Rather than methylation of the miR-126 host gene EGFL7, epigenetic mechanism involving DNMT1- and PARP1-mediated chromatin remodeling was found to upregulate of miR-126 in asbestos-exposed cells, while miR-126 was downregulated in malignant cells. Analysis of MM tissue supported the role of PARP1 in miR-126 regulation. Therefore, activation of the EGFR pathway and the PARP1-mediated epigenetic regulation both play a role in asbestos-induced miRNA expression, associated with in asbestos-induced carcinogenesis and tumor progression. Schizophrenia-associated anomalies in gene expression in postmortem brain can be attributed to a combination of genetic and environmental influences. Given the small effect size of common variants, it is likely that we may only see the combined impact of some of these at the pathway level in small postmortem studies. At the gene level, however, there may be more impact from common environmental exposures mediated by influential epigenomic modifiers, such as microRNA (miRNA). We hypothesise that dysregulation of miRNAs and their alteration of gene expression have significant implications in the pathophysiology of schizophrenia. In this study, we integrate changes in cortical gene and miRNA expression to identify regulatory interactions and networks associated with the disorder. Gene expression analysis in post-mortem prefrontal dorsolateral cortex (BA 46) (n = 74 matched pairs of schizophrenia, schizoaffective, and control samples) was integrated with miRNA expression in the same cohort to identify gene-miRNA regulatory networks. A significant gene-miRNA interaction network was identified, including miR-92a, miR-495, and miR-134, which converged with differentially expressed genes in pathways involved in neurodevelopment and oligodendrocyte function. The capacity for miRNA to directly regulate gene expression through respective binding sites in BCL11A, PLP1, and SYT11 was also confirmed to support the biological relevance of this integrated network model. The observations in this study support the hypothesis that miRNA dysregulation is an important factor in the complex pathophysiology of schizophrenia. Proper fluid balance is critical for life. Learning plays an important role in shaping the appetitive behaviors required for drinking. Children often forego drinking plain water and instead consume beverages such as milk or juice. What effect this may have on adult thirst responses remains an open question. To model aspects of the human condition, we bred Sprague-Dawley rats and prevented the pups from obtaining fluid other than from nursing. Pups were weaned onto either tap water, 5% sucrose, or 0.45% saline, and given access to only that fluid for at least 7 weeks. We then measured intake of water or sucrose/saline in one-bottle tests after mild hypertonic saline (HS) injection, or overnight fluid deprivation, and in two-bottle tests after HS injection while rats were maintained on their respective fluids, and after all subjects had only water to drink for a week. We found that sucrose- and saline-maintained rats drank less water than did controls after the HS challenge. After overnight fluid deprivation, rats maintained on saline drank less water and more saline, but there was no difference in intake between water-maintained and sucrose-maintained rats. Differences in licking patterns, including more licks/burst for sucrose by sucrose-maintained rats were detected, even in cases when total intake was not different. These data provide evidence that adult rat water intake can be reduced by exclusively drinking sucrose or saline early in life. OBJECTIVES Monocyte-derived macrophages, as the predominant immune cell type that is increased in inflamed synovium, play a vital role during knee osteoarthritis (KOA) progression. However, the mechanisms underlying the recruitment of circulating monocytes to osteoarthritic knees remain uncertain. Based on previous data obtained from plasma, we investigated the contributions of CCL2, CCL3, CCL4 and their cognate receptors in circulating monocyte chemotaxis and KOA development. selleck screening library METHODS Using flow cytometry staining, we characterized the expression patterns of the chemokine receptors in CD14+CD16- circulating monocytes from KOA patients and healthy volunteers. The expression of chemokines in synovial fluids, synovium and cartilage was investigated in KOA patients and in patients without KOA. The role of chemokines and their cognate receptors in the chemotaxis of CD14+CD16- circulating monocytes was assessed using chemokine neutralizing antibodies (NA) and receptor antagonists in vitro and in vivo. RESULTS The majority of CD14+CD16- circulating monocytes were CCR1-and CCR2-positive. CCL2, CCL3 and CCL4 were elevated in synovial fluid of KOA patients compared with that of controls. The most likely source of these chemokines is inflamed synovium and cartilage in the osteoarthritic knee. The CCL3/CCR1 and CCL2/CCR2 axes showed substantial ability to recruit CD14+CD16- monocytes in transwell assays. Similar results were confirmed in a mouse model of collagenase-induced KOA (CIA) in which blocking either the CCL3/CCR1 axis or the CCL2/CCR2 axis reduced synovial hyperplasia and F4/80+ macrophage infiltration. CONCLUSIONS Our findings suggested that, analogous to the CCL2/CCR2 axis, CCL3 produced in osteoarthritic knees can chemoattract circulating monocytes to the inflamed synovium through CCR1. The CRISPR-Cas13b system is a recently identified Class 2, RNA-targeting CRISPR-Cas system. The system has been repurposed to achieve robust mRNA knockdown and precise RNA-editing in mammalian cells. While the CRISPR-Cas13b system has become a powerful tool for nucleic acids manipulation, the mechanisms of the system are still not fully understood. Cas13b endonucleases from different bacterial species show poor overall sequence homologies, suggesting that structural (and probably functional) diversities may exist. It is therefore important to study CRISPR-Cas13b cases from different bacterial species. Here we report the expression, purification, and initial characterization of a Cas13b endonuclease that is associated with the 8th putative CRISPR locus from Porphyromonas gingivalis genome (Pgi8Cas13b). The full-length Pgi8Cas13b protein (1119 residues) was successfully expressed in E. Coli cells, and purified by affinity and ion-exchange chromatography methods. The purified protein is biologically active, being able to bind its cognate crRNA with high specificity and affinity. Preparation of biologically active Pgi8Cas13b protein provides the basis for further in vitro biochemical and biophysical studies of the Pgi8Cas13b CRISPR system. Aldehyde dehydrogenase 3A1 is constitutively expressed in a taxon-specific manner in the cornea, where, due to its high abundance, it has been characterized as a corneal crystallin. ALDH3A1 has been proposed to be a multifaceted protein that protects cellular homeostasis through several modes of action. The present study examines the mechanisms by which ALDH3A1 exerts its cytoprotective role under conditions of oxidative stress. To this end, we have utilized an isogenic HCE-2 (human corneal epithelium) cell line pair differing in the expression of ALDH3A1. Single cell gel electrophoresis assay and H2DCFDA analysis revealed that the expression of ALDH3A1 protected HCE-2 cells from H2O2-, tert-butyl peroxide- and etoposide-induced oxidative and genotoxic effects. Furthermore, comparative qPCR analysis revealed that a panel of cell cycle (Cyclins B1, B2, D, E), apoptosis (p53, BAX, BCL-2, BCL-XL) and DNA damage response (DNA-PK, NBS1) genes were up-regulated in the ALDH3A1 expressing HCE-2 cells. Moreover, the expression profile of a variety of DNA damage signaling (DDS)-related genes, was investigated (under normal and oxidative stress conditions) by utilizing the RT2 profiler™ PCR array in both isogenic HCE-2 cell lines. Our results demonstrated that several genes associated with ATM/ATR signaling, cell cycle regulation, apoptosis and DNA damage repair were differentially expressed under all conditions tested. In conclusion, this study suggests that ALDH3A1 significantly contributes to the antioxidant defense of corneal homeostasis by maintaining DNA integrity possibly through altering the expression of specific DDS-related genes. Further studies will shed light on the precise role(s) of this multifunctional protein. Exosomes have gained increasing attention as they participate in cell cross-talk in pathological environments and are functional paracrine factors of therapeutic stem cells. Osteoarthritis (OA) is a common age-related degenerative joint disease, leading to a debilitating lifestyle for sufferers. However, currently no drugs on the market promote cartilage repair, and the patients usually have to undergo arthroplasty in the late stage of OA. Although significant progress has been made in the development of stem cells for the treatment of OA and cartilage injury, problems like immune rejection remain. Recently, increasing evidence has demonstrated that exosomes from the joint microenvironment (“negative” exosomes) could play vital and complicated roles in the progression of OA. Moreover, exosomes from therapeutic cells (“therapeutic” exosomes) have also shown enormous potential for OA therapy/cartilage repair. Here, we first discuss the definition and biological background of exosomes. Then, we critically examin precision treatment of OA in the future, despite the limitations and challenges. Development of biomaterials for hernia and pelvic organ prolapse (POP) repair is encouraged because of high local complication rates with current materials. Therefore, we aimed to develop a functionalized electrospun mesh that promotes tissue ingrowth and provides adequate mechanical strength and compliance during degradation. We describe the in vivo function of a new supramolecular bioactivated polycarbonate (PC) material based on fourfold hydrogen bonding ureidopyrimidinone (UPy) units (UPy-PC). The UPy-PC material was functionalized with UPy-modified cyclic arginine-glycine-aspartic acid (cRGD) peptide additives. Morphometric analysis of the musculofascial content during wound healing showed that cRGD functionalization promotes myogenesis with inhibition of collagen deposition at 14 days. It also prevents muscle atrophy at 90 days and exerts an immunomodulatory effect on infiltrating macrophages at 14 days and foreign body giant cell formation at 14 and 90 days. Additionally, the bioactivated material promon of the implant, accelerates tissue ingrowth and reduces scar formation, resulting in physiological neotissue formation when used for abdominal wall reconstruction in rat hernia model. Moreover, cRGD-bioactivation prevents muscle atrophy and modulates the inflammatory response. These data provide a promising outlook towards a new type of biomaterial for the treatment of hernia and POP. This work is focused on production of volatile fatty acids (VFA) through anaerobic digestion (AD) using raw (without pre-treatment) brewers’ spent grain (BSG) as feedstock. VFAs are by-products from AD of organic wastes with wide potential industrial application in bioplastic production. A long term fed batch stirred-tank reactor was operated and the impact of three hydraulic retention times (HRT) and two organic loading rates (OLR) on VFA production was assessed. Results showed clearly that AD of raw BSG is possible without a pre-treatment step. The maximum volumetric VFA productivity of 91.3 ± 9.1 mgCODL-1 h-1 and VFA concentration of 24.9 ± 2.6 g L-1 were obtained for 16 days of HRT and 16 gTSinL-1d-1 of OLR. This is the highest value of VFA concentration so far reported for BSG. Propionic, acetic and butyric acids were the main VFAs produced. Community identification by FISH and its correlation with process parameters was performed by principal component analysis.