Photodynamic therapy (PDT) has been proven to be a minimally invasive and effective therapeutic strategy for cancer treatment. It can be used alone or as a complement to conventional cancer treatments, such as surgical debulking and chemotherapy. The mitochondrion is an attractive target for developing novel PDT agents, as it produces energy for cells and regulates apoptosis. Current strategy of mitochondria targeting is mainly focused on utilizing cationic photosensitizers that bind to the negatively charged mitochondria membrane. However, such an approach is lack of selectivity of tumor cells. To minimize the damage on healthy tissues and improve therapeutic efficacy, an alternative targeting strategy with high tumor specificity is in critical need. Herein, we report a tumor mitochondria-specific PDT agent, IR700DX-6T, which targets the 18 kDa mitochondrial translocator protein (TSPO). IR700DX-6T induced apoptotic cell death in TSPO-positive breast cancer cells (MDA-MB-231) but not TSPO-negative breast cancer cells (MCF-7). In vivo PDT study suggested that IR700DX-6T-mediated PDT significantly inhibited the growth of MDA-MB-231 tumors in a target-specific manner. These combined data suggest that this new TSPO-targeted photosensitizer has great potential in cancer treatment.
BackgroundThe p53 tumour suppressor protein is a transcription factor that prevents oncogenic progression by activating the expression of apoptosis and cell-cycle arrest genes in stressed cells. The stability of p53 is tightly regulated by ubiquitin-dependent degradation, driven mainly by its negative regulators ubiquitin ligase MDM2.Principal FindingsIn this study, we have identified OTUD5 as a DUB that interacts with and deubiquitinates p53. OTUD5 forms a direct complex with p53 and controls level of ubiquitination. The function of OTUD5 is required to allow the rapid activation of p53-dependent transcription and a p53-dependent apoptosis in response to DNA damage stress.ConclusionsAs a novel deubiquitinating enzyme for p53, OTUD5 is required for the stabilization and the activation of a p53 response.
Connexin 43 (Cx43), known to be the main protein building blocks of gap junctions and hemichannels in mammalian heart, plays an important role in cardiocytes proliferation. Gap junctional intercellular communication has been suggested to be necessary for cellular proliferation and differentiation. However, the effect of Cx43 hemichannel on cardiocytes proliferation and the mechanism remain unclear. In this study, rat heart cell line H9c2 was used. The Cx43 location, the proliferation rate and hemichannel activity of H9c2 cells and Wnt-3a
Mortalin is frequently overexpressed in human malignancies. Previous studies have suggested that mortalin contributes to ovarian cancer development and progression, but further investigation is warranted. The aim of this study is to elucidate the mechanism of mortalin in ovarian cancer development and progression. In this study, lentivirus‐delivered mortalin short hairpin RNA (shRNA) was used to knockdown mortalin expression in A2780 and A2780/cis ovarian cancer cell lines, and lentiviral mortalin‐pLVX‐AcGFP was used to generate mortalin‐overexpressing cell lines. The results demonstrated that decreased mortalin expression reduced ovarian cancer cell proliferation, colony formation, migration and invasion by Cell Counting Kit‐8 assay, colony formation assay, wounding healing assay and Transwell cell invasion assay, respectively. Flow cytometry results suggested that mortalin promotes the G1 transition, leading to faster restoration of a normal cell‐cycle distribution. Cell‐cycle proteins, including C‐myc and Cyclin‐D1, significantly increased, and Cyclin‐B1 remarkably decreased upon mortalin down‐regulation. Western blot analysis showed that mortalin knockdown significantly decreased p‐c‐Raf and phospho‐extracellular–regulated protein kinases (p‐ERK1/2) pathways but not the Jun N‐terminal kinase pathway, whereas mortalin overexpression had the opposite effect. Taken together, these results indicate that mortalin is an oncogenic factor, and mitogen‐activated protein kinase‐ERK signalling pathway activation by mortalin may contribute to ovarian cancer development and progression.
Molybdenum disulfide (MoS 2 ), a new type of transition metal dichalcogenides nanomaterial, has attracted significant attention lately in the biomedical industry, with many promising applications such as photothermal-triggered drug delivery agent for cancer. Accompanied with these promising applications are the growing concerns about their potential biocompatibility. Here, we use all-atom molecular dynamics simulations to investigate the interaction of a MoS 2 nanotube with YAP65 WW domain, a mostly antiparallel β-sheet model protein widely used in molecular simulations. We find that YAP65 loses most of its secondary and tertiary structures within a few hundred nanoseconds after adsorbing onto the MoS 2 nanotube surface, indicating that the MoS 2 nanotube displays significant structural damage to YAP65. The strong dispersion interactions, especially from those "signature" aromatic residues (Tyr28 and Trp39), help drive YAP65 adsorption onto the nanotube surface, which thus breaks the native beta strand hydrogen bond network and subsequently destroys the secondary and tertiary structures. These findings might shed new light onto the potential nanotoxicity of MoS 2 nanomaterial and its underlying molecular mechanism.
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