Abstract
The P56S mutation in VAPB (vesicle-associated membrane protein-associated protein B) causes autosomal dominant motoneuronal diseases. Although it was reported that the P56S mutation induces localization shift of VAPB from endoplasmic reticulum (ER) to non-ER compartments, it remains unclear what the physiological function of VAPB is and how the P56S mutation in VAPB causes motoneuronal diseases. Here we demonstrate that overexpression of wild type VAPB (wt-VAPB) promotes unfolded protein response (UPR), which is an ER reaction to suppress accumulation of misfolded proteins, and that small interfering RNA for VAPB attenuates UPR to chemically induced ER stresses, indicating that VAPB is physiologically involved in UPR. The P56S mutation nullifies the function of VAPB to mediate UPR by inhibiting folding of VAPB that results in insolubility and aggregate formation of VAPB in non-ER fractions. Furthermore, we have found that expression of P56S-VAPB inhibits UPR, mediated by endogenous wt-VAPB, by inducing aggregate formation and mislocalization into non-ER fractions of wt-VAPB. Consequently, the P56S mutation in a single allele of the VAPB gene may diminish the activity of VAPB to mediate UPR to less than half the normal level. We thus speculate that the malfunction of VAPB to mediate UPR, caused by the P56S mutation, may contribute to the development of motoneuronal degeneration linked to VAPB/ALS8.
Highlights
To date, four ALS-causative genes have been identified, and precise characterization of their physiological roles and abnormalities by ALS-causing mutations is bringing us clues as to how ALS and other motor neuron diseases occur
We further show that the P56S mutation causes almost complete loss of function of VAPB to mediate unfolded protein response (UPR) by inducing its misfolding and localization shift to the non-endoplasmic reticulum (ER) compartments
The P56S Mutation Induces the Insolubility of VAPB—We cloned a human wild type VAPB (wt-VAPB) cDNA, from which the P56S-VAPB mutant cDNA was generated by site-directed mutagenesis
Summary
Four ALS-causative genes have been identified, and precise characterization of their physiological roles and abnormalities by ALS-causing mutations is bringing us clues as to how ALS and other motor neuron diseases occur. We further show that the P56S mutation causes almost complete loss of function of VAPB to mediate UPR by inducing its misfolding and localization shift to the non-ER compartments. It has been known that some synaptic vesicular proteins, followed by induction of ER stress, induced expression of fluosuch as VAMP2, are known to localize in a scattered membrane rescent XBP1-Venus in NSC34 cells transfected with pCAX-F-
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