Abstract
Naturally occurring mutants of membrane and secretory proteins are often associated with the pathogenesis of human diseases. Here, we describe the molecular basis of a novel phenotype of congenital sucrase-isomaltase deficiency (CSID), a disaccharide malabsorption disorder of the human intestine in which several structural features and functional capacities of the brush-border enzyme complex sucrase-isomaltase (SI) are affected. The cDNA encoding SI from a patient with CSID reveals a mutation in the isomaltase subunit of SI that results in the substitution of a cysteine by an arginine at amino acid residue 635 (C635R). When this mutation is introduced into the wild type cDNA of SI a mutant enzyme, SI(C635R), is generated that shows a predominant localization in the endoplasmic reticulum. Nevertheless, a definite localization of SI(C635R) in the Golgi apparatus and at the cell surface could be also observed. Epitope mapping with conformation-specific mAbs protease sensitivity assays, and enzymatic activity measurements demonstrate an altered folding pattern of SI(C635R) that is responsible for a substantially increased turnover rate and an aberrant sorting profile. Thus, SI(C635R) becomes distributed also at the basolateral membrane in contrast to wild type SI. Concomitant with the altered sorting pattern, the partial detergent extractability of wild type SI shifts to a complete detergent solubility with Triton X-100. The mutation has therefore affected an epitope responsible for the apical targeting fidelity of SI. Altogether, the combined effects of the C635R mutation on the turnover rate, function, polarized sorting, and detergent solubility of SI constitute a unique and novel pathomechanism of CSID.
Highlights
Fermentative diarrhea upon ingestion of disaccharides and oligosaccharides [2]
We describe a new variant of congenital sucrase-isomaltase deficiency (CSID) characterized by an exchange of a cysteine by an arginine at position 635 of the isomaltase subunit (C635R)
The ratio of the mature precursor forms of SI (pro-SI) to the ER-located mannose-rich protein is severalfold lower than that in the wild type counterpart. This could reflect substantial differences in the conversion rates of the immature pro-SI into its complex glycosylated counterpart in the patient affected by CSID
Summary
Fermentative diarrhea upon ingestion of disaccharides and oligosaccharides [2]. Analysis of this disorder at the molecular and subcellular levels has unraveled a number of phenotypes of CSID, which are characterized by perturbations in the intracellular transport, polarized sorting, aberrant processing, and defective function of SI [3,4,5]. A mutation at the position 620 of SI (L620P), for example, has been identified as one of the possible genetic modifications occurring in the CSID [6] This mutant is mainly found to be localized in the ER, it can be at least partially expressed on the cell surface. We describe a new variant of CSID characterized by an exchange of a cysteine by an arginine at position 635 of the isomaltase subunit (C635R) We demonstrate that this mutant SI is transported to the cell surface at a substantially slower rate than its wild type counterpart, primarily because of an initial block in the ER. An increased turnover, a reduced enzymatic activity, as well as partial missorting of the mutant to the basolateral membrane altogether account for the generation of CSID phenotype
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