Organization of the SUC gene family in Saccharomyces.

The SUC gene family of yeast (Saccharomyces) includes six structural genes for invertase (SUC1 through SUC5 and SUC7) found at unlinked chromosomal loci. A given yeast strain does not usually carry SUC+ alleles at all six loci; the natural negative alleles are called suc0 alleles. Cloned SUC2 DNA probes were used to investigate the physical structure of the SUC gene family in laboratory strains, commercial wine strains, and different Saccharomyces species. The active SUC+ genes are homologous. The suc0 allele at the SUC2 locus (suc2(0) in some strains is a silent gene or pseudogene. Other SUC loci carrying suc0 alleles appear to lack SUC DNA sequences. These findings imply that SUC genes have transposed to different chromosomal locations in closely related Saccharomyces strains.     

Novel genetic components controlling invertase production in Saccharomyces cerevisiae

Low levels of invertase (EC 3.2.1.26) activity were observed in most diploid strains of S. cerevisiae used in this work. There was no effect of mating type on invertase levels, and cell surface was not a limiting factor, because an increase in ploidy did not cause further decrease in specific invertase activity. Finally, some diploids showed the activity expected from the additive effects of different SUC genes, and haploid strains possessing two SUC genes expressed very variable invertase activities depending on the strain. This suggested the existence of one or more additional genes which control the levels of invertase. Genetic analysis of SUC5 strains provided evidence of the existence of a new gene, RPS5, which drastically reduced the specific invertase activity in strains possessing active SUC alleles. The recessive allele of this gene (rps5) allows expression of higher levels of invertase. We suggest that genes similar RPS5 are responsible for the low levels of invertase activity observed in diploid strains of S. cerevisiae.     

SUC1 gene of Saccharomyces: a structural gene for the large (glycoprotein) and small (carbohydrate-free) forms of invertase.

Saccharomyces cerevisiae revertant strain D10-ER1 has been shown to contain thermosensitive forms of the large (glycoprotein) and small (carbohydrate-free) invertases and a very low level of the small enzyme, along with a wild-type level of the large form (T. Mizunaga et al., Mol. Cell. Biol. 1:460-468, 1981). These characteristics cosegregated in crosses of the revertant strain with wild-type sucrose-fermenting (SUC1) or nonfermenting (suc0) strains. In addition, there is tight linkage between sucrose and maltose fermentation in revertant D10-ER1 (characteristic of the SUC1 and MAL1 genes). From this we infer that a single reversion event is responsible for the several changes observed in D10-ER1, and that this mutation maps within or very close to the SUC1 gene present in the ancestor strain 4059-358D. The revertant SUC1 allele in D10-ER1 (termed SUC1-R1) was expressed independently of the wild-type SUC1 gene when both were present in diploid cells. Diploids carrying only the wild-type or the mutant genes synthesized invertases with the characteristics of the parental Suc+ haploids. The possibility that a modifier gene was responsible for the alterations in the invertases of revertant D10-ER1 was ruled out by appropriate crosses. We conclude that SUC1 is a structural gene that codes for both the large and the small forms of invertase and suggest that SUC2 through SUC5 are structural genes as well.     

Evolution of the dispersed SUC gene family of Saccharomyces by rearrangements of chromosome telomeres.

The SUC gene family of Saccharomyces contains six structural genes for invertase (SUC1 through SUC5 and SUC7) which are located on different chromosomes. Most yeast strains do not carry all six SUC genes and instead carry natural negative (suc0) alleles at some or all SUC loci. We determined the physical structures of SUC and suc0 loci. Except for SUC2, which is an unusual member of the family, all of the SUC genes are located very close to telomeres and are flanked by homologous sequences. On the centromere-proximal side of the gene, the conserved region contains X sequences, which are sequences found adjacent to telomeres (C. S. M. Chan and B.-K. Tye, Cell 33:563-573, 1983). On the other side of the gene, the homology includes about 4 kilobases of flanking sequence and then extends into a Y' element, which is an element often found distal to the X sequence at telomeres (Chan and Tye, Cell 33:563-573, 1983). Thus, these SUC genes and flanking sequences are embedded in telomere-adjacent sequences. Chromosomes carrying suc0 alleles (except suc20) lack SUC structural genes and portions of the conserved flanking sequences. The results indicate that the dispersal of SUC genes to different chromosomes occurred by rearrangements of chromosome telomeres.     

Genetic control of invertase formation in Saccharomyces cerevisiae

Summary Nine sucrose nonfermenting mutants have been isolated from yeast strain EK-6B, carrying the tightly linked SUC3 and MAL3 genes. These mutants are allelic to the SUC3 gene recessive in nature and none of them has detectable levels of either internal or external invertase. A single point mutation leading to the loss of both invertases suggests that either SUC3 is a control gene or codes for a polypeptide which is shared by both invertases.     

The structural genes of internal invertases in Saccharomyces cerevisiae.

Summary Polyacrylamide gel electrophoresis (without SDS) of invertases from strains each carrying only one of the five known SUC-genes revealed differences in mobility of the internal enzymes. SUC1 invertase moved distinctly slower than the invertases formed in the presence of genes SUC2 to SUC5. Three bands of internal invertase activity were found in diploids carrying both SUC1 (slow invertase) and one of the other SUC-genes (fast invertases). Tetrad analysis of such diploids yielded haploids which showed the same three bands if they carried SUC1 in combination with another SUC gene. A gene dosage effect was observed in relation to invertase activity in haploid strains with only gene SUC1 or only SUC4 on one hand, and both genes on the other hand. A sucrose non-fermenting and invertase negative strain with mutant allele suc3-3 of gene SUC3 (fast invertase) was crossed with SUC1. The heterozygous diploid and the recombinant haploids (SUC1 suc3-3) showed two bands in the region of the internal invertase: a slow SUC1 band and a second band corresponding to the intermediate band of SUC1-SUC3 strains. The intermediate band in SUC1 suc3-3 strains is considered as a hybrid consisting of an active SUC1-monomer and an inactive suc3-mutant monomer. Formation of such hybrid bands was taken as evidence for the structural nature of SUC-genes.     

白血病细胞中不同启动子驱动外源基因表达能力差异分析

为了分析不同启动子在白血病细胞中驱动外源基因表达能力的差异,文章选择了4种含不同启动子EF1α、PGK、Ubiquitin和CMV驱动的GFP报告基因的慢病毒载体,用以感染4种不同的白血病细胞株——NB4、HL60、Kasumi和THP1,利用荧光显微镜、流式细胞仪和荧光定量PCR的方法检测其GFP表达效率,发现EF1α启动子驱动GFP表达的能力最强,CMV最弱,PGK和Ubiquitin则介于两者之间。该结果提示在白血病细胞中研究基因功能时,应根据不同的研究需求选择最为合适的启动子。     

Use of bacteriocin promoters for gene expression in Lactobacillus plantarum C11

AIMS: To exploit promoters involved in production of the bacteriocin sakacin P for regulated overexpression of genes in Lactobacillus plantarum C11. METHODS AND RESULTS: Production of sakacin P by Lact. sakei LTH673 is controlled by a peptide-based quorum sensing system that drives strong, regulated promoters. One of these promoters (PorfX) was used to establish regulated overexpression of genes encoding chloramphenicol acetyltransferase from Bacillus pumilus, aminopeptidase N from Lactococcus lactis or chitinase B from Serratia marcescens in Lact. plantarum C11, a strain that naturally possesses the regulatory machinery that is necessary for promoter activation. The expression levels obtained were highly dependent on which gene was used and on how the promoter was coupled to this gene. The highest expression levels (14% of total cellular protein) were obtained with the aminopeptidase N gene translationally fused to the regulated promoter. CONCLUSIONS: Sakacin promoters permit regulated expression of a variety of genes in Lact. plantarum C11. SIGNIFICANCE AND IMPACT OF THE STUDY: This study shows the usefulness of regulated bacteriocin promoters for developing new gene expression systems for lactic acid bacteria, in particular lactobacilli.     

Relationship of large and small invertases in Saccharomyces: mutant selectively deficient in small invertase.

A mutant strain of Saccharomyces cerevisiae (D10-ER1) has been isolated after a two-step mutagenesis of strain 4059-358D (SUC 1) using ethyl methane sulfonate. Cells of this new strain produced a level of total invertase equaling that of 4059 but contained only trace amounts of the small, internal, aglycan form of the enzyme (less than 0.1% of total in D10-ER1 compared with 6% in 4059). When D10.ER1 was crossed with an invertase-hyperproducing strain dgr3 (SUC3), progeny were isolated (HZ400-5A and HZ400-2C) in which levels of total invertase had at least quadrupled. The percentage of small invertase, however, remained insignificant. Levels of small invertase in strain HZ400-5A were determined by affinity chromatography on conconavalin A-Sepharose, gel permeation chromatography, and isopycnic centrifugation in CsCl. The large invertase of the SUC1 yeasts described here was found to contain a form apparently greater in size than the large invertase of the SUC2 strain FH4C; this probably reflects a higher content of carbohydrate. The overall results of this study do not support a direct structural relationship between large and small invertases. The implications on invertase biosynthesis and structure are discussed.     

Construction of modular tandem expression vectors for the green alga Chlamydomonas reinhardtii using the Cre/lox-system

The successful expression of foreign genes mainly depends on both a reliable method for transformation and a suitable promoter sequence. We created a series of modular plasmids that facilitate the rapid construction of large tandem vectors for transgene expression under the control of different promoter sequences in Chlamydomonas reinhardtii. Tandem vectors carrying expression cassettes for Renilla luciferase and a metabolic selection marker (ARG7) were manufactured by fusing two plasmids in vitro using Cre/lox site-specific recombination. Supercoiled and linear plasmids were used to transform an arginine auxotrophic Chlamydomonas strain, and rates of co-expression as well as levels of luciferase activity were monitored for frequently used promoters (HSP70A, LHCB1, PSAD, and the chimeric HSP70A/RBCS2). Linearized tandem vectors generally increased the co-expression frequency (up to 77%) compared with standard cotransformation protocols. Most transformants showed a single and complete integration event confirming the close linkage of active selectable marker and reporter gene within the nuclear genome. The analysis of luciferase activity showed expression levels within three orders of magnitude for the promoters used, with the artificial HSP70A/RRBCS2 being the most active. For 69% of all luminescent transformants carrying the HSP70A promoter luciferase expression was enhanced by heatshock, indicating physiological promoter function in a transgenic context.     

Regulation of Harvest-induced Senescence in Broccoli (Brassica oleracea var. italica) by Cytokinin, Ethylene, and Sucrose

Broccoli (Brassica oleracea var. italica) deteriorates rapidly following harvest. The two plant hormones ethylene and cytokinin are known to act antagonistically on harvest-induced senescence in broccoli: ethylene by accelerating the process, and cytokinin by delaying it. To determine the level at which these hormones influenced senescence, we isolated and monitored the expression of genes normally associated with senescence in broccoli florets treated with exogenous 6-benzyl aminopurine (6-BAP), 1-aminocyclopropane-1-carboxylic acid (ACC), a combination of 6-BAP and ACC, and sucrose, in the five days following harvest. Exogenous 6-BAP caused both a reduction (BoACO) and an increase (BoACS) in ethylene biosynthetic gene expression. The expression of genes used as senescence markers, BoCP5 and BoMT1, was reduced, whereas BoCAB1 levels were maintained after harvest in response to exogenous 6-BAP. In addition, the expression of genes encoding sucrose transporters (BoSUC1 and BoSUC2) and carbohydrate metabolizing enzymes (BoINV1 and BoHK1) was also reduced upon 6-BAP feeding. Interestingly, the addition of ACC prevented the 6-BAP-induced increase in expression of BoACS, but 6-BAP negated the ACC-induced increase in expression of BoACO. The culmination of these results indicates a significant role for cytokinin in the delay of senescence. The implication that cytokinin regulates postharvest senescence in broccoli by inhibiting ethylene perception and/or biosynthesis, thus regulating carbohydrate transport and metabolism, as well as senescence-associated gene expression, is discussed and a model presented.     

Construction of a sucrose-fermenting bakers' yeast incapable of hydrolysing fructooligosaccharides.

Fructooligosaccharides stimulate the growth of intestinal bifidobacteria which are related to the favorable health and nutrition of humans and other animals. Since the efficient amount of fructooligosaccharide for an adult human is relatively large (about 5 g per day), its addition to daily foods like bakery goods might be beneficial. However, commercial Bakers' yeast hydrolyses fructooligosaccharides by the action of invertase encoded in SUC genes and ferments the resulting monosaccharides. According to the findings that strains carrying the MAL-constitutive gene and lacking the SUC gene fermented sucrose and not fructooligosaccharide, we constructed a sucrose-fermenting strain, YOY920, incapable of hydrolysing fructooligosaccharide, by cross-breeding a baking strain and a laboratory strain. In a molasses medium, the cell yield of YOY920 was comparable to that of a baking strain FSC6001, and much higher than that of the non-sucrose-fermenting strains. Although fructooligosaccharide inhibited the dough leavening ability of YOY920, white bread containing fructooligosaccharide could be produced in the defined dough formula using the new strain.     

Characterization of promoter function and cell-type-specific expression from viral vectors in the nervous system

Viral vectors have become important tools to effectively transfer genes into terminally differentiated cells, including neurons. However, the rational for selection of the promoter for use in viral vectors remains poorly understood. Comparison of promoters has been complicated by the use of different viral backgrounds, transgenes, and target tissues. Adenoviral vectors were constructed in the same vector background to directly compare three viral promoters, the human cytomegalovirus (CMV) immediate-early promoter, the Rous sarcoma virus (RSV) long terminal repeat, and the adenoviral E1A promoter, driving expression of the Escherichia coli lacZ gene or the gene for the enhanced green fluorescent protein. The temporal patterns, levels of expression, and cytotoxicity from the vectors were analyzed. In sensory neuronal cultures, the CMV promoter produced the highest levels of expression, the RSV promoter produced lower levels, and the E1A promoter produced limited expression. There was no evidence of cytotoxicity produced by the viral vectors. In vivo analyses following stereotaxic injection of the vector into the rat hippocampus demonstrated differences in the cell-type-specific expression from the CMV promoter versus the RSV promoter. In acutely prepared hippocampal brain slices, marked differences in the cell type specificity of expression from the promoters were confirmed. The CMV promoter produced expression in hilar regions and pyramidal neurons, with minimal expression in the dentate gyrus. The RSV promoter produced expression in dentate gyrus neurons. These results demonstrate that the selection of the promoter is critical for the success of the viral vector to express a transgene in specific cell types.