ライフサイエンスコーパス: chromatophore

1 ribution of differently-coloured cell-types (chromatophores).

2 sids, chemosensory array, and photosynthetic chromatophore.

3 and LH2), which pack tightly together in the chromatophore.

4 ature of membranes caused by proteins in the chromatophore.

5 bandshift of carotenoids in Rb. sphaeroides chromatophores.

6 dominant visible colors presented within the chromatophores.

7 recognizable targeting signals were found in chromatophores.

8 the range of colors presented in cephalopod chromatophores.

9 activating different combinations of colored chromatophores.

10 of DB-sCTPs is related to their import into chromatophores.

11 ys a key role in the differentiation of both chromatophores.

12 ptors whose fields of view are restricted by chromatophores.

13 ugh the self-organisation of three different chromatophores.

14 ment of different types of pigment-producing chromatophores.

15 e often arranged in pseudo-organelles called chromatophores.

16 ions of the bacterial plasma membrane termed chromatophores.

17 f the bc(1) activity found in the complement chromatophores.

18 are affected by mutations in three types of chromatophores.

19 e carotenoid bandshift in both B187DN and WT chromatophores.

20 were similar (+/- 15%) in both WT and B187DN chromatophores.

21 that of some sea urchins, which also possess chromatophores [1].

22 This amoeba harbors a "chromatophore," a nascent photosynthetic organelle deriv

23 Comparison with chromatophore abundance and position in extant reptiles

24 ited decreased Symbiodiniaceae and increased chromatophore abundances, while O. faveolata at 12 m wat

25 pts the coloration of their skin using their chromatophores according to the background substrate.

26 DCCD treatment of chromatophores also slows down the kinetics of flash-ind

27 in chromatophores depend on a combination of chromatophore and nucleus-encoded proteins.

28 , we isolated granules from specific colored chromatophores and imaged them using multiple modalities

29 As SWS1 is nested beneath chromatophores and thus subject to light changes from pi

30 After 11 days, ICM vesicles (chromatophores) and membrane invagination sites were iso

31 rane (intracytoplasmic membrane and air-aged chromatophore), and purified bc(1) complex was prepared

32 nthetic electron transfer in whole cells, in chromatophores, and with purified components to ascertai

33 wever, O. wendtii's response disappears when chromatophores are contracted within the skeleton.

34 Acting as primitive organelles, chromatophores are densely packed with the membrane prot

35 Cephalopod chromatophores are small dermal neuromuscular organs, ea

36 ow that the color-producing endosomes of all chromatophores are substantially affected in the LYST mu

37 mes, the pigments found in squid retinas and chromatophores, are derivatives of tryptophan, and the f

38 s result from the positioning and density of chromatophores between different morphs and patterns.

39 The zebrafish has three different types of chromatophores: black melanophores, yellow xanthophores,

40 ously form spots in the absence of the other chromatophores both on the regenerated skin of the tail

41 rns, generated by the spatial arrangement of chromatophores, but little is known of the mechanisms re

42 changes in Symbiodiniaceae and biomolecule (chromatophores, calmodulin, carbonic anhydrase and mucus

43 The shape of these chromatophores can be spherical (as in Rhodobacter sphae

44 cal properties of single types of developing chromatophore cells.

45 CHROMAS, segments and classifies individual chromatophores, compensates for animal movements and ski

46 om these models, support the hypothesis that chromatophores constitute a screening mechanism in O. we

47 1 complex, purified from RS delta IV-adapted chromatophores containing a fraction of the wild type cy

48 At night, these chromatophores contract and O. wendtii loses spatial vis

49 of EdnRBa through DNA methylation in yellow chromatophores contributes to pigmentation changes from

50 ionary origin ( approximately 60 Mya) termed chromatophores (CRs).

51 In Rhodobacter sphaeroides chromatophores, cytochromes (cyt) c(1) and c(2) have clo

52 er, the small number and lack of movement of chromatophores defies traditional Turing-type pattern ge

53 A high-resolution tool for the analysis of chromatophore deformations during behavior reveals detai

54 rformance with species with widely different chromatophore densities and patterning behaviors.

55 Biological processes in chromatophores depend on a combination of chromatophore

56 In the zebrafish embryo, chromatophores derive from the neural crest cells.

57 onstrated binding of recombinant DB-sCTPs to chromatophore-derived genomic DNA sequences with an affi

58 ems, but by harnessing the timing of natural chromatophore development.

59 Anolis, indicating that tfec is required for chromatophore development.

60 C migratory onset and strongly contribute to chromatophore development.

61 lex, which has not been imaged yet in native chromatophores, did not induce a preferred membrane curv

62 the cyanobacterial endosymbiont remained in chromatophore DNA.

63 kes reveal that CLCN2 is indeed expressed in chromatophores during embryogenesis and in the adult bra

64 nabling precise and parallel measurements of chromatophore dynamics and long-term tracking over devel

65 computational pipeline to track and analyze chromatophore dynamics from high-resolution videos of be

66 using either purified or detergent dispersed chromatophore-embedded R. capsulatus bc(1) complex, we d

67 duction are ongoing and dynamic processes in chromatophore evolution.

68 es of excised octopus skin during periods of chromatophore expansion and contraction and then modeled

69 n of the chromatophore muscles, resulting in chromatophore expansion.

70 d specialized cells and tissues, such as the chromatophores for camouflage or suckers to grasp prey.

71 EGT-derived proteins could be imported into chromatophores for function.

72 A model of a chromatophore from Rhodospirillum photometricum was cons

73 Bacterial chromatophores from Rhodobacter sphaeroides accomplish t

74 rane fragments derived from bacterial cells (chromatophores from Rhodopseudomonas sphaeroides) and ma

75 bandshift of carotenoids in Rb. sphaeroides chromatophores from wild type (WT) and mutant cells, in

76 e isolation intracytoplasmic (ICM) vesicles (chromatophores) from Rhodopseudomonas sphaeroides using

77 ade acquired a photosynthetic organelle, the chromatophore, from an alpha-cyanobacterial donor(3).

78 Our analyses revealed that nuclear and chromatophore gene inventories provide highly complement

79 light-induced transcriptional regulation of chromatophore genes and most EGT-derived nuclear genes.

80 Chromatophore genes faced relaxed selection when compare

81 The chromatophore genome is about a third the size of the ge

82 Once inside, they interact with the chromatophore genome potentially providing nuclear contr

83 Chromatophore genome reduction entailed the loss of many

84 Here we generated the complete chromatophore genome sequence from P. longichromatophora

85 Several genes have been transferred from the chromatophore genome to the host nuclear genome through

86 ly 25% putatively arose through EGT from the chromatophore genome.

87 csos4A) are encoded by both the nuclear and chromatophore genomes, suggesting that EGT in Paulinella

88 nd compared these data to that from existing chromatophore genomes.

89 While compositional analysis of chromatophore granules in Doryteuthis pealeii reveals th

90 cohydrolase (DRAG) with membrane proteins of chromatophores has been investigated.

91 of eukaryotic provenance is targeted to the chromatophore, implicating host-endosymbiont coordinatio

92 The chromatophores in Paulinella are evolutionary-early-stag

93 otein complexes, now known as ribosomes, and chromatophores in photosynthetic microorganisms attracte

94 eds of thousands of pigment-filled saccules (chromatophores) in the skin, which are controlled by mot

95 Owing to specialized pigment cells (chromatophores) in the skin,(6) these cephalopod mollusk

96 concentration was identical in WT and B187DN chromatophores, indicating that covalent modification of

97 out chromatophores or in detergent-disrupted chromatophores, indicating that position 175 of cytochro

98 tergent disruption of the sealed, inside-out chromatophores, indicating that this position of cytochr

99 imental findings on the nature of long-range chromatophore interactions.

100 The shape of chromatophores is primarily dependent on species, and is

101 Time-resolved fluorescence of chromatophores isolated from strains of Rhodobacter spha

102 We conclude that DCCD treatment of chromatophores leads to modification of the rate of Q(o)

103 ures of pigment progenitors delineating into chromatophore lineages, mesenchyme cells, and enteric NC

104 opositive cells are present in the posterior chromatophore lobe, the putative location of the chromat

105 Famide-immunopositive cells in the posterior chromatophore lobes also express glutamate-like immunore

106 c lobes (75% the total volume of the brain), chromatophore lobes whose motor neurons directly innerva

107 Chromatophore matching to substrate has not been reporte

108 Cryptic tail colors emerge during chromatophore maturation upon reorganization of the guan

109 g regions are on the cytoplasmic side of the chromatophore membrane and closed to the DE loop and hel

110 omplex formation was observed both in native chromatophore membrane and in chromatophores treated wit

111 Chromatophore membrane and intracytoplasmic membrane (IC

112 h the association of DRAG with three or more chromatophore membrane proteins.

113 cytochrome b on the periplasmic side of the chromatophore membrane.

114 onstructed by site-directed mutagenesis, and chromatophore membranes as well as purified bc1 complexe

115 The number of acidocalcisomes and chromatophore membranes as well as the amounts of PPi an

116 sh activation through the reaction center in chromatophore membranes from Rhodobacter sphaeroides, ha

117 lex, the steady-state level of cyt cy in the chromatophore membranes obtained using cells grown in mi

118 -subunit cytochrome (cyt) b-c1 subcomplex in chromatophore membranes of Rhodobacter capsulatus mutant

119 In this study, CooC was purified from the chromatophore membranes of Rhodospirillum rubrum with a

120 ne conditions that, along with intracellular chromatophore membranes, could represent a rudimentary b

121 entified and thought to be localized only to chromatophore membranes, is predominantly located in aci

122 ible candidates for association with DRAG in chromatophore membranes.

123 acidocalcisomes but in PPi synthesis in the chromatophore membranes.

124 he as yet incomplete integration of host and chromatophore metabolisms.

125 The chromatophore morphology and the orientation of the phot

126 matophore lobe, the putative location of the chromatophore motoneuron somata.

127 situ hybridization shows that some putative chromatophore motoneurons express FaRP-like immunoreacti

128 les directly innervated by centrally located chromatophore motoneurons.

129 ty is also present in the somata of putative chromatophore motoneurons.

130 ls the complex and distributed nature of the chromatophore motor units.

131 Pharmacological studies demonstrate that the chromatophore muscles contain receptors blocked by gluta

132 gans, each of which is regulated by a set of chromatophore muscles directly innervated by centrally l

133 pplication causes a rapid contraction of the chromatophore muscles, resulting in chromatophore expans

134 ata show that FMRFamide acts directly on the chromatophore muscles.

135 FMRFamide application causes contraction of chromatophore muscles; however, the FMRFamide effect is

136 ty and function of the transmitter(s) at the chromatophore neuromuscular junction (NMJ) in the Europe

137 ate likely acts as a neurotransmitter at the chromatophore NMJ.

138 o function as neurotransmitters at the Sepia chromatophore NMJ.

139 low transmitters, respectively, at the Sepia chromatophore NMJ.

140 The chromatophore of purple bacteria is an intracellular sph

141 hromes, the pigments present in the eyes and chromatophores of cephalopods.

142 s whose motor neurons directly innervate the chromatophores of the color-changing skin, and a vertica

143 In chromatophores of the purple bacterium Rhodobacter sphae

144 In intact cells and in isolated chromatophores of this mutant, only approximately 30% of

145 diated by specialized pigment cells known as chromatophores of which, uric acid crystal-forming leuco

146 ge has independently gained plastids (termed chromatophores) of alpha-cyanobacterial provenance.

147 aleimide (NEM), either in sealed, inside-out chromatophores or in detergent-disrupted chromatophores,

148 but also cephalopod-specific cells, such as chromatophores or sucker cells.

149 Chromatophore organs in cephalopod skin are known to pro

150 f neuronally actuated yellow, red, and brown chromatophore organs, each filled with thousands of pigm

151 the coordinated activity of millions of skin chromatophore organs, each of which is regulated by a se

152 s encode proteins that fill gaps in critical chromatophore pathways/processes.

153 it relies on easy-to-obtain and ready-to-use chromatophores, paving the way for artificial simplified

154 ), we describe a cellular mechanism in which chromatophore pigment activity (i.e., dispersion and agg

155 When dispersed, chromatophore pigment selectively absorbs the short-wave

156 y contracting muscles to reversibly activate chromatophores--pigment-containing cells under their ski

157 role for Pax7 in the early specification of chromatophore precursor cells.

158 estive of a Pax3-driven fate switch within a chromatophore precursor or stem cell.

159 Previous work on the D(LL) mutant in chromatophore preparations showed that RCs assembled wit

160 Chromatophores prepared from these two mutant cells have

161 iated predominately ipsilateral expansion of chromatophores present on the mantle, but not on the hea

162 wnian dynamics of small molecules within the chromatophore probe the mechanisms of directional charge

163 Concurrently, using an annotated squid chromatophore proteome together with microscopy, we iden

164 nd -LH2 complexes from digitonin-solubilized chromatophores revealed high levels of comigrating elect

165 utcome of optimizing the balance between the chromatophore's structural integrity and robust energy c

166 The implications of our results for chromatophore shape are discussed.

167 different photosynthetic proteins influence chromatophore shape is presented.

168 Chromatophore shape is thought to be influenced by the i

169 When applied to many chromatophores simultaneously and combined with statisti

170 while studies on squid focused mainly on the chromatophore system for communication.

171 tyles, the use of dens, the reduction of the chromatophore system in deep-sea species, and metabolic

172 The metabolic demand of the fully activated chromatophore system is nearly as great as an octopus's

173 Adaptation of the chromatophore system to the bottom substrate in the labo

174 A chromatophore-targeted glucose-6-phosphate dehydrogenase

175 -targeting signals, a large arsenal of short chromatophore-targeted proteins (sCTPs; <90 amino acids)

176 Interestingly, besides proteins carrying chromatophore-targeting signals, a large arsenal of shor

177 key role in controlling the expansion of the chromatophores that generate these diverse body patterns

178 formance is further optimized by phototropic chromatophores that regulate the dose of illumination re

179 um-derived photosynthetic organelles termed 'chromatophores' that originated relatively recently (0.0

180 high-resolution array of 'cellular pixels' (chromatophores) that are controlled by the brain.

181 a, which contains photosynthetic organelles (chromatophores) that are only 60-200 million years old.

182 we have observed in Rhodobacter sphaeroides chromatophores, that when a fraction of heme b(H) is red

183 Binding of ligands (cytochrome c(2) for the chromatophores, the peptide agonists DAMGO and melanotan

184 rmal photoreception in hogfish is to monitor chromatophores to detect information about color change

185 EdnRBa functions in yellow chromatophores to signal the aggregation of yellow pigme

186 both in native chromatophore membrane and in chromatophores treated with 0.5 M NaCl in the presence o

187 on spatial regulation of the numbers of each chromatophore type, we engineered asip1 homozygous knock

188 rought about by the interactions among three chromatophore types: black melanophores with melanin-pac

189 mparison to recent experiments indicate that chromatophores, ubiquitous in biological pattern formati

190 f an entire cell organelle, a photosynthetic chromatophore vesicle from a purple bacterium, that reve

191 evel structural model of a low-light-adapted chromatophore vesicle from Rhodobacter sphaeroides, we i

192 An all-atom structural model for an entire chromatophore vesicle is presented, which improves upon

193 The overall architecture of chromatophore vesicles and the structural integration of

194 Photosynthetic chromatophore vesicles found in some purple bacteria con

195 cteria is contained within organelles called chromatophores, which form as extensions of the cytoplas

196 ed by neural crest-derived pigment cells, or chromatophores, which include black melanophores, yellow

197 in) [9, 10], preserves dermal pigment cells (chromatophores)-xanthophores, iridophores, and melanopho