High-copy-number integration into the ribosomal DNA of Saccharomyces cerevisiae: a new vector for high-level expression.

Yeast vectors suitable for high-level expression of heterologous proteins should combine a high copy number with a high mitotic stability under non-selective conditions. Since high stability can best be assured by integration of the vector into chromosomal DNA we have set out to design a vector that is able to integrate into the yeast genome in a large number of copies. The rDNA locus appeared to be an attractive target for such multiple integration since it encompasses 100-200 tandemly repeated units. Plasmids containing several kb of rDNA for targeted homologous recombination, as well as the deficient LEU2-d selection marker were constructed and, after transformation into yeast, tested for both copy number and stability. One of these plasmids, designated pMIRY2 (for multiple integration into ribosomal DNA in yeast), was found to be present in 100-200 copies per cell by restriction analysis. The pMIRY2 transformants retained 80-100% of the plasmid copies over a period of 70 generations of growth in batch culture under non-selective conditions. To explore the potential of pMIRY2 as an expression vector we have inserted the homologous genes for phosphoglycerate kinase (PGK) and Mn2+-dependent superoxide dismutase (SOD) as well as the heterologous genes for thaumatin from Thaumatococcus danielli (under the GAPDH promoter), into this plasmid and analyzed the yield of the various proteins. Under optimized conditions the level of PGK in cells transformed with pMIRY2-PGK was about 50% of total soluble protein. The yield of thaumatin in the pMIRY2-thaumatin transformants exceeded by about a factor of 100 the level of thaumatin observed in transformants carrying only a single thaumatin gene integrated at the TRP1 locus in chromosome IV.

Cloning, characterization and overexpression of the phytase-encoding gene (phyA) of Aspergillus niger.

Phytase catalyzes the hydrolysis of phytate (myo-inositol hexakisphosphate) to myo-inositol and inorganic phosphate. A gene (phyA) of Aspergillus niger NRRL3135 coding for extracellular, glycosylated phytase was isolated using degenerate oligodeoxyribonucleotides deduced from phytase amino acid (aa) sequences. Nucleotide (nt) sequence analysis of the cloned region revealed the presence of an open reading frame coding for 467 aa and interrupted once by an intron of 102 bp in the 5' part of the gene. The start codon is followed by a sequence coding for a putative signal peptide. Expression of phyA is controlled at the level of mRNA accumulation in response to inorganic phosphate levels. After cell growth in low-phosphate medium, a transcript of about 1.8 kb was visualized. Transcription of phyA initiates at at least seven start points within a region located 45-25 nt upstream from the start codon. In transformants of A. niger, expression of multiple copies of phyA resulted in up to more than tenfold higher phytase levels than in the wild-type strain.

Cloning and characterization of the acyl-coenzyme A: 6-aminopenicillanic-acid-acyltransferase gene of Penicillium chrysogenum.

A gene, aat, encoding acyl-CoA: 6-aminopenicillanic acid acyltransferase (AAT), the last enzyme of the penicillin (Pn) biosynthetic pathway, has been cloned from the genome of Penicillium chrysogenum AS-P-78. The gene contains three introns in the 5'-region and encodes a protein of 357 amino acids with an Mr of 39,943. It complements mutants of P. chrysogenum deficient in AAT activity. The aat gene is expressed as a 1.15-kb transcript and the encoded protein appears to be processed post-translationally into two nonidentical polypeptides of 102 and 255 aa, with Mrs of 11,498 and 28,461, respectively. Three proteins of 40, 11, and 29 kDa (the last one corresponding to the previously purified AAT), were identified in extracts of P. chrysogenum. The aa sequence of the N-terminal end of the 11-kDa polypeptide matched the nucleotide (nt) sequence of the 5'-region of aat. The N-terminal end of the 29-kDa polypeptide corresponded to the sequence beginning at nt position 916 of the sequenced DNA fragment (nt 441 of aat gene). The aat gene of P. chrysogenum resembles the genes encoding Pn acylases of Escherichia coli, Proteus rettgeri and Pseudomonas sp., all of which encode two nonidentical subunits derived from a common precursor, encoded by a single open reading frame.

Strain improvement of Penicillium chrysogenum by recombinant DNA techniques.

The penDE gene from Penicillium chrysogenum has been isolated; the gene is located in close vicinity of the pcbC gene. Amplification of the pcbC-penDE gene cluster in Penicillium chrysogenum Wis54-1255 leads to a significant increase in penicillin production. In selected transformants an increase of up to 40% is observed.

Two genes involved in penicillin biosynthesis are linked in a 5.1 kb SalI fragment in the genome of Penicillium chrysogenum.

Two genes, pcbC and penDE (also named ips and aat, respectively) encoding the enzymes isopenicillin N synthase and acyl-CoA:6-amino penicillanic acid (6-APA) acyltransferase, which are involved in the penicillin biosynthetic pathway in Penicillium chrysogenum, were cloned. Both genes are clustered together in a 5.1 kb SalI DNA fragment and are separated by a nontranscribed intergenic region of 1.5 kb. These genes are transcribed from different promoters in two separate transcripts of about 1.15 kb each. The penDE gene complements mutants of P. chrysogenum deficient in acyltransferase and the pcbC gene increases the level of isopenicillin N synthase in strains containing low levels of this enzyme. The clustering of penicillin biosynthetic genes is of great interest in the light of previous claims of horizontal transfer of the pcbC gene from beta-lactam producing Streptomyces to filamentous fungi.

Transcription of an artificial ribosomal RNA gene in yeast.

We constructed an artificial yeast rRNA gene and studied its transcription after introduction into a recipient yeast strain. The artificial gene comprised a fragment containing the sequence from position -207 to +128 relative to the site of initiation of Saccharomyces carlsbergensis 37S pre-rRNA, followed by a marker fragment from Spirodela oligorhiza chloroplast DNA and finally a fragment containing the sequence from position -36 to +101 relative to the 3' end of the 26S rRNA gene. The resulting construct was cloned into the yeast-Escherichia coli shuttle vector pJDB207. Both Northern blot hybridization and R-loop analysis of RNA from transformed Saccharomyces cerevisiae cells revealed a discrete transcript of the expected length. S1 nuclease mapping as well as primer extension analysis showed that the major proportion of the transcripts was initiated at exactly the same site as 37S pre-rRNA. These results show that the respective rDNA fragments contain the information for correct initiation of transcription and formation of the 3' end. A minor proportion of the transcripts was initiated at a number of sites between positions -1 and -100 upstream of the predominant start. The proportion and the pattern of these upstream starts is affected by the vector context of the artificial rRNA gene.

Deletion mapping of the yeast Pol I promoter.

Deletions in the promoter region of the 37S pre-rRNA operon in yeast were constructed and analysed in vivo using an artificial ribosomal minigene present on an extrachromosomal yeast vector. Sequences required for correct transcription initiation were found to be located between positions -192 and +15 relative to the start; a 5'-deletion down to position -133 reduces the transcription yield of the minigene at least five-fold. To allow detection of transcription of the minigene in isolated nuclei of yeast transformed with a minigene-bearing plasmid we attempted to increase the minigene copy number. The transcription yield in vivo appeared not to be proportional to the copy number but was found to be greatly enhanced when two or three minigenes are present in tandem. alpha-Amanitin sensitivity of transcription of these minigenes in isolated nuclei proved that RNA polymerase I is responsible for their transcription.

The genes coding for histone H3 and H4 in Neurospora crassa are unique and contain intervening sequences.

Sequences coding for histone H3 and H4 of Neurospora crassa could be identified in genomic digests with the use of the corresponding genes from sea urchin and X. laevis as hybridization probes. A 2.6 kb HindIII-generated N. crassa DNA fragment, showing homology with the heterologous histone H3-gene probes was cloned in a charon 21A vector. Using DNA from this clone as a homologous hybridization probe a 6.9 kb SalI-generated DNA fragment was isolated which in addition to the histone H3-gene also contains the gene coding for histone H4. Several lines of evidence demonstrate the presence of only a single histone H3- as well as a single histone H4-gene in N. crassa. The two genes are physically linked on the genome. DNA sequencing of the N. crassa histone H3- and H4-genes confirmed their identity and, in addition, revealed the presence of one short intron (67 bp) within the coding sequence of the H3-gene and even two introns (68 and 69 bp) within the H4-gene. The amino acid sequences of the N. crassa histones H3 and H4, as deduced from the DNA sequences, and those of the corresponding yeast histones differ only at a few positions. Much larger sequence differences, however, are observed at the DNA level, reflecting a diverging codon usage in the two lower eukaryotes.

3'-End formation of transcripts from the yeast rRNA operon.

Deletion analysis of artificial rRNA minigenes transformed into Saccharomyces cerevisiae revealed that a 110 bp long fragment corresponding to positions -36 to +74 relative to the 3'-end of the 26S rRNA gene, is both necessary and sufficient for obtaining transcripts whose 3'-termini are identical to those of 26S and 37S (pre-)rRNA. These termini are produced via processing of longer transcripts because in an rna 82.1 mutant the majority of the minigene transcripts extend further downstream. Since the rna 82.1 mutation inactivates an endonuclease involved in the 3'-processing of 5S pre-rRNA it is concluded that the maturation of 37S- and that of 5S pre-rRNA requires a common factor. Comparison of the spacer sequences between Saccharomyces carlsbergensis, Saccharomyces rosei and Hansenula wingei revealed several conserved sequence blocks within the region between +10 and +55. These conserved sequence tracts, which are part of a longer region showing dyad symmetry, are supposed to be involved in the interaction with the processing component(s). Deletion of the sequences required for the formation of the 3'-ends of 26S rRNA and 37S pre-rRNA revealed a putative terminator for transcription by RNA polymerase I situated at position +210. This site maps within a DNA fragment that also contains the enhancing element for rDNA transcription by RNA polymerase I.