Homologous versus heterologous gene expression in the yeast, Saccharomyces cerevisiae.

DNA sequences normally flanking the highly expressed yeast 3-phosphoglycerate kinase (PGK) gene have been placed adjacent to heterologous mammalian genes on high copy number plasmid vectors and used for expression experiments in yeast. For many genes thus far expressed with this system, expression has been 15-50 times lower than the expression of the natural homologous PGK gene on the same plasmid. We have extensively investigated this dramatic difference and have found that in most cases it is directly proportional to the steady-state levels of mRNAs. We demonstrate this phenomenon and suggest possible causes for this effect on mRNA levels.     

Expression of heteropolymeric ferritin improves iron storage in Saccharomyces cerevisiae

Saccharomyces cerevisiae was engineered to express different amount of heavy (H)- and light (L)-chain subunits of human ferritin by using a low-copy integrative vector (YIp) and a high-copy episomal vector (YEp). In addition to pep4::HIS3 allele, the expression host strain was bred to have the selection markers leu2(-) and ura3(-) for YIplac128 and YEp352, respectively. The heterologous expression of phytase was used to determine the expression capability of the host strain. Expression in the new host strain (2805-a7) was as high as that in the parental strain (2805), which expresses high levels of several foreign genes. Following transformation, Northern and Western blot analyses demonstrated the expression of H- and L-chain genes. The recombinant yeast was more iron tolerant, in that transformed cells formed colonies on plates containing more than 25 mM ferric citrate, whereas none of the recipient strain cells did. Prussian blue staining indicated that the expressed isoferritins were assembled in vivo into a complex that bound iron. The expressed subunits showed a clear preference for the formation of heteropolymers over homopolymers. The molar ratio of H to L chains was estimated to be 1:6.8. The gel-purified heteropolymer took up iron faster than the L homopolymer, and it took up more iron than the H homopolymer did. The iron concentrations in transformants expressing the heteropolymer, L homopolymer, and H homopolymer were 1,004, 760, and 500 micro g per g (dry weight) of recombinant yeast cells, respectively. The results indicate that heterologously expressed H and L subunits coassemble into a heteropolymer in vivo and that the iron-carrying capacity of yeast is further enhanced by the expression of heteropolymeric isoferritin.     

酿酒酵母基因组位置效应对外源基因表达的影响

外源基因元件和模块在底盘细胞中发挥特定功能是合成生物学研究的基本过程,而外源元件和模块在基因组中的位置对其功能的实现具有显著影响。为了系统、全面地表征酿酒酵母基因组位置效应对外源基因的表达影响,以绿色荧光蛋白为报告基因,通过双交换同源重组方法,对酿酒酵母单基因敲除库进行高通量转化,构建酿酒酵母基因组单位点荧光标记菌株库。结合流式细胞术和高通量测序技术对单位点荧光标记库菌株进行分析,构建高表达位点库和低表达位点库,共发现促进绿色荧光蛋白表达的位点428个,抑制绿色荧光蛋白表达的位点444个。通过分析高、低表达位点在酵母染色体上的分布,从全基因组尺度上对酿酒酵母基因组整合位置对基因表达的影响进行表征。本研究可为酿酒酵母基因组位置效应的分布规律和产生机理研究提供重要参考,对外源蛋白工业生产和合成生物学中的基因表达精细调控也具有重要的指导意义。     

Adaptation of Saccharomyces cerevisiae expressing a heterologous protein

Production of the heterologous protein, bovine aprotinin, in Saccharomyces cerevisiae was shown to affect the metabolism of the host cell to various extent depending on the strain genotype. Strains with different genotypes, industrial and laboroatory, respectively, were investigated. The maximal specific growth rate of the strains was reduced by 54% and 33%, respectively, upon the introduction of the gene encoding aprotinin. Growing the strains in sequential shake flask cultivations for 250 generations led to an increased maximal specific growth rate and a decrease in the yield of aprotinin as a result of the adaptation. Determination of the level of mRNA encoding aprotinin and the plasmid copy number pointed to different mechanisms responsible for the decline in aprotinin yield in the different strains.     

Characterization of a gene encoding Trametes versicolor laccase A and improved heterologous expression in Saccharomyces cerevisiae by decreased cultivation temperature

Laccase can be used for enzymatic detoxification of lignocellulosic hydrolysates. A Saccharomyces cerevisiae strain with enhanced resistance to phenolic inhibitors and thereby improved ability to ferment lignocellulosic hydrolysates would presumably be obtained by heterologous expression of laccase. Sequencing of the cDNA for the novel laccase gene lcc2 from the lignin-degrading basidiomycete Trametes versicolor showed that it encodes an isoenzyme of 499 amino-acid residues preceded by a 21-residue signal peptide. By comparison with Edman degradation data, it was concluded that lcc2 encodes an isoenzyme corresponding to laccase A. The gene product of lcc2 displays 71% identity with the previously characterized T. versicolor lcc1 gene product. An alignment of laccase sequences revealed that the T. versicolor isoenzymes in general are more closely related to corresponding isoenzymes from other white-rot fungi than to the other T. versicolor isoenzymes. The multiplicity of laccase is thus a conserved feature of T. versicolor and related species of white-rot fungi. When the T. versicolor lcc2 cDNA was expressed in S. cerevisiae, the production of active enzyme was strongly dependent on the temperature. After 3 days of incubation, a 16-fold higher laccase activity was found when a positive transformant was kept at 19 °C instead of 28 °C. Similar experiments with Pichia pastoris expressing the T. versicolor laccase gene lcc1 also showed that the expression level was favoured considerably by lower cultivation temperature, indicating that the observation made for the S. cerevisiae expression system is of general significance. Received: 8 December 1998 / Received revision: 9 April 1999 / Accepted: 16 April 1999     

Nodamura virus RNA replication in Saccharomyces cerevisiae: heterologous gene expression allows replication-dependent colony formation

Nodamura virus (NoV) and Flock House virus (FHV) are members of the family Nodaviridae. The nodavirus genome is composed of two positive-sense RNA segments: RNA1 encodes the viral RNA-dependent RNA polymerase and RNA2 encodes the capsid protein precursor. A small subgenomic RNA3, which encodes nonstructural proteins B1 and B2, is transcribed from RNA1 during RNA replication. Previously, FHV was shown to replicate both of its genomic RNAs and to transcribe RNA3 in transiently transfected yeast cells. FHV RNAs and their derivatives could also be expressed from plasmids containing RNA polymerase II promoters. Here we show that all of these features can be recapitulated for NoV, the only nodavirus that productively infects mammals. Inducible plasmid-based systems were used to characterize the RNA replication requirements for NoV RNA1 and RNA2 in Saccharomyces cerevisiae. Induced NoV RNA1 replication was robust. Three previously described NoV RNA1 mutants behaved in yeast as they had in mammalian cells. Yeast colonies were selected from cells expressing NoV RNA1, and RNA2 replicons that encoded yeast nutritional markers, from plasmids. Unexpectedly, these NoV RNA replication-dependent yeast colonies were recovered at frequencies 10(4)-fold lower than in the analogous FHV system. Molecular analysis revealed that some of the NoV RNA replication-dependent colonies contained mutations in the NoV B2 open reading frame in the replicating viral RNA. In addition, we found that NoV RNA1 could support limited replication of a deletion derivative of the heterologous FHV RNA2 that expressed the yeast HIS3 selectable marker, resulting in formation of HIS+ colonies.     

Enhancement of stress tolerance and ethanol production in Saccharomyces cerevisiae by heterologous expression of a trehalose biosynthetic gene from Streptomyces albus

The ability to grow and produce ethanol under stressful conditions is an important factor in industrial bioethanol production. Trehalose is found in many organisms including Saccharomyces cerevisiae, and has been known to play an important role in enhancing various types of stress tolerance. In this study, Streptomyces albus trehalose-6-phosphate synthase gene (salC) was expressed in Saccharomyces cerevisiae, and the recombinant strain with salC gene showed significantly improved stress resistances and ethanol production. The stress sensitivity and viability tests indicated that the recombinant had a greater resistance to ethanol than the control. At elevated temperatures, the results of flask cultures showed that the expression of salC played a positive role in protecting cells from heat stress. The recombinant strain was found to consume 100 g/L glucose and to produce 39 g/L ethanol at 40°C with an ethanol yield 6% higher than that of the control strain. In the fed-batch experiment in a bioreactor the recombinant strain produced 69 g/L ethanol with about 16% higher yield and about 13% higher productivity than the control strain. This demonstrated the enhancement of ethanol production capabilities of the recombinant strain under a high-ethanol stress condition.     

Energetics of l-proline uptake by Saccharomyces cerevisiae

l-Proline is transported into the yeast Saccharomyces cerevisiae against a concentration gradient of up to 135:1, the gradient decreasing with increasing proline concentration and suspension density. The concentrative uptake is practically unaffected by inhibitors, except antimycin. It is markedly reduced by anaerobic conditions. Uptake of l-proline, either by normal cells or in the presence of inhibitors, elicits no alkalification of the medium (estimated by pH and conductivity measurements) and no membrane depolarization (estimated by distribution of tetraphenylphosphonium). There is no relationship between the electrochemical potential gradient of protons and the measured accumulation ratios of proline. Likewise, intracellular ATP levels bear little relation to the accumulation. If, based on analogy with other yeasts and bacteria, l-proline is symported with H⁺ ions the process must occur in local domains of the membrane where both the ΔpH and the membrane potential may differ substantially from those measured in the bulk solution.     

A vector for construction of gene libraries and the expression of heterologous genes in Saccharomyces cerevisiae

We have constructed a convenient new vector, YEp-DE, for the construction of gene libraries and the expression of heterologous genes in Saccharomyces cerevisiae. The vector contains the yeast LEU2 gene, the 2 mu origin of replication, and a region from pUC18 that includes the ampr gene, the Escherichia coli origin of replication (ori), and the LacZ gene with multiple cloning sites. Five sites (Sac1, Sma1, BamH1, Sal1, Sph1) in this region are unique. This vector has advantages over similar yeast-E. coli shuttle vectors: small size (7291 bp, entirely sequenced), convenient cloning sites, and lacZ selection for detecting recombinant plasmids.     

Expression of the cloned uracil permease gene of Saccharomyces cerevisiae in a heterologous membrane

A piece of DNA of the yeast Saccharomyces cerevisiae complementing the uracil permease gene was introduced into a plasmid able to replicate autonomously in Schizosaccharomyces pombe. A strain of S. pombe lacking uracil transport activity was transformed with this new plasmid carrying the gene of S. cerevisiae. The behaviour of the transformant shows not only an expression of the uracil permease gene in the heterologous membrane but also that the transport of uracil is active and coupled to the energy furnishing system of the heterologous host.