Your search keyword '"Knauf C"' showing total 7 results

1. Protocol for the preclinical evaluation of gut barrier function and immune interaction in an HT-29/PBMC co-culture model.

Author

Astre G, Créchet L, Pomié N, Pereira O, Cani PD, Knauf C, and Abot A

Abstract

Here, we present a protocol for the pre-clinical evaluation of gut barrier function and immune interaction in an HT-29/PBMC co-culture model. We describe steps for culturing HT-29 cells and peripheral blood mononuclear cells (PBMCs), assembling the co-culture model, and testing cell viability. We then detail procedures for performing efficacy tests through stress challenges and barrier permeability assays. For complete details on the use and execution of this protocol, please refer to Abot et al. 1 ., Competing Interests: Declaration of interests P.D.C. was co-founder of The Akkermansia Company SA. P.D.C. and C.K. co-founded Enterosys SAS. G.A., L.C., N.P., O.P., and A.A. are employees at Enterosys., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

2. A newly identified protein from Akkermansia muciniphila stimulates GLP-1 secretion.

Author

Cani PD and Knauf C

Subjects

Akkermansia, Humans, Membrane Proteins, Transcription Factors, Glucagon-Like Peptide 1, Metabolic Diseases

Abstract

Akkermansia muciniphila is a gut commensal known to improve host metabolism. The outer membrane protein Amuc_1100 has been shown to partially replicate these beneficial effects. Here, Yoon et al. (2021) have identified a novel protein (P9) secreted by A. muciniphila that stimulates GLP-1 secretion, thereby adding new insight to the biomolecule era to treat metabolic diseases., Competing Interests: Declaration of interests P.D.C. is the inventor on patent applications dealing with the use of A. muciniphila and its components in the treatment of metabolic disorders. P.D.C. is co-founder of A-Mansia Biotech SA. P.D.C. and C.K. are co-founders of Enterosys S.A. (Labège, France)., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

3. Mitochondrial Dynamics Mediated by Mitofusin 1 Is Required for POMC Neuron Glucose-Sensing and Insulin Release Control.

Author

Ramírez S, Gómez-Valadés AG, Schneeberger M, Varela L, Haddad-Tóvolli R, Altirriba J, Noguera E, Drougard A, Flores-Martínez Á, Imbernón M, Chivite I, Pozo M, Vidal-Itriago A, Garcia A, Cervantes S, Gasa R, Nogueiras R, Gama-Pérez P, Garcia-Roves PM, Cano DA, Knauf C, Servitja JM, Horvath TL, Gomis R, Zorzano A, and Claret M

Subjects

Animals, GTP Phosphohydrolases genetics, Glucose genetics, Insulin genetics, Insulin Secretion, Mice, Mice, Knockout, Mitochondria genetics, GTP Phosphohydrolases metabolism, Glucose metabolism, Insulin metabolism, Insulin-Secreting Cells transplantation, Mitochondria metabolism, Mitochondrial Dynamics, Neurons metabolism, Pro-Opiomelanocortin

Abstract

Proopiomelanocortin (POMC) neurons are critical sensors of nutrient availability implicated in energy balance and glucose metabolism control. However, the precise mechanisms underlying nutrient sensing in POMC neurons remain incompletely understood. We show that mitochondrial dynamics mediated by Mitofusin 1 (MFN1) in POMC neurons couple nutrient sensing with systemic glucose metabolism. Mice lacking MFN1 in POMC neurons exhibited defective mitochondrial architecture remodeling and attenuated hypothalamic gene expression programs during the fast-to-fed transition. This loss of mitochondrial flexibility in POMC neurons bidirectionally altered glucose sensing, causing abnormal glucose homeostasis due to defective insulin secretion by pancreatic β cells. Fed mice lacking MFN1 in POMC neurons displayed enhanced hypothalamic mitochondrial oxygen flux and reactive oxygen species generation. Central delivery of antioxidants was able to normalize the phenotype. Collectively, our data posit MFN1-mediated mitochondrial dynamics in POMC neurons as an intrinsic nutrient-sensing mechanism and unveil an unrecognized link between this subset of neurons and insulin release., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

4. Hedgehog partial agonism drives Warburg-like metabolism in muscle and brown fat.

Author

Teperino R, Amann S, Bayer M, McGee SL, Loipetzberger A, Connor T, Jaeger C, Kammerer B, Winter L, Wiche G, Dalgaard K, Selvaraj M, Gaster M, Lee-Young RS, Febbraio MA, Knauf C, Cani PD, Aberger F, Penninger JM, Pospisilik JA, and Esterbauer H

Subjects

AMP-Activated Protein Kinase Kinases, Adipocytes metabolism, Animals, Cell Line, Cells, Cultured, Cilia metabolism, Diabetes Mellitus metabolism, Humans, Mice, Neoplasms metabolism, Obesity metabolism, Protein Kinases metabolism, Smoothened Receptor, Adipose Tissue, Brown metabolism, Glycolysis, Hedgehog Proteins metabolism, Muscle Cells metabolism, Receptors, G-Protein-Coupled metabolism, Signal Transduction

Abstract

Diabetes, obesity, and cancer affect upward of 15% of the world's population. Interestingly, all three diseases juxtapose dysregulated intracellular signaling with altered metabolic state. Exactly which genetic factors define stable metabolic set points in vivo remains poorly understood. Here, we show that hedgehog signaling rewires cellular metabolism. We identify a cilium-dependent Smo-Ca(2+)-Ampk axis that triggers rapid Warburg-like metabolic reprogramming within minutes of activation and is required for proper metabolic selectivity and flexibility. We show that Smo modulators can uncouple the Smo-Ampk axis from canonical signaling and identify cyclopamine as one of a new class of "selective partial agonists," capable of concomitant inhibition of canonical and activation of noncanonical hedgehog signaling. Intriguingly, activation of the Smo-Ampk axis in vivo drives robust insulin-independent glucose uptake in muscle and brown adipose tissue. These data identify multiple noncanonical endpoints that are pivotal for rational design of hedgehog modulators and provide a new therapeutic avenue for obesity and diabetes., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

5. Drosophila genome-wide obesity screen reveals hedgehog as a determinant of brown versus white adipose cell fate.

Author

Pospisilik JA, Schramek D, Schnidar H, Cronin SJ, Nehme NT, Zhang X, Knauf C, Cani PD, Aumayr K, Todoric J, Bayer M, Haschemi A, Puviindran V, Tar K, Orthofer M, Neely GG, Dietzl G, Manoukian A, Funovics M, Prager G, Wagner O, Ferrandon D, Aberger F, Hui CC, Esterbauer H, and Penninger JM

Subjects

Adipocytes, Brown metabolism, Adipocytes, White metabolism, Adipogenesis, Animals, Cyclic AMP metabolism, Glucocorticoids metabolism, Humans, Mice, Mice, Knockout, Muscle Cells metabolism, Repressor Proteins genetics, Drosophila Proteins metabolism, Hedgehog Proteins metabolism, Obesity genetics

Abstract

Over 1 billion people are estimated to be overweight, placing them at risk for diabetes, cardiovascular disease, and cancer. We performed a systems-level genetic dissection of adiposity regulation using genome-wide RNAi screening in adult Drosophila. As a follow-up, the resulting approximately 500 candidate obesity genes were functionally classified using muscle-, oenocyte-, fat-body-, and neuronal-specific knockdown in vivo and revealed hedgehog signaling as the top-scoring fat-body-specific pathway. To extrapolate these findings into mammals, we generated fat-specific hedgehog-activation mutant mice. Intriguingly, these mice displayed near total loss of white, but not brown, fat compartments. Mechanistically, activation of hedgehog signaling irreversibly blocked differentiation of white adipocytes through direct, coordinate modulation of early adipogenic factors. These findings identify a role for hedgehog signaling in white/brown adipocyte determination and link in vivo RNAi-based scanning of the Drosophila genome to regulation of adipocyte cell fate in mammals.

Published

2010

6. Apelin stimulates glucose utilization in normal and obese insulin-resistant mice.

Author

Dray C, Knauf C, Daviaud D, Waget A, Boucher J, Buléon M, Cani PD, Attané C, Guigné C, Carpéné C, Burcelin R, Castan-Laurell I, and Valet P

Subjects

AMP-Activated Protein Kinases genetics, AMP-Activated Protein Kinases metabolism, Adipokines, Animals, Apelin, Carrier Proteins pharmacology, Intercellular Signaling Peptides and Proteins, Male, Mice, Mice, Knockout, Muscle, Skeletal metabolism, Nitric Oxide Synthase Type III genetics, Nitric Oxide Synthase Type III metabolism, Oncogene Protein v-akt metabolism, Adipose Tissue metabolism, Carrier Proteins physiology, Glucose metabolism, Insulin Resistance physiology, Obesity metabolism

Abstract

Adipose tissue (AT) secretes several adipokines that influence insulin sensitivity and potentially link obesity to insulin resistance. Apelin, a peptide present in different tissues, is also secreted by adipocytes. Apelin is upregulated in obese and hyperinsulinemic humans and mice. Although a tight relation exists between the regulation of apelin and insulin, it remains largely unknown whether apelin affects whole-body glucose utilization. Herein, we show that in chow-fed mice, acute intravenous injection of apelin has a powerful glucose-lowering effect associated with enhanced glucose utilization in skeletal muscle and AT. Through in vivo and in vitro pharmacological and genetic approaches, we demonstrate the involvement of endothelial NO synthase, AMP-activated protein kinase, and Akt in apelin-stimulated glucose uptake in soleus muscle. Remarkably, in obese and insulin-resistant mice, apelin restored glucose tolerance and increased glucose utilization. Apelin could thus represent a promising target in the management of insulin resistance.

Published

2008

7. Targeted deletion of AIF decreases mitochondrial oxidative phosphorylation and protects from obesity and diabetes.

Author

Pospisilik JA, Knauf C, Joza N, Benit P, Orthofer M, Cani PD, Ebersberger I, Nakashima T, Sarao R, Neely G, Esterbauer H, Kozlov A, Kahn CR, Kroemer G, Rustin P, Burcelin R, and Penninger JM

Subjects

Animals, Apoptosis Inducing Factor genetics, Cell Respiration drug effects, Diabetes Mellitus genetics, Diabetes Mellitus metabolism, Diet adverse effects, Glucose metabolism, Insulin pharmacology, Liver cytology, Liver drug effects, Liver metabolism, Mice, Mice, Knockout, Mitochondria drug effects, Mosaicism drug effects, Muscles cytology, Muscles drug effects, Muscles metabolism, Obesity genetics, Obesity metabolism, Organ Specificity drug effects, Phenotype, Substrate Specificity drug effects, Apoptosis Inducing Factor deficiency, Diabetes Mellitus prevention & control, Gene Deletion, Gene Targeting, Mitochondria metabolism, Obesity prevention & control, Oxidative Phosphorylation drug effects

Abstract

Type-2 diabetes results from the development of insulin resistance and a concomitant impairment of insulin secretion. Recent studies place altered mitochondrial oxidative phosphorylation (OxPhos) as an underlying genetic element of insulin resistance. However, the causative or compensatory nature of these OxPhos changes has yet to be proven. Here, we show that muscle- and liver-specific AIF ablation in mice initiates a pattern of OxPhos deficiency closely mimicking that of human insulin resistance, and contrary to current expectations, results in increased glucose tolerance, reduced fat mass, and increased insulin sensitivity. These results are maintained upon high-fat feeding and in both genetic mosaic and ubiquitous OxPhos-deficient mutants. Importantly, the effects of AIF on glucose metabolism are acutely inducible and reversible. These findings establish that tissue-specific as well as global OxPhos defects in mice can counteract the development of insulin resistance, diabetes, and obesity.

Published

2007