Downregulation of estrogen receptor and modulation of growth of breast cancer cell lines mediated by paracrine stromal cell signals.

PURPOSE: Breast cancers have a poorer prognosis if estrogen receptor expression was lost during recurrence. It is unclear whether this conversion is cell autonomous or whether it can be promoted by the microenvironment during cancer dormancy. We explored the ability of marrow-derived stromal cell lines to arrest co-cultured breast cancer cells and suppress estrogen receptor alpha (ER) expression during arrest, facilitating the emergence of estrogen-independent breast cancer clones. METHODS: Cancer cell growth, ER protein, microRNA, and mRNA levels were measured in breast cancer cell lines exposed to conditioned medium from marrow stromal lines in the presence and absence of estrogen and of signaling pathway modulators. RESULTS: We demonstrate that paracrine signaling from the stromal cell line HS5 downregulated ER in T47D and MCF7 breast cancer cells. This occurred at the mRNA level and also through decreased ER protein stability. Additionally, conditioned medium (CM) from HS5 arrested the breast cancer cells in G0/G1 in part through interleukin-1 (IL1) and inhibited cancer cell growth despite the activation of proliferative pathways (Erk and AKT) by the CM. Similar findings were observed for CM from the hFOB 1.19 osteoblastic cell line but not from two other fibroblastic marrow lines, HS27A and KM101. HS5-CM inhibition of MCF7 proliferation could not be restored by exogenous ER, but was restored by the IL1-antagonist IL1RA. In the presence of IL1RA, HS5-CM activation of AKT and Erk enabled the outgrowth of breast cancer cells with suppressed ER that were fulvestrant-resistant and estrogen-independent. CONCLUSIONS: We conclude that marrow-derived stromal cells can destabilize estrogen receptor protein to convert the ER status of growth-arrested ER+ breast cancer cell lines. The balance between stromal pro- and anti-proliferative signals controlled the switch from a dormant phenotype to estrogen-independent cancer cell growth.

Identification of a protein in adrenal particulates that binds adrenocorticotropin specifically and with high affinity.

This paper is concerned with the identification and isolation in cross-linked form of a protein of bovine adrenal cortical particulates that binds the ACTH probe 125I-[Phe2,Nle4,DTBct25]ACTH-(1-25) amide specifically, reversibly, and with high affinity. This protein may well represent the long sought, adenylate cyclase-linked, low affinity ACTH receptor or a portion thereof. Evaluation of the binding data by Scatchard analysis afforded a linear plot corresponding to a dissociation constant of 2.7 X 10(-9) M with a single class of binding sites. Competitive binding studies using nonradioactive ACTH analogs served to establish the specificity of the binding. ACTH-(1-24), was the most active competitor, followed by [Gln5]ACTH-(1-20) amide, [Gln5,Phe9] ACTH-(1-24), and ACTH-(11-20) amide, the weakest binder of the group. These findings correlate well with the ability of the peptides to stimulate cAMP formation in bovine adrenal cortical cells, i.e. ACTH-(1-24) greater than [Gln5]ACTH-1-20) amide greater than [Gln5,Phe9]ACTH-(1-24). ACTH-(11-20) amide is biologically inactive but inhibits ACTH-(1-24)-stimulated adenylate cyclase with a 50% inhibition ratio of 400:1. Nonspecific binding was suppressed by inclusion in the incubates of the protease inhibitors pepstatin, bacitracin, and benzamidine. The binding protein was cross-linked to the radioactive probe with disuccinimidyl suberate with a high cross-linking yield. The cross-linked material was solubilized with sodium dodecyl sulfate (SDS), and the 100,000 X g supernatant was subjected to SDS-polyacrylamide gel electrophoresis, followed by a autoradiography. The gel showed the presence of a band corresponding to an apparent mol wt of 43,000 (assuming a molecule of ligand bound). This band was absent when cross-linking was performed in the presence of unlabeled ACTH-(1-24). Similar results were obtained when cross-linking was performed with dithiobis (succinimidyl)propionate or ethyleneglycolbis (succinimidyl)succinate. The soluble cross-linked material bound to a column of succinoylavidin Sepharose and could be eluted with guanidinium chloride at pH 1.5. SDS-polyacrylamide gel electrophoresis and autoradiography of the affinity-purified material afforded the same pattern as the unpurified material; however, considerably more radioactivity was present in the high mol wt region of the gels.

Radioactive probes for adrenocorticotropic hormone receptors.

Our attempts to develop adrenocorticotropic hormone (ACTH) analogues that can be employed for ACTH receptor identification and isolation began with the synthesis of ACTH fragments containing N epsilon-(dethiobiotinyl)lysine (dethiobiocytin) amide in position 25 to be used for affinity chromatographic purification of hormone-receptor complexes on Sepharose-immobilized avidin resins. Because labeling ACTH or ACTH fragments by conventional iodination techniques destroys biological activity due to oxidation of Met4 and incorporation of iodine into Tyr2, we have prepared [Phe2,Nle4]ACTH1-24, [Phe2,Nle4,biocytin25]ACTH1-25 amide, and [Phe2,Nle4,dethiobiocytin25]ACTH1-25 amide by conventional synthetic techniques. The HPLC profiles and amino acid analyses of the final products indicate that the materials are of a high degree of purity. The amount of tertiary butylation of the Trp residue in the peptides was assessed by NMR and was found to be less than 0.5%. All three peptides are equipotent with the standard ACTH1-24 as concerns their ability to stimulate steroidogenesis and cAMP formation in bovine adrenal cortical cells. Iodination of [Phe2,Nle4]ACTH1-24, with iodogen as the oxidizing agent, has been accomplished without any detectable loss of biological activity. The mono- and diiodo derivatives of [Phe2,Nle4]ACTH1-24 have been prepared, separated by HPLC, and assayed for biological activity. Both peptides have the full capacity to stimulate steroidogenesis and cAMP production in bovine adrenal cortical cells.

Synthetic tools for adrenocorticotropin receptor identification.

Biotinylated photoaffinity derivatives of adrenocorticotropin (ACTH) are potentially useful tools for the identification of ACTH receptors. The hormone can be attached covalently to its receptor by photoactivation, and the presence of biotin in the molecule facilitates isolation of the solubilized hormone-receptor complex on columns of immobilized succinoylavidin (Suc-avidin). Six photoprobes of ACTH1-24 have been prepared by reacting ACTH1-24, [25-biocytin]ACTH1-25 amide, and [25-dethiobiocytin]ACTH1-25 amide with either 4- or 5-azido-2-nitrophenylsulfenyl (4-NAPS and 5-NAPS, respectively) chlorides in acetic acid. The homogeneity of the photoprobes was carefully monitored by thin-layer chromatography and amino acid analyses of acid hydrolysates. The presence of underivatized starting material in the photoprobes was critically scrutinized by high-pressure liquid chromatography and was estimated to be less than 0.5%. Both the 4- and 5-NAPS derivatives stimulated maximal steroidogenesis (as compared with ACTH1-24) in calf adrenal cortical cells. However, the potencies of the two isomers differed significantly. The ED50 for steroidogenesis with 5-NAPS-ACTH1-24 was 100-fold greater than the standard (ACTH1-24) while that for 4-NAPS-ACTH1-24 was only approximately 7 times greater. Although 4-NAPS-ACTH1-24 was capable of stimulating maximal adenosine cyclic 3',5'-phosphate (cAMP) production, the 5-NAPS derivative was usually not. The level of stimulation with the 5-NAPS derivative varied considerably from cell preparation to cell preparation. ACTH1-24-induced cAMP production was inhibited by 5-NAPS-ACTH1-24 or 5-NAPS-[25-dethiobiocytin]ACTH1-25 amide.(ABSTRACT TRUNCATED AT 250 WORDS)