Abstract
Over a decade ago, the gene STT3 was identified in a staurosporine and temperature sensitivity screen of yeast. Subsequently the product of this gene was shown to be a subunit of the endoplasmic reticulum-localized oligosaccharyl transferase (OT) complex. Although stt3 mutants are known to be staurosporine-sensitive, we found that mutants of other OT subunits (except ost4 Delta) are staurosporine-resistant, which indicates that this phenotype of stt3 mutants is not simply a consequence of their defect in glycosylation, as previously speculated. Staurosporine sensitivity was found to be an allele-specific phenotype restricted to cells harboring mutations in highly conserved residues in the N-terminal domain of the STT3 protein. Cells bearing mutations in one of the cytosolic-oriented loops (amino acids 158-168) in the N terminus of Stt3p were found to be specifically susceptible to staurosporine. Staurosporine is a specific inhibitor of Pkc1p, and a genetic link had previously been suggested between PKC1 and STT3. It is known that overexpression of PKC1 suppresses the staurosporine sensitivity of the stt3 mutants in an allele-specific manner, which is typical of mutants of Pkc1p cascade. It has been shown that the pkc1 null mutant exhibits lowered OT activity. Our results combined with these previous observations indicate that the N-terminal domain of Stt3p may interact with members of the Pkc1p cascade and consequently mutations in this domain result in staurosporine sensitivity. We further speculate that the Pkc1p regulates OT activity through the N-terminal domain of Stt3p, the C-terminal domain of which possesses the recognition and/or catalytic site of the OT complex.
Highlights
A number of staurosporine- and temperature-sensitive (STT)1 genes were identified during the staurosporine and temperature sensitivity screening in Saccharomyces cerevisiae [1]
Because glycosylation is linked to cell wall biosynthesis [11,12,13,14,15] and Pkc1p is a central regulatory element in the biosynthesis of the yeast cell wall [16], it is assumed that staurosporine sensitivity of the stt3 mutants is a consequence of their glycosylation defect [3]
Mutants of Most of the OT Subunits Are Staurosporine Resistant—To understand the basis of the staurosporine sensitivity of stt3 mutants, which is believed to be a result of a defect in N-glycosylation, we examined the staurosporine sensitivity of mutants of the 8 subunits of the oligosaccharyl transferase complex (Fig. 1)
Summary
MAT a ura his leu ade trp met MAT a ura his leu ade trp met stt MAT a ura his leu ade trp met stt MAT a ura leu ade trp can his3 ⌬stt3::his5ϩ (S: pombe) (YEp352-STT3) MAT a ura leu ade trp can his3 ⌬ost1::his5ϩ (S: pombe) (YEp352-OST1-HA) MAT a ura leu ade trp can his3 ⌬ost1::his5ϩ (S: pombe) (YEp352-ost1D306AHA) MAT␣ ura leu ade lys his trp1 ⌬ost2::LEU2 (pRS314-OST2–3) MAT␣ ura leu ade lys his trp1 ⌬ost2::LEU2 (pRS314-ost2–3) MAT a leu met ura MAT a leu met ura3 ⌬ost3::KAN MAT a leu met ura3 ⌬ost6::KAN MAT a ade can leu trp ura MAT a ade can leu trp ura3 ⌬ost4::URA3 MAT a ade his ura lys MAT a ade his ura lys wbp MAT a ade his ura lys2 ⌬ost5::his5ϩ. This led us to propose that Pkc1p cascade controls N-glycosylation by regulation of Stt3p activity
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