80 research outputs found
Hypomethylation of MB-COMT promoter is a major risk factor for schizophrenia and bipolar disorder
The variability in phenotypic presentations and the lack of consistency of genetic associations in mental illnesses remain a major challenge in molecular psychiatry. Recently, it has become increasingly clear that altered promoter DNA methylation could play a critical role in mediating differential regulation of genes and in facilitating short-term adaptation in response to the environment. Here, we report the investigation of the differential activity of membrane-bound catechol-O-methyltransferase (MB - COMT) due to altered promoter methylation and the nature of the contribution of COMT Val158Met polymorphism as risk factors for schizophrenia and bipolar disorder by analyzing 115 post-mortem brain samples from the frontal lobe. These studies are the first to reveal that the MB - COMT promoter DNA is frequently hypomethylated in schizophrenia and bipolar disorder patients, compared with the controls (methylation rate: 26 and 29 versus 60; P = 0.004 and 0.008, respectively), particularly in the left frontal lobes (methylation rate: 29 and 30 versus 81; P = 0.003 and 0.002, respectively). Quantitative gene-expression analyses showed a corresponding increase in transcript levels of MB - COMT in schizophrenia and bipolar disorder patients compared with the controls (P = 0.02) with an accompanying inverse correlation between MB - COMT and DRD1 expression. Furthermore, there was a tendency for the enrichment of the Val allele of the COMT Val158Met polymorphism with MB - COMT hypomethylation in the patients. These findings suggest that MB - COMT over-expression due to promoter hypomethylation and/or hyperactive allele of COMT may increase dopamine degradation in the frontal lobe providing a molecular basis for the shared symptoms of schizophrenia and bipolar disorder. © Copyright 2006 Oxford University Press
Analysis of apoptosis methods recently used in Cancer Research and Cell Death & Disease publications
Apoptosis Deregulation and the Development of Cancer Multi-Drug Resistance
The ability of tumor cells to evade apoptosis is established as one of the hallmarks of cancer. The deregulation of apoptotic pathways conveys a survival advantage enabling cancer cells to develop multi-drug resistance (MDR), a complex tumor phenotype referring to concurrent resistance toward agents with different function and/or structure. Proteins implicated in the intrinsic pathway of apoptosis, including the Bcl-2 superfamily and Inhibitors of Apoptosis (IAP) family members, as well as their regulator, tumor suppressor p53, have been implicated in the development of MDR in many cancer types. The PI3K/AKT pathway is pivotal in promoting survival and proliferation and is often overactive in MDR tumors. In addition, the tumor microenvironment, particularly factors secreted by cancer-associated fibroblasts, can inhibit apoptosis in cancer cells and reduce the effectiveness of different anti-cancer drugs. In this review, we describe the main alterations that occur in apoptosis-and related pathways to promote MDR. We also summarize the main therapeutic approaches against resistant tumors, including agents targeting Bcl-2 family members, small molecule inhibitors against IAPs or AKT and agents of natural origin that may be used as monotherapy or in combination with conventional therapeutics. Finally, we highlight the potential of therapeutic exploitation of epigenetic modifications to reverse the MDR phenotype
Apoptosis Deregulation and the Development of Cancer Multi-Drug Resistance
Simple Summary Despite recent therapeutic advances against cancer, many
patients do not respond well or respond poorly, to treatment and develop
resistance to more than one anti-cancer drug, a term called multi-drug
resistance (MDR). One of the main factors that contribute to MDR is the
deregulation of apoptosis or programmed cell death. Herein, we describe
the major apoptotic pathways and discuss how pro-apoptotic and
anti-apoptotic proteins are modified in cancer cells to convey drug
resistance. We also focus on our current understanding related to the
interactions between survival and cell death pathways, as well as on
mechanisms underlying the balance shift towards cancer cell growth and
drug resistance. Moreover, we highlight the role of the tumor
microenvironment components in blocking apoptosis in MDR tumors, and we
discuss the significance and potential exploitation of epigenetic
modifications for cancer treatment. Finally, we summarize the current
and future therapeutic approaches for overcoming MDR. The ability of
tumor cells to evade apoptosis is established as one of the hallmarks of
cancer. The deregulation of apoptotic pathways conveys a survival
advantage enabling cancer cells to develop multi-drug resistance (MDR),
a complex tumor phenotype referring to concurrent resistance toward
agents with different function and/or structure. Proteins implicated in
the intrinsic pathway of apoptosis, including the Bcl-2 superfamily and
Inhibitors of Apoptosis (IAP) family members, as well as their
regulator, tumor suppressor p53, have been implicated in the development
of MDR in many cancer types. The PI3K/AKT pathway is pivotal in
promoting survival and proliferation and is often overactive in MDR
tumors. In addition, the tumor microenvironment, particularly factors
secreted by cancer-associated fibroblasts, can inhibit apoptosis in
cancer cells and reduce the effectiveness of different anti-cancer
drugs. In this review, we describe the main alterations that occur in
apoptosis-and related pathways to promote MDR. We also summarize the
main therapeutic approaches against resistant tumors, including agents
targeting Bcl-2 family members, small molecule inhibitors against IAPs
or AKT and agents of natural origin that may be used as monotherapy or
in combination with conventional therapeutics. Finally, we highlight the
potential of therapeutic exploitation of epigenetic modifications to
reverse the MDR phenotype
Multidrug-Resistant Bacteria on Healthcare Workers’ Uniforms in Hospitals and Long-Term Care Facilities in Cyprus
Healthcare workers’ (HCW) clothing has been shown to harbor multidrug-resistant bacteria (MDRB) and may contribute to transmission. The aim of this study was to evaluate presence of MDRB on HCW uniforms in Cyprus. A cross-sectional study was carried out in 9 hospital wards and 7 long-term care facilities (LTCFs) in Nicosia, Cyprus, from April–August 2019. Sampling of HCW uniform pockets was conducted at the end of the first shift. Personal hygiene and other habits were recorded during personal interviews. Among 140 sampled HCW (69 from hospitals, 71 from LTCFs), 37 MDRB were identified, including 16 vancomycin-resistant enterococci (VRE), 15 methicillin-resistant Staphylococcus aureus (MRSA), 5 extended spectrum b-lactamase (ESBL)-producing bacteria, and 1 carbapenem-resistant Acinetobacter baumannii. Presence of MDRB was higher in LTCFs compared to hospitals (p = 0.03). Higher MDRB rates in uniforms were noted in HCWs that worked <1 year (41.7% vs. 21.1%) and in HCWs that opted for home laundering (23.5% vs. 12.5%) or visited the toilet during shifts (38.1% vs. 20.2%). Our findings indicate that HCW uniforms harbor MDRB and relevant interventions may reduce transmission risk. We identified LTCFs as an important area for targeted measures. Additional factors associated with HCW practices, characteristics, and attire laundering practices represent areas for improvement, particularly in LTCFs. © 2021 by the authors. Licensee MDPI, Basel, Switzerland
Epigenetic dysregulation of HTR2A in the brain of patients with schizophrenia and bipolar disorder
Introduction: HTR2A gene has been the subject of numerous studies in psychiatric genetics because LSD, which resembles serotonin causes psychosis and atypical antipsychotic drugs target the HTR2A receptor. However, evidence for the role of HTR2A polymorphism(s) in schizophrenia (SCZ) and bipolar disorder (BD) has been elusive. We hypothesized that epigenetic dysregulation of HTR2A may be involved in psycho-pathogenesis and analyzed promoter DNA methylome and expression of HTR2A in SCZ, BD and control subjects. Method: DNA derived from post-mortem brains of patients with SCZ and BD and matched control subjects (each 35) were obtained from the Stanley Medical Research Institute. While bisulfite DNA sequencing was used to screen and quantify cytosine methylation in the HTR2A promoter, corresponding gene expression was analyzed by qRT-PCR. Results: We found strong evidence for epigenetic fine-tuning of HTR2A expression. In general, the expression of HTR2A in individuals carrying the C allele of T102C (or G allele of -1438A/G polymorphism) was higher than TT genotype. Interestingly, promoter DNA of HTR2A was hypermethylated at and around the -1438A/G polymorphic site, but was hypomethylated at and around T102C polymorphic site in SCZ and BD compared to the controls. Furthermore, epigenetic down-regulation of HTR2A was associated with early age of disease onset in SCZ and BD. Conclusion: Epigenetic dysregulation of HTR2A may contribute to SCZ, BD and earlier age of disease onset. Further research is required to delineate the dysregulation of other components of serotoninergic pathway to design new therapeutics based on the downstream effects of serotonin. © 2011 Elsevier B.V
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