There is a complete lack of highly sensitive and specific biomarkers for early pancreatic ductal adenocarcinoma (PDAC) diagnosis, limiting multi-modal therapeutic options. Mitochondrial DNA (mtDNA) is an excellent resource for biomarker discovery because of its high copy number and increased mutational frequency in cancer cells. We examined if mtDNA mutations can be detected in circulating extracellular vesicles (EVs) of PDAC patients and used for discerning between cancer and non-cancer subjects. A greater yield of circulating EVs (~ 1.4 fold; p = 0.002) was obtained in PDAC patients (n = 20) than non-cancer (NC) individuals (n = 10). PDAC-EVs contained a higher quantity of total DNA (~ 5.5 folds; p = 0.0001) than NC-EVs and had greater enrichment of mtDNA (~ 14.02-fold; p = 0.0001). PDAC-EVs also had higher levels of cardiolipin (a mitochondrial inner-membrane phospholipid), suggestive of their mitochondrial origin. All mtDNA mutations in PDAC-EVs were unique and frequency was remarkably higher. Most mtDNA mutations (41.5%) in PDAC-EVs were in the respiratory complex-I (RCI) (ND1-ND6), followed by the RCIII gene (CYTB; 11.2%). Among the non-coding genes, D-Loop and RNR2 exhibited the most mutations (15.2% each). Altogether, our study establishes, for the first time, that mtDNA mutations can be detected in circulating EVs and potentially serve as a tool for reliable PDAC diagnosis.
A novel class of bifunctional molecules
was synthesized integrating
acridine (Ac) and redox-active naphthalenediimide (NDI) scaffolds
directly and through a flexible linker (en). We evaluated in vitro
antiplasmodial activity, physicochemical properties, and a possible
mode of action. Theoretical studies suggested electronic segmentation
between the electron-rich Ac and electron-deficient NDI scaffolds.
Orthogonal Ac–NDI molecules showed activities in the micromolar
to submicromolar range against a chloroquine (CQ)-sensitive strain
of human malaria pathogen Plasmodium falciparum (maximum activity, IC50: 0.419 μM). The flexible
Ac–en–NDI molecules were most potent and showed activity
in the nanomolar range against both CQ-sensitive (with most effective
compounds, IC50: 3.65 and 4.33 nM) as well as CQ-resistant
(with most effective compounds, IC50: 52.20 and 28.53 nM)
strains of P. falciparum. Significantly,
with CQ-resistant strains, the activity of the most effective compounds
was 1 order of magnitude better than that of standard drug CQ. Ac–en–NDI-conjugated
molecules were significantly more potent than the individual NDI and
Ac-based molecules. The structure–activity relationship (SAR)
suggests that the flexible spacer (en) linking the Ac and NDI scaffolds
plays a vital role in exhibiting improved potency. None of the molecules
triggered hemolysis in culture, and the most potent compounds did
not show cytotoxicity in vitro against mammalian fibroblast NIH3T3
cells at their respective IC50 values. The other significant
outcome of this work is that some of the investigated molecules have
the potential to affect multiple processes in the parasite including
the hemozoin formation in digestive vacuoles (DVs), mitochondrial
membrane potential, and the redox homeostasis of the parasite.
Mitochondria are pivotal organelles that govern cellular energy production through the oxidative phosphorylation system utilizing five respiratory complexes. In addition, mitochondria also contribute to various critical signaling pathways including apoptosis, damage-associated molecular patterns, calcium homeostasis, lipid, and amino acid biosynthesis. Among these diverse functions, the energy
Hyaluronan-binding protein 1 (HABP1), a multi-compartmental, multi-functional protein has a wide range of functions, which can be attributed to its ability to associate with a variety of cellular ligands. Earlier we have reported that HABP1 overexpression in rat normal fibroblasts (F-HABP07) shows chronic generation of reactive oxygen species (ROS), induction of autophagy, and apoptosis. However, a significant proportion of cells remained viable after the majority went through apoptosis from 60 to 72 h. In this study, an attempt has been made to delineate the cellular events in the declined population of surviving cells. It has been elucidated here that, these cells at later time points of growth, that is, 72 and 84 h, not only appeared to shrink but also are devoid of autophagic vacuoles and displayed polyploidy. F-HABP07 cells exhibited an altered cytoskeletal structure from their parental cell line F111, assumed to be caused upon inhibition of actin polymerization and decrease in IQ motif-containing GTPase activating protein 1 (IQGAP1), a key protein associated with maintenance of cytoskeletal integrity. Enhanced expression and nuclear localization of AKT observed in F-HABP07 cells appears to be contributing toward the maintenance of high ROS levels in these cells and also potentially modulating the IQGAP1 activity. These observations, in fact have been considered to result in sustained DNA damage, which then leads to increased expression of p53 and activation of p21 and carry out the cellular events responsible for senescence. Subsequent assessment of the presence of positive β-gal staining and enhanced expression of p16 INK4a in F-HABP07, confirmed that HABP1 overexpressing fibroblasts undergo senescence.
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