Your search keyword '"John S. Debenham"' showing total 3 results

1. GPR120 suppresses adipose tissue lipolysis and synergizes with GPR40 in antidiabetic efficacy

Author

Santhosh Satapati, Ying Qian, Margaret S. Wu, Aleksandr Petrov, Ge Dai, Sheng-ping Wang, Yonghua Zhu, Xiaolan Shen, Eric S. Muise, Ying Chen, Emanuel Zycband, Adam Weinglass, Jerry Di Salvo, John S. Debenham, Jason M. Cox, Ping Lan, Vinit Shah, Stephen F. Previs, Mark Erion, David E. Kelley, Liangsu Wang, Andrew D. Howard, and Jin Shang

Subjects

lipolysis and fatty acid metabolism, insulin resistance, diabetes, fatty acid, Biochemistry, QD415-436

Abstract

GPR40 and GPR120 are fatty acid sensors that play important roles in glucose and energy homeostasis. GPR40 potentiates glucose-dependent insulin secretion and demonstrated in clinical studies robust glucose lowering in type 2 diabetes. GPR120 improves insulin sensitivity in rodents, albeit its mechanism of action is not fully understood. Here, we postulated that the antidiabetic efficacy of GPR40 could be enhanced by coactivating GPR120. A combination of GPR40 and GPR120 agonists in db/db mice, as well as a single molecule with dual agonist activities, achieved superior glycemic control compared with either monotherapy. Compared with a GPR40 selective agonist, the dual agonist improved insulin sensitivity in ob/ob mice measured by hyperinsulinemic-euglycemic clamp, preserved islet morphology, and increased expression of several key lipolytic genes in adipose tissue of Zucker diabetic fatty rats. Novel insights into the mechanism of action for GPR120 were obtained. Selective GPR120 activation suppressed lipolysis in primary white adipocytes, although this effect was attenuated in adipocytes from obese rats and obese rhesus, and sensitized the antilipolytic effect of insulin in rat and rhesus primary adipocytes. In conclusion, GPR120 agonism enhances insulin action in adipose tissue and yields a synergistic efficacy when combined with GPR40 agonism.

Published

2017

2. Discovery and Optimization of a Novel Triazole Series of GPR142 Agonists for the Treatment of Type 2 Diabetes

Author

John S. Debenham, Dann L. Parker, Birgit T. Priest, Ravi P. Nargund, Feroze Ujjainwalla, Randal M. Bugianesi, Michele Pachanski, Liangqin Guo, William K. Hagmann, George J. Eiermann, Yi Zang, Ramzi F. Sweis, Andrew D. Howard, Jenna L. Terebetski, Melissa Kirkland, Yue Feng, Gino Salituro, Derun Li, Christopher Joseph Sinz, Stan Mitelman, Maria E. Trujillo, Scott D. Edmondson, Karen H. Dingley, Jin Shang, Nicole Buist, Xiaofang Li, Weiguo Liu, Mary Ann Powles, Terri M. Kelly, and Edward C. Sherer

Subjects

0301 basic medicine, medicine.medical_specialty, Organic Chemistry, Triazole, Type 2 Diabetes Mellitus, Glucose excursion, Type 2 diabetes, Metabolic stability, medicine.disease, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Endocrinology, chemistry, Internal medicine, Drug Discovery, medicine, Deficient mouse, Potency, Lead compound

Abstract

GPR142 has been identified as a potential glucose-stimulated insulin secretion (GSIS) target for the treatment of type 2 diabetes mellitus (T2DM). A class of triazole GPR142 agonists was discovered through a high throughput screen. The lead compound 4 suffered from poor metabolic stability and poor solubility. Lead optimization strategies to improve potency, efficacy, metabolic stability, and solubility are described. This optimization led to compound 20e, which showed significant reduction of glucose excursion in wild-type but not in GPR142 deficient mice in an oral glucose tolerance test (oGTT) study. These studies provide strong evidence that reduction of glucose excursion through treatment with 20e is GPR142-mediated, and GPR142 agonists could be used as a potential treatment for type 2 diabetes.

Published

2016

3. Hemicelluloses: Science and Technology

Author

Paul Gatenholm, Maija Tenkanen, RunCang Sun, X. F. Sun, J. Tomkinson, Juergen Puls, Bodo Saake, P. Maréchal, J. Jorda, P.-Y. Pontalier, L. Rigal, B. Saake, N. Erasmy, Th. Kruse, E. Schmekal, J. Puls, H. Stålbrand, J. Lundqvist, A. Andersson, P. Hägglund, L. Anderson, F. Tjerneld, A. Jacobs, A. Teleman, O. Dahlman, M. Palm, G. Zacchi, Olof B. Dahlman, Anna Jacobs, Maria Nordström, Ursula Mais, Herbert Sixta, Mirjam A. Kabel, Henk A. Schols, Alphons G. J. Voragen, David J. Kiemle, Arthur J. Stipanovic, Kelly E. Mayo, Arja Lappalainen, Jaakko Pere, Robert H. Marchessault, Johannes P. Roubroeks, Wolfgang G. Glasser, Anne-Mari Olsson, Lennart Salmén, Alan Esker, Ulrike Becker, Sylvie Jamin, Shinji Beppu, Scott Renneckar, Wolfgang Glasser, Tea Hannuksela, Bjarne Holmbom, Åsa Linder, Per Tomas Larsson, Arja Paananen, Monika Österberg, Mark Rutland, Tekla Tammelin, Terhi Saarinen, Kirsi Tappura, Per Stenius, Thomas Heinze, Andreas Koschella, Anna Ebringerová, Charles M. Buchanan, Norma L. Buchanan, John S. Debenham, Maria Jacobsson, Michael C. Shelton, Thelma L., Paul Gatenholm, Maija Tenkanen, RunCang Sun, X. F. Sun, J. Tomkinson, Juergen Puls, Bodo Saake, P. Maréchal, J. Jorda, P.-Y. Pontalier, L. Rigal, B. Saake, N. Erasmy, Th. Kruse, E. Schmekal, J. Puls, H. Stålbrand, J. Lundqvist, A. Andersson, P. Hägglund, L. Anderson, F. Tjerneld, A. Jacobs, A. Teleman, O. Dahlman, M. Palm, G. Zacchi, Olof B. Dahlman, Anna Jacobs, Maria Nordström, Ursula Mais, Herbert Sixta, Mirjam A. Kabel, Henk A. Schols, Alphons G. J. Voragen, David J. Kiemle, Arthur J. Stipanovic, Kelly E. Mayo, Arja Lappalainen, Jaakko Pere, Robert H. Marchessault, Johannes P. Roubroeks, Wolfgang G. Glasser, Anne-Mari Olsson, Lennart Salmén, Alan Esker, Ulrike Becker, Sylvie Jamin, Shinji Beppu, Scott Renneckar, Wolfgang Glasser, Tea Hannuksela, Bjarne Holmbom, Åsa Linder, Per Tomas Larsson, Arja Paananen, Monika Österberg, Mark Rutland, Tekla Tammelin, Terhi Saarinen, Kirsi Tappura, Per Stenius, Thomas Heinze, Andreas Koschella, Anna Ebringerová, Charles M. Buchanan, Norma L. Buchanan, John S. Debenham, Maria Jacobsson, Michael C. Shelton, and Thelma L.

Subjects

Hemicellulose--Congresses, Hemicellulose

Abstract

Produced by the majority of trees and terrestrial plants, hemicelluloses (a set of polysaccharides) are the most abundant form of polymer after cellulose. Seeing hemicelluloses as an important yet neglected renewable resource that can move us beyond the petrochemical economy, Gatenholm (Chalmers U. of Technology, Sweden) and Tenkanen (U. of Helsinki, Finland) present 23 papers examining the chemical properties of hemicelluloses, as well as modifications and applications. Papers discuss isolation and characterization, analytical methods, molecular architecture and assembly, and interactions with cellulose. Distributed by Oxford U. Press. Annotation : 2004 Book News, Inc., Portland, OR (booknews.com).

Published

2004