An inducible gene involved in commitment of lymphocytes to transform

Sequence analysis and expression in cultured lymphocytes of the human FOSB gene (G0S3)

G0S3 is a member of a set of putative G0/G1 switch regulatory genes (G0S genes) selected by screening cDNA libraries prepared from human blood mononuclear cells cultured for 2 hr with lectin and cycloheximide. The sequence shows high homology with the murine FOSB gene, which encodes a component of the AP1 transcriptional regulator. Comparison of cDNA and genomic sequences reveals a 4-exon structure characteristic of the FOS family of genes. Freshly isolated cells show high levels of FOSB/G0S3 and FOS/G0S7 mRNAs, which decline rapidly during incubation in culture medium. The kinetics of expression suggest that the high initial levels are caused by the isolation procedure, and do not reflect constitutive expression. In cells preincubated for a day, levels of FOS mRNA reach a maximum 20 min after the addition of lectin and decline to control levels over the next 3 hr. Levels of FOSB mRNA reach a maximum 40 min after the addition of lectin and decline to control levels over the next 6 hr. In freshly isolated cells, both FOS and FOSB mRNAs increase dramatically in response to the protein synthesis inhibitor cycloheximide. In preincubated cells, the cycloheximide response is decreased, especially in the case of FOSB. These differences in expression of FOS and FOSB suggest different roles and regulation. Regions of low base order-dependent stem-loop potential in the region of the gene are defined. These indicate where base order has been adapted for purposes other than stem-loop stability (e.g., encoding proteins or gene regulation). Regions of low potential in a 68.5-kb genomic segment containing the FOSB gene suggest that the potential may help locate genes in uncharted DNA sequences.

A human putative lymphocyte G0/G1 switch gene homologous to a rodent gene encoding a zinc-binding potential transcription factor

G0S24 is a member of a set of genes (putative G0/G1 switch regulatory genes) that are expressed transiently within 1-2 hr of the addition of lectin or cycloheximide to human blood mononuclear cells. Comparison of a full-length cDNA sequence with the corresponding genomic sequence reveals an open reading frame of 326 amino acids, distributed across two exons. Potential phosphorylation sites include the sequence PSPTSPT, which resembles an RNA polymerase II repeat reported to be a target of the cell cycle control kinase cdc2. Comparison of the derived protein sequence with those of rodent homologs allows classification into three groups. Group 1 contains G0S24 and the rat and mouse TIS11 genes (also known as TTP, Nup475, and Zfp36). Members of this group have three tetraproline repeats. Groups 1 and 2 have a serine-rich region and an "arginine element" (RRLPIF) at the carboxyl terminus. All groups contain cysteine- and histidine-rich putative zinc finger domains and a serine-phenylalanine "SFS" domain similar to part of the large subunit of eukaryotic RNA polymerase II. Comparison of group 1 human and mouse genomic sequences shows high conservation in the 5' flank and exons. A CpG island suggests expression in the germ line. G0S24 has potential sites for transcription factors in the 5' flank and intron; these include a serum response element. Protein and genomic sequences show similarities with those of a variety of proteins involved in transcription, suggesting that the G0S24 product has a similar role.

A conformation hypothesis for the suppressor and promoter functions of p53 in cell growth control and in cancer

Cancer is a genetic disease caused by defective control of cell proliferation. As cancer cells divide, the genetic defect is inherited by each daughter cell, leading to tumour development with possible progression to malignancy. The identification of those genes linked with cancer is essential for our understanding of the regulation of cell proliferation and for the therapeutic management of cancer cell growth. Recent studies have revealed that p53 is the most commonly affected gene in human cancer. It is a single copy gene and functions in the regulation of cell proliferation. Mutation of p53 is linked with tumour development, and this may involve abnormal functioning of mutant p53 protein. A mutant allele of p53 is functionally temperature-sensitive and can promote or suppress cell proliferation. The tertiary structure of the mutant protein is also sensitive to temperature and adopts promoter and suppressor forms of p53. A conformation model for the functioning of p53 proposes that wild-type p53 is induced to change from suppressor to promoter form during the cell growth response. This model predicts that any mutation that deregulates the normal control of p53 conformation may lead to cancer.

Three human homologs of a murine gene encoding an inhibitor of stem cell proliferation

The G0S19 genes are members of the "small inducible" family of genes, which have similar exon-intron organizations and encode secreted proteins with similar dispositions of cysteine and proline residues. G0S19-1 mRNA is increased shortly after the addition of lectin or cycloheximide to cultured human blood mononuclear cells. The cDNA sequence is homologous to that of a murine gene encoding an inhibitory cytokine (MIP1 alpha/SCI), which decreases hemopoietic stem cell proliferation. The homology extends to the 3' noncoding region, which contains two conserved elements: (i) GGGACTCTTC, a potential transcription factor NF chi B-binding site, and (ii) TTTTGTAATTTATTTT, which is found in some related genes (e.g., that encoding the immediate early protein ornithine decarboxylase). A similar but complementary sequence is present in human immunodeficiency virus. Two of the three human genes that hybridize to G0S19-1 cDNA were sequenced. G0S19-1 has 5' AP1-like recognition elements as found in some other phorbol ester-responsive genes (e.g., c-fos). G0S19-2 has a 5' Alu sequence, but is likely to be expressed because of the conservation of sections of the gene believed to be important for function. The 5' flanks of both genes contain the nucleotide motifs CK-2 and SRE, indicating cytokine-like genes with the potential to respond to growth factors. G0S19-1 is the main G0S19 gene expressed in adult T lymphocytes and may encode a homeostatic negative regulator of the size of cell populations (or subpopulations) which are derived ultimately from marrow stem cells. As such, it is a potential antioncogene.

A set of human putative lymphocyte G0/G1 switch genes includes genes homologous to rodent cytokine and zinc finger protein-encoding genes

Lymphocyte G0/G1 switch genes (G0S genes) are potential oncogenes and may regulate, be regulated by, or be coordinately regulated with, latent lymphotropic viruses. To identify these genes, a cDNA library was prepared from blood mononuclear cells that had been cultured for 2 hr with a T-cell mitogen (lectin) and cycloheximide. Eight differentially hybridizing recombinants were characterized by RNA and DNA blotting and sequencing. One cDNA (G0S7) corresponded to the oncogene c-fos. Another cDNA (G0S19) was homologous (70%) to a cDNA encoding a murine inhibitor of stem cell proliferation (the cytokine MIP1 alpha) and, less closely, to other members of the "small inducible" secreted protein-encoding gene family. Whereas cDNA hybridization to genomic DNA blots indicated a small subfamily of G0S19 genes, simple patterns of bands indicated that most cDNAs, including G0S30 cDNA, corresponded to single-copy genes. The 3' noncoding sequence of G0S30 cDNA was homologous (87-89%) to the 3' noncoding sequences of certain rodent genes (NGFI-A, Krox24, EGR1) that encode zinc finger proteins (putative transcriptional regulators). This degree of evolutionary conservation suggests an important function for the 3' noncoding region. The 3' noncoding regions of some cDNAs contained the TTATTTAT (mRNA destabilization) element. The corresponding RNAs each formed doublets in agarose gels. Previous studies of c-fos RNA from HeLa cells indicate that this is due to cycloheximide-dependent stabilization of poly(A) tails. Our results reveal the power of cycloheximide enrichment in isolating what would appear to be significant low-abundance mRNAs.

Lymphocyte blastogenesis. Post-transcriptional controls of protein synthesis

To better understand the regulation of macromolecular synthesis in the response of lymphocytes to a mitogen, we have used two-dimensional electrophoresis to search for specificity in the early increase seen in protein synthesis in human lymphocytes treated with phytohemagglutinin and examined the role of new RNA synthesis in this response. Our results confirm a major increase in overall protein synthesis after 4 h of phytohemagglutinin treatment. A further disproportionate increase in the synthetic rates of certain polypeptides was observed using two-dimensional polyacrylamide gel electrophoresis. While actinomycin-D reduced protein synthesis to a level below that of untreated cells, phytohemagglutinin nonetheless enhanced total protein synthesis even in the presence of actinomycin. Some, but not all, of the disproportionate increases in synthesis seen for certain polypeptides are blocked by actinomycin. These results imply the existence of multiple mechanisms controlling protein synthesis early in the course of lymphocyte stimulation. At least some of these do not require new RNA synthesis and thus operate at a post-transcriptional level.

Different forms of p53 detected by monoclonal antibodies in non-dividing and dividing lymphocytes

The commitment of non-dividing cells (in G0) to enter division can be studied using primary cultures of lymphocytes. The cells are stable in G0 unless stimulated by mitogen such as concanavalin A (Con A). Commitment to enter the division cycle depends on the expression of gene(s) induced by Con A and the synthesis of p53 protein correlates with this commitment step. I show here that in unstimulated cells, a second form of p53 is synthesized and is restricted to G0.

Nuclear proteins associated with gene expression in mouse plasmacytoma cell lines

Nucleoplasmic and non-histone chromatin proteins from two unrelated and four related mouse plasmacytoma cell lines have been analysed by biosynthetic labelling with [35S]-methionine followed by one- and two-dimensional polyacrylamide gel electrophoresis. We have attempted to find a relationship between the patterns of nuclear proteins and gene expression in mutant plasmacytoma cell lines. The majority of nuclear proteins are common to all of the cell lines studied as would be expected if the majority of nuclear proteins are concerned with functions common to all plasma cells. There are, however, both qualitative and quantitative differences in the nuclear protein patterns of mutant and parent cell lines which appear to correlate with differences in gene expression. The turnover of nuclear proteins in two of the cell lines, MOPC 315.40 (IgA producer) and MOPC 315.32 (lambda 2 chain producer) was studied using pulse-chase techniques.

A clonal analysis of the differentiation of 3T3-L1 preadipose cells: role of insulin

Cells of the established preadipose line, 3T3-L1, appear to be undifferentiated fibroblasts during exponential growth. When cells become quiescent, a small percentage of them accumulate triglyceride and become morphologically indistinguishable from mature adipocytes. When insulin is added to quiescent cultures, up to 50% of the cells differentiate into adipocytes. The distribution of lipid-containing cells which appear in clusters of varying sizes was analyzed to determine whether commitment to differentiation occurred after quiescence or during exponential growth and whether insulin was required as an inducer of commitment. The spatial arrangement of 3T3-L1 cells at quiescence on some culture dishes was destroyed by replating. This resulted in random distribution of these cells. The distribution of adipocytes among replated and nonreplated cells in these experiments was compared to a computer generated random distribution of differentiated among undifferentiated cells. Dispersal of cells at confluence resulted in a distribution of fat among nonfat cells not significantly different from the computer generated random distribution. In undisturbed cultures, the distribution of fat cells is not random and is consistent with a commitment event in single cells at any cell division during exponential growth followed by divisions of both committed and uncommitted cells. Since insulin affected the number of mature adipocytes only when added after cessation of exponential growth, insulin is not the inducer of commitment but merely enhances lipid production in previously committed cells.

Synchronization of MEL cell commitment with cordycepin

The response of differentiating MEL cells to the nucleotide analogue cordycepin reveals a previously unrecognized aspect of the molecular events which cause commitment of these cells to terminal erythroid differentiation. Cordycepin rapidly inhibits commitment of DMSO-treated MEL cells in a dose range which does not cause cytotoxicity. Reversal of cordycepin treatment in the presence of inducer leads to a rapid and synchronous commitment of a significant proportion of cells in the culture. These results suggest that MEL cells can be blocked just prior to the point of commitment by cordycepin treatment.