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1. Defibrinogenation Ameliorates Retinal Microgliosis and Inflammation in A CX3CR1-Independent Manner

   https://doi.org/10.1177/17590914221131446  

   Sarker, Borna; Cardona, Sandra M.; Church, Kaira A.; Vanegas, Difernando; Velazquez, Priscila; Rorex, Colin; Rodriguez, Derek; Mendiola, Andrew S.; Kern, Timothy S.; Domingo, Nadia D.; et al (January 2022, ASN Neuro)

   Microglia-mediated inflammation plays a significant role in neuronal and vascular damage in diabetic retinopathy (DR), but the mechanism linking inflammation, neurodegeneration, and impaired vascular integrity is still unclear. Previous studies from diabetic mouse models showed accumulation of fibrinogen at vessel lesions surrounded by perivascular microglial clusters. The purpose of this study was to evaluate whether the pathological hallmarks of gliosis and vascular aberrations characterized in diabetic animal models are consistent with those in diabetic human retinas, and to assess the effects of the defibrinogenating agent ancrod in retinal pathology and visual acuity in a two-hit inflammatory diabetic mouse model. Post-mortem human eyes were assessed for retinal and inflammatory gene expression by quantitative PCR. Immunohistochemical analyses in human and murine retinas were performed using markers of gliosis, vascular integrity, and fibrinogen deposition. An inflammatory microenvironment, with microgliosis and microaneurysms, was found in the diabetic human eye. Microglial activation, fibrinogen deposition, and axonal loss were also observed in the diabetic murine retina. Ancrod treatment correlated with reduced microgliosis, less fibrinogen deposition, and reduced pro-inflammatory cytokine levels in diseased retinal tissues. Together, these data suggest that fibrinogen contributes to microglia-mediated inflammation in the diabetic retina. Since retinal microgliosis, vascular pathology, and vision deficits manifest in diabetic mice irrespective of CX3CR1 genotype, our results indicate that defibrinogenation can dampen systemic neuroinflammation and vascular insults, thereby improving vision at early stages of diabetes. Summary Statement Diabetic human and murine retinas revealed pronounced microglial morphological activation and vascular abnormalities associated with inflammation. Pharmacological fibrinogen depletion using ancrod dampened microglial morphology alterations, resolved fibrinogen accumulation, rescued axonal integrity, and reduced inflammation in the diabetic murine retina. 

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2. TrmB Family Transcription Factor as a Thiol-Based Regulator of Oxidative Stress Response

   https://doi.org/10.1128/mbio.00633-22  

   Mondragon, Paula; Hwang, Sungmin; Kasirajan, Lakshmi; Oyetoro, Rebecca; Nasthas, Angelina; Winters, Emily; Couto-Rodriguez, Ricardo L.; Schmid, Amy; Maupin-Furlow, Julie A. (August 2022, mBio)

   Babitzke, Paul (Ed.)

   ABSTRACT Oxidative stress causes cellular damage, including DNA mutations, protein dysfunction, and loss of membrane integrity. Here, we discovered that a TrmB (transcription regulator of mal operon) family protein (Pfam PF01978) composed of a single winged-helix DNA binding domain (InterPro IPR002831) can function as thiol-based transcriptional regulator of oxidative stress response. Using the archaeon Haloferax volcanii as a model system, we demonstrate that the TrmB-like OxsR is important for recovery of cells from hypochlorite stress. OxsR is shown to bind specific regions of genomic DNA, particularly during hypochlorite stress. OxsR-bound intergenic regions were found proximal to oxidative stress operons, including genes associated with thiol relay and low molecular weight thiol biosynthesis. Further analysis of a subset of these sites revealed OxsR to function during hypochlorite stress as a transcriptional activator and repressor. OxsR was shown to require a conserved cysteine (C24) for function and to use a CG-rich motif upstream of conserved BRE/TATA box promoter elements for transcriptional activation. Protein modeling suggested the C24 is located at a homodimer interface formed by antiparallel α helices, and that oxidation of this cysteine would result in the formation of an intersubunit disulfide bond. This covalent linkage may promote stabilization of an OxsR homodimer with the enhanced DNA binding properties observed in the presence of hypochlorite stress. The phylogenetic distribution TrmB family proteins, like OxsR, that have a single winged-helix DNA binding domain and conserved cysteine residue suggests this type of redox signaling mechanism is widespread in Archaea. IMPORTANCE TrmB-like proteins, while not yet associated with redox stress, are found in bacteria and widespread in archaea. Here, we expand annotation of a large group of TrmB-like single winged-helix DNA binding domain proteins from diverse archaea to function as thiol-based transcriptional regulators of oxidative stress response. Using Haloferax volcanii as a model, we reveal that the TrmB-like OxsR functions during hypochlorite stress as a transcriptional activator and repressor of an extensive gene coexpression network associated with thiol relay and other related activities. A conserved cysteine residue of OxsR serves as the thiol-based sensor for this function and likely forms an intersubunit disulfide bond during hypochlorite stress that stabilizes a homodimeric configuration with enhanced DNA binding properties. A CG-rich DNA motif in the promoter region of a subset of sites identified to be OxsR-bound is required for regulation; however, not all sites have this motif, suggesting added complexity to the regulatory network. 

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3. A 3D Bioprinted Human Cardiac Cell Platform to Model the Pathophysiology of Diabetes

   Binata Joddar, Shweta AnilKumar (January 2020, Circulation research)

   null (Ed.)

   Type-II diabetes (T2D) patients affected by underlying hyperglycemic (high glucose/blood sugar) conditions often suffer from cardiac atrophy, resulting in tissue mass reduction and debilitating cardiac health. To understand pathophysiological mechanisms during progression of cardiac atrophy, a 3D bioprinted organoid platform was developed from a mixture of hydrogels containing human cardiac cells, including cardiomyocytes (CM), fibroblasts (CF) and endothelial cells (EC), to mimic the functionality of the in-vivo tissue. The organoids were cultured using normoglycemic- or hyperglycemic-conditions. The expression of essential biomarkers in these organoids, for myocardin (Myocd), troponin-I (TRP-I), fibroblast protein-1 (FSP-1) and endothelin-1 (ET-1) was confirmed. To assess the physiological cellular connections during hyperglycemia, the presence of Connexin-43 (CX-43) was assessed in the presence of a CX-43 blocker, gap26. Epigenomic tools were used to simultaneously interrogate histone-modifications by histone 3 lysine 9 mono-methylation (H3K9me1) along with the co-regulation of inflammatory mediators, such as the high mobility group box 1 (HMGB1) and toll like receptor 4 (TLR4) in the cardiac organoids cultured using normal versus hyperglycemic conditions. Organoids exposed to high glucose showed an increased expression of H3K9me1 as well as inflammatory mediators HMGB1 and TLR4. Hyperglycemia also exhibited alterations in expression of Myocd and FSP-1 in the organoids, compared to normoglycemic conditions. Treatment with gap26 affected the CX-43 expression significantly, in organoids cultured under hyperglycemia suggesting that high glucose conditions associated with prolonged diabetes may lead to compromised CM-CF coupling, essential for maintenance of cardiac functionality. Increased levels of H3K9me1 suggest decreased expression of Myocd, which may lead to CM degeneration. Epigenetic modifications including alterations in histone methylation in regulation of the myocardial genes and gap junction proteins under hyperglycemic conditions, may lead to cardiac atrophy. We expect to establish an actual T2D patient iPSC cell derived cardiac platform, to offer new therapeutic opportunities within the field. 

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4. Progranulin Protects against Hyperglycemia-Induced Neuronal Dysfunction through GSK3β Signaling

   https://doi.org/10.3390/cells12131803  

   Dedert, Cass; Salih, Lyuba; Xu, Fenglian (July 2023, Cells)

   Type II diabetes affects over 530 million individuals worldwide and contributes to a host of neurological pathologies. Uncontrolled high blood glucose (hyperglycemia) is a major factor in diabetic pathology, and glucose regulation is a common goal for maintenance in patients. We have found that the neuronal growth factor progranulin protects against hyperglycemic stress in neurons, and although its mechanism of action is uncertain, our findings identified Glycogen Synthase Kinase 3β (GSK3β) as being potentially involved in its effects. In this study, we treated mouse primary cortical neurons exposed to high-glucose conditions with progranulin and a selective pharmacological inhibitor of GSK3β before assessing neuronal health and function. Whole-cell and mitochondrial viability were both improved by progranulin under high-glucose stress in a GSK3β—dependent manner. This extended to autophagy flux, indicated by the expressions of autophagosome marker Light Chain 3B (LC3B) and lysosome marker Lysosome-Associated Membrane Protein 2A (LAMP2A), which were affected by progranulin and showed heterogeneous changes from GSK3β inhibition. Lastly, GSK3β inhibition attenuated downstream calcium signaling and neuronal firing effects due to acute progranulin treatment. These data indicate that GSK3β plays an important role in progranulin’s neuroprotective effects under hyperglycemic stress and serves as a jumping-off point to explore progranulin’s protective capabilities in other neurodegenerative models. 

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5. Bone Marrow-Derived Cells Restore Functional Integrity of the Gut Epithelial and Vascular Barriers in a Model of Diabetes and ACE2 Deficiency

   https://doi.org/10.1161/CIRCRESAHA.119.315743  

   Duan, Yaqian; Prasad, Ram; Feng, Dongni; Beli, Eleni; Li Calzi, Sergio; Longhini, Ana Leda; Lamendella, Regina; Floyd, Jason L.; Dupont, Mariana; Noothi, Sunil K.; et al (November 2019, Circulation Research)

   null (Ed.)

   Rationale: There is incomplete knowledge of the impact of bone marrow cells on the gut microbiome and gut barrier function. Objective: We postulated that diabetes mellitus and systemic ACE2 (angiotensin-converting enzyme 2) deficiency would synergize to adversely impact both the microbiome and gut barrier function. Methods and Results: Bacterial 16S rRNA sequencing and metatranscriptomic analysis were performed on fecal samples from wild-type, ACE2 −/y , Akita (type 1 diabetes mellitus), and ACE2 −/y -Akita mice. Gut barrier integrity was assessed by immunofluorescence, and bone marrow cell extravasation into the small intestine was evaluated by flow cytometry. In the ACE2 −/y -Akita or Akita mice, the disrupted barrier was associated with reduced levels of myeloid angiogenic cells, but no increase in inflammatory monocytes was observed within the gut parenchyma. Genomic and metatranscriptomic analysis of the microbiome of ACE2 −/y -Akita mice demonstrated a marked increase in peptidoglycan-producing bacteria. When compared with control cohorts treated with saline, intraperitoneal administration of myeloid angiogenic cells significantly decreased the microbiome gene expression associated with peptidoglycan biosynthesis and restored epithelial and endothelial gut barrier integrity. Also indicative of diabetic gut barrier dysfunction, increased levels of peptidoglycan and FABP-2 (intestinal fatty acid-binding protein 2) were observed in plasma of human subjects with type 1 diabetes mellitus (n=21) and type 2 diabetes mellitus (n=23) compared with nondiabetic controls (n=23). Using human retinal endothelial cells, we determined that peptidoglycan activates a noncanonical TLR-2 (Toll-like receptor 2) associated MyD88 (myeloid differentiation primary response protein 88)-ARNO (ADP-ribosylation factor nucleotide-binding site opener)-ARF6 (ADP-ribosylation factor 6) signaling cascade, resulting in destabilization of p120-catenin and internalization of VE-cadherin as a mechanism of deleterious impact of peptidoglycan on the endothelium. Conclusions: We demonstrate for the first time that the defect in gut barrier function and dysbiosis in ACE2 −/y -Akita mice can be favorably impacted by exogenous administration of myeloid angiogenic cells. 

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