Comparison of cell wall proteins of Saccharomyces cerevisiae as anchors for cell surface expression of heterologous proteins.

The carboxyl-terminal regions of five cell wall proteins (Cwp1p, Cwp2p, Ag alpha 1p, Tip1p, and Flo1p) and three potential cell wall proteins (Sed1p, YCR89w, and Tir1p) all proved capable of immobilizing alpha-galactosidase in the cell wall of Saccharomyces cerevisiae. The fraction of the total amount of fusion protein that was localized to the cell wall varied depending on the anchor domain used. The highest proportion of cell wall incorporation was achieved with Cwp2p, Ag alpha 1p, or Sed1p as an anchor. Although 80% of these fusion proteins were incorporated in the cell wall, the total production of alpha-galactosidase-Ag alpha 1p was sixfold lower than that of alpha-galactosidase-Cwp2p and eightfold lower than that of alpha-galactosidase-Sed1p. Differences in mRNA levels were not responsible for this discrepancy, nor was an intracellular accumulation of alpha-galactosidase-Ag alpha 1p detectable. A lower translation efficiency of the alpha-galactosidase-AG alpha 1 fusion construct is most likely to be responsible for the low level of protein production. alpha-Galactosidase immobilized by the carboxyl-terminal 67 amino acids of Cwp2p was most effective in the hydrolysis of the high-molecular-weight substrate guar gum from Cyamopsis tetragonoloba. This indicates that the use of a large anchoring domain does not necessarily result in a better exposure of the immobilized enzyme to the exterior of the yeast cell.

Immobilizing proteins on the surface of yeast cells.

Yeast has a rigid cell wall comprising an outer layer of glycoproteins and an internal skeletal layer of glucan; heterologous proteins can be targeted to the glycoprotein layer and become covalently linked to the glucan skeleton. Yeast is a eukaryote that has 'generally regarded as safe' (GRAS) status, and is easy to cultivate, so it seems ideally suited for applications including the manufacture of recyclable, immobilized, biocatalysts, whole-cell vaccines, the presentation of peptide or antibody libraries, and the presentation of adhesion or metal-binding proteins.

Expression and secretion of antifreeze peptides in the yeast Saccharomyces cerevisiae.

The antifreeze peptide AFP6 from the polar fish Pseudopleuronectus americanus has been expressed in and secreted by the yeast Saccharomyces cerevisiae as a biologically active molecule. The gene for the 37 amino acid long peptide has been chemically synthesized using yeast preferred codons. Subsequently, the gene has been cloned into an episomal expression vector as well as in a multicopy integration vector, which is mitotically more stable. The expression is under the control of the inducible GAL7 promoter. The enzyme alpha-galactosidase has been investigated as a carrier protein to facilitate expression and secretion of AFP. In order to reach increased expression levels, tandem repeats of the AFP gene (up to eight copies) have been cloned. In most cases the genes are efficiently expressed and the products secreted. The expression level amounts to approximately 100 mg/l in the culture medium. In a number of genetic constructs the genes are directly linked and expressed as AFP multimers. In other constructs linker regions have been inserted between the AFP gene copies, that allow the peptide to be processed by specific proteinases, either from the endogenous yeast proteolytic system or from a non-yeast source. The latter requires a separate processing step after yeast cultivation to obtain mature AFP. In all these cases proteolytic processing is incomplete, generating a heterogeneous mixture of mature AFP, carrier and chimeric protein, and/or a mixture of AFP-oligomers. The antifreeze activity has been demonstrated for such mixtures as well as for AFP multimers.

Expression of an alpha-galactosidase gene under control of the homologous inulinase promoter in Kluyveromyces marxianus.

For expression of the alpha-galactosidase gene from Cyamopsis tetragonoloba in Kluyveromyces marxianus CBS 6556 we have used the promoter of the homologous inulinase-encoding gene (INU1). The INU1 gene has been cloned and sequenced and the coding region shows an identity of 59% with the Saccharomyces cerevisiae invertase gene (SUC2). In the 5'-flanking region of INU1 we found a sequence (TAAATCCGGGG) that perfectly matches to the MIG1 binding consensus sequence (WWWWTSYGGGG) of the S. cerevisiae GAL1, GAL4 and SUC2 genes. Using the K. marxianus INU1 promoter and prepro-signal sequence, we obtained a high alpha-galactosidase production level (153 mg/l) and a secretion efficiency of 99%. Both the production level and the secretion efficiency were significantly reduced when the INU1 pro-peptide was deleted. With either the S. cerevisiae PGK or GAL7 promoter we could obtain only low alpha-galactosidase production levels (2 mg/l).

Processing and termination of 23S rRNA-5S rRNA-tRNA(Gly) primary transcripts in Thermus thermophilus HB8.

The two 23S rRNA-5S rRNA-tRNAGly operons from the extreme thermophilic eubacterium Thermus thermophilus HB8 were used to characterized the in vivo processing and termination of 23S rRNA-5S rRNA-tRNAGly primary transcripts in this organism by nuclease S1 mapping. A processing site in the pre-23S rRNA 3'-flanking region is located approximately 25 nucleotides upstream of 5S rRNA and precedes a putative 23S-5S rRNA spacer antitermination box A. Cleavage at this site and 5S rRNA 5' end formation were shown to be inseparable events. Termination of transcription at the uridine cluster following the termination-associated hairpin was shown to be efficient but leaky. Subsequent to the operon, a functional promoter was detected whose -35 box coincided with the uridine-rich termination region. The promoter directed synthesis of a beta-galactosidase fusion protein in Escherichia coli.

Characterization of a 17 kDa protein gene upstream from the small cytoplasmic RNA gene of Bacillus subtilis.

The Bacillus subtilis small cytoplasmic RNA (scRNA) is the structural homologue of both the RNA component of the eukaryotic signal recognition particle (SRP) and the Escherichia coli 4.5S RNA, and it can complement the essential function of the latter RNA in vivo. In the course of characterization of the single-copy scRNA gene locus (scr) we identified an open reading frame, termed ORF17, upstream from scr that encodes an acidic 17 kDa protein of unknown function. This analysis involved DNA sequencing, monitoring expression of transcriptional and translational ORF17-cat and ORF17-lacZ fusions, respectively, and purification and sequencing of the ORF17-lacZ fusion protein. Apparently, transcription of ORF17 proceeds into scr. A small portion of the 17 kDa protein shows homology to deoxycytidylate (DCMP) deaminase of bacteriophagphage T2, but no similarity exists to the sequenced SRP-polypeptides or any other known protein sequences.

The Bacillus subtilis small cytoplasmic RNA gene and 'dnaX' map near the chromosomal replication origin.

The Bacillus subtilis small cytoplasmic RNA (scRNA) has an important, although not yet defined function in protein biosynthesis. Here we describe the mapping of the single copy scRNA gene and the flanking homolog to dnaZX of Escherichia coli, termed 'dnaX'. The scRNA gene region of a B. subtilis wild-type strain was marked with a cat gene and mapped by scoring chromosomal cotransformation rates of various mutant strains to chloramphenicol resistance and loss of the mutant phenotypes, respectively. This analysis, together with an EcoRI map comparison, places the scRNA gene and dnaX in the vicinity of recM near the replication origin region of B. subtilis.

Escherichia coli 4.5S RNA gene function can be complemented by heterologous bacterial RNA genes.

The essential 4.5S RNA gene of Escherichia coli can be complemented by 4.5S RNA-like genes from three other eubacteria, including both gram-positive and gram-negative organisms. Two of the genes encode RNAs similar in size to the E. coli species; the third, from Bacillus subtilis, specifies an RNA more than twice as large. The heterologous genes are expressed efficiently in E. coli, and the product RNAs resemble those produced by cognate cells. We conclude that the heterologous RNAs can replace E. coli 4.5S RNA and that the essential function of 4.5S RNA is evolutionarily conserved. A consensus structure is presented for the functionally related 4.5S RNA homologs.

Transcription and processing of Bacillus subtilis small cytoplasmic RNA.

The 271 nucleotides long scRNA (small cytoplasmic RNA) from Bacillus subtilis is structurally related to the Escherichia coli 4.5 S RNA (114 nucleotides), an essential molecule supposed to be involved in protein biosynthesis, but it possesses an additional moiety completely missing in the E. coli 4.5 S RNA. Both RNAs share a conserved hairpin with the eukaryotic 7SL RNAs, which mediate protein translocation as part of the signal recognition particle (SRP). We have cloned and sequenced the entire scRNA gene region from B. subtilis and have studied transcription and processing of the scRNA in B. subtilis by nuclease S1 mapping. This analysis revealed the scRNA gene to constitute a monofunctional transcription unit, expressed from a single promoter to a rho-independent terminator, yielding a precursor which extends the mature scRNA by approximately 40 nucleotides at both ends. Processing of the scRNA apparently involves only two endonucleolytic cuts and occurs first at the 5' end.

The 4.5S RNA gene from Pseudomonas aeruginosa.

The essential 4.5S RNA of Escherichia coli contains a structural motif, which is also present in RNAs from other organisms, i.e. Bacillus subtilis scRNA, Halobacterium halobium 7S RNA and eukaryotic 7SL RNAs. This suggests a common function in all organisms, which could be related to protein translocation, since 7SL RNA is essential for this process in eukaryotes. We have analysed the structure and expression of the 4.5S RNA gene from another gram-negative eubacterium, Pseudomonas aeruginosa. The single copy gene encodes a 113 nucleotides long RNA, which shares 75% sequence homology to the E. coli 4.5S RNA and also exhibits the completely conserved hairpin structure of the corresponding RNAs of B. subtilis and E. coli. Transcription initiates 24 nucleotides upstream from the mature 5' end and exceeds beyond the 4.5S RNA coding region. A distal open reading frame, similar to that described for E. coli, does not exist downstream from the P. aeruginosa 4.5S RNA gene.

Genomic organization of rDNA in Pseudomonas aeruginosa.

We have examined the number and organization of rRNA genes in Pseudomonas aeruginosa by hybridization of restriction nuclease digests of genomic DNA to 3'-32P-labelled 23 S, 16 S and 5 S rRNAs and corresponding labelled DNA from the rrnB operon of Escherichia coli. The immediate conclusion from these hybridization data is that there are 4 transcriptional units coding for rDNA in P. aeruginosa. We report here a putative model of the genomic organization of all 4 rDNA operons.