Involvement of histidine permease (Hip1p) in manganese transport in Saccharomyces cerevisiae

In a search for components involved in Mn²⁺ homeostasis in the budding yeast Saccharomyces cerevisiae, we isolated a mutant with modifications in Mn²⁺ transport. The mutation was found to be located in HIP1, a gene known to encode a high-affinity permease for histidine. The mutation, designated hip1–272, caused a frameshift that resulted in a stop codon at position 816 of the 1812-bp ORF. This mutation led to Mn²⁺ resistance, whereas the corresponding null mutation did not. Both hip1–272 cells and the null mutant exhibited low tolerance to divalent cations such as Co²⁺, Ni²⁺, Zn²⁺, and Cu²⁺. The Mn²⁺ phenotype was not influenced by supplementary histidine in either mutant, whereas the sensitivity to other divalent cations was alleviated by the addition of histidine. The cellular Mn²⁺ content of the hip1–272 mutant was lower than that of wild type or null mutant, due to increased rates of Mn²⁺ efflux. We propose that Hip1p is involved in Mn²⁺ transport, carrying out a function related to Mn²⁺ export. Received: 9 January 1998 / Accepted: 4 May 1998     

Cloning, mapping and functional characterization of the hemB gene of Pseudomonas aeruginosa , which encodes a magnesium-dependent 5-aminolevulinic acid dehydratase

During tetrapyrrole biosynthesis 5-aminolevulinic acid dehydratase (ALAD) catalyzes the condensation of two molecules of 5-aminolevulinic acid (ALA) to form one molecule of the pyrrole derivative porphobilinogen. In Escherichia coli, the enzyme is encoded by the gene hemB. The hemB gene was cloned from Pseudomonas aeruginosa by functional complementation of an E. coli hemB mutant. An open reading frame of 1011 bp encoding a protein of 336 amino acids (M_r = 37 008) was identified. The gene was mapped to SpeI fragment G and DpnI fragment G of the P. aeruginosa chromosome, corresponding to the 10 to 12 min region of the new map or 19 to 22 min interval of the old map. The 5′ end of the hemB mRNA was determined and the −10 and −35 regions of a potential σ⁷⁰-dependent promoter were localized. No obvious regulation of the hemB gene by oxygen, nitrate, heme or iron was detected. Alignment of the amino acid sequences deduced from hemB revealed a potential metal-binding site and indicated that the enzyme is Mg²⁺-dependent. P. aeruginosa hemB was overexpressed in an E. coli hemB mutant using the phage T7 RNA polymerase system and its Mg²⁺-dependent activity was directly demonstrated. Received: 11 July 1997 / Accepted: 9 October 1997     

A synthetic combination of mutations, including fs(1)pyr? Su(b) , r? Su(b) and b , causes female sterility and reduces embryonic viability in Drosophila melanogaster

A Drosophila melanogaster mutant, fs(1)pyr ^Su(b) , carrying a mutation that maps to the tip of the X chromosome, has been isolated. The mutation, when present alone, does not confer a detectable phenotype. However, this mutation causes female sterility and reduces embryonic viability when combined with mutations which deregulate the pyrimidine and β-alanine pools. Embryos that are homozygous for the mutations fs(1)pyr ^Su(b) , r ^Su(b) [previously designated as Su(b)] and b, and originate from a female parent homozygous for the three mutations show severely reduced viability. Newly laid eggs begin development normally, but the majority of the embryos die just before the eggs are due to hatch. Received: 15 May 1998 / Accepted: 18 January 1999     

Plasmid-determined nodulation and nitrogen-fixation abilities inRhizobium phaseoli

Summary InRhizobium phaseoli strain 8002, the 190 Md plasmid pRP2JI which determines the ability to produce nitrogen-fixing nodules onPhaseolus beans (Nod⁺ Fix⁺) and the production of melanin on L-tyrosine-containing media (Mel⁺), was shown to be transmissible by conjugation to otherRhizobium strains. When pRP2JI was transferred to Nod^- strains ofR. leguminosarum (which normally nodulates peas) the transconjugants gained the ability to nodulatePhaseolus beans and to make melanin.Out of 187 derivatives of strain 8002 carrying pRP2JI plasmids into which the transposon Tn5 had been inserted, six were Fix^- Nod⁺ Mel⁺, one was Fix^- Nod⁺ Mel^- and four were Fix⁺ Nod⁺ Mel^-. Three other derivatives of strain 8002 were Nod^- Mel^-; these had suffered deletions of c 30 Md in pRP2JI. Thus the genes for melanin production and nodulation appear to be closely linked, but melanin production is not necessary for the induction of nitrogen-fixing nodules onPhaseolus beans.     

The pea ( Pisum sativum L.) genes sym33 and sym40 control infection thread formation and root nodule function

Two novel non-allelic mutants that were unable to fix nitrogen (Fix⁻) were obtained after EMS (ethyl methyl sulfonate) mutagenesis of pea (Pisum sativum L.). Both mutants, SGEFix⁻–1 and SGEFix⁻–2, form two types of nodules: SGEFix⁻–1 forms numerous white and some pink nodules, while mutant SGEFix⁻–2 forms white nodules with a dark pit at the distal end and also some pinkish nodules. Both mutations are monogenic and recessive. In both lines the manifestation of the mutant phenotype is associated with the root genotype. White nodules of SGEFix⁻–1 are characterised by hypertrophied infection threads and infection droplets, mass endocytosis of bacteria, abnormal morphological differentiation of bacteroids, and premature degradation of nodule symbiotic structures. The structure of the pink nodules of SGEFix⁻–1 does not differ from that of the parental line, SGE. White nodules of SGEFix⁻–2 are characterised by “locked” infection threads surrounded with abnormally thick plant cell walls. In these nodules there is no endocytosis of bacteria into host-cell cytoplasm. The pinkish nodules of SGEFix⁻–2 are characterised by virtually undifferentiated bacteroids and premature degradation of nodule tissues. Thus, the novel pea symbiotic genes, sym40 and sym33, identified after complementation analysis in SGEFix⁻–1 and SGEFix⁻–2 lines, respectively, control early nodule developmental stages connected with infection thread formation and function. Received: 12 June 1998 / Accepted: 25 June 1998     

In Bradyrhizobium japonicum the common nodulation genes, nodABC, are linked to nifA and fixA

Summary Using cloned Rhizobium phaseoli nodulation (nod) genes as hybridization probes homologous restriction fragments were detected in the genome of the slow-growing soybean symbiont, Bradyrhizobium japonicum strain 110. These fragments were isolated from a cosmid library, and were shown to lie 10 kilobasepairs (kb) upstream from the nifA and fixA genes. Specific nod probes from Rhizobium leguminosarum were used to identify nodA-, nodB-, and nodC-like sequences clustered within a 4.5 kb PstI fragment. A mutant was constructed in which the kanamycin resistance gene from Tn5 was inserted into the nodA homologous B. japonicum region. This insertion was precisely located, by DNA sequencing, to near the middle of the nodA gene. B. japonicum mutants carrying this insertion were completely nodulation deficient (Nod^-).     

Benzene/toluene/p-xylene degradation. Part II. Effect of substrate interactions and feeding strategies in toluene/benzene and toluene/p-xylene fermentations in a partitioning bioreactor

A two-phase aqueous/organic partitioning bioreactor scheme was used to degrade mixtures of toluene and benzene, and toluene and p-xylene, using simultaneous and sequential feeding strategies. The aqueous phase of the partitioning bioreactor contained Pseudomonas sp. ATCC 55595, an organism able to degrade benzene, toluene and p-xylene simultaneously. An industrial grade of oleyl alcohol served as the organic phase. In each experiment, the organic phase of the bioreactor was loaded with 10.15 g toluene, and either 2.0 g benzene or 2.1 g p-xylene. The resulting aqueous phase concentrations were 50 mg/l, 25 mg/l and 8 mg/l toluene, benzene and p-xylene respectively. The simultaneous fermentation of benzene and toluene consumed these compounds at volumetric rates of 0.024 g l⁻¹ h⁻¹ and 0.067 g l⁻¹ h⁻¹, respectively. The simultaneous fermentation of toluene and p-xylene consumed these xenobiotics at volumetric rates of 0.066 g l⁻¹ h⁻¹ and 0.018 g l⁻¹ h⁻¹, respectively. A sequential feeding strategy was employed in which toluene was added initially, but the benzene or p-xylene aliquot was added only after the cells had consumed half of the initial toluene concentration. This strategy was shown to improve overall degradation rates, and to reduce the stress on the microorganisms. In the sequential fermentation of benzene and toluene, the volumetric degradation rates were 0.056 g l⁻¹ h⁻¹ and 0.079 g l⁻¹ h⁻¹, respectively. In the toluene/p-xylene sequential fermentation, the initial toluene load was consumed before the p-xylene aliquot was consumed. After 12 h in which no p-xylene degradation was observed, a 4.0-g toluene aliquot was added, and p-xylene degradation resumed. Excluding that 12-h period, the microbes consumed toluene and p-xylene at volumetric rates of 0.074 g l⁻¹ h⁻¹ and 0.025 g l⁻¹ h⁻¹, respectively. Oxygen limitation occurred in all fermentations during the rapid growth phase. Received: 16 November 1998 / Received revision: 29 March 1999 / Accepted: 9 April 1999     

Characterisation of new symbiotic Medicago truncatula (Gaertn.) mutants, and phenotypic or genotypic complementary information on previously described mutants

From a pool of Medicago truncatula mutants—obtained by gamma-irradiation or ethyl methanesulfonate mutagenesis—impaired in symbiosis with the N-fixing bacterium Sinorhizobium meliloti, new mutants are described and genetically analysed, and for already reported mutants, complementary data are given on their phenotypic and genetic analysis. Phenotypic data relate to nodulation and mycorrhizal phenotypes. Among the five new mutants, three were classified as [Nod⁺ Fix^– Myc⁺] and the mutations were ascribed to two loci, Mtsym20 (TRV43, TRV54) and Mtsym21 (TRV49). For the two other new mutants, one was classified as [Nod^–/+ Myc⁺] with a mutation ascribed to gene Mtsym15 (TRV48), and the other as [Nod^– Myc^-/+] with a mutation ascribed to gene Mtsym16 (TRV58). Genetic analysis of three previously described mutants has shown that [Nod^–/+ Myc⁺] TR74 mutant can be ascribed to gene Mtsym14, and that [Nod^–/+ Myc^–/+] TR89 and TRV9 mutants are ascribed to gene Mtsym2 (dmi2). Using a detailed analysis of mycorrhizal phenotype, we have observed a delayed typical arbuscular mycorrhizal formation on some mutants that present thick lens-shaped appressoria. This phenotype was called [Myc^–/+] and mutants TR25, TR26, TR89, TRV9, P1 and Y6 were reclassified as [Myc^–/+]. Mutant P1 was reclassified as [Nod^–/+] because of a late nodulation observed on roots of this mutant.     

Analysis of pss genes of Rhizobium leguminosarum required for exopolysaccharide synthesis and nodulation of peas: their primary structure and their interaction with psi and other nodulation genes

Summary Strains of Rhizobium leguminosarum (R. l.) biovar viciae containing pss mutations fail to make the acidic exopolysaccharides (EPS) and are unable to nodulate peas. It was found that they also failed to nodulate Vicia hirsuta, another host of this biovar. When peas were co-inoculated with pss mutant derivatives of a strain of R.l. bv viciae containing a sym plasmid plus a cured strain lacking a sym plasmid (and which is thus Nod^-, but for different reasons) but which makes the acidic EPS, normal numbers of nodules were formed, the majority of which failed to fix nitrogen (the occasional Fix⁺ nodules were pressumably induced by strains that arose as a result of genetic exchange between cells of the two inoculants in the rhizosphere). Bacteria from the Fix^- nodules contained, exclusively, the strain lacking its sym plasmid. When pss mutant strains were co-inoculated with a Nod^- strain with a mutation in the regulatory gene nodD (which is on the sym plasmid pRL1JI), normal numbers of Fix⁺ nodules were formed, all of which were occupiced solely by the nodD mutant strain. Since a mutation in nodD abolishes activation of other nod genes required for early stages of infection, these nod genes appear to be dispensable for subsequent stages in nodule development. Recombinant plasmids, containing cloned pss genes, overcame the inhibitory effects of psi, a gene which when cloned in the plasmid vector pKT230, inhibits both EPS production and nodulation ability. Determination of the sequence of the pss DNA showed that one, or perhaps two, genes are required for correcting strains that either carry pss mutations or contain multi-copy psi. The predicted polypeptide product of one of the pss genes had a hydrophobic aminoterminal region, suggesting that it may be located in the membrane. Since the psi gene product may also be associated with the bacterial membrane, the products of psi and pss may interact with each other.     

Detection of nptII (kanamycin resistance) genes in genomes of transgenic plants by marker-rescue transformation

We have developed a novel system for the sensitive detection of nptII genes (kanamycin resistance determinants) including those present in transgenic plant genomes. The assay is based on the recombinational repair of an nptII gene with an internal 10-bp deletion located on a plasmid downstream of a bacterial promoter. Uptake of an nptII gene by transformation restores kanamycin resistance. In Escherichia coli, promoterless nptII genes provided by electroporation were rescued with high efficiency in a RecA-dependent recombinational process. For the rescue of nptII genes present in chromosomal plant DNA, the system was adapted to natural transformation, which favours the uptake of linear DNA. When competent Acinetobacter sp. BD413 (formerly A. calcoaceticus) cells containing the mutant nptII gene on a plasmid were transformed with DNA from various transgenic plants carrying nptII as a marker gene (Solanum tuberosum, Nicotiana tabacum, Beta vulgaris, Brassica napus, Lycopersicon esculentum), kanamycin-resistant transformants were obtained roughly in proportion to the concentration of nptII genes in the plant DNA. The rescue of nptII genes occurred in the presence of a more than 6 × 10⁶-fold excess of plant DNA. Only 18 ng of potato DNA (2.5 × 10³ genome equivalents, each with one copy of nptII) was required to produce one kanamycin-resistant transformant. These experiments and others employing DNA isolated from soil samples demonstrate that the system allows reliable and highly sensitive monitoring of nptII genes in transgenic plant DNA and in DNA from environmental sources, such as soil, without the need for prior DNA amplification (e.g. by PCR). Received: 20 May 1997 / Accepted: 17 October 1997     

Genetic evidence for interaction between components of the yeast 26S proteasome: combination of a mutation in RPN12 (a lid component gene) with mutations in RPT1 (an ATPase gene) causes synthetic lethality

The 19S regulatory particle of the yeast 26S proteasome consists of six related ATPases (Rpt proteins) and at least 11 non-ATPase proteins (Rpn proteins). RPN12 (formerly NIN1) encodes an Rpn component of the 19S regulatory particle and is essential for growth. To determine which subunit(s) of the 26S proteasome interact(s) with Rpn12, we attempted to screen for mutations that cause synthetic lethality in the presence of the rpn12-1 (formerly nin1-1) mutation. Among the candidates recovered was a new allele of RPT1 (formerly CIM5). This mutant allele was designated rpt1-2; on its own this mutation caused no phenotypic change, whereas the rpn12-1 rpt1-2 double mutant was lethal, suggesting a strong interaction between Rpn12 and Rpt1. The site of the rpt1-2 mutation was determined by DNA sequencing of the RPT1 locus retrieved from the mutant, and a single nucleotide alteration was found. This changes amino acid 446 of the RPT1 product from alanine to valine. The alanine residue is conserved in all Rpt proteins, except Rpt5, but no function has yet been assigned to the region that contains it. We propose that this region is necessary for Rpt1 to interact with Rpn12. The terminal phenotype of the rpn12-1 rpt1-2 double mutant was not cell cycle specific, suggesting that in the double mutant cells the function of the 26S proteasome is completely eliminated, thereby inducing multiple defects in cellular functions. Received: 1 February 1999 / Accepted: 5 May 1999     

Genetic analyses of the formation of the serrated margin of leaf blades in Arabidopsis : combination of a mutational analysis of leaf morphogenesis with the characterization of a specific marker gene expressed in hydathodes and stipules

Developmental control of the formation of the serrated margin of leaf blades was investigated. First, the expression was characterized of a marker gene encoding β-glucuronidase in strain #1-35-38, a transgenic strain of Arabidopsis thaliana (L.) Heynh, derived by the use of a previously described transposon-tagging system. In strain #1-35-38, expression of the marker gene was tissue-specific, being restricted to stipules and the toothed margins of laminae. Using this transgenic marker gene, we examined the development of leaf blade margins in Arabidopsis. We compared the pattern of expression of the marker gene in the leaves of the wild-type plant with that in plants carrying the asymmetric leaves1 (as1) mutation, which causes dramatic changes in leaf-blade morphology in Arabidopsis. The as1 mutant showed normal morphology of early leaf primordia. The mutation affected the development of leaf segmentation in Arabidopsis without any change in the number or morphology of cells in laminae. The as1 mutation affected leaf morphology independently of mutations in other genes known to affect leaf morphogenesis, such as the acaulis1 mutation and the angustifolia mutation. Based upon these results, the development of the morphology of leaf margins in Arabidopsis is discussed. Received: 9 January 1997 / Accepted: 24 June 1997     

Intrachromosomal recombination between direct repeats in Penicillium chrysogenum : gene conversion and deletion events

Recombination between direct repeats has been studied in Penicillium chrysogenum using strain TD7-88 (lys⁻ pyr⁺), which contains two inactive copies of the lys2 gene separated by 4.5 kb of DNA (including the pyrG gene) in its genome. Gene conversion leading to products with the lys⁺ pyr⁺ phenotype was observed at a frequency of 1 in 3.2 × 10³ viable spores. Two types of deletion events giving rise to lys⁺ pyr⁻ and lys⁻ pyr⁻ phenotypes were obtained with different frequencies. Southern analysis revealed that gene conversion occurs mainly as a result of crossing over events that remove the BamHI frameshift mutation present in one of the repeats. In lys⁻ pyr⁻ recombinants, the deletion events do not affect the frameshift mutation in the BamHI site, while lys⁺ pyr⁻ recombinants showed repair of the BamHI frameshift mutation and the genotype of the parental non-disrupted strain was restored. In summary, deletion events in P. chrysogenum tend to favor the restoration of the phenotype and genotype characteristic of the parental non-disrupted strain. Received: 9 November 1998 / Accepted: 14 April 1999     

Resistance of pea roots to endomycorrhizal fungus or Rhizobium correlates with enhanced levels of endogenous salicylic acid

The analysis of SA accumulation in roots of plant symbiotic mutants revealed two independent phenomena associated with the inability of either the plant or the microsymbiont to form a compatible symbiosis. SA accumulation in roots of the wild type and symbiosis-resistant P2 (Nod^-, MYC^-) Pisum sativum genotypes was induced upon interaction with Glomus mosseae. The amplitude of this accumulation was higher in P2 plants and increased with time, an effect that was not observed in roots of the wild-type, an effect that was not observed in roots of the wild-type P. sativum genotype. Likewise, Rhizobium leguminosarum wild type or a mutant blocked in Nod factor biosynthesis induced SA accumulation in P2, whereas SA accumulation in roots of the wild-type plant was dependent on the inability of the bacterium to produce Nod factors. These results suggest that the sym30 gene, which is mutated in P2 plants, could be implicated in a common pathway that leads to the suppression of an SA-dependent defence mechanism in legume plants against Rhizobium and endomycorrhizal fungi, thus allowing establishment of symbiosis.     

Genetic interaction of DED1 encoding a putative ATP-dependent RNA helicase with SRM1 encoding a mammalian RCC1 homolog in Saccharomyces cerevisiae

 The Saccharomyces cerevisiae temperature-sensitive mutants srm1-1, mtr1-2 and prp20-1 carry alleles of a gene encoding a homolog of mammalian RCC1. In order to identify a protein interacting with RCC1, a series of suppressors of the srm1-1 mutation were isolated as cold-sensitive mutants and one of the mutants, designated ded1-21, was found to be defective in the DED1 gene. The double mutant, srm1-1 ded1-21, could grow at 35° C, but not at 37° C. A revertant of srm1-1 ded1-21 that became able to grow at 37° C acquired another mutation in the SRM1 gene, indicating the tight relationship between SRM1 and DED1. In all the rcc1 ^- strains examined, the amount of mutated SRM1 proteins was reduced or not detectable at the nonpermissive temperature. While mutated SRM1 protein was stabilized in all of the rcc1 ^- strains by the ded1-21 mutation, the ded1-21 mutation suppressed both srm1-1 and mtr1-2, but not the prp20-1 mutation, contrary to the previous finding that overproduction of the S. cerevisiae Ran homolog GSP1 suppresses prp20-1, but not srm1-1 or mtr1-2. Received: 20 March 1996/Accepted: 1 July 1996     

Characterization of an lrp -like ( IrpC ) gene from Bacillus subtilis

In the course of the Bacillus subtilis genome sequencing project, we identified an open reading frame encoding a putative 16.4 kDa protein. This protein shows, respectively, 34% and 25% identity with the Escherichia coli regulatory proteins Lrp and AsnC. Phylogenetic analysis suggests that it represents a new group in the AsnC-Lrp family. Sequence comparisons, as well as immunodetection experiments, lead to the conclusion that the product of this B. subtilislrp-likegene is a bona fide Lrp protein – the first one to be detected in gram-positive bacteria. When expressed in E.␣coli, the B. subtilis Lrp-like protein is able to repress, by about two-fold, the expression of the ilvIH operon which is normally regulated by E. coli Lrp, indicating functional similarity in their regulatory targets. Vegetative growth of a B. subtilis lrp-like mutant is not affected in rich medium. However, the lrp-like mutation causes a transitory inhibition of growth in minimal medium in the presence of valine and isoleucine, which is relieved by leucine. This points to a possible role in regulation of amino acid metabolism. In addition, sporogenesis occurs earlier in the lrp-like mutant than in the reference strain, implying that the B. subtilis Lrp-like protein plays a role in the growth phase transition. Received: 28 January 1997 / Accepted: 18 April 1997     

Cloning and sequence analysis of the arginine deiminase gene from Mycoplasma arginini

Summary A deletion mutant of Rhizobium leguminosarum biovar viciae lacking the host-specific nodulation (nod) gene region (nodFEL nodMNT and nodO) but retaining the other nod genes (nodD nodABCIJ) was unable to nodulate peas or Vicia hirsuta, although it did induce root hair deformation. The mutant appeared to be blocked in its ability to induce infection threads and could be rescued for nodulation of V. hirsuta in mixed inoculation experiments with an exopolysaccharide deficient mutant (which is also Nod^–). The nodulation deficiency of the deletion mutant strain could be partially restored by plasmids carrying the nodFE, nodFEL or nodFELMNT genes but not by nodLMN. Surprisingly, the mutant strain could also be complemented with a plasmid that did not carry any of the nodFELMNT genes but which did carry the nodO gene on a 30 kb cloned region of DNA. Using appropriate mutations it was established that nodO is essential for nodulation in the absence of nodFE. Thus, either of two independent nod gene regions can complement the deletion mutant for nodulation of V. hirsuta. Similar observations were made for pea nodulation except that nodL was required in addition to nodO for nodulation in the absence of the nodFE genes. These observations show that nodulation can occur via either of two pathways encoded by non-homologous genes.Dedicated to the memory of the late Dr. David Goodchild     

Competitive nodulation blocking of Afghanistan pea is determined by nodDABC and nodFE alleles in Rhizobium leguminosarum

Summary One well-defined competitive interaction amongst rhizobia is that between compatible and non-compatible strains of Rhizobium leguminosarum with respect to the nodulation of some primitive pea genotypes. The Middle Eastern pea cv Afghanistan is nodulated effectively can R. leguminosarum TOM, but its capacity to nodulate can be blocked if a mixed inoculation is made with R. leguminosarum PF₂. This PF₂ phenotype (Cnb) is encoded by its symbiotic plasmid and cosmid clones thereof. We found that Cnb is also encoded by the well-characterized Sym plasmid pRL1JI of R. leguminosarum strain 248. We have isolated and characterized a 6.9 kb HindIII fragment of pSymPF₂ which confers the Cnb⁺ phentoype on other (Cnb^–) rhizobia. A Tn5 site-directed Cnb^– mutant was constructed by homogenotization and was also found to be Nod^– on the European pea cv Rondo. DNA hybridization and complementation analysis indicated that the 6.9 kb Cnb⁺ fragment contained the nodD, nodABC and nodFE operons. Analysis of the Cnb phenotype of nod::Tn5 alleles of pRL1JI showed that mutations of nodC, nodD or nodE all abolished Cnb activity whereas mutants in nodI and nodJ reduced activity to 50% of the wild-type level.