Yeast introns contain three highly conserved sequences which are known to be required for splicing of pre‐mRNA. Using in vitro mutagenesis, we have synthesized seven point mutations at five different sites in these signals in the yeast actin intron. The mutant introns were then inserted into each of three constructs, which allowed us to assess the consequences both in vivo and in vitro. In virtually every case, we found the efficiency of splicing to be significantly depressed; mature mRNA levels in vivo ranged from 0 to 47% of wild‐type. Surprisingly, the tightest mutations were not necessarily at the sites of nucleolytic cleavage and branch formation; these nucleotides are thus highly preferred, but are not absolutely necessary. Moreover, while particular nucleotides are specifically required for the final step in splicing, i.e. 3′ cleavage and exon ligation, the predominant consequence of mutation within the conserved signals appears to be the inhibition of assembly of the splicing complex.
The transformation of Aspergillus oryzae has been achieved with a plasmid carrying the Aspergillus nidulans argB gene coding for ornithine carbamoyltransferase (OCTase). The frequency of transformation was relatively low (0.7 transformants/^g DNA)but the transformed phenotype was extremely stable for manygenerations without selective pressure. Southern blot analysis revealed that transformation had occurred by integration of multiple tandem copies of plasmid DNAinto the host genome through non-homologous recombination. There was no evidence of the existence of free plasmid in the transformants. The number of integrated copies of the plasmid ranged from 15 to 60. The specific activity of OCTase in the cellfree extract was proportional to the copy number of the plasmid, indicating that most of the integrated argB gene was expressed. Aspergillus oryzae has been important in fermentation industries in Japan, i.e., sake, shoyu and miso manufacture as well as the production of industrial enzymes. Strain improvement in A. oryzae has been carried out by mutation and protoplast fusion,1} but not yet by genetic transformation, since vectors carrying selectable markers for the development of a transformation system are not readily available.
A gene, designated amyR, coding for a transcriptional activator involved in amylolytic gene expression has been cloned from Aspergillus oryzae by screening for a clone that enabled to reverse the reduced expression of the alpha-amylase gene (amyB) promoter. amyR encodes 604 amino acid residues of a putative DNA-binding protein carrying a zinc binuclear cluster motif (Zn(II)2Cys6) belonging to the GAL4 family of transcription factors. The amyR gene disruptants showed a significant restricted growth on starch medium and produced little of the amylolytic enzymes including alpha-amylase and glucoamylase compared with a non-disruptant, indicating that amyR is a transcriptional activator gene involved in starch/maltose-induced efficient expression of the amylolytic genes in A. oryzae. In addition, sequencing analysis found that amyR, agdA (encoding alpha-glucosidase), and amyA (encoding alpha-amylase), are clustered on a 12-kb DNA fragment of the largest chromosome in A. oryzae, and that amyR is about 1.5 kb upstream of agdA and transcribed in the opposite direction. Furthermore, transcriptional analysis revealed that the amyR gene was expressed in the presence of glucose comparable to the level in the presence of maltose, while the amylolytic genes were transcribed at high levels only in the presence of maltose.
A yeast cell wall glycoprotein with a molecular weight of 40,000, named gp40, was solubilized from SDS-extracted cell wall of Saccharomyces cerevisiae by incubation with Rarobacter faecitabidus protease I, which is a yeast-lytic enzyme. Based on its amino acid sequence, we cloned and sequenced the gene encoding the precursor of gp40, named CWP1; cell wall protein gene. The DNA sequence of the CWP1 gene was identical to YKL443, an open reading frame identified in a genome sequencing program for yeast chromosome XI. This gene encoded a serine-rich protein of 239 amino acids with a molecular weight of 24,267. The presence of hydrophobic sequences in the N- and C-termini of the CWP1 protein suggests that it is secreted as a glycosylphosphatidylinositol-anchored protein and is subsequently integrated into the cell wall. Since a gene disruption experiment showed no growth defect, the CWP1 gene is not essential for growth. Mutant CWP1 protein deficient in the C-terminal hydrophobic sequence was secreted into the culture medium, not anchored to the cell wall, thereby indicating that this hydrophobic sequence plays a crucial role in anchoring to the cell wall. Homology between the CWP1 protein and TIP1 family of cold shock proteins suggests that they belong to a new family of cell wall proteins.
A 260-kDa structural cell wall protein was purified from sodium dodecyl sulfate-treated cell walls of Saccharomyces cerevisiae by incubation with Rarobacter faecitabidusprotease I, which is a yeast-lytic enzyme. Amino acid sequence analysis revealed that this protein is the product of the SED1 gene.SED1 was formerly identified as a multicopy suppressor oferd2, which encodes a protein involved in retrieval of luminal endoplasmic reticulum proteins from the secretory pathway. Sed1p is very rich in threonine and serine and, like other structural cell wall proteins, contains a putative signal sequence for the addition of a glycosylphosphatidylinositol anchor. However, the fact that Sed1p, unlike other cell wall proteins, has six cysteines and seven putative N-glycosylation sites suggests that Sed1p belongs to a new family of cell wall proteins. Epitope-tagged Sed1p was detected in a β-1,3-glucanase extract of cell walls by immunoblot analysis, suggesting that Sed1p is a glucanase-extractable cell wall protein. The expression of Sed1p mRNA increased in the stationary phase and was accompanied by an increase in the Sed1p content of cell walls. Disruption of SED1 had no effect on exponentially growing cells but made stationary-phase cells sensitive to Zymolyase. These results indicate that Sed1p is a major structural cell wall protein in stationary-phase cells and is required for lytic enzyme resistance.
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