In vivo restriction of Escherichia coli-transforming DNA by endonuclease R.M.EcoRI

Transformation of Escherichia coli K-12 for various chromosomal markers was accomplished by using AB1157 recBC+ strain as a recipient. The yield of transformants was reduced 10-fold, as compared with that obtained in JC7623 recBC sbcB recipient. Elimination of transformation has been obtained for arg, pro, his markers in AB1157 (pSA14) harbouring the R.M.EcoRI coding plasmid. Production of restriction endonuclease in this strain did not affect the efficiency of transformation for thr, leu markers. The presence of pSA25 which is isogenic to pSA14 but devoid of R.M.EcoRI genes has been irrelevant to transformation for leu, arg, pro, his, thr markers. Correlation between the restriction of transformed markers in vivo and in vitro is discussed.     

Genetic complementation of the Saccharomyces cerevisiae leu2 gene by the Escherichia coli leuB gene.

The leucine operon of Escherichia coli was cloned on a plasmid possessing both E. coli and Saccharomyces cerevisiae replication origins. This plasmid, pEH25, transformed leuA, leuB, and leuD auxotrophs of E. coli to prototrophy; it also transformed leu2 auxotrophs of S. cerevisiae to prototrophy. beta-Isopropylmalate dehydrogenase was encoded by the leuB gene of E. coli and the leu2 gene of yeast. Verification that the leuB gene present on pEH26 was responsible for complementing yeast leu2 was obtained by isolating in E. coli several leuB mutations that resided on the plasmid. These mutant leuB- plasmids were no longer capable of complementing leu2 in S. cerevisiae. We conclude that S. cerevisiae is capable of transcribing at least a portion of the polycistronic leu operon of E. coli and can translate a functional protein from at least the second gene of this operon. The yeast Leu+ transformants obtained with pEH25, when cultured in minimal medium lacking leucine, grew with a doubling time three to four times longer than when cultured in medium supplemented with leucine.     

Meiotic Gene Conversion and Crossing over between Dispersed Homologous Sequences Occurs Frequently in Saccharomyces cerevisiae

We have examined meiotic recombination between two defined leu2 heteroalleles present at the normal LEU2 locus and in leu2-containing plasmids inserted at four other genomic locations. In diploids where the two leu2 markers were present at allelic locations on parental homologs, the frequency of Leu2+ spores varied 38-fold, in a location-dependent manner. These results indicate that recombination in a genetic interval can be modulated by sequences at least 2.7 kb outside that interval. Leu2+ meiotic segregants were also recovered from diploids where LEU2 was marked with one heteroallele, and the other leu2 heteroallele was inserted at another genomic location. These products of ectopic interactions, between dispersed copies of leu2 sharing only 2.2 kb of homology, were recovered at a frequency comparable to that observed in corresponding allelic crosses. This high frequency of ectopic meiotic recombination was observed in crosses where both recombining partners could potentially pair with sequences at an allelic position. In addition, a significant fraction (22-50%) of these ectopic recombinants were associated with crossing over of flanking sequences.     

非随机方法构建酿酒酵母基因工程菌

酿酒酵母是基因工程产品研究和生产的一个重要表达系统,表达载体和宿主细胞是构成表达系统的两大要素,虽然外源基因表达的方式、强度主要由表达载体控制．但宿主细胞的选择对最终获取产品的质量和数量也具有十分关键的作用。酿酒酵母基因工程宿主菌除要求具有高的DNA转化效率、细胞生长密度和稳定性、低的内源蛋白水解酶活性外,还必须具备与表达载体相对应的营养缺陷筛选标记,用传统随机诱变方法得到的营养缺陷变异株,因含有本底和隐性突变,在细胞生长密度和稳定性方面往往不能满足基因工程产品研究和生产的要求,甚至不能有效地表达外源基因。本文报道用重组技术,通过非随机方法构建了酿酒酵母基因工程宿主茁。研究表明用该方法得到的宿主菌在细胞生长密度、稳定性和表达外源基因方面优于用传统随机诱变方法得到的宿主菌。     

Construction of two new vectors for transformation of laboratory,natural and industrial<Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> strains to trifluoroleucine and G418 resistance

Two new plasmids, pEC3 and pECkan, were constructed and their use in yeast transformation described. Both plasmids are derivative of the pRS416 vector, in which the URA3 auxotrophic marker was replaced by the LEU4* gene (pEC3) or the kanMX4 gene (pECkan). pEC3 and pECkan plasmids transformed natural and commercial Saccharomyces cerevisiae strains to 5,5,5-trifluoro-DL-leucine and G418 (aminoglycoside related to gentamicin) resistance, respectively, with efficiency ranging from 10(-5) to 10(-7) transformants per number of viable cells. pEC3 transformed the Leu- laboratory strain, carrying the mutations leu4 leu9, to leucine prototrophy with efficiency of approximately 10(-4).     

Extrachromosomal Recombination Is Deranged in the Rec2 Mutant of Ustilago Maydis

Transformation of a leu1 auxotroph of Ustilago maydis to prototrophy with an autonomously replicating plasmid containing the selectable LEU1 gene was found to be efficient regardless of whether the transforming DNA was circular or linear. When pairs of autonomously replicating plasmids bearing noncomplementing leu1 alleles were used to cotransform strains deleted entirely for the genomic copy of the LEU1 gene, Leu+ transformants were observed to arise by extrachromosomal recombination. The frequency of recombination increased severalfold when one plasmid of the pair was made linear by cleavage at one end of the leu1 gene, but increased 10-100-fold when both plasmids were first made linear. The increase in recombination noted in wild-type and rec1 strains was not apparent in the rec2 mutant unless the members of the pair of plasmids were cut at opposite ends of the leu1 gene to yield linear molecules offset in only one of the two possible configurations. Use of a pair of plasmid substrates designed to measure nonreciprocal and multiple exchange events revealed only a minor fraction of the total events arise through these modes, and further that no stimulation occurred when the plasmid DNA was linear. It is unlikely that the defect in rec2 lies in a mismatch correction step since a high yield of Leu+ recombinants was obtained from the rec2 mutant when it was transformed with heteroduplex DNA constructed from plasmids with the two different leu1 alleles.     

Construction of a Quadruple Auxotrophic Mutant of an Industrial Polyploid Saccharomyces cerevisiae Strain by Using RNA-Guided Cas9 Nuclease

Industrial polyploid yeast strains harbor numerous beneficial traits but suffer from a lack of available auxotrophic markers for genetic manipulation. Here we demonstrated a quick and efficient strategy to generate auxotrophic markers in industrial polyploid yeast strains with the RNA-guided Cas9 nuclease. We successfully constructed a quadruple auxotrophic mutant of a popular industrial polyploid yeast strain, Saccharomyces cerevisiae ATCC 4124, with ura3, trp1, leu2, and his3 auxotrophies through RNA-guided Cas9 nuclease. Even though multiple alleles of auxotrophic marker genes had to be disrupted simultaneously, we observed knockouts in up to 60% of the positive colonies after targeted gene disruption. In addition, growth-based spotting assays and fermentation experiments showed that the auxotrophic mutants inherited the beneficial traits of the parental strain, such as tolerance of major fermentation inhibitors and high temperature. Moreover, the auxotrophic mutants could be transformed with plasmids containing selection marker genes. These results indicate that precise gene disruptions based on the RNA-guided Cas9 nuclease now enable metabolic engineering of polyploid S. cerevisiae strains that have been widely used in the wine, beer, and fermentation industries.     

pULB113, an RP4::mini-Mu plasmid, mediates chromosomal mobilization and R-prime formation in Erwinia amylovora, Erwinia chrysanthemi, and subspecies of Erwinia carotovora.

The RP4::mini-Mu plasmid pULB113, transferred from Escherichia coli strain MXR, was stable and transfer proficient in Erwinia amylovora strain EA303, E. carotovora subsp. atroseptica strain ECA12, E. carotovora subsp. carotovora strain ECC193, and E. chrysanthemi strain EC183. The plasmid mobilized an array of Erwinia sp. chromosomal markers (E. amylovora: his+,ilv+,rbs+,ser+,thr+;E. chrysanthemi:arg+,his+,ilv+,leu+; E. carotovora subsp. atroseptica: arg+,gua+,leu+,lys+,pur+,trp+; E. carotovora subsp. carotovora: arg+,gua+,leu+,lys+,out+[export of enzymes],pur+,trp+), suggesting random interactions of the plasmid with the chromosomes. In E. carotovora subsp. carotovora, pULB113-mediated two-factor crosses revealed linkage between three auxotrophic markers and the out loci. The export of pectate lyase, polygalacturonase, and cellulase and the maceration of potato tuber tissue occurred with Out+, but not Out-, strains of E. carotovora subsp. carotovora, indicating the importance of enzyme export in plant tissue maceration. Erwinia sp. donors harboring pULB113 complemented mutations in various biosynthetic and catabolic genes (arg, gal, his, leu, met, pro, pur, thy) in Escherichia coli recA strains. Escherichia coli transconjugants harbored pULB113 primes as indicated by the cotransfer of Erwinia genes and pULB113 markers and a change in plasmid mass. Moreover, the PstI and SmaI cleavage patterns of selected pULB113 primes were different from those of pULB113. pULB113 primes carried DNA insertions ranging from 3 to about 160 kilobases. These findings indicate that pULB113 is useful for in vivo gene cloning and genetic analysis of various enterobacterial phytopathogens.     

pULB113, an RP4::mini-Mu plasmid, mediates chromosomal mobilization and R-prime formation in Erwinia amylovora, Erwinia chrysanthemi, and subspecies of Erwinia carotovora

The RP4::mini-Mu plasmid pULB113, transferred from Escherichia coli strain MXR, was stable and transfer proficient in Erwinia amylovora strain EA303, E. carotovora subsp. atroseptica strain ECA12, E. carotovora subsp. carotovora strain ECC193, and E. chrysanthemi strain EC183. The plasmid mobilized an array of Erwinia sp. chromosomal markers (E. amylovora: his+,ilv+,rbs+,ser+,thr+;E. chrysanthemi:arg+,his+,ilv+,leu+; E. carotovora subsp. atroseptica: arg+,gua+,leu+,lys+,pur+,trp+; E. carotovora subsp. carotovora: arg+,gua+,leu+,lys+,out+[export of enzymes],pur+,trp+), suggesting random interactions of the plasmid with the chromosomes. In E. carotovora subsp. carotovora, pULB113-mediated two-factor crosses revealed linkage between three auxotrophic markers and the out loci. The export of pectate lyase, polygalacturonase, and cellulase and the maceration of potato tuber tissue occurred with Out+, but not Out-, strains of E. carotovora subsp. carotovora, indicating the importance of enzyme export in plant tissue maceration. Erwinia sp. donors harboring pULB113 complemented mutations in various biosynthetic and catabolic genes (arg, gal, his, leu, met, pro, pur, thy) in Escherichia coli recA strains. Escherichia coli transconjugants harbored pULB113 primes as indicated by the cotransfer of Erwinia genes and pULB113 markers and a change in plasmid mass. Moreover, the PstI and SmaI cleavage patterns of selected pULB113 primes were different from those of pULB113. pULB113 primes carried DNA insertions ranging from 3 to about 160 kilobases. These findings indicate that pULB113 is useful for in vivo gene cloning and genetic analysis of various enterobacterial phytopathogens.     

Conservation and transfer of Escherichia coli genetic segments by partial diploid Hfr strains of Salmonella typhosa

Heterozygous, partial diploid hybrids were obtained in a Salmonella typhosa Hfr strain by using it as the recipient in a mating with the Escherichia coli Hfr donor WR2004 (O...proA...leu). Three of these S. typhosa Hfr hybrids were observed to mobilize and transfer the diploid E. coli genes, at high frequencies, to an E. coli recipient. The gradient of transfer frequencies of E. coli markers from these S. typhosa Hfr hybrids was similar to that observed with E. coli Hfr WR2004, from which they were derived. Interrupted matings with one of these S. typhosa Hfr hybrids, designated WR4272, showed the entry times for the proA, thr(-)leu, and argB E. coli diploid markers to be identical to the times obtained for these markers with E. coli Hfr WR2004. Also, the pattern of unselected inheritance of the diploid E. coli markers of S. typhosa Hfr hybrid WR4272 was similar to that observed with the chromosomal markers of E. coli Hfr WR2004. It was concluded that S. typhosa Hfr hybrid WR4272 contains, in addition to its Salmonella genome, a physically continuous E. coli chromosomal segment which is genetically complete from proA to at least the strA locus. The two other S. typhosa Hfr hybrids, on the basis of transmission frequency gradients, appeared to contain a continuous E. coli diploid segment complete from proA through the fuc locus. Other classes of S. typhosa Hfr hybrids, derived from mating with E. coli Hfr WR2010 (O...tna...xyl), were also observed to transfer E. coli genes at high frequency.     

The presence of a defective LEU2 gene on 2 mu DNA recombinant plasmids of Saccharomyces cerevisiae is responsible for curing and high copy number.

The copy number of 2 mu DNA-derived plasmids in CIR+ Saccharomyces cerevisiae transformants is determined by its selective marker and is usually much lower than that of the endogenous plasmid. Only plasmids containing the leu2 allele of pJDB219, designated as leu2-d, under selective conditions displayed a higher copy number than did endogenous 2 mu DNA and by displacement generated cured cells. Spontaneous loss of 2 mu DNA occurred with a frequency of about 0.02% per generation. Curing plasmids, like pMP78, have copy numbers of 35; noncuring plasmids, like pDB248 or YEp6, have copy numbers of 4 to 8. The 2 mu DNA copy number in strains AH22 and YNN27 were determined to be 40 and 100, respectively. The high copy number of leu2-d-containing plasmids can be explained by its weak expression of less than 5% that of the wild-type LEU2 gene. The leu2-d allele has a deletion of the 5'-end sequence starting from 29 base pairs before the ATG initiation codon, but surprisingly, its expression is still regulated. On YRp7, which contains the chromosomal autonomic replication sequence ARS1, the defective leu2-d allele could not complement a leu2 host strain. This suggests a more stringent control of replication of ARS1-containing plasmids than of 2 mu-containing plasmids.     

Genetic analysis of the polyauxotrophy of the early mitotic progeny of Saccharomyces cerevisiae zygotes. III. The behavior of the chromosome-III markers in polyauxotrophic clones and their mitotic and meiotic segregants

Cloning and segregation analysis of polyauxotrophic (PA) progeny, as well as the study of diploid segregants, revealed an unusual state of the diploid genome in these strains. Analysis of linkage markers of chromosome III in all crosses may be expected to illuminate relationships between the homologous chromosomes. All PA strains were assigned to two major classes. In the class of PA strains with recombinant chromosome III, the effect of approachment of third linkage markers was noted. In other strains, transposition of genetic marker metA1 to chromosome III and its linkage to leu2 were discovered. The present study has demonstrated that the unusual state of the diploid genome of PA strains induces multiple nonspecific alterations in chromosome relationship and structure. It is likely that these alterations are the consequence of disturbance in mitotic apparatus of cell.     

Multiple New Genes That Determine Activity for the First Step of Leucine Biosynthesis in Saccharomyces Cerevisiae

The first step in the biosynthesis of leucine is catalyzed by α-isopropylmalate (α-IPM) synthase. In the yeast Saccharomyces cerevisiae, LEU4 encodes the isozyme responsible for the majority of α-IPM synthase activity. Yeast strains that bear disruption alleles of LEU4, however, are Leu(+) and exhibit a level of synthase activity that is 20% of the wild type. To identify the gene or genes that encode this remaining activity, a leu4 disruption strain was mutagenized. The mutations identified define three new complementation groups, designated leu6, leu7 and leu8. Each of these new mutations effect leucine auxotrophy only if a leu4 mutation is present and each results in loss of α-IPM synthase activity. Further analysis suggests that LEU7 and LEU8 are candidates for the gene or genes that encode an α-IPM synthase activity. The results demonstrate that multiple components determine the residual α-IPM synthase activity in leu4 gene disruption strains of S. cerevisiae.     

Cloning, Disruption and Chromosomal Mapping of Yeast LEU3 , a Putative Regulatory Gene

The LEU3 gene of the yeast Saccharomyces cerevisiae, which is involved in the regulation of at least two LEU structural genes (LEU1 and LEU2), has been cloned by complementation of leu3 mutations and shown to reside within a 5.6-kb fragment. Transformation of leu3 mutants with LEU3-carrying multicopy plasmids restored normal, leucine-independent growth behavior in the recipients. It also restored approximately wild-type levels of isopropylmalate isomerase (LEU1) and beta-isopropylmalate dehydrogenase (LEU2), which were strongly reduced when exogenous leucine was supplied. Strains containing a disrupted leu3 allele were constructed by deleting 0.7-kb of LEU3 DNA and inserting the yeast HIS3 gene in its place. Like other leu3 mutants, these strains were leaky leucine auxotrophs, owing to a basal level of expression of LEU1 and LEU2. Southern transfer and genetic analyses of strains carrying a disrupted leu3 allele demonstrated that the cloned gene was LEU3, as opposed to a suppressor. Disruption of LEU3 was performed also with a diploid and shown to be nonlethal by tetrad analysis. Northern transfer experiments showed that the LEU3 gene produces mRNA approximately 2.9 kilonucleotides in length. The leu3 marker was mapped to chromosome XII by the spo11 method. Linkage to ura4 by about 44 centiMorgans places leu3 on the right arm of this chromosome.     

Introduction of a feed back resistant α-isopropylmalate synthase gene of Saccharomyces cerevisiae into sake yeast

A mutant LEU4 gene (LEU4^fbr-2), responsible for both the overproduction of iso-amyl alcohol in yeast and the phenotype of yeast resistant to 5,5,5-trifluoro-dl-leucine (TFL), was isolated from a TFL-resistant mutant of Saccharomyces cerevisiae F-7. The single copy number of LEU4^fbr-2 complemented the leucine auxotrophy of S. cerevisiae HB190 (a, leu4, leu5), and also transformed it to TFL-resistant. Leucine-insensitive α-isopropylmalate synthase activity was detected in the crude extract of the Leu⁺ transformant. Also sake yeast Kyokai no. 7 (K-7) was transformed by the LEU4^fbr-2 gene to TFL-resistant. The resulting transformants produced 3∼30-fold higher levels of iso-amyl alcohol (approx. 50∼475 ppm) in shaking cultures, while in static cultures the increase in productivity was only 2.5-fold compared with that of recipient strain K-7. The isolated LEU4^fbr-2 gene may be useful as a positive selectable marker for the transformation of industrial yeast.     

Cloning and Characterization of Yeast LEU4, One of Two Genes Responsible for α-Isopropylmalate Synthesis

By complementation of an alpha-isopropylmalate synthase-negative mutant of Saccharomyces cerevisiae (leu4 leu5), a plasmid was isolated that carried a structural gene for alpha-isopropylmalate synthase. Restriction mapping and subcloning showed that sequences sufficient for complementation of the leu4 leu5 strain were located within a 2.2-kilobase SalI-PvuII segment. Southern transfer hybridization indicated that the cloned DNA was derived intact from the yeast genome. The cloned gene was identified as LEU4 by integrative transformation that caused gene disruption at the LEU4 locus. When this transformation was performed with a LEU4fbr LEU5 strain, the resulting transformants had lost the 5',5',5'-trifluoro-D,L-leucine resistance of the recipient strain but were still Leu+. When it was performed with a LEU4 leu5 recipient, the resulting transformants were Leu-. The alpha-isopropylmalate synthase of a transformant that carried the LEU4 gene on a multicopy plasmid (in a leu5 background) was characterized biochemically. The transformant contained about 20 times as much alpha-isopropylmalate synthase as wild type. The enzyme was sensitive to inhibition by leucine and coenzyme A, was inactivated by antibody generated against alpha-isopropylmalate synthase purified from wild type and was largely confined to the mitochondria. The subunit molecular weight was 65,000-67,000. Limited proteolysis generated two fragments with molecular weights of about 45,000 and 23,000. Northern transfer hybridization showed that the transformant produced large amounts of LEU4-specific RNA with a length of about 2.1 kilonucleotides. The properties of the plasmid-encoded enzyme resemble those of a previously characterized alpha-isopropylmalate synthase that is predominant in wild-type cells. The existence in yeast of a second alpha-isopropylmalate synthase activity that depends on the presence of an intact LEU5 gene is discussed.     

Unequal crossing-over in conjugated crossings in Escherichia coli K-12

A genetic model has been developed allowing to study non-equal crossingover in conjugative crossings of Escherichia coli. The model is based on obtaining tandem duplications in the region of the deo operon of E. coli in conjugative crosses Hfr x Hfr. It was shown that when using transposon (Tn5, Tn10) genetic markers the majority of recombinant progeny phenotypically corresponding to rare 2-crossover and 4-crossover recombinants for the deo operon constitute direct tandem duplications resulting from non-equal interchromosomal exchange. Apart from the deo operon, the duplications obtained cover, in some cases, linked thr and leu loci. In the crosses, where point mutations for genes of the deo operon served as genetic markers, the frequency of duplications' formation was lower than that of rare 2-crossover and 4-crossover recombinants' formation. Evolutionary role of the non-equal crossingover phenomenon in E. coli is discussed.     

Genetics of Aspergillus flavus: linkage of aflatoxin mutants

Eight aflatoxin (afl) mutants of Aspergillus flavus were induced with N-methyl-N'-nitro-N-nitrosoguanidine. Heterozygous diploids formed between afl mutants and tester strains revealed that each afl mutant was recessive. Haploids selected from these heterozygous diploids indicated the linkage of all eight afl mutants to markers on group VII. These include previously mapped arg-7 (arginine), leu (leucine), dominant afl-1, and nor which accumulates norsolorinic acid that is visible as an orange-red pigment. Diploid complementation tests indicated that all but two afl mutants were nonallelic. Diploids homozygous for nor, resulting from crossing-over, were isolated and used to map new afl genes.     

Translocation of transposons Tn10 and Tn5 in the Yersinia pestis chromosome

The possibility of translocation of the transposons Tn5 and Tn10 into the genome of Yersinia pestis, with the subsequent mutagenic effect was demonstrated. We revealed transposon harbouring clones at frequency 10(-4) to 10(-2). Derivatives of P1cml clr100ts phage served as vectors. Insertion of Tn10 transposon induced mutations in ilv, ser, arg, pur, pro, leu, nic, tyr, gua genes. The number of the insertion sites on the chromosome obtained for Tn5 was the same, these being arg, ade, pyr, leu, gua, trp, his, pan, ilv. The majority of auxotrophs did not revert. Occasionally, revertants were observed at frequencies 10(-8) to 10(-6). Unlike Escherichia coli, reversion was not accompanied by the loss of transposons. The rearrangements induced by transposons, presumably, near the insertion site, as well as duplications of transposons followed by incorporation of copies into novel sites, led to the appearance of additional defective genes, which made it possible to select various types of polyauxotrophs. Based on reiteration of coinciding double and triple mutant markers, we proposed a linkage group of genes within a segment of Y. pestis chromosome: lys ... tyr - ser - arg - ilv - leu - gua - ade(pur) - pro ... his ... pyr ... trp. The reasons for peculiarities of the behaviour of transposons in Y. pestis bacteria are discussed.