Constitutive overexpression of the 27,000 dalton heat shock protein in late passage human breast cancer cells.

We present evidence that the mechanisms controlling induction of heat shock transcription factors (HSFs) and mRNA expression of the 27,000 molecular weight heat shock protein, hsp27, are diverse in human breast cancer cells. Heat shock accumulation of hsp27 RNA is associated with the activation of HSF in MDA-MB-231 cells. We have later passage MCF-7 breast cancer cell lines with elevated, constitutive expression of hsp27 mRNA, perhaps due to hsp27 gene amplification. Estradiol and heat shock treatment no longer affect the level of hsp27 mRNA in these cells. Heat induction of HSF is inhibited in cells overexpressing hsp27, although metal ions and amino acid analogs are still capable of activating HSF. These cells will provide a useful system for characterizing alternative pathways in HSF inhibition and activation.

The ER-positive/PgR-negative breast cancer phenotype is not associated with mutations within the DNA binding domain.

We have used in vitro DNA binding assays as a measure of estrogen receptor (ER) function in human breast tumors. We found that the majority of ER+ (25 ER+/progesterone receptor [PgR]+, and 25 ER+/PgR-) tumors we examined were capable of binding consensus estrogen response element (ERE) oligonucleotides in this assay system. We found significant proteolytic activity in many of the tumors such that protease inhibitors were found to be essential during the preparation of tumor extracts. We next applied direct sequence analysis of the ER DNA binding domain of several of these tumors, and determined that the ER+/PgR- breast tumors did not contain mutations within the DNA binding domain which might explain their apparent discordant receptor phenotype. We did identify an alternatively spliced ER variant missing exon 3 of the DNA binding domain. This variant was unable to function as a transcriptional inducer of an estrogen-responsive reporter in a yeast assay system. Furthermore, the exon 3 ER deletion variant was expressed at equivalent levels in all of the ER+ breast tumors, so that it does not appear to be involved in the evolution of the ER+/PgR- breast cancer phenotype.

Progesterone receptor gene restriction fragment length polymorphisms in human breast tumors.

We examined the progesterone receptor (PgR) gene in tissue from both primary human breast tumors and normal placentas, detecting restriction fragment length polymorphisms (RFLPs) with the restriction endonucleases Pst I/Sst I and HindIII. There was a general agreement of the Pst I and Sst I polymorphisms in any individual tumor, suggesting that they define two alleles in the human PgR locus, one being characterized by a deletion of about 300 base pairs with respect to the other. Both primary human breast tumor specimens (n = 36) and human term placentas (n = 48) displayed similar allele frequencies and typical mendelian distribution of these Pst I/Sst I alleles. The previously reported HindIII PgR RFLP was also investigated in 132 breast tumors. The HindIII PgR gene RFLP did not display typical mendelian distribution in the breast tumors; the factors affecting the HindIII allele frequencies are presently unknown. Neither the HindIII RFLP nor the deletion defined by Pst I and Sst I correlated with PgR expression as determined by a ligand-binding assay, suggesting that neither is related to the heterogeneity of PgR expression seen in breast tumors.