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.     

Diversification of Paralogous α-Isopropylmalate Synthases by Modulation of Feedback Control and Hetero-Oligomerization in Saccharomyces cerevisiae

Production of α-isopropylmalate (α-IPM) is critical for leucine biosynthesis and for the global control of metabolism. The budding yeast Saccharomyces cerevisiae has two paralogous genes, LEU4 and LEU9, that encode α-IPM synthase (α-IPMS) isozymes. Little is known about the biochemical differences between these two α-IPMS isoenzymes. Here, we show that the Leu4 homodimer is a leucine-sensitive isoform, while the Leu9 homodimer is resistant to such feedback inhibition. The leu4Δ mutant, which expresses only the feedback-resistant Leu9 homodimer, grows slowly with either glucose or ethanol and accumulates elevated pools of leucine; this phenotype is alleviated by the addition of leucine. Transformation of the leu4Δ mutant with a centromeric plasmid carrying LEU4 restored the wild-type phenotype. Bimolecular fluorescent complementation analysis showed that Leu4-Leu9 heterodimeric isozymes are formed in vivo. Purification and kinetic analysis showed that the hetero-oligomeric isozyme has a distinct leucine sensitivity behavior. Determination of α-IPMS activity in ethanol-grown cultures showed that α-IPM biosynthesis and growth under these respiratory conditions depend on the feedback-sensitive Leu4 homodimer. We conclude that retention and further diversification of two yeast α-IPMSs have resulted in a specific regulatory system that controls the leucine–α-IPM biosynthetic pathway by selective feedback sensitivity of homomeric and heterodimeric isoforms.     

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.     

Sulfonylurea-resistant mutants and natural tolerance of cyanobacteria

The herbicide sulfometuron methyl (SM) inhibited the growth of the cyanobacterium Synechococcus sp. PCC7942, but not of Synechocystis sp. PCC6714. The inhibitory effect was alleviated by the simultaneous addition of valine, leucine and isoleucine. SM resistant mutants were isolated from Synechococcus 7942, two types of which were further analysed. In these mutants, SM3/20 and SM2/32, the activity of acetolactate synthase (ALS) — a key enzyme in the biosynthesis of branched-chain amino acids —appeared 2600- and 300-fold, respectively, more resistant to SM than that of their wild type. Strain SM2/32 also exhibited a low level of ALS activity. Although the growth of the latter mutant was extremely inhibited by valine, the sensitivity of its ALS activity to feed-back inhibition by the amino acid was unaltered. At high concentrations valine inhibited growth of the wild type strains and of the mutant SM3/20. Isoleucine alleviated the valine-induced growth inhibition. Unlike that of Synechococcus 7942, the ALS activity of Synechocystis was found to tolerate high concentrations (100-fold) of the herbicide. The study confirms that the SM mutations are correlated with a cyanobacterial ilv gene.Abbreviations ALS acetolactate synthase; ile, isoleucine - leu leucine - NTG N-methyl-N-nitro-N-nitrosoguanidine - SM sulfometuron methyl - SM^r sulfometuron methyl resistant - val valine     

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.     

Trifluoroleucine resistance and regulation of alpha-isopropyl malate synthase in Saccharomyces cerevisiae

Seven spontaneous Saccharomyces cerevisiae mutants that express dominant resistance to 5,5,5-trifluoro-DL-leucine have been characterised at the molecular level. The gene responsible for the resistance was cloned from one of the mutants (FSC2.4). Determination of its nucleotide sequence showed that it was an allele of LEU4 (LEU4-1), the gene that encodes α-isopropyl malate synthase I (α-IPM synthase I), and that the mutation involved a codon deletion localised close to the 3′ end of the LEU4 ORF. Six different point mutations – four transitions and two transversions – were found in the remaining mutants. α-IPM synthase activity was found to be insensitive to feedback inhibition by leucine in five of the strains. In the other two the enzyme was resistant to Zn²⁺-mediated inactivation by Coenzyme A, a previously postulated control mechanism in energy metabolism; as far as we know, this represents the first direct in vivo evidence for this mechanism. The seven mutations define a region, the R-region, involved in both leucine feedback inhibition and in Zn²⁺-mediated inactivation by CoA. Deletion experiments involving the R-region showed that it is also necessary for enzyme activity. Received: 30 September 1998 / Accepted: 20 October 1998     

One-step gene disruption by cotransformation to isolate double auxotrophs in Candida albicans

Summary The Candida albicans LEU2 gene was disrupted by substituting lambda DNA for a small deletion within the LEU2 gene. Cotransformation with a selectable URA3 ARS vector was used to introduce a linear fragment containing the disruption into the genome of a C. albicans ura3 deletion mutant. Cotransformants containing the lambda DNA were identified by colony hybridization and the URA3 plasmid was subsequently cured. Leu2 disrupted heterozygotes were detected by Southern hybridization and one disruptant was subsequently treated with UV irradiation. Only one leu2 ura3 mutant (SGY-484) was isolated out of 11,000 mutagenized cells. SGY-484 was transformed to Leu⁺ with either the C. albicans or Saccharomyces cerevisiae LEU2 gene. Southern hybridization analysis revealed that the mutant is not homozygous for the disruption; the leu2 mutation reverts and is most likely a point mutation. Unexpectedly, an ade2 ura3 mutant was isolated from the same mutagenesis.     

Total deletion of yeast LEU4: further evidence for a second alpha-isopropylmalate synthase and evidence for tight LEU4-MET4 linkage

Using a combination of restriction endonuclease digestion, nuclease BAL 31 treatment, and standard ligation procedures, a 4.4-kb DNA segment that carried the yeast LEU4 gene [encoding alpha-isopropylmalate synthase (IPMS) I] and adjoining sequences was excised from an appropriate plasmid and replaced with the yeast HIS3 gene. The new plasmid was digested to obtain a linear HIS3-carrying fragment flanked by remnants of the LEU4 region. Integrative transformation of a LEU4fbr LEU5+ his3- strain with this fragment resulted in the deletion of the LEU4 gene from the genome of some recipients, as demonstrated by transformant phenotype, genetic analysis and the absence of RNA capable of hybridizing to a LEU4 probe. The leu4 deletion strains remained Leu+. The extract of one such strain contained about 18% of the IPMS activity of wild-type cells. It is concluded that the residual activity is that of a second IPMS (IPMS II) that depends on an intact LEU5 locus. IPMS II was inhibited by leucine, but its sensitivity was about an order of magnitude lower than that of IPMS I. Deletion of the LEU4 region by the method utilized here resulted in an amino acid auxotrophy that could be satisfied by methionine, homocysteine, or cysteine. Complementation tests and genetic analysis demonstrated that the affected gene was MET4. Linkage to MET4 would place the LEU4 gene on the left arm of chromosome XIV.     

A new Escherichia coli gene, fdrA, identified by suppression analysis of dominant negative FtsH mutations

An Escherichia coli membrane protein, FtsH, has been implicated in several cellular processes, including integration of membrane proteins, translocation of secreted proteins, and degradation of some unstable proteins. However, how it takes part in such diverse cellular events is largely unknown. We previously isolated dominant negative ftsH mutations and proposed that FtsH functions in association with some other cellular factor(s). To test this proposal we isolated multicopy suppressors of dominant negative ftsH mutations. One of the multicopy suppressor clones contained an N-terminally truncated version of a new gene that was designated fdrA. The FdrA fragment suppressed both of the phenotypes — increased abnormal translocation of a normally cytoplasmic domain of a model membrane protein and retardation of protein export — caused by dominant negative FtsH proteins. The intact fdrA gene (11.9 min on the chromosome) directed the synthesis of a 60 kDa protein in vitro.     

A <Emphasis Type="Italic">Sordaria macrospora</Emphasis> mutant lacking the <Emphasis Type="Italic">leu1</Emphasis> gene shows a developmental arrest during fruiting body formation

Developmental mutants with defects in fruiting body formation are excellent resources for the identification of genetic components that control cellular differentiation processes in filamentous fungi. The mutant pro4 of the ascomycete Sordaria macrospora is characterized by a developmental arrest during the sexual life cycle. This mutant generates only pre-fruiting bodies (protoperithecia), and is unable to form ascospores. Besides being sterile, pro4 is auxotrophic for leucine. Ascospore analysis revealed that the two phenotypes are genetically linked. After isolation of the wild-type leu1 gene from S. macrospora, complementation experiments demonstrated that the gene was able to restore both prototrophy and fertility in pro4. To investigate the control of leu1 expression, other genes involved in leucine biosynthesis specifically and in the general control of amino acid biosynthesis (“cross-pathway control”) have been analysed using Northern hybridization and quantitative RT-PCR. These analyses demonstrated that genes of leucine biosynthesis are transcribed at higher levels under conditions of amino acid starvation. In addition, the expression data for the cpc1 and cpc2 genes indicate that cross-pathway control is superimposed on leucine-specific regulation of fruiting body development in the leu1 mutant. This was further substantiated by growth experiments in which the wild-type strain was found to show a sterile phenotype when grown on a medium containing the amino acid analogue 5-methyl-tryptophan. Taken together, these data show that pro4 represents a novel mutant type in S. macrospora, in which amino acid starvation acts as a signal that interrupts the development of the fruiting body. Electronic Supplementary Material Supplementary material is available for this article at http://dx.doi.org/10.1007/s00438-005-0021-8     

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.     

Yeast amber suppressors corresponding to tRNA3Leu genes

Amber suppressors previously isolated from the yeast Saccharomyces cerevisiae and belonging to the same phenotypic class (Liebman et al., 1976) were assigned to nine different linkage groups named SUP52 through SUP60. One of these suppressors, SUP52, had been shown to cause the insertion of leucine and had been genetically mapped (Liebman et al., 1977). The following additional amber suppressors were mapped: SUP53 maps near the centromere of chromosome III closely linked to leu2; SUP54 maps on chromosome VII, 6 cM distal to trp5; SUP56 maps on chromosome I, 5.4 cM distal to ade1; SUP57 maps on chromosome VI, closely linked to met10; and SUP58 maps on the left arm of chromosome XI, loosely linked to met14. We show by protein analysis that like SUP52, the suppressors SUP53 through SUP56 are leucine-inserters. Furthermore, by hybridization with a cloned tRNA3Leu probe we demonstrate that at least SUP53, SUP54, SUP55 and SUP56 contain mutations in redundant tRNA3Leu genes because they each generate a new XbaI site in a DNA fragment encompassing a tRNA3Leu gene. These new XbaI sites are predicted by the known sequences of tRNA3Leu genes if the CAA anticodon mutates to the amber suppressing anticodon CTA. It is likely that each of the nine suppressors in this phenotypic class contain similar mutations in different tRNA3Leu genes since we find that there are approximately nine unlinked redundant copies of tRNA3Leu genes in haploid strains.     

A multicopy suppressor ofnin1-1 of the yeastSaccharomyces cerevisiae is a counterpart of theDrosophila melanogaster diphenol oxidase A2 gene,Dox-A2

NIN1 is an essential gene for growth of the yeastSaccharomyces cerevisiae and was recently found to encode a component of the regulatory subunit of the 26S proteasome. Thenin1-1 mutant is temperature sensitive and its main defect is in G₁/S progression and G₂/M progression at non-permissive temperatures. One of the two multicopy suppressors ofnin1-1, SUN2 (SUppressor of Nin1-1), was found to encode a protein of 523 amino acids whose sequence is similar to those ofDrosophila melanogaster diphenol oxidase A2 and the mouse mast-cell Tum^– transplantation antigen, P91A. The C-terminal half of Sun2p was found to be functional as Sun2p at 25° C, 30° C, and 34° C but not at 37° C. The open reading frame (ORF) of theDrosophila diphenol oxidase A2 gene (Dox-A2) was obtained from a lambda phage cDNA library using the polymerase chain reaction technique. TheDox-A2 ORF driven by theTDH3 promoter complemented the phenotype of a strain deleted forsun2. ThisDox-A2-dependent strain was temperature sensitive and accumulated dumb-bell-shaped cells, with an undivided nucleus at the isthmus, after temperature upshift. This morphology is similar to that ofnin1-1 cells kept at a restrictive temperature. These results suggest thatSUN2 is a functional counterpart ofDox-A2 and that these genes play a pivotal role in the cell cycle in each organism.     

Genetic Interaction between the ero1-1 and leu2 Mutations in Saccharomyces cerevisiae

The conditional ero1-1 mutant, deficient in the ER-localized PDI oxidase Ero1p, is blocked in disulfide bond formation under restrictive conditions, such as high temperature, lack of oxygen, or high concentrations of membrane-permeant thiols. Previous studies of the physiological consequences of the ero1-1 mutation were carried out in a leu2 mutant. The ero1-1 leu2 strain does not grow in standard synthetic complete medium at 30 °C, a defect that can be remedied by increasing the L-leucine concentration in the medium or by transforming the ero1-1 leu2 strain with the LEU2 wild-type allele. In addition, the LEU2 gene can partially complement the growth impairment at 37 °C of the ero1-1 leu2 mutant. The leucine transporter Bap2p exhibits a dramatic decrease in stability in an ero1-1 strain, which may account for the pronounced leucine demand observed in the ero1-1 leu2 mutant.     

Leucine biosynthesis and its regulation in the basidiomycete Rhodosporidium toruloides

Complementation tests and enzyme analyses separated 29 leucine auxotrophs of the Basidiomycete Rhodosporidium toruloides into three groups, each deficient in one of the leucine biosynthetic enzymes. The following differences are suggested between the organization of the leucine pathway in R. toruloides and the Ascomycetes Saccharomyces cerevisiae and Neurospora crassa: (1) isopropylmalate, the product of the first enzymic reaction appears not to be an internal inducer of the later enzymes of the pathway; this is consistent with the apparent lack of mutants homologous to the leu3 class in N. crassa and S. cerevisiae; (2) as in S. cerevisiae, but unlike N. crassa, isopropylmalate synthase is under the control of a general cross pathway control system; (3) unlike S. cerevisiae, but like N. crassa, R. toruloides appears to possess only one gene encoding isopropylmalate synthase.Abbreviations IPM Isopropylmalate - EMS methanesulphonic acid, ethyl ester     

Caffeine Sensitivity of the Yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> with Mutant <Emphasis Type="Italic">MCD4</Emphasis> Is Associated with Disturbances of Calcium Homeostasis and Degradation of Misfolded Proteins

MCD4 codes for a protein involved in glycosylphosphatidylinositol synthesis in the yeast Saccharomyces cerevisiae. Some MCD4 mutations have effects potentially unrelated to defects in the synthesis of phospholipids of this group. The ssu21 mutation of MCD4 causes caffeine sensitivity. To study the molecular basis of this phenotype, yeast genes were screened for multicopy suppressors of caffeine sensitivity of the ssu21 mutant. The screening revealed genes involved in aminoglycerophospholipid metabolism, protein degradation, and the unfolded protein response. The suppressor effect of the cloned genes increased at a higher concentration of extracellular calcium. Caffeine sensitivity of the ssu21 mutant appeared to be associated with cytoplasmic accumulation of misfolded proteins.__________Translated from Molekulyarnaya Biologiya, Vol. 39, No. 3, 2005, pp. 464–476.Original Russian Text Copyright © 2005 by Fominov, Ter-Avanesyan.     

Frameshift Suppression in SACCHAROMYCES CEREVISIAE. II. Genetic Properties of Group II Suppressors

Suppressors of ICR-induced mutations that exhibit behavior similar to bacterial frameshift suppressors have been identified in the yeast Saccharomyces cerevisiae. The yeast suppressors have been divided into two groups. One of these groups (Group II: SUF1, SUF3, SUF4, SUF5 and SUF6) appears to include a set of informational suppressors in which the vehicle of suppression is glycyl-tRNA. Some of the genetic properties of Group II suppressors are described in this communication.——Corevertants of the Group II frameshift mutations his4–519 and leu2–3 have been characterized to determine the spectrum of reversion events induced by the frameshift mutagen ICR-170. Seventythree ICR-induced corevertants were analyzed. With the exception of one corevertant, which carried an allele of SUF1, all carried alleles of SUF3 or SUF5. SUF1, SUF3, SUF4 and SUF6 were represented among spontaneous and UV-induced corevertants. In the course of these experiments one of the suppressors was mapped. SUF5, the probable structural gene for tRNA^GLY1, is located between ade2 and ade9 on chromosome XV.——SUF1, SUF4 and SUF6 have novel properties and comprise a distinct subset of suppressors. Although these suppressors show no genetic linkage to each other, they share several common features including lethality in haploid pairwise combinations, reduced tRNA^GLY3 isoacceptor activity and increased efficiency of suppression in strains carrying the cytoplasmically inherited [PSI] element. In addition, strains carrying SUF1, SUF4 or SUF6 are phenotypically unstable and give rise to mitotic Suf⁺ segregants at high frequency. These segregants invariably contain a linked, second-site mutation that maps in or adjacent to the suppressor gene itself. Strains carrying any of these suppressors also give rise to mitotic segregants that exhibit enhanced efficiency of suppression; mutations responsible for this phenotype map at two loci, upf1 and upf2. These genes show no genetic linkage to any of the Group II suppressors.——Methods that permit positive selection for mutants with decreased or enhanced efficiency of suppression have been devised in order to examine large numbers of variants. The importance of these interacting mutants is underscored by their potential utility in studying suppressor function at the molecular level.     

Characterization of Leucine Auxotrophs of the White Rot Basidiomycete Phanerochaete chrysosporium

Six leucine auxotrophic strains of the white rot basidiomycete Phanerochaete chrysosporium were characterized genetically and biochemically. Complementation studies involving the use of heterokaryons identified three leucine complementation groups. Since all of the leucine auxotrophs grew on minimal medium supplemented with α-ketoisocaproate as well as with leucine, the transaminase catalyzing the last step in the leucine pathway was apparently normal in all strains. Therefore, the wild-type, auxotrophic, and several heterokaryotic strains were assayed for the activities of the other enzymes specific to leucine biosynthesis. Leu2 and Leu4 strains (complementation group I) lacked only α-isopropylmalate synthase activity; Leu3 and Leu6 strains (group III) lacked isopropylmalate isomerase activity; and Leu1 and Leu5 strains (group II) lacked β-isopropylmalate dehydrogenase. Heterokaryons formed from leucine auxotrophs of different complementation groups had levels of activity for all three enzymes similar to those found in the wild-type strain.