Cadmium (Cd) is a toxic, heavy industrial metal that poses serious environmental health hazards to both humans and wildlife. Lately, Cd and Cd containing compounds have been classified as known human carcinogens and epidemiological data show causal associations with prostate, breast and lung cancer. The molecular mechanisms involved in Cd-induced carcinogenesis are poorly understood and are only now beginning to be elucidated. The effects of chronic exposure to Cd have recently become of great interest due to the development of malignancies in Cd-induced tumorigenesis in animal. Briefly, various in vitro studies demonstrate that Cd can act as a mitogen, stimulate cell proliferation, inhibit apoptosis and DNA repair, and induce carcinogenesis in several mammalian tissues and organs. Thus, the various mechanisms involved in chronic Cd exposure and malignant transformations warrant further investigation. In this review, we will focus on recent evidence of various leading general and tissue specific molecular mechanisms that follow chronic exposure to Cd in prostate, breast and lung transformed malignancies. In addition, this review considers less defined mechanisms such as epigenetic modification and autophagy, which are thought to play a role in the development of Cd-induced malignant transformation.
Cell cycle deregulation is strongly associated with the pathogenesis of prostate cancer (CaP). Clinical trials of cell cycle regulators that target either the G0/G1 or G2/M phase to inhibit the growth of cancers including CaP are increasing. In this study, we determined the cell-cycle regulatory potential of the herbal molecule Withaferin-A (WA) on CaP cells. WA induced irreversible G2/M arrest in both CaP cell lines (PC3 and DU145) for 48 h. The G2/M arrest was accompanied by upregulation of phosphorylated Wee1, phophorylated histone H3, p21 and Aurora-B. On the other hand, downregulation of cyclins (E2, A, and B1) and phorphorylated Cdc2 (Tyr15) was observed in WA-treated CaP cells. In addition, decreased levels of phosphorylated Chk1 (Ser345) and Chk2 (Thr68) were evident in WA-treated CaP cells. Our results suggest that activation of Cdc2 leads to accumulation in M-phase, with abnormal duplication, and initiation of mitotic catastrophe that results in cell death. In conclusion, these results clearly highlight the potential of WA as a regulator of the G2/M phase of the cell cycle and as a therapeutic agent for CaP.
Background:Autophagy is a catabolic process that has a vital role in cancer progression and treatment. Current chemotherapeutic agents, which target autophagy, result in growth inhibition in many cancer types. In this study, we examined the role of autophagy in breast cancer (BCa) patients as well as BCa cell lines.Methods:Tissue microarray was used to detect the expression of an autophagy marker, LC3B in BCa patients (normal/hyperplasia=8; grade-I=15, grade-II=84, and grade-III=27) and BCa cell lines. To modulate the activation of autophagy, we used novel herbal compound nimocinol acetate (NA) in BCa cell lines and the anticancer activity was measured by phenotypic and molecular analysis.Results:LC3B is highly expressed in tumours as compared with normal tissues. Activation of LC3B in NA-treated BCa (MCF-7 and MDA-MB-231) cells was evident as compared with other autophagy makers. Further, our results confirmed that NA-transcriptionally regulates LC3B (as confirmed by mRNA levels and reporter assay), which resulted in the formation of acidic autophagy vesicles and autolysosomes in BCa cells. Nimocinol acetate inhibited mTOR-mediated pro-survival signalling that resulted in inhibition of growth in BCa cells without affecting normal breast epithelial cells. Downregulation of LC3B expression by siRNA significantly inhibited the anticancer effects of NA in BCa cells.Conclusions:Together, our results suggest that LC3B is highly expressed in BCa tissues and increasing the threshold of LC3B activation dictates the pro-apoptotic function, which in turn, suppresses the growth of BCa cells. Nimocinol acetate could be a potential agent for treatment of BCa.
Previous studies have demonstrated that there are persistent changes in dopamine systems following withdrawal from methamphetamine (METH). This study examined changes in striatal dopamine transporter (DAT), tyrosine hydroxylase (TH) and dopamine receptor 2 (D2) 72 hours after withdrawal from METH intravenous self-administration (IVSA). Rats were given limited (1 hour) or extended (6 hour) access to METH IVSA (0.05 mg/kg/0.1 ml infusion) for 22 days. Controls did not receive METH IVSA. The rats given extended access to IVSA displayed higher METH intake during the first hour of drug access compared to rats given limited access. Extended access to METH also produced a concomitant increase in striatal DAT levels relative to drug-naïve controls. There were no changes in TH or D2 levels across groups. Previous studies have reported a decrease in striatal DAT levels during protracted periods (>7 days) of withdrawal from METH IVSA. This study extends previous work by showing an increase in striatal DAT protein expression during an earlier time point of withdrawal from this drug. These results are an important first step toward understanding the dynamic changes in dopamine systems that occur during different time points of withdrawal from METH IVSA.
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