ライフサイエンスコーパス: origin of life

1 has become a key unanswered question in the origin of life.

2 entory with left-handed molecules before the origin of life.

3 believed to have been a key event during the origin of life.

4 grated behaviors was a crucial aspect of the origin of life.

5 tifying in its implications for the chemical origin of life.

6 e patterns, we attempt to glance at the very origin of life.

7 ts, where they may have played a role in the origin of life.

8 d to the organic inventory necessary for the origin of life.

9 tions for organic chemical evolution and the origin of life.

10 and thus possibly played a vital role in the origin of life.

11 catalysts available at an early stage in the origin of life.

12 two hydrophobic faces, was essential to the origin of life.

13 unlikely that cytosine played a role in the origin of life.

14 an RNA-like substance, played a role in the origin of life.

15 for this enzyme in the proposed autotrophic origin of life.

16 ating peptides may have played a role in the origin of life.

17 biomedical utility and implications for the origin of life.

18 0(6) yr) to be involved in a low-temperature origin of life.

19 and are thought to have been crucial for the origin of life.

20 n the origin of metabolism, and probably the origin of life.

21 nce on organic chemical evolution before the origin of life.

22 ave been a critical process required for the origin of life.

23 able C1 feedstock molecule is crucial to the origin of life.

24 mperature gradients might play a role in the origin of life.

25 isms that must have been available since the origin of life.

26 and have been implicated in theories of the origin of life.

27 communities and their potential role in the origin of life.

28 ns a mystery in the puzzle to understand the origin of life.

29 cation is considered a key transition in the origin of life.

30 ctions, and possibly virus evolution and the origin of life.

31 ng been sought by chemists interested in the origin of life.

32 lusion with significant implications for the origin of life.

33 onucleic acid (RNA) at an early stage in the origin of life.

34 to be involved in chemical evolution and the origin of life.

35 idy, genomic complexity, speciation, and the origin of life.

36 tion with their possible contribution to the origin of life.

37 plets is considered an essential step in the origin of life.

38 ng the possible pathways responsible for the origin of life.

39 for nonenzymatic RNA replication during the origin of life.

40 of potential relevance to understanding the origin of life.

41 and would seem to be a prerequisite for the origin of life.

42 mond Bernal proposed a role for clays in the origin of life.

43 ally with population density since the early origins of life.

44 possible progenitor candidates of RNA in the origins of life.

45 create novel proteins and to understand the origins of life.

46 n evolutionary development as ancient as the origins of life.

47 have made a significant contribution to the origins of life.

48 aqueous conditions is a critical step in the origins of life.

49 ate problem in the "RNA first" model for the origins of life.

50 igomers that would have played a role in the origins of life.

51 biosphere, and may have implications for the origins of life.

52 tion have the potential to shed light on the origins of life.

53 nvestigate various scenarios relevant to the origins of life.

54 arly relevant to prebiotic chemistry and the origins of life.

55 solutions to many basic questions about the origins of life.

56 At some stage in the origin of life, an informational polymer must have arise

57 cycles, and their potential to inform on the origin of life and its potential outside of Earth.

58 and polypeptides was a key transition in the origin of life and remains at the heart of all biology.

59 The finding provides insights into both the origin of life and the potential threat posed by pathoge

60 kely to have played an important role in the origin of life, and a small number of fully synthetic se

61 e compartments is a central question for the origin of life, and has technological repercussions in d

62 forces will have been omnipresent since the origin of life, and living organisms have evolved mechan

63 role in hydrothermal redox chemistry at the origin of life, and materials applications that utilize

64 The implications of this study in the origin of life are discussed.

65 Circadian rhythms date back to the origins of life, are found in virtually every species an

66 A) have been invoked as key reagents for the origin of life as activated forms of acetate analogous t

67 In the traditional concept for the origin of life as proposed by Oparin and Haldane in the

68 cal evidence for the physical setting of the origin of life because there are no unmetamorphosed rock

69 thought to be an unlikely mechanism for the origins of life because of unfavourable chemical conditi

70 es support for the involvement of RNA in the origin of life, but such support would be considerably s

71 s pioneered modern research on the molecular origins of life, but their actual relevance in this fiel

72 uch forces may have been instrumental in the origin of life by driving a primitive form of self-repli

73 urrent experiments with implications for the origin of life, emphasizing the ability of unexpected ph

74 This latter could not occur in an anoxic, "origin of life" environment.

75 when evaluating their potential roles in the origin of life, extant biology, or biotechnology.

76 nt a current view of the biochemistry of the origin of life, focusing on issues surrounding the emerg

77 arth's water is central to understanding the origins of life-fostering environments and to assessing

78 discipline that sought explanations for the origins of life from chemical and physical first princip

79 rebiotic organic molecules important for the origins of life from impacts of carbonaceous asteroids a

80 A high-temperature origin of life has been proposed, largely for the reason

81 The origin of life has puzzled molecular scientists for over

82 nt synthetic approaches to understanding the origin of life have yielded insights into plausible path

83 e Earth's surface, and is central to current origin of life hypotheses as well as the search for micr

84 step in quantifying and thus testing various origin-of-life hypotheses regarding the origin and evolu

85 ation flowed symmetrically in the era of the origin of life, i.e. the primitive translation machinery

86 e reaction conditions are compatible with an origin of life in volcanic-hydrothermal sub-seafloor flo

87 p focus discussion on open questions for the origins of life in a planetary context.

88 is profoundly contingent in that independent origins of life in the universe will spawn radically dif

89 loor, this process might be relevant, at the origin of life, in an RNA world hypothesis.

90 e components have properties relevant to the origin of life, including the ability to self-assemble i

91 s in particular transformed the study of the origin of life into a respectable field of inquiry and e

92 The origin of life is also the origin of evolution.

93 nt obstacle to the "RNA-first" model for the origin of life is an inability to generate reasonable "h

94 The concept of an RNA world in the chemical origin of life is appealing, as nucleic acids are capabl

95 The origin of life is believed to have progressed through an

96 scribed, and their possible relevance to the origin of life is discussed.

97 A critical event in the origin of life is thought to have been the emergence of

98 nce of our calculations to understanding the origins of life is discussed.

99 ential significance of these findings to the origins of life is discussed.

100 rsal chart of pathways may be central to the origin of life, is emergent from organic chemistry, and

101 In order to approach the problem of the origin of life it is therefore reasonable to start from

102 In studying the origins of life, it is important to examine reactions of

103 ution of respiratory systems but also in the origin of life itself.

104 100 yr), we conclude that a high-temperature origin of life may be possible, but it cannot involve ad

105 sly been investigated for their relevance to origin-of-life models.

106 Therefore, any theory for the origin of life must address the emergence of such a syst

107 During the origin of life, mutation rates are thought to have been

108 One possible definition for the origin of life on Earth is the time at which the interva

109 The origin of life on Earth was a chemical affair.

110 across a membrane was a critical step at the origin of life on earth, and it is still performed in al

111 ch are believed to have been critical to the origin of life on Earth, remain important in physiology

112 organic compounds that played a role in the origin of life on Earth.

113 Synthetic life: the origin of life on the early Earth, and the ex novo trans

114 ess in the Solar System that may predate the origin of life on the Earth.

115 Understanding the origins of life on Earth guides our search for life else

116 The origins of life on Earth required the establishment of s

117 e thought to be essential to elucidating the origins of life on Earth.

118 gical processes and to better understand the origins of life on Earth.

119 ent of an RNA world and other models for the origins of life on Earth.

120 planet formation and may eventually seed the origins of life on nascent planets.

121 ould have existed in an RNA world during the origins of life on the Earth.

122 Such a scenario is interesting from an origins of life perspective because a rudimentary form o

123 as RNA is considered a key transition in the origin of life, pre-dating the appearance of protein enz

124 is thought to have played a key role in the origin of life prior to the evolution of ribozyme-cataly

125 made on parameter estimation for determining origins of life probabilities, based on constraints from

126 vational routes for improving constraints on origins of life probabilities.

127 The origin-of-life problem has been traditionally conceived

128 The origin-of-life quest has long been split into several at

129 anide (HCN) is believed to be central to the origin of life question.

130 Theories for the origin of life require the availability of reduced (or '

131 But the origin of life required, owing to conformational constra

132 ch as this will be increasingly necessary as origins-of-life researchers move toward systems-level in

133 rding to a current "RNA first" model for the origin of life, RNA emerged in some form on early Earth

134 ose the concept of a ribofilm in which RNA's origin-of-life role is more akin to a slowly changing pl

135 nant of peptide structure and activity in an origins-of-life scenario.

136 Many origins-of-life scenarios depict a situation in which th

137 All scientific approaches to the origin of life share a common problem: a chemical path t

138 will be close to a full understanding of the origin of life, so the future of research in this field

139 Origins of life studies represent an exciting and highly

140 Contemporary research into the origins of life subscribes to the Darwinian principle of

141 To address central problems in the origin of life such as the formation of linear polymers

142 Most models of the origin of life suggest organisms developed from environm

143 To study the origin of life, synthetic biologists construct simple 'p

144 uld have been a more favorable place for the origin of life than previously thought.

145 During the origin of life, the biological information of nucleic ac

146 hetic drugs to biodegradable plastics to the origin of life, the chiral selection of molecules presen

147 cs of chemical reactions associated with the origin of life, the energetics of early metabolisms, and

148 ortance of molecular self-replication in the origin of life, the feasibility of peptide self-replicat

149 Because of its importance for the origin of life, the nonenzymatic copying of RNA template

150 an say nothing about the temperatures of the origin of life, the RNA world, and organisms preceding t

151 High-temperature origin-of-life theories require that the components of t

152 tion encoded in their genomes, and since the origin of life this information has been encoded using a

153 Therefore, unless the origin of life took place extremely rapidly (<100 yr), w

154 A crucial transition in the origin of life was the emergence of an informational pol

155 emergence of functional sequences during the origin of life would be possible even in the face of the

156 chemical homochirality was a key step in the origin of life, yet prebiotic mechanisms for chiral sepa