ライフサイエンスコーパス: self-replication

1 , producing more compartments with increased self-replication.

2 mal scheduling naturally emerges in cellular self-replication.

3 es), an important stepping stone towards RNA self-replication.

4 e sequences have the property of spontaneous self-replication.

5 emonstrated how this system can give rise to self-replication.

6 pic properties and are capable of continuous self-replication.

7 eriodic behavior with fundamental aspects of self-replication.

8 etic restriction and capacity for autonomous self-replication.

9 ing on nucleic acid polymers, allowing their self-replication.

10 ing of complex cellular behaviors, including self-replication.

11 nitial darwinian selection was for molecular self-replication.

12 independent of any genomic functions beyond self-replication.

13 s increased sensitivity, responsiveness, and self-replication.

14 exponential growth of ribozymes that undergo self-replication.

15 can lead to increased responsiveness and to self-replication.

16 the smallest known microorganisms capable of self-replication.

17 ate would not have led to the termination of self-replication.

18 plex beyond its CAC, leading to the onset of self-replication.

19 talyze a critical reaction for prebiotic RNA self-replication according to the RNA world hypothesis.

20 ors with the high specificity, low cost, and self-replication and -repair of biocatalysts.

21 etabolites and processing units required for self-replication and additionally requiring that these p

22 e type of molecule was supposedly capable of self-replication and chemical catalysis.

23 Self-replication and evolution under selective pressure

24 gence of an informational polymer capable of self-replication and its compartmentalization within pro

25 re the cellular regulation of conformational self-replication and its phenotypic effects, we analyzed

26 lls must select between alternative fates of self-replication and lineage commitment during continuou

27 Examples include self-replication and molecular machines.

28 turational lineage stages and yet capable of self-replication and multipotent differentiation, being

29 prebiotic synthesis to the emergence of RNA self-replication and precellular Darwinian evolution.

30 ny of the putative processes associated with self-replication and self-reproduction.

31 Given that molecular self-replication and the capacity for selection are nece

32 inimum with blood cells, have a low level of self-replication, and depend on CSF-1.

33 tributed over its surface, and the rules for self-replication are encoded into the specificity and st

34 icated that the new beta-cells were not from self-replication but arose through differentiation of po

35 Conditions under which self-replication can be significantly more effective und

36 Using compartmentalized self-replication (CSR), we evolved a version of Pyrococc

37 Optimal self-replication does not require constant energy expend

38 ivo favors differentiation at the expense of self-replication, eventually resulting in a complete los

39 Self-replication has also been implemented with syntheti

40 Self-replication has been demonstrated in synthetic chem

41 e origin of life, the feasibility of peptide self-replication has not been established experimentally

42 g the smallest and simplest cells capable of self-replication, has a distinct cellular polarity chara

43 Mechanisms of molecular self-replication have the potential to shed light on the

44 persistent when released from cells with no self-replication in graywater.

45 An exciting next step would be to use self-replication in materials fabrication, which require

46 ns of our experiments for the possibility of self-replication in the 3'-NP-DNA and RNA systems.

47 despite the central importance of molecular self-replication in the origin of life, the feasibility

48 Bacterial self-replication is a complex process composed of many d

49 Self-replication is a fundamental concept.

50 Self-replication is a remarkable phenomenon in nature th

51 Self-replication is an essential attribute of life but t

52 The emergence of an RNA catalyst capable of self-replication is considered a key transition in the o

53 vity are compromised to the extent that full self-replication is inefficient.

54 cence, which leads to a diminished beta-cell self-replication, massive depletion of the pancreatic is

55 w, suggesting that there may be undiscovered self-replication mechanisms possible in much simpler sys

56 nd microorganisms, and could have driven the self-replication of a protobiont.

57 Here we describe the autonomous self-replication of a reconfigurable string of parts fro

58 er liver injury, regeneration occurs through self-replication of hepatocytes.

59 results demonstrate that TPO can mediate the self-replication of HSC in LTBMC, and provide proof that

60 ng orthogonal from each other: autocatalytic self-replication of oligomers from native monomers and n

61 s of such fundamental biological behavior as self-replication of structural elements and preservation

62 Increased self-replication of T cells in RA was indicated by age-i

63 rocesses to facilitate the self-assembly and self-replication of the first biological systems.

64 Self-replication of the most primitive HSC produces daug

65 protein-only inheritance requires efficient self-replication of the underlying conformation.

66 amic combinatorial library (DCL) may lead to self-replication of this molecule.

67 infection or inflammatory reactions, besides self-replication of tissue resident macrophages.

68 nd control molecular association, catalysis, self-replication or other chemical processes.

69 , temporally regulated viral expression, and self-replication proceeding to infection of new cells.

70 The self-replication process displays parabolic growth patte

71 ditional template units for the nucleic acid self-replication process, resulting in the ultrasensitiv

72 tion of a hydrophobic pocket in water, (iii) self-replication properties and (iv) allosteric properti

73 Hence, any consideration of self-replication raises one of the most profound questio

74 Cellular self-replication requires not only duplicating all cellu

75 The resulting self-replication scheme is a hypercycle, and computer si

76 Tfl (Thermus flavus)) and compartmentalized self-replication selection, we have evolved polymerases

77 re we describe short-patch compartmentalized self-replication (spCSR), a novel strategy to expand the

78 Feeders of angioblasts yielded self-replication, stellate cell precursors caused lineag

79 hBTSCs were similar in vitro with respect to self-replication, stemness traits, and multipotency.

80 cular recognition principles common to model self-replication systems in chemical biology.

81 l that ES cells have an innate programme for self-replication that does not require extrinsic instruc

82 what is probably the most iconic example of self-replication--the ability of a system to replicate,

83 ere is a reasonably wide parameter range for self-replication, there is a subtle balance between the

84 s of beta-cells predominantly occurs through self-replication; therefore, understanding the regulatio

85 rigin of life by driving a primitive form of self-replication through fragmentation.

86 In particular, self-replication through RNA-catalysed templated RNA syn

87 not only remained intact but were capable of self-replication using native monomers as the substrate.

88 The possibility of optimizing self-replication was explored by controlling the frequen

89 the consequences of hematopoietic stem cell self-replication will assist in the development of new a

90 itical aggregation concentration (CAC), then self-replication will not occur.

91 smallest and simplest known cells capable of self-replication, yet it has a complex architecture with