Altered Blood and Brain Expression of Inflammation and Redox Genes in Alzheimer's Disease, Common to APPV717I × TAUP301L Mice and Patients.

Despite intensive research, the pathophysiology of Alzheimer's disease (AD) is still not fully understood, and currently there are no effective treatments. Therefore, there is an unmet need for reliable biomarkers and animal models of AD to develop innovative therapeutic strategies addressing early pathologic events such as neuroinflammation and redox disturbances. The study aims to identify inflammatory and redox dysregulations in the context of AD-specific neuronal cell death and DNA damage, using the APPV717I× TAUP301L (AT) mouse model of AD. The expression of 84 inflammatory and 84 redox genes in the hippocampus and peripheral blood of double transgenic AT mice was evaluated against age-matched controls. A distinctive gene expression profile in the hippocampus and the blood of AT mice was identified, addressing DNA damage, apoptosis and thrombosis, complemented by inflammatory factors and receptors, along with ROS producers and antioxidants. Gene expression dysregulations that are common to AT mice and AD patients guided the final selection of candidate biomarkers. The identified inflammation and redox genes, common to AD patients and AT mice, might be valuable candidate biomarkers for preclinical drug development that could be readily translated to clinical trials.

Oxidative stress in hepatitis C virus-human immunodeficiency virus co-infected patients.

INTRODUCTION AND OBJECTIVES: Human immunodeficiency virus (HIV) and hepatitis C virus (HCV) co-infection generates sustained inflammation with increased reactive oxygen species production. The pathogenic impact of systemic oxidative stress is known to influence drug treatment and follow-up. The aim of this case-control study was to compare the redox status in HCV-HIV co-infected with respect to HIV-infected individuals and to explore the relation between redox and HIV follow-up variables. PATIENTS OR MATERIALS AND METHODS: Blood samples were drawn from 330 individuals divided into three groups: HIV, HCV-HIV and presumable healthy subjects. Redox, hematological, hemochemical, immunologic and virological indexes were determined. RESULTS: Both HIV groups had significant differences in global indexes of damage and antioxidant status (p<0.05) with respect to the supposedly healthy individual group. HCV-HIV group showed a significantly higher damage (total hydroperoxide and advanced oxidation protein products) compared to the control and HIV groups (p<0.05). The overall modification of the redox indexes showed that 72% of individuals with simultaneous detrimental differences were related to HCV-HIV condition. CONCLUSIONS: These results corroborate that oxidative stress occurs in the HIV condition and also during HCV-HIV co-infection, with different molecular changes of follow-up indexes. Redox indexes diagnosis should be considered in early diagnosis and treatment of HCV-HIV co-infection.

Telomerase inhibitors induce mitochondrial oxidation and DNA damage-dependent cell death rescued by Bcl-2/Bcl-xL.

BACKGROUND: Reactivation of telomerase is a hallmark of cancer and the majority of cancers over-express telomerase. Telomerase-dependent telomere length maintenance confers immortality to cancer cells. However, telomere length-independent cell survival functions of telomerase also play a critical role in tumorigenesis. Multiple telomerase inhibitors have been developed as therapeutics and include anti-sense oligonucleotides, telomerase RNA component targeting agents, chemical inhibitors of telomerase, small molecule inhibitors of hTERT, and telomerase vaccine. In general, telomerase inhibitors affect cell proliferation and survival of cells depending on the telomere length reduction, culminating in replicative senescence or cell death by crisis. However, most telomerase inhibitors kill cancer cells prior to significant reduction in telomere length, suggesting telomere length independent role of telomerase in early telomere dysfunction-dependent cell death. METHODS: In this study, we explored the mechanism of cell death induced by three prominent telomerase inhibitors utilizing a series of genetically encoded sensor cells including redox and DNA damage sensor cells. RESULTS: We report that telomerase inhibitors induce early cell cycle inhibition, followed by redox alterations at cytosol and mitochondria. Massive mitochondrial oxidation and DNA damage induce classical cell death involving mitochondrial transmembrane potential loss and mitochondrial permeabilization. Real-time imaging of the progression of mitochondrial oxidation revealed that treated cells undergo a biphasic mitochondrial redox alteration during telomerase inhibition, emphasizing the potential role of telomerase in the redox regulation at mitochondria. Additionally, silencing of hTERT confirmed its predominant role in maintaining mitochondrial redox homeostasis. Interestingly, the study also demonstrated that anti-apoptotic Bcl-2 family proteins still confer protection against cell death induced by telomerase inhibitors. CONCLUSION: The study demonstrates that redox alterations and DNA damage contribute to early cell death by telomerase inhibitors and anti-apoptotic Bcl-2 family proteins confer protection from cell death by their ability to safeguard mitochondria from oxidation damage.

Overexpression of NAD(P)H:quinone oxidoreductase 1 (NQO1) and genomic gain of the NQO1 locus modulates breast cancer cell sensitivity to quinones.

AIMS: Alterations in the expression of antioxidant enzymes are associated with changes in cancer cell sensitivity to chemotherapeutic drugs (menadione and ß-lapachone). Mechanisms of acquisition of resistance to pro-oxidant drugs were investigated using a model of oxidative stress-resistant MCF-7 breast cancer cells (Resox cells). MAIN METHODS: FISH experiments were performed in tumor biopsy and breast cancer cells to characterize the pattern of the NQO1 gene. SNP-arrays were conducted to detect chromosomal imbalances. Finally, the importance of NQO1 overexpression in the putative acquisition of either drug resistance or an increased sensitivity to quinones by cancer cells was investigated by immunoblotting and cytotoxicity assays. KEY FINDINGS: Genomic gain of the chromosomal band 16q22 was detected in Resox cells compared to parental breast cancer MCF-7 cells and normal human mammary epithelial 250MK cells. This genomic gain was associated with amplification of the NQO1 gene in one tumor biopsy as well as in breast cancer cell lines. Using different breast cell models, we found that NQO1 overexpression was a main determinant for a potential chemotherapy resistance or an increased sensitivity to quinone-bearing compounds. SIGNIFICANCE: Because NQO1 is frequently modified in tumors at genomic and transcriptomic levels, the impact of NQO1 modulation on breast cancer cell sensitivity places NQO1 as a potential link between cancer redox alterations and resistance to chemotherapy. Thus, the NQO1 gene copy number and NQO1 activity should be considered when quinone-bearing molecules are being utilized as potential drugs against breast tumors.