Ricardo D. Basco

Processing of yeast exoglucanase (β‐glucosidase) in a KEX2‐dependent manner

We have detected proteolytic processing of a form of exoglucanase representative of the endoplasmic reticulum (form A). This processing did not take place when form A was obtained from protoplasts lysed in the presence of either EDTA or leupeptin, two wel‐characterized inhibitors of KEX2 endoprotease from Saccharomyces cerevisiae. Sequencing of the amino terminus of an A‐like form of enzyme secreted by a kex2 mutant indicated the presence of 4 amino acids, with a pair of basic residues (Lys‐Arg) at their carboxyl side, preceding the amino terminus of the wild‐type external exoglucanase.

Preferential transfer of truncated oligosaccharides to the first sequon of yeast exoglucanase in Saccharomyces cerevisiae alg3 cells

In addition to the exoglucanases (Exg) secreted into the culture medium by wild type cells, ExgIa and ExgIb, which have oligosaccharides attached to both potential N-glycosylation sites, Saccharomyces cerevisiae alg3 mutant secreted substantial amounts (35--44%) of underglycosylated and unglycosylated forms. Quantification of these forms indicated that no more than 78% of the available N-sites were occupied. About 50% of the transferred oligosaccharides were endo H sensitive, indicating that the lipid-linked precursor had completed its synthesis to Glc3-Man9-GlcNAc2. The other 50% remained endo H-resistant and, accordingly, it should be derived from the precursor oligosaccharide Man5-GlcNAc2 synthesized by this mutant. A closer analysis of forms that have received two oligosaccharides (ExgIb) showed that the first sequon was enriched in truncated residues, whereas the second one was enriched in regular counterparts. Similarly, analysis of the individual underglycosylated glycoforms indicated that 38% of the oligosaccharides attached to the second site were regular. This percentage dropped to 20% for glycoforms carrying the oligosaccharide in the first sequon. The preferential transfer of truncated oligosaccharides to the first glycosylation site seems to be a consequence of (1) the low percentage of truncated lipid linked oligosaccharides that receives the glucotriose unit, and (2) the effect of the glucotriose unit on the selection of N-sites to be glycosylated.

In vivo processing of the precursor of the major exoglucanase by KEX2 endoprotease in the Saccharomyces cerevisiae secretory pathway

We have established the main post-translational modification of the major exoglucanase of Saccharomyces cerevisiae as the enzyme progresses through the secretory pathway. The protein portion of the enzyme accumulated by sec18 cells was about 2 kDa larger than that of the secreted enzyme. This precursor (form A) was stable when maintained in the endoplasmic reticulum but was processed to the mature form (form B) before the block imposed by the sec7 mutation. Sec7 cells, when incubated at 37 degrees C, accumulated form B first, but upon prolonged incubation, form A was preferentially accumulated. When the supply of newly synthesized exoglucanase was prevented by the addition of cycloheximide, the accumulated A was transformed into B in the presence of altered Sec7p that still prevented secretion. Conversion of A into B was prevented in the double mutant sec7 kex2-1, indicating that Kex2p is central to the in vivo processing. Consistent with this, a KEX2 deletion mutant secreted form A exclusively. Conversion of A into B was also prevented in sec7 cells by the presence of dinitrophenol, a poison that depletes ATP levels, indicating that processing is dependent upon intracellular transport which involves ER --> Golgi and/or, at least, one intra-Golgi step(s). It follows that this transport step(s) is independent of functional Sec7p.

Two ionic forms of exoglucanase in yeast secretory mutants

Analysis of exoglucanase activity accumulated by sec mutants from Saccharomyces cerevisiae revealed the presence of two ionic forms of the major exoglucanase (exo II) secreted into the culture medium. From the accumulation pattern of representative sec mutants and the carbohydrate composition it appears that the less acidic form is converted into the more acidic one by addition of one phosphate to one of the oligosaccharide cores as the enzyme progresses through the secretory pathway. Exoglucanase I, the heavier isoenzyme, was not accumulated by the mutants. Accordingly, it should arise from exoglucanase II after the execution point of sec1 mutation.

Disruption and phenotypic analysis of six open reading frames from the left arm of Saccharomyces cerevisiae chromosome VII

Six open reading frames (ORFs) from Saccharomyces cerevisiae chromosome VII were deleted using the kanMX4 module and the long‐flanking homology‐PCR replacement strategy in at least two different backgrounds. Among these ORFs, two of them (YGL100w and YGL094c) are now known genes which encode well‐characterized proteins (Seh1p, a nuclear pore protein, and Pan2p, a component of Pab1p‐stimulated poly(A) ribonuclease, respectively). The other four ORFs (YGL101w, YGL099w, YGL098w and YGL096w) code for proteins of unknown function, although the protein encoded by YGL101w has a strong similarity to the hypothetical protein Ybr242p. Gene disruptions were performed in diploid cells using the KanMX4 cassette, and the geneticin (G418)‐resistant transformants were checked by PCR. Tetrad analysis of heterozygous deletant strains revealed that YGL098w is an essential gene for vegetative growth in three backgrounds, whereas the other five genes are non‐essential, although we have found some phenotypes in one of them. YGL099wΔ strain did not grow at all at 15°C and showed a highly impaired sporulation and a significantly lower mating efficiency. The other three deletants did not reveal any significant differences with respect to their parental strains in our basic phenotypic tests. Copyright