Cathepsin D is partly endocytosed by the LRP1 receptor and inhibits LRP1-regulated intramembrane proteolysis.

The aspartic protease cathepsin-D (cath-D) is a marker of poor prognosis in breast cancer that is overexpressed and hypersecreted by human breast cancer cells. Secreted pro-cath-D binds to the extracellular domain of the ß-chain of the LDL receptor-related protein-1 (LRP1) in fibroblasts. The LRP1 receptor has an 85-kDa transmembrane ß-chain and a noncovalently attached 515-kDa extracellular α-chain. LRP1 acts by (1) internalizing many ligands via its α-chain, (2) activating signaling pathways by phosphorylating the LRP1ß-chain tyrosine and (3) modulating gene transcription by regulated intramembrane proteolysis (RIP) of its ß-chain. LRP1 RIP involves two cleavages: the first liberates the LRP1 ectodomain to give a membrane-associated form, LRP1ß-CTF, and the second generates the LRP1ß-intracellular domain, LRP1ß-ICD, that modulates gene transcription. Here, we investigated the endocytosis of pro-cath-D by LRP1 and the effect of pro-cath-D/LRP1ß interaction on LRP1ß tyrosine phosphorylation and/or LRP1ß RIP. Our results indicate that pro-cath-D was partially endocytosed by LRP1 in fibroblasts. However, pro-cath-D and ectopic cath-D did not stimulate phosphorylation of the LRP1ß-chain tyrosine. Interestingly, ectopic cath-D and its catalytically inactive (D231N)cath-D, and pro-(D231N)cath-D all significantly inhibited LRP1 RIP by preventing LRP1ß-CTF production. Thus, cath-D inhibits LRP1 RIP independently of its catalytic activity by blocking the first cleavage. As cath-D triggers fibroblast outgrowth by LRP1, we propose that cath-D modulates the growth of fibroblasts by inhibiting LRP1 RIP in the breast tumor microenvironment.

William L. McGuire Memorial Symposium. Control of breast cancer cell growth by steroids and growth factors: interactions and mechanisms.

Over the past two decades, the simple model for control of breast cancer growth involving one or two factors acting directly or indirectly via endocrine pathways has turned into a complex model implicating numerous interacting factors and the diverse cell populations constituting breast tumors. Current approaches to breast cancer therapy now require integration of these multiple parameters and enhanced understanding of the different levels of their intricate interactions.

Inhibition of breast cancer growth by suramin.

In this study, the polyanionic compound suramin was shown to be a potent in vitro growth inhibitor of both hormone-insensitive, estrogen receptor-negative human breast cancer cells (MDA MB231 and SK-BR-3) and hormone-responsive, estrogen receptor-positive human breast cancer cells (ZR 75-1, T47D, and MCF7). The inhibitory effect of suramin was dose dependent, with a median effective dose varying from 7 microM for MDA MB231 cells to 50 microM for MCF7 cells. This result indicated that estrogen receptor-negative cells were more sensitive to the drug. In MCF7 cells, not only did suramin block the mitogenic action of growth factors such as epidermal growth factor (EGF) and insulin-like growth factors I and II (IGF-I and IGF-II, respectively), but it also totally abolished the increase in cell proliferation induced by the steroid hormone 17 beta-estradiol (E2). Maximal inhibition was obtained after 5 days of suramin treatment, and inhibition either was partially reversed by E2, IGF-I, and IGF-II or was not reversible by EGF following removal of drug. In addition, suramin significantly decreased synthesis and secretion of the lysosomal enzyme cathepsin D, which was shown to be associated with a high risk of breast tumor metastasis. These results therefore suggest that, because of its effects on growth and cathepsin D secretion, suramin might be a helpful additional therapeutic tool for breast cancer patients, especially for patients with estrogen receptor-negative tumors which are insensitive to antihormonal strategies.

Anti-steroidal and anti-growth factor activities of anti-estrogens.

Both steroid hormones, such as estrogens and progestins acting via nuclear receptors, and growth factors, such as EGF, IGF-I and IGF-II acting via transmembrane receptors, are able to modulate the growth of human breast cancer cells. In addition to its anti-estrogenic action requiring estrogen receptor (ER) and leading to growth arrest, we have previously shown that the anti-hormone tamoxifen (Tam) is able to block EGF, insulin and IGF-I mitogenic activities in total absence of estrogens (BBRC, 146,1502,1987). This anti-growth factor activity is observed exclusively in ER + cells and is rescued by estradiol addition, thus suggesting that it is mediated by accessible ER sites. In the same culture conditions, progestins and anti-progestins do not display such an inhibition, whereas retinoic acid does, thus indicating that this anti-growth factor effect is not restricted to ER ligands. To progress in the understanding of this inhibition, we first analyzed how Tam could affect EGF and IGF-I binding in responsive cells. We have shown that Tam neither affects EGF and IGF-I binding to their respective receptors by direct competition nor modulates their affinities. However, our recent data suggest that Tam pretreatment (6 days) of MCF7 cells, which similarly prevents EGF and IGF-I mitogenic activities, results in opposite effects on the concentrations of their binding sites. In conclusion, we propose that some steroid antagonists can inhibit not only the action of agonist ligands of the receptors they are binding to, but can also modulate the action of growth factors by decreasing their receptor concentrations or altering their functionalities.

Interactions of cathepsin-D and insulin-like growth factor-II (IGF-II) on the IGF-II/mannose-6-phosphate receptor in human breast cancer cells and possible consequences on mitogenic activity of IGF-II.

The lysosomal enzyme cathepsin-D (cath-D) and insulin-like growth factor-II (IGF-II), which share a common IGF-II/mannose-6-phosphate (M6P) transmembrane receptor, are both synthesized and secreted by breast cancer cells, upon which they might exert an intracrine/autocrine control on proliferation. We have evaluated the binding of 125I-immunopurified human cath-D in different breast cell membrane preparations. The concentration of high affinity M6P reversible binding sites (mean Kd, 0.85 nM) varied among the different breast cancer cells (0-0.82 pmol/mg membrane protein), but there was no correlation between the presence of steroid receptor and M6P-dependent binding. Cross-linking experiments with [125I]cath-D and [125I]IGF-II showed the formation of complexes with the 270,000 mol wt IGF-II/M6P receptor molecule which migrated, respectively, at 330,000 and 270,000 mol wt in 3-10% gradient sodium dodecyl sulfate-polyacrylamide gels. [125I]IGF-II cross-linking was increased by M6P (20% above control), whereas cath-D strongly inhibited IGF-II interaction by 80%. Conversely, IGF-II reduced [125I]cath-D cross-linking by 55%. Direct ligand binding on receptors transferred onto nitrocellulose sheets by Western blotting confirmed the interaction of both ligands on the same receptor molecule. By studying IGF-II's growth-promoting activity in these cells in a wide range of concentrations, we show that IGF-II triggers its mitogenic response via IGF-II/M6P receptor at low concentrations, whereas it is mainly acting via IGF-I receptor at high concentrations. Three lines of evidences lead us to that conclusion.(ABSTRACT TRUNCATED AT 250 WORDS)