Structure of an abequose-containing O-polysaccharide from Citrobacter freundii O22 strain PCM 1555

The lipopolysaccharide of Citrobacter freundii O22 (strain PCM 1555) was degraded under mild acidic conditions and the O-polysaccharide released was isolated by gel chromatography. Sugar and methylation analyses along with ¹H and ¹³C NMR spectroscopy, including two-dimensional ¹H,¹H ROESY and ¹H,¹³C HMBC experiments, showed that the repeating unit of the O-polysaccharide has the following structure:

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where Abe is abequose (3,6-dideoxy-d-xylo-hexose). SDS–PAGE and immunoblotting revealed that the O-antigen of C. freundii O22 is serologically indistinguishable from those of Salmonella group B serovars (Typhimurium, Brandenburg, Sandiego, Paratyphi B) but not related to other abequose-containing O-antigens tested (Citrobacter werkmanii O38 and Salmonella Kentucky) or colitose (l enantiomer of abequose)-containing O-antigen of Escherichia coli O111.     

Nucleotide sequence of the recF gene cluster from Staphylococcus aureus and complementation analysis in Bacillus subtilis recF mutants

We have determined the nucleotide sequence of a 3.5 kb segment in the recF region of the Staphylococcus aureus chromosome. The gene order at this locus, dnaA-dnaN-recF-gyrB is similar to that found in the replication origin region of many other bacteria. S. aureus RecF protein (predicted molecular mass 42.3 kDa), has 57% amino acid sequence identity with the Bacillus subtilis RecF protein (42.2 kDa), but only 26% with the Escherichia coli RecF protein (40.5 kDa). We have shown that the S. aureus recF gene partially complements the defect of a B. subtilis recF mutant, but does not complement an E. coli recF strain. The amino acid sequence alignment of seven available RecF proteins (five of them from bacteria of gram-negative origin) allowed us to identify eight highly conserved regions ( to ) and to predict five new conserved regions within the gram-positive group (a to f). We suggest that the basic mechanism of homologous recombination is conserved among free-living bacteria.     

Isolation and characterization of spontaneous srl-recA deletion mutants in Escherichia coli K-12

Summary A method was developed for the isolation of spontaneous mutants of Escherichia coli K-12 with deletions extending from the srl operon to the adjacent recA gene. The srl-recA deletion mutants were extremely sensitive to DNA-damaging agents; unable to support growth of the feckless red gam mutant bio11; and recombination-deficient in transduction and in conjugation. They therefore resembled recA point mutants such as recA13. The existence of these recA deletion mutants shows that the recA gene is not essential for viability.     

Molecular analysis of irradiation-induced and spontaneous deletion mutants at a disease resistance locus inLactuca sativa

The major cluster of disease resistance genes in lettuce (Lactuca sativa) contains at least nine downy mildew resistance genes (Dm) spanning a genetic distance of 20 cM and a physical distance of at least 6 Mb. Nine molecular markers that were genetically tightly linked toDm3 were used to analyze nine independent deletion mutants and construct a map of the region surroundingDm3. This analysis identified a linear order of deletion breakpoints and markers along the chromosome. There was no evidence for chromosomal rearrangements associated with the deletions. The region is not highly recombinagenic and the deletion breakpoints provided greater genetic resolution than meiotic recombinants. The region contains a mixture of high- and low-copy-number sequences; no single-copy sequences were detected. Three markers hybridized to low-copy-number families of sequences that are duplicated predominantly close toDm3. This was not true for sequences related to the triose-phosphate isomerase gene; these had been shown previously to be linked toDm3, as well as to two independent clusters ofDm genes, and elsewhere in the genome. Two spontaneous mutants ofDm3 were identified; several markers flankingDm3 are absent in one of these two mutants. The stability of theDm3 region was also studied by analyzing the genotypes of diverse related cultivars. The 1.5 Mb region surroundingDm3 has remained stable through many generations of breeding with and without selection forDm3 activity.     

A complementation analysis by parasexual recombination of Candida albicans morphological mutants

Benomyl treatment (at 100 micrograms ml-1) of Candida albicans 1001, and other strains derived from it, determined the appearance of morphological mutants similar to those derived from UV irradiation treatment. A permanent alteration in the morphogenesis of these mutant strains determined their inability to grow by budding, to form oval yeast cells or blastospores (Y-phenotype) and their growth as long filamentous forms, mostly with the appearance of pseudomycelium, giving rise to rough colonies (R phenotype). In order to carry out a genetic complementation analysis, we isolated morphological mutants that carried other genetic markers (nutritional, conditional lethal) adequate for crosses by means of protoplast fusion. Wild-type hybrids of regular mononuclear oval yeast cells and smooth colonies were obtained by crossing pairs of complementing mutants, whereas hybrids from crosses of non-complementing mutants still retained their morphological alterations. Our results define two complementation groups, which represent two genes relevant for dimorphism, whose alteration interferes with the correct transition from blastospores to mycelium.     

Analysis of the downstream region of nodD3 P1 promoter by deletion and complementation tests in Sinorhizobium meliloti

Rhizobia specifically interacts with the host, leguminous plants, leading to the formation of nitrogen-fixing root nodules. The Rhizobium genes essential for nodule formation are called nodulation genes (nod or nol). The expression of nod genes requires the presence of host signals, generally flavonoids, and the product of regulatory nodD gene, NodD[1,2]. The expression of nod genes results in the synthesis of Nod factors, which serve as the signal molecules to elicit root cor-tical cells di…     

Physiological and biochemical characterization of chlorate-resistant mutants ofAnabaena doliolum

Chlorate-resistant mutants of the filamentous cyanobacterium,Anabaena doliolum, were isolated by N-methyl-N-nitro-N-nitrosoguanidine (MNNG)¹ mutagenesis. Three classes of mutants were obtained that were altered either in the nitrate uptake activity or nitrate reductase enzyme activity or both. These results suggest that the genetic determinant of the uptake system was distinct from that of the reductase system.Uptake studies of nitrite and ammonium and rate of nitrite reductase activity in the mutants revealed that the nitrite and ammonium metabolisms were not affected by this mutation.Both nitrate and chlorate acted like a pair of antagonists, with nitrate protecting the growth against chlorate with increase in its concentration; similarly, increasing chlorate concentrations counteracted the growth-protective action of nitrate.     

A genetical and biochemical study of chlorate-resistant mutants ofSalmonella typhimurium

S.typhimurium can form nitrate reductase A, chlorate reductase C, thiosulfate reductase, tetrathionate reductase and formic dehydrogenase. None of these enzymes are formed in chlorate-resistant mutants. Conjugation experiments showed the presence of a strong linkage between thechl andgal markers of the bacterial chromosome. By deletion mapping the gene ordernic A aro G gal bio chl D uvr B chl A was found. Strains with deletions terminating betweenbio anduvr B or betweenuvr B andchl A have a number of aberrant properties. Though resistant against chlorate they reduce nitrate and form gas. After growth with nitrate they form less nitrate reductase than the wild type which may explain the resistance against chlorate. After growth with thiosulfate they form small amounts of thiosulfate reductase and chlorate reductase C. In crosses between anE.coli Hfrchl ⁺ strain and aS.typhimurium chl A strain recombinants were obtained, forming nitrate reductase A and chlorate reductase C. These recombinants do not form gas, which indicates that thechl ⁺ gene fromE.coli does not function normally inS.typhimurium.The author is very gratefull to Miss C. W. Bettenhaussen, Miss W. M. C. Kapteijn and Mr. K. Pietersma for technical assistance. Helpfull suggestions of Dr. P. van de Putte (Medical Biological Laboratory of the National Defence Organization TNO, Rijswijk) are gratefully acknowledged.     

Membrane reconstitution in chl-r mutants of Escherichia coli K 12 VI. Morphological study of membrane assembly during complementation between extracts of chl-r mutants

The particles formed during the complementation between supernatant extracts of mutants chl A⁻ and chl B⁻ of Escherichia coli K 12 have been examined under the electron microscope. These particles look like membranous formations with a vesicular structure limited by a triple-layered membrane. The observations made on these particles at various incubation times during complementation show that the aggregation progresses through several stages of organization. When the phenomenon becomes steady, the population of reaggregated particles shows a large structural heterogeneity: it consists of small aggregates, filaments and particulary well-organized closed vesicles. As we had previously shown for the reconstitution of nitrate reductase, the rate of formation and the structure of newly formed aggregates depend on various parameters (temperature, dialysis).     

Membrane reconstitution in CHL-R mutants of Escherichia coli K 12 V. ATPase incorporation into particles formed by complementation

Mechanical treatments of cell suspensions of Escherichia coli K 12 strain PA 601, and its two mutants chl A⁻ and chl B⁻, in a buffer without Mg²⁺ lead to partial solubilization of membrane-bound ATPase. After ultracentrifugation of cell-free extracts, ATPase can be recovered in the soluble fraction. Contrary to membrane ATPase, the soluble enzyme has the following properties: (1) it is insensitive to N,N′-dicyclohexylcarbodiimide; (2) heat-inactivation kinetics show a reactivation in the first 3 min and the half-time is 15 min; (3) ADP is a substrate. In the course of complementation between soluble fractions of mutants chl A⁻ and chl B⁻, a part of soluble ATPase is incorporated into the newly formed particles. The specific activity of these particles is nearly the same as that of native particles; the ATPase bound to native membrane and the ATPase bound to the newly-formed particles both have the same biochemical properties.     

Characterization and complementation analysis of sporogenous mutants of Dictyostelium discoideum

Sporogenous mutants of the cellular slime mold Dictyostelium discoideum are defined as mutants which are able to undergo terminal differentiation into spores in monolayer cultures in the presence of millimolar amounts of exogenous cyclic AMP. We describe the morphological development and cellular differentiation of a collection of 12 independently isolated sporogenous mutants of strain V12 M2. All mutants develop more rapidly than do wild-type at an air-water interface, display aberrant morphogenesis, and show overt spore and stalk differentiation as soon as 4 hr after starvation. All mutants differentiate in submerged monolayer culture in the presence of cAMP into variable proportions of spores and stalk cells. A number of the mutants also form both stalk cells and spores in submerged culture in the absence of exogenous cAMP. The spores formed by many of the mutants have a greatly reduced viability. Using parasexual genetics, we have found that two of the 12 mutants analyzed are dominant to wild-type and the remaining ten fall into a minimum of four complementation groups, the overall analysis thus yielding a minimum of four and a maximum of seven complementation groups. Intracellular cAMP levels in vegetative cells are significantly elevated in the two dominant mutants but are similar to wild type in all the other mutants.     

Genetic analysis of nitrate reductase deficient mutants of Nicotiana plumbaginifolia: Evidence for six complementation groups among 70 classified molybdenum cofactor deficient mutants

Summary A total of 70 cnx mutants have been characterized from a collection of 211 nitrate reductase deficient (NR^-) mutants isolated from mutagenized Nicotiana plumbaginifolia protoplast cultures after chlorate selection and regeneration into plants. They are presumed to be affected in the biosynthesis of the molybdenum cofactor since they are also deficient for xanthine dehydrogenase activity but contain NR apoenzyme. The remaining clones were classified as nia mutants. Sexual crosses performed between cnx mutants allowed them to be classified into six independent complementation groups. Mutants representative of these complementation groups were used for somatic hybridization experiments with the already characterized N. plumbaginifolia mutants NX1, NX24, NX23 and CNX103 belonging to the complementation groups cnxA, B, C and D respectively. On the basis of genetic analysis and somatic hybridization experiments, two new complementation groups, cnxE and F, not previously described in higher plants, were characterized. Unphysiologically high levels of molybdate can restore the NR activity of cnxA mutant seedlings in vivo, but cannot restore NR activity to any mutant from the other cnx complementation groups.     

Molybdenum cofactor in chlorate-resistant and nitrate reductase-deficient insertion mutants of Escherichia coli

We examined molybdenum cofactor activity in chlorate-resistant (chl) and nitrate reductase-deficient (nar) insertion mutants and wild-type strains of Escherichia coli K-12. The bacterial molybdenum cofactor was assayed by its ability to restore activity to the cofactor-deficient nitrate reductase found in the nit-1 strain of Neurospora crassa. In the wild-type E. coli strains, molybdenum cofactor was synthesized constitutively and found in both cytoplasmic and membrane fractions. Cofactor was found in two forms: the demolybdo form required additional molybdate in the assay mix for detection, whereas the molybdenum-containing form was active without additional molybdate. The chlA and chlE mutants had no detectable cofactor. The chlB and the narG, narI, narK, and narL (previously designated chlC) strains had cofactor levels similar to those of the wild-type strains, except the chlB strains had two to threefold more membrane-bound cofactor. Cofactor levels in the chlD and chlG strains were sensitive to molybdate. When grown in 1 microM molybdate, the chlD strains had only 15 to 20% of the wild-type levels of the demolybdo and molybdenum-containing forms of the cofactor. In contrast, the chlG strains had near wild-type levels of demolybdo cofactor when grown in 1 microM molybdate, but none of the molybdenum-containing form of the cofactor. Near wild-type levels of both forms of the cofactor were restored to the chlD and chlG strains by growth in 1 mM molybdate.     

Molecular analysis of theArabidopsis pattern formation geneGNOM: gene structure and intragenic complementation

TheGNOM gene is required for pattern formation along the main body axis of the embryo in the flowering plantArabidopsis thaliana. Mutations in theGNOM gene alter the asymmetric division of the zygote and interfere with the formation of distinct apical-basal regions in the developing embryo. We have isolated theGNOM gene by positional cloning, characterised its structure and determined the molecular lesions in mutant alleles. Although the predicted 163 kDa GNOM protein has a conserved domain in common with the yeast secretory protein Sec7p, it is most closely related in size and overall similarity to the product of the yeastYEC2 gene, which is not essential for cell viability. Four fully complementinggnom alleles carry missense mutations in conserved regions, seven partially complementing alleles have premature stop codon mutations and two non-complementing alleles have splice-site lesions. Our results suggest that the GNOM protein acts as a complex of identical subunits and that partial complementation may involve low levels of full-length protein generated by inefficient translational read-through.Communicated by H. Saedler     

Development of gene transfer methods forRubrivivax gelatinosus S1: construction, characterization and complementation of apuf operon deletion strain

Gene transfer systems were developed inRubrivivax (Rx.) gelatinosus S1. First, a system for conjugative transfer of mobilizable plasmids fromEscherichia coli toRx. gelatinosus S1 was established. Secondly, optimal conditions for the transformation ofRx. gelatinosus S1 by electroporation were determined. A puf strain was constructed. Complementation with thepuf operon from a wild-type strain cloned in a replicative plasmid restored photosynthetic growth. Two insertion strains were also selected. All the strains constructed were green, due to a change in carotenoid content. Characterization of these strains provides genetic evidence for a superoperon organization in this bacterium.     

Genetic analysis and complementation by germ-line transformation of lethal mutations in the unc-22 IV region of Caenorhabditis elegans

Summary The subject of this study is the organization of essential genes in the 2 map-unit unc-22 IV region of the Caenorhabditis elegans genome. With the goal of achieving mutational saturation of essential genes in this region, 6491 chromosomes mutagenized with ethyl methanesulfonate (EMS) were screened for the presence of lethal mutations in the unc-22 region. The genetic analysis of 21 lethal mutations in the unc-22 region resulted in the identification of 6 new essential genes, making a total of 36 characterized to date. A minimum of 49 essential genes are estimated to lie in this region. A set of seven formaldehyde-induced deficiencies of unc-22 and surrounding loci were isolated to facilitate the positioning of essential genes on the genetic and physical maps. In order to study essential genes at the molecular level, our approach was to rescue lethal mutations by the injection of genomic DNA in the form of cosmid clones into the germ-line of balanced heterozygotes carrying a lethal mutation. The cosmid clones containing let-56 and let-653 were identified by this method.