Abstract
Cathepsin D (CD), the major intracellular aspartyl protease, is a mediator of IFN-γ and TNF-α induced apoptosis. Using subtractive hybridization screening we isolated CD as an upregulated transcript in PA1 human ovarian cancer cells undergoing adriamycin-induced apoptosis. CD mRNA levels increased in wild-type p53-expressing PA1, ML1 leukemia and U1752 lung cancer cells but not in mutant p53-expressing cells following adriamycin exposure. Overexpression of CD inhibited growth of colon, liver, and ovarian cancer cells. CD protein expression was increased by exposure of ML1 cells to etoposide, adriamycin or γ-radiation. Inhibition of CD protease with Pepstatin A suppressed p53-dependent apoptosis in lymphoid cells, suggesting a possible role for CD in p53-dependent cell death. CD−/− fibroblasts were found to be more resistant to killing by adriamycin and etoposide, as compared to CD+/+ cells. Two p53 DNA-binding sites located in the CD-promoter specifically bound to p53 protein in vitro and appeared to mediate transactivation of a CD-promoter luciferase-reporter during p53-dependent apoptosis. These observations link CD protease to p53-dependent tumor suppression and chemosensitivity.
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Change history
05 February 2025
The original online version of this article was revised:Following the publication of this article, a duplication was noted in Figure 1 due to incorrect labelling during figure assembly (70B was incorrectly labeled as 170B in Figure 1 and we inadvertently used the same loading control of 70A for 70B). The raw data has been provided and the corrected figure and figure legend are shown below. This correction does not impact the interpretation of the results and conclusions of the paper.Corrected legend for Figure 1: Induction of gene expression following exposure of PA1 cells to adriamycin. Probes 8A, 15A, 48A, 70A, and 70B were obtained from screening a cDNA library of PA1 cells following 10 h treatment (-/+ Adriamycin) following use of a subtractive hybridization technique as described in Materials and methods. Clone 70B is Cathepsin D (CD), whereas clones 8A, 15A, 48A and 70A are novel uncharacterized genes. The p21 clone is not shown. An ethidium bromide stain of the total RNA (10 mg/lane) is shown in the lower panel to demonstrate equivalent loading. The sizes of mRNA are indicated by arrows, and the positions of ribosomal RNAs, 28S and 18S, are shown by bars.
11 February 2025
A Correction to this paper has been published: https://doi.org/10.1038/s41388-025-03291-6
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The original online version of this article was revised:Following the publication of this article, a duplication was noted in Figure 1 due to incorrect labelling during figure assembly (70B was incorrectly labeled as 170B in Figure 1 and we inadvertently used the same loading control of 70A for 70B). The raw data has been provided and the corrected figure and figure legend are shown below. This correction does not impact the interpretation of the results and conclusions of the paper.Corrected legend for Figure 1: Induction of gene expression following exposure of PA1 cells to adriamycin. Probes 8A, 15A, 48A, 70A, and 70B were obtained from screening a cDNA library of PA1 cells following 10 h treatment (-/+ Adriamycin) following use of a subtractive hybridization technique as described in Materials and methods. Clone 70B is Cathepsin D (CD), whereas clones 8A, 15A, 48A and 70A are novel uncharacterized genes. The p21 clone is not shown. An ethidium bromide stain of the total RNA (10 mg/lane) is shown in the lower panel to demonstrate equivalent loading. The sizes of mRNA are indicated by arrows, and the positions of ribosomal RNAs, 28S and 18S, are shown by bars.
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Wu, G., Saftig, P., Peters, C. et al. Potential role for Cathepsin D in p53-dependent tumor suppression and chemosensitivity. Oncogene 16, 2177–2183 (1998). https://doi.org/10.1038/sj.onc.1201755
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DOI: https://doi.org/10.1038/sj.onc.1201755
