ライフサイエンスコーパス: S. meliloti

1 S. meliloti also produces sulfated cell surface polysacc

2 S. meliloti ExpR activates transcription of genes involv

3 S. meliloti has three quorum-sensing systems (Sin, Tra,

4 S. meliloti Hfq is involved in controlling the populatio

5 S. meliloti lpsB complements a mutant of R. leguminosaru

6 S. meliloti MsbA2 is required for the invasion of nodule

7 S. meliloti Nod factor is a lipochitooligosaccharide tha

8 S. meliloti nodulation factor treatments of MtROP9i led

9 S. meliloti NRG185 produces oligosaccharides that are al

10 S. meliloti produces Nod factor, which elicits the forma

11 S. meliloti requires exogenous CO(2) for growth and may

12 S. meliloti rpoA encodes a 336-amino-acid, 37-kDa protei

13 S. meliloti strains lacking functional rns1 are able to

14 S. meliloti synthesizes an unusual sulfate-modified form

15 S. meliloti unable to produce the exopolysaccharide succ

16 S. meliloti wild-type strain Rm1021 requires production

17 S. meliloti, a symbiont of leguminous plants, synthesize

18 hia coli BL21 (DE3) engineered to express 11 S. meliloti nod genes.

19 Only 28% of the 462 S. meliloti cell cycle-regulated genes were also transcr

20 In addition, S. meliloti cells constitutively producing Nod factors w

21 ation of NCR247 lowered its activity against S. meliloti.

22 and exhibited antimicrobial activity against S. meliloti.

23 ns influenced the activity of NCR247 against S. meliloti.

24 An S. meliloti relA mutant which cannot produce ppGpp was p

25 In addition, an S. meliloti lpsB mutant that is defective at a stage in

26 We have previously identified an S. meliloti Tn5 insertion mutant, S9, which is specifica

27 We recently identified an S. meliloti two-component sensory histidine kinase, CbrA

28 Our studies of an S. meliloti loss-of-function hfq mutant have revealed th

29 Through detailed analysis of an S. meliloti mutant incapable of producing ppGpp, we show

30 sistent with the functional expression of an S. meliloti phosphoglycerol transferase gene.

31 es (amplified by inverse PCR) as a probe, an S. meliloti genomic library was screened, and two overla

32 haracterizing Ca L. asiaticus regulators, an S. meliloti host can be used for preliminary identificat

33 d to compatibility; most importantly, (v) an S. meliloti Rm41 derivative, carrying exo genes from an

34 nor novel lipid of R. leguminosarum 3841 and S. meliloti.

35 s is a close relative of both B. abortus and S. meliloti, and this bacterium is the causative agent o

36 e demonstrate that the YbeY from E. coli and S. meliloti can reciprocally complement the rRNA process

37 onal activation in both R. leguminosarum and S. meliloti.

38 the genomic and structural levels, PhiM9 and S. meliloti phage PhiM12 have a small number of open rea

39 of structure-related genes in both PhiM9 and S. meliloti-infecting T4 superfamily phage PhiM12, which

40 n when B. japonicum produced the appropriate S. meliloti Nod factor.

41 eobacteria with similar ecological niches as S. meliloti, suggesting that the CtrA cell cycle regulat

42 tions involve ecotype-strain specificity, as S. meliloti Rm41 and NRG247 are Fix+ (compatible) on M.

43 noglycan oligosaccharide populations between S. meliloti strains; (iv) the structural nature of the s

44 n the establishment of the symbiosis between S. meliloti and its host Medicago sativa.

45 Symbiosis between S. meliloti and its plant host alfalfa is dependent on b

46 pment of a nitrogen-fixing symbiosis between S. meliloti and its plant hosts.

47 be crucial for the chronic infection of both S. meliloti and B. abortus.

48 biosynthesis of exopolysaccharides (EPS) by S. meliloti.

49 In addition, MtFNSII-2 was inducible by S. meliloti and methyl jasmonate treatment, whereas MtFN

50 Symbiotic infection by S. meliloti requires an osmosensory two-component system

51 Alfalfa nodule invasion by S. meliloti can be mediated by any one of three symbioti

52 st one of two exopolysaccharides produced by S. meliloti (succinoglycan or EPS II) is required for no

53 forms of certain polysaccharides produced by S. meliloti are crucial for establishing this symbiosis.

54 Interestingly, the EPS II produced by S. meliloti in low-phosphate conditions does not allow t

55 it, whereas the oligosaccharides produced by S. meliloti Rm41 include many nonsuccinylated subunits,

56 biotically active polysaccharide produced by S. meliloti wild-type strain Rm1021 is succinoglycan.

57 the second major EPS known to be produced by S. meliloti, but typically is expressed only under condi

58 rmine which exopolysaccharide is produced by S. meliloti.

59 e for root hair infection of ecotype R108 by S. meliloti nodF nodL mutant producing modified NFs.

60 sport suggests that substrates recognized by S. meliloti DctA must have appropriately spaced carbonyl

61 e nodulation of alfalfa (Medicago sativa) by S. meliloti.

62 invasion process requires the synthesis, by S. meliloti, of at least one of the two symbiotically im

63 l stages during invasion of M. truncatula by S. meliloti.

64 oteobacterial pathogens and might be used by S. meliloti to sense host cues during infection.

65 Within specialized host cells, S. meliloti differentiates into highly polyploid, enlarg

66 f understanding of the physiological changes S. meliloti cells go through during the early stages of

67 ated this by constructing and characterizing S. meliloti mutants in the lpxXL and acpXL genes, which

68 After inoculation with compatible S. meliloti, LYK3:GFP puncta are relatively stable.

69 osely related species are able to complement S. meliloti fcrX function.

70 ting for the inability of lpcC to complement S. meliloti lpsB mutants.

71 custom Affymetrix GeneChip with the complete S. meliloti genome and approximately 10,000 probe sets f

72 wo new avenues for understanding the complex S. meliloti-alfalfa interactions which occur during symb

73 We have constructed S. meliloti mutants that lack HPrK or that lack key amin

74 zobium meliloti or to the invasion defective S. meliloti mutant, exoA.

75 in trans rescue with a Nod factor-deficient S. meliloti mutant.

76 ant to wild-type and succinoglycan-deficient S. meliloti at the early time point of 3 days postinocul

77 tula inoculated with succinoglycan-deficient S. meliloti more strongly express an unexpectedly large

78 We show that, when starved, dividing S. meliloti bet hedge by forming two daughter cells with

79 t intracellular regulatory pathways to drive S. meliloti endoreduplication and differentiation during

80 zed by R. leguminosarum bv viciae expressing S. meliloti nod genes, but the plants were yellow and se

81 ithout the small 83 amino acid protein FeuN, S. meliloti cells are unable to grow, and this phenotype

82 mutants in a genetic screen designed to find S. meliloti mutants that had abnormal succinate-mediated

83 d lipid A is important, but not crucial, for S. meliloti chronic infection and that BacA must have an

84 ght microscopy after staining with X-Gal for S. meliloti expressing a constitutive GUS gene, by confo

85 the SMc01113 gene is absolutely required for S. meliloti symbiosis with alfalfa and also for the prot

86 ich we refer to here as the mel system, for "S. meliloti."

87 ExoR(c20) was isolated directly from S. meliloti periplasm to identify its N-terminal amino a

88 ion and characterization of a ctrA gene from S. meliloti.

89 vitro, we reconstituted RNAP holoenzyme from S. meliloti alpha and E. coli beta, beta', and sigma sub

90 inguishable from those of NodD isolated from S. meliloti.

91 ts capable of distinguishing S. medicae from S. meliloti.

92 AcpXL purified from S. meliloti expressing pSSB-1 is fully acylated, mainly

93 ned similar results using purified RNAP from S. meliloti.

94 nce responses, and other functions that give S. meliloti an advantage in its specialized niche.

95 important implications for understanding how S. meliloti polysaccharides are functioning in the plant

96 In S. meliloti, exoR and the exoS-chvI two-component system

97 In S. meliloti, ExoS/ChvI is a key regulator of gene expres

98 ribute to the release of free fatty acids in S. meliloti, neither one can use phospholipids as substr

99 encodes an LPS sulfotransferase activity in S. meliloti.

100 -mediated regulation of stress adaptation in S. meliloti.

101 opriate GalA donor substrate is available in S. meliloti membranes.

102 cycle-dependent regulons of CtrA and DnaA in S. meliloti and C. crescentus.

103 they do not stimulate nod gene expression in S. meliloti, the flavonoids naringenin, eriodictyol, and

104 t LPS might not have a symbiotic function in S. meliloti.

105 duction of RF for intracellular functions in S. meliloti.

106 ctrA is also an essential gene in S. meliloti, and it is expressed similarly to the autore

107 oxes from other phosphate-regulated genes in S. meliloti and to the consensus PHO box in Escherichia

108 for the regulation of core glycosylation in S. meliloti and other bacteria containing LpcC orthologs

109 However, in S. meliloti, free-living cells of the cpdR1-null mutant

110 Deletion of hprK in S. meliloti enhanced catabolite repression caused by suc

111 tional LPS sulfotransferase activity(ies) in S. meliloti that can compensate for the loss of LpsS.

112 enzymology and genetics of PHB metabolism in S. meliloti have been well characterized, phasins have n

113 ich quorum sensing downregulates motility in S. meliloti.

114 ng of the mechanisms that govern motility in S. meliloti.

115 rmined the nature of the expR101 mutation in S. meliloti.

116 s of R. leguminosarum and R. etli but not in S. meliloti or Escherichia coli.

117 ent open reading frames, podJ1 and podJ2, in S. meliloti.

118 e of three quorum sensing systems present in S. meliloti, controls the production of the symbioticall

119 hat has not been characterized previously in S. meliloti.

120 FixJ binds to the nifA and fixK promoters in S. meliloti and induces expression of the corresponding

121 propose that frequency-modulated pulsing in S. meliloti represents the molecular mechanism for a col

122 e involved in more than carbon regulation in S. meliloti and suggest that the phenotypes observed occ

123 ps, including Brucella; however, its role in S. meliloti has not been investigated.

124 lain the requirements for RpoH1 and RpoH2 in S. meliloti and that there must be other crucial targets

125 another possible quorum sensing system(s) in S. meliloti.

126 iple glycosyl transferase activities seen in S. meliloti 2011 membranes.

127 w that the ExpR/Sin quorum-sensing system in S. meliloti is involved in the regulation of genes respo

128 Our data indicate that in S. meliloti, and possibly in other Rhizobiaceae species,

129 o facilitate our studies of transcription in S. meliloti, we cloned and characterized the gene for th

130 ays an important role in manganese uptake in S. meliloti.

131 erated selection procedure, four independent S. meliloti dctA mutants were isolated that retained som

132 The inferred S. meliloti RpoH promoter consensus sequences share feat

133 Transfer of pMJK-1 into S. meliloti 1021 results in heterologous expression of 1

134 entified in this manner and transferred into S. meliloti, in which they also directed the expression

135 Using green fluorescent protein-labeled S. meliloti cells, we have shown that there are signific

136 eliloti engages in a symbiosis with legumes: S. meliloti elicits the formation of plant root nodules

137 m the recently characterized cyanophage-like S. meliloti phages of the PhiM12 group.

138 and lsrB genes are expressed in free-living S. meliloti cells, but they are not required for cell gr

139 Expression profiling of free-living S. meliloti grown with the plant signal molecule luteoli

140 Analysis of free-living S. meliloti strains with mutations in genes related to n

141 s in LPS structure can affect the ability of S. meliloti to form an effective symbiosis.

142 to play an important role in the ability of S. meliloti to successfully invade its host, also helps

143 NodD, we assayed the DNA binding activity of S. meliloti NodD1 treated with the flavonoid inducer lut

144 cell growth that enabled global analysis of S. meliloti cell cycle-regulated gene expression.

145 germinating seeds, we assayed chemotaxis of S. meliloti towards betonicine, choline, glycine betaine

146 Coexpression of S. meliloti aqpS and arsC in a strain of E. coli lacking

147 of two cpdR homologues, cpdR1 and cpdR2, of S. meliloti that encode single-domain response regulator

148 Derivatives of S. meliloti strain Rm1021 carrying an lpsB mutation are

149 To study the coordinate differentiation of S. meliloti and its legume partner during nodule develop

150 Our discovery of S. meliloti chemotaxis to plant-derived QACs adds anothe

151 lay a greater role in the overall fitness of S. meliloti both during the free-living stage and in its

152 ct on the lipid A in the free-living form of S. meliloti, is essential for the chronic infection.

153 sure liquid chromatographic fractionation of S. meliloti culture filtrate extracts revealed at least

154 entify peptidase genes in the core genome of S. meliloti that modulate symbiotic outcome in a manner

155 Searching the genome of S. meliloti, we identified a potential lysophospholipase

156 ystem (PTS) have been found in the genome of S. meliloti.

157 Growth of S. meliloti is modelled in three ecological niches (bulk

158 ay an important role in supporting growth of S. meliloti near germinating seeds of alfalfa.

159 h 7, 4'-dihydroxyflavone, a major inducer of S. meliloti nod genes, completely restored nodulation.

160 ever, luteolin, the plant-derived inducer of S. meliloti's nod genes, is not required for mature biof

161 ave previously shown that the sinRI locus of S. meliloti encodes a quorum-sensing system that plays a

162 This novel locus of S. meliloti is designated the cgm (cyclic glucan modific

163 Mapping of S. meliloti mutations conferring resistance to PhiM12, N

164 The lipid A molecules of S. meliloti and B. abortus are unusually modified with a

165 system also seems to regulate a multitude of S. meliloti genes, including genes that participate in l

166 A SMc01003-deficient mutant of S. meliloti transiently accumulates diacylglycerol, sugg

167 er classes of K-antigen-defective mutants of S. meliloti AK631 exhibit unique patterns of sensitiviti

168 ysaccharides is unclear, although mutants of S. meliloti with reduced LPS sulfation exhibit symbiotic

169 homology (39% amino acid identity) to Pcs of S. meliloti.

170 that ExoR binds to ExoS in the periplasm of S. meliloti to inhibit ExoS/ChvI activity, and that ExoR

171 and ChvI, and localizes to the periplasm of S. meliloti.

172 nodulation or nitrogen fixation phenotype of S. meliloti.

173 tudied the symbiotic infection phenotypes of S. meliloti mutants deficient in succinoglycan productio

174 fact, enhances the symbiotic productivity of S. meliloti 1021 with the host plant Medicago truncatula

175 f K antigen and the symbiotic proficiency of S. meliloti AK631.

176 is of the whole-genome expression profile of S. meliloti reveals that the ExpR/Sin quorum-sensing sys

177 document complex transcriptional profiles of S. meliloti in different environments.

178 s system in which to study the regulation of S. meliloti genes could provide an important tool for ou

179 erize the global transcriptional response of S. meliloti rpoH1, rpoH2, and rpoH1 rpoH2 mutants during

180 genomic library and discovered a segment of S. meliloti DNA which allows Ralstonia eutropha to grow

181 We utilized the genomic sequence of S. meliloti to identify an open reading frame, SMc04267

182 n the bacteria expressed the complete set of S. meliloti nod genes.

183 ith both free-living and symbiotic states of S. meliloti.

184 different species of rhizobia in a strain of S. meliloti lacking endogenous NodD activity.

185 This phylogenetic and structural study of S. meliloti-infecting T4 superfamily phage PhiM9 provide

186 n total lipids from R. leguminosarum 3841 or S. meliloti 1021 were added.

187 In planktonic S. meliloti, MucR properly coordinates a diverse set of

188 On wild-type plants, S. meliloti strains producing no succinoglycan or only u

189 The predicted S. meliloti cell cycle regulon of CtrA, but not that of

190 acterial BacA protein is critical to prevent S. meliloti from being hypersensitive toward NCR AMPs.

191 leguminosarum bv viciae strain that produced S. meliloti Nod factor.

192 ated with wild-type, succinoglycan-producing S. meliloti more strongly express genes encoding transla

193 determined that BacA specifically protected S. meliloti against oxidized NCR247.

194 tand the role of aqpS in arsenic resistance, S. meliloti aqpS and arsC were disrupted individually.

195 ound that protein exudation in the M. sativa-S. meliloti interaction caused an increase in the secret

196 pproximately 50% of the nearly 250 sequenced S. meliloti strains but not found in over 60 sequenced s

197 rs were identified in the recently sequenced S. meliloti genome.

198 t and the physiology of the free-living soil S. meliloti before and during the establishment of nodul

199 Therefore, like E. coli and other species, S. meliloti requires only one groEL gene for viability,

200 3841 genomic DNA library in the host strain S. meliloti 1021.

201 itionally, during early stages of symbiosis, S. meliloti is presented with an oxidative burst that mu

202 In this symbiosis, S. meliloti undergoes a drastic cellular change leading

203 We leveraged synchronized S. meliloti populations to determine how treatment with

204 Our results demonstrate that S. meliloti alpha functions are conserved in heterologou

205 mutation in E. coli rpoA, demonstrating that S. meliloti alpha supports RNAP assembly, sequence-speci

206 It was previously reported that S. meliloti cell surface polysaccharides are also covale

207 We show that S. meliloti CpdR1 has a polar localization pattern and a

208 Previous studies had shown that S. meliloti 1021 mutants that produce increased levels o

209 the properties of agl mutants suggests that S. meliloti possesses at least one additional alpha-gluc

210 The S. meliloti bluB mutant is unable to grow in minimal med

211 The S. meliloti cpdR1-null mutant can invade the host cytopl

212 The S. meliloti genome encodes 14 of these alternative sigma

213 The S. meliloti gltA gene was mutated by inserting a kanamyc

214 The S. meliloti iolA (mmsA) gene product seems to be involve

215 The S. meliloti ML beta-glucan participates in bacterial agg

216 Since both the S. meliloti and B. abortus bacA mutants have an increase

217 As in C. crescentus, the S. meliloti PodJ1 protein appears to act as a polarity b

218 ffect on transcriptional activation from the S. meliloti dctA promoter in vitro.

219 e-16S rRNA precursor that accumulates in the S. meliloti DeltaybeY strain.

220 suggest that events demonstrated here in the S. meliloti-alfalfa association may be widely important

221 suggest that AqpS is the only protein of the S. meliloti ars operon that facilitates transport of ars

222 tic approach, we identified a homolog of the S. meliloti carbohydrate sulfotransferase, LpsS, in Meso

223 mechanisms governing the alterations of the S. meliloti cell cycle in planta are largely unknown.

224 molecule also inhibits the expression of the S. meliloti exp genes, responsible for the production of

225 due entirely to LpsB, since membranes of the S. meliloti lpsB mutant 6963 do not glycosylate Kdo(2)-[

226 d mass spectrometry, and the analysis of the S. meliloti NRG247 oligosaccharides showed that this str

227 To achieve polyploidy, the S. meliloti cell cycle program must be altered to uncoup

228 iporter], and arsC (arsenate reductase), the S. meliloti ars operon includes an aquaglyceroporin (aqp

229 However, our finding that the S. meliloti bacA mutant also has an increased sensitivit

230 We show that the S. meliloti CtrA belongs to the CtrA-like family of resp

231 The results of this study suggest that the S. meliloti Lon protease is important for controlling tu

232 These results indicate that the S. meliloti stringent response has roles in both succino

233 ur studies indicate that, in contrast to the S. meliloti-Medicago model symbiosis, bacteroids in the

234 These S. meliloti mutants induced a more severe infection phen

235 Any one of three S. meliloti polysaccharides, succinoglycan, EPS II, or K

236 Moreover, adding Nod Factor antibody to S. meliloti cells inhibits biofilm formation, while chit

237 Contrary to S. meliloti, S. fredii HH103 showed little or no sensiti

238 This pathway is likely not limited to S. meliloti as suggested by the presence of homologous g

239 lates this type of specificity pertaining to S. meliloti strain Rm41.

240 In pathogenic bacteria closely related to S. meliloti, exoS-chvI homologues are required for virul

241 hibits a reduced transcriptional response to S. meliloti, indicating that the machinery responsible f

242 nsp2) showed no transcriptional response to S. meliloti, suggesting that the encoded proteins are re

243 bination with the use of flavone pre-treated S. meliloti cells, completely restored nodulation in fla

244 This report shows that M. truncatula-S. meliloti interactions involve ecotype-strain specific

245 of N-acyl homoserine lactones (AHLs) in two S. meliloti strains, Rm1021 and Rm41.

246 rimeric oligosaccharides (STOs) from the two S. meliloti strains were compared by chromatography and

247 nitrogen stress response (NSR) of wild type S. meliloti Rm1021, and isogenic strains missing both PI

248 Membranes of the wild-type S. meliloti strain 2011 catalyze the glycosylation of Kd

249 oserine lactones (AHLs) by two commonly used S. meliloti strains, AK631 and Rm1021.

250 for their microscopic nodule phenotype using S. meliloti constitutively expressing lacZ.

251 In vivo, S. meliloti rpoA expressed in Escherichia coli complemen

252 we discovered that in the absence of VLCFAs, S. meliloti produces novel pentaacylated lipid A species

253 gene sma0113 as needed for strong SMCR when S. meliloti was grown in succinate plus lactose, maltose

254 These results imply that, when S. meliloti is exposed to environmental arsenate, arsena

255 s of flavins destined for secretion, whereas S. meliloti has another enzyme that performs this functi

256 -fold more in this interaction compared with S. meliloti alone.

257 ntly reduced nodulation when inoculated with S. meliloti.

258 ecreted in the incompatible interaction with S. meliloti.

259 aled only R108 forms functional nodules with S. meliloti nodF nodL, and we pinpointed three residues

260 la A17, the Fix phenotypes are reversed with S. meliloti NRG185 and NRG34, and there is a correlation

261 tula A17, and the phenotype is reversed with S. meliloti NRG185.