ABSTRACT
Cadmium (Cd) is a malleable element with odorless, tasteless characteristics that occurs naturally in the earth's crust, underground water, and soil. The most common reasons for the anthropological release of Cd to the environment include industrial metal mining, smelting, battery manufacturing, fertilizer production, and cigarette smoking. Cadmium-containing products may enter the environment as soluble salts, vapor, or particle forms that accumulate in food, soil, water, and air. Several epidemiological studies have highlighted the association between Cd exposure and adverse health outcomes, especially renal toxicity, and the impact of Cd exposure on the development and progression of carcinogenesis. Also highlighted is the evidence for early-life and even maternal exposure to Cd leading to devastating health outcomes, especially the risk of cancer development in adulthood. Several mechanisms have been proposed to explain how Cd mediates carcinogenic transformation, including epigenetic alteration, DNA methylation, histone posttranslational modification, dysregulated non-coding RNA, DNA damage in the form of DNA mutation, strand breaks, and chromosomal abnormalities with double-strand break representing the most common DNA form of damage. Cd induces an indirect genotoxic effect by reducing p53's DNA binding activity, eventually impairing DNA repair, inducing downregulation in the expression of DNA repair genes, which might result in carcinogenic transformation, enhancing lipid peroxidation or evasion of antioxidant interference such as catalase, superoxide dismutase, and glutathione. Moreover, Cd mediates apoptosis evasion, autophagy activation, and survival mechanisms. In this review, we decipher the role of Cd mediating carcinogenic transformation in different models and highlight the interaction between various mechanisms. We also discuss diagnostic markers, therapeutic interventions, and future perspectives.
ABSTRACT
OBJECTIVES: Prostate cancer (PCa) is the most commonly diagnosed cancer and the second leading cause of cancer death in men in the USA. Photodynamic therapy (PDT) is a state-of-the-art treatment that combines high selectivity with minor side effects. Pheophorbide-a (Pheo) is a natural pigment with a photosensitizer property. Our study delved into the impact of Pheo alone or Pheo-PDT combination on the androgen-independent metastatic prostate cancer (AIPC) cell lines DU-145 and C4-2. Furthermore, an in-depth examination has been conducted on the photocytotoxicity mechanism of Pheo-PDT in these specific cell lines. METHODS: In vitro studies were conducted using the AIPC cell lines. DU-145 and C4-2 cells were treated with Pheo at different concentrations for 60 min alone, or Pheo treatment followed by exposure to 670 nm illumination (60 mW/cm2 in 88 s pulses), producing 5 J/cm2 via portable light-emitting diode. KEY FINDINGS: Our results show that Pheo-PDT substantially inhibits cell viability, anchorage-independent growth, and migration capacities and induces autophagy and apoptosis via the over-production of reactive oxygen species that mediates endoplasmic reticulum stress in AIPC cell lines. CONCLUSIONS: Our study highlights the potential benefits of Pheo-PDT in metastatic hormone-insensitive PCa cell lines. It paves the way for treating localized and locally advanced PCa as a possible candidate for castration-resistant prostate cancer.
