREs), has been developed. Multiple (p(ARR3)LovTATA) AREs from the androgen-regulated probasin gene were linked to G-free cassettes and used in nuclear extracts prepared from prostate carcinoma cell lines (PC3 and LNCaP cells) to test specific induction of transcription by full-length AR and by glutathione-S-transferase (GST)-fusion peptides in which the androgen receptor (AR) DNA-binding domain alone (AR524-649), or together with the ligand-binding domain (AR524-902), or a portion of the NH2-terminal domain (AR232-649) were incorporated. In the presence of AR, nuclear extracts from PC3 cells had greater activity in supporting transcription than those from LNCaP cells; and lower background activity than those from HeLa cells. All of the AR forms correctly initiated in vitro transcription of ARE-templates in an androgen-independent manner. The amount of specific, inducible transcript was dependent on the concentration of AR peptide present. AR524-902 was the most potent transactivator tested, with the maximal level of specific transcript over 900-fold higher than the minimal level. At all concentrations this peptide was three to four times more active than either AR524-649 or AR232-649. In conclusion, we have developed a very specific and sensitive cell-free transcription system for delineating trans-activational regions of the AR.
J Steroid Biochem Mol Biol 1996 Nov
PMID:Induction of cell-free, in vitro transcription by recombinant androgen receptor peptides. 901 Mar 16

Expression of c-fos and jun protooncogenes was analyzed in the ovine extraembryonic trophoblast from days 14-18 of gestation, using Northern and Western blotting and immunohistochemistry. This study was carried out in relation to the early implantation process and the expression of interferon-tau, which is secreted in large amounts for a few days before implantation. Our results demonstrated that c-fos, c-jun, and junB were differently expressed in the ovine trophoblast around the time of implantation. The c-fos mRNA and protein were detected at high levels prior to attachment and decreased thereafter, following the pattern of expression of interferon-tau, whereas c-jun expression was maintained at relatively high levels during the implantation process. By contrast, the levels of junB mRNA and protein decreased prior to attachment. Immunohistochemical studies indicated that JunB, like C-Fos and interferon-tau, was no longer expressed in the trophoblastic cells which had established cellular contacts with the uterine epithelium. A striking finding in this study is the temporal correlation between the accumulation of c-Fos and c-Jun proteins and the expression of the interferon-tau (days 14 and 15 of gestation). We also showed by gel-retardation assays that an AP-1-like site present in the promoter of one interferon-tau gene was functional in vitro, as judged by its ability to bind day-15 trophoblast nuclear protein extracts. Nuclear proteins binding to this site had the characteristics of AP-1, as judged by the ability to be competed efficiently by a consensus TRE (12.0-tetradecanoyl phorbol 13-acetate-responsive element)-site oligonucleotide and by antibodies to c-Fos and Jun proteins. These results suggest that Fos and Jun could form regulatory complexes of interferon-tau expression and/or are regulated by common mechanisms which are still unknown.
Mol Reprod Dev 1997 Feb
PMID:Expression of c-fos and jun protooncogenes in ovine trophoblasts in relation to interferon-tau expression and early implantation process. 902 44

Serum response element binding protein (SRE BP) is a novel binding factor present in nuclear extracts of avian and NIH 3T3 fibroblasts which specifically binds to the cfos SRE within a region overlapping and immediately 3' to the CArG box. Site-directed mutagenesis combined with transfection experiments in NIH 3T3 cells showed that binding of both serum response factor (SRF) and SRE BP is necessary for maximal serum induction of the SRE. In this study, we have combined size fractionation of the SRE BP DNA binding activity with C/EBPbeta antibodies to demonstrate that homodimers and heterodimers of p35C/EBPbeta (a transactivator) and p20C/EBPbeta (a repressor) contribute to the SRE BP complex in NIH 3T3 cells. Transactivation of the SRE by p35C/EBPbeta is dependent on SRF binding but not ternary complex factor (TCF) formation. Both p35C/EBPbeta and p20C/EBPbeta bind to SRF in vitro via a carboxy-terminal domain that probably does not include the leucine zipper. Moreover, SRE mutants which retain responsiveness to the TCF-independent signaling pathway bind SRE BP in vitro with affinities that are nearly identical to that of the wild-type SRE, whereas mutant SRE.M, which is not responsive to the TCF-independent pathway, has a nearly 10-fold lower affinity for SRE BP. We propose that C/EBPbeta may play a role in conjunction with SRF in the TCF-independent signaling pathway for SRE activation.
Mol Cell Biol 1997 Mar
PMID:Regulation of the cfos serum response element by C/EBPbeta. 903 1

Insulin and vanadate function as complete mitogens for SV40-transformed murine 3T3T (CSV3-1) cells but not for nontransformed 3T3T cells. Mitogenesis induced by insulin and vanadate in CSV3-1 cells is associated with the induction of the expression of protooncogenes c-jun and junB, two major AP-1 transcription factor components. We now report that both insulin and vanadate induce a significant increase in AP-1 DNA binding activity in CSV3-1 cells but not in 3T3T cells. Gel supershift assays and Western blot analysis using specific antibodies demonstrate that the increased AP-1 binding activity induced by insulin and vanadate in CSV3-1 cells is primarily contributed by an increase in the expression of c-Jun and JunB protein levels. Furthermore, treatment of CSV3-1 cells with antisense oligodeoxyribonucleotides to c-jun or to junB blocks insulin- and vanadate-induced mitogenesis whereas antisense junD oligomers have no inhibitory effects. These results therefore demonstrate that the induction of AP-1 binding activity associated with c-Jun and JunB is required for insulin- and vandate-induced mitogenesis in SV40-transformed murine 3T3T cells. Additional data presented in this paper show that JunD/AP-1 binding activity, which is thought to play a negative role in regulating cell proliferation, is also slightly induced following insulin and vanadate stimulation in CSV3-1 cells. Nevertheless, the ratio of proliferation promoting c-Jun/AP-1 and JunB/AP-1 binding activities to proliferation inhibiting JunD/AP-1 binding activity is significantly increased following insulin and vanadate stimulation. These results therefore support the concept that modulation of the balance of positive Jun/AP-1 and negative Jun/AP-1 activities is important in regulating cell proliferation.
Mol Cell Biochem 1997 Mar
PMID:Induction of AP-1 activity associated with c-Jun and JunB is required for mitogenesis induced by insulin and vanadate in SV40-transformed 3T3T cells. 906 90

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