Martin Fusek

Cathepsin D-Many functions of one aspartic protease

For years, it has been held that cathepsin D (CD) is involved in rather non-specific protein degradation in a strongly acidic milieu of lysosomes. Studies with CD knock-out mice revealed that CD is not necessary for embryonal development, but it is indispensable for postnatal tissue homeostasis. Mutation that abolishes CD enzymatic activity causes neuronal ceroid lipofuscinosis (NCL) characterized by severe neurodegeneration, developmental regression, visual loss and epilepsy in both animals and humans. In the last decade, however, an increasing number of studies demonstrated that enzymatic function of CD is not restricted solely to acidic milieu of lysosomes with important consequences in regulation of apoptosis. In addition to CD enzymatic activity, it has been shown that apoptosis is also regulated by catalytically inactive mutants of CD which suggests that CD interacts with other important molecules and influences cell signaling. Moreover, procathepsin D (pCD), secreted from cancer cells, acts as a mitogen on both cancer and stromal cells and stimulates their pro-invasive and pro-metastatic properties. Numerous studies found that pCD/CD level represents an independent prognostic factor in a variety of cancers and is therefore considered to be a potential target of anti-cancer therapy. Studies dealing with functions of cathepsin D are complicated by the fact that there are several simultaneous forms of CD in a cell-pCD, intermediate enzymatically active CD and mature heavy and light chain CD. It became evident that these forms may differently regulate the above-mentioned processes. In this article, we review the possible functions of CD and its various forms in cells and organisms during physiological and pathological conditions.

Effect of human procathepsin D on proliferation of human cell lines

We have used human procathepsin D isolated from supernatant of human breast cancer cell line ZR-75-1 to test its mitogenic activity for a broad spectrum of human-derived cell lines. These cell lines included: breast cancer cell lines ZR-75-1, MDA-MB-436, MBA-MD-483 and MDA-MB-231, B lymphoblastoid cell line Raji, the monocytoid cell line U937, T lymphoblastoid cell line 8402, epitheloid carcinoma cell line HELA, hepatocellular carcinoma cell line Hep G2, breast milk epithelial cell line HBL-100 and angiosarcoma cell line HAEND-1. We have tested the level of proliferation of these cell lines depending on the presence of procathepsin D in the medium. In parallel we have also measured the effect of insulin-like growth factor II under the same experimental conditions. We have found a significant difference between the influence of IGF II and that of procathepsin D. While IGF II promoted in practically the same way the proliferation of all cell lines tested, procathepsin D had a very pronounced effect on breast cancer cell lines only. This finding might help to explain some contradictory results of prognostic significance of procathepsin D in human breast cancer.

Analysis of the interaction of procathepsin D activation peptide with breast cancer cells

Cathepsin D, a lysosomal aspartic proteinase, is secreted in the form of enzymatically inactive proenzyme by many types of human breast cancer tissue and exerts mitogenic activity toward these tissues. Flow cytometry was used to test the binding of procathepsin D purified from the secretion of the breast cancer cell line ZR‐75‐1 to human breast cancer cells. No previously known surface antigens or soluble M6P‐R or anti‐M6P‐R antibodies were found to inhibit the specific binding of procathepsin D‐FITC. Similarly, none of these potential inhibitors was found to inhibit growth factor activity of procathepsin D. Our results indicate that procathepsin D growth factor activity is mediated by a new, previously unknown receptor moiety and that the binding activity can be localized in position 27–44 of the activation peptide of procathepsin D. Furthermore, in vivo experiments indicate that treatment with anti‐procathepsin D antibodies can reverse the growth of human breast tumors in athymic nude mice. Int. J. Cancer 73:403–409, 1997.

Procathepsin D in breast cancer: What do we know? Effects of ribozymes and other inhibitors

Procathepsin D (pCD) is a major secreted glycoprotein in some human breast and other cancer cell lines. Several groups proposed that pCD served as a growth factor for these cell lines. Secreted pCD has been demonstrated in tissue section, tissue culture supernatants, carcinoma cytosols, and nipple aspirates. Moreover, several clinical studies suggested a potential role for this molecule in metastasis because its concentration in primary tumors correlated with an increased incidence of tumor metastases. In this paper, the effects of pCD were evaluated by proliferation in vitro and by mouse studies in vivo. Subsequent flow cytometry experiments showed the specificity of pCD binding to cancer cells. Cell cultivation showed that addition of either pCD or its activation peptide stimulates growth of cancer cells. These effects can be inhibited both in vitro and in vivo by anti-pCD antibodies. In addition, production of pCD can be inhibited by specifically designed ribozymes. This paper is focused on mitogenic effects of pCD, which seem to involve interaction of the activation peptide with as yet unidentified receptor. Different mechanisms by which pCD could promote development and spread of cancer cells are discussed.

Effect of procathepsin D and its activation peptide on prostate cancer cells

Cathepsin D, a lysosomal aspartic proteinase, is secreted in the form of enzymatically inactive precursor in some cancer cells. This precursor, called procathepsin D, was found to exhibit growth factor activity toward breast cancer cell lines and this activity was later shown to be mediated by its activation peptide. In the present investigation we have used human procathepsin D and a synthetic 44 amino acid peptide corresponding to the activation peptide of procathepsin D to test its growth factor activity for human prostate cancer-derived cell lines PC3, DU145 and LNCaP. We have tested the level of proliferation of these cell lines depending on the presence of either procathepsin or activation peptide in the medium. In parallel, we have also measured the time dependency of this growth and established the optimal dose of activation peptide. These findings represent the first experimental data showing the direct effects of procathepsin D on prostate cancer cells.

Candida parapsilosis expresses and secretes two aspartic proteinases

We have isolated and characterized a second aspartic proteinase secreted by the CHUV E‐18 strain of Candida parapsilosis. This proteinase is produced at a level corresponding to approximately 25% of the production of the main proteinase described earlier [1]. This minor proteinase has similar molecular weight and pH optimum but differs in the isoelectric point and in the specificity when compared with the major secreted form. The determination of the amino terminal amino acid sequence identified this minor form of Candida parapsilosis aspartic proteinase as a protein which corresponds to the sequence deduced from genomic DNA originally reported as a pseudogene [1]. We conclude that strain CHUV E‐18 of Candida parapsilosis expresses and secretes two different aspartic proteinases.

Depletion of procathepsin D gene expression by RNA interference – A potential therapeutic target for breast cancer

Elevated level of procathepsin D (pCD), a zymogen of lysosomal aspartic proteinase cathepsin D, is associated with highly invasive neoplasms that include breast cancer. Independent studies have established that secreted pCD functions as a growth factor acting both in an autocrine and paracrine manner. Therefore, to explore whether pCD can be employed as a therapeutic target, the present study evaluates the impact of pCD knockdown using RNA interference technology. Of the three siRNA oligos tested, siRNA-3 exhibited a 90% inhibitory effect on pCD gene expression. Stable attenuation of pCD in breast cancer cells MDA-MB-231 was achieved by using a plasmid vector-based shRNA system. Pronounced suppression of pCD expression was accompanied by a significant reduction in invasion and proliferation of MDA-MB-231 cells stably transfected with functional shRNA. Importantly, in the athymic nude mice model, downregulation of pCD in breast cancer cells significantly reduced their metastatic potential. In addition, we observed a reduction in Cdc42 and NF-κB2 expression in MDA-MB-231 cells with decreased pCD expression. When combined, our in vitro and in vivo experiments demonstrate that targeting pCD through RNAi technology represents a potential therapeutic tool for developing a therapy against breast cancer.

Purification and crystallization of human cathepsin D.

The two-chain form of human cathepsin D was purified from human spleen with a method utilizing an ion exchange chromatography step prior to the pepstatin affinity column normally used to purify aspartic proteases. The protein was crystallized from 21% polyethylene glycol 8000 at pH 4.0 using the hanging drop vapour diffusion method. Small crystals were used as seeds to grow crystals suitable for X-ray data collection. The crystals diffract to a resolution of 3.2 A and have space group P2(1)2(1)2(1) with unit cell dimensions a = 59.9 A, b = 99.6 A, c = 133.6 A. There are two molecules in the asymmetric unit.

Human Procathepsin D: Three-Dimensional Model and Isolation

Human procathepsin D was isolated from medium of human breast cancer cell line ZR-75-1 potentiated with estrogen. The isolation involved both immunoaffinity chromatography and ion-exchange chromatography. The affinity chromatography employed polyclonal antibodies raised against a synthetic activation peptide of human cathepsin D. We have started preliminary crystallization trials using the isolated material. A model of human procathepsin D was also built using coordinates of human cathepsin D and pig pepsinogen. The model aids understanding of multiple roles played by activation peptides of aspartic proteinases and will be used as a starting model for molecular replacement.

Procathepsin D Involvement in Chemoresistance of Cancer Cells

Background: The role of pCD in cancer has been studied for a long time. We have focused on the hypothesis that increased expression and/or secretion of pCD in cancer cells causes increased chemoresistance to apoptosis inducing molecules. Aim: The aim was to evaluate the effects of pCD expression/release on chemoresistance. Materials and Methods: We tested the LC50 values for various transfectants of breast cancer cell line MDA-MB-231 as well as effects of exogenous additions of pCD, its mutants, pepstatine, antibodies, and Brefeldin on the resistance. Results: We found that pCD levels can be correlated with chemoresistance, the pro-resistant activity seems to be localized outside the cells, proteolytic activity is not involved, and PI3-Akt signaling has an important role in antiapoptotic effects of pCD. Conclusion: We can conclude that overexpression of pCD has strong influence on increased resistance of tumor cells. This could, in fact, be an important contribution in the possible use of pCD level determination for prognostic and/or therapeutic purposes.