Transition of starving Dictyostelium cells to differentiation phase at a particular position of the cell cycle

The relationship between proliferation and differentiation in Dictyostelium discoideum Ax-2 was analyzed with reference to the cell-cycle position at the onset of starvation, using cells synchronized by temperature shift (11.5 degrees C-22.0 degrees C). To examine how far Ax-2 cells at any particular phase of the cell cycle are able to progress through the cycle in response to nutritional deprivation, we measured temporal changes in cell number and nuclearity after starvation. Nuclear DNA synthesis in synchronously developing cells was also monitored by pulse-labeling with [methyl-3H]thymidine. Increase in cell number and subsequent DNA synthesis occurred in cells just before mitosis (referred to as T0.5 cells and T1 cells; 0.5 h and 1 h after the shift-up from 11.5 degrees C to 22.0 degrees C respectively), but not in T3, T5, or T7 cells. When T1 cells were incubated for 6 h in the absence of external nutrients, they (T1 + 6 cells) exhibited developmental features similar to T7 cells, which most rapidly acquired chemotactic sensitivity to 3',5'-cyclic adenosine monophosphate (cAMP) and EDTA-resistant cohesiveness after starvation. Thus, it is quite likely that Ax-2 cells may progress through the cell cycle to a particular point (possibly the cell-cycle position of T7 cells), irrespective of the presence or absence of nutrients, and enter the differentiation phase from this point under conditions of nutritional deprivation. There was no difference in the ratio of prestalk to prespore cells in migratory pseudoplasmodia derived from cells that had been starved at other cell-cycle positions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immortalization of human T lymphocytes by oncogenes

Immortalized human T cell lines were established by cotransfecting c-Ha-ras and c-myc oncogenes to lymph node lymphocytes. The cell lines kept growing for 3 months after establishment without a decrease in growth rate. The cells did not require interleukin-2(IL-2) for their growth, but addition of IL-2 stimulated the growth of these cells. Flow cytometric analysis revealed that these cells were T cells expressing CD4 or CD8 antigens. A CD4 positive (CD4⁺) cell line produced IL-6, indicating that the cell line belongs to helper T cells. The CD8 positive (CD8⁺) cell line possessed cytotoxicity to tumor cells, indicating that the cell line were killer T cells. Both cell lines were able to proliferate in serum-free medium indefinitely.     

Multiple ubiquitin-specific protease genes are involved in degradation of yeast tryptophan permease Tat2 at high pressure

When Saccharomyces cerevisiae cells are exposed to high hydrostatic pressure, tryptophan permease Tat2 is degraded in a manner dependent on Rsp5 ubiquitin ligase. Consequently, cell growth is arrested in tryptophan auxotrophic strains. Here we show that of 17 ubiquitin-specific protease genes (UBP), deletion of DOA4, UBP6 or UBP14 causes stabilization of Tat2 and hence the cells can grow at 25 MPa. These disruptant cells displayed marked sensitivity to the arginine analogue canavanine. Internal free ubiquitin decreased 2- to 5-fold upon UBP deletion, although overproduction of ubiquitin did not affect their high-pressure growth and canavanine sensitivity. These results suggest that multiple ubiquitin-specific proteases are involved in pressure-induced degradation of Tat2, rather than free ubiquitin depletion.     

Eicosapentaenoic acid plays a role in stabilizing dynamic membrane structure in the deep-sea piezophile Shewanella violacea: a study employing high-pressure time-resolved fluorescence anisotropy measurement

Shewanella violacea DSS12 is a psychrophilic piezophile that optimally grows at 30MPa. It contains a substantial amount of eicosapentaenoic acid (EPA) in the membrane. Despite evidence linking increased fatty acid unsaturation and bacterial growth under high pressure, little is known of how the physicochemical properties of the membrane are modulated by unsaturated fatty acids in vivo. By means of the newly developed system performing time-resolved fluorescence anisotropy measurement under high pressure (HP-TRFAM), we demonstrate that the membrane of S. violacea is highly ordered at 0.1MPa and 10°C with the order parameter S of 0.9, and the rotational diffusion coefficient D(w) of 5.4μs(-1) for 1-[4-(trimethylamino)pheny]-6-phenyl-1,3,5-hexatriene in the membrane. Deletion of pfaA encoding the omega-3 polyunsaturated fatty acid synthase caused disorder of the membrane and enhanced the rotational motion of acyl chains, in concert with a 2-fold increase in the palmitoleic acid level. While the wild-type membrane was unperturbed over a wide range of pressures with respect to relatively small effects of pressure on S and D(w), the ΔpfaA membrane was disturbed judging from the degree of increased S and decreased D(w). These results suggest that EPA prevents the membrane from becoming hyperfluid and maintains membrane stability against significant changes in pressure. Our results counter the generally accepted concept that greater fluidity is a membrane characteristic of microorganisms that inhabit cold, high-pressure environments. We suggest that retaining a certain level of membrane physical properties under high pressure is more important than conferring membrane fluidity alone.     

Systematic analysis of HSP gene expression and effects on cell growth and survival at high hydrostatic pressure in Saccharomyces cerevisiae

We systematically investigated the role of HSP genes in the growth and survival of Saccharomyces cerevisiae under high hydrostatic pressure together with analysis of pressure-regulated gene expression. Cells of strain BY4742 were capable of growth at moderate pressure of 25 MPa. When pressure of 25 MPa was applied to the cells, the expression of HSP78, HSP104, and HSP10 was upregulated by about 3- to 4-fold, and that of HSP32, HSP42, and HSP82 was upregulated by about 2- to 2.6-fold. However, the loss of one of the six genes did not markedly affect growth at 25 MPa, while the loss of HSP31 impaired high-pressure growth. These results suggest that Hsp31 plays a role in high-pressure growth but that the six upregulated genes do not. Extremely high pressure of 125 MPa decreased the viability of the wild-type cells to 1% of the control level. Notably, the loss of HSP genes other than HSP31 enhanced the survival rate by about fivefold at 125 MPa, suggesting that the cellular defensive system against high pressure could be strengthened upon the loss of the HSP genes. In this paper, we describe the requirement for and significance of a subset of HSP genes in yeast cell growth at moderate pressure and survival at extremely high pressure.