Amro Ilaiwy1, Miao Liu2, Traci L Parry3, James R Bain4, Christopher B Newgard4, Jonathan C Schisler5, Michael J Muehlbauer4, Florin Despa2, Monte S Willis5. 1. University of Damascus, Faculty of Medicine. 2. Department of Pharmacology and Nutritional Sciences, University of Kentucky, Lexington, KY, USA. 3. McAllister Heart Institute, University of North Carolina, Chapel Hill, NC, USA. 4. Sarah W. Stedman Nutrition and Metabolism Center, Duke Molecular Physiology Institute, Duke University Medical Center, Durham, NC, USA. 5. Department of Pharmacology, University of North Carolina, Chapel Hill, NC, USA.
Abstract
INTRODUCTION: Chronic hypersecretion of the 37 amino acid amylin is common in type 2 diabetics (T2D). Recent studies implicate human amylin aggregates cause proteotoxicity (cell death induced by misfolded proteins) in both the brain and the heart. OBJECTIVES: Identify systemic mechanisms/markers by which human amylin associated with cardiac and brain defects might be identified. METHODS: We investigated the metabolic consequences of amyloidogenic and cytotoxic amylin oligomers in heart, brain, liver, and plasma using non-targeted metabolomics analysis in a rat model expressing pancreatic human amylin (HIP model). RESULTS: Four metabolites were significantly different in 3 or more of the the four compartments (heart, brain, liver, and plasma) in HIP rats. When compared to a T2D rat model, HIP hearts uniquely had significant DECREASES in five amino acids (lysine, alanine, tyrosine, phenylalanine, serine), with phenylalanine decreased across all four tissues investigated, including plasma. In contrast, significantly INCREASED circulating phenylalanine is reported in diabetics in multiple recent studies. CONCLUSION: DECREASED phenylalanine may serve as a unique marker of cardiac and brain dysfunction due to hyperamylinemia that can be differentiated from alterations in T2D in the plasma. While the deficiency in phenylalanine was seen across tissues including plasma and could be monitored, reduced tyrosine was seen only in the brain. The 50% reduction in phenylalanine and tyrosine in HIP brains is significant given their role in supporting brain chemistry as a precursor for catecholamines (dopamine, norepinephrine, epinephrine), which may contribute to the increased morbidity and mortality in diabetics at a multi-system level beyond the effects on glucose metabolism.
INTRODUCTION: Chronic hypersecretion of the 37 amino acid amylin is common in type 2 diabetics (T2D). Recent studies implicate humanamylin aggregates cause proteotoxicity (cell death induced by misfolded proteins) in both the brain and the heart. OBJECTIVES: Identify systemic mechanisms/markers by which humanamylin associated with cardiac and brain defects might be identified. METHODS: We investigated the metabolic consequences of amyloidogenic and cytotoxic amylin oligomers in heart, brain, liver, and plasma using non-targeted metabolomics analysis in a rat model expressing pancreatichumanamylin (HIP model). RESULTS: Four metabolites were significantly different in 3 or more of the the four compartments (heart, brain, liver, and plasma) in HIP rats. When compared to a T2D rat model, HIP hearts uniquely had significant DECREASES in five amino acids (lysine, alanine, tyrosine, phenylalanine, serine), with phenylalanine decreased across all four tissues investigated, including plasma. In contrast, significantly INCREASED circulating phenylalanine is reported in diabetics in multiple recent studies. CONCLUSION: DECREASED phenylalanine may serve as a unique marker of cardiac and brain dysfunction due to hyperamylinemia that can be differentiated from alterations in T2D in the plasma. While the deficiency in phenylalanine was seen across tissues including plasma and could be monitored, reduced tyrosine was seen only in the brain. The 50% reduction in phenylalanine and tyrosine in HIP brains is significant given their role in supporting brain chemistry as a precursor for catecholamines (dopamine, norepinephrine, epinephrine), which may contribute to the increased morbidity and mortality in diabetics at a multi-system level beyond the effects on glucose metabolism.
Authors: Denise M Scholtens; Michael J Muehlbauer; Natalie R Daya; Robert D Stevens; Alan R Dyer; Lynn P Lowe; Boyd E Metzger; Christopher B Newgard; James R Bain; William L Lowe Journal: Diabetes Care Date: 2013-08-29 Impact factor: 19.112
Authors: Sanda Despa; Savita Sharma; Todd R Harris; Hua Dong; Ning Li; Nipavan Chiamvimonvat; Heinrich Taegtmeyer; Kenneth B Margulies; Bruce D Hammock; Florin Despa Journal: J Am Heart Assoc Date: 2014-08-21 Impact factor: 5.501
Authors: Han Ly; Nirmal Verma; Fengen Wu; Miao Liu; Kathryn E Saatman; Peter T Nelson; John T Slevin; Larry B Goldstein; Geert Jan Biessels; Florin Despa Journal: Ann Neurol Date: 2017-07-29 Impact factor: 10.422
Authors: Amro Ilaiwy; Gabriella A M Ten Have; James R Bain; Michael J Muehlbauer; Sara K O'Neal; Jessica M Berthiaume; Traci L Parry; Nicolaas E Deutz; Monte S Willis Journal: Am J Pathol Date: 2019-09 Impact factor: 4.307
Authors: Miao Liu; Nirmal Verma; Xiaoli Peng; Sarah Srodulski; Andrew Morris; Martin Chow; Louis B Hersh; Jing Chen; Haining Zhu; Mihai G Netea; Kenneth B Margulies; Sanda Despa; Florin Despa Journal: Diabetes Date: 2016-06-22 Impact factor: 9.461