Evaluating the iron chelator function of sirtinol in non-small cell lung cancer.

A distinctive feature of cancer is the upregulation of sirtuin proteins. Sirtuins are class III NAD+-dependent deacetylases involved in cellular processes such as proliferation and protection against oxidative stress. SIRTs 1 and 2 are also overexpressed in several types of cancers including non-small cell lung cancer (NSCLC). Sirtinol, a sirtuin (SIRT) 1 and 2 specific inhibitor, is a recent anti-cancer agent that is cytotoxic against several types of cancers including NSCLC. Thus, sirtuins 1 and 2 represent valuable targets for cancer therapy. Recent studies show that sirtinol functions as a tridentate iron chelator by binding Fe3+ with 3:1 stoichiometry. However, the biological consequences of this function remain unexplored. Consistent with preliminary literature, we show that sirtinol can deplete intracellular labile iron pools in both A549 and H1299 non-small cell lung cancer cells acutely. Interestingly, a temporal adaptive response occurs in A549 cells as sirtinol enhances transferrin receptor stability and represses ferritin heavy chain translation through impaired aconitase activity and apparent IRP1 activation. This effect was not observed in H1299 cells. Holo-transferrin supplementation significantly enhanced colony formation in A549 cells while increasing sirtinol toxicity. This effect was not observed in H1299 cells. The results highlight the fundamental genetic differences that may exist between H1299 and A549 cells and offer a novel mechanism of how sirtinol kills NSCLC cells.

Efficacy of the HSP70 inhibitor PET-16 in multiple myeloma.

Multiple myeloma (MM) is a common and largely incurable blood cancer for which new treatment options are needed, as resistance to current modalities is an issue. Additionally, because this tumor type often resides in a hypoxic niche of the bone marrow, new therapeutics that remain effective even under hypoxic conditions are sought. Because of the secretory nature of MM cells they are uniquely under proteotoxic stress, and we hypothesized that these tumor cells may alleviate this stress by upregulating the major stress-induced cytosolic form of the chaperone HSP70. In this work we test the efficacy of the HSP70 inhibitor PET-16 for MM. We show that MM cell lines express significant levels of HSP70, and further that inhibition of HSP70 causes decreased viability and apoptosis, along with proteotoxic stress, as assessed by the accumulation of poly-ubiquitylated proteins. Importantly, we show that growth of these tumor cells under hypoxic conditions has no effect on the ability of PET-16 to be cytotoxic. The HSP70 inhibitor PET-16 should thus be considered further for pre-clinical analyses of efficacy in MM.

High motility of triple-negative breast cancer cells is due to repression of plakoglobin gene by metastasis modulator protein SLUG.

One of highly pathogenic breast cancer cell types are the triple negative (negative in the expression of estrogen, progesterone, and ERBB2 receptors) breast cancer cells. These cells are highly motile and metastatic and are characterized by high levels of the metastasis regulator protein SLUG. Using isogenic breast cancer cell systems we have shown here that high motility of these cells is directly correlated with the levels of the SLUG in these cells. Because epithelial/mesenchymal cell motility is known to be negatively regulated by the catenin protein plakoglobin, we postulated that the transcriptional repressor protein SLUG increases the motility of the aggressive breast cancer cells through the knockdown of the transcription of the plakoglobin gene. We found that SLUG inhibits the expression of plakoglobin gene directly in these cells. Overexpression of SLUG in the SLUG-deficient cancer cells significantly decreased the levels of mRNA and protein of plakoglobin. On the contrary, knockdown of SLUG in SLUG-high cancer cells elevated the levels of plakoglobin. Blocking of SLUG function with a double-stranded DNA decoy that competes with the E2-box binding of SLUG also increased the levels of plakoglobin mRNA, protein, and promoter activity in the SLUG-high triple negative breast cancer cells. Overexpression of SLUG in the SLUG-deficient cells elevated the motility of these cells. Knockdown of plakoglobin in these low motility non-invasive breast cancer cells rearranged the actin filaments and increased the motility of these cells. Forced expression of plakoglobin in SLUG-high cells had the reverse effects on cellular motility. This study thus implicates SLUG-induced repression of plakoglobin as a motility determinant in highly disseminating breast cancer.

Mode of action of the retrogene product SNAI1P, a SNAIL homolog, in human breast cancer cells.

SNAI1P, a protein coded by a retrogene, is a member of the SNAI family of E2-box binding transcriptional repressors. To evaluate whether the mode of action of SNAI1P is similar to those of the other predominant members of the SNAI family, we studied its action on human claudin 7 (CLDN7) gene promoter which has seven E2-boxes. We over-expressed FLAG-tagged SNAI1P in MCF7 and MDA-MB-468 cells. SNAI1P inhibited the expression of CLDN7 in these recombinant cells. SNAI1P also inhibited cloned CLDN7 gene promoter activity in human breast cancer cells. ChIP assays revealed that SNAI1P is recruited on the CLDN7 gene promoter along with the co-repressor CtBP1 and the effector HDAC1. Treatment of the cells with trichostatin A, an inhibitor of HDAC1, abrogated the repressor activity of SNAI1P. These data suggest that SNAI1P inhibits CLDN7 gene promoter epigenetically in breast cancer cells through chromatin remodeling.

In vivo binding to and functional repression of the VDR gene promoter by SLUG in human breast cells.

The regulation of vitamin D receptor (VDR), a key mediator in the vitamin D pathway, in breast cancer etiology has long been of interest. We have shown here that the transcriptional repressor protein SLUG inhibits the expression of VDR in human breast cancer cells. To explore the possibility that SLUG regulates the VDR gene promoter, we cloned a 628bp fragment (-613 to +15) of the human VDR gene promoter. This region contains three E2-box sequences (CAGGTG/CACCTG), the classical binding site of SLUG. SLUG specifically inhibited VDR gene promoter activity. Chromatin-immunoprecipitation (ChIP) assays revealed that SLUG is recruited on the native VDR gene promoter along with the co-repressor protein CtBP1 and the effector protein HDAC1. These data suggests that SLUG binds to the E2-box sequences of the VDR gene promoter and recruits CtBP1 and HDAC1, which results in the inhibition of VDR gene expression by chromatin remodeling.

BRCA1 accumulates in the nucleus in response to hypoxia and TRAIL and enhances TRAIL-induced apoptosis in breast cancer cells.

A major contributing factor to the development of breast cancer is decreased functional expression of breast cancer susceptibility gene 1, BRCA1. Another key contributor to tumorigenesis is hypoxia. Here we show that hypoxia increased the nuclear localization of BRCA1 in MCF-7 and MDA-MB-468 human breast cancer cell lines without changing its steady-state expression level. Nuclear accumulation of BRCA1 was not evident in MCF-12A or HMEC (human mammary epithelial cell) nonmalignant mammary epithelial cells under the same conditions. Hypoxia also increased the cell surface expression of TRAIL on MDA-MB-468 cells. Neutralization of TRAIL precluded the hypoxia-induced accumulation of BRCA1 in the nucleus, whereas exogenously administered TRAIL mimicked the effect. Treatment of MDA-MB-468 cells with TRAIL resulted in a dose- and time-dependent increase in apoptosis. Furthermore, TRAIL-induced apoptosis in HCC1937 cells, which harbor a BRCA1 mutation, increased synergistically when wild-type BRCA1 was reconstituted in the cells, and downregulation of BRCA1 expression in MDA-MB-468 cells reduced the apoptotic response to TRAIL. These data provide a novel link between hypoxia, TRAIL and BRCA1, and suggest that this relationship may be especially relevant to the potential use of TRAIL as a chemotherapeutic agent.

Human SLUG does not directly bind to CtBP1.

SLUG is a transcriptional repressor protein implicated to have major role in the oncogenesis and metastasis of human breast cells. We previously have shown by chromatin immunoprecipitation assay that human SLUG (hSLUG) is co-localized with the co-repressor protein CtBP1 as bound to the BRCA2 gene silencer [M.K. Tripathi, S. Misra, S.V. Khedkar, N. Hamilton, C. Irvin-Wilson,, C. Sharan, L. Sealy, G. Chaudhuri, J. Biol. Chem. 280 (2005) 17163-17171]. hSLUG was predicted to be binding directly to CtBP1 because of an apparent presence of CtBP1 binding site in its amino acid sequences. Here, we provide evidence through yeast two-hybrid and in vitro co-immunoprecipitation analyses that hSLUG does not directly interacts with hCtBP1. This observation will help in the study of the mode of action of hSLUG in human cells.