Cynthia J. Kerner scite author profile

Cotransporters harness ion gradients to drive 'active' transport of substrates into cells, for example, the Na+/glucose cotransporter (SGLT1) couples sugar transport to Na+ gradients across the intestinal brush border. Glucose-Galactose Malabsorption (GGM) is caused by a defect in SGLT1. The phenotype is neonatal onset of diarrhea that results in death unless these sugars are removed from the diet. Previously we showed that two sisters with GGM had a missense mutation in the SGLT1 gene. The gene has now been screened in 30 new patients, and a heterologous expression system has been used to link the mutations to the phenotype.

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Membrane Topology of the Human Na+/Glucose Cotransporter SGLT1

Turk

Kerner

Lostao³

et al. 1996

Journal of Biological Chemistry

160

128

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The membrane topology of the human Na+/glucose cotransporter SGLT1 has been probed using N-glycosylation scanning mutants and nested truncations. Functional analysis proved essential for establishment of signal-anchor topology. The resultant model diverges significantly from previously held suppositions of structure based primarily on hydropathy analysis. SGLT1 incorporates 14 membrane spans. The N terminus resides extracellularly, and two hydrophobic regions form newly recognized membrane spans 4 and 12; the large charged domain near the C terminus is cytoplasmic. This model was evaluated further using two advanced empirically-based algorithms predictive of transmembrane helices. Helix ends were predicted using thermo-dynamically-based algorithms known to predict x-ray crystallographically determined transmembrane helix ends. Several considerations suggest the hydrophobic C terminus forms a 14th transmembrane helix, differentiating the eukaryotic members of the SGLT1 family from bacterial homologues. Our data inferentially indicate that these bacterial homologues incorporate 13 spans, with an extracellular N terminus. The model of SGLT1 secondary structure and the predicted helix ends signify information prerequisite for the rational design of further experiments on structure/function relationships.

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Prenatal Identification of a Heterozygous Status in Two Fetuses at Risk for Glucose–galactose Malabsorption

et al. 1996

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Cynthia J. Kerner

Defects in Na+/glucose cotransporter (SGLT1) trafficking and function cause glucose-galactose malabsorption

Membrane Topology of the Human Na+/Glucose Cotransporter SGLT1

Prenatal Identification of a Heterozygous Status in Two Fetuses at Risk for Glucose–galactose Malabsorption

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