Transformation by ras modifies AP1 composition and activity.

The Ras proteins play a central role in regulating cell growth and their mutation can lead to abnormal proliferation. To analyse the potential link betwen AP1 activity, encoded by members of the jun and fos gene families, and Ras-mediated cellular transformation, we have studied several NIH3T3 clones which overexpress the Ha-Ras or Ki-Ras oncogenes. These transformed fibroblasts accumulated higher levels of cJun, JunB, Fra1 and Fra2 proteins relative to their normal counterparts.

Mouse JunD negatively regulates fibroblast growth and antagonizes transformation by ras.

As NIH 3T3 fibroblasts become quiescent, the level of c-Jun protein decreases while JunD accumulates. When resting cells are stimulated with fresh serum, nuclear-localized JunD is rapidly degraded, followed by resynthesis of both c-Jun and JunD later in G1. Overexpression of JunD results in slower growth and an increase in the percentage of cells in G0/G1 while c-Jun overexpression produces larger S/G2 and M phase populations.

Human hnRNP protein A1 gene expression. Structural and functional characterization of the promoter.

hnRNP protein A1 (34 kDa, pl 9.5) is a prominent member of the family of proteins (hnRNP proteins) that associate with the nascent transcripts of RNA polymerase II and that accompany the hnRNA through the maturation process and the export to the cytoplasm. New evidence suggests an active and specific role for some of these proteins, including protein A1, in splicing and transport.

Wild-type p53 can down-modulate the activity of various promoters.

The wild-type (wt) p53 protein is the product of a tumor suppressor gene that is a frequent target for inactivation in many types of tumors. The nuclear localization of the protein, as well as additional features, suggest that it may be involved in the regulation of gene expression. To explore this possibility, the effects of overproduced wt p53 were investigated in a number of systems.

Overexpression of avian or mouse c-jun in primary chick embryo fibroblasts confers a partially transformed phenotype.

The coding sequences of avian (quail) or murine c-jun proto-oncogenes were introduced into a non-defective retroviral vector derived from Rous sarcoma virus (RSV) in which c-jun replaces v-src. Primary avian fibroblasts chronically infected with either one of these viruses exhibit some phenotypic traits characteristic of RSV-transformed cells, including sustained growth in low serum medium and ability to develop colonies from single cells in agar, even though they are still of normal morphology and contact inhibited. This altered growth control correlates with enhanced AP1-specific DNA binding activity as well as with higher levels of c-Jun products.

Stimulation of protein kinase C or protein kinase A mediated signal transduction pathways shows three modes of response among serum inducible genes.

Activation of the signal transduction pathways mediated by protein kinase A (PKA) or protein kinase C (PKC) led to different responses of several serum inducible genes including the jun gene family, c-fos, c-myc, krox 20 and krox 24. Whereas all of these genes were stimulated by the phorbol ester TPA, a chemical activator of protein kinase C, they were differently regulated upon cAMP stimulation of the PKA dependent pathway. The proto-oncogenes jun B, c-fos, and to a lesser extent jun D were stimulated by increasing the intracellular concentration of cAMP, whereas the TPA stimulation of c-jun and c-myc was inhibited under these conditions.

Characterization of junD: a new member of the jun proto-oncogene family.

In an extensive screen of a cDNA library prepared from serum-stimulated mouse NIH 3T3 cells, we identified three distinct jun-related clones. Two of them were carrying c-jun and junB sequences respectively, whereas the sequence of the third group of clones (junD) was distinct from these two and from v-jun. The amino acid sequences derived from these jun-related clones are very well conserved in five distinct regions including the putative DNA binding domain.