G6PC3 Mutations Are Associated with a Major Defect of Glycosylation: a Novel Mechanism for Neutrophil Dysfunction

Overview

Journal Glycobiology

Date 2011 Mar 10

PMID 21385794

Citations 46

Authors

BuHussain Hayee

Aristotelis Antonopoulos

Emma J Murphy

Farooq Z Rahman

Gavin Sewell

Bradley N Smith

Sara McCartney

Mark Furman

Georgina Hall

Stuart L Bloom

Stuart M Haslam

Howard R Morris

Kaan Boztug

Christoph Klein

Bryan Winchester

Edgar Pick

David C Linch

Rosemary E Gale

Andrew M Smith

Anne Dell

Anthony W Segal

Affiliations

Soon will be listed here.

Abstract

Glucose-6-phosphatase, an enzyme localized in the endoplasmic reticulum (ER), catalyzes the hydrolysis of glucose-6-phosphate (G6P) to glucose and inorganic phosphate. In humans, there are three differentially expressed glucose-6-phosphatase catabolic genes (G6PC1-3). Recently, it has been shown that mutations in the G6PC3 gene result in a syndrome associating congenital neutropenia and various organ malformations. The enzymatic function of G6PC3 is dependent on G6P transport into the ER, mediated by G6P translocase (G6PT). Mutations in the gene encoding G6PT result in glycogen storage disease type-1b (GSD-1b). Interestingly, GSD-1b patients exhibit a similar neutrophil dysfunction to that observed in G6PC3-deficient patients. To better understand the causes of neutrophil dysfunction in both diseases, we have studied the neutrophil nicotinamide adenine dinucleotide phosphate (NADPH) oxidase of patients with G6PC3 and G6PT syndromes. Unexpectedly, sodium dodecyl sulfate-polyacrylamide gel electrophoresis experiments indicated hypo-glycosylation of gp91(phox), the electron-transporting component of the NADPH oxidase, in all of these patients. Rigorous mass spectrometric glycomic profiling showed that most of the complex-type antennae which characterize the neutrophil N-glycome of healthy individuals were severely truncated in the patients' neutrophils. A comparable truncation of the core 2 antenna of the O-glycans was also observed. This aberrant neutrophil glycosylation is predicted to have profound effects on the neutrophil function and merit designation of both syndromes as a new class of congenital disorders of glycosylation.

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