ライフサイエンスコーパス: prokaryotic cell

1 t the arrangement of the chromosome inside a prokaryotic cell.

2 erimental dataset of relatively less crowded prokaryotic cell.

3 nown about the physical environment inside a prokaryotic cell.

4 ere between 47%-96%, representing >99.98% of prokaryotic cells.

5 sis of adenine nucleotides in eukaryotic and prokaryotic cells.

6 C/AG microsatellite alleles in eukaryotic or prokaryotic cells.

7 ments mediate sensory-motor responses in all prokaryotic cells.

8 minal respiratory chains in mitochondria and prokaryotic cells.

9 transduction pathways in both eukaryotic and prokaryotic cells.

10 electively facilitate the entry of iron into prokaryotic cells.

11 altered excitation spectra when expressed in prokaryotic cells.

12 constantly secreted from both eukaryotic and prokaryotic cells.

13 is essentially negligible for typical ~1 um prokaryotic cells.

14 chanism to distribute sizeable cargos within prokaryotic cells.

15 een limited to the study of relatively small prokaryotic cells.

16 t could be even more valuable if expanded to prokaryotic cells.

17 s effectors into neighbouring eukaryotic and prokaryotic cells.

18 et effectors/toxins into both eukaryotic and prokaryotic cells.

19 to defined in vitro biochemical analysis and prokaryotic cells.

20 eir physiological function in eukaryotic and prokaryotic cells.

21 atility as it can target both eukaryotic and prokaryotic cells.

22 t the mechanisms that determine the shape of prokaryotic cells.

23 eukaryotic cells and the plasma membrane in prokaryotic cells.

24 ety of water-soluble molecules and ions into prokaryotic cells.

25 ays a critical role in the osmoregulation of prokaryotic cells.

26 fundamental process for both eukaryotic and prokaryotic cells.

27 osphate found ubiquitously in eukaryotic and prokaryotic cells.

28 important targets for regulatory factors in prokaryotic cells.

29 onveniently be maintained and manipulated in prokaryotic cells.

30 ing structure essential for cell division in prokaryotic cells.

31 ropensity of plectonemically branched DNA in prokaryotic cells.

32 t of the cytoplasmic space in eukaryotic and prokaryotic cells.

33 loned and shown to operate in eukaryotic and prokaryotic cells.

34 of the homologous recombination machinery in prokaryotic cells.

35 Z ring, which is required for cytokinesis in prokaryotic cells.

36 f flagella were themselves once free-living (prokaryotic) cells.

37 In prokaryotic cells, a direct gating of mechanosensitive c

38 In prokaryotic cells, a single-input-module motif with one

39 dization and microscopy, we demonstrate that prokaryotic cell abundances on seafloor-exposed basalts

40 CRISPR adaptive immunity pathways protect prokaryotic cells against foreign nucleic acids using CR

41 eled target nucleic acids are not useful for prokaryotic cell analysis using such arrays, a mRNA enri

42 the possible site for DNA replication in the prokaryotic cell and the site through which newly synthe

43 had a cytoskeleton that enabled it to engulf prokaryotic cells and a complex internal membrane system

44 re is compatible with both recombineering in prokaryotic cells and CRISPR editing in eukaryotic cells

45 iggle in place between segregation events in prokaryotic cells and during interphase in eukaryotic nu

46 gle phospholipase effector to influence both prokaryotic cells and eukaryotic hosts.

47 PldB targets the periplasm of prokaryotic cells and exerts an antibacterial activity.

48 fers from its counterparts in eukaryotic and prokaryotic cells and in other viruses in that it contai

49 s between segregated daughter chromosomes in prokaryotic cells and is essential for cell division.

50 cognized by the DNA replication machinery in prokaryotic cells and reveal that Ada contributes to mut

51 nine Raman band was a suitable biomarker for prokaryotic cells and thymine Raman band for eukaryotic

52 importance of this enzyme to the survival of prokaryotic cells and to the treatment of bacterial infe

53 d DNA, respectively, to target eukaryotic or prokaryotic cells, and also homologues of eukaryotic pro

54 cytolysin is lytic for eukaryotic as well as prokaryotic cells, and it consists of two structural sub

55 l between DNA segregation and cytokinesis in prokaryotic cells, and reveals a potential molecular mec

56 l (phage) infection, a small fraction of the prokaryotic cells are able to integrate a small sequence

57 mbiotic relationships between eukaryotic and prokaryotic cells are common in nature.

58 ne which part of the functional machinery of prokaryotic cells are correlated with the environments.

59 Many prokaryotic cells are encapsulated by a surface layer (S

60 Many prokaryotic cells are encased in a para-crystalline shea

61 Most prokaryotic cells are encased in a surface layer (S-laye

62 vered by T6SSs into target eukaryotic and/or prokaryotic cells as well as 196 immunity proteins.

63 rom eukaryotic organisms and small RNAs from prokaryotic cells as well as viruses.

64 rom eukaryotic organisms and small RNAs from prokaryotic cells as well as viruses.

65 It is now well established that prokaryotic cells assemble diverse proteins into dynamic

66 is a core biological process that occurs in prokaryotic cells at high speeds ( approximately 1 nucle

67 cytoskeletal proteins will not only advance prokaryotic cell biology and reveal evolutionary princip

68 hnologies have only recently been applied to prokaryotic cell biology, revealing the exquisite subcel

69 tive bacteria, which play important roles in prokaryotic cell biology.

70 cterial proteins are needed for the study of prokaryotic cell biology.

71 ifferentiation is an outstanding question in prokaryotic cell biology.

72 The method was extended to prokaryotic cells by analysis of extracts from E. coli.

73 In contrast, in prokaryotic cells, cAMP enhances the DNA binding of the

74 ned and easily observed for enumeration, and prokaryotic cells can easily be counted on the same slid

75 sues as stages in the gradual destruction of prokaryotic cells caused by viral multiplication during

76 increased cytotoxicological potency against prokaryotic cells compared to eukaryotic cells.

77 al process of in vivo protein synthesis in a prokaryotic cell containing several thousand unique mRNA

78 In the South Subtropical Pacific, prokaryotic cell counts, glucose turnover, and peptidase

79 Despite the power of bacterial genetics, the prokaryotic cell cycle has remained poorly understood.

80 Although the major events in prokaryotic cell cycle progression are likely to be coor

81 mportance to understanding regulation of the prokaryotic cell cycle.

82 potentially useful system to investigate the prokaryotic cell cycle.

83 ies that take place beyond the bounds of the prokaryotic cell cytosol must connect to membrane or cyt

84 ed by the cleaved DNA, ultimately leading to prokaryotic cell death.

85 , an essential cytoskeletal component of the prokaryotic cell division apparatus.

86 The first visible event in prokaryotic cell division is the assembly of the soluble

87 asts use proteins derived from the ancestral prokaryotic cell division machinery, whereas mitochondri

88 cterial protein FtsZ, a key component of the prokaryotic cell division machinery.

89 Prokaryotic cell division occurs through the formation o

90 plete functional replacement of an essential prokaryotic cell division protein by another and may exp

91 cestors was the host cell recruitment of the prokaryotic cell division protein FtsZ to function in ch

92 6 gene product is related closely to Ftn2, a prokaryotic cell division protein unique to cyanobacteri

93 edness of tubulin and FtsZ, the tubulin-like prokaryotic cell division protein, we tested the effect

94 on, function, and evolution of the Z ring in prokaryotic cell division.

95 triction force, and the mechanism underlying prokaryotic cell division.

96 FtsZ is a tubulin homolog essential for prokaryotic cell division.

97 protein tubulin and plays a central role in prokaryotic cell division.

98 Furthermore, the majority of prokaryotic cells do not contain GSL, which explains the

99 fication of the total transcript of a single prokaryotic cell for in-depth analysis.

100 and supply lipids in all eukaryotic and some prokaryotic cells for energy metabolism, membrane synthe

101 In this study, we used a prokaryotic cell-free expression system to reconstitute

102 unctional in driving protein expression in a prokaryotic cell-free transcription and translation syst

103 from expanded CRISPR cassette can protect a prokaryotic cell from virus infection or plasmid transfo

104 CRISPR-Cas systems defend prokaryotic cells from invasive DNA of viruses, plasmids

105 volutionary transitions, during which simple prokaryotic cells gave rise to complex eukaryotic cells.

106 al roles in the regulation of eukaryotic and prokaryotic cell growth, division, and differentiation.

107 Receptor proteins in both eukaryotic and prokaryotic cells have been found to form two-dimensiona

108 to occlude Kv channels in eukaryotic but not prokaryotic cells, hBD-2 interacted with prokaryotic and

109 layer proteins perform multiple functions in prokaryotic cells, including cellular defense, cell-shap

110 nce space, performing disparate functions in prokaryotic cells, including cellular defense, cell-shap

111 , there is growing interest in nonanimal and prokaryotic cell interfacing.

112 is only active after translocation from the prokaryotic cell into the eukaryotic plant cell.

113 mRNA decay in prokaryotic cells involves the action of both endo- and

114 reverse transcriptase (RT) to be found in a prokaryotic cell is encoded by an element called a retro

115 The prokaryotic cell is traditionally seen as a "bag of enzy

116 Protein synthesis in both eukaryotic and prokaryotic cells is a complex process requiring a large

117 Transcriptome analysis of single prokaryotic cells is a recently developed and powerful t

118 piratory chain in mitochondria and respiring prokaryotic cells is described by the product of three t

119 a dynamic ring marking the division plane of prokaryotic cells, is essential for cytokinesis.

120 In both eukaryotic and prokaryotic cells, it has been recently established that

121 How prokaryotic cells maintain such gene providers is centra

122 lation, as well as for understanding how the prokaryotic cell maintains homeostasis in a changing env

123 the spatial orientation of the enzyme within prokaryotic cells may differ.

124 demonstrate that the dynamic architecture of prokaryotic cell membranes is controlled by the MreB cyt

125 The functional organization of prokaryotic cell membranes, which is essential for many

126 ean Drilling Program Leg 201 showed elevated prokaryotic cell numbers in sediment layers where methan

127 at the interface between the eukaryotic and prokaryotic cells of the mammalian intestinal ecosystem.

128 iate voltage electron microscopes only small prokaryotic cells or peripheral regions of eukaryotic ce

129 n specific to viruses, lacking homologues in prokaryotic cells, outside known proviruses.

130 antibiotics display improved selectivity for prokaryotic cells over eukaryotic cells presumably due t

131 determinants", which provide specificity for prokaryotic cells over eukaryotic cells.

132 Inside prokaryotic cells, passive translational diffusion typic

133 Prokaryotic cells possess CRISPR-mediated adaptive immun

134 alysis is established, but TTA from a single prokaryotic cell presents additional challenges with muc

135 ranscription factor (TF)-gene pair in living prokaryotic cells remains challenging.

136 biological process, which is fundamental in prokaryotic cells, remains as yet not clearly understood

137 e) number of antibiotic resistance genes per prokaryotic cell (RGPC) was significantly lower in the s

138 tic-like features, it is not known how these prokaryotic cells segregate their chromosomes before the

139 nd lack of membrane-based DNA encapsulation, prokaryotic cells still organize and scale their nucleoi

140 , a basic element in the division process of prokaryotic cells such as Escherichia coli, Bacillus sub

141 ein surface layers (S-layers) are ubiquitous prokaryotic cell-surface structures involved in structur

142 Given the lack of a nucleus in prokaryotic cells, the significance of spatial organizat

143 uspension culture allows both eukaryotic and prokaryotic cells to assume physiologically relevant phe

144 axis signal transduction pathway that allows prokaryotic cells to control their movements in response

145 ding to partners ranging from eukaryotic and prokaryotic cells to extracellular macromolecules.

146 ar vesicles (EVs) secreted by eukaryotic and prokaryotic cells to transport lipids, proteins, and nuc

147 Prokaryotic cell transcriptomics has been limited to mix

148 Eukaryotic and prokaryotic cells use cytoskeletal proteins to regulate

149 cystophyte plastid (cyanelle) has retained a prokaryotic cell wall between the two envelope membranes

150 rchitecture of eukaryotes, but its impact in prokaryotic cells was much less characterized.

151 ssengers affecting numerous responses of the prokaryotic cell, whereas in the latter, they act as ago

152 the number of spacers in a CRISPR array of a prokaryotic cell which maximizes its protection against

153 is available about diffusion coefficients in prokaryotic cells, which differ from eukaryotic cells in

154 atiotemporal and stage-specific processes of prokaryotic cells within complex environments.

155 btle genetic modifications in eukaryotic and prokaryotic cells without the requirement for prior gene