Correlation of rare coding variants in the gene encoding human glucokinase regulatory protein with phenotypic, cellular, and kinetic outcomes
Matthew G. Rees, David Ng, Sarah Ruppert, Clesson Turner, Nicola L. Beer, Amy J. Swift, Mario A. Morken, Jennifer E. Below, Ilana Blech, NISC Comparative Sequencing Program, James C. Mullikin, Mark I. McCarthy, Leslie G. Biesecker, Anna L. Gloyn, Francis S. Collins
Matthew G. Rees, David Ng, Sarah Ruppert, Clesson Turner, Nicola L. Beer, Amy J. Swift, Mario A. Morken, Jennifer E. Below, Ilana Blech, NISC Comparative Sequencing Program, James C. Mullikin, Mark I. McCarthy, Leslie G. Biesecker, Anna L. Gloyn, Francis S. Collins
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Research Article Genetics

Correlation of rare coding variants in the gene encoding human glucokinase regulatory protein with phenotypic, cellular, and kinetic outcomes

Abstract

Defining the genetic contribution of rare variants to common diseases is a major basic and clinical science challenge that could offer new insights into disease etiology and provide potential for directed gene- and pathway-based prevention and treatment. Common and rare nonsynonymous variants in the GCKR gene are associated with alterations in metabolic traits, most notably serum triglyceride levels. GCKR encodes glucokinase regulatory protein (GKRP), a predominantly nuclear protein that inhibits hepatic glucokinase (GCK) and plays a critical role in glucose homeostasis. The mode of action of rare GCKR variants remains unexplored. We identified 19 nonsynonymous GCKR variants among 800 individuals from the ClinSeq medical sequencing project. Excluding the previously described common missense variant p.Pro446Leu, all variants were rare in the cohort. Accordingly, we functionally characterized all variants to evaluate their potential phenotypic effects. Defects were observed for the majority of the rare variants after assessment of cellular localization, ability to interact with GCK, and kinetic activity of the encoded proteins. Comparing the individuals with functional rare variants to those without such variants showed associations with lipid phenotypes. Our findings suggest that, while nonsynonymous GCKR variants, excluding p.Pro446Leu, are rare in individuals of mixed European descent, the majority do affect protein function. In sum, this study utilizes computational, cell biological, and biochemical methods to present a model for interpreting the clinical significance of rare genetic variants in common disease.

Authors

Matthew G. Rees, David Ng, Sarah Ruppert, Clesson Turner, Nicola L. Beer, Amy J. Swift, Mario A. Morken, Jennifer E. Below, Ilana Blech, James C. Mullikin, Mark I. McCarthy, Leslie G. Biesecker, Anna L. Gloyn, Francis S. Collins

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Figure 7

Effect of 0–500 μM F1P or F6P on inhibition of 10 mU/ml recombinant GCK by 1 unit of selected GKRP variants.

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Effect of 0–500 μM F1P or F6P on inhibition of 10 mU/ml recombinant GCK ...
Comparisons of recombinant proteins with WT GKRP. (A) p.Arg612Cys showed no significant difference (P > 0.1) in response to F1P (n = 12) or F6P (n = 12). (B and C) p.Pro383Thr (n = 12; P < 0.02 for 30–500 μM F1P< 0.04 for 5–500 μM F1P) showed a significantly reduced response to F1P but not F6P (P > 0.1). (D and E) p.Ile500Ser and p.Gln234Pro showed a significantly reduced response to F1P (n = 12 and P < 0.03 for 15–500 μM for p.Ile500Ser; n = 38 and P < 0.02 for 20–500 μM for p.Gln234Pro) and F6P (n = 19 and P < 0.05 for 200–500 μM for p.Ile500Ser; n = 41 and P < 0.02 for 10–500 μM for p.Gln234Pro). GCK activity is plotted as a percentage of that obtained in the absence of regulatory protein at 5 mM glucose. Data points are mean ± SEM. *P < 0.05; P < 0.01; P < 0.001.