ライフサイエンスコーパス: bacteriorhodopsin

1 ter-characterized membrane protein (Asp85 in bacteriorhodopsin).

2 rate and yield of another membrane protein, bacteriorhodopsin.

3 on gradients or the light-driven proton pump bacteriorhodopsin.

4 developed to study the initial unfolding of bacteriorhodopsin.

5 hanges to those caused by dark adaptation in bacteriorhodopsin.

6 ntly, does not denature the membrane protein bacteriorhodopsin.

7 24-O(gamma) hydrogen bond does not stabilize bacteriorhodopsin.

8 on transport cycle of the light-driven pump, bacteriorhodopsin.

9 ules can be related to the pump mechanism of bacteriorhodopsin.

10 observed for the light-activated proton pump bacteriorhodopsin.

11 luation of the last proton transfer steps in bacteriorhodopsin.

12 nts of the light-driven proton/hydroxyl-pump bacteriorhodopsin.

13 s a biological detergent that can solubilize bacteriorhodopsin.

14 lent binding of retinal and final folding to bacteriorhodopsin.

15 ated at the extracellular side in helix C of bacteriorhodopsin.

16 lles, containing retinal, to give functional bacteriorhodopsin.

17 part of the proton release complex (PRC) in bacteriorhodopsin.

18 torial, light-driven transport of protons by bacteriorhodopsin.

19 (a) of the retinal protonated Schiff base in bacteriorhodopsin.

20 s has been quantified for frozen crystals of bacteriorhodopsin.

21 tion making it comparable to the proton pump bacteriorhodopsin.

22 sporter distantly related to the proton pump bacteriorhodopsin.

23 roton transport cycle of the related protein bacteriorhodopsin.

24 ually stable, single domain proteins such as bacteriorhodopsin.

25 hromophore within the membrane-bound protein bacteriorhodopsin.

26 intermediate in the ion-motive photocycle of bacteriorhodopsin.

27 re, we directly determine the flexibility of bacteriorhodopsin -- a protein that uses the energy in l

28 capabilities of proteins and, in the case of bacteriorhodopsin, a 700-fold improvement has been reali

29 Bacteriorhodopsin, a membrane protein with a relative mo

30 in situ isomerization dynamics of retinal in bacteriorhodopsin, a microbial retinal protein that func

31 Bacteriorhodopsin, a particularly simple integral membra

32 GUVs containing bacteriorhodopsin, a photoactivable proton pump, can gen

33 BO is the apoprotein of bacteriorhodopsin, a structurally well characterized pro

34 the Halobacterium sp. NRC-1 genome, reduced bacteriorhodopsin accumulation on solid medium but not i

35 in the identification the smaller regulons (bacteriorhodopsin-activator protein).

36 lutamate residue corresponding to Asp(85) in bacteriorhodopsin acts as the primary acceptor of the Sc

37 eubacterial MP, (ii) Halobacterium salinarum bacteriorhodopsin, an alpha-helical archaebacterial MP w

38 al changes in the stability of 42 mutants of bacteriorhodopsin and 25 mutants of rhomboid protease.

39 (PM) are two-dimensional crystals formed by bacteriorhodopsin and a variety of lipids.

40 hich in turn promoted the flux of photons to bacteriorhodopsin and accelerated the proton pumping kin

41 An M intermediate of wild-type bacteriorhodopsin and an N intermediate of the V49A muta

42 Two membrane-associated proteins, bacteriorhodopsin and ApoA lipoprotein, were coexpressed

43 Proton pumps, bacteriorhodopsin and ATP synthases in particular, are c

44 of heptahelical membrane proteins related to bacteriorhodopsin and characterized by a duplicated moti

45 ptake events in the light-driven proton-pump bacteriorhodopsin and correlate these to other molecular

46 stitutions at 24 positions in the B helix of bacteriorhodopsin and examined their effects on structur

47 of helical membrane proteins, we found that bacteriorhodopsin and halorhodopsin are the most tightly

48 -200-Thr and Val-210-Tyr), expected to align bacteriorhodopsin and HtrII in similar juxtaposition as

49 on of the structured EF interhelical loop of bacteriorhodopsin and its change in the M photointermedi

50 ever, deletion of both brp and blh abolished bacteriorhodopsin and retinal production in liquid mediu

51 is supported by experiments carried out with bacteriorhodopsin and rhodopsin, in which cutting or eli

52 photoproduct(s) M' were studied in wild-type bacteriorhodopsin and several mutants at low temperature

53 of reactions in the photocycles of wild-type bacteriorhodopsin and several site-specific mutants.

54 relation between the binding of one Ca2+ per bacteriorhodopsin and the amount of blue membrane conver

55 ed at individual sites throughout helix D of bacteriorhodopsin and the changes in the fluorescence of

56 he visible absorbance maxima of ground state bacteriorhodopsin and the mean decay times of the photoc

57 The proton pump bacteriorhodopsin and the phototaxis receptor sensory rh

58 pairwise helix-helix interaction surfaces of bacteriorhodopsin and three other seven-transmembrane-he

59 imine similar to the pKa changes observed in bacteriorhodopsin and visual opsins during isomerization

60 ApoA lipoprotein enhanced the solubility of bacteriorhodopsin and would facilitate functional studie

61 idues (the homologs of Asp-85 and Asp-212 in bacteriorhodopsin) and an arginine residue (the homolog

62 ransmembrane G protein-coupled receptor-like bacteriorhodopsin, and cytochrome P450s (peripheral MPs)

63 orylation in mitochondria, proton pumping in bacteriorhodopsin, and uncoupling membrane potentials by

64 absorption spectrum, opposite of the case of bacteriorhodopsin; and (iii) efficient reversible light-

65 tually all successful photonic devices using bacteriorhodopsin are based on chemical or genetic varia

66 or groups, corresponding to D212 and D115 in bacteriorhodopsin, are clearly different from other micr

67 , the homologues of the Asp-85 and Asp-96 in bacteriorhodopsin, are the proton acceptor and donor to

68 niques for the extramembranous domains using bacteriorhodopsin as a scaffold for membrane attachment

69 esponds well with estimates for mutations in bacteriorhodopsin as well as for those mutations in the

70 o photoactive protein systems, rhodopsin and bacteriorhodopsin, as a means to characterize collective

71 ral information is available for the initial bacteriorhodopsin, as well as the first five states in t

72 oxylic acids of the light-driven proton pump bacteriorhodopsin, Asp-85 and Asp-96, were replaced, sho

73 These include Asp73, which in the case of bacteriorhodopsin (Asp85) functions as the Schiff base c

74 prenoid synthesis, carotenoid synthesis, and bacteriorhodopsin assembly.

75 ) studies of the photocycle intermediates of bacteriorhodopsin at cryogenic temperatures, water molec

76 he non-illuminated D85S mutant and wild-type bacteriorhodopsin at low pH.

77 In the photocycle of bacteriorhodopsin at pH 7, a proton is ejected to the ex

78 In the photocycle of bacteriorhodopsin at pH 7, proton release from the proto

79 e was constructed and docked into a helical, bacteriorhodopsin-based model of the recently identified

80 the current fabrication technique, versatile bacteriorhodopsin-based photoelectric immunosensors can

81 d regulation of carotenoid metabolism during bacteriorhodopsin biogenesis, we have identified an H. s

82 unctional lycopene beta-cyclase required for bacteriorhodopsin biogenesis.

83 -frame deletion of brp, a gene implicated in bacteriorhodopsin biogenesis.

84 rometer as a passive structure, covered by a bacteriorhodopsin (bR) adlayer as the active element.

85 n orientation to two transmembrane proteins, bacteriorhodopsin (bR) and F(0)F(1)-ATP synthase; the so

86 Previous work with the alpha-helical MPs bacteriorhodopsin (bR) and glycophorin A (GpA) shows tha

87 Bacteriorhodopsin (BR) and sensory rhodopsin II (SRII) a

88 Bacteriorhodopsin (BR) and sensory rhodopsin II (SRII) f

89 Bacteriorhodopsin (BR) and sensory rhodopsin II (SRII),

90 Bacteriorhodopsin (BR) and specific lipid molecules self

91 Bacteriorhodopsin (BR) and SRII are used as homology par

92 surfactants to the integral membrane protein bacteriorhodopsin (BR) and the formation of protein-surf

93 The dynamics of bacteriorhodopsin (bR) and the lipid headgroups in orien

94 ion on the protein conformational changes of bacteriorhodopsin (bR) as a function of temperature.

95 mperature dependence of the FT-IR spectra of bacteriorhodopsin (bR) as a function of the pH and of th

96 n unfolding, we chose Halobacterium halobium bacteriorhodopsin (bR) as a model system.

97 of cryo-trapped photocycle intermediates of bacteriorhodopsin (bR) by a factor of approximately 90.

98 ined functional and structural roles for the bacteriorhodopsin (bR) carboxyl-terminus.

99 were conducted on purple membrane containing bacteriorhodopsin (bR) deposited on gold, aluminum/alumi

100 the polarizable proton continua observed in bacteriorhodopsin (bR) during its photocycle.

101 As a test case, bacteriorhodopsin (bR) from Halobacterium salinarum was

102 The photosensitive protein bacteriorhodopsin (bR) has been shown to be a promising

103 Arginine-82 (R82) of bacteriorhodopsin (bR) has long been recognized as an im

104 The retinylidene protein bacteriorhodopsin (BR) is a heptahelical light-dependent

105 Bacteriorhodopsin (bR) is a light-driven proton pump.

106 The light-driven proton pump bacteriorhodopsin (bR) is a transmembrane protein that u

107 ole of proline residues in the photocycle of bacteriorhodopsin (bR) is addressed using solid-state NM

108 Bacteriorhodopsin (BR) is an integral membrane protein,

109 d below 2000 cm(-1) upon exciting retinal in bacteriorhodopsin (bR) is found to have a rise time in t

110 Bacteriorhodopsin (BR) is the photoactive proton pump fo

111 of the steps in the proton pumping cycle of bacteriorhodopsin (BR) is the release of a proton from t

112 thod for quantifying the dissociation of the bacteriorhodopsin (BR) lattice, a naturally occurring tw

113 Light absorbed by bacteriorhodopsin (bR) leads to a proton being released

114 olecular transformations in a self-assembled bacteriorhodopsin (bR) monolayer are monitored by observ

115 The parallel model for the bacteriorhodopsin (BR) photocycle at neutral pH and a te

116 e purple membrane (PM) lattice, the earliest bacteriorhodopsin (BR) photocycle intermediates, and div

117 The bacteriorhodopsin (bR) photocycle was followed by use of

118 t to modify the kinetics and pathways of the bacteriorhodopsin (BR) photocycle was reviewed.

119 d with proton translocation steps during the bacteriorhodopsin (BR) photocycle were determined by tim

120 The proton pump photocycle of bacteriorhodopsin (bR) produces photocurrent on a micros

121 Among these pumps, bacteriorhodopsin (BR) proteins cooperate with ATP synth

122 made by fusing proteoliposomes containing a bacteriorhodopsin (bR) proton pump onto the nanowire sur

123 nvestigated the role of the native lipids on bacteriorhodopsin (bR) proton transfer and their connect

124 FX structure of the light-driven proton pump bacteriorhodopsin (bR) to 2.3 A resolution and a method

125 r the bR(555), bR(568), and M(412) states of bacteriorhodopsin (bR) using solid-state NMR spectroscop

126 In one method, bacteriorhodopsin (bR) was added directly to a Saccharom

127 Bacteriorhodopsin (bR), a light-activated proton pump in

128 Aqueous droplets containing bacteriorhodopsin (bR), a light-driven proton pump, were

129 o be important for the proper functioning of bacteriorhodopsin (BR), a light-driven proton pump.

130 To examine this coordination, we study bacteriorhodopsin (BR), a light-induced proton pump in t

131 Electron transport (ETp) across bacteriorhodopsin (bR), a natural proton pump protein, i

132 Bacteriorhodopsin (bR), a representative transmembrane p

133 the overall structure most closely resembles bacteriorhodopsin (BR), an archaeal proton pump.

134 The high stability of the membrane protein bacteriorhodopsin (bR), an archetypal member of the rhod

135 metry (MS) method allows for the analysis of bacteriorhodopsin (BR), an integral membrane protein tha

136 g been recognized as an important residue in bacteriorhodopsin (bR), because its mutation usually res

137 al rhodopsins, in particular the proton pump bacteriorhodopsin (BR), than to earlier known channelrho

138 In the photocycle of bacteriorhodopsin (BR), the first proton movement, from

139 osition dependence of photocycle kinetics of bacteriorhodopsin (bR), transient absorption spectroscop

140 culations on the 1.55 A crystal structure of bacteriorhodopsin (bR), we identify the principal molecu

141 set obtained through mechanical unfolding of bacteriorhodopsin (bR), which contained a significant nu

142 this protocol to the model membrane protein bacteriorhodopsin (bR).

143 scovered light-driven proton pump similar to bacteriorhodopsin (BR).

144 as found to bind a limit of two molecules of bacteriorhodopsin (BR).

145 mpare its proton transport steps to those of bacteriorhodopsin (BR).

146 ve trimeric state and the monomeric state of bacteriorhodopsin (bR).

147 ypical of other microbial rhodopsins such as bacteriorhodopsin (BR).

148 lorhodopsin (HR) and the outward proton pump bacteriorhodopsin (BR).

149 f a bromide-bound form of the D85S mutant of bacteriorhodopsin, bR(D85S), a protein that uses light e

150 ssess the rate of folding from SDS-denatured bacteriorhodopsin (bRU) and provides accurate thermodyna

151 Utilizing tandem-MS, bacteriorhodopsin can be effectively liberated from the

152 Bacteriorhodopsin can be released from the octylglucosid

153 So far, bacteriorhodopsins capable of generating a chemiosmotic

154 he Arg-82 homolog that fulfills this role in bacteriorhodopsin caused minimal spectral changes in the

155 ct role for cations in the regulation of the bacteriorhodopsin color under normal conditions.

156 ransform infrared spectra were acquired, and bacteriorhodopsin contributions were subtracted.

157 ch is demonstrated using cell-free expressed bacteriorhodopsin coupled to a quartz glass surface in a

158 ed the L intermediate of the photocycle in a bacteriorhodopsin crystal in photo-stationary state at 1

159 Here, through an analysis of bacteriorhodopsin crystal structures and the transmembra

160 l generated from molecular modeling based on bacteriorhodopsin crystallographic structure indicated t

161 We illuminated bacteriorhodopsin crystals at 210K to produce, in a phot

162 The method was validated using bacteriorhodopsin crystals generated in live Halobacteri

163 We produced the K intermediate in bacteriorhodopsin crystals in a photostationary state at

164 e microscopy the morphology of in cubo grown bacteriorhodopsin crystals in inert buffers and during e

165 rared absorption bands, recorded from single bacteriorhodopsin crystals, confirm that the M-substate

166 and for spin-labeled lipids and spin-labeled bacteriorhodopsin cysteine mutants.

167 effect of divalent ion binding to deionized bacteriorhodopsin (dI-bR) on the thermal transitions of

168 n of the secondary and tertiary structure of bacteriorhodopsin during its in vitro refolding from an

169 The structural changes of bacteriorhodopsin during its photochemical cycle, as rev

170 the photoactive sites of proteorhodopsin and bacteriorhodopsin during the primary photoreaction.

171 hanics (QM/MM) model is constructed from the bacteriorhodopsin E204Q mutant crystal structure.

172 involved OFETs integrating phospholipids and bacteriorhodopsin exposed to 1-5% anesthetic doses that

173 e primary photochemical event in an oriented bacteriorhodopsin film is measured by directly probing t

174 y directly probing the electric field in the bacteriorhodopsin film using an ultrafast electro-optic

175 ctions after illumination of 100% humidified bacteriorhodopsin films was followed with FTIR spectrosc

176 Here we characterize the kinetics of bacteriorhodopsin folding and employ phi-value analysis

177 tion of a key apoprotein intermediate during bacteriorhodopsin folding.

178 onic colloidal capsules (CCs) assembled with bacteriorhodopsin for converting solar energy into elect

179 shapes and optimize retinal isomerization in bacteriorhodopsin, for excitation levels up to 1.8 x 10(

180 In bacteriorhodopsin, four of the eight tryptophan residues

181 Using bacteriorhodopsin from Halobacterium salinarum and the t

182 activity similar to that of the well studied bacteriorhodopsin from halophilic archaea.

183 The data show that, while folding of bacteriorhodopsin from SDS into lipids is a co-operative

184 Proton transfer in bacteriorhodopsin from the cytoplasm to the extracellula

185 Bacteriorhodopsin functions as a light-driven proton pum

186 We find that bacteriorhodopsin has a high thermodynamic stability, wi

187 n recent years, structural information about bacteriorhodopsin has grown substantially with the publi

188 er with previous work, this study shows that bacteriorhodopsin has to populate at least two folding i

189 the ionizable groups in the resting state of bacteriorhodopsin have been carried out using the recent

190 The kinetics of an individual helix of bacteriorhodopsin have been monitored during folding of

191 three membrane-embedded proline residues of bacteriorhodopsin have been replaced individually by ala

192 onnecting the seven transmembrane helices of bacteriorhodopsin have each been replaced in turn by str

193 positions throughout the N-terminal half of bacteriorhodopsin helix B.

194 kflow of spin-labeled Haloarcula marismortui bacteriorhodopsin-I (HmbRI) are obtained, and refolded f

195 e spectral tuning difference with respect to bacteriorhodopsin: (i) repositioning of the guanidinium

196 unds of the storage of the release proton in bacteriorhodopsin in a hydrogen-bonded water network.

197 ng to measure the thermodynamic stability of bacteriorhodopsin in bicelles and micelles.

198 lar to those previously reported for folding bacteriorhodopsin in detergent or lipid micelles, except

199 le membrane formation after the induction of bacteriorhodopsin in halobacteria.

200 Partially denatured, labelled bacteriorhodopsin in SDS was folded directly into phosph

201 Biogenesis of the light-driven proton pump bacteriorhodopsin in the archaeon Halobacterium salinaru

202 vealed unexpected differences between NR and bacteriorhodopsin in the configuration of the retinal ch

203 c parts of the heptahelical membrane protein bacteriorhodopsin in the mutant R82A and its second site

204 y by means of light-driven proton pumping by bacteriorhodopsin in the purple membrane.

205 holipids (TRITC-DHPE) and membrane proteins (bacteriorhodopsin) in a planar polymer-tethered 1-stearo

206 polar residue, tyrosine 199, not present in bacteriorhodopsin, in the middle of the membrane bilayer

207 ions of the tryptophan residues in wild-type bacteriorhodopsin, in the resting state, and in critical

208 for the last photocycle intermediate (O) of bacteriorhodopsin, in which Asp85 is protonated, the pro

209 re, time-resolved FTIR difference spectra of bacteriorhodopsin, including the water O-H stretching vi

210 ding step in the SDS-induced denaturation of bacteriorhodopsin involves a reduction in alpha-helical

211 ures provide insight into how this mutant of bacteriorhodopsin is able to bind a variety of different

212 ain hydrogen-bonding interactions throughout bacteriorhodopsin is only 0.6 kcal mol(-1).

213 inal Schiff base in chymotryptically cleaved bacteriorhodopsin is reduced to a secondary retinylamine

214 polyene chain of the retinal chromophore in bacteriorhodopsin is studied using molecular dynamics si

215 key event in light-driven proton pumping by bacteriorhodopsin is the formation of the L intermediate

216 elates with the fact that the FG loop mutant bacteriorhodopsin is the most susceptible to denaturatio

217 Bacteriorhodopsin is the smallest autonomous light-drive

218 ermediate in the proton-motive photocycle of bacteriorhodopsin is the starting state for the first pr

219 s the transducer, which contains photoactive bacteriorhodopsin, is here first demonstrated for direct

220 ion of the retinal protonated Schiff-base in bacteriorhodopsin, isorhodopsin and rhodopsin, all of wh

221 structure of the homologous retinal protein, bacteriorhodopsin, it is not clear where the carotenoid

222 blocked by the reduction conditions, but the bacteriorhodopsin lattice remains intact.

223 nergy (0.20-0.41 eV) is required for optimal bacteriorhodopsin liberation on the FT-ICR, in compariso

224 The photovoltaic behavior of films in which bacteriorhodopsin molecules are embedded in a polyvinyl

225 n, we reexamined the unfolding of individual bacteriorhodopsin molecules in native lipid bilayers.

226 Studies on a bacteriorhodopsin mutant of Lys216, which cannot bind re

227 action structure of the non-illuminated D96A bacteriorhodopsin mutant reveals structural changes as f

228 ons, the seven-transmembrane helical protein bacteriorhodopsin-octylglucoside micelle and the empty n

229 protein of marine proteobacteria similar to bacteriorhodopsin of the archaea, is a light-driven prot

230 we simulated two conformations of wild-type bacteriorhodopsin, one of the dark-adapted state and the

231 it does not perturb either the structure of bacteriorhodopsin or the nature of the light-activated c

232 Below 195 K, the bacteriorhodopsin photocycle could not be adequately des

233 of an early M-intermediate of the wild-type bacteriorhodopsin photocycle formed by actinic illuminat

234 tion of the pigment and the last step of the bacteriorhodopsin photocycle imply low barriers against

235 The L to M reaction of the bacteriorhodopsin photocycle includes the crucial proton

236 In the N to O reaction of the bacteriorhodopsin photocycle, Asp-96 is protonated from

237 The K state, an early intermediate of the bacteriorhodopsin photocycle, contains the excess free e

238 tion to the all- trans isomer, mimicking the bacteriorhodopsin photocycle, in a single crystal.

239 by structures of intermediate states in the bacteriorhodopsin photocycle, this study also suggests t

240 tinct kinetic forms of M-intermediate in its bacteriorhodopsin photocycle.

241 amed in analogy to photointermediates in the bacteriorhodopsin photocycle.

242 The rate of the proton pump of bacteriorhodopsin photosynthetic system is examined in t

243 nto the heterotrophic, oxygen-respiring, and bacteriorhodopsin-photosynthetic haloarchaeal common anc

244 es, and the lipid-induced recovery of native bacteriorhodopsin properties in terms of the visible abs

245 Similarly to bacteriorhodopsin, proteorhodopsin that normally contain

246 ure the dynamics of the initial unfolding of bacteriorhodopsin provides a platform for quantifying th

247 By varying the pH, the D85N mutant of bacteriorhodopsin provides models for several photocycle

248 However, unlike bacteriorhodopsin, PRs have a single highly conserved hi

249 rganized transmembrane protein arrays: (i) a bacteriorhodopsin purple membrane-like structure where p

250 Here, we show that three residues in bacteriorhodopsin replaced by the corresponding residues

251 Bacteriorhodopsin represents the simplest, and possibly

252 In the deletion strains, bacteriorhodopsin, retinal, and beta-carotene were undet

253 gineered human beta2-adrenergic receptor and bacteriorhodopsin revealed a number of factors that incr

254 of the light-induced changes associated with bacteriorhodopsin's ability to convert light energy into

255 olved resonance Raman vibrational spectra of bacteriorhodopsin's key J and K photoisomerization inter

256 Early intermediates of bacteriorhodopsin's photocycle were modeled by means of

257 wledge, that transmembrane proteins, such as bacteriorhodopsin, sarcoplasmic reticulum Ca(2+)ATPase (

258 those of other microbial rhodopsins such as bacteriorhodopsin, sensory rhodopsin II, and Neurospora

259 ve-site residue corresponding to Asp(212) in bacteriorhodopsin serves as an alternative proton accept

260 were both able to keep the membrane protein bacteriorhodopsin stable, one of them for at least 3 mon

261 rane of Halobacteria are required for normal bacteriorhodopsin structure, function, and photocycle ki

262 sequent retinal binding and final folding to bacteriorhodopsin, suggesting that these proline residue

263 ubstantial differences relative to wild-type bacteriorhodopsin, suggesting that they represent inhere

264 Crystals of bacteriorhodopsin that contain approximately 10(11) unit

265 ex of bacterioopsin (Bop) and retinal called bacteriorhodopsin that functions as a light-driven proto

266 The folding of the transmembrane protein bacteriorhodopsin that occurs during the binding of its

267 as the dynamic phase transition, although in bacteriorhodopsin the latter is usually believed to take

268 In the case of bacteriorhodopsin, the calculated terahertz spectra are

269 and tested on the integral membrane protein, bacteriorhodopsin, the crystal structure of which had pr

270 Bacteriorhodopsin, the light-driven proton pump of Halob

271 zation in the initial photochemical event in bacteriorhodopsin, the primary photoproduct K makes a th

272 ing the high-resolution crystal structure of bacteriorhodopsin, there are no obvious helix-helix inte

273 asurements of wild-type (WT) and D96N mutant bacteriorhodopsin thin films have been carried out using

274 by the corresponding residues in SRII enable bacteriorhodopsin to efficiently relay the retinal photo

275 observe, however, that the three prolines in bacteriorhodopsin transmembrane helices can be changed t

276 The bacteriorhodopsin transport cycle includes protonation o

277 vailable for all of the intermediates of the bacteriorhodopsin transport cycle, and they describe the

278 ere calculated in nine crystal structures of bacteriorhodopsin trapped in bR, early M, and late M sta

279 s applied to the photoactivated proton pump, bacteriorhodopsin, using conformational free energy diff

280 Bacteriorhodopsin was co-reconstituted with the lactose

281 a light-triggered electrochemical gradient, bacteriorhodopsin was co-reconstituted with the permease

282 fect on the overall structure of a Nanodisc, bacteriorhodopsin was embedded into a Nanodisc and simul

283 An atomic model for bacteriorhodopsin was first determined by Henderson et a

284 SDS denatured bacteriorhodopsin was folded directly into phosphatidylc

285 A spin-label at site 101 in the C-D loop of bacteriorhodopsin was previously found to detect a confo

286 1, originating from the initial unphotolyzed bacteriorhodopsin, was observed as a trough in the diffe

287 13 peptides, spanning the entire sequence of bacteriorhodopsin, was synthesized, and the structures o

288 nidirectional transmembrane ion transport in bacteriorhodopsin, we determined the atomic structures o

289 nformations in the structure and function of bacteriorhodopsin, we have constructed bacterioopsin gen

290 e is applied vertically to the C-terminus of bacteriorhodopsin, we reproduce the major experimental f

291 By applying this method to bacteriorhodopsin, we show that our smaller nanodiscs ca

292 C), a complex in the extracellular domain of bacteriorhodopsin where an excess proton is shared by a

293 zed a unique divalent cation binding site on bacteriorhodopsin which controls the blue-to-purple tran

294 oped striking light-powered proteins such as bacteriorhodopsin, which can convert light energy into c

295 ose-binding protein and the membrane protein bacteriorhodopsin, which display moderate to weak coupli

296 is in the space occupied by a tryptophan in bacteriorhodopsin, which is replaced by the smaller glyc

297 The structure of the D85S mutant of bacteriorhodopsin with a nitrate anion bound in the Schi

298 en distinct distorted helix conformations in bacteriorhodopsin with a single-point mutation.

299 tained reliable phi-values for 16 mutants of bacteriorhodopsin with good coverage across the protein.

300 Folded bacteriorhodopsin, with all trans retinal covalently bou