Auxotrophic mutations related to symbiotic properties of Rhizobium meliloti strain L5-30.

Mutants isolated from effective R. meliloti strain L5-30 which required histidine (his-240), arginine+uracil (arg-55) and cysteine (cys-243, cys-244 and cys-246) showed also loss of effectiveness. Mutant requiring isoleucine+valine (ilv-74) was non-infective. Relation of the metabolic deficiency to the symbiotic properties of these mutants was tested comparing symbiotic response of their prototrophic revertants and transductants. It was found that all revertants and transductants of the strain his-240 were effective which suggests that histidine deficiency was the cause of their ineffectiveness. All revertants and transductants of the cysteine mutants were still ineffective. This result indicates two independent mutations which were not cotransductible. Prototrophic revertants of the mutant arg-55 were ineffective whereas 56.9 percent of transductants appeared effective suggesting close linkage of two mutations. i.e. auxotrophic and the other concerned with symbiotic effectiveness. Though one of 69 prototrophic transductants obtained from the non-nodulating mutant ilv-74 remained non-nodulating, it seems that changes in nodulating ability of the mutant are related to the auxotrophic requirements.     

Chromosomal gene controlling symbiotic nitrogen fixation in Rhizobium meliloti L5-30

Auxotrophic Rhizobium meliloti strain RM 246 carries two independent mutations: in the biosynthesis of cysteine (cys) and symbiotic nitrogen fixation process (fix). These two mutations were mapped by transduction between his-240 and ade-4 markers. Cotransduction frequencies show the following order of genes: his-240 fix-1 cys-246 ade-4.     

Genetic and Metabolic Controls for Sulfate Metabolism in Neurospora crassa: Isolation and Study of Chromate-Resistant and Sulfate Transport-Negative Mutants

Mutants of Neurospora resistant to chromate were selected and all were found to map at a single genetic locus designated as cys-13. The chromate-resistant mutants grow at a wild-type rate on minimal media but are partially deficient in the transport of inorganic sulfate, especially during the conidial stage. An unlinked mutant, cys-14, is sensitive to chromate but transports sulfate during the mycelial stage at only 25% of the wild-type rate; cys-14 also grows at a fully wild-type rate on minimal media. The double-mutant strain, cys-13;cys-14, cannot utilize inorganic sulfate for growth and completely lacks the capacity to transport this anion. The only biochemical lesion that has been detected for the double-mutant strain is its loss in capacity for sulfate transport. Neurospora appears to possess two distinct sulfate permease species encoded by separate genetic loci. The transport system (permease I) encoded by cys-13 predominates in the conidial stage and is replaced by sulfate permease II, encoded by the cys-14 locus, during outgrowth into the mycelial phase. The relationship of these new mutants to cys-3, a regulatory gene that appears to control their expression, is discussed.     

Transductional analysis of chloramphenicol biosynthesis genes in Streptomyces venezuelae.

Auxotrophs isolated from two chloramphenicol-nonproducing mutants of Streptomyces venezuelae included three requiring pyridoxal (Pxl-), VS248 (cml-11 pdx-2), VS253 (cml-11 pdx-3), and VS258 (cml-12 pdx-4), and one requiring thiosulfate, VS263 (cml-12 cys-28). Results of SV1-mediated transductions were consistent with the relative marker order cys-28-cml-12-cml-11-pdx-2,3,4,5, all of which were cotransducible and must therefore span less than 45 kilobases of DNA, the approximate length of DNA packaged by SV1. cys-28 was also cotransducible with arg-4 and arg-6, but arg and pdx were not cotransducible. Results of crosses with donors carrying any one of 11 cml mutations were consistent with the location of all cml mutations between cys-28 and pdx markers. Also, a new Pxl- auxotroph (pdx-6) and two new Cml- mutants were recovered after localized hydroxylamine mutagenesis of a cys-28 cml+ strain derived from VS263 by transduction.     

Classical and molecular genetic analyses of his-3 mutants of Neurospora crassa. II. Southern blot analyses and molecular mechanisms of mutagenicity

Previous studies (Overton et al., Mutation Res., 1989) on specific revertibility of 81 his-3 mutants have shown a correlation between complementation pattern and presumed genetic alteration similar to that shown by ad-3B mutants. In the present study, restriction enzyme analyses were used to further characterize the genetic alterations in individual his-3 mutants. The restriction fragment banding patterns of the majority of mutants were identical with that shown by wild-type 74-OR23-1A and were consistent with expectations based on previous data suggesting that they resulted from single base-pair alterations (Overton et al., Mutation Res., 1989). His-3 mutants with altered banding patterns were only found among those with polarized complementation patterns or noncomplementing mutants. One of the mutants with a polarized complementation pattern, 1-189-83, and another noncomplementing mutant, 1-189-85, are associated with genetic alterations proximal to the his-3 locus. In one other mutant, 1-226-565 (with a polarized complementation pattern), an insertion of approx. 2 kb has occurred in the proximal region of the his-3 locus. Two other mutants, 1-155-270 and 1-155-276 (both noncomplementing), contained a large insertion of approx. 12.8 kb in the proximal region of the his-3 locus.     

Molecular cloning and characterization of the cys-3 regulatory gene of Neurospora crassa.

The regulatory gene cys-3+ controls the synthesis of a number of enzymes involved in sulfur metabolism. cys-3 mutants show a multiple loss of enzymes in different pathways of sulfur metabolism. The cys-3+ gene was isolated by transformation of an aro-9 qa-2 cys-3 inl strain with a clone bank followed by screening with the "sib selection" method. The library used (pRAL1) contained inserts of Sau3a partial digest fragments of about 9 kilobases as well as the Neurospora qa-2+ gene. Double selection for qa-2+ and cys-3+ function was carried out. The transformants obtained with the isolated cys-3+ clone show recovery of the enzyme activities associated with the cys-3 mutation (e.g., arylsulfatase and sulfate permease). Restriction fragment length polymorphism experiments confirmed the identity of the clone, mRNA studies with Northern blots show that the expression of the cys-3+ gene is inducible. In contrast to cys-3+, the cys-3 (P22) mutant gene was not expressed at a higher level under sulfur-derepressed conditions.     

Development of auxotrophic agrobacterium tumefaciens for gene transfer in plant tissue culture

Auxotrophic strains of Agrobacterium tumefaciens were generated for use in liquid co-culture with plant tissue for transient gene expression. Twenty-one auxotrophs were recovered from 1,900 tetracycline-resistant insertional mutants generated with a suicide vector transposon mutagenesis system. Twelve of these auxotrophs were characterized on a nutrient matrix. Isolates were screened for growth in plant cell and root culture, and three auxotrophs were identified that had limited growth: adenine (ade-24), leucine (leu-27), and cysteine (cys-32). Ade-24 displayed poor T-DNA delivery in a transient expression test delivering GUS from a binary vector, while cys-32 displayed the best ability to deliver DNA of these three auxotrophs. The growth yield of cys-32 on cysteine was assessed to provide a quantitative basis for co-culture nutrient supplementation. The utility of cys-32 for delivering T-DNA to plant tissues is demonstrated, where an 85-fold enhancement in GUS expression over wild-type A. tumefaciens was achieved.     

Metabolic suppressors of a regulatory mutant in Neurospora

The synthesis of a number of enzymes of sulfur assimilation in Neurospora crassa is controlled by the sulfur source. Mutants in one regulatory gene, cys-3, are unable to make any of the enzymes. This locus is thought to specify a macromolecule that is required for the expression of the structural genes. A mutant, scon ^c, of another regulatory gene is nonrepressible for the synthesis of the enzymes. We report here the isolation of suppressed scon ^c strains which are actually the double mutant, scon ^c,cys-3. These strains are phenotypically indistinguishable from single mutants at the cys-3 locus. Thus cys-3 is epistatic to scon ^c. Evidence that the expression of the cys-3 gene is itself controlled is also presented.This work is supported by a Public Health Service grant, GM-08995, from the National Institute of General Medical Sciences. One of us (R.L.M.) is supported by a Public Health Service Career Development Award.     

Random mutagenesis of human cytochrome p450 2A6 and screening with indole oxidation products.

Cytochrome P450 (P450) 2A6 mutants from randomized libraries generated in the substrate recognition sequence (SRS) regions were screened in Escherichia coli on the basis of indole metabolism. SRS 3 and 4 libraries yielded colonies that produced indigo at least as well as wild-type (WT) P450 2A6, and some colonies were consistently more blue upon replating. One mutant, F209T, showed indole 3-hydroxylation WT. The double mutant L240C/N297Q consistently produced very blue colonies. Five mutants yielded mixtures of pigments from indole different than WT, as judged by visible spectra and HPLC of products. When bacteria expressing the mutants were grown in the presence of each of 26 substituted indoles, a variety of patterns of formation of different dyes was seen with several of the mutants. This approach has potential value in understanding P450 2A6 function and generating new dyestuffs and other products.     

Characterization of nonattaching mutants of Agrobacterium tumefaciens.

The first step in tumor formation by Agrobacterium tumefaciens is the site-specific binding of the bacteria to plant host cells. Transposon mutants of the bacteria which fail to attach to carrot suspension culture cells were isolated. These mutants showed no significant attachment to carrot cells with either microscopic or viable cell count assays of bacterial binding. The nonattaching mutants were all avirulent. When revertants of the mutants were obtained by enriching for bacteria which do bind to carrot cells, the bacteria were found to have regained the ability to bind to carrot cells and virulence simultaneously. These results suggest that the ability of the bacteria to bind to plant cells is required for virulence. Like the parent strain, all of the nonattaching mutants synthesized cellulose, but unlike the parent strain, they failed to aggregate carrot suspension culture cells. The transposon Tn5, which was used to obtain the mutants, was located on a 12-kilobase EcoRI fragment of the bacterial chromosomal DNA in all of the nonattaching mutants from strain C58. That the mutant phenotype was due to the Tn5 insertion was shown by cloning the Tn5-containing DNA fragment from the mutant bacteria and using it to replace the wild-type fragment in the parent strain by marker exchange. The resulting bacteria had the same mutant phenotype as the original Tn5 mutants; they did not attach to carrot cells, they did not cause the aggregation of carrot cells, and they were avirulent. No difference was seen between the parent strain and the nonattaching mutants in hydrophobicity, motility, flagella, fimbriae, beta-2-glucan content, size of lipopolysaccharide, or ability of the lipopolysaccharide to inhibit bacterial attachment to tissue culture cells. Differences were seen between the parent strain and the nonattaching mutants in the polypeptides removed from the bacteria during the preparation of spheroplasts. Three of the mutants were lacking a polypeptide of about 34 kilodaltons (kDa). One mutant was lacking the 34-kDa polypeptide and another polypeptide of about 38 kDa. The fifth mutant was lacking a polypeptide slightly smaller than the 34-kDa polypeptide missing in the other four mutants. These missing polypeptides all reappeared in the revertants of the mutants. Thus, bacterial binding to plant cells appears to require the presence of these polypeptides.     

Variation in Binding and Virulence of Agrobacterium tumefaciens Chromosomal Virulence (chv) Mutant Bacteria on Different Plant Species

Chromosomal virulence (chv) mutants of Agrobacterium tumefaciens have been reported to be deficient in binding to cells of zinnia, tobacco, and bamboo. The mutants are nonpathogenic on stems of Kalanchoë, sunflower, tomato, Jerusalem artichoke, and tobacco, but they cause tumors on tubers of Solanum tuberosum. We used a root cap cell binding assay to test ability of cells from individual plants of 13 different plant species to bind parent or chv mutant bacteria. The same plants were then inoculated to test for disease response. Cells from nine of the plant species were grossly deficient in their abilities to bind mutant bacteria, and the plants inoculated with mutant bacteria failed to form tumors. In contrast, root cap cells as well as root hairs and root surfaces of S. tuberosum, S. okadae, and S. hougasii bound chv mutant bacteria as well as wild type. Nevertheless, S. tuberosum roots inoculated with mutant bacteria did not develop tumors. Although S. okadae plants inoculated with mutant bacteria formed a few tumors, and S. hougasii developed as many tumors in response to chv mutants as in response to the parent strain, the tumors induced by mutant bacteria were smaller.     

紫云英根瘤菌的exo与nod基因在宿主结瘤过程中的协同作用

紫云英根瘤菌菌株107经转座子Tn5诱变的胞外多糖合成缺陷型变种(Exo~-),在共生性状方面的改变有四种类型。我们选用了仅在宿主根部形成瘤状突起(Calli)的A类(NA-01,NA-02)、形成无效瘤(Nod~ ,Fix~-)的B类(NA-12)及不结瘤的(Nod~-)D类(NA-14)中的四个突变株分别与消除了共生质粒的Exo~ Nod~-变种(热处理变种及ANU-1116)混合接种紫云英幼苗,观察到与D类变种配合的接种组仍不能结瘤,而与A,B两类变种配合的接种组均诱导宿主产生形态正常的无效根瘤,并且该无效瘤全部被Nod~-变种侵占。说明一个表型仍为Exo~ ,但失去共生质粒的Nod~-变种,可在一个含有该质粒的Exo~-变种的帮助下进入根瘤。这提示共生质粒上的结瘤基因(nod)仅与侵染过程的早期有关,瘤的发育尚需根瘤菌的其他基因,其中包括exo基因的参与。 此外,共生质粒缺失的三个异种根瘤菌突变株分别与紫云英根瘤菌Exo~-变种混合接种时,也都在紫云英根部诱导出无效瘤,并且从瘤中能分离到这三个异种菌。表明在最初的识别作用发生后,植物对共生菌的专一性要求有所降低。     

Assembly-defective OmpC mutants of Escherichia coli K-12.

Novel ompC(Dex) alleles were utilized to isolate mutants defective in OmpC biogenesis. These ompC(Dex) alleles also conferred sensitivity to sodium dodecyl sulfate (SDS), which permitted the isolation of SDS-resistant and OmpC-specific phage-resistant mutants that remained Dex+. Many mutants acquired resistance against these lethal agents by lowering the OmpC level present in the outer membrane. In the majority of these mutants, a defect in the assembly (metastable to stable trimer formation) was responsible for lowering OmpC levels. The assembly defects in various mutant OmpC proteins were caused by single-amino-acid substitutions involving the G-39, G-42, G-223, G-224, Q-240, G-251, and G-282 residues of the mature protein. This assembly defect was correctable by an assembly suppressor allele, asmA3. In addition, we investigated one novel OmpC mutant in which an assembly defect was caused by a disulfide bond formation between two nonnative cysteine residues. The assembly defect was fully corrected in a genetic background in which the cell's ability to form disulfide bonds was compromised. The assembly defect of the two-cysteine OmpC protein was also mended by asmA3, whose suppressive effect was not achieved by preventing disulfide bond formation in the mutant OmpC protein.     

Mutational analysis of the DNA-binding domain of the CYS3 regulatory protein of Neurospora crassa.

cys-3, the major sulfur regulatory gene of Neurospora crassa, activates the expression of a set of unlinked structural genes which encode sulfur catabolic-related enzymes during conditions of sulfur limitation. The cys-3 gene encodes a regulatory protein of 236 amino acid residues with a leucine zipper and an upstream basic region (the b-zip region) which together may constitute a DNA-binding domain. The b-zip region was expressed in Escherichia coli to examine its DNA-binding activity. The b-zip domain protein binds to the promoter region of the cys-3 gene itself and of cys-14, the sulfate permease II structural gene. A series of CYS3 mutant proteins obtained by site-directed mutagenesis were expressed and tested for function, dimer formation, and DNA-binding activity. The results demonstrate that the b-zip region of cys-3 is critical for both its function in vivo and specific DNA-binding in vitro.     

Molecular and classical genetic analyses of his-3 mutants of Neurospora crassa. I. Tests for allelic complementation and specific revertibility

A collection of 81 his-3 mutants of Neurospora crassa was analyzed in assays for allelic complementation and specific revertibility. In these studies, the linearity of the complementation map of the his-3 cistron (Webber, 1965) was confirmed and mutants were classified as complementing with non-polarized or polarized complementation patterns, or non-complementing. In the assays for spontaneous or induced revertibility, 89% (71/80) of the mutants reverted either spontaneously or after treatment with the chemical mutagens N-methyl-N'-nitro-N-nitrosoguanidine, ethyl methanesulfonate, 2-methoxy-6-chloro-9-(3-[ethyl-2-chloroethyl]aminopropylamino) acridine dihydrochloride, nitrous acid or hydroxylamine. The frequency of revertible mutants among the non-polarized complementing mutants was 96% (45/47), and 79% (15/19) for the polarized complementing and 79% (11/14) for the non-complementing mutants. The results of these classical genetic assays for allelic complementation and specific revertibility suggest a correlation between complementation pattern and presumptive genetic alterations at the molecular level among his-3 mutants similar to that found with ad-3B mutants induced by nitrous acid (Malling and de Serres, 1967), ethyl methanesulfonate (Malling and de Serres, 1968), or ultraviolet (Kilbey et al., 1971).