Faculty Bibliography

The expression of the neuronal type III intermediate filament protein peripherin was examined in the rat embryo during and following neuronogenesis in the spinal cord and the peripheral nervous system. In situ hybridization analysis reveals that peripherin mRNA is found in the mid-gestational rat embryo in ventral and lateral motoneurons in the spinal cord, and in neurons of all peripheral ganglia examined, including spinal, sympathetic, and enteric ganglia. Peripherin mRNA is seen only in post-migratory motoneurons or neuronal cells in aggregating ganglia, indicating that precursor cells do not express peripherin. To examine the expression of the protein, an affinity-purified antibody (anti-per) specific for a bacterially produced peripherin fusion protein was generated. Anti-per specifically recognizes a 58 kDa, cytoskeletal-enriched, nerve growth factor (NGF)-inducible protein of the expected tissue distribution. Immunocytodetection with anti-per shows that the initiation of peripherin protein synthesis is coincident with the morphological differentiation of neurons. In development, peripherin is one constituent of a program of gene expression activated at terminal neuronal differentiation

A DNA element located at positions -295 to -289 of the c-fos promoter (FAP site) is highly homologous to a consensus 12-O-tetradecanoyl phorbol-13-acetate-responsive element (TRE) and to a cyclic AMP (cAMP)-responsive element (CRE). We found that an oligonucleotide containing the FAP element was a transcription regulator which was distinct from both the TRE and CRE. When cloned in multiple copies in front of a reporter gene in HeLa cells, the FAP oligonucleotide was a powerful constitutive activator sequence. Conversely, in the same cells, reporter plasmids containing multiple copies of the TRE of the human metallothionein gene required phorbol esters for their induction. In PC12 cells, the FAP oligonucleotide was cAMP responsive. Its activity was mediated through a cAMP-dependent protein kinase II and did not rely on ongoing protein synthesis for activation. Adenovirus E1a proteins activated viral promoters through ATF (activation transcription factor) consensus binding sequences identical to the CRE. However, E1a repressed the FAP oligonucleotide-associated transcriptional activity in HeLa cells. In PC12 cells, E1a neither transactivated nor transrepressed the basal and cAMP-stimulated FAP activity. In contrast, the CRE of the human c-fos promoter located at -60 was weakly induced by cAMP and E1a in both HeLa and PC12 cells. We suggest that the FAP oligonucleotide acts through a factor(s) distinct from those employed by the TRE and CRE and that the FAP-associated protein factor(s) may differ in HeLa and PC12 cells in expression or posttranslational regulation

In cells transformed by v-raf, an oncogenic counterpart of the serine/threonine kinase Raf-1, regulatory elements of the c-fos promoter were active under conditions of cell growth or stimulation for which they were inactive in untransformed control cells. This suggests that v-raf transforms by deregulating transcription of early response genes

Medulloblastoma is a rare brain tumor usually occurring in late childhood or early adolescence. Little is known regarding the cell of origin or cellular events leading to its malignant transformation. We have studied the expression of developmentally regulated mRNA in tumor samples by the Northern hybridization assay to determine a relative stage at which a block to further differentiation occurs. In a series of five medulloblastoma tumors analyzed, only one of eight markers for cellular differentiation, the glial fibrillary acidic protein mRNA, was expressed at significant levels. Interestingly, three of six medulloblastoma tumor samples were found to have elevated levels of c-myc mRNA. In one of these tumors, we have found evidence of mutation of the c-myc protooncogene. We discuss possible mechanisms of c-myc activation in medulloblastoma tumors

A lambda cDNA library was prepared from polyadenylated RNA isolated from quiescent human diploid FS-4 fibroblasts stimulated with tumor necrosis factor for 3 h. Differential screening was used to isolate cDNA sequences that are stimulated by tumor necrosis factor. Eight distinct tumor necrosis factor-stimulated gene sequences (designated TSG-1, -6, -8, -12, -14, -21, -27, and -37) were partially sequenced and compared with known sequences from GenBank. TSG-1 was identical to the gene for interleukin-8. TSG-8 corresponded to the gene for monocyte chemotactic and activating factor. TSG-21 and -27 were identical to the genes for collagenase and stromelysin, respectively. The other four sequences showed no homologies with known genes. Patterns of induction of mRNAs corresponding to the eight cloned cDNAs by various cytokines, growth factors, and activators of second messenger pathways were analyzed in FS-4 cells

We have studied nerve growth factor (NGF) regulation of the expression of the tyrosine hydroxylase (TH) gene in PC12 cells. The TH gene encodes the initial and rate-limiting enzyme of the catecholamine biosynthetic pathway. We show that the TH gene is transiently transcriptionally induced by a mechanism reliant on new protein synthesis during 1-2 hr of NGF stimulation, a time following the induction of the c-fos gene at 15 min post-NGF treatment. A potential regulatory sequence located within the TH gene promoter, the TH-FSE, shares homology to a known regulatory element, the fat-specific element (FSE), which is found upstream from genes activated during adipocyte differentiation and binds the Fos-Jun transcription factor complex. We show that the TH-FSE DNA sequence elevates the basal level of transcription from the rat TH promoter and is required for NGF inducibility. This DNA element binds authentic Fos-Jun products produced abundance during NGF stimulation and by in vitro translation. We demonstrate further that the TH-FSE can bind proteins present in PC12 nuclear extracts in a sequence-specific manner. The DNA/nucleoprotein complex that forms increases in abundance during NGF stimulation and reaches a maximum level at 4 hr of treatment. Antibody inhibition studies utilizing an anti-Fos antibody indicate that Fos and/or Fos-related antigen(s) associate with the TH-FSE and suggest that the Fos protein family contributes to the regulation of TH in vivo. These results support a model in which NGF-induced immediate early genes, including c-Fos, contribute to the regulation of delayed early genes such as TH and thereby control neuronal differentiation

A primary response to many growth factor-induced transmembrane signals is the rapid activation of transcription of the proto-oncogene c-fos and other early-response genes, including the beta-actin gene. The c-raf gene encodes a cytoplasmic serine/threonine kinase, raf-1, whose activity is also responsive to transmembrane signals and which in mutant form can transform cells. Here we show that in transient assays, the v-raf protein, which is a constitutively activated oncogenic counterpart of raf-1, can transactivate transcription from two early-response promoters, including the c-fos promoter from human and murine cells and the human beta-actin gene promoter. Multiple elements of the human fos promoter, including the dyad symmetry element necessary for growth-factor induction, an octanucleotide direct repeat element, and the region spanning the sequence from nucleotides -225 to -99 can all serve as targets for raf induction. The c-myc promoter and two adenovirus-2 early promoters are not induced. These findings indicate that raf kinase, when activated by a transmembrane signal or by mutation of a regulatory domain, can phosphorylate a factor(s) capable of regulating transcription of the c-fos and actin genes. The oncogenic form of raf may transform by constitutively activating early response protooncogenes such as c-fos.