Localization and symbiotic function of a region on the Rhizobium leguminosarum Sym plasmid pRL1JI responsible for a secreted, flavonoid-inducible 50-kilodalton protein.

A previously described (R. A. de Maagd, C. A. Wijffelman, E. Pees, and B. J. J. Lugtenberg, J. Bacteriol. 170:4424-4427, 1988) Sym plasmid-dependent, naringenin-inducible 50-kilodalton protein of Rhizobium leguminosarum biovar viciae is further characterized in this paper. The protein was overproduced by constructing a strain containing multiple copies of the R. meliloti nodD gene, which facilitated its purification. An antiserum was used to screen Tn5 insertion mutants located in the pRL1JI region found to be responsible for the production of the 50-kilodalton protein. These inserts define a new nod locus left of the nod genes identified previously. Mutations in this region affect the nodulation ability in a way which is dependent on the bacterial background as well as on the host plant. The mutants nodulate normally in a strain RBL1532 (R. leguminosarum biovar viciae strain 248, cured of its Sym plasmid) background on all three tested host plant species. In contrast, in a strain RBL5045 (R. leguminosarum biovar trifolii strain RCR5, cured of its Sym plasmid) background, nodulation on Vicia sativa is severely impaired, whereas nodulation on Vicia hirsuta and Trifolium subterraneum is apparently unaltered.     

Transformation of Chlamydia muridarum Reveals a Role for Pgp5 in Suppression of Plasmid-Dependent Gene Expression

Transformation of Chlamydia trachomatis should greatly advance the chlamydial research. However, significant progress has been hindered by the failure of C. trachomatis to induce clinically relevant pathology in animal models. Chlamydia muridarum, which naturally infects mice, can induce hydrosalpinx in mice, a tubal pathology also seen in women infected with C. trachomatis. We have developed a C. muridarum transformation system and confirmed Pgp1, -2, -6, and -8 as plasmid maintenance factors, Pgp3, -5, and -7 as dispensable for in vitro growth, and Pgp4 as a positive regulator of genes that are dependent on plasmid for expression. More importantly, we have discovered that Pgp5 can negatively regulate the same plasmid-dependent genes. Deletion of Pgp5 led to a significant increase in expression of the plasmid-dependent genes, suggesting that Pgp5 can suppress the expression of these genes. Replacement of pgp5 with a mCherry gene, or premature termination of pgp5 translation, also increased expression of the plasmid-dependent genes, indicating that Pgp5 protein but not its DNA sequence is required for the inhibitory effect. Replacing C. muridarum pgp5 with a C. trachomatis pgp5 still inhibited the plasmid-dependent gene expression, indicating that the negative regulation of plasmid-dependent genes is a common feature of all Pgp5 regardless of its origin. Nevertheless, C. muridarum Pgp5 is more potent than C. trachomatis Pgp5 in suppressing gene expression. Thus, we have uncovered a novel function of Pgp5 and developed a C. muridarum transformation system for further mapping chlamydial pathogenic and protective determinants in animal models.     

Distribution of Symbiotic Genotypes in Rhizobium leguminosarum biovar viciae Populations Isolated Directly from Soils

The distribution of symbiotic (Sym) plasmid types across background genotypes was investigated in two field populations of Rhizobium leguminosarum biovar viciae isolated directly from soils. PCR-based methods were used to characterize the background genotypes and the Sym gene types. Identical Sym gene types were associated with a variable range of background genotypes, while the same background genotype could harbor distinct Sym gene types. Random distributions of Sym gene types in the background genotypes were observed in the two soil populations. These results suggest that Sym plasmid transfer is less restricted than previously thought on the basis of the analysis of strains isolated from legume nodules.     

Medicago truncatula IPD3 is a member of the common symbiotic signaling pathway required for rhizobial and mycorrhizal symbioses

Legumes form endosymbiotic associations with nitrogen-fixing bacteria and arbuscular mycorrhizal (AM) fungi which facilitate nutrient uptake. Both symbiotic interactions require a molecular signal exchange between the plant and the symbiont, and this involves a conserved symbiosis (Sym) signaling pathway. In order to identify plant genes required for intracellular accommodation of nitrogen-fixing bacteria and AM fungi, we characterized Medicago truncatula symbiotic mutants defective for rhizobial infection of nodule cells and colonization of root cells by AM hyphae. Here, we describe mutants impaired in the interacting protein of DMI3 (IPD3) gene, which has been identified earlier as an interacting partner of the calcium/calmodulin-dependent protein, a member of the Sym pathway. The ipd3 mutants are impaired in both rhizobial and mycorrhizal colonization and we show that IPD3 is necessary for appropriate Nod-factor-induced gene expression. This indicates that IPD3 is a member of the common Sym pathway. We observed differences in the severity of ipd3 mutants that appear to be the result of the genetic background. This supports the hypothesis that IPD3 function is partially redundant and, thus, additional genetic components must exist that have analogous functions to IPD3. This explains why mutations in an essential component of the Sym pathway have defects at late stages of the symbiotic interactions.     

Host genes inPisum sativum L. conferring resistance to EuropeanRhizobium leguminosarum strains

Summary Using primitive and wild pea plants from Afghanistan, Iran and Turkey, three host genes were detected, which confer resistance to nodulation by Rhizobium strains of cultivated peas from Europe. A dominant gene Sym 1 controls temperature-sensitive nodulation in pea cv. Iran. Another gene Sym 2 confers general resistance to a large number of European Rhizobium strains at all temperatures used. The degree of dominance of the latter gene is dependent on the Rhizobium strain used. A third gene Sym 4 is responsible for specific resistance to a single Rhizobium strain.     

Evidence for genetic exchange and recombination of Rhizobium symbiotic plasmids in a soil population

A soil population of 16 Rhizobium leguminosarum bv. trifolii isolates was characterized by using three Sym (for symbiotic) plasmid-specific DNA hybridization probes: (i) an R. leguminosarum bv. trifolii-specific, repeated-sequence probe; (ii) a nifHDK gene probe, and (iii) a nod gene probe. A predominant Sym plasmid family was identified among the isolates. Three other unrelated Sym plasmid families were also identified. The isolates were also classified either by using a chromosomal DNA hybridization probe or by serological relatedness to 25 different R. leguminosarum bv. trifolii antisera. With either method, it was possible to group the 16 soil isolates into identical or related families. However, the correlation between the two techniques was not high. Irrespective of the means used to classify the bacterial host strain, it was possible to identify the same Sym plasmids in unrelated strains, as well as unrelated Sym plasmids in identical host strains. These data indicate that, within this soil population, there has been genetic exchange of Sym plasmids, and in one instance the hybridization pattern indicates that in vivo recombination of two different Sym plasmids may have occurred. Symbiotic effectiveness tests on red, strawberry, and subterranean clovers clearly differentiated the isolates. In general, the pattern of response was similar within groupings on the basis of Sym plasmid and chromosomal profiles but different between such groups.     

The Channel-Forming Sym1 Protein Is Transported by the TIM23 Complex in a Presequence-Independent Manner

The majority of multispanning inner mitochondrial membrane proteins utilize internal targeting signals, which direct them to the carrier translocase (TIM22 complex), for their import. MPV17 and its Saccharomyces cerevisiae orthologue Sym1 are multispanning inner membrane proteins of unknown function with an amino-terminal presequence that suggests they may be targeted to the mitochondria. Mutations affecting MPV17 are associated with mitochondrial DNA depletion syndrome (MDDS). Reconstitution of purified Sym1 into planar lipid bilayers and electrophysiological measurements have demonstrated that Sym1 forms a membrane pore. To address the biogenesis of Sym1, which oligomerizes in the inner mitochondrial membrane, we studied its import and assembly pathway. Sym1 forms a transport intermediate at the translocase of the outer membrane (TOM) complex. Surprisingly, Sym1 was not transported into mitochondria by an amino-terminal signal, and in contrast to what has been observed in carrier proteins, Sym1 transport and assembly into the inner membrane were independent of small translocase of mitochondrial inner membrane (TIM) and TIM22 complexes. Instead, Sym1 required the presequence of translocase for its biogenesis. Our analyses have revealed a novel transport mechanism for a polytopic membrane protein in which internal signals direct the precursor into the inner membrane via the TIM23 complex, indicating a presequence-independent function of this translocase.     

Genetic dissection of the initiation of the infection process and nodule tissue development in the Rhizobium-pea (Pisum sativum L.) symbiosis

Twelve non-nodulating pea (Pisum sativum L.) mutants were studied to identify the blocks in nodule tissue development. In nine, the reason for the lack of infection thread (IT) development was studied; this had been characterized previously in the other three mutants. With respect to IT development, mutants in gene sym7 are interrupted at the stage of colonization of the pocket in the curled root hair (Crh- phenotype), mutants in genes sym37 and sym38 are blocked at the stage of IT growth in the root hair cell (Ith- phenotype) and mutants in gene sym34 at the stage of IT growth inside root cortex cells (Itr- phenotype). With respect to nodule tissue development, mutants in genes sym7, sym14 and sym35 were shown to be blocked at the stage of cortical cell divisions (Ccd- phenotype), mutants in gene sym34 are halted at the stage of nodule primordium (NP) development (Npd- phenotype) and mutants in genes sym37 and sym38 are arrested at the stage of nodule meristem development (Nmd- phenotype). Thus, the sequential functioning of the genes Sym37, Sym38 and the gene Sym34 apparently differs in the infection process and during nodule tissue development. Based on these data, a scheme is suggested for the sequential functioning of early pea symbiotic genes in the two developmental processes: infection and nodule tissue formation.     

Distribution of O-acetyl groups in the exopolysaccharide synthesized by Rhizobium leguminosarum strains is not determined by the Sym plasmid

The patterns of O-acetylation of the exopolysaccharide (EPS) from the Sym plasmid-cured derivatives of Rhizobium leguminosarum bv. trifolii strain LPR5, R. leguminosarum bv. trifolii strain ANU843 and R. leguminosarum bv. viciae strain 248 were determined by 1H and 13C NMR spectroscopy. Beside a site indicative of the chromosomal background, these strains have one site of O-acetylation in common, namely residue b of the repeating unit. The O-acetyl esterification pattern of EPS of the Sym plasmid-cured derivatives of strains LPR5, ANU843, and 248 was not altered by the introduction of a R. leguminosarum bv. viciae Sym plasmid or a R. leguminosarum bv. trifolii Sym plasmid. The induction of nod gene expression by growth of the bacteria in the presence of Vicia sativa plants or by the presence of the flavonoid naringenin, produced no significant changes in either amount or sites of O-acetyl substitution. Furthermore, no such changes were found in the EPS from a Rhizobium strain in which the nod genes are constitutively expressed. The substitution pattern of the exopolysaccharide from R. leguminosarum is, therefore, determined by the bacterial genome and is not influenced by genes present on the Sym plasmid. This conclusion is inconsistent with the suggestion of Philip-Hollingsworth et al. (Philip-Hollingsworth, S., Hollingsworth, R. I., Dazzo, F. B., Djordjevic, M. A., and Rolfe, B. G. (1989) J. Biol. Chem. 264, 5710-5714) that nod genes of R. leguminosarum bv. trifolii, by influencing the acetylation pattern of EPS, determine the host specificity of nodulation.     

Identification of DNA amplification fingerprinting (DAF) markers close to the symbiosis-ineffective sym31 mutation of pea (Pisum sativum L.)

 We demonstrate efficient genome mapping through a combination of bulked segregant analysis (BSA) with DNA amplification fingerprinting (DAF). Two sets of 64 octamer DAF primers, along with two PCR programs of low- and high-annealing temperatures (30°C and 55°C, respectively), appeared to be enough to locate molecular markers within 2–5 cM of a gene of interest. This approach allowed the rapid identification of four BSA markers linked to the pea (Pisum sativum L.) Sym31 gene, which is responsible for bacteroid and symbiosome differentiation. Three of these markers are shown to be tightly linked to the sym31 mutation. Two markers flanking the Sym31 gene, A21-310 and B1-277, cover a 4–5 cM interval of pea linkage group 3. Both markers were converted to sequence-characterized amplified regions (SCARs). The flanking markers may be potential tools for marker-assisted selection or for positional cloning of the Sym31 gene. Received: 2 July 1998 / Accepted: 8 October 1998     

Identification and characterization of the nodD gene in Rhizobium leguminosarum strain 1001

A gene library of the symbiotic 240-kb plasmid of Rhizobium leguminosarum strain 1001 was constructed in pUC18. The clones showing homology with a 6.6-kb fragment containing nodEFDABC from the Sym plasmid pRLlJI were detected by colony hybridization. Additional probes from the symbiotic region of pRLlJI were used to localize the corresponding genes on the map of pRle1001a. The relative positions of nod and nif gene clusters are different than those of pRLlJI. A comparison of the amino acid sequence for NodD from pRle1001a with NodD proteins from other Rhizobium species showed a high degree of sequence conservation at the amino terminus of the protein.     

Characterization of Zea mays endosperm C-24 sterol methyltransferase: one of two types of sterol methyltransferase in higher plants

We report the characterization of a higher-plant C-24 sterol methyltransferase by yeast complementation. A Zea mays endosperm expressed sequence tag (EST) was identified which, upon complete sequencing, showed 46% identity to the yeast C-24 methyltransferase gene (ERG6) and 75% and 37% amino acid identity to recently isolated higher-plant sterol methyltransferases from soybean and Arabidopsis, respectively. When placed under GAL4 regulation, the Z. mays cDNA functionally complemented the erg6 mutation, restoring ergosterol production and conferring resistance to cycloheximide. Complementation was both plasmid-dependent and galactose-inducible. The Z. mays cDNA clone contains an open reading frame encoding a 40 kDa protein containing motifs common to a large number of S-adenosyl-L-methionine methyltransferases (SMTs). Sequence comparisons and functional studies of the maize, soybean and Arabidopsis cDNAs indicates two types of C-24 SMTs exist in higher plants.     

Characteristics of PRD1, a Plasmid-Dependent Broad Host Range DNA Bacteriophage

Several distinctive properties of PRD1, an icosahedral plasmid-dependent phage, are described. The drug-resistance plasmid-dependent host range of PRD1 extends beyond the P incompatibility group and includes gram-negative bacteria containing plasmids of incompatibility groups N and W. PRD1 phage will infect pseudomonads and Enterobacteriaceae containing either a P or W incompatibility group plasmid. PRD1 adsorbs to the cell wall of R(+) bacteria and thus its infectivity indicates cell wall alterations by these drug-resistance plasmid groups. PRD1 nucleic acid is duplex DNA with an estimated molecular weight of 24 x 10(6). The appearance of PRD1 in electron micrographs is suggestive of lipid content in addition to its buoyant density of 1.348 in CsCl and its sensitivity to chloroform. The latent period of PRD1 varies with the R(+) host bacterial strain used for growth of the phage.     

The Sym31Gene Responsible for Bacteroid Differentiation Is Involved in Nitrate-Dependent Nodule Formation in Pea Plants

The effects of exogenous nitrate on the number of developing nodules and their leghemoglobin content in the original pea (Pisum sativumL.) line and its symbiotic mutants were studied. Mutation in the Sym31gene conferred the tolerance to nitrate in the corresponding pea line and manifested itself as the number of nodules independent of the nitrate concentration. Thus, the Sym31gene was identified as the only known symbiotic gene involved in both the differentiation of symbiotic compartments and the nitrate-dependent process of nodule formation. The presence of leghemoglobin in double mutants (sym13, sym31) indicates the possibility of the complementary contribution of these genes in the control of leghemoglobin synthesis.     

Regulation of Syrm and Nodd3 in Rhizobium Meliloti

The early steps of symbiotic nodule formation by Rhizobium on plants require coordinate expression of several nod gene operons, which is accomplished by the activating protein NodD. Three different NodD proteins are encoded by Sym plasmid genes in Rhizobium meliloti, the alfalfa symbiont. NodD1 and NodD2 activate nod operons when Rhizobium is exposed to host plant inducers. The third, NodD3, is an inducer-independent activator of nod operons. We previously observed that nodD3 carried on a multicopy plasmid required another closely linked gene, syrM, for constitutive nod operon expression. Here, we show that syrM activates expression of the nodD3 gene, and that nodD3 activates expression of syrM. The two genes constitute a self-amplifying positive regulatory circuit in both cultured Rhizobium and cells within the symbiotic nodule. We find little effect of plant inducers on the circuit or on expression of nodD3 carried on pSyma. This regulatory circuit may be important for regulation of nod genes within the developing nodule.     

Selection by genetic complementation and characterization of the gene coding for the yeast porphobilinogen deaminase.

The porphobilinogen deaminase (PBG-D) gene of Saccharomyces cerevisiae has been isolated by genetic complementation of a mutant GL7 (alpha hem 3) strain, previously shown to be defective in this haembiosynthetic enzyme [Gollub, Liu, Dayan, Adlersberg & Sprinson (1977) J. Biol. Chem. 252, 2846-2854]. The gene was selected from a yeast wild-type genomic DNA library ligated into the shuttle vector YEp13. The complementing gene restored growth of the hem 3 (PBG-D) mutant strain on media in the absence of exogeneous haem or fatty acid and sterol supplements. The recombinant plasmid was retained in the Hem+ transformant provided that selective pressure for plasmid-dependent growth was maintained. Transformation of the mutant strain (hem 3) restored the PBG-D activity to levels up to 10-fold those of the parental strain. The mutant strain GL7 does not show any measurable enzymic activity. Analysis of the plasmid designated YEpPBG-D (containing the PBG-D gene) by hybrid-selected translation revealed that it contained the coding information for a single protein of apparent Mr 43,000. The coding region was localized on an 1.5 kb endonuclease-EcoRI fragment (E4), within the 5.5 kb genomic insert in YEpPBG-D.