Inhibition of 12/15-Lipoxygenase Protects Against β-Cell Oxidative Stress and Glycemic Deterioration in Mouse Models of Type 1 Diabetes

Hernandez-Perez, Marimar; Chopra, Gaurav; Fine, Jonathan; Conteh, Abass M.; Anderson, Ryan M.; Linnemann, Amelia K.; Benjamin, C.; Nelson, Jennifer B.; Benninger, Kara S.; Nadler, Jerry L.; Maloney, David J.; Tersey, Sarah A.; Mirmira, Raghavendra G.

doi:10.2337/db17-0215

Cited by 43 publications

(44 citation statements)

References 54 publications

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“…Docking methods are evaluated by predicting the correct pose/binding mode (evaluated using RMSD or TMScore of the coordinates of the atoms) or by measuring predicted binding affinities 4,8,11,12,16 . Application to protein targets involved in disease holds the promise of discovering new therapeutics using traditional single target approaches or by virtually measuring the interactions of a compound with the proteins from multi-organism proteome [17][18][19][20][21][22] . The resulting chemo-proteome interactions can be interrogated to study polypharmacology 19 and investigate the effect drugs and agents have on protein classes in a disease-specific context 19,22 .…”

Section: Introductionmentioning

confidence: 99%

“…The resulting chemo-proteome interactions can be interrogated to study polypharmacology 19 and investigate the effect drugs and agents have on protein classes in a disease-specific context 19,22 . In previous works, we have used the algorithm presented herein to combat Ebola 20 , determine the toxicity of potential diabetes therapeutics 21 , and rank the affinity of kinase inhibitors for the treatment of Acute Myeloid Leukemia 23 .…”

Section: Introductionmentioning

confidence: 99%

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CANDOCK: Chemical atomic network based hierarchical flexible docking algorithm using generalized statistical potentials

Fine

Konc

Samudrala

et al. 2018

Preprint

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Small molecule docking has proven to be invaluable for drug design and discovery. However, existing docking methods have several limitations, such as, improper treatment of the interactions of essential components in the chemical environment of the binding pocket (e.g. cofactors, metal-ions, etc.), incomplete sampling of chemically relevant ligand conformational space, and the inability to consistently correlate docking scores of the best binding pose with experimental binding affinities. We present CANDOCK, a novel docking algorithm that utilizes a hierarchical approach to reconstruct ligands from an atomic grid using graph theory and generalized statistical potential functions to sample biologically relevant ligand conformations. Our algorithm accounts for protein flexibility, solvent, metal ions and cofactors interactions in the binding pocket that are traditionally ignored by current methods.We evaluate the algorithm on the PDBbind and Astex proteins to show its ability to reproduce the binding mode of the ligands that is independent of the initial ligand conformation in these benchmarks.Finally, we identify the best selector and ranker potential functions, such that, the statistical score of best selected docked pose correlates with the experimental binding affinities of the ligands for any given protein target. Our results indicate that CANDOCK is a generalized flexible docking method that addresses several limitations of current docking methods by considering all interactions in the chemical environment of a binding pocket for correlating the best docked pose with biological activity.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

CANDOCK: Chemical atomic network based hierarchical flexible docking algorithm using generalized statistical potentials

Fine

Konc

Samudrala

et al. 2018

Preprint

Self Cite

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“…It should be noted that genetic disruption of both 12-LOX and 15-LOX in multiple diabetic models largely recapitulates the Aloxe3 -mediated enhancement of hepatic insulin sensitivity and reduced hepatic steatosis ( 15 – 17 ). Therefore, it is plausible that — in addition to (or perhaps in lieu of) generating the PPARγ ligand 12-KETE — eLOX3 either depletes 12-LOX products 12-HpETE and 12-HETE ( Figure 2 ) to the host’s benefit, or 12-LOX and 15-LOX deletion shunts arachidonic acid down the eLOX3 enzymatic pathway to activate PPARγ.…”

Section: Discussionmentioning

confidence: 90%

Hepatocyte ALOXE3 is induced during adaptive fasting and enhances insulin sensitivity by activating hepatic PPARγ

Higgins¹,

Zhang²,

Mayer³

et al. 2018

JCI Insight

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The hepatic glucose fasting response is gaining traction as a therapeutic pathway to enhance hepatic and whole-host metabolism. However, the mechanisms underlying these metabolic effects remain unclear. Here, we demonstrate the epidermal-type lipoxygenase, eLOX3 (encoded by its gene, Aloxe3), is a potentially novel effector of the therapeutic fasting response. We show that Aloxe3 is activated during fasting, glucose withdrawal, or trehalose/trehalose analogue treatment. Hepatocyte-specific Aloxe3 expression reduced weight gain and hepatic steatosis in diet-induced and genetically obese (db/db) mouse models. Aloxe3 expression, moreover, enhanced basal thermogenesis and abrogated insulin resistance in db/db diabetic mice. Targeted metabolomics demonstrated accumulation of the PPARγ ligand 12-KETE in hepatocytes overexpressing Aloxe3. Strikingly, PPARγ inhibition reversed hepatic Aloxe3–mediated insulin sensitization, suppression of hepatocellular ATP production and oxygen consumption, and gene induction of PPARγ coactivator-1α (PGC1α) expression. Moreover, hepatocyte-specific PPARγ deletion reversed the therapeutic effect of hepatic Aloxe3 expression on diet-induced insulin intolerance. Aloxe3 is, therefore, a potentially novel effector of the hepatocellular fasting response that leverages both PPARγ-mediated and pleiotropic effects to augment hepatic and whole-host metabolism, and it is, thus, a promising target to ameliorate metabolic disease.

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“…This model is also supported by the lack of effect of GW9662 also on ALOXE3-induced thermogenesis. In addition, it should be recognized that genetic disruption of both 12-LOX and 15-LOX in multiple diabetic models largely recapitulates the ALOXE3-mediated enhancement of hepatic insulin sensitivity and reduced hepatic steatosis (15)(16)(17). Therefore, it is quite feasible that -in addition to generating the PPARg ligand 12-KETE -either ALOXE3 activity also depletes 12-LOX products 12-HpETE and 12-HETE ( Fig.…”

Section: Discussionmentioning

confidence: 99%

“…In humans, a recent large cohort adults with type 2 diabetes demonstrated a potentially protective role for 5-lipoxygenases ALOX5 and ALOX5AP against diabetes mellitus (14). Conversely, ALOX12/15 inhibition in rodent models inhibited oxidative stress, b-cell deterioration, hepatic steatosis and systemic inflammation (15)(16)(17)(18). Together, these data suggest that intracellular lipid intermediary metabolism drives both tissue-level and whole-organism metabolic homeostasis.…”

Section: Introductionmentioning

confidence: 97%

ALOXE3 is a hepatic fasting-responsive lipoxygenase that enhances insulin sensitivity via hepatic PPARγ

Higgins

Zhang

et al. 2018

Preprint

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The hepatic glucose fasting response is gaining traction as a therapeutic pathway to enhance hepatic and wholehost metabolism. However, the mechanisms underlying these metabolic effects remain unclear. Here, we demonstrate the lipoxygenase, ALOXE3, is a novel effector of the therapeutic fasting response. We show that ALOXE3 is activated during fasting, glucose withdrawal, or trehalose/trehalose analogue treatment. Hepatocytespecific ALOXE3 expression reduced weight gain and hepatic steatosis in diet-induced and genetically obese (db/db) models. ALOXE3 expression moreover enhanced basal thermogenesis and abrogated insulin resistance in db/db diabetic mice. Targeted metabolomics demonstrated accumulation of the PPARg ligand, 12-KETE in hepatocytes overexpressing ALOXE3. Strikingly, PPARg inhibition reversed hepatic ALOXE3-mediated insulin sensitization, suppression of hepatocellular ATP production and oxygen consumption, and gene induction of PPARg coactivator-1a (PGC1a) expression. Moreover, hepatocyte-specific PPARg deletion reversed the therapeutic effect of hepatic ALOXE3 expression on diet-induced insulin intolerance. ALOXE3 is therefore a novel effector of the hepatocellular fasting response that leverages both PPARg-mediated and pleiotropic effects to augment hepatic and whole-host metabolism, and is thus a promising target to ameliorate metabolic disease.

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Inhibition of 12/15-Lipoxygenase Protects Against β-Cell Oxidative Stress and Glycemic Deterioration in Mouse Models of Type 1 Diabetes

Cited by 43 publications

References 54 publications

CANDOCK: Chemical atomic network based hierarchical flexible docking algorithm using generalized statistical potentials

CANDOCK: Chemical atomic network based hierarchical flexible docking algorithm using generalized statistical potentials

Hepatocyte ALOXE3 is induced during adaptive fasting and enhances insulin sensitivity by activating hepatic PPARγ

ALOXE3 is a hepatic fasting-responsive lipoxygenase that enhances insulin sensitivity via hepatic PPARγ

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