METASTASIS-ASSOCIATED MTS1 GENE-EXPRESSION IS DOWN-REGULATED BY HEAT-SHOCK IN VARIANT CELL-LINES OF THE B16 MURINE MELANOMA

被引：10

作者：

CAJONE, F ^{[1
]}

DEBIASI, S ^{[1
]}

PARKER, C ^{[1
]}

LAKSHMI, MS ^{[1
]}

SHERBET, GV ^{[1
]}

机构：

[1] UNIV NEWCASTLE UPON TYNE,SCH MED,CANC RES UNIT,NEWCASTLE TYNE NE2 4HH,ENGLAND

来源：

MELANOMA RESEARCH | 1994年 / 4卷 / 03期

关键词：

CANCER INVASION; HEAT SHOCK PROTEINS; METASTASIS; METASTASIS-ASSOCIATED MTS1 GENE;

D O I：

10.1097/00008390-199406000-00001

中图分类号：

R73 [肿瘤学];

学科分类号：

100214 ;

摘要：

Tumour cells are more heat sensitive than corresponding normal cells but the reasons for this are poorly understood. Here we report that induction of heat shock proteins was associated with a down-regulation of the metastasis associated mts1 gene in BL6-B16 murine melanoma cells, and the heat-resistant HTG variant of the BL6 line. Melanocyte stimulating hormone, which does not affect B16 cell proliferation but upregulates mts1 expression, only marginally enhanced heat shock protein expression in F1 cells as determined by immunohistochemical methods. Retinoic acid, which inhibits cell proliferation and down-regulates the mts1 gene, reduced heat shock protein expression in the ML8-B16 variant line. This suggests that the changes in the heat shock protein expression reported here may be cell proliferation related. Heat shock proteins are known to stabilize microtubules, whereas mts1 has been implicated in their depolymerization. Taxol, which stabilizes microtubules and arrests cells at the G1 phase of the cell cycle, down-regulated mts1 gene expression in both F1 and ML8 lines. Taxol also reduced heat shock protein expression in ML8 cells. These data suggest opposing functions of heat shock proteins and the mts1 gene in microtubule polymerization, and may provide a rationale for the use of hyperthermia as a treatment for tumours.

引用

页码：143 / 150

页数：8

共 48 条

[1]

Yatvin M.B., Dennis W.H., Elegbede J.A., Elson C.E., Sensitivity of tumour cells to heat and way of modifying the response, SEB Symposium 41. Temperature and Animal Cells, pp. 235-267, (1987)

[2]

Wallen C.A., Colby T.V., Stewart J.R., Cell kill and tumour control after heat treatment with and without vascular occlusion in RIF-1 tumours, Radiat Res, 106, pp. 215-223, (1989)

[3]

Chen T.T., Heidelberger C., Quantitative studies on the malignant transformation of mouse prostate cells by carcinogenic hydrocarbon in vitro, Int J Cancer, 4, pp. 166-178, (1969)

[4]

Giovanella B.C., Stehlin J.S., Morgan A.C., Selective lethal effect of supranormal temperature on mouse sarcoma cells, Cancer Res, 36, pp. 3944-3950, (1976)

[5]

Hainaut P., Milner P., Interaction of heat shock protein 70 with p53 translated in vitro-, evidence for interaction with dimeric p53 and for a role in the regulation of p53 conformation, EMBO J, 11, pp. 3513-3520, (1992)

[6]

Glass J.R., De Witt R.G., Cress A.E., Rapid loss of stress fibres in Chinese hamster ovary cells after hyperthermia, Cancer Res, 45, pp. 258-262, (1985)

[7]

Coakley W.T., Hyperthermia effects on the cytoskeleton and on cell morphology, Bowler K, Fuller BJ, (1987)

[8]

Ebralidze A., Tulchinsky E., Grigorian M., Isolation and characterisation of a gene specifically expressed in different metastatic cells and whose deduced gene product has a high degree of homology to Ca2+ binding protein family, Genes Dev, 3, pp. 1086-1093, (1989)

[9]

Jackson-Grusby L., Swiergiel J., Linzer D., A growth related mRNA in cultured mouse cells encodes a placental calcium binding protein, Nucleic Acids Res, 15, pp. 6677-6690, (1988)

[10]

Ebralidze A., Florene V., Lukanidin E., Et al., The murine mtsl gene is highly expressed in metastatic but not in non-metastatic human tumour lines, Clin Exp Metastasis, 8, (1990)

← 1 2 3 4 5 →