Identification and cDNA cloning of single-stranded DNA binding proteins that interact with the region upstream of the human c-myc gene.

We have previously reported that a c-myc protein complex binds to the region upstream of the c-myc gene, where exist an origin of cellular DNA replication (ori) and a transcriptional enhancer. Both functions require a 21 bp long sequence, while the c-myc protein complex recognizes a 7 bp consensus therein. It was recently reported that single-stranded DNA binding proteins bound specifically to sequences that play roles in DNA replication or transcription. We examined for proteins binding to the single-stranded DNAs of the 21 bp element (myc(H-P)21). In a band shift assay with HL60 cells nuclear extract, probes of either the plus strand or the minus strand gave rise to specific signals. Mutation introduced within a short consensus (A/TCTA/TA/TT) present in both strands completely abolished binding in either case. Southwestern blotting analysis showed that proteins of molecular weight 105, 80, 50, 45, 40, 39.5 and 14 kDa bound sequence-specifically to either strand and 22 kDa to minus strand to the cognate A/TCTA/TA/TT consensus. These single-stranded DNA binding proteins were named MSSP, c-myc gene single strand binding proteins. We attempted to isolate the cDNAs encoding these proteins by screening a human cDNA library with the plus single-stranded oligonucleotide as a probe. Among several positive clones, we have characterized one, termed MSSP-1. MSSP-1 produced in E. coli as a fusion protein with GST specifically interacted with single-stranded TCTTAT (plus myc(H-P)21) and ACT-ATT (in minus myc(H-P)21), the consensus of which can be referred to as A/TCTA/TA/TT. Sequence analysis of MSSP-1 cDNA revealed that two domains thereof are homologous to the RNA binding motifs common to several ribonucleoproteins. Interestingly, the MSSP-1/GST fusion protein specifically recognized myc(H-P)21 not only in single-stranded but also in double-stranded forms. Binding properties of MSSP-1 imply its functions in DNA replication. Furthermore, when the AT stretch in the SV40 ori core was substituted by TCTTAT, MSSP-1 promoted viral DNA replication depending on the consensus sequences.

A eukaryotic nuclear protein of 130 kDa binds to a bacterial cAMP responsive element.

It has been known that one of the signal transduction mechanisms in Escherichia coli is mediated by cAMP which binds to the receptor protein (CAP), and that CAP complexed with cAMP facilitates gene expression by binding to the specific sequences. To identify a molecular mechanism in eukaryotes similar to a cAMP-mediated pathway in E. coli, the function of the CAP binding site of lac gene in E. coli and the protein(s) interacting with it were examined in a mammalian system. From transient expression studies of the fusion gene between the chloramphenicol acetyltransferase and lac genes, it was found that the lacCAP binding site could act as an enhancer activity on the SV40 promoter, and also as an additive enhancer activity to the SV40 enhancer in HeLa cells. However, the activity was not stimulated by cpt-cAMP (a highly stable analogue of cAMP) in HeLa cells, although it was induced in PC12 cells. These results suggest that a bacterial cAMP responsive element may function also in eukaryotes as a cis-acting element in a cell type dependent manner. Results from gel mobility shift assays showed that a protein(s) exists that specifically binds to the lacCAP binding site in eukaryotic nuclear extracts. As one of the proteins binding to the above site, we have identified a 130 kDa protein by using the Southwestern method. Although a function of the 130 kDa protein has not yet been understood, there is a possibility that the 130 kDa protein may play a role in the regulation of cAMP-dependent gene expression.

c-myc protein complex binds to two sites in human hsp70 promoter region.

We investigated the binding of partially purified (enriched) c-myc protein to the human hsp70 promoter region by band shift and ultraviolet crosslinking assays. In the hsp70 promoter region, two sites were found to be homologous to the c-myc protein complex binding sequence in the c-myc gene. These sites are located at positions -230 and -160 bases relative to the transcription initiation site, overlapping with the region reported for the regulation of hsp70 gene expression by c-myc, and upstream of other regulatory sequences including the heat shock element and the serum responsive element. The results shown here suggest that the c-myc protein complex from human HL-60 cells binds to the two sites of the region directly and sequence specifically. It is therefore suggested that the c-myc protein or protein complex contribute to the regulation of hsp70 gene expression by binding directly to the promoter region.

Events blocked in prereplicative phase in senescent human diploid cells, TIG-1, following serum stimulation.

When senescent human diploid cells, TIG-1, were stimulated with serum at the end of their proliferative life span, such biochemical events as uptakes of 2-deoxyglucose and uridine, and expression of c-myc, were enhanced. However, RNA synthesis, polyamine accumulation, thymidine uptake and DNA synthesis were not enhanced at all. Protein synthesis increased only moderately as compared with that observed in younger cells. These results indicated that the events in prereplicative phase known to be independent on protein synthesis are induced in senescent cells after the stimulation with serum, whereas those required protein synthesis failed to increase to the same extent as seen in young cells.

Failure in S6 protein phosphorylation by serum stimulation of senescent human diploid fibroblasts, TIG-1.

When quiescent young or senescent human diploid cells, TIG-1, were metabolically labeled with 32Pi and stimulated with 10% fetal bovine serum, the phosphorylation of ribosomal S6 protein was enhanced in young cells but not in senescent cells while that of some other proteins were increased in both cells. Inability to stimulate the phosphorylation of S6 protein in senescent cells after serum addition may be the primary cause of the failure of enhancement in protein synthesis followed by the block of prereplicative events dependent on protein synthesis and thus of the failure of cells to enter S phase. However, when the cell-free preparation from serum-stimulated senescent cells was incubated with [gamma-32P]ATP, S6-kinase activity was stimulated and S6 in ribosomal fraction was susceptible to phosphorylation as observed in young cells. Differences in S6 phosphorylation of senescent cells between in vivo and in vitro was discussed.

Cell cycle-dependent activation of C-myc enhancer.

The cellular oncogene c-myc encodes a nuclear protein that is considered to play a role in cell proliferation. In this report, the region upstream from the transcriptional promoter of the c-myc gene was examined for regulatory activity on its expression during cell cycle. Plasmids which contain the upstream region of human c-myc gene linked to the bacterial chloramphenicol acetyltransferase (CAT) gene were transfected to rat 3Y1 cells together with pSV2Hg (containing the hygromycin resistance gene linked to the SV40 promoter). Stably transformed cell lines were obtained by hygromycin selection. In random culture, the cells possessing CAT gene preceeded by the upstream region of the c-myc gene, including the HindIII-PstI [myc(H-P)] region, showed strong CAT activity. The myc(H-P) region contains a c-myc protein complex binding site. On the other hand, the cells carrying a similar myc-CAT construct, but without the myc(H-P) region, showed very low levels of CAT expression. These cell lines were then synchronized by serum starvation and their CAT expression was examined by Northern blotting. The expression became maximal between G1 and S phases of the cell cycle, in correspondence with the increase of endogenous c-myc expression. CAT expression of the cells containing the CAT gene linked to the SV40 enhancer/ promoter was less affected by cell cycle, neither was the expression of a housekeeping gene, the hypoxanthine phosphoribosyl transferase (HPRT). These results suggest that the myc(H-P) region is important for cell cycle dependent regulation of c-myc expression.

Enhancement of gene expression by polyamidoamine dendrimer conjugates with alpha-, beta-, and gamma-cyclodextrins.

To improve the transfection efficiency of nonviral vector, we synthesized the starburst polyamidoamine dendrimer conjugates with alpha-, beta-, and gamma-cyclodextrins (CDE conjugates), expecting the synergistic effect of dendrimer and cyclodextrins (CyDs). The (1)H NMR spectroscopic data indicated that alpha-, beta-, and gamma-CyDs are covalently bound to dendrimer in a molar ratio of 1:1. The agarose gel electrophoretic studies revealed that CDE conjugates formed the complexes with plasmid DNA (pDNA) and protected the degradation of pDNA by DNase I in the same manner as dendrimer. CDE conjugates showed a potent luciferase gene expression, especially in the dendrimer conjugate with alpha-CyD (alpha-CDE conjugate) which provided the greatest transfection activity (approximately 100 times higher than those of dendrimer alone and of the physical mixture of dendrimer and alpha-CyD) in NIH3T3 and RAW264.7 cells. In addition, the gene transfer activity of alpha-CDE conjugate was superior to that of Lipofectin. The enhancing gene transfer effect of alpha-CDE conjugate may be attributable to not only increasing the cellular association, but also changing the intracellular trafficking of pDNA. These findings suggest that alpha-CDE conjugate could be a new preferable nonviral vector of pDNA.

Extinction of expression of the genes encoding haematopoietic cell-restricted transcription factors in T-lymphoma x fibroblast cell hybrids.

We previously reported that expression of the T-cell receptor (TCR) alpha and lck genes is extinguished in hybrids between mouse T-lymphoma EL4 cells and mouse fibroblast B82 cells. In the present study, we found that the activities of the TCRalpha minimum enhancer and the lck promoter monitored by the luciferase or chloramphenicol acetyltransferase (CAT) assays were markedly inhibited in the hybrids. Expression of the TCF-1, LEF-1, GATA-3, Ikaros, c-myb and Fli-1 genes, which encode the haematopoietic cell-restricted transcription factors that appear to be responsible for the activities of the enhancer and the promoter, was fully extinguished or markedly suppressed in the hybrids. On the other hand, expression of the transcription factor genes observed in both parental cells, such as the AML1 and c-ets-1 genes, and that of the genes encoding ubiquitously expressed transcription factors, such as the E2A, CREB and c-ets-2 genes, was not significantly suppressed in the hybrids. These results suggest that the genes encoding haematopoietic cell-restricted transcription factors are targets for negative regulation in fibroblastic background and that the repression of these genes may consequently lead to suppression of the promoter and/or enhancer activities of several T-cell-specific structural genes in T-lymphoma x fibroblast cell hybrids.