Use of green fluorescent protein color variants expressed on stable broad-host-range vectors to visualize rhizobia interacting with plants.

We developed two sets of broad-host-range vectors that drive expression of the green fluorescent protein (GFP) or color variants thereof (henceforth collectively called autofluorescent proteins [AFPs]) from the lac promoter. These two sets are based on different replicons that are maintained in a stable fashion in Escherichia coli and rhizobia. Using specific filter sets or a dedicated confocal laser scanning microscope setup in which emitted light is split into its color components through a prism, we were able to unambiguously identify bacteria expressing enhanced cyan fluorescent protein (ECFP) or enhanced yellow fluorescent protein (EYFP) in mixtures of the two. Clearly, these vectors will be valuable tools for competition, cohabitation, and rescue studies and will also allow the visualization of interactions between genetically marked bacteria in vivo. Here, we used these vectors to visualize the interaction between rhizobia and plants. Specifically, we found that progeny from different rhizobia can be found in the same nodule or even in the same infection thread. We also visualized movements of bacteroids within plant nodule cells.

Simultaneous imaging of Pseudomonas fluorescens WCS365 populations expressing three different autofluorescent proteins in the rhizosphere: new perspectives for studying microbial communities.

To visualize simultaneously different populations of pseudomonads in the rhizosphere at the single cell level in a noninvasive way, a set of four rhizosphere-stable plasmids was constructed expressing three different derivatives of the green fluorescent protein (GFP), namely enhanced cyan (ECFP), enhanced green (EGFP), enhanced yellow (EYFP), and the recently published red fluorescent protein (RFP; DsRed). Upon tomato seedling inoculation with Pseudomonas fluorescens WCS365 populations, each expressing a different autofluorescent protein followed by plant growth for 5 days, the rhizosphere was inspected using confocal laser scanning microscopy. We were able to visualize simultaneously and clearly distinguish from each other up to three different bacterial populations. Microcolonies consisting of mixed populations were frequently observed at the base of the root system, whereas microcolonies further toward the root tip predominantly consisted of a single population, suggesting a dynamic behavior of microcolonies over time. Since the cloning vector pME6010 has a broad host range for gram-negative bacteria, the constructed plasmids can be used for many purposes. In particular, they will be of great value for the analysis of microbial communities, for example in processes such as biocontrol, biofertilization, biostimulation, competition for niches, colonization, and biofilm formation.

The sss colonization gene of the tomato-Fusarium oxysporum f. sp. radicis-lycopersici biocontrol strain Pseudomonas fluorescens WCS365 can improve root colonization of other wild-type pseudomonas spp.bacteria.

We show that the disease tomato foot and root rot caused by the pathogenic fungus Fusarium oxysporum f. sp. radicis-lycopersici can be controlled by inoculation of seeds with cells of the efficient root colonizer Pseudomonas fluorescens WCS365, indicating that strain WCS365 is a biocontrol strain. The mechanism for disease suppression most likely is induced systemic resistance. P. fluorescens strain WCS365 and P. chlororaphis strain PCL1391, which acts through the production of the antibiotic phenazine-1-carboxamide, were differentially labeled using genes encoding autofluorescent proteins. Inoculation of seeds with a 1:1 mixture of these strains showed that, at the upper part of the root, the two cell types were present as microcolonies of either one or both cell types. Microcolonies at the lower root part were predominantly of one cell type. Mixed inoculation tended to improve biocontrol in comparison with single inoculations. In contrast to what was observed previously for strain PCL1391, mutations in various colonization genes, including sss, did not consistently decrease the biocontrol ability of strain WCS365. Multiple copies of the sss colonization gene in WCS365 improved neither colonization nor biocontrol by this strain. However, introduction of the sss-containing DNA fragment into the poor colonizer P. fluorescens WCS307 and into the good colonizer P. fluorescens F113 increased the competitive tomato root tip colonization ability of the latter strains 16- to 40-fold and 8- to 16-fold, respectively. These results show that improvement of the colonization ability of wild-type Pseudomonas strains by genetic engineering is a realistic goal.

A Lotus japonicus nodulation system based on heterologous expression of the fucosyl transferase NodZ and the acetyl transferase NoIL in Rhizobium leguminosarum.

Heterologous expression of NodZ and NolL proteins in Rhizobium leguminosarum bv. viciae led to the production of acetyl fucosylated lipo-chitin oligosaccharides (LCOs), indicating that the NolL protein obtained from Mesorhizobium loti functions as an acetyl transferase. We show that the NolL-dependent acetylation is specific for the fucosyl penta-N-acetylglucosamine species. In addition, the NolL protein caused elevated production of LCOs. Efficient nodulation of Lotus japonicus by the NodZ/NolL-producing strain was demonstrated. Nodulation efficiency was further improved by the addition of the ethylene inhibitor L-alpha-(2-aminoethoxyvinyl) glycine (AVG).

Bacterial nodulation protein NodZ is a chitin oligosaccharide fucosyltransferase which can also recognize related substrates of animal origin.

The nodZ gene, which is present in various soil bacteria such as Bradyrhizobium japonicum, Azorhizobium caulinodans, and Rhizobium loti, is involved in the addition of a fucosyl residue to the reducing N-acetylglucosamine residue of lipochitin oligosaccharide (LCO) signal molecules. Using an Escherichia coli strain that produces large quantities of the NodZ protein of B. japonicum, we have purified the NodZ protein to homogeneity. The purified NodZ protein appears to be active in an in vitro transfucosylation assay in which GDP-beta-fucose and LCOs or chitin oligosaccharides are used as substrates. The products of the in vitro reaction using chitin oligosaccharides as substrate were studied by using mass spectrometry, linkage analysis, and composition analysis. The data show that one fucose residue is added to C6 of the reducing-terminal N-acetylglucosamine residue. The substrate specificity of NodZ protein was analyzed in further detail, using radiolabeled GDP-beta-fucose as the donor. The results show that chitin oligosaccharides are much better substrates than LCOs, suggesting that in Rhizobium NodZ fucosylates chitin oligosaccharides prior to their acylation. The free glycan core pentasaccharides of N-linked glycoproteins are also substrates for NodZ. Therefore, the NodZ enzyme seems to have an activity equivalent to that of the enzyme involved in the addition of the C6-linked fucosyl substituent in the glycan core of N-linked glycoproteins in eukaryotes. Oligosaccharides that contain only one N-acetylglucosamine at the reducing terminus are also substrates for NodZ, although in this case very high concentrations of such oligosaccharides are needed. An example is the leukocyte antigen Lewis-X, which can be converted by NodZ to a novel fucosylated derivative that could be used for binding studies with E-selectin.

Cloning and characterization of four genes of Rhizobium leguminosarum bv. trifolii involved in exopolysaccharide production and nodulation.

Four different genes of Rhizobium leguminosarum bv. trifolii strain RBL5599 involved in exopolysaccharide (EPS) production were identified by complementation of Tn5-induced EPS-deficient mutants (Exo mutants) with a cosmid bank. On one cosmid pssA was located, which was found to be almost identical to the pss4 gene from R. leguminosarum bv. viciae VF39 and highly homologous to a family of glycosyl transferases. Two pssA mutants, exo2 and exo4, were characterized and found to produce 19 and 1% of the wild-type amount of EPS, respectively. The three other genes were found to be closely linked on a different complementing cosmid. pssC revealed similarity to exoM and exoW of R. meliloti, both encoding glucosyl transferases involved in the synthesis of succinoglycan. A mutation in this gene (mutant exo50) did reduce EPS synthesis to 27% of the wild-type amount. We found an operon closely linked to pssC, consisting of two overlapping genes, pssD and pssE, that is essential for EPS production. Homology of pssD and pssE was found with cps14F and cps14G of Streptococcus pneumoniae, respectively: two genes responsible for the second step in capsule polysaccharide synthesis. Furthermore, pssD and pssE were homologous to the 5' and 3' parts, respectively, of spsK of Sphingomonas S88, which encodes a putative glycosyl transferase. Structural analysis of EPS produced by Exo mutants exo2, exo4, and exo50 showed it to be identical to that of the parental strain RBL5599, with the exception of acetyl groups esterified to one of the glucose residues being absent.

Rhizobium nodulation protein NodA is a host-specific determinant of the transfer of fatty acids in Nod factor biosynthesis.

In the biosynthesis of lipochitin oligosaccharides (LCOs) the Rhizobium nodulation protein NodA plays an essential role in the transfer of an acyl chain to the chitin oligosaccharide acceptor molecule. The presence of nodA in the nodABCIJ operon makes genetic studies difficult to interpret. In order to be able to investigate the biological and biochemical functions of NodA, we have constructed a test system in which the nodA, nodB and nodC genes are separately present on different plasmids. Efficient nodulation was only obtained if nodC was present on a low-copy-number vector. Our results confirm the notion that nodA of Rhizobium leguminosarum biovar viciae is essential for nodulation on Vicia. Surprisingly, replacement of R. l. by viciae nodA by that of Bradyrhizobium sp. ANU289 results in a nodulation-minus phenotype on Vicia. Further analysis revealed that the Bradyrhizobium sp. ANU289 NodA is active in the biosynthesis of LCOs, but is unable to direct the transfer of the R. l. by, viciae nodFE-dependent multi-unsaturated fatty acid to the chitin oligosaccharide acceptor. These results lead to the conclusion that the original notion that nodA is a common nod gene should be revised.

Rhizobium NodI and NodJ proteins play a role in the efficiency of secretion of lipochitin oligosaccharides.

Thin-layer chromatographic analysis of extracts of D-[1-14C]glucosamine-labelled rhizobia was used to analyze the effects of nodI, nodJ, and nodT on secretion of lipochitin oligosaccharide (LCO) signal molecules. Secretion was analyzed by comparing quantities of radiolabelled LCOs present in the cellular and spent growth medium fractions. A second rapid and sensitive method was introduced to estimate the secreted LCO fractions by using D-[1-14C]glucosamine-labelled cells grown in medium supplemented with chitinase. At various times after induction of LCO synthesis, the quantity of degradation products of LCOs was compared with the amount of nondegraded LCOs. In wild-type strains of Rhizobium leguminosarum biovars viciae and trifolii the nodI and nodJ genes (but not the nodT gene) strongly enhance the secretion of LCOs during the first 5 h after the induction of LCO synthesis. In LCO-overproducing strains the enhancement of secretion was observed only during the first 3 h after induction. At times later than 5 h after induction, a significant influence of the presence of the nodI and nodJ genes on LCO secretion was detectable neither in the wild type nor in LCO-overproducing strains. By using plasmids in which the nodI and nodJ genes are cloned separately under control of a flavonoid-inducible promoter, it was shown that both genes are needed for a wild-type level of LCO secretion. Therefore, these results demonstrate that nodI and nodJ play a role in determining the efficiency of LCO secretion.

Structural identification of metabolites produced by the NodB and NodC proteins of Rhizobium leguminosarum.

The Rhizobium nodulation genes nodABC are involved in the synthesis of lipo-chitin oligosaccharides. We have analysed the metabolites which are produced in vivo and in vitro by Rhizobium strains which express the single nodA, nodB and nodC genes or combinations of the three. In vivo radioactive labelling experiments, in which D-[1-14C]-glucosamine was used as a precursor, followed by mass spectrometric analysis of the purified radiolabelled metabolic products, showed that Rhizobium strains that only express the combination of the nodB and nodC genes do not produce lipo-chitin oligosaccharides but instead produce chitin oligomers (mainly pentamers) which are devoid of the N-acetyl group on the non-reducing terminal sugar residue (designated NodBC metabolites). Using the same procedure we have shown that when the nodL gene is expressed in addition to the nodBC genes the majority of metabolites contain an additional O-acetyl substituent on the non-reducing terminal sugar residue (designated NodBCL metabolites). The NodBC and NodBCL metabolites purified after in vivo labelling were compared with the radiolabelled metabolites produced in vitro by Rhizobium bacterial cell lysates to which UDP-N-acetyl-D-[U-14C]-glucosamine was added using thin-layer chromatography. The results show that the lysates of strains which expressed the nodBC or nodBCL genes can also produce NodBC and NodBCL metabolites. The same results were obtained when the NodB and NodC proteins were produced separately in two different strains. On the basis of these and other recent results, we propose that NodB is a chitin oligosaccharide deacetylase, NodC an N-acetylglucosaminyltransferase and, by default, NodA is involved in lipid attachment.

The structures and biological activities of the lipo-oligosaccharide nodulation signals produced by type I and II strains of Bradyrhizobium japonicum.

Bradyrhizobium japonicum produces lipo-oligosaccharide signal molecules that induce deformation of root hairs and meristematic activity on soybeans. B. japonicum USDA135 (a Type I strain) produces modified chitin pentasaccharide molecules with either a terminal N-C16:0- or N-C18:1-glucosamine with and without an O-acetyl group at C-6 and with 2-O-methylfucose linked to C-6 of the reducing N-acetylglucosamine. An additional molecule has N-C16:1-glucosamine and no O-acetyl group. All of these molecules cause root hair deformation on Vicia sativa and Glycine soja. The C18:1-containing molecules were tested and found to induce meristem formation on G. soja. USDA61 (a Type II strain) produces eight additional molecules. Five have a carbamoyl group on the terminal N-acylglucosamine. Six have chitin tetrasaccharide backbones. Three have a terminal N-acyl-N-methylglucosaminosyl residue. In four molecules, the reducing-end N-acetylglucosamine is glycosidically linked to glycerol and has a branching fucosyl, rather than a 2-O-methylfucosyl, residue. One molecule has a terminal N-acylglucosamine that has both acetyl and carbamoyl groups (one each).

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.

nodO, a new nod gene of the Rhizobium leguminosarum biovar viciae sym plasmid pRL1JI, encodes a secreted protein.

The region of the Rhizobium leguminosarum biovar viciae Sym plasmid pRL1JI, responsible for the production and secretion of a previously described 50-kilodalton protein (R. A. de Maagd, C. A. Wijffelman, E. Pees, and B. J. J. Lugtenberg, J. Bacteriol. 170:4424-4427, 1988), was cloned and its nucleotide sequence was determined. A new nod gene, nodO, preceded by a poorly conserved nod box, was identified and its transcriptional start site was determined. Comparison of its predicted protein product with the N-terminal amino acid sequence of the isolated secreted protein showed that nodO is the structural gene of this protein, although the nucleotide sequence predicted a protein only 30,002 daltons in size. This comparison also showed that the secreted protein is not the product of N-terminal processing of a larger precursor. A conventional N-terminal signal sequence was not detected in the NodO protein. The NodO protein has significant homology with a part (residues 720 to 920) of the hemolysin protein (HlyA) of Escherichia coli. Analysis of the transcriptional regulation of the nodO gene revealed that, in contrast with other nod promoters in this species, activity of the nodO promoter is greatly enhanced in the presence of multiple copies of the nodD gene.

Additional nodulation genes on the Sym plasmid of Rhizobium leguminosarum biovar viciae.

A Rhizobium leguminosarum biovar viciae strain lacking a 40 kb DNA region of the Sym plasmid pRL1IJ to the left (3' side) of gene nodE failed to nodulate Vicia sativa plants. Therefore this DNA region was investigated for the presence of additional nodulation genes. Complementation experiments indicated that the DNA region to the left (3' side) of nodE is functionally homologous between R. leguminosarum bv. viciae and R. leguminosarum bv. trifolii. In this DNA region, three nodulation genes were identified, nodT, nodM and nodL. TnphoA insertions in the nodT gene, about 4.5 kb to the left of nodE, lead to a delay in nodulation on Trifolium subterraneum, but not on V. sativa plants. TnphoA insertions in gene nodM have no detectable influence on nodulation. Finally, TnphoA insertions in the nodL gene affected nodulation so that only rarely nodules were induced on the inoculated plants. The nucleotide sequence of this gene is presented. On the basis of the sequence a membrane integrated protein is predicted with a molecular weight of 20.1 kDa. Microscopical analysis of the infection process by nodL mutants indicate a role for nodL in maintaining the stability of the infection thread. Experiments using transcriptional lacZ fusions suggest that nodL belongs to the same transcriptional unit as nodF,E. Very low expression of nodL seems to be sufficient for biological activity.

Flagella of a plant-growth-stimulating Pseudomonas fluorescens strain are required for colonization of potato roots.

The role of motility in the colonization of potato roots by Pseudomonas bacteria was studied. Four Tn5-induced flagella-less mutants of the plant-growth-stimulating P. fluorescens WCS374 appeared to be impaired in their ability to colonize growing potato roots.