ライフサイエンスコーパス: archaeal genome

1 92 base pairs it is by far the largest known archaeal genome.

2 to accurately and efficiently replicate the archaeal genome.

3 eins, is widely distributed in bacterial and archaeal genomes.

4 ems in more than 100 sequenced bacterial and archaeal genomes.

5 with operon structure in both bacterial and archaeal genomes.

6 onnected gene neighborhoods in bacterial and archaeal genomes.

7 d this method to several other bacterial and archaeal genomes.

8 onserved in all or most of the bacterial and archaeal genomes.

9 n the unannotated regions of prokaryotic and archaeal genomes.

10 ction systems in the sequenced bacterial and archaeal genomes.

11 comparative genome analysis of the sequenced archaeal genomes.

12 homologous counterparts in the four complete archaeal genomes.

13 idered the evolutionarily stable core of the archaeal genomes.

14 ed by the completely sequenced bacterial and archaeal genomes.

15 the topological state of bacterial and some archaeal genomes.

16 ows modification of phylogenetically diverse Archaeal genomes.

17 ative DNA polymerase for duplication of most archaeal genomes.

18 putative encapsulin systems in bacterial and archaeal genomes.

19 sites and reconstructed RbkR regulons in 94 archaeal genomes.

20 probable horizontal origin) in bacterial and archaeal genomes.

21 transposons present in diverse bacterial and archaeal genomes.

22 over 1000 completely sequenced bacterial and archaeal genomes.

23 ne content and gene order similarity between archaeal genomes.

24 was built in 2008 to annotate bacterial and archaeal genomes.

25 ensus of CRISPR-Cas systems in bacterial and archaeal genomes.

26 en assumed that Pol B enzymes also replicate archaeal genomes.

27 the phylogeny of all available bacterial and archaeal genomes.

28 orresponding chemoreceptors in bacterial and archaeal genomes.

29 nts of the MVA pathway are often absent from archaeal genomes.

30 ir phylogenetic distribution among available archaeal genomes.

31 e functional annotation of new bacterial and archaeal genomes.

32 rtitioning technique to all proteins from 53 archaeal genomes.

33 omplete and publicly available bacterial and archaeal genomes.

34 tomated service for annotating bacterial and archaeal genomes.

35 s of GTPCHI have not been identified in most archaeal genomes.

36 one-component proteins in 365 bacterial and archaeal genomes.

37 eins from completely sequenced bacterial and archaeal genomes.

38 switch elements from the whole bacterial and archaeal genomes.

39 e target aptamer structures in bacterial and archaeal genomes.

40 notated as a selenocysteine synthase gene in archaeal genomes.

41 more than 15% of all sequenced bacterial and archaeal genomes(1,6,7), but the molecular basis of how

42 ularly critical for gene-dense bacterial and archaeal genomes(1-3) in which continued transcription w

43 naschii, Methanosarcina acetivorans (largest Archaeal genome, 5.8 Mb), and yeast.

44 we report the analysis of 1,167 nonredundant archaeal genomes (608 high-quality genomes) recovered fr

45 This taxonomy is based on 2,392 archaeal genomes, 93.3% of which required one or more ch

46 These two archaeal genomes also have only one identifiable gene en

47 y available and user-submitted bacterial and archaeal genome and contig sources.

48 (NCBI) contains nearly 200 000 bacterial and archaeal genomes and 150 million proteins with up-to-dat

49 n (NCBI) contains over 315 000 bacterial and archaeal genomes and 236 million proteins with up-to-dat

50 ucts from each of the complete bacterial and archaeal genomes and approximately 35% of those from the

51 viral and transposon genes) in bacterial and archaeal genomes and demonstrated statistically signific

52 stone sequences have been identified in many archaeal genomes and in environmental samples, and they

53 Archaeal genomes and metagenome-assembled genomes (MAGs)

54 sable elements present in most bacterial and archaeal genomes and play an important role in genomic e

55 e below the photic zone, where bacterial and archaeal genomes and proteomes undergo a community-wide

56 in systems are ubiquitous in prokaryotic and archaeal genomes and regulate growth in response to stre

57 we identify eCIS loci in 1,249 bacterial and archaeal genomes and reveal an enrichment of these loci

58 s been observed previously for bacterial and archaeal genomes () and reveal a trimodality in eukaryot

59 all index (4.2 GB for 4078 bacterial and 200 archaeal genomes) and classifies sequences at very high

60 pairs of completely sequenced bacterial and archaeal genomes, and for each genome a template-anchore

61 Spt4-Spt5 complex are universally encoded in archaeal genomes, and here we demonstrate that both elon

62 method was used to analyze 34 bacterial and archaeal genomes, and yielded more than 7600 pairs of ge

63 upporting the gene-regulatory repertoires of archaeal genomes are briefly noted.

64 Consequently, archaeal genomes are depleted of transcriptional regulat

65 yotic RNA polymerase (RNAP) II system, while archaeal genomes are more similar to bacteria with dense

66 Archaeal genomes are nearly devoid of RT in any form.

67 Functionally linked genes in bacterial and archaeal genomes are often organized into operons.

68 We review here how archaeal genomes are organized and how such organization

69 Archaeal genomes are particularly rich in such sequences

70 t, the transcriptional regulators encoded by archaeal genomes are primarily of bacterial rather than

71 As more archaeal genomes are sequenced, effective research and a

72 Archaeal genomes are typically small, circular, gene den

73 on and DNA repair for the maintenance of the archaeal genome at high temperatures.

74 are now nearly 1,000 completed bacterial and archaeal genomes available, most of which were chosen fo

75 ogeny of 10,575 evenly-sampled bacterial and archaeal genomes, based on a comprehensive set of 381 ma

76 s and detailed analysis of conserved motifs, archaeal genomes become as amenable to meaningful interp

77 et can be viewed in genomic context with the Archaeal Genome Browser at archaea.ucsc.edu.

78 The UCSC Archaeal Genome Browser offers a graphical web-based res

79 CCD genes are also present in some archaeal genomes, but the encoded enzymes remain uninves

80 t abundant proteins encoded in bacterial and archaeal genomes, but whose functions in the transposon

81 pathway except shikimate kinase are found in archaeal genomes by sequence homology to their bacterial

82 g the gene order in the completely sequenced archaeal genomes complemented by sequence profile analys

83 The majority of bacterial and archaeal genomes contain 6-14% non-coding DNA.

84 Most bacterial and archaeal genomes contain many genes with little or no si

85 lf-targeting CRISPR spacers in bacterial and archaeal genomes containing Acr-encoding proviruses.

86 Computer analysis of the archaeal genome databases failed to identify orthologues

87 Analyses of archaeal genomes did not reveal the presence of genes en

88 Although archaeal genomes encode a diverse set of type IV pilus s

89 Numerous bacterial and archaeal genomes encode from one to eight HicAB modules

90 However, many archaeal genomes encode more than one TFB and/or TBP lea

91 ysis revealed that many of the bacterial and archaeal genomes encode motifs that may be involved in m

92 n silico analyses showed that most sequenced archaeal genomes encode predicted pilins and conserved p

93 All archaeal genomes encode RNA polymerase (RNAP) subunits E

94 Bacterial and archaeal genomes encompass numerous operons that typical

95 logs of the 321-aa protein were found in all archaeal genomes examined, but not in eukaryotic or bact

96 Archaeal genomes feature a strong Shine-Dalgarno ribosom

97 gulating proteins has been identified in the archaeal genome, few of them have been studied at the mo

98 approach that searched completely sequenced archaeal genomes for a kinase-like protein with a patter

99 to be present in the sequenced bacterial and archaeal genomes from GenBank.

100 Here we recovered 43,191 bacterial and archaeal genomes from publicly available marine metageno

101 The reconstruction of bacterial and archaeal genomes from shotgun metagenomes has enabled in

102 f PHX ribosomal protein (RP) genes where the archaeal genome generally encodes more RP genes and fewe

103 Sequencing of bacterial and archaeal genomes has revolutionized our understanding of

104 er, less than 100 circularized bacterial and archaeal genomes have been assembled and published from

105 intriguing as: (i) bioinformatic searches of archaeal genomes have not identified lipoprotein biogene

106 Over 3000 microbial (bacterial and archaeal) genomes have been made publically available to

107 genome was sequenced in 1995, and the first archaeal genome in 1996.

108 ale scan of complete and draft bacterial and archaeal genomes in the NCBI RefSeq database reveals tha

109 ort-read sequencing data (4644 bacterial and archaeal genomes including 12,006 plasmids).

110 Analysis of 26 bacterial and archaeal genomes indicates that the degree of clustering

111 y available draft and finished bacterial and archaeal genomes into quality-controlled clades, reports

112 he bza gene content of several bacterial and archaeal genomes is consistent with experimentally deter

113 A substantial fraction of bacterial and archaeal genomes is dedicated to antivirus defense.

114 tify noncoding RNA elements in bacterial and archaeal genomes is hampered by the difficulty of de nov

115 The evolution of bacterial and archaeal genomes is highly dynamic and involves extensiv

116 Evolution of bacterial and archaeal genomes is highly dynamic, including extensive

117 attern of single-copy genes in bacterial and archaeal genomes is the presence of 1-15 copies of each

118 Archaeal genomes lack a recognizable peptidyl-tRNA hydro

119 e cobinamide has been under question because archaeal genomes lack orthologs to the bacterial nucleos

120 undreds of sequenced bacterial and dozens of archaeal genomes leads to several generalizations on the

121 ce of two components of the MVA pathway from archaeal genomes led to the discovery of an alternative

122 Here I describe recent developments in archaeal genome maintenance, including investigations of

123 The absence of strand asymmetry in the archaeal genomes may reflect the presence of multiple or

124 For each bacterial and archaeal genome, MiST 3.0 provides a complete signal tra

125 acterium Synechocystis sp. genome nor in the archaeal genomes of Methanococcus jannaschii, Methanobac

126 ranscription-associated proteins in the four archaeal genomes, of which 168 have homologs only in Bac

127 OASIS annotations of 1737 bacterial and archaeal genomes offered an unprecedented opportunity to

128 The browser currently contains 115 archaeal genomes, plus 31 genomes of viruses known to in

129 Small bacterial and archaeal genomes provide insights into the minimal requi

130 for 55 species, including 16 bacterial and 4 archaeal genomes representing phylogenetically diverse l

131 approximately 90% of sequenced bacterial and archaeal genomes, respectively, and evolve rapidly, acqu

132 n 36 groups of closely related bacterial and archaeal genomes reveals purifying selection affecting A

133 Our sequence analysis of archaeal genomes reveals that the highly conserved ribos

134 served differences between the four complete archaeal genomes seem to reflect disparate approaches to

135 The amount of bacterial and archaeal genome sequence and methylome data has greatly

136 Each complete archaeal genome sequence contains a homolog of this arch

137 d Synechocystis sp., and the first available archaeal genome sequence, that of Methanococcus jannasch

138 None of the four archaeal genomes sequenced to date contain open reading

139 As all complete archaeal genome sequences contain an MTH1669 homolog, th

140 e reconstructed virus and host bacterial and archaeal genome sequences from community genomic data fr

141 tic code usage of over 250,000 bacterial and archaeal genome sequences in GenBank and discovered five

142 The analysis of completed archaeal genome sequences led to the identification of a

143 haeal histones do not have histone tails and archaeal genome sequences provide no evidence for archae

144 In addition, of the six complete archaeal genome sequences published so far, five are the

145 Consortium (GSC) for reporting bacterial and archaeal genome sequences.

146 k for all bacterial genomes and one of three archaeal genomes sequences to date, confirming known or

147 ny areas of molecular biology, the advent of archaeal genome sequencing has now drawn researchers to

148 In addition, seven more archaeal genome sequencing projects are under way, inclu

149 A survey of bacterial and archaeal genomes shows that many Tn7-like transposons co

150 veal the presence of Gms homologs in diverse archaeal genomes spanning all four archaeal superphyla a

151 re is no enrichment of STRs in bacterial and archaeal genomes, suggesting that these genomes are not

152 ive inoviruses were also detected in several archaeal genomes, suggesting that, collectively, members

153 ransfer rates across available bacterial and archaeal genomes supports that the barriers observed in

154 iptional regulators encoded in bacterial and archaeal genomes that control gene expression in metabol

155 sable elements present in most bacterial and archaeal genomes that play an important role in genomic

156 collection of closely related bacterial and archaeal genomes that provides several tools to aid rese

157 kflow that enabled assembly of bacterial and archaeal genomes that were at least 80% complete.

158 resent in 32% of all sequenced bacterial and archaeal genomes, that mediate protection against specif

159 In almost all archaeal genomes, the xpb gene lies adjacent to a conser

160 s were obtained for the poorly characterized archaeal genomes; these include a previously uncharacter

161 s the signs of complexity observed in Asgard archaeal genomes to the proposed role of mitochondria in

162 yses of completely sequenced prokaryotic and archaeal genomes, together with their annotations.

163 ill facilitate the analysis of bacterial and archaeal genomes using ecological and evolutionary theor

164 ces in recovering eukaryotic, bacterial, and archaeal genomes using Hi-C contact maps, few of Hi-C-ba

165 Since the first archaeal genome was sequenced, much attention has been f

166 The coverage of the archaeal genomes was only slightly lower than that of ba

167 ess of analysing the four available complete archaeal genomes, we have noted that certain regions cha

168 nce comparisons among complete bacterial and archaeal genomes, we have uncovered a putative MIG prote

169 iple groups of closely related bacterial and archaeal genomes, we obtained robust estimates of the ge

170 34 clusters of closely related bacterial and archaeal genomes, we show here that terminal branches of

171 By expanding our analysis to 7,012 archaeal genomes, we suggest that CRISPR-Cas targeting o

172 kinase, and pyrophosphohydrolase families in archaeal genomes were evaluated as candidate enzymes for

173 Eight of the eleven archaeal genomes were from microbial species without pre

174 Historically, bacterial and archaeal genomes were reconstructed from pure (monoclona

175 All archaeal genomes which have been sequenced are predicted

176 ins 966 complete and 157 draft bacterial and archaeal genomes, which collectively contain more than 2

177 Here we report the first archaeal genome-wide nucleosome occupancy map, as observ