ライフサイエンスコーパス: R. sphaeroides

1 R. sphaeroides CheAs exhibit two interesting differences

2 R. sphaeroides CheYs did not affect E. coli lacking CheY

3 R. sphaeroides DMSOR expressed in a mobA(-) Escherichia

4 R. sphaeroides has a single, plain filament whose confor

5 R. sphaeroides moves in a series of runs and stops produ

6 R. sphaeroides mutants which lacked either cyt c2 or cyt

7 R. sphaeroides possesses a phosphorelay cascade compatib

8 R. sphaeroides sigma37 controls genes that function duri

9 In a R. sphaeroides mutant lacking RsAgo, expression of plasm

10 Additionally, R. sphaeroides CbbR was shown to bind to the region betw

11 re as E. coli CheA and can phosphorylate all R. sphaeroides chemotaxis response regulators.

12 An R. sphaeroides transposon mutant in this gene, bchP, pos

13 us reg locus was capable of complementing an R. sphaeroides regA-deficient mutant to phototrophic gro

14 For example, an R. sphaeroides deltaRpoH mutant is not generally defecti

15 and RoxR enabled photosynthetic growth of an R. sphaeroides PrrA mutant.

16 nction during environmental stress, since an R. sphaeroides deltaRpoH mutant is approximately 30-fold

17 In heterologous complementation analysis, R. sphaeroides PrrA rescued the growth defect of a P. ae

18 d small subunit genes from R. capsulatus and R. sphaeroides, also supported the unrelatedness of thes

19 avior as wild-type oxidase with horse Cc and R. sphaeroides Cc(2), showing that these residues are no

20 onstructed and expressed in both E. coli and R. sphaeroides.

21 However, their reactions with horse and R. sphaeroides Cc are different, as expected from the di

22 Both lipid IVA and R. sphaeroides lipid A inhibited the effects of LPS and

23 be present in the nondenitrifying bacterium R. sphaeroides 2.4.1.

24 larity and evolutionary relationship between R. sphaeroides and mitochondria, our data suggest that t

25 B (prrB) gene, previously isolated from both R. sphaeroides and Rhodobacter capsulatus and shown to r

26 inactive, trapped P(+)Q(B)(-) state in both R. sphaeroides and B. viridis RCs that does not recombin

27 was cloned, sequenced, and expressed in both R. sphaeroides and Escherichia coli.

28 ute for the assimilation of this molecule by R. sphaeroides.

29 AdoCbl produced by R. sphaeroides was identified and quantified by high-per

30 roidenone, are differentially synthesized by R. sphaeroides, depending on the growth conditions.

31 gene expression are the major means used by R. sphaeroides in adaptation to diverse conditions.

32 of the cbbXYZ gene products, we constructed R. sphaeroides strains in which the genes were inactivat

33 om an overexpressing variant of denitrifying R. sphaeroides 2.4.3 was investigated by proton, nitroge

34 er with increased activity when using either R. sphaeroides RNA polymerase or Escherichia coli Esigma

35 To evaluate R. sphaeroides transcriptome flexibility, expression pro

36 .3 x 10(4) s-1 and k-1 = 1.7 x 10(4) s-1 for R. sphaeroides cytochrome oxidase in the resting state.

37 species but, unlike these, is essential for R. sphaeroides chemotaxis to all compounds tested.

38 ructure was modeled using the structures for R. sphaeroides dimethyl sulfoxide reductase, Rhodobacter

39 AcuI from R. sphaeroides catalyzes the NADPH-dependent acrylyl-CoA

40 second operon (groESL2) was also cloned from R. sphaeroides, using a groEL1 gene fragment as a probe;

41 Cytochrome c oxidase (COX) from R. sphaeroides contains one Ca(2+) ion per enzyme that i

42 this conserved glutamate in the oxidase from R. sphaeroides (E101(II)I,A,C,Q,D,N,H) and residues in t

43 3 in subunit II of cytochrome c oxidase from R. sphaeroides) is not involved in the dominant tunnelin

44 ted mutagenesis using the cbb3 oxidases from R. sphaeroides and Vibrio cholerae.

45 ion of a 24-kDa IF3-like protein (PifC) from R. sphaeroides, we used nested PCR to clone and characte

46 ide bioinformatic analysis of promoters from R. sphaeroides and two other alpha-proteobacterial speci

47 its/nmol molybdenum for enzyme purified from R. sphaeroides.

48 e by crotonyl-CoA carboxylase/reductase from R. sphaeroides was attributed to the fact that the enzym

49 Transcription from R. sphaeroides rRNA promoters was unexpectedly weak, cor

50 However, R. sphaeroides cyt cy, unlike that of R. capsulatus, is

51 To test this hypothesis, R. sphaeroides mutants expressing His6-tagged bc1 comple

52 d in the vicinity of the recently identified R. sphaeroides 2.4.1 homolog of the anaerobic regulatory

53 In R. sphaeroides, synthesis of a novel homoserine lactone

54 lographic structures (His-217 and Asp-252 in R. sphaeroides).

55 The conserved tyrosine residue (Tyr-288 in R. sphaeroides, Tyr-244 in the bovine enzyme) that is ad

56 hese results suggest a model where Cyt c' in R. sphaeroides 2.4.3 may shuttle NO to the membrane, whe

57 Inactivation of cerI in R. sphaeroides results in mucoid colony formation on aga

58 own that the expression of chemoreceptors in R. sphaeroides varies with growth conditions.

59 f proteins required for normal chemotaxis in R. sphaeroides is all the proteins encoded by cheOp2 and

60 A homologues are essential for chemotaxis in R. sphaeroides under laboratory conditions.

61 , and CheA(4) is essential for chemotaxis in R. sphaeroides.

62 catalytic mechanism of the bc(1) complex in R. sphaeroides.

63 S, which are utilized for denitrification in R. sphaeroides 2.4.3.

64 nt transcription termination is essential in R. sphaeroides.

65 rried on multicopy plasmids was expressed in R. sphaeroides under the direction of its own promoter,

66 Because ppsR gene expression in R. sphaeroides 2.4.1 appears to be largely independent o

67 n change the specific activity of GSH-FDH in R. sphaeroides extracts.

68 s of the primary pathway for CO2 fixation in R. sphaeroides, regB was also found to be required for t

69 ep in enabling one to model electron flow in R. sphaeroides 2.4.1.

70 ple chemosensory protein homologues found in R. sphaeroides are not redundant.

71 the molybdenum as compared to that found in R. sphaeroides DMSO reductase demonstrated the presence

72 rificans promoters were shown to function in R. sphaeroides, resulting in high levels of cbbL cbbS an

73 ded by two differentially regulated genes in R. sphaeroides 2.4.1: hemA and hemT.

74 acement of the wild-type chemotaxis genes in R. sphaeroides with their corresponding fluorescent prot

75 li Tsr, MCP-like proteins were identified in R. sphaeroides WS8N.

76 onfirming its role and function as an IF3 in R. sphaeroides.

77 ters were consistent with prior knowledge in R. sphaeroides and/or other bacteria.

78 odel in which the multiple different MCPs in R. sphaeroides are contained within a polar chemorecepto

79 the regulation of tetrapyrrole metabolism in R. sphaeroides.

80 Each of the mutants in R. sphaeroides, with an exception at only one position,

81 nerally correlated with the data obtained in R. sphaeroides and support the computer predictions.

82 een the first two genes of the cco operon in R. sphaeroides 2.4.1, which encodes a cytochrome c termi

83 203 identified a second chemotaxis operon in R. sphaeroides that contains homologues of cheY, cheA an

84 l physical interactors of Mic60 and Orf52 in R. sphaeroides.

85 r and multiple sensory signaling pathways in R. sphaeroides generate the same swimming response as se

86 bacteriochlorophyll biosynthetic pathways in R. sphaeroides in response to the availability of molecu

87 he existence of two chemosensory pathways in R. sphaeroides, a feature that so far is unique in bacte

88 Overexpression of full-length PcrZ in R. sphaeroides affects expression of a small subset of g

89 II) produced a chemotaxis minus phenotype in R. sphaeroides, suggesting that cheA(II) forms part of a

90 the assembly of a functional photosystem in R. sphaeroides, a model organism for the study of struct

91 biosynthesis of all tetrapyrroles present in R. sphaeroides 2.4.1.

92 olve the interacting redox chains present in R. sphaeroides under diverse growth conditions, and many

93 r either of the cyt c oxidases is present in R. sphaeroides.

94 Additionally, the FnrL protein in R. sphaeroides is required for anaerobic growth in the d

95 may act as a signal-transduction protein in R. sphaeroides, it may have an unusual role in controlli

96 multiple copies of chemosensory proteins in R. sphaeroides.

97 pression of genes encoding DMSO reductase in R. sphaeroides and identify the DorS-DorR proteins as a

98 We observed a strong reduction in R. sphaeroides CarD levels when cells enter stationary p

99 m with a central role in redox regulation in R. sphaeroides.

100 blished for hemA transcription regulation in R. sphaeroides.

101 stribution of members of the NnrR regulon in R. sphaeroides revealed patterns of coselection of struc

102 f these findings for cobamide remodelling in R. sphaeroides and in other CbiZ-containing microorganis

103 The lethality of rho' in R. sphaeroides together with our inability to obtain a n

104 ting that CcmG has another important role in R. sphaeroides.

105 promoters that respond to (1)O(2) stress in R. sphaeroides.

106 nd biochemical evidence we conclude that, in R. sphaeroides, the activity of the cobyric acid-produci

107 Therefore, in R. sphaeroides, the global PrrBA system regulates photos

108 Rhodobacter sphaeroides and introduced into R. sphaeroides by using a broad-host-range vector.

109 stance to nitrite when it was mobilized into R. sphaeroides strain 2.4.1 containing nirK.

110 The polymorphic ability of isolated R. sphaeroides filaments was tested in vitro by varying

111 rD increased the activity of 15 of 16 native R. sphaeroides promoters tested in vitro that lacked -7T

112 moters were experimentally validated to nine R. sphaeroides sigma(E)-dependent promoters that control

113 Nonetheless, R. sphaeroides cyt cy can act at least in R. capsulatus

114 ional strains (ATCC 17019 and ATCC 17025) of R. sphaeroides have been sequenced.

115 trol mechanism involved in the adaptation of R. sphaeroides to changes in light intensity and oxygen

116 Finally, we found that the same aspects of R. sphaeroides ChrR needed for a response to (1)O(2) are

117 t parameter selection produces assemblies of R. sphaeroides comparable to or exceeding the quality of

118 e tethered photosynthetically grown cells of R. sphaeroides by their flagella and measured the respon

119 an ancient partnership between CI and CII of R. sphaeroides 2.4.1.

120 Aside from the size variation of CII of R. sphaeroides, variation in sequence lengths of the CII

121 m) are localized in separate compartments of R. sphaeroides.

122 rations of spermidine in growing cultures of R. sphaeroides gave rise to a twofold increase in the ex

123 oli delta cheW mutants, in-frame deletion of R. sphaeroides cheW did not affect either swimming behav

124 Expression of R. sphaeroides cheW in an E. coli delta cheW chemotaxis

125 Expression of R. sphaeroides cheW in Escherichia coli showed concentra

126 opionyl-CoA was detected in cell extracts of R. sphaeroides grown with 3-hydroxypropionate, and both

127 er region were detected in crude extracts of R. sphaeroides.

128 transcription of the cbb(I) operon genes of R. sphaeroides.

129 The genome of R. sphaeroides 2.4.1 has been completely sequenced and f

130 ne for Surf1p was deleted from the genome of R. sphaeroides.

131 constitutive level throughout the growth of R. sphaeroides 2.4.3.

132 ion is critical for photosynthetic growth of R. sphaeroides.

133 nome restriction maps (EcoRI and HindIII) of R. sphaeroides strain 2.4.1 were constructed using shotg

134 at the aspartic residue D442 (a homologue of R. sphaeroides D485) may be the second Na(+) binding sit

135 phoresis, isolated recombinant subunit IV of R. sphaeroides cytochrome b-c1 complex.

136 pothesis that the photosynthetic membrane of R. sphaeroides 2.4.1 contains a significant number of he

137 diffusion of quinones in native membranes of R. sphaeroides are discussed.

138 ctly, the levels of TspO in the membranes of R. sphaeroides.

139 1914 or yhdH into a DeltaacuI::kan mutant of R. sphaeroides on a plasmid complemented 3-hydroxypropio

140 aging of membranes prepared from a mutant of R. sphaeroides, DPF2G, that synthesizes only the LH2 com

141 Mutants of R. sphaeroides deficient in the biosynthesis of the beta

142 tudy, however, we found that PrrA mutants of R. sphaeroides were capable of chemoautotrophic growth,

143 gths of sequence 5' to the cbb(II) operon of R. sphaeroides CAC.

144 In contrast, overexpression of R. sphaeroides cheW in wild-type R. sphaeroides inhibite

145 enzymes of coproporphyrinogen III oxidase of R. sphaeroides, provided in trans to the wild type strai

146 e respiratory electron transport pathways of R. sphaeroides are more complex than those of R. capsula

147 light of our knowledge of the physiology of R. sphaeroides under aerobic and photosynthetic growth c

148 Three mutants at the Asp407 position of R. sphaeroides cytochrome oxidase, Asp407Ala, Asp407Asn,

149 The properties of R. sphaeroides cells containing translational fusions be

150 of photosystem biosynthesis, regB (prrB) of R. sphaeroides is intimately involved in the positive re

151 Rhodobacter capsulatus, a close relative of R. sphaeroides.

152 In characterizing the response of R. sphaeroides to heat, we found that its growth tempera

153 we present the annotated genome sequence of R. sphaeroides WS8N.

154 hromosome II (CII)-specific DNA sequences of R. sphaeroides have rapidly evolved, while CI-specific D

155 A series of R. sphaeroides mutants with replacements of the E54, Q61

156 ation of the copper binding stoichiometry of R. sphaeroides Cox11 led to the finding that an apparent

157 ural genes of the cbb regulon in a strain of R. sphaeroides capable of aerobic CO2-dependent growth i

158 iosynthetic pathway) resulted in a strain of R. sphaeroides that would not grow on acetate in the abs

159 2.4.3 is the only strain of R. sphaeroides with norEF, even though all four of the s

160 e occurrence of norEF in the 2.4.3 strain of R. sphaeroides, which can reduce nitrate to nitrous oxid

161 used to examine approximately 25 strains of R. sphaeroides in an effort to assess the occurrence of

162 ir high sequence divergence among strains of R. sphaeroides suggest the involvement of CII in the evo

163 omosomal sequences from the three strains of R. sphaeroides were aligned, using Mauve, to examine the

164 ary relationships among different strains of R. sphaeroides.

165 s accumulated by resting cell suspensions of R. sphaeroides, we demonstrated that TspO negatively reg

166 The termini of R. sphaeroides flagellin are predicted to have a lower p

167 s study illustrates the potential utility of R. sphaeroides and the coxII promoter for heterologous e

168 A truncated version of R. sphaeroides Rho (Rho') is toxic to a bacterium relate

169 verexpression of PgsARs in either E. coli or R. sphaeroides did not have dramatic effects on the phos

170 n all high-resolution structures of oxidized R. sphaeroides cytochrome c oxidase, a water molecule is

171 nd MreB in aerobic and in photoheterotrophic R. sphaeroides cells using fluorescence microscopy.

172 rRNA promoters were activated by purified R. sphaeroides CarD, a transcription factor found in man

173 in vitro transcription assays with purified R. sphaeroides core RNA polymerase and sigma(E), we show

174 In common with other ALASs the recombinant R. sphaeroides HemA requires pyridoxal 5'-phosphate (PLP

175 Since R. sphaeroides harbors both a cbb3-Cox and an aa3-type c

176 G are sufficient for TTQ biosynthesis, since R. sphaeroides cannot synthesize TTQ.

177 bility of each sigma factor to recognize six R. sphaeroides promoters (cycA P1, groESL(1), rpoD P(HS)

178 While some R. sphaeroides proteins restore tumbling to smooth-swimm

179 fraction of another representative species, R. sphaeroides, but it was completely unaffected by anti

180 the three classes of tRFs for eight species: R. sphaeroides, S. pombe, D. melanogaster, C. elegans, X

181 In contrast to wild-type strains, R. sphaeroides and R. capsulatus fnrL mutants do not syn

182 Free-swimming R. sphaeroides was examined by both differential interfe

183 Using this assay, we demonstrate that R. sphaeroides can utilize 3-hydroxypropionate as the so

184 Our results demonstrate that R. sphaeroides exhibits persistence over the course of a

185 o acid sequence comparisons demonstrate that R. sphaeroides RpoH(II) belongs to a phylogenetically di

186 Despite this, and the fact that R. sphaeroides is widely used for the study of structure

187 DNase I footprint analyses indicated that R. sphaeroides CbbR binds to the cbb(I) promoter between

188 intrinsic promoter activity, indicating that R. sphaeroides RNAP can utilize -7T when present.

189 Here we report that R. sphaeroides strain 2.4.1 synthesizes AdoCbl de novo a

190 ree-dimensional swimming pattern showed that R. sphaeroides changed speed while swimming, sometimes d

191 y NMR spectroscopy cumulatively suggest that R. sphaeroides GSH-FDH can play a critical role in forma

192 The R. sphaeroides groESL1 operon contains a putative hairpi

193 The range of transitions made by the R. sphaeroides filament differs from that reported for S

194 When expressed in Escherichia coli, the R. sphaeroides rho gene relieves Rho-dependent polarity

195 Most of the DNA sequence duplications in the R. sphaeroides genome occurred early in species history,

196 over the history of gene duplications in the R. sphaeroides genome, 44 gene duplications were sampled

197 vels of cbbL cbbS and cbbM expression in the R. sphaeroides host.

198 me a to oxyferryl heme a3 is the same in the R. sphaeroides K362M CcO mutant as in wild-type CcO, ind

199 y inactive enzyme in the set examined in the R. sphaeroides oxidase are in R52, a residue that, along

200 ons N338T and N338A were introduced into the R. sphaeroides protein by site-directed mutagenesis to d

201 ications occurred prior to the origin of the R. sphaeroides 2.4.1 lineage.

202 The sequence of the R. sphaeroides fliC gene, which encodes the flagellin pr

203 sion levels of one-fifth to one-third of the R. sphaeroides ORFs were significantly different in cell

204 trating that the alpha and beta forms of the R. sphaeroides oxidase exist at room temperature; theref

205 The N139D mutant of the R. sphaeroides oxidase was further characterized by exam

206 eaction was studied using two mutants of the R. sphaeroides oxidase, K362M and D132N, that block, res

207 produced by integral membrane enzymes of the R. sphaeroides photosynthetic apparatus.

208 Knowledge of the R. sphaeroides response to (1)O(2) and its regulator sig

209 To relate the context of the R. sphaeroides trp genes to those of other bacteria, the

210 under the direction of its own promoter, the R. sphaeroides rrnB promoter, and the E. coli lac promot

211 styrene-maleic acid copolymer to purify the R. sphaeroides cytochrome bc(1) complex in native lipid

212 The genetic region surrounding the R. sphaeroides rho gene has been determined and found to

213 We present data demonstrating that the R. sphaeroides genome possesses an extensive amount of e

214 on by using translational lac fusions to the R. sphaeroides cbb(I) and cbb(II) promoters.

215 ata from the literature, thus validating the R. sphaeroides genechip as a powerful and reliable tool

216 Whereas the R. sphaeroides signal sequence prevents formation of act

217 ects were similar to those observed with the R. sphaeroides CytcO.

218 1(DE3) cells in its mature form and with the R. sphaeroides or E. coli N-terminal signal sequence.

219 , we found a fourth cheY and expressed these R. sphaeroides proteins in E. coli.

220 rimental validation of predictions from this R. sphaeroides TRN model showed that high precision and

221 ide (DMSO) or trimethylamine N-oxide (TMAO), R. sphaeroides 2.4.1T utilizes DMSO or TMAO as the termi

222 , Paracoccus denitrificans, and is lethal to R. sphaeroides.

223 ho (Rho') is toxic to a bacterium related to R. sphaeroides, Paracoccus denitrificans, and is lethal

224 logue, found in a species closely related to R. sphaeroides, than to its duplicate, counterpart allel

225 th increased information content relative to R. sphaeroides TRN models built via other approaches.

226 e chromatin immunoprecipitation technique to R. sphaeroides.

227 pression of R. sphaeroides cheW in wild-type R. sphaeroides inhibited motility completely, the equiva

228 cyt c oxidase (aa3-Cox), we examined whether R. sphaeroides cyt cy can act as an electron carrier to

229 expected for a "scotophobic" response, while R. sphaeroides, which stops rather than reverses, accumu

230 Possible reasons why R. sphaeroides maintains two distinct pathways for Cbi s

231 While RpoH(I) reconstituted with R. sphaeroides core RNA polymerase transcribed all six p

232 ain sigma(E)-dependent promoters both within R. sphaeroides and across the bacterial phylogeny.