Browsing by Author "Mirmira, Raghavendra"

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    12-lipoxygenase Promotes Macrophage Infiltration and Pancreatic Islet Dysfunction in the Vertebrate Models of Diabetes Pathogenesis
    (2020-05) Kulkarni, Abhishek Anant; Harrington, Maureen; Mirmira, Raghavendra; Anderson, Ryan; Goebl, Mark; Mosley, Amber; Marrs, James
    Diabetes is a morbid metabolic disorder that affects almost 500 million people worldwide. Although multiple factors contribute to diabetes pathogenesis, pancreatic islet inflammation and dysfunction are shared characteristics of its major forms. 12- lipoxygenase (12-LOX), an enzyme involved in lipid metabolism, has been implicated in islet inflammation. 12-LOX generates reactive oxygen species (ROS) that activate inflammation and serve as major contributors to islet dysfunction. Importantly, since ROS are transient moieties, they are challenging to study in vivo. Hence, establishing better animal models of ROS-mediated stress is critical to facilitate the discovery and preclinical testing of novel diabetes therapeutics. Here, I have adapted a zebrafish model of conditional β-cell injury, which is regulated by the administration of the prodrug metronidazole (MTZ), to study responses to ROS in vivo. I demonstrate that with MTZ treatment, ROS are generated within β-cells and subsequently exhibit recruitment of macrophages into the islet and induction of β-cell death. I utilized this model to uncover roles for macrophages and 12-LOX during islet injury. Excessive macrophage infiltration exacerbates islet inflammation and dysfunction. Interestingly, on the depletion of macrophages in zebrafish, I observed that β-cells recovered normal function upon cessation of prodrug treatment. This suggests that infiltrating macrophages promote maladaptive inflammation and premature removal of damaged β-cells. Thus, limiting the macrophage infiltration may be a therapeutic approach to restoring β-cell function. Based on the established roles of 12-LOX in other contexts, I hypothesized that its inhibition would prevent the localized infiltration of proinflammatory macrophages. To test this, I used both zebrafish and mouse models and observed a significant reduction in macrophage migration upon loss of 12- LOX activity. Furthermore, I found that expression of CXCR3, a crucial receptor regulating migration, was significantly reduced in 12-LOX loss-of-function macrophages. These data suggest a role for 12-LOX in macrophages, which is conserved across species. Collectively, my study reveals novel roles for 12-LOX in macrophage function and provides testable therapeutic targets for the resolution of inflammation-induced damage in the pancreatic islets.
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    Mouse and human islets survive and function after coating by biosilicification
    (American Physiological Society, 2013-11-15) Jaroch, David B.; Lu, Jing; Madangopal, Rajtarun; Stull, Natalie D.; Stensberg, Matthew; Shi, Jin; Kahn, Jennifer L.; Herrera-Perez, Ruth; Zeitchek, Michael; Sturgis, Jennifer; Robinson, J. Paul; Yoder, Mervin C.; Porterfield, D. Marshall; Mirmira, Raghavendra; Rickus, Jenna L.; Medicine, School of Medicine
    Inorganic materials have properties that can be advantageous in bioencapsulation for cell transplantation. Our aim was to engineer a hybrid inorganic/soft tissue construct by inducing pancreatic islets to grow an inorganic shell. We created pancreatic islets surrounded by porous silica, which has potential application in the immunoprotection of islets in transplantation therapies for type 1 diabetes. The new method takes advantage of the islet capsule surface as a template for silica formation. Mouse and human islets were exposed to medium containing saturating silicic acid levels for 9-15 min. The resulting tissue constructs were then cultured for up to 4 wk under normal conditions. Scanning electron microscopy and energy dispersive X-ray spectroscopy was used to monitor the morphology and elemental composition of the material at the islet surface. A cytokine assay was used to assess biocompatibility with macrophages. Islet survival and function were assessed by confocal microscopy, glucose-stimulated insulin release assays, oxygen flux at the islet surface, expression of key genes by RT-PCR, and syngeneic transplant into diabetic mice.
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    OR05-3 Mir-21 Contributes to Cytokine-Induced Beta Cell Dysfunction via Inhibition of mRNAs Regulating Beta Cell Identity
    (Oxford University Press, 2019-04-15) Ibrahim, Sara; Anderson, Ryan; Mirmira, Raghavendra; Sims, Emily; Medicine, School of Medicine
    A hallmark of diabetes is the loss of physical or functional β cell mass. Alterations in β cell microRNA (miRNA) profiles have been described in diabetes. MiRNAs have also been shown to serve as important regulators of β cell development and function, implicating them in β cell dysfunction during diabetes development. Our lab has previously demonstrated that β cell microRNA 21 (miR-21) is increased in models of diabetes. However, a comprehensive analysis of the β cell effects of miR-21 remain poorly defined, and the effects of miR-21 on in vivo glucose homeostasis have never been explored. To this end, we performed a comprehensive in silico analysis of bioinformatics databases to identify potential β cell targets of miR-21, which yielded multiple targets in the Transforming Growth Factor Beta 2 (Tgfb2) and Fibroblast Growth Factor Receptor 3 (Fgfr3) pathways associated with regulation of differentiation. We hypothesize that β cell miR-21 plays a critical role in inhibiting β cell function and inducing loss of β cell identity. To validate targets in vitro, we developed a model whereby miR-21 is upregulated using a dose dependent lentiviral Tetracycline-on system in INS1 cells. Overexpression of miR-21 led to a reduction in expression levels of several members of the Tgfb2 and Fgfr3 pathways as well as multiple transcription factors associated with β cell function and identity, and an increase in aldehyde dehydrogenase transcripts, consistent with β cell dedifferentiation. To verify direct interactions between miR-21 and candidate target mRNAs, a biotin pulldown experiment was performed using a 3’ biotinylated mature miR-21 construct and a 3’ biotinylated cel-miR-67 control construct. Several mRNAs associated with β cell identity were enriched in the pulldown, indicating a direct interaction with miR-21. Lineage tracing was performed within an in vivo zebrafish model of β cell specific oxidative stress in which β cells expressed a nuclear GFP signal. Whole body knock down of miR-21 by morpholino microinjection showed a protective effect in stressed β cells and rescued against a dedifferentiated phenotype. To test the effect of miR-21 on glucose tolerance in vivo, inducible β cell specific knockout (βmiR-21KO) and overexpression (βmiR-21) mice were generated by crossing Ins1tm1(CreERT2)Thor mice with miR-21 floxed mice and miR-21-CAG-Z-EGFP mice, respectively. When compared to littermate controls, intraperitoneal glucose tolerance tests (IPGTT) exhibited hyperglycemia in βmiR-21 mice and euglycemia in βmiR-21KO mice. Metabolic studies, including glucose stimulated insulin secretion (GSIS) and insulin tolerance tests (ITT) are ongoing in our mouse models. Our results implicate miR-21 as a regulator of β cell dedifferentiation during diabetes development.