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.

Tumor cell growth inhibition by caveolin re-expression in human breast cancer cells

Abstract: Cancer development is a multistage process that results from the step-wise acquisition of somatic alterations in diverse genes. Recent studies indicate that caveolin-1 expression correlates with the level of oncogenic transformation in NIH3T3 cells, suggesting that caveolin in caveolae may regulate normal cell proliferation. In order to better understand potential functions of caveolin-1 in cancer development, we have studied expression levels of caveolin-1 in human breast cancer cells, and have found that caveolin expression is significantly reduced in human breast cancer cells compared with their normal mammary epithelial counterparts. When the caveolin cDNA linked to the CMV promoter is transfected into human mammary cancer cells having no detectable endogenous caveolin, overexpression of caveolin-1 resulted in substantial growth inhibition, as seen by the 50% decrease in growth rate and by approximately 15-fold reduction in colony formation in soft agar. In addition, characterization of caveolin-1 expression during cell cycle progression indicates that expression of alpha-caveolin-1 is regulated during cell cycle. Furthermore p53-deficient cells showed a loss in caveolin expression. In summary, the overall expression patterns, its ability to inhibit tumor growth in culture, its regulation during the cell cycle, and the loss of expression in p53-deficient cells all are consistent with an important growth regulating function for caveolin-1 in normal human mammary cells, that needs to be repressed in oncogenic transformation and tumor cell growth.

Protracted low-dose effects on human endothelial cell proliferation and survival in vitro reveal a selective antiangiogenic window for various chemotherapeutic drugs.

Abstract: Recent preclinical studies have shown that frequent administration in vivo of low doses of chemotherapeutic drugs (“metronomic” dosing) can affect tumor endothelium and inhibit tumor angiogenesis, reducing significant side effects (e.g., myelosuppression) involving other tissues, even after chronic treatment. This suggests that activated endothelial cells may be more sensitive, or even selectively sensitive, to protracted (“high-time”) low-dose chemotherapy compared with other types of normal cells, thus creating a potential therapeutic window. To examine this hypothesis, we assessed the effects of several different chemotherapeutic drugs—namely paclitaxel, 4-hydroperoxycyclophosphamide, BMS-275183 (an oral taxane), doxorubicin, epothilone B (EpoB) and its analogue 5-methylpyridine EpoB—on human microvascular or macrovascular endothelial cells, fibroblasts, and drug-sensitive or multidrug-resistant breast cancer cell lines in cell culture, using both short-term (24 h) versus long-term (144 h), continuous exposures, where drug-containing medium was replaced every 24 h. Whereas little differential and only weak effects were observed using the short-term exposure, a striking trend of comparative vascular endothelial cell hypersensitivity was induced using the continuous long-term exposure protocol. Potent differential growth inhibition effects as well as induction of apoptosis were observed with IC50 values in the range of 25–143 pm for paclitaxel, BMS-275183, EpoB, and 5-methylpyridine-EpoB. In contrast, the IC50 values for tumor cells and fibroblasts tested were in the range of 500 pm to >1 nm for these drugs. Similar differential IC50 values were noted using 4-hydroperoxycyclophosphamide. The results are consistent with the possibility that continuous low-dose therapy with various chemotherapeutic drugs may have a highly selective effect against cycling vascular endothelial cells, and may be relevant to the use of continuous or frequent administration of low doses of certain types of drugs as an optimal way of delivering antiangiogenic therapy.

Telomerase modulates expression of growth-controlling genes and enhances cell proliferation

Abstract: Most somatic cells do not express sufficient amounts of telomerase to maintain a constant telomere length during cycles of chromosome replication Consequently, there is a limit to the number of doublings somatic cells can undergo before telomere shortening triggers an irreversible state of cellular senescence Ectopic expression of telomerase overcomes this limitation, and in conjunction with specific oncogenes can transform cells to a tumorigenic phenotype However, recent studies have questioned whether the stabilization of chromosome ends entirely explains the ability of telomerase to promote tumorigenesis and have resulted in the hypothesis that telomerase has a second function that also supports cell division Here we show that ectopic expression of telomerase in human mammary epithelial cells (HMECs) results in a diminished requirement for exogenous mitogens and that this correlates with telomerase-dependent induction of genes that promote cell growth Furthermore, we show that inhibiting expression of one of these genes, the epidermal growth factor receptor (EGFR), reverses the enhanced proliferation caused by telomerase We conclude that telomerase may affect proliferation of epithelial cells not only by stabilizing telomeres, but also by affecting the expression of growth-promoting genes

Bombesin stimulation of DNA synthesis and cell division in cultures of Swiss 3T3 cells.

Abstract: Bombesin is shown to be a potent mitogen for Swiss 3T3 cells. At nanomolar concentrations the peptide markedly enhances the ability of fresh serum to stimulate DNA synthesis in confluent and quiescent cultures of these cells. In the presence of a low concentration (3.5%) of serum, bombesin stimulates 3T3 cell proliferation. In serum-free medium, bombesin induces DNA synthesis in the absence of any other added growth factor; half-maximal effect is obtained at 1 nM. The mitogenic effect of bombesin is dependent on dose and time, is mimicked by litorin, and is markedly potentiated by insulin, colchicine, platelet-derived growth factor, and fibroblast-derived growth factor. These mitogens increase the maximal response elicited by bombesin and decrease the bombesin concentration required to produce half-maximal effect (from 1 nM to 0.3 nM). In contrast, vasopressin, phorbol esters, or cAMP increasing agents fail to enhance the maximal level of DNA synthesis induced by bombesin. Bombesin and litorin may provide useful model peptides for studies on the mechanism(s) by which extracellular ligands control cell proliferation.