ライフサイエンスコーパス: eukaryotic organism

1 ogenesis of mineral-forming vesicles from an eukaryotic organism.

2 a prokaryotic-type cardiolipin synthase in a eukaryotic organism.

3 RNA (sRNA) repertoire in any prokaryotic or eukaryotic organism.

4 bacterial RR domains and this example from a eukaryotic organism.

5 trogenase cofactor biosynthetic pathway in a eukaryotic organism.

6 s orchestrate the genetic circuitry of every eukaryotic organism.

7 been tested under natural conditions for any eukaryotic organism.

8 r to provide flexibility and adaptability to eukaryotic organisms.

9 antisense RNAs are found in a wide range of eukaryotic organisms.

10 erstanding a process that is universal among eukaryotic organisms.

11 velopment, function, and malignant events in eukaryotic organisms.

12 is dispensable for a considerable number of eukaryotic organisms.

13 nt, differentiation, and genome stability in eukaryotic organisms.

14 ects that target related viral, bacterial or eukaryotic organisms.

15 ent biological activities in a wide range of eukaryotic organisms.

16 play individually numerous crucial roles in eukaryotic organisms.

17 NADH), suggesting a surprising homology with eukaryotic organisms.

18 es of 'snapshots' across a broad spectrum of eukaryotic organisms.

19 r role in stabilizing collagenous domains in eukaryotic organisms.

20 Function647 protein family found in diverse eukaryotic organisms.

21 to be involved in developmental processes of eukaryotic organisms.

22 nary origin of Hen1 present in bacterial and eukaryotic organisms.

23 0-nucleotides (nts) that are present in most eukaryotic organisms.

24 process of purging deleterious mutations in eukaryotic organisms.

25 tous sensor/transducer of calcium signals in eukaryotic organisms.

26 is therefore likely to be conserved in other eukaryotic organisms.

27 teractions and microbiome formation in basal eukaryotic organisms.

28 ircumvent redundancy problems encountered in eukaryotic organisms.

29 n genome size and evolution of virtually all eukaryotic organisms.

30 an important antiviral mechanism in diverse eukaryotic organisms.

31 n during PCD in these evolutionarily ancient eukaryotic organisms.

32 reductase domains, is widely distributed in eukaryotic organisms.

33 tal feature of genome architecture in higher eukaryotic organisms.

34 role in increasing the genetic variations in eukaryotic organisms.

35 the high mobility group (HMG) proteins from eukaryotic organisms.

36 tical to development and maintenance of many eukaryotic organisms.

37 proper bipolar spindle formation in various eukaryotic organisms.

38 ration of transgenic DNA into the genomes of eukaryotic organisms.

39 with important functions in prokaryotic and eukaryotic organisms.

40 r similar to the complexes observed in other eukaryotic organisms.

41 nt in the metabolism of both prokaryotic and eukaryotic organisms.

42 UF647 domain protein family found in diverse eukaryotic organisms.

43 a heritable epigenetic mark present in many eukaryotic organisms.

44 tions in genomic DNA in both prokaryotic and eukaryotic organisms.

45 red for the initiation of DNA replication in eukaryotic organisms.

46 ry mechanisms of FAD homeostasis by FMNAT in eukaryotic organisms.

47 is a highly conserved protein present in all eukaryotic organisms.

48 athways that are universally conserved among eukaryotic organisms.

49 gous to programmed cell death (apoptosis) in eukaryotic organisms.

50 tion factor is known as Spt5 in archaeal and eukaryotic organisms.

51 rity in one of the largest clades of complex eukaryotic organisms.

52 ve diverse and important biological roles in eukaryotic organisms.

53 the evolutionary and ecological expansion of eukaryotic organisms.

54 leus that have been found in major clades of eukaryotic organisms.

55 cently cloned and characterized from several eukaryotic organisms.

56 eserve cellular homeostasis in virtually all eukaryotic organisms.

57 sembly in similar fashion in all archaea and eukaryotic organisms.

58 ntial for cellular energy production in most eukaryotic organisms.

59 ne tract found at the end of introns in most eukaryotic organisms.

60 nnatural amino acids in both prokaryotic and eukaryotic organisms.

61 Homologous recombination has a dual role in eukaryotic organisms.

62 LCB-Ps) are important signaling molecules in eukaryotic organisms.

63 nvolved in chromatin-based gene silencing in eukaryotic organisms.

64 lso be adapted for use in the study of other eukaryotic organisms.

65 ntral to the development and survival of all eukaryotic organisms.

66 at the 3' end of the intron compared to most eukaryotic organisms.

67 mechanisms of mRNA decay in prokaryotic and eukaryotic organisms.

68 mere length and chromosome stability in most eukaryotic organisms.

69 usly unknown function conserved in divergent eukaryotic organisms.

70 nnatural amino acids in both prokaryotic and eukaryotic organisms.

71 ranscriptionally regulate gene expression in eukaryotic organisms.

72 in signaling exists in this diverse group of eukaryotic organisms.

73 n of gene expression in both prokaryotic and eukaryotic organisms.

74 may have had a key role in the evolution of eukaryotic organisms.

75 gulation of gene activation and silencing in eukaryotic organisms.

76 ntrons from a subset of transfer RNAs in all eukaryotic organisms.

77 ny expression profiling experiment involving eukaryotic organisms.

78 % to encompass over 30,000 proteins from 138 eukaryotic organisms.

79 of the cytoplasm during cell division among eukaryotic organisms.

80 acterial species and all currently sequenced eukaryotic organisms.

81 ination for genetic studies of intracellular eukaryotic organisms.

82 able for a growing number of prokaryotic and eukaryotic organisms.

83 tal processes and environmental responses in eukaryotic organisms.

84 ion is conserved between M. tuberculosis and eukaryotic organisms.

85 covered interactions between V. cholerae and eukaryotic organisms.

86 pping identified sequences to the genomes of eukaryotic organisms.

87 lular biology shared between fungi and other eukaryotic organisms.

88 c initiator for the synthesis of glycogen in eukaryotic organisms.

89 is essential for the health and longevity of eukaryotic organisms.

90 f Agrobacterium can be extended to non-plant eukaryotic organisms.

91 nsights to the transcriptional regulation in eukaryotic organisms.

92 ated activation of the MAP kinase cascade in eukaryotic organisms.

93 the essential trafficking of iron in diverse eukaryotic organisms.

94 nd have been investigated in prokaryotic and eukaryotic organisms.

95 all Gram-negative bacteria and even several eukaryotic organisms.

96 the other subunits, are highly conserved in eukaryotic organisms.

97 at acidifies subcellular compartments in all eukaryotic organisms.

98 e-embedded photoreceptors in prokaryotic and eukaryotic organisms.

99 ssential for the survival of prokaryotic and eukaryotic organisms.

100 eved to be a major force in the evolution of eukaryotic organisms.

101 ol can be easily adjusted for application to eukaryotic organisms.

102 ce-specific regulation of gene expression in eukaryotic organisms.

103 redox homeostasis in various prokaryotic and eukaryotic organisms.

104 en identified in bacteria, yeasts, and other eukaryotic organisms.

105 ed DNA viruses infect archaea, bacteria, and eukaryotic organisms.

106 stantial genome plasticity compared to other eukaryotic organisms.

107 o animals that can affect protein folding in eukaryotic organisms.

108 ial biological process in the development of eukaryotic organisms.

109 the Lon substrates in other prokaryotic and eukaryotic organisms.

110 ents located in other parts of genes in many eukaryotic organisms.

111 on and also occur in reduced numbers in some eukaryotic organisms.

112 is an essential gene-regulation mechanism in eukaryotic organisms.

113 es and in viruses known to infect a range of eukaryotic organisms.

114 truction of tunable gene circuits in complex eukaryotic organisms.

115 and regulatory machinery in plants and other eukaryotic organisms.

116 und in the nucleus and/or organelles of most eukaryotic organisms.

117 aromyces cerevisiae and potentially to other eukaryotic organisms.

118 iRNAs) are important regulatory molecules in eukaryotic organisms.

119 hat are key regulators of gene expression in eukaryotic organisms.

120 o-evolve to ensure proper protein folding in eukaryotic organisms.

121 O) is required for survival of virtually all eukaryotic organisms.

122 egulatory roles of 6mA in gene expression in eukaryotic organisms.

123 s reside within almost every cell nucleus of eukaryotic organisms.

124 lock the molecular underpinnings of aging in eukaryotic organisms.

125 ontributes to numerous cellular functions in eukaryotic organisms.

126 t transcriptional regulatory capabilities of eukaryotic organisms.

127 ylated in T. cruzi approaching that of other eukaryotic organisms (0.5-1.7%).

128 ociated protein degradation (ERAD) system in eukaryotic organisms(1-4).

129 In eukaryotic organisms, 3'-terminal 2'-O-methylation of sm

130 Eukaryotic organisms age, yet detrimental age-associated

131 etabolic differences between prokaryotic and eukaryotic organisms, allowing easier distinction betwee

132 In higher eukaryotic organisms, AMPs can also be referred to as 'h

133 ivity from cultured human cells to an intact eukaryotic organism and suggest that low-cost, highly de

134 derived from 25 038 genomes, as well as 477 eukaryotic organisms and 2502 viral proteomes that were

135 et of intracellular proteins to membranes in eukaryotic organisms and also promotes protein-protein i

136 Marine viruses affect Bacteria, Archaea and eukaryotic organisms and are major components of the mar

137 enerating such a code is highly conserved in eukaryotic organisms and consists of ordered assembly of

138 0 are extensively conserved in multicellular eukaryotic organisms and define a novel family of struct

139 Here, we study dormancy in different eukaryotic organisms and find it to be associated with a

140 and Cdc16) domains are broadly conserved in eukaryotic organisms and function as GAPs for Rab GTPase

141 solated from various bacterial, archaeal, or eukaryotic organisms and have been evaluated for their a

142 view of TA elements in both prokaryotic and eukaryotic organisms and highlight their similarities an

143 own that autophagy occurs in a wide range of eukaryotic organisms and in multiple different cell type

144 It occurs in a wide variety of eukaryotic organisms and in some viruses.

145 n of free thiamin to TPP in plants and other eukaryotic organisms and is central to thiamin cofactor

146 eins (MCTPs) are evolutionarily conserved in eukaryotic organisms and may function as signaling molec

147 Ataxin-2 (ATXN2) homologs exist in all eukaryotic organisms and may have contributed to their o

148 bipolar (Kinesin-5) family are conserved in eukaryotic organisms and play critical roles during the

149 ranscription factors (TFs) are ubiquitous in eukaryotic organisms and play major roles during plant d

150 Roseobacters also occur associated with eukaryotic organisms and possess streamlined as well as

151 nucleotides (nt) in length are found in most eukaryotic organisms and regulate numerous biological fu

152 They are produced by prokaryotic and eukaryotic organisms and show diverse biological activit

153 is an environmental signal perceived by most eukaryotic organisms and that can have major impacts on

154 Fungi are eukaryotic organisms and there are a limited number of t

155 tissue development and tissue homeostasis in eukaryotic organisms and, when dysregulated, causes inap

156 is at a quality yet achieved only for a few eukaryotic organisms, and constitutes an important refer

157 ese molecules are prevalent in bacterial and eukaryotic organisms, and involved in a variety of respo

158 y cellular energy sensor highly conserved in eukaryotic organisms, and it has an essential role in au

159 fferent fluorophores in both prokaryotic and eukaryotic organisms, and it should facilitate both bioc

160 ber of noncoding RNA transcripts (ncRNAs) in eukaryotic organisms, and there is growing interest in t

161 tal metabolic organelles found in almost all eukaryotic organisms, and they rely exclusively on impor

162 od, our data indicate that certain groups of eukaryotic organisms appeared and diversified during the

163 Multicellular eukaryotic organisms are attacked by numerous parasites

164 Genomes of eukaryotic organisms are packaged into nucleosomes that

165 tein kinase (MAPK) pathway is widely used by eukaryotic organisms as a central conduit via which cell

166 ual reproduction enables genetic exchange in eukaryotic organisms as diverse as fungi, animals, plant

167 lear membrane structure is important for all eukaryotic organisms as evidenced by the numerous human

168 ll be rapidly populated with prokaryotic and eukaryotic organisms as relevant data become available i

169 GAT-ADCS is found in eukaryotic organisms autonomous for folate biosynthesis,

170 Iron (Fe) is an essential element for all eukaryotic organisms because it functions as a cofactor

171 Iron is an essential micronutrient for all eukaryotic organisms because it participates as a redox-

172 present in a wide variety of prokaryotic and eukaryotic organisms but are of largely unknown function

173 players in the development of multi-cellular eukaryotic organisms but have yet to be comprehensively

174 n numerous essential biological processes in eukaryotic organisms, but are often more difficult to is

175 n the regulation of small GTPase activity in eukaryotic organisms, but little is known about ELMO pro

176 epistasis than the other allele is 50~70% in eukaryotic organisms, but only 20~30% in bacteria and ar

177 rase II (RNAPII) is remarkably widespread in eukaryotic organisms, but the effects of such transcript

178 Ps) lasting seconds to minutes also occur in eukaryotic organisms, but their biological functions and

179 Arthropods are the most diverse group of eukaryotic organisms, but their phylogenetic relationshi

180 s work, we show that proteins expressed by a eukaryotic organism can be isotopically labeled and prod

181 the DNA-transfer mechanisms from bacteria to eukaryotic organisms can also help in understanding hori

182 plants to exchange small RNAs with invading eukaryotic organisms can be exploited to provide disease

183 The proteins injected by bacteria into eukaryotic organisms can lead to fates as diverse as dea

184 While all eukaryotic organisms characterized to date contain an eI

185 The centromeres of most eukaryotic organisms consist of highly repetitive arrays

186 tein-protein interaction networks in several eukaryotic organisms contain significantly more self-int

187 scence are near-universal characteristics of eukaryotic organisms, controlled by many interacting qua

188 In eukaryotic organisms, cysteine palmitoylation is an impo

189 our diverse types of aquatic and terrestrial eukaryotic organisms (Danio rerio (zebrafish), Fundulus

190 elements (TEs) are both a boon and a bane to eukaryotic organisms, depending on where they integrate

191 lved in the regulation of gene expression in eukaryotic organisms depict a highly complex process req

192 In diverse eukaryotic organisms, Dicer-processed, virus-derived sma

193 R was tested on the genome sequences of four eukaryotic organisms, Drosophila melanogaster, Daphnia p

194 ptides serve as signals between bacteria and eukaryotic organisms during both pathogenic and symbioti

195 tocol we describe here can be applied to any eukaryotic organism (e.g., yeast, human), and it require

196 xation, carboxysomes could be transferred to eukaryotic organisms (e.g. plants) to increase photosynt

197 n developmental and pathological situations, eukaryotic organisms employ the catabolic process of aut

198 t StII, a pore-forming protein from a marine eukaryotic organism, encapsulated into Lp functions as a

199 Many eukaryotic organisms encode more than one RNA-dependent

200 usage appears to follow common rules in the eukaryotic organisms examined to date: all chromosomes a

201 functions, which may be a recurring theme in eukaryotic organisms experiencing programmed genome rear

202 In contrast, eukaryotic organisms exploit a multitude of replication

203 To minimize ROS toxicity, prokaryotic and eukaryotic organisms express a battery of low-molecular-

204 We have also learned that most eukaryotic organisms express multiple eIF4E family membe

205 Genomes across a wide range of eukaryotic organisms fold into higher-order chromatin do

206 This approach is then applied to a range of eukaryotic organisms for which extensive protein interac

207 lying unity between the cells and tissues of eukaryotic organisms from yeast to humans.

208 agy are fundamental homeostatic processes in eukaryotic organisms fulfilling essential roles in devel

209 In eukaryotic organisms, gene expression requires an additi

210 s are calculated for genes from nonmammalian eukaryotic organisms, genes from the same organism again

211 GPCAT homologues were found in the major eukaryotic organism groups but not in prokaryotes or cho

212 t that Arabidopsis (Arabidopsis thaliana), a eukaryotic organism, has two functional GEN1 homologs in

213 signaling molecules in both prokaryotic and eukaryotic organisms have discovered a new class of heme

214 Eukaryotic organisms have several different HDACs, but t

215 ng characteristics including low toxicity to eukaryotic organisms, high stability at circumneutral pH

216 uctures of 96 680 protein domains from seven eukaryotic organisms (Homo sapiens, Mus musculus, Bos ta

217 resource for orthologous proteins from nine eukaryotic organisms: Homo sapiens, Mus musculus, Rattus

218 Survival of eukaryotic organisms in the face of such challenge requi

219 rising homology between some prokaryotic and eukaryotic organisms in the mechanisms responsible for M

220 tant for numerous cellular processes in most eukaryotic organisms, including cellular proliferation,

221 These predict DISC1 orthologues in diverse eukaryotic organisms, including early-branching animals

222 We highlight recent findings from diverse eukaryotic organisms, including humans, that suggest bot

223 species produced by both bacteria and higher eukaryotic organisms, including mammalian vertebrates, h

224 In many eukaryotic organisms, including yeast (Saccharomyces cer

225 ned 38 genes from a range of prokaryotic and eukaryotic organisms into both pCold and pET14 systems,

226 Ribosome biogenesis in eukaryotic organisms involves the coordinated assembly o

227 Aging of a eukaryotic organism is affected by its nutrition state a

228 f the hundreds of GPCRs present in a typical eukaryotic organism is therefore critical to understand

229 extent of transfers from these lineages into eukaryotic organisms is contentious.

230 evelopmental and phenotypic divergence among eukaryotic organisms is driven primarily by variation in

231 e photosynthetic electron transport chain of eukaryotic organisms is facilitated by the soluble coppe

232 Intracellular copper (Cu) in eukaryotic organisms is regulated by homeostatic systems

233 A fundamental characteristic of eukaryotic organisms is the generation of genetic variat

234 volutionarily conserved nucleolar protein in eukaryotic organisms, is required for maintaining DNA me

235 NusG, referred to as Spt5 in archaeal and eukaryotic organisms, is the only transcription factor c

236 Filamentous fungi are multicellular eukaryotic organisms known for nutrient recycling as wel

237 Some model eukaryotic organisms lack the ability to insert selenocy

238 Even eukaryotic organisms lacking nervous systems contain hom

239 (most) life but rather the demise of certain eukaryotic organisms, leading to a decline in species ri

240 ic ncRNAs alone (such as viroids) can infect eukaryotic organisms, leading to diseases.

241 nylate cyclase (HemAC-Lm) in the unicellular eukaryotic organism Leishmania.

242 For complex eukaryotic organisms like humans, the genome is vast and

243 ession profiles have been generated for many eukaryotic organisms, little is known about the specific

244 e classical pathway, found throughout higher eukaryotic organisms, mediates intercellular communicati

245 In plants, as in all eukaryotic organisms, microtubule- and actin-filament ba

246 but have only been applied to multicellular eukaryotic organisms more recently.

247 In both prokaryotic and eukaryotic organisms, nucleoside diphosphate kinase is a

248 h AtBUD13 homologs are widely distributed in eukaryotic organisms, phylogenetic analysis revealed tha

249 e RNA polymerases (RNAP I-III) shared by all eukaryotic organisms, plant genomes encode a fourth RNAP

250 Unlike most eukaryotic organisms, plants are not known to activate m

251 genome and apply the new method to two other eukaryotic organisms, Plasmodium and Penicillium.

252 l protein kinases in diverse prokaryotic and eukaryotic organisms, playing significant roles in yeast

253 ting the immense diversity of single-celled, eukaryotic organisms (protists) has been a formidable ch

254 uclear pore complexes (NPCs) is conserved in eukaryotic organisms ranging from yeast to mammals.

255 , gene regulatory network inference for most eukaryotic organisms remain challenging.

256 brane merger during cell-cell fusion in most eukaryotic organisms remain elusive.

257 In both prokaryotic and eukaryotic organisms, repressors and activators are resp

258 cking systems with those of humans and other eukaryotic organisms reveal major differences.

259 a global genetic network mapped for a model eukaryotic organism revealed that genetic interactions o

260 Cross-comparison of AtSubP on six nontrained eukaryotic organisms (rice [Oryza sativa], soybean [Glyc

261 For all eukaryotic organisms, RNA polymerase II (Pol II) is resp

262 ept is illustrated as being generalizable to eukaryotic organisms (Saccharomyces cerevisiae) and thus

263 athogens like Plasmodium)-suggests that many eukaryotic organisms share a common gamete fusion mechan

264 Phylogenetic analysis of selected eukaryotic organisms showed that most life forms encode

265 egulate critical cellular activities in many eukaryotic organisms, such as membrane trafficking, telo

266 ns and adenylate cyclase from prokaryotic to eukaryotic organisms suggests that they share an early c

267 saccharomyces pombe but not in various other eukaryotic organisms tested despite strict conservation

268 In contrast to the FPPS of other eukaryotic organisms, TgFPPS is bifunctional, catalyzing

269 to rapidly identify membrane proteins from a eukaryotic organism that are most amenable to expression

270 Here we report the first study of RNRs in a eukaryotic organism that encodes class I and class II RN

271 Eukaryotic organisms that colonized multilayered settlem

272 s fungus, promises to be applicable to other eukaryotic organisms that have a low frequency of homolo

273 rly defined property of many prokaryotic and eukaryotic organisms that move across solid surfaces in

274 Our studies suggest that unlike most other eukaryotic organisms that rely on TBP for Pol III transc

275 In higher eukaryotic organisms, the checkpoint kinase 1 (Chk1) con

276 astically different from those used by other eukaryotic organisms, the extreme AT-rich nature of P. f

277 Ubiquitous in eukaryotic organisms, the flagellum is a well-studied or

278 However, since dynein is essential in most eukaryotic organisms, the in-depth study of the cellular

279 orms have been reported in simple to complex eukaryotic organisms, the mechanisms by which such isofo

280 s to establish complete genomic sequences of eukaryotic organisms, the so-called 'finished' genomes a

281 comitant with or shortly after the origin of eukaryotic organisms themselves.

282 es, especially thermophiles, but uncommon in eukaryotic organisms, thereby suggesting that this prope

283 In eukaryotic organisms, these enzymes are reported to have

284 yeast Saccharomyces cerevisiae is the first eukaryotic organism to have its genome completely sequen

285 Ks) regulate essential adaptive responses in eukaryotic organisms to environmental changes.

286 NA splicing is a major mechanism utilized by eukaryotic organisms to expand their protein-coding capa

287 g is a genome defense mechanism used by many eukaryotic organisms to fight viruses and to control tra

288 ry, innate immune mechanisms found in modern eukaryotic organisms today are highly complex but yet bu

289 Eukaryotic organisms typically express multiple type IV

290 ate high- confidence network predictions for eukaryotic organisms using Markov Random Fields in a sem

291 This method can be easily adapted to other eukaryotic organisms using the detailed procedures descr

292 ctin interacting protein 1) is ubiquitous in eukaryotic organisms, where it cooperates with cofilin t

293 widely distributed in prokaryotic and lower eukaryotic organisms, where it is often found in transme

294 however, highly diverse and pervasive among eukaryotic organisms, which we hypothesize may confound

295 Fungi are a diverse group of eukaryotic organisms whose activities are intricately li

296 budding yeast Saccharomyces cerevisiae is a eukaryotic organism with extensive genetic redundancy.

297 cant expansion of the functional proteome of eukaryotic organisms with limited gene numbers.

298 ncounter a variety of viruses, bacteria, and eukaryotic organisms with pathogenic potential.

299 view of the regulation of gene expression in eukaryotic organisms, with a major shift towards epigene

300 EMBLEM extends lineage tracing to any eukaryotic organism without genetic engineering.