* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Surface polysaccharide mutants of Rhizobium sp. (Acacia) strain
Genomic library wikipedia , lookup
Bisulfite sequencing wikipedia , lookup
Non-coding DNA wikipedia , lookup
Endogenous retrovirus wikipedia , lookup
Molecular cloning wikipedia , lookup
Vectors in gene therapy wikipedia , lookup
Gel electrophoresis of nucleic acids wikipedia , lookup
Artificial gene synthesis wikipedia , lookup
Nucleic acid analogue wikipedia , lookup
DNA supercoil wikipedia , lookup
Deoxyribozyme wikipedia , lookup
Community fingerprinting wikipedia , lookup
Point mutation wikipedia , lookup
Microbiology (1995), 141, 573-581 Printed in Great Britain Surface polysaccharide mutants of Rhizobium sp. (Acacia) strain GRHZ: major requirement of lipopolysaccharide for successful invasion of Acacia nodules and host range determination Isabel Maria Ldpez-Lara,’ Guy Orgambide,2 Frank B. Dazzo,’ Jose Olivares’ and Nicolds Toro’ Author for correspondence : Nicolas Toro. Tel : 1 Department of Microbiology, Estaci6n Experimentaldel Zaidln, Consejo Superior de lnvestigaciones Cientificas, Prof. Albareda 1, 18008 Granada, Spain 2 Department of Microbiology, Michigan State University, East Lansing, MI 48824, USA +34 58 121011 . Fax : + 34 58 129600. Two transposon Tn5-induced mutants of wild-type broad-host-range Rhizobium sp. GRHZ were isolated and found to harbour different alterations in surface polysaccharides. These mutants, designated GRHZ-14 and GRHZ-50, induced a few, empty nodules on Acacia and lost the ability to nodulate most host herbaceous legumes. Whereas mutant GRHZ-14 produces an acidic exopolysaccharide (EPS) similar to the wild-type, the acidic EPS of mutant GRHZ-50 lacks galactose and the pyruvyl and 3-hydroxybutyryl substituents attached to this sugar moiety. In addition, both mutants GRHZ-50 and GRHZ-14 were altered in smooth lipopolysaccharides (LPS). DNA sequence analyses of the corresponding Tn5 insertions revealed that strain GRHZ-50 was mutated in a DNA locus homologous to gal€, and in vitro enzyme assays indicated that the UDPglucose 4-epimerase (GalE) activity was missing in this mutant strain. DNA hybridization studies showed that the GRHZ-50 mutant DNA has homologous sequences within the different biovars of Rhizobium leguminosarum. However, no DNA homology to GRHZ-14 altered DNA was found in those rhizobial strains, indicating that it represents a new chromosomal Ips locus in Rhizobium sp. (Acacia) involved in symbiotic development. Keywords : Rhixobium sp. GRH2, legume tree, polysaccharide, Tn5 INTRODUCTION Acacia is the largest and most diverse genus of legume trees, containing approximately 1500 species, and serves as a model legume for studies of symbiotic nitrogen fixation under conditions of desiccation stress. We are investigating the role(s) of Rhixobizrm surface glycoconjugates in the development of nitrogen-fixing rootnodule symbiosis with Acacia. For these studies, we are using wild-type Rhixobium sp. GRH2 which was originally isolated from root nodules of Acacia yanopLylla in Chile (Herrera e t al., 1985). A unique aspect of this rhizobial strain is its wide host range, which includes legume trees (e.g. Acacia, Prosopis) and a diversity of herbaceous legumes such as Trzfolizrm, Lotzrs, Phaseolus, Vicia and Siratro (Herrera e t al., 1985; L6pez-Lara e t al., 1993). Although many reports suggest an involvement of Rhixobium acidic heteropolysaccharides (exopolysaccha.......................................................................................................................................................... Abbreviation : EPS, exopolysaccharide. 0001-9303 0 1995 SGM rides ; EPS) and lipopolysaccharides (LPS) in symbiotic infection of herbaceous legume roots (Abe e t al., 1984; Canter Cremers e t al., 1990; Carlson, 1982; Dazzo e t al., 1992; Herrera e t al., 1985; Lamb e t al., 1982; Maier & Brill, 1978; Muller e t al., 1988; Noel e t al., 1986; Reuber e t al., 1991 ; Zhan e t al., 1992), little is known about their importance in root infection of legume trees. We have recently shown that the excreted acidic heteropolysaccharide produced by wild-type GRH2 and R. legzrminosarum bv. trifolii ANU843 are very similar in structure, and the analysis of an Exo- mutant derivative of GRH2 indicates that this surface glycoconjugate is important for invasion of host cells in Acacia nodules (L6pez-Lara e t a/., 1993). In this study, we isolated and characterized two different surface polysaccharide mutants of GRH2 in order to examine the role of smooth LPS in symbiotic development. This study of new GRH2 mutants identifies : (i) a major requirement of smooth LPS for successful invasion of Acacia nodules and in determination of host range; (ii) a dual role of exoB encoding UDPglucose 4epimerase involved in production of both smooth LPS Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 573 I. M. L O P E Z - L A R A a n d O T H E R S and acidic EPS and in development of root nodule symbiosis; a n d (iii) a n e w chromosomal Ips locus in Rhipbizlm involved in symbiotic development. METHODS Bacterial strains and genetic manipulations. Rhixobitlm sp. GRH2 was originally isolated from root nodules of A . yanopbylla (Herrera e t al., 1985). Other bacterial strains used in this work are listed in Table 1. Bacteria were routinely grown in minimal medium (MM; Robertsen e t al., 1981), T Y (Beringer, 1974) or T Y supplemented with mannitol (YMT). Transposon Tn5: :mob random mutagenesis was done by mating Escherichia coli S17-1 (pSUP5011) with RhiTobium sp. GRH2. Kanamycin (Km)-resistant transconjugants were selected on MM agar (L6pez-Lara e t al., 1993). Antibiotics were used at the following concentrations : kanamycin sulfate (Km), 180 pg ml-' ; tetracycline (Tc), 10 pg ml-'. Plasmid isolation, random primer DNA labelling, DNA hybridization, and Southern blotting were performed according to standard procedures (Maniatis e t al., 1982). Cloning of the GRHZ-14 and GRHZ-50 Tn5 insertions. The total DNA of mutants GRH2-14 and GRH2-50 was EcoRI digested and cloned in plasmid pSUP102. After ligation, D N A was transformed in E. coli DH5a (Bethesda Research Laboratories). Km-resistant colonies were selected and analysed for plasmid content. Plasmid clones with the T n 5 insertion were designated pIS14 and pIS50. DNA sequencing. The left junctions of Tn5insertions 14 and 50 were cloned as Sall fragments in pUC18 from plasmids pIS14 and pIS50, respectively. The sequence data were obtained by the chain-termination method (Sanger e t al., 1977) using the ISSOL specific primer 5'-AAAGGTTCCGTTCAGGACGC-3'. Sequence analysis. Sequence analysis and homology search were done with the GCG software package (Devereux e t al., 1984). The amino acid sequences deduced from the nucleotide sequences were compared with the actual version in the Swissprot and PIR Protein Data Banks using the program FASTA (Pearson & Lipman, 1988). LPS analyses by SDS-PAGE. Cell cultures (1.5 ml) were pelleted, suspended in SDS sample buffer (Laemmli, 1970), denatured at 100 "C for 3 min, and treated with proteinase K. After discontinuous SDS-PAGE, gels were stained by periodic acid/silver for carbohydrates (Hitchcock & Brown, 1983). Isolation and fractionation of the EPS components. The native EPS was isolated and fractionated as previously described (Lopez-Lara e t al., 1993). Alternatively, EPS was obtained from bacteria grown on solid medium. Cells were suspended in 10 mM sodium phosphate buffer (5-7 ml per plate), and pelleted by centrifugation. EPS was isolated by precipitation of the culture supernatant with 2 vols cold ethanol. The precipitated EPS was redissolved in water and then dialysed against water for 48 h at 4 "C. Compositional and spectroscopic analyses of the EPS. Sugar composition, glycosidic linkage determination and 'H-NMR analyses of the native EPS were carried out as previously described (Lopez-Lara e t al., 1993). Nodulation assays. Plants were grown on nitrogen-free medium (Rigaud & Puppo, 1975) under microbiologically controlled conditions and inoculated as described by Olivares e t al. (1980). Nodulation of tree legumes and herbaceous legumes was followed for 6 months and 1 month, respectively. Table 1. Strains used or constructed in this work Strain Rhixobium sp. GRH2 Source/reference Broad-host-range Rhixobium sp. isolated from A . ganopbylla root nodules GRH2 derivative obtained by Tn5 mutagenesis, exo-57, EPSGRH2 derivative obtained by T n i mutagenesis, exo- 14 with altered LPS GRH2 derivative obtained by Tn5 mutagenesis, exo-50, lacks the UDPglucose 4-epimerase Herrera e t al. (1985) R. meliloti Rm2011 Wild-type, SmR C a d e t al. (1979) R. leguminosarum VF39 RS1050 Wild-type, bv. viciae, SmR Wild-type, bv. triflii 8002 Wild-type, bv. phaseoli Priefer (1989) F. Rodriguez-Quiiiones, Facultad Farmacia, Universidad de Sevilla, Spain Lamb e t al. (1982) B. japonicum 122DES Wild-type, Hup' Emerich et al. 1980) A . tumefaciens A348 A136 containing pTiA6NC Garfinkel & Nester (1980) GRH2-57 GRH2-14 GRH2-50 574 Relevant characteristics Lopez-Lara et al. (1993) This work This work Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 Rhixobitcm sp. LPS mutants and symbiotic behaviour Enzyme assay for UDPglucose 4-epimerase. Bacteria were grown on MM medium containing glucose or galactose as sole carbon source. Cells were disrupted by sonication and debris removed by centrifugation. Cell-free extracts were used to measure the UDPglucose 4-epimerase activity according to Fukasawa e t al. (1980). Plant microscopy. Root nodules were processed as previously described (Lopez-Lara et al., 1993). Two micrometre sections were stained with alkaline toluidine blue solution and examined by light microscopy. Ultrathin sections were stained with uranyl acetate and lead citrate, and examined by transmission electron microscopy using a Philips CM-10 electron microscope. Computer-assistedimage analysis of nodule histology was performed using Bioquand System IV software as described previously (Dazzo & Petersen, 1989). RESULTS Isolation and characterization of Rhizobium sp. GRH2 surface polysaccharide mutants RhixobiZlm sp. GRH2 was mutagenized with Tn5: :mob, and Kmr transconjugants were selected on MM agar with mannitol as carbon source. By screening 10000 random T n 5 insertion mutants, colonies with a non-mucoid, supermucoid or a rough morphology were selected visually (Lopez-Lara e t al., 1993). Two of the mutant strains with a rough colony morphology were designated GRH2-14 and GRH2-50. A Southern blot of EcoRIdigested total DNA of GRH2-14 and GRH2-50 mutant strains, probed with Tn5, showed a single insertion located in 2.4 and 3-2 kb EcoRI fragments, respectively (data not shown). In addition, Southern blotting an electrophoretic gel of Eckhart lysates from these mutants using T n 5 probe indicated that the T n 5 insertions were located on the chromosome, not on any of the five large plasmids (Toro e t al., 1984). T o determine whether the T n 5 insertions were responsible for the altered colony morphology exhibited by the mutants, the insertions were cloned as EcoRI fragments (Fig. la) in the pSUP102 vector and transferred back to the wild-type strain GRH2. Transcon jugants showed the same colony morphology to that of GRH2-14 and GRH2-50 mutant strains indicating that the T n 5 insertion was responsible for the rough colony phenotype. These results were further confirmed by hybridization of EcoRI-digested total DNA from RS R k1 I 1 2 3 4 5 Fig. 2. LPS profiles on an SDS-polyacrylamide gel. Periodic acid/siIver-stainedSDS-polyacrylamide gel (12 %) of proteinaseK-treated SDS extracts of Rhizobiurn sp. GRH2 (lane l), EPSGRHZ-57 (lane 2), GRH2-50 (lane 3), GRH2-50 complemented with plasmid p501 (lane 4) and GRH2-14 (lane 5). GRH2 and mutants using the mutant cloned restriction fragments as D N A probes. The rough colony phenotype exhibited by GRH2-14 and GRH2-50 strains suggested that they were Ips mutants. Proteinase-K-digested cell extracts of wild-type and mutant strains were separated by SDS-PAGE and stained by the periodic acid/silver procedure. As shown in Fig. 2, the relative staining intensity of the slow-migrating carbohydrate band of ‘smooth’ LPS present in the wildtype was considerably reduced in the mutants. Apparently, the GRH2-14 and GRH2-50 mutants have an alteration in the smooth LPS, due likely to a loss in 0antigen content. Reintroduction of the corresponding T n 5 insertions into the wild-type GRH2 also reproduced the altered LPS profile. Complementation of Rhizobium sp. GRH2-14 and GRH2-50 mutants (b) R S t l H I RSS I. I RS I 1 B I R . I p501 1 kb Fig. 1, (a) Restriction fragments containing the Tn5 insertion of GRH2-14 and GRH2-50 mutant strains. (b) Restriction map of GRH2-50 complementing plasmid p501. R, EcoRI; B, BarnHI; HI Hindlll; 5, Sall. We attempted to restore the wild-type phenotype of GRH2-14 and GRH2-50 mutants by carrying out a conjugative mating with a wild-type GRH2 cosmid (pLAFR1) clone bank (Lopez-Lara e t al., 1993). Mucoid colonies, occurring at a frequency of 0.1 %, were obtained only in the case of GRH2-50 and no complementation was achieved for the GRH2-14 mutant strain. Cosmids isolated from the mucoid colonies of GRH2-50 deriva- Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 575 I. M. L O P E Z - L A R A a n d O T H E R S tives were identical and designated p501. A restriction map of cosmid p501 is shown in Fig. l(b). Upon reintroduction of cosmid p501 into mutant GRH2-50, the wild-type mucoid phenotype was restored, which indicated that this phenotype was encoded by plasmid p501. Hybridization of p501 with the EcoRI Tn5-mutant fragment isolated from GRH2-50 further confirmed that the DNA inserted in p501 carries the wild-type DNA that was mutated by the T n 5 insertion. In addition, plasmid p501 also restored the wild-type LPS profile (Fig. 2, lane 4) of mutant GRH2-50 but not of mutant strain GRH214. GRHZ GRH2-50 Identification of DNA homologous to GRH2-14 and GRH2-50 mutant loci in Rhizobium Genomic DNA from various Rbixobiztm species was examined for homology to the mutant loci of GRH2-14 and GRH2-50 by Southern blot hybridization. DNA fragments homologous to the GRH2-50 DNA probe (Fig. la) were found in R. legztminosarzlm bv. viciae, bv. trzfolii and bv. pkaseoli but no homology was detected with Rhixobatlm meliloti, Bradyrbixobitlm japonicztm or Agrobacteriztm tztmefaciens DNA. On the contrary, no DNA fragments homologous to the GRH2-14 DNA probe (Fig. la) were found in the four fast-growing rhizobia analysed nor in B. japonicztm or A. tztmefaciens (data not shown). In addition, no homology was detected with the R. legztminosarmz strain VF39 Ips genes containing plasmid pCos4 (Priefer, 1989). Sequencing of Tn5 insertions In order to better understand the phenotypes of GRH2-14 and GRH2-50 mutations, we determined the DNA sequence of the corresponding left Tn5-DNA junctions. The partial amino acid sequences deduced were compared with sequences in the Swissprot and PIR Data Banks. N o homologous sequences were found to the predicted product encoded by the mutant locus of GRH2-14. O n the other hand, a significant homology (up to 43%) to GalE protein (UDPglucose 4-epimerase) from different organisms was found for the putative protein encoded by the GRH2-50 mutant locus. This result suggested that strain GRH2-50 was an exoB mutant. Analysis of the UDPglucose 4-epimerase activity in wild-type GRHZ and derivative strains To further confirm that strain GRH2-50 was an exoB mutant, cell-free extracts from wild-type GRH2 and the mutant GRH2-50 were assayed for the presence of UDPglucose 4-epimerase activity. Data indicated that this enzyme activity was present in the wild-type [99 nmol substrate used min-' (mg protein)-'] but absent in the GRH2-50 mutant strain. Similar values were obtained for cells grown with glucose or galactose as the sole carbon source indicating a constitutive expression. In the cell-free extract prepared from GRH2-50 complemented with cosmid p501,the enzymic activity was recovered [98 nmol substrate used min-' (mg protein)-']. 576 5 4 3 p.p.m. 2 1 Fig. 3. 'H-NMR spectra of the native acidic EPS from GRH2, GRH2-50 and GRHZ-50 complemented with plasmid p501. 3-HB, 3-Hydroxybutyryl substituent; Ac, acetate; Pyr, pyruvyl substituent. Structural evaluation of the acidic heteropolysaccharides from GRH2-14, GRH2-50 and GRH2-50(~501) Gel filtration analyses indicated that while GRH2-14 produced a similar amount of EPS to the wild-type GRH2, the yield of EPS produced by mutant GRH2-50 was fivefold lower. Based on sugar composition and 'HNMR spectral features, the high molecular mass acidic EPS made by the insertion-mutant GRH2-14 was indistinguishable from the wild-type GRH2 acidic EPS, which consists of an octasaccharide-repeat-unit-based polymer with glucose, glucuronic acid and galactose glycosyl components in a 5 :2 : 1 ratio, and acetyl, pyruvyl and 3-hydroxybutyryl substitutions (Lopez-Lara e t al., 1993). In contrast, 'H-NMR analysis indicated that GRH2-50 EPS was altered in both glycosidic and non-carbohydrate substitutions composition (Fig. 3). The spectrum of this EPS was totally devoid of 3-hydroxybutyryl resonances and displayed a single pyruvyl resonance whose relative integration indicated that GRH2-50 EPS bears a single pyruvate residue per repeat unit, as compared to two residues in GRH2 EPS. Compositional analysis showed that GRH2-50 polysaccharide contains glucose and glucuronic acid in an approximate 3: 1 ratio similar to the Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 Rhipbitlm sp. LPS mutants and symbiotic behaviour Fig. 4. Longitudinal sections of an effective root nodule of A. cyanophy//a infected with wild-type Rhizobium sp. (Acacia) strain GRH2 examined by light microscopy (a) and transmission electron microscopy (b). Note the numerous infected host cells interspersedwithin the large central zone in (a), and a portion of an infected host cell with numerous symbiosomes containing pleomorphic bacteroids surrounded by peribacteroid membranes in (b). Scale bars: (a) 100 pm; (b) 1 pm. CW, Cell wall; B, bacteroid; PM, peribacteroid membrane. wild-type EPS, but no trace of a galactosyl component was detected. 1H-NMR spectroscopy and compositional analyses indicated that the introduction of plasmid p501 into the GRH2-50 background resulted in restoration of the production of the wild-type EPS. The 'H-NMR spectrum of GRH2-50 (p501) EPS was superimposable with that of the GRH2 EPS for both glycosidic and non-carbohydrate substitutions resonances (Fig. 3). Assuming a stoichiometry of two pyruvyl residues per GRH2 EPS repeat unit (Lopez-Lara e t a/., 1993), the pyruvate/acetate/3hydroxybutyrate ratio was 2-00: 1-62:0.84 for the EPS of the complemented mutant, as compared to 2-00: 1.56 :0.78 in the wild-type EPS. In addition, both the EPS sugar ratios were similar (glucose/glucuronic acid/galactose approximately 5 :2 : l), showing the restoration of the galactose moiety as a component of the EPS of the strain. The structures of GRH2-50 and GRH2-50 (p501) EPS were further examined by GC/MS analysis of the Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 577 I. M. LOPEZ-LARA a n d O T H E R S Fig. 5. Longitudinal sections of an ineffective root nodule of A. cyanophylla induced by Ips mutant GRH2-14, examined by light microscopy (a and b) and transmission electron microscopy (c and d). Scale bars: (a) 100 pm; (b) 20 pm; (c) 10 pm; (d) 5 pm. NP, Nodule parenchyma; CT,central tissue; V, vacuole; GM, electron-dense granular material. glycosidic linkage composition. The analysis of GRH2-50 (p501) EPS showed the predominance of 4-linked glucose, and the occurrence of 4-linked glucuronic acid, 4,6-linked glucose, 4,6-linked galactose and 3,4,6-linked glucose. This pattern of partially methylated alditol acetates was similar to the one obtained from the GRH2 wild-type EPS (Lopez-Lara e t a/., 1993). In the GRH2-50 EPS, 4linked glucose was also predominant ;4-linked glucuronic acid and 4,6-linked glucose were also present but no other derivative was found. This result reinforced the above NMR and GC/MS data indicating that the GRH2-50 57% mutation results in an altered EPS lacking the galactose component, as well as one pyruvyl moiety and 3hydroxybutyryl substitutions, whereas the introduction of the p501 plasmid into the GRH2-50 background restores the production of the wild-type EPS. Symbiotic phenotype of GRH2-14 and GRHZ-50 mutant strains Wild-type strain GRH2 is able to elicit reddish, elongated root nodules within 20 d of inoculation on A . cyanupbylla, Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 Rhizobim sp. LPS mutants and symbiotic behaviour Fig. 6. Longitudinal sections of an ineffective root nodule of A. cyanophylla induced by Ips mutant GRH2-50, examined by light microscopy (a and b) and transmission electron microscopy (c and d). Scale bars: (a) 100 pm; (b) 20 pm; (c) 2 pm; (d) 2 pm. NP, Nodule parenchyma; CT, central tissue; V, vacuole; GM, electron-dense granular material. Acacia melanoxjlon and Prosopis chilensis plants. Inoculation of these tree-legumes with GRH2-14 and GRH2-50 mutant strains resulted in alteration of their root system leading to shorter and thicker roots without the formation of reddish, elongated nodules. Occasionally, inoculated roots of tree legumes developed a few small white nodules after 1 month of incubation with either of these two mutant strains. Reintroduction of the corresponding T n 5 insertions into the wild-type GRH2 also reproduced the altered symbiotic phenotype. Combined light and transmission electron microscopy of median longitudinal sections through 1-month-old A. cyanoph~lla nodules indicated that many host cells in the central tissue were invaded by the wild-type strain GRH2, which developed into pleiomorphic endosymbiotic bacteroids within symbiosomes (Fig. 4a, b). In contrast, Acacia nodules were not invaded by either GRH2-14 or GRH2-50 mutant strains (Figs 5a-c and 6a-c). Other distinguishing mor- Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 I. M. LOPEZ-LARA a n d O T H E R S phological features of median sections through ' empty ' nodules induced by GRH2-14 and GRH2-50 mutant strains were a smaller proportional area of the central tissue (7 % and 15 %, respectively, compared to 59 YOfor nodules induced by wild-type GRH2) and a more expansive nodule parenchyma between the peripheral nodule cortex and the central tissue. Nodule cells in this layer surrounding the central tissue stained intensely with toluidine blue (Figs 4a, 5a and 6a) and contained large vacuoles in which was deposited electron-dense granular material that was not bacteria (Figs 5d and 6d). Neither GRH2-14 nor GRH2-50 mutant strains were able to induce nodules on the herbaceous legumes which are nodulated by the GRH2 wild-type strain, such as Lottls corniculattls, Vicia kirstlta, Triflitlm stlbterraneum, Tr;folium repens and Triflitlm incarnattlm. However, like wild-type GRH2, mutants GRH2-14 and GRH2-50 elicited nodules on Phaseoltls vdgaris. DISCUSSION Broad-host-range. rhizobia are very useful for investigating the molecular mechanisms of symbiotic interactions between bacteria and plants. For this study, we have used wild-type Rhixobitlm sp. strain GRH2, which was isolated from root nodules of A. cyanoplylla and has a broad host range which includes legume trees and herbaceous legumes (Herrera et al., 1985). Here we report the characterization of two mutant strains of GRH2 which are defective in production of smooth LPS. One of them, strain GRH2-50, is an exoB mutant which lacks UDPglucose 4-epimerase activity. A consequence of this mutation is the inability to produce UDPgalactose and thus it is defective in production of glycoconjugates containing galactosyl components. In a previous study (L6pez-Lara e t al., 1993), we found that the acidic EPS of wild-type GRH2 is closely related to the EPS of wild-type R. legtlminosartlm bv. trifalii ANU843 (Hollingsworth e t al., 1988). The simultaneous lack of galactose, one pyruvyl residue, and the 3-hydroxybutyryl substituents in the EPS of the GRH2-50 exoB mutant is best explained by proposing that the EPS of wild-type GRH2, like wildtype ANU843, hai a galactose residue at the terminus of the branch in each oligosaccharide repeat unit which is substituted with one pyruvate residue and is also the site of esterification of 3-hydroxybutyrate substitutions. The inability of the GRH2-50 exoB mutant to produce smooth LPS implies that UDPgalactose is also required for synthesis of this cell surface polysaccharide. Preliminary studies of GRH2 LPS suggest that the sugar composition is different from that of strain ANU843, and that the LPS of mutant GRH2-50 lacks galactose and contains galacturonic acid instead (S. Hollingsworth, personal communication). Attempts to complement the mutant phenotypes exhibited by GRH2-14 d GRH2-50 with a wild-type cosmid bank were only successful with the latter mutant strain. Southern blot hybridization and complementation studies showed that both GRH2-50 and GRH2-14 mutant strains carry a single T n 5 insertion. Reintroduction into 580 the wild-type strain GRH2 of the corresponding T n 5 insertions reproduced the colony morphology, LPS and symbiotic mutant phenotypes. Thus, the lack of complementation of strain GRH2-14 suggests that: (i) the wild-type DNA was not well represented in the genomic bank used, (ii) the mutation could be dominant, or (iii) several copies of the wild-type DNA region could be lethal. Whereas the GRH2-50 mutant locus is well conserved among R. legtlminosartlm strains, GRH2-14 mutant DNA did not show homology in these rhizobial strains nor with pCos4. In addition, sequence analysis of the left junction of the T n 5 insertion 14 did not reveal homologous sequences in the Swissprot and PIR Protein Data Banks. Therefore, the GRH2-14 mutant locus may represent a newly described Ips gene for Acacia rhizobia. In a previous study we reported an EPS mutant derivative of GRH2 (mutant GRH2-57) which was partially defective in nodule invasion in Acacia. It still nodulated this host but exhibited a fivefold reduction in nodule occupancy (Lopez-Lara e t al., 1993). The LPS mutant strains described here (GRH2-14 and GRH2-50) have even more drastic defects in their symbiotic phenotypes on this tree legume host. These mutant strains are only able to induce a few small white nodules in Acacia, and these nodules are devoid of bacteria. Therefore, whereas a mutation which blocks acidic EPS biosynthesis results in a partial loss in ability to fully invade Acacia nodules, a mutation which blocks biosynthesis of smooth LPS completely prevents bacterial invasion of nodule cells on this preferred tree legume host. This demonstrates the critical importance of LPS and acidic EPS in enabling rhizobia to overcome the host cell barriers in order to achieve nodule invasion in the nitrogen-fixing Rhixobitlm-Acacia symbiosis. Nodulation tests with a diversity of legumes have revealed that these polysaccharide mutants of Acacia rhizobia are also altered in host range. In a previous study (Lopez-Lara e t al., 1993), the EPS mutant GRH2-57 lost the ability to nodulate clovers and vetch, but retained the ability to nodulate Phaseoltls and Lottls. Therefore, the importance of EPS in nodulation and host range on herbaceous legume hosts is correlated with the type (determinant or indeterminant) of nodule ontogeny. In contrast, the LPS mutant strains GRH2-14 and GRH2-50 were able to nodulate Phaseoltls but not Lottls. These results suggest that the symbiotic defect exhibited by these two LPS mutants on herbaceous legume hosts was not dependent on the nodule ontogeny. Thus, our results highlight the contributing role(s) of the surface polysaccharides (LPS and acidic EPS) in determining the host range of Acacia rhizobia. ACKNOWLEDGEMENTS This work was supported by Comision Asesora de Investigacion Cientifica y Ticnica grants BI090-0747 and BI093-0677 (to J.O. and N.T.), National Institute of Health Grant no. GM-34331-06 and the Michigan State University Biotechnology Research Center (to F. B. D.). I. L-L. was supported by a M. E. C. fellowship. We thank H. S. Pankratz and J. Palma for technical assistance. Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 Rhipbitlm sp. LPS mutants a n d symbiotic behaviour REFERENCES Abe, M., Sherwood, 1. E., Hollingsworth, R. 1. & Dazzo, F. B. (1984). Stimulation of clover root hair infection by lectin-binding oligosaccharides from the capsular and extracellular polysaccharides of Rhixobium trfolii. J Bacteriol160, 517-520. Beringer, J. E. (1974). R factor transfer in Rhixobium leguminosarum. J Gen Microbiol84, 188-1 98. Canter Cremers, H. C. J., Batley, M., Redmond, J. W., Eydems, L., Breedveld, M. W., Zevenhuizen, L. P. T. M., Pees, E., Wijffelman, C. A. & Lugtenberg, B. J. 1. (1990). Rhixobizlm leguminosarum exoB mutants are deficient in the synthesis of UDP-glucose 4'-epimerase. J Biol Chem 265,21122-21 127. Carlson, R. W. (1982). Nitrogen fixation. Rhixobium. In Surface Chemisty, vol. 2, pp. 199-234. Edited by W. J. Broughton. Oxford : Oxford University Press. Cass6, F., Boucher, C., Julliot, 1. S., Michel, M. & Denari6, J. (1979). Identification and characterization of large plasmids in Rhixobium meliloti using agarose gel electrophoresis. J Bacteriol113, 229-242. Dazzo, F. B. & Petersen, M. (1989). Applications of computerassisted image analysis for microscopic studies of the Rhixobiumlegume symbiosis. Symbiosis 7 , 193-210. Dazzo, F. B., Truchet, G. L., Hollingsworth, R. I., Hrabak, E. M., Pankratz, H. S., Philip-Hollingsworth, S., Salzwedel, J. L., Chapman, K., Appenzeller, L., Squartini, A., Gerhold, D. & Orgambide, G. (1992). Rhixobium lipopolysaccharide modulates infection thread development in white clover root hairs. J Bacterioll73, 5371-5384. Devereux, 1.. Haeberli, P. & Smithies, 0. (1984). A comprehensive set of sequence analysis programs for the VAX. Nucleic Acids Res 12, 387-395. Emerich, D. W., Ruiz-ArgUeso, T., Russell, 5. A. & Evans, H. J. (1980). Investigation of the H, oxidation system in Rhixobium japonicum 122DES nodule bacteroids. Plant Physiol66, 1061-1 066. Fukasawa, T., Obonai, K., Segawa, T. & Nogi, Y. (1980). The enzymes of the galactose cluster in Saccharomyces cerevisiae. J Biof Chem 255, 2705-2707. Garfinkel, D. 1. & Nester, E. W. (1980). Agrobacterium tumefaciens mutants affected in crown gall tumorigenesis and octopine catabolism. J Bacteriol 144, 732-743. Herrera, M. A., Bedmar, E. J. & Olivares, J. (1985). Host specificity of Rhiqobium strains isolated from nitrogen-fixing trees and nitrogenase activities of strain GRH2 in symbiosis with Prosopis chilensis. Plant Science 42, 177-1 82. Hitchcock, P. 1. & Brown, T. M. (1983). Morphological hetero- geneity among Salmonella lipopolysaccharide chemotypes in silverstained polyacrylamide gels. ] Bacteriol154, 269-277. Hollingsworth, R. I., Dazzo, F. B., Hallenga, K. & Musselman, B. (1988). The complete structure of the Trifoliin A lectin-binding capsular polysaccharide of Rhixobium triflii 843. Carbohydr Res 172, 97-1 12. Laemmli, U. K. (1970). Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227, 680-685. Lamb, J. W., Hombrecher, G. &Johnston, A. W. B. (1982). Plasmid- determined nodulation and nitrogen fixation abilities in Rhixobium phaseoli. Mol & Gen Genet 186, 444452. L6pez-Lara, M. I., Orgambide, G., Dazzo, F. B., Olivares, J. & Toro, N. (1993). Characterization and symbiotic importance of acidic extracellular polysaccharides of Rhixobium sp. strain GRH2 isolated from Acacia nodules. J Bacteriol 175, 2826-2832. Maier, R. J. & Brill, W. 1. (1978). Involvement of Rhixobium japonicum 0 antigen in soybean nodulation. J Bacteriol 133, 1295-1299. Maniatis, T., Fritsch, E. F. & Sambrook, 1. (1982). Molecular Cloning: a Laboratoy Manzlal. Cold Spring Harbor, NY : Cold Spring Harbor Laboratory. MUller, P., Hynes, M., Kapp, D., Niehaus, K. & PUhler, A. (1988). Two classes of Rhizobium meliloti infection mutants differ in exopolysaccharide production and in coinoculation properties with nodulation mutants. Mol & Gen Genet 211, 17-26. Noel, K. D., Vandenbosch, K. A. & Kulpaca, B. (1986). Mutations in Rhixobium phaseoli that lead to arrested development of infection threads. J Bacterioll68, 1392-1401. Olivares, J., Casadesus, 1. & Bedmar, E. J. (1980). Methods for testing degree of infectivity of Rhixobium meliloti strains. Appl Environ Microbiol39, 967-970. Pearson, W. R. & Lipman, D. J. (1988). Improved tools for biological sequences comparison. Proc Natl Acad Sci U S A 85, 2444-2448. Priefer, U. B. (1989). Genes involved in lipopolysaccharide production and symbiosis are clustered on the chromosome of Rhixobium leguminosarum biovar viciae VF39. J Bacteriol 171, 6161-6 168. Reuber, T. L., Reed, 1. W., Glazebrook, J., Glucksmann, A. M., Ahman, D., Marra, A. & Walker, G. C. (1991). Rhixobium meliloti exopolysaccharides : genetic analysis and symbiotic importance. Biochem Soc Trans 19, 636-641. Rigaud, J. & Puppo, A. (1975). Indole-3-acetic acid catabolism by soybean bacteroids. J Gen Microbiol88, 223-228. Robertsen, B. K., Aiman, P., Darvill, A. G., McNeil, M. & Albersheim, P. (1981). The structure of acidic extracellular polysaccharides secreted by Rhixobium leguminosarum and Rhixobium trifalii. Plant Physi0l67, 389-340. Sanger, F., Nicklen, 5. 81Coulson, A. R. (1977). DNA sequencing with chain-terminating inhibitors. Proc Natl Acad Sci U S A 74, 5463-5467. Toro, N., Herrera, M. A. & Olivares, J. (1984). Location of nifgenes on large plasmids in Rhixobium strains isolated from legume tree root nodules. F E M S Microbiol Lett 24, 113-1 15. Zhan, Y., Hollingsworth, R. 1. & Priefer, U. (1992). Characterization of structural defects in the lipopolysaccharides of symbiotically impaired Rhixobium leguminosarum bv. viciae VF-39 mutants. Carbobydr Res 231, 261-271. Received 21 June 1994; revised 11 October 1994; accepted 26 October 1994. Downloaded from www.microbiologyresearch.org by IP: 78.47.27.170 On: Fri, 14 Oct 2016 11:48:26 58 1