Analysis of the inducible MEL1 gene of Saccharomyces carlsbergensis and its secreted product, alpha-galactosidase (melibiase)

Rapid construction of large synthetic genes: total chemical synthesis of two different versions of the bovine prochymosin gene

We have tested several different synthesis designs and assembly methodologies to develop an improved gene synthesis strategy which enables significantly longer nucleotide sequences to be easily constructed. This strategy, based in part upon our ability to synthesize high-quality extended-length oligodeoxynucleotides (over 100-mer in length), together with the use of chemical 5'-phosphorylation, and simplified low-melting-temperature agarose gel purification methods, combines ease, speed and high overall efficiency. We show that it is now feasible to synthesize routinely even long genes (at least 1-2 kb). To demonstrate this capability we have chemically synthesized and assembled two different versions of the gene encoding the bovine enzyme prochymosin (prorennin). One gene is essentially the natural bovine prochymosin gene sequence. In the second gene the codons have been optimized with regard to the codon bias of highly expressed yeast genes. Each synthetic gene was in excess of 1100 bp, yet they were assembled from only 13 or 14 pairs of complementary oligodeoxynucleotides (oligos), the average lengths of which were 87 and 82 bp, respectively. The 'mutation' rate was low enough to assess that more than 75% of all such oligo pairs (160-170 total nt) were error-free.

Codon usage in yeast: cluster analysis clearly differentiates highly and lowly expressed genes

Codon usage data has been compiled for 110 yeast genes. Cluster analysis on relative synonymous codon usage revealed two distinct groups of genes. One group corresponds to highly expressed genes, and has much more extreme synonymous codon preference. The pattern of codon usage observed is consistent with that expected if a need to match abundant tRNAs, and intermediacy of tRNA-mRNA interaction energies are important selective constraints. Thus codon usage in the highly expressed group shows a higher correlation with tRNA abundance, a greater degree of third base pyrimidine bias, and a lesser tendency to the A+T richness which is characteristic of the yeast genome. The cluster analysis can be used to predict the likely level of gene expression of any gene, and identifies the pattern of codon usage likely to yield optimal gene expression in yeast.

Expression of synthetic human-lysozyme gene in Saccharomyces cerevisiae: use of a synthetic chicken-lysozyme signal sequence for secretion and processing

A multicopy plasmid was constructed to direct the synthesis and secretion of human lysozyme (HLY) in Saccharomyces cerevisiae. This plasmid contains a synthetic chicken-lysozyme signal sequence (SIG) and a synthetic HLY structural gene, both inserted between the yeast GAL10 promoter and 2 mu plasmid FLP (flip-flop recombination gene) terminator. The resulting plasmid directed the expression of the hybrid pre-lysozyme, with most of the HLY activity secreted into the culture medium and extracellular periplasmic space. The HLY activity in the culture medium increased with cell growth. The yeast accurately processed the hybrid precursor at the junction between the chicken SIG and the coding sequence downstream, yielding mature HLY. HLY purified from the culture medium was homogeneous and displayed specific activity identical to that of authentic HLY.