Faculty Bibliography

We have analysed the regulation of c-myc expression in murine fibroblasts and F9 teratocarcinoma cells. The initiation of c-myc transcription is induced to similar levels after serum stimulation of confluent and subconfluent Balb/c A31 fibroblasts while intragenic pausing within the gene's first exon remains unaffected. Sense c-myc transcription continues unabated for at least 18 hours in subconfluent cells, whereas in confluent cells it rapidly falls to pre-induced levels. Cytoplasmic c-myc mRNAs accumulate within 1-2 hours of serum addition to subconfluent cells and reach a higher level than expected from the degree of induction of sense transcription. However, c-myc mRNA levels fall close to pre-induced levels by 18 hours demonstrating that c-myc expression is initially subject to strong positive and then eventually strong negative post-transcriptional control. Anti-sense transcription within the c-myc locus was found to be constitutive under all these physiological states, thereby demonstrating that c-myc transcriptional control is strand specific. Epidermal growth factor stimulates c-myc transcription in a way different from that of serum: (1) initiation of transcription is not significantly enhanced, but intragenic pausing is significantly abrogated; and (2) post-transcriptional mechanisms do not enhance the degree of c-myc mRNA accumulation. In contrast to our results in fibroblastic cells, differentiating F9 teratocarcinoma cells down-regulate c-myc expression entirely at the post-transcriptional level. Our findings indicate that different cell types preferentially employ different modes of myc control depending on their physiological status

We have examined the effects of the E1a products of adenovirus types 5 and 12 on the expression of polyomavirus early and late promoters. In cotransfection experiments in HeLa cells, plasmids expressing the E1a region of adenovirus type 5 or 12 repressed both the early and late promoters of polyomavirus, and deletion analysis indicates that the polyomavirus enhancers were the target of the E1a repression. With mutants lacking enhancer sequences, the polyomavirus early promoter but not the late promoter was trans-activated by E1a. Chimeric mutant plasmids with deletions in the regulatory region that contained either the A enhancer or the B enhancer were repressed to the same extent, indicating that E1a can repress both elements. Polyomavirus variant plasmids with rearrangements in the regulatory region conferring activity in embryonal carcinoma stem cells were repressed by E1a as was the wild type, suggesting that the repressor function is quite general. We discuss a model in which the influence of E1a on the transcriptional activity of a gene is the sum of positive and negative effects on promoter and enhancer elements and discuss possible mechanisms of negative regulation of enhancer function

Cholinergic agonists rapidly and transiently induced transcription of the c-fos protooncogene and one or more actin genes in neuronally differentiated PC12 cells. Transcription was activated within minutes after stimulation of the nicotinic acetylcholine receptor and required an influx of extracellular Ca2+ ions through voltage-sensitive calcium channels. Nicotine activation proceeded by a different pathway from activation by nerve growth factor, whose stimulation of these genes is independent of extracellular Ca2+ ions. These findings suggest that neurotransmitters may rapidly activate specific gene transcription in nondividing neuronally differentiated cells. They also suggest a functional role for neurotransmitter induction of c-fos and actin expression in the nervous system

Stimulation of quiescent 3T3 cells with purified growth factors or of the pheochromocytoma cell line PC12 with nerve growth factor results in the rapid transient induction of c-fos, c-myc, and actin gene transcription (M.E. Greenberg and E.B. Ziff, Nature [London] 312:711-716; M.E. Greenberg, L.A. Greene, and E.B. Ziff, J. Biol. Chem. 26:14101-14110). We used protein synthesis inhibitors to investigate whether synthesis of new proteins plays a role in the rapid induction and subsequent repression of the transcription of these genes. Pretreatment of quiescent 3T3 cells with the inhibitor anisomycin before growth factor stimulation caused a superinduction of c-fos and c-myc mRNA levels upon growth factor addition. Nuclear runoff transcription analyses of 3T3 cells indicated that anisomycin potentiated c-fos, c-myc, and also actin expression at the transcriptional level, possibly by inhibiting transcriptional repression. Somewhat different results were obtained when PC12 cells were incubated with either anisomycin or cycloheximide. In PC12 cells protein synthesis inhibitors superinduced nerve growth factor activation of c-fos mRNA production but completely abolished the activation of c-myc. The results suggest that in PC12 cells c-fos transcription is activated by a protein-synthesis-independent mechanism, whereas c-myc stimulation requires new protein synthesis. The difference in the effect of anisomycin on growth factor activation of c-myc expression in 3T3 versus PC12 cells may be due to differential stringency of protein synthesis inhibition in the two cells or could reflect cell type differences in c-myc regulation

Nerve growth factor (NGF) promotes neuronal differentiation of PC12 pheochromocytoma cells. We show here that within 5 min after its addition, NGF transiently stimulates c-fos proto-oncogene and actin transcription by greater than 100-fold in nonsynchronized PC12 cells. c-myc and ornithine decarboxylase transcription are also transiently activated, but more slowly. The corresponding mRNAs are induced as well. Two weeks' exposure to NGF causes no significant changes in the transcription of these and a variety of other genes analyzed; however, c-fos mRNA levels are increased severalfold under these conditions. Neuronally differentiated PC12 cells retain the capacity for rapid transcriptional responses. Removal of NGF from such cells for several hours followed by its readdition results in rapid induction of c-fos and actin transcription. These NGF-promoted transcriptional changes in PC12 cells are similar to those previously observed in quiescent fibroblasts stimulated by platelet-derived growth factor (Greenberg, M.E., and Ziff, E.B. (1984) Nature 311, 433-438). This rapid transcriptional activation in PC12 cells could be necessary for neuronal differentiation, but is apparently not sufficient since diverse agents without differentiating activity such as epidermal growth factor, insulin, dibutyryl cAMP, phorbol ester, and elevated K+ were also found to induce transcription. These results suggest that c-fos, c-myc, and actin induction may be general nuclear responses to growth or differentiation factors in a variety of different cell types

We transiently expressed adenovirus type C E1a proteins in wild-type or mutant form from plasmid vectors which have different combinations of E1a and simian virus 40 enhancer elements and which contain the DNA replication origin of SV40 and can replicate in COS 7 cells. We measured the levels of E1a mRNA encoded by the vectors and the transition regulation properties of the protein products. Three vectors encoded equivalent levels of E1a mRNA in COS 7 cells: (i) a plasmid encoding the wt 289-amino acid E1a protein (this complemented the E1a deletion mutant dl312 for early region E2a expression under both replicative and nonreplicative conditions); (ii) a vector for the wt 243-amino acid E1a protein (this complemented dl312 weakly and only under conditions of high multiplicities of dl312); (iii) a mutant, pSVXL105, in which amino acid residues-38 through 44 of the 289-amino acid E1a protein (which includes two highly conserved residues) are replaced by 3 novel amino acids (this also complemented dl312 efficiently). A fourth vector, mutant pSVXL3 with which linker substitution shifts the reading frame to encode a truncated 70-amino acid fragment from the amino terminus of the 289-amino acid protein, was unable to complement dl312. Surprisingly, pSVXL3 overexpressed E1a mRNA approximately 30-fold in COS 7 cells in comparison with the other vectors. The pSVXL3 overexpression could be reversed by cotransfection with a wt E1a vector. We suggest that wt E1a proteins regulate the levels of their own mRNAs through the recently described transcription repression functions of the 289- and 243-amino acid E1a protein products and that pSVXL3 fails to autoregulate negatively

Using a transient expression assay in HeLa cells, we show that products from the adenovirus-5 E1a transcription unit repress transcription from the SV40 early promoter. The repression is unrelated to T antigen autoregulation, occurs maximally with low concentrations of E1a expression plasmid, is exerted at the transcriptional level, and requires functional E1a protein. The 289 and 243 amino acid E1a proteins are equally effective at repressing transcription. Since only the 289 amino acid protein is efficient at activating transcription, we conclude that activation and repression are separate E1a functions. We discuss possible mechanisms for E1a repression and the relationship of repression to the function of E1a in cell immortalization and transformation.

Splicing provides viruses with great genetic versatility. It is still too early to say whether this versatility is derived from ingeneous mechanisms evolved by necessity by the viruses, or whether the viruses indeed mimic cellular mechanisms. In any event, it is unlikely that cells will provide a single genomic cluster of genes that utilize splicing in such diverse ways as adenovirus, or the other viruses discussed here. And we may speculate that when the full role of splicing in adenovirus gene expression program is known, its import will continue to be a source of amazement!