Triallelic complementation and hybrid enzyme formation in Chlamydomonas reinhardi

Summary In Chlamydomonas, the arg-7 cistron (linkage group I) is the structural gene for the multimeric (probably pentameric) enzyme argininosuccinate lyase. Most of the alleles of the cistron were previously shown to complement in some pair combinations, giving rise to phenotypically wild-type diploids.By crossing diploid (mt^-) and haploid (mt⁺) cells bearing different markers of auxotrophy, seven different presumptive triploid strains, phenotypically wild-type, were isolated. Each strain had 3 different arg-7 alleles or 2 mutant alleles associated with a wild one.The isolates were cytologically and biochemically analyzed: it could be concluded that they were triploid or ar least trisomic for the linkage group I.The specific activity and the thermosensitivity of the lyase were compared in the different triploids and in the diploids bearing two of the three corresponding arg-7 alleles. In most cases, the enzyme formed by triallelic complementation was more active and more heat resistant than the enzyme formed by diallelic complementation. These results can be interpreted by assuming that hybrid enzyme is formed by interaction between the products of the three different alleles. They provide a molecular basis for explaining the increased vigor often found in polyploids.     

Developmental genetic analysis of lethal alleles at the ewg locus and their effects on muscle development in Drosophila melanogaster

The recessive X-linked mutation erect wing (ewg), in Drosophila melanogaster, was characterized as a flightless behavioral mutant which specifically lacked the dorsal longitudinal flight muscles [1]. This mutation was mapped distal to the X chromosomal locus yellow, and further to the cytological segment 1 A 1 to 1 B2-3 [2]. Several lethal complementation groups have been mapped to this interval [3]. Our complementation tests show that ewg is allelic to one lethal complementation group in the region 1 A 1 to 1 B2-3. A further analysis of ewg and several lethal alleles isolated at this locus was undertaken in the present investigation. Most of the lethal alleles at this locus lead to a late embryonic or early larval lethal phase, indicating that the ewg⁺ gene product is necessary for the development of more than just the dorsal longitudinal flight muscles. Intragenic complementation was observed for some of the ewg lethal alleles. Genetic mosaics with ewg lethal alleles showed that mutant cell clones in cuticular structures are viable. Mosaic analysis is consistent with a mesodermal defect associated with the locus.     

Genetic characterization of the 44D-45B region of the Drosophila melanogaster genome based on an F2 lethal screen

We have performed an F₂ genetic screen to identify lethal mutations that map to the 44D-45B region of the Drosophila melanogaster genome. By screening 8500 mutagenized chromosomes for lethality over Df(2R)Np3, a deficiency which encompasses nearly 1% of the D. melanogaster euchromatic genome, we recovered 125 lines with lethal mutations that represent 38 complementation groups. The lethal mutations have been mapped to deficiencies that span the 44D-45B region, producing an approximate map position for each complementation group. Lethal mutations were analyzed to determine the phase of development at which lethality occurred. In addition, we have linked some of the complementation groups to P element-induced lethals that map to 44D-45B, thus possibly providing new alleles of a previously tagged gene. Some of the complementation groups represent potentially novel alleles of previously identified genes that map to the region. Several genes have been mapped by molecular means to the 44D-45B region, but do not have any reported mutant alleles. This screen may have uncovered mutant alleles of these genes. The results of complementation tests with previously identified genes in 44D-45B suggests that over half of the complementation groups identified in this screen may be novel. Received: 13 July 1999 / Accepted: 4 November 1999     

Genetic analysis by somatic hybridization of cytokinin overproducing developmental mutants of the moss, Physcomitrella patens

Summary Cytokinins are important regulators of growth and development in lower and higher eukaryotic plants. Genetic analysis by means of somatic hybridization, achieved through protoplast fusion, revealed that, of 15 independently isolated gametophore and cytokinin over-producing (OVE) mutants in the model system,Physcomitrella patens, 14 carry recessive mutations responsible for this abnormal phenotype. Seven of these strains have been assigned to three complementation groups:OVEA, OVEB andOVEC. A further three strains have been demonstrated not to belong to theOVEA group and another mutant does not fall into groupOVEB. Phenotypic segregation ratios among progeny obtained following self-fertilization of a number of different somatic hybrids showed that severalOVE mutations behave as recessive alleles of single Mendelian genes.     

prp4 from Schizosaccharomyces pombe, a mutant deficient in pre-mRNA splicing isolated using genes containing artificial introns

Summary We have generated a bank of temperature-sensitive (ts) Schizosaccharomyces pombe mutant strains. About 150 of these mutants were transformed with a ura4 gene containing an artificial intron. We screened these is mutants for mutants deficient in splicing of the ura4 intron. With this approach three mutants were isolated which have a general defect in the splicing process. Two of these mutants fall into the prp1 complementation group and one defines a new complementation group, prp4.     

Double mutants of Phycomyces with abnormal phototropism

Summary Seven genes (madA to madG) are known which effect phototropism in Phycomyces. These genes have been partially ordered with respect to the associated stimulus-response pathway. Mutants affected in these genes serve as useful probes of photosensory transduction processes in this model system. To extend and deepen the analysis of the system, we have constructed a family of 21 double mutants in all combinations for the seven mad genes. A set of seven standard alleles was adopted for this work. The double mutants were isolated from crosses between isogenic single-mutant strains of opposite mating type. After a partial physiologic screening of the progeny, the double mutants were identified by complementation tests using single-mutant strains of known genotype. For all but three of the double mutants, the photogeotropism phenotypes were distinct from those of the respective single-mutant parentals. One triple mutant (madA madB madC) was constructed as part of this work. Various applications of the double mutants and the triple mutant are discussed. Recombination analyses were performed on the progeny from seven mad crosses to complete an earlier study. The results establish that all seven mad genes are unlinked.     

Five genetic loci involved in the synthesis of acidic exopolysaccharides are closely linked in the genome of Rhizobium sp strain NGR234

Summary R-prime plasmids were constructed from a derivative of Rhizobium strain NGR234 (ANU280) and were shown to contain overlapping genomic DNA segments involved in biosynthesis of exopolysaccharides (EPS). The R-primes originally constructed carried the mutant allele from Tn5-induced EPS-deficient (Exo^–) mutant ANU2811. This plasmid-located mutant allele was dominant to the corresponding wild-type allele as merodiploid strains were Exo^–. Exo⁺ revertants occurred at a low rate (1×10^-7) and these were shown to result from double reciprocal recombination events, which led to the isolation of R-prime plasmids carrying functional wild-type exo alleles. R-prime plasmids that carry overlapping segments of DNA from parental strain ANU280 complemented 28 of the 30 group 2 Exo^– mutants of strain ANU280. Complementation of these Exo^– mutants also restored their symbiotic abilities of effective nodulation. Subsequent in vivo recombination between the wild-type alleles located on the R-prime and the corresponding mutated allele on the genome, was used to generate a new family of R-primes, which carried mutations in the exo genes. The 30 group 2 Exo^– mutants were classified into 7 distinct genetic groups based upon complementation and physical mapping data. Five of the seven exo loci were gentically linked and located on a 15-kb region of DNA. Mutations at two loci were dominant only when the mutations were R-prime plasmid-located while a mutation at a second locus was cis-dominant to two other exo loci. At least five genes involved in the synthesis of acidic exopolysaccharide synthesis have been identified.     

双组分系统rcsC基因影响禽致病性大肠杆菌的致病性及相关生物学特性

【目的】双组分系统Rcs感受外界环境变化,并调控细菌的适应性及生存等。本文探讨Rcs双组分系统传感器激酶RcsC对禽致病性大肠杆菌(avian pathogenic Escherichia coli,APEC)相关生物学特性及致病性的影响。【方法】采用Red同源重组的方法构建rcsC基因缺失株,并利用互补质粒构建互补株,然后比较野生株、基因缺失株与互补株的生长特性、运动性、生物被膜、凝集沉淀能力、致病力及毒力基因转录水平的差异。【结果】rcsC基因缺失不影响APEC的生长速度,然而,缺失RcsC导致APEC的运动能力升高、生物被膜形成能力降低和凝集能力增强。凝集试验结果显示rcsC基因有助于APEC的凝集沉降。细胞黏附入侵结果表明,rcsC在APEC侵袭DF-1细胞过程中发挥作用,而对黏附能力无影响。动物感染试验结果表明rcsC基因缺失能显著降低APEC的毒力。荧光定量PCR检测结果表明,rcsC基因缺失株中ompA、aatA、fyuA和luxS基因的转录水平均显著降低,而fimC和tsh基因的转录水平显著升高。【结论】RcsC参与调控APEC的运动性、生物被膜形成、凝集沉降和致病力。     

Isolation and Characterization of Chemotaxis Mutants of Chlamydomonas reinhardtii

Zoospores of Chlamydomonas reinhardtii exhibit chemotaxis towards maltose, sucrose, xylose, mannitol, and ammonium. Ten independent mutants defective in chemotaxis towards sugars have been isolated. These mutants form five phenotypic classes. Genetic analysis of two mutant strains defective in chemotaxis to maltose (CHE1, CHE3) and two mutant strains defective in chemotaxis to sucrose (CHE2, CHE4) indicated that the defect in them depended on single nuclear recessive mutant alleles. Mutations mal1, mal2, suc1, and suc2 represent four chemotactic loci that are unlinked to the marker mt located on the linkage group VI. Four loci are unlinked to each other. These observations suggest that the mal and the suc loci do not constitute a spatially single functional group.     

Expanding the ku70 toolbox for filamentous fungi: establishment of complementation vectors and recipient strains for advanced gene analyses

Mutants with a defective non-homologous-end-joining (NHEJ) pathway have boosted functional genomics in filamentous fungi as they are very efficient recipient strains for gene-targeting approaches, achieving homologous recombination frequencies up to 100%. For example, deletion of the ku70 homologous gene kusA in Aspergillus niger resulted in a recipient strain in which deletions of essential or non-essential genes can efficiently be obtained. To verify that the mutant phenotype observed is the result of a gene deletion, a complementation approach has to be performed. Here, an intact copy of the gene is transformed back to the mutant, where it should integrate ectopically into the genome. However, ectopic complementation is difficult in NHEJ-deficient strains, and the gene will preferably integrate via homologous recombination at its endogenous locus. To circumvent that problem, we have constructed autonomously replicating vectors useful for many filamentous fungi which contain either the pyrG allele or a hygromycin resistance gene as selectable markers. Under selective conditions, the plasmids are maintained, allowing complementation analyses; once the selective pressure is removed, the plasmid becomes lost and the mutant phenotype prevails. Another disadvantage of NHEJ-defective strains is their increased sensitivity towards DNA damaging conditions such as radiation. Thus, mutant analyses in these genetic backgrounds are limited and can even be obscured by pleiotropic effects. The use of sexual crossings for the restoration of the NHEJ pathway is, however, impossible in imperfect filamentous fungi such as A. niger. We have therefore established a transiently disrupted kusA strain as recipient strain for gene-targeting approaches.     

Yeast cell-cycle mutantcdc21 is a temperature-sensitive thymidylate auxotroph

Summary Genetic tests with the yeast cell-cycle mutantcdc21 isolated by Hartwell indicate that the CDC21 gene in yeast is the same as the TMP1 gene, whose mutant alleles confer an auxotrophic requirement for thymidine-5-monophosphate (dTMP). Yeast strains carryingcdc21 can grow at 37° in the presence of dTMP provided that they are permeable to this compound. The gene is shown to be linked toade2 on Chr. XV, and a case of intragenic complementation betweencdc21 and anothertmp1 allele is reported.     

The genetic fine structure of the complex locus aro3 involved in early aromatic amino acid biosynthesis in Schizosaccharomyces pombe.

Summary The complex locus aro3 of Schizosaccharomyces pombe was subjected to genetical fine structure analysis. By comparing the complementation map and the meiotic recombination map, the aro3 locus could be subdivided into the five adjacent subregions A, B, C, D and E. Out of 115 aro3 alleles, 26 nonsense alleles and 30 missense alleles could be identified by the criteria of nonsense suppressor sensitivity and leakiness, respectively. Most alleles with a pleiotropic complementation pattern are of the nonsense type. We conclude from the polarity of the complementation patterns characterising the nonsense alleles that the translation direction proceeds from subregion A to subregion E. Antipolar effects in complementation are more frequent than in the analogous system of the arom gene cluster of Neurospora crassa.This work formed part of a Ph.D. thesis submitted to the University of Bern     

A method for rapid mapping of mutations by plasmid rescue strategy inSaccharomyces cerevisiae

The products ofPRP17 andPRP18 genes are required for the second step of pre-mRNA splicing reactions inSaccharomyces cerevisiae. Temperature-sensitive mutants at either of these loci accumulate products of the first splicing reaction at nonpermissive temperature. To characterize functional regions in these proteins the mutations in three temperature-sensitive alleles ofPRP17 and two temperature-sensitive alleles ofPRP18 were mapped by the plasmid rescue strategy, One of the procedures adopted in the past is plasmid rescue of the mutant allele followed by sequencing of the entire gene. In this work we describe an adaptation of the above procedure that allows, first, rapid mapping of chromosomal segments bearing the mutations, followed by sequence characterization of the minimal segment. The strategy adopted was to integrate a wild-type copy of the gene at the homologous mutant chromosomal locus, followed by recovery of the chromosomal fragments from these integrants as plasmids inE. coli. The recovered plasmids were screened by a complementation assay for those that contained in them the chromosomal mutation. The mutations in all the three alleles ofPRP17 map to a small region in the N-terminal half of the protein, whereas the temperature-sensitive mutations in the two alleles ofPRP18 map to different regions of the PRP18 protein. The recovered mutant plasmids from all five alleles at the two loci were sequenced and the nucleotide changes were found to result in missense mutations in each case. Our strategy is therefore a rapid method to map chromosomal mutations and is of general use in structure-function analysis of cloned genes.     

Mutational analysis of the MAL1 locus of Saccharomyces: identification and functional characterization of three genes

Summary Fermentation of maltose by Saccharomyces strains depends on the presence of any one of five unlinked MAL loci (MAL1, MAL2, MAL3, MAL4 or MAL6). Earlier mutational analyses of MAL2 and MAL6 containing strains have identified a single complementation group at each of these two loci. However complementation analysis between naturally occurring Mal^– Saccharomyces strains isolated from the wild demonstrated the presence of two complementation groups (designated MALp and MALg) at the MAL1, MAL3 and MAL6 loci. The available evidence suggests that the MALp gene is functionally equivalent to the complementation group identified by mutational analysis at the MAL6 locus and that this gene encodes a protein involved in the regulation of the coordinate induction of both maltase and maltose permease synthesis.In this paper we report the isolation, in a well characterized MAL1 strain, of 47 mutants unable to ferment maltose. All the mutants, with one exception, map at the MAL1 locus. These mal1 mutants, except for one, are recessive to MAL1 and fall into two major complementation groups. Evidence is presented that these two classes of mutants identify both a gene involved in the regulation of maltose fermentation (MAL1R) and a gene involved in maltose transport (MAL1T). We also report here the isolation of a temperature sensitive maltose nonfermenting mutant mapping at the MAL1 locus identifying a third gene (MAL1S) at this locus. The maltase synthesized by this mutant, when assayed in cell-free extracts, is significantly more thermolabile than the wild type enzyme. Our findings demonstrate that MAL1 is a complex locus comprising at least three genes: MAL1R, a gene involved in the coordinate regulation of the synthesis of maltase and maltose transport; MAL1T, a gene encoding a component of the maltose transport system; and MAL1S, a likely candidate for the structural gene for maltase.     

Heat shock induces chromosome loss in the yeast Candida albicans

Summary The heat shock protocol described in this paper causes mitotic instability in log phase Candida albicans cells. Such instability is induced in diploid, aneuploid and tetraploid strains. The strains analysed are multiple heterozygotes which facilitates the detection of mitotic instability as manifested by the formation of homozygotes. Strains previously shows to be carrying cis linked mutant alleles show coincident segregation of the linked alleles. Conversely, strains which carry unlinked mutant alleles display no such coincident segregation. This segregation of complete linkage groups suggests that heat shock is inducing chromosome some loss in C. albicans. The application of this protocol to the genetics of the imperfect fungus C. albicans has produced evidence of at least three chromosomes.     

苹果树腐烂病菌非核糖体多肽合成酶基因VmNRPS12的功能

【目的】非核糖体多肽合成酶(NRPS)在植物病原真菌与其寄主互作过程中发挥着重要作用,明确Vm NRPS12基因在苹果树腐烂病菌致病过程中的功能,将为今后深入研究苹果树腐烂病菌NRPS作用机制提供理论依据。【方法】基于苹果树腐烂病菌全基因组数据,得到VmNRPS12基因。运用qRT-PCR技术分析VmNRPS12在侵染初期的表达水平,利用Double-joint PCR和PEG介导的原生质体转化获得该基因抗潮霉素的突变体,对突变体进行PCR检测及Southern blot验证得到敲除突变体,进一步通过重新导入该基因全长片段获得互补突变体,最后对野生型、敲除突变体和互补突变体进行菌落、产孢及致病力观察,对检测数据用SPSS软件进行差异显著性分析。【结果】定量分析显示该基因在侵染初期显著上调表达,且接种48 h后的表达量是对照的138.6倍。该基因的敲除突变体在营养生长及产孢方面与野生型菌株03-8相比无显著性差异,但致病力与野生型菌株03-8相比显著减弱,且互补突变体致病力近似恢复至野生型水平。【结论】VmNRPS12基因与苹果树腐烂病菌致病性相关。     

Biochemical analysis of mutants defective in nitrate assimilation in Neurospora crassa: evidence for autogenous control by nitrate reductase

Summary A biochemical analysis of mutants altered for nitrate assimilation in Neurospora crassa is described. Mutant alleles at each of the nine nit (nitrate-nonutilizing) loci were assayed for nitrate reductase activity, for three partial activities of nitrate reductase, and for nitrite reductase activity. In each case, the enzyme deficiency was consistent with data obtained from growth tests and complementation tests in previous studies. The mutant strains at these nit loci were also examined for altered regulation of enzyme synthesis. Such exeriments revealed that mutations which affect the structural integrity of the native nitrate reductase molecule can result in constitutive synthesis of this enzyme protein and of nitrite reductase. These results provide very strong evidence that, as in Aspergillus nidulans, nitrate reductase autogenously regulates the pathway of nitrate assimilation. However, only mutants at the nit-2 locus affect the regulation of this pathway by nitrogen metabolite repression.     

Construction and Analyses of Mutant <Emphasis Type="Italic">ftsH</Emphasis> Alleles of <Emphasis Type="Italic">Bacillus subtilis</Emphasis> Involving the ATPase- and Zn-Binding Domains

The ftsH gene, present in all eubacterial species, is anchored in the cytoplasmic membrane and contains an ATP- and a Zn-binding domain that are both part of a metalloprotease activity. The Bacillus subtilis ftsH is not essential, but null mutants exhibit a pleiotropic phenotype including filamentous growth; hypersensitivity towards heat and salt stress and a failure to sporulate. To find out whether one or the other functional domain is involved in these different phenotypes, point mutations were introduced into the coding region for both domains leading to a replacement of conserved amino acid residues. The mutant alleles were fused to a xylose-inducible promoter and integrated ectopically into two different strains, one expressing the wild-type ftsH allele and the other carrying a ftsH knockout. While none of the strains exhibited a growth defect in rich medium at 37°C, those strains expressing only the mutant alleles did not resume growth after heat or salt stress challenge. Furthermore, none of the mutant alleles promoted sporulation. While only those purified mutant FtsH proteins with an intact Walker A box exhibited ATPase activity, all of them failed to degrade -casein.     

青枯雷尔氏菌胞外多糖合成缺失突变株构建及其生物学特性

【目的】由青枯雷尔氏菌(Ralstonia solanacearum)引起的植物青枯病是一种毁灭性土传病害。胞外多糖(extracellular polysaccharides,EPS)是青枯雷尔氏菌关键的致病因子之一。通过构建胞外多糖缺失突变株,研究胞外多糖在青枯病致病中的作用。【方法】从青枯雷尔氏菌FJAT-91的基因组中克隆出胞外多糖合成结构基因epsD同源臂,克隆至自杀性质粒p K18mobsacB,再将庆大霉素抗性基因(Gm)插入同源臂中间,获得重组质粒p K18-epsD。将重组质粒转化至青枯雷尔氏菌FJAT-91感受态细胞中,通过同源重组敲除epsD基因,获得EPS合成缺失的突变株FJAT-91Δeps 。研究突变株与野生菌株在菌落形态、胞外多糖合成、运动能力、定殖能力的差异性。【结果】突变菌株FJAT-91ΔepsD与出发菌株FJAT-91相比:胞外多糖产量显著减少,生长较慢;泳动能力(swimming motility)和群集运动能力(swarming motility)显著降低;在番茄苗根部和茎部的定殖能力显著降低;弱化指数(AI)为0.905,鉴定为无致病力菌株。【结论】胞外多糖在青枯雷尔氏菌的致病中起着关键的作用,本课题研究成果为开发植物疫苗提供了优良的材料与研究基础。