Your search keyword '"Nelson, B."' showing total 3 results

1. Insertion of a synthetic switch into insulin provides metabolite-dependent regulation of hormone-receptor activation.

Author

Chen YS, Gleaton J, Yang Y, Dhayalan B, Phillips NB, Liu Y, Broadwater L, Jarosinski MA, Chatterjee D, Lawrence MC, Hattier T, Michael MD, and Weiss MA

Subjects

Blotting, Western, Fructose chemistry, Fructose metabolism, Hep G2 Cells, Humans, Insulin metabolism, Ligands, Models, Molecular, Protein Conformation, Signal Transduction, Insulin chemistry

Abstract

Insulin-signaling requires conformational change: whereas the free hormone and its receptor each adopt autoinhibited conformations, their binding leads to structural reorganization. To test the functional coupling between insulin's "hinge opening" and receptor activation, we inserted an artificial ligand-dependent switch into the insulin molecule. Ligand-binding disrupts an internal tether designed to stabilize the hormone's native closed and inactive conformation, thereby enabling productive receptor engagement. This scheme exploited a diol sensor ( meta -fluoro-phenylboronic acid at Gly A1 ) and internal diol (3,4-dihydroxybenzoate at Lys B28 ). The sensor recognizes monosaccharides (fructose > glucose). Studies of insulin-signaling in human hepatoma-derived cells (HepG2) demonstrated fructose-dependent receptor autophosphorylation leading to appropriate downstream signaling events, including a specific kinase cascade and metabolic gene regulation (gluconeogenesis and lipogenesis). Addition of glucose (an isomeric ligand with negligible sensor affinity) did not activate the hormone. Similarly, metabolite-regulated signaling was not observed in control studies of 1) an unmodified insulin analog or 2) an analog containing a diol sensor without internal tethering. Although secondary structure (as probed by circular dichroism) was unaffected by ligand-binding, heteronuclear NMR studies revealed subtle local and nonlocal monosaccharide-dependent changes in structure. Insertion of a synthetic switch into insulin has thus demonstrated coupling between hinge-opening and allosteric holoreceptor signaling. In addition to this foundational finding, our results provide proof of principle for design of a mechanism-based metabolite-responsive insulin. In particular, replacement of the present fructose sensor by an analogous glucose sensor may enable translational development of a "smart" insulin analog to mitigate hypoglycemic risk in diabetes therapy., Competing Interests: Competing interest statement: M.A.W. has equity in Thermalin Inc. (Cleveland, OH) at which he serves as Chief Innovation Officer; he has also been a consultant to Merck Research Laboratories and DEKA Research and Development Corp. N.B.P. is a consultant to Thermalin Inc. M.C.L.'s laboratory has a Research Agreement with Eli Lilly and Company to conduct research not connected to this publication.

Published

2021

2. Peptide Model of the Mutant Proinsulin Syndrome. I. Design and Clinical Correlation

Author

Balamurugan Dhayalan, Michael D. Glidden, Alexander N. Zaykov, Yen-Shan Chen, Yanwu Yang, Nelson B. Phillips, Faramarz Ismail-Beigi, Mark A. Jarosinski, Richard D. DiMarchi, and Michael A. Weiss

Subjects

Protein Folding, Adolescent, Endocrinology, Diabetes and Metabolism, Diabetes Mellitus, Humans, Insulin, Disulfides, Peptides, Proinsulin

Abstract

The mutant proinsulin syndrome is a monogenic cause of diabetes mellitus due to toxic misfolding of insulin’s biosynthetic precursor. Also designatedmutant INS-gene induced diabetes of the young(MIDY), this syndrome defines molecular determinants of foldability in the endoplasmic reticulum (ER) of β-cells. Here, we describe a peptide model of a key proinsulin folding intermediate and variants containing representative clinical mutations; the latter perturb invariant core sites in native proinsulin (LeuB15→Pro, LeuA16→Pro, and PheB24→Ser). The studies exploited a 49-residue single-chain synthetic precursor (designated DesDi), previously shown to optimizein vitroefficiency of disulfide pairing. Parent and variant peptides contain a single disulfide bridge (cystine B19-A20) to provide a model of proinsulin’s first oxidative folding intermediate. The peptides were characterized by circular dichroism and redox stability in relation to effects of the mutations on (a)in vitrofoldability of the corresponding insulin analogs and (b) ER stress induced in cell culture on expression of the corresponding variant proinsulins. Striking correlations were observed between peptide biophysical properties, degree of ER stress and age of diabetes onset (neonatal or adolescent). Our findings suggest that age of onset reflects the extent to which nascent structure is destabilized in proinsulin’s putative folding nucleus. We envisage that such peptide models will enable high-resolution structural studies of key folding determinants and in turn permit molecular dissection of phenotype-genotype relationships in this monogenic diabetes syndrome. Our companion study (next article in this issue) employs two-dimensional heteronuclear NMR spectroscopy to define site-specific perturbations in the variant peptides.

Published

2021

3. Insertion of a synthetic switch into insulin provides metabolite-dependent regulation of hormone-receptor activation.

Author

Yen-Shan Chen, Gleaton, Jeremy, Yanwu Yang, Dhayalan, Balamurugan, Phillips, Nelson B., Yule Liu, Broadwater, Laurie, Jarosinski, Mark A., Chatterjee, Deepak, Lawrence, Michael C., Hattier, Thomas, Michael, M. Dodson, and Weiss, Michael A.

Subjects

INSULIN derivatives, INSULIN, CINNAMON, HORMONE receptors, METABOLIC regulation, CURCUMIN, GENETIC regulation, FIREPROOFING agents

Abstract

Insulin-signaling requires conformational change: whereas the free hormone and its receptor each adopt autoinhibited conformations, their binding leads to structural reorganization. To test the functional coupling between insulin's "hinge opening" and receptor activation, we inserted an artificial ligand-dependent switch into the insulin molecule. Ligand-binding disrupts an internal tether designed to stabilize the hormone's native closed and inactive conformation, thereby enabling productive receptor engagement. This scheme exploited a diol sensor (meta-fluoro-phenylboronic acid at GlyA1) and internal diol (3,4-dihydroxybenzoate at LysB28). The sensor recognizes monosaccharides (fructose > glucose). Studies of insulin-signaling in human hepatoma-derived cells (HepG2) demonstrated fructose-dependent receptor autophosphorylation leading to appropriate downstream signaling events, including a specific kinase cascade and metabolic gene regulation (gluconeogenesis and lipogenesis). Addition of glucose (an isomeric ligand with negligible sensor affinity) did not activate the hormone. Similarly, metabolite-regulated signaling was not observed in control studies of 1) an unmodified insulin analog or 2) an analog containing a diol sensor without internal tethering. Although secondary structure (as probed by circular dichroism) was unaffected by ligand-binding, heteronuclear NMR studies revealed subtle local and nonlocal monosaccharide-dependent changes in structure. Insertion of a synthetic switch into insulin has thus demonstrated coupling between hinge-opening and allosteric holoreceptor signaling. In addition to this foundational finding, our results provide proof of principle for design of a mechanism-based metabolite-responsive insulin. In particular, replacement of the present fructose sensor by an analogous glucose sensor may enable translational development of a "smart" insulin analog to mitigate hypoglycemic risk in diabetes therapy. [ABSTRACT FROM AUTHOR]

Published

2021