Abstract
Conformation-based disorders are manifested at the level of protein structure, necessitating an accurate understanding of how misfolded proteins are processed by the cellular proteostasis network. Asparagine-linked glycosylation plays important roles for protein quality control within the secretory pathway. The suspected role for the MAN1B1 gene product MAN1B1, also known as ER mannosidase I, is to function within the ER similar to the yeast ortholog Mns1p, which removes a terminal mannose unit to initiate a glycan-based ER-associated degradation (ERAD) signal. However, we recently discovered that MAN1B1 localizes to the Golgi complex in human cells and uncovered its participation in ERAD substrate retention, retrieval to the ER, and subsequent degradation from this organelle. The objective of the current study was to further characterize the contribution of MAN1B1 as part of a Golgi-based quality control network. Multiple lines of experimental evidence support a model in which neither the mannosidase activity nor catalytic domain is essential for the retention or degradation of the misfolded ERAD substrate Null Hong Kong. Instead, a highly conserved, vertebrate-specific non-enzymatic decapeptide sequence in the luminal stem domain plays a significant role in controlling the fate of overexpressed Null Hong Kong. Together, these findings define a new functional paradigm in which Golgi-localized MAN1B1 can play a mannosidase-independent gatekeeper role in the proteostasis network of higher eukaryotes.
Highlights
IntroductionResults: The MAN1B1 catalytic domain is dispensable for endoplasmic reticulum (ER)-associated degradation (ERAD), which helped identify an important conserved, non-enzymatic decapeptide sequence within the luminal stem
The capacity of Golgi-localized MAN1B1 to promote endoplasmic reticulum (ER)-associated degradation (ERAD) was investigated
Prior studies have demonstrated that MAN1B1 exhibits a quantitative trait in regard to the capacity of its intracellular concentration to regulate the efficiency of Null Hong Kong (NHK) quality control [20]
Summary
Results: The MAN1B1 catalytic domain is dispensable for ERAD, which helped identify an important conserved, non-enzymatic decapeptide sequence within the luminal stem. Multiple lines of experimental evidence support a model in which neither the mannosidase activity nor catalytic domain is essential for the retention or degradation of the misfolded ERAD substrate Null Hong Kong. A highly conserved, vertebrate-specific nonenzymatic decapeptide sequence in the luminal stem domain plays a significant role in controlling the fate of overexpressed Null Hong Kong. Together, these findings define a new functional paradigm in which Golgi-localized MAN1B1 can play a mannosidase-independent gatekeeper role in the proteostasis network of higher eukaryotes
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