Cell growth

About: Cell growth is a research topic. Over the lifetime, 104237 publications have been published within this topic receiving 3751303 citations. The topic is also known as: GO:0016049 & cellular growth.

The Saccharomyces cerevisiae Cell Cycle

Abstract: INTRODUCTION The cell cycle is the process of vegetative (asexual) cellular reproduction; in a normal cell cycle, one cell gives rise to two cells that are genetically identical to the original cell. Questions about the cell cycle can be conveniently divided into two categories. First, one can ask how a cell carries out a cell cycle, once it has undertaken to do so. Into this category fall questions about the morphological and biochemical aspects of cell-cycle events and about the mechanisms that ensure their temporal and functional coordination. Second, one can ask what determines when a cell will undertake a cell cycle, or how the overall control of cell proliferation is achieved. Into this category fall questions about the coordination of successive cell cycles, the coordination of growth with division, the coordination of cell proliferation with the availability of essential nutrients, and the selection of developmental alternatives. In the text that follows, we consider these two categories of questions in turn. Our bibliography is intended more as a guide to the literature than as a historically accurate record of the development of the field; we apologize to the earlier workers whose contributions thus get less explicit credit than they deserve. HOW DOES A CELL CARRY OUT A CELL CYCLE? As has often been noted, successful completion of a cell cycle requires a cell to integrate the processes that duplicate the cellular material with the processes that partition the duplicated material into two viable daughter cells. Another useful formulation of the...

p53-dependent and independent expression of p21 during cell growth, differentiation, and DNA damage

Abstract: Expression of p21 has been shown to be up-regulated by the p53 tumor suppressor gene in vitro in response to DNA-damaging agents. However, p21 expression can be regulated independently of p53, and here we show that expression of p21 in various tissues during development and in the adult mouse occurs in the absence of p53 function. However, most tissues tested did require p53 for p21 induction following exposure of the whole animal to gamma irradiation. These results show that normal tissue expression of p21 to high levels is not dependent on p53 and confirm that induction of p21 by DNA-damaging agents does require p53. p21 is expressed upon differentiation of p53-deficient murine erythroleukemia (MEL) cells, and the kinetics of induction of p21 in this system suggest that it may be involved in the growth arrest that precedes terminal differentiation. The gene is up-regulated in mouse fibroblasts in response to serum restimulation but the kinetics and levels of induction differ between wild-type and mutant cells. Expression of p21 message following serum restimulation is superinducible by cycloheximide in wild-type but not in p53-deficient cells. The increases in p21 mRNA are reflected in changes in p21 protein levels. p21 expression also appears to be regulated at the post-transcriptional level because moderate increases in mRNA expression, during differentiation of MEL cells and upon serum restimulation of fibroblasts, are followed by large increases in protein levels. Regulation of the mouse p21 promoter by p53 depends on two critical p53-binding sites located 1.95 and 2.85 kb upstream from the transcriptional initiation site. The sequences mediating serum responsiveness of the promoter map to a region containing the proximal p53 site. p53 appears to play a critical role in p21 induction following DNA damage. Moreover, p21 can be regulated independently of p53 in several situations including during normal tissue development, following serum stimulation, and during cellular differentiation.

Cytoplasmic localization of p21Cip1/WAF1 by Akt-induced phosphorylation in HER-2/neu-overexpressing cells.

Abstract: Amplification or overexpression of HER-2/neu in cancer cells confers resistance to apoptosis and promotes cell growth. The cellular localization of p21Cip1/WAF1 has been proposed to be critical either in promoting cell survival or in inhibiting cell growth. Here we show that HER-2/neu-mediated cell growth requires the activation of Akt, which associates with p21Cip1/WAF1 and phosphorylates it at threonine 145, resulting in cytoplasmic localization of p21Cip1/WAF1. Furthermore, blocking the Akt pathway with a dominant-negative Akt mutant restores the nuclear localization and cell-growth-inhibiting activity of p21Cip1/WAF1. Our results indicate that HER-2/neu induces cytoplasmic localization of p21Cip1/WAF1 through activation of Akt to promote cell growth, which may have implications for the oncogenic activity of HER-2/neu and Akt.

Angiotensin II induces hypertrophy, not hyperplasia, of cultured rat aortic smooth muscle cells.

Abstract: We have explored the hypothesis that contractile agonists are important regulators of smooth muscle cell growth by examining the effects of one potent contractile agonist, angiotensin II (AII), on both cell proliferation and cellular hypertrophy. AII neither stimulated proliferation of cells made quiescent in a defined serum-free media nor augmented cell proliferation induced by serum or platelet-derived growth factor. However, AII did induce cellular hypertrophy of postconfluent quiescent cultures following 4 days of treatment, increasing smooth muscle cell protein content by 20% as compared with vehicle-treated controls. AII-induced hypertrophy was maximal at 1 microM, had an ED50 of 5 nM, and was blocked by the specific AII receptor antagonist Sar1,Ile8 AII. The cellular hypertrophy was due to an increase in protein synthesis, which was elevated within 6-9 hours following AII treatment, while no changes in protein degradation were apparent. AII was even more effective in inducing hypertrophy of subconfluent cultures, causing a 38% increase in protein content after 4 days of treatment (1 microM) and showing a maximal response at concentrations as low as 0.1 nM. Interestingly, in subconfluent cultures, AII treatment (1 microM, 4 days) was associated with a 50% increase in the fraction of cells with 4C DNA content with the virtual absence of cells in S-phase of the cell cycle, consistent with either arrest of cells in the G2 phase of the cell cycle or development of tetraploidy.(ABSTRACT TRUNCATED AT 250 WORDS)