Our knowledge of the mechanisms that regulate transcription in higher eukaryotic cells has increased enormously during the past 2 years. Earlier studies, using a combination of in vitro mutagenesis and DNA-mediated gene transfer, identified two distinct types of cis-acting regulatory sequences: promoters, which are located close to the initiation site and act in a position-dependent fashion, and enhancers, which can be located far from the initiation site and act in a position-and orientation-independent fashion. Promoters can be subdivided into proximal elements, including the cap site itself and the TATA box, which is involved in fixing the site of initiation, and distal elements, which can be spread over several hundred base pairs. It is now clear that many promoters, particularly those of 'housekeeping' genes, lack TATA boxes and are instead composed of GC-rich elements that are often located within methylation-free islands (Bird 1986). Transcription controlled by this latter class of promoters often initiates at multiple sites. Many enhancer elements, for example, those of the immunoglobulin, insulin, and elastase genes, impose tissue-specific expression on adjacent promoters.These cis-acting elements operate by interacting with protein factors, many of which have now been identified by gel retardation and footprinting assays and some of which have been purified to homogeneity. In a few cases the corresponding genes have been cloned. In many of these studies well-characterized cis-acting elements of viruses, particularly of the DNA tumor viruses, have played a major role. At the recent ICRF-sponsored meeting on the Molecular Biology of SV40, Polyoma, and Adenoviruses (held in Cambridge, England, July 27-August 1, 1987) there was a major emphasis on such trans-acting factors. The results reported both identified new factors and considerably clarified the relationships amongst previously described factors.In this review we will discuss data reported at the meeting and, where appropriate, refer to recently published work. We will concentrate almost exclusively on work with DNA tumor viruses, referring to other systems only when there are direct connections to our major topic. Table 1 lists the factors of relevance, giving the DNA sequences they recognize, their synonyms, and the regulatory systems in which they are known to be involved.
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.
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.
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