ライフサイエンスコーパス: genetic evolution

1 ation of acclimation, epigenetic effect, and genetic evolution.

2 adgets) evolved through cultural rather than genetic evolution.

3 hly resilient to the immune pressure driving genetic evolution.

4 been suggested to play a significant role in genetic evolution.

5 utations suggesting parallel methylation and genetic evolution.

6 advantage of TP53-mutant cells and promoted genetic evolution.

7 nant progression is characterized by minimal genetic evolution.

8 ering their immune resistance as a result of genetic evolution.

9 els with, as well as clear differences from, genetic evolution.

10 m that of their native range indicates rapid genetic evolution.

11 our model invokes realistic trends of HIV-1 genetic evolution.

12 important similarities in their patterns of genetic evolution.

13 ls can be used to study metastasis and tumor genetic evolution.

14 d among populations, which I call collateral genetic evolution.

15 pports and supplements the standard model of genetic evolution.

16 rapeutics whose efficacy can withstand viral genetic evolution.

17 Kenyan population to profile intrahost viral genetic evolution and adaptations driven by vaccine-indu

18 rating feedback material might influence the genetic evolution and attenuation of PEDV.

19 tudinal patient samples, we further revealed genetic evolution and cell-type plasticity as mechanisms

20 ssibly Alzheimer's disease, but also due its genetic evolution and complex alternative splicing featu

21 utagenic in mammals, perhaps contributing to genetic evolution and disease.

22 Our findings highlight ongoing genetic evolution and high diversity of circulating RSV-

23 ion tumor-sequencing approach highlights the genetic evolution and non-UVB mutational signatures asso

24 orts on the application of WGS to understand genetic evolution and reconstruct transmission pathways

25 e feasible for all felid species, supporting genetic evolution and speciation studies.

26 An important challenge in genetics, evolution and biotechnology is to understand a

27 preeminent model system to understand phage genetics, evolution and ecology in obligate intracellula

28 anism(s) (i.e., phenotypic plasticity and/or genetic evolution) and long-term consequences (e.g., abi

29 Antigenic evolution was more punctuated than genetic evolution, and genetic change sometimes had a di

30 population size and range have affected our genetic evolution, and recent modeling efforts have reaf

31 types has extensive application in microbial genetics, evolution, and biotechnology.

32 rry important implications for complex trait genetics, evolution, and medicine.

33 Studying the genetics, evolution, and neurobiology of acoustic commun

34 ary viral sequence diversity and rapid viral genetic evolution are hallmarks of hepatitis C virus (HC

35 ironment we find (1) a high rate of parallel genetic evolution at orthologous nucleotide and amino ac

36 Furthermore, we uncover evidence of parallel genetic evolution at some loci around optix and WntA in

37 ce has led to many practical applications of genetic evolution but few practical uses of cultural evo

38 al organisms often show evidence of parallel genetic evolution, but the causes are unclear.

39 nd simultaneously characterize antigenic and genetic evolution by modeling the diffusion of antigenic

40 Furthermore, cultural and genetic evolution can interact with one another and infl

41 finding indicates that cultural change, like genetic evolution, can follow theoretically derived patt

42 arious analyses and conclusions pertinent to genetics, evolution, conservation and disease.

43 tion of genetic variants, different rates of genetic evolution could be found under different selecti

44 tween parasite-stress and cultural outcomes: genetic evolution, developmental plasticity, neurocognit

45 ochastic factors and purifying selection for genetic evolution differs over, at least, three broad in

46 istory of extinct species and to investigate genetic evolution directly.

47 pplications are also predicted in population genetics, evolution, earth sciences, and economics.

48 on of proteomics to the fields of behavioral genetics, evolution, ecology and population dynamics, an

49 The genetic evolution from a benign neurofibroma to a malign

50 sts the existence of a right-skewed model of genetic evolution from monoclonal gammopathy of undeterm

51 can we identify the 'smoking guns' of human genetic evolution from neutral ticks of the molecular ev

52 This study advances our understanding of genetic evolution from the perspective of genome archite

53 recent progress in defining the patterns of genetic evolution giving rise to relapse in follicular l

54 Our results suggest that the continuous genetic evolution has not led to significant antigenic d

55 To understand genetic evolution in cancer during metastasis, we analyz

56 Empirically observed neutral genetic evolution in extremely large clonal populations

57 To investigate genetic evolution in high-grade serous (HGS) ovarian can

58 ns contribute disproportionately to parallel genetic evolution in independent dune ecotypes of Helian

59 ionally, neuroplasticity may affect rates of genetic evolution in many ways: for example, decreasing

60 Sequential analysis in del(5q)-MDS revealed genetic evolution in MDS-SCs and MDS-progenitors prior t

61 The probability of parallel genetic evolution is a function of the strength of selec

62 Genetic evolution is constrained by gene function, the s

63 al influenza is generally S-shaped while the genetic evolution is half-circle shaped.

64 This mode of genetic evolution is likely favored by selection because

65 Our findings show that parallel genetic evolution is strongly biased by constraints and

66 tions to adjust to environmental change when genetic evolution is too slow to keep pace.

67 n the S, N, and ORF1a/b genes and showed the genetic evolution landscape of SARS-CoV-2 by comparing w

68 After serial DAA treatment failure, HCV genetic evolution led to a complex genome-wide network o

69 of cultural evolution, inspired by models of genetic evolution, lend support to the former and do not

70 nomic and phylogenetic analyses suggest that genetic evolution may have led to the enhanced virulence

71 n of recent shared ancestry is important for genetics, evolution, medicine, conservation biology, and

72 ng-distance seasonal migration on population genetic evolution occurs through promotion of demographi

73 The genetic evolution of a large population undergoing mutag

74 that Myc and Ras cooperation depends on the genetic evolution of a particular cancer.

75 The genetic evolution of altruism (i.e., a behavior resultin

76 Thus, genetic evolution of arsS may influence progression to h

77 Although human tumours are shaped by the genetic evolution of cancer cells, evidence also suggest

78 evolving cultural traits, together with the genetic evolution of commensals and parasites that have

79 Here we trace the genetic evolution of EBOV in the current outbreak that h

80 f cell-associated viral DNA and mRNA and the genetic evolution of HIV-1 in seven acutely infected pat

81 The genetic evolution of human immunodeficiency virus type 1

82 een humans and mice and has an impact on the genetic evolution of human sex chromosomes.

83 provides evidence for swine in promoting the genetic evolution of influenza A virus and highlights th

84 -existing EGFR(T790M)-positive clones or via genetic evolution of initially EGFR(T790M)-negative drug

85 ccount of mirror neurons should not preclude genetic evolution of its underlying mechanisms.

86 The recent genetic evolution of K. pneumoniae has led to the emerge

87 The study revealed the rapid genetic evolution of M. avium in chronically infected pa

88 populations reunite, even in the absence of genetic evolution of mate preference.

89 selection as a viable strategy for mimicking genetic evolution of materials as it occurs in nature.

90 -tracing approaches developed to unravel the genetic evolution of metastasis.

91 A better understanding of the genetic evolution of metastatic disease has the potentia

92 these model systems, our study examines the genetic evolution of metastatic phenotypes.

93 However, the serial genetic evolution of mutant cancer genes(7,8) and the al

94 and February 2024, to uncover the origin and genetic evolution of OROV in the current outbreak.

95 tributed to the extraordinarily rapid recent genetic evolution of our species.

96 A quantitative analysis of the timing of the genetic evolution of pancreatic cancer was performed, in

97 histocompatibility complex can influence the genetic evolution of pathogenic retroviruses in vivo.

98 findings show that LINE-1 contributes to the genetic evolution of PDAC and suggest that somatic inser

99 Genetic evolution of pneumococcal clones from Taiwan(19F

100 Genetic evolution of secondary AML is a dynamic process

101 We conclude that parallel genetic evolution of separate metastatic sites with diff

102 e epigenetic silencing mechanism impacts the genetic evolution of sex chromosomes and contributed to

103 itical role of persistent replication in the genetic evolution of SIV.

104 curious parallel noted by Darwin between the genetic evolution of species and the cultural evolution

105 invention that could not have influenced the genetic evolution of the cortex.

106 Therefore, the genetic evolution of the M gene in H9N2 virus increases

107 Genetic evolution of the simian immunodeficiency virus (

108 pect to the extent of persistent viremia and genetic evolution of the V1 region of envelope.

109 cancer patients in order to reconstruct the genetic evolution of these viruses.

110 These results suggest that genetic evolution of this common colonic commensal has r

111 We have investigated the genetic evolution of three functionally distinct regions

112 These results shed light on the early genetic evolution of UM and move us closer to a molecula

113 However, the early genetic evolution of UM is poorly understood, and biomar

114 ther tools to study genetic similarities and genetic evolution of viral quasispecies.

115 ired to definitively determine the effect of genetic evolution on the inferred hierarchies.

116 Whether via genetic evolution or dynamic adaptation, many networks c

117 correlation between viral setpoint and HIV-1 genetic evolution over time is important in the understa

118 gests shared adaptive responses via repeated genetic evolution, phenotypic plasticity or both.

119 stimate of the SARS-CoV-2 incidence based on genetic evolution rates.

120 n in the brain progressed with a nonspecific genetic evolution, recurrent migration events, and an ex

121 se animal species, yet how it interacts with genetic evolution remains largely unexplored.

122 arkable correspondence between antigenic and genetic evolution, significant differences were observed

123 logical acclimation, epigenetic effects, and genetic evolution, termed as adaptation.

124 antly more likely to be in earlier stages of genetic evolution than larger tumors.

125 Genetic evolution that occurs during cancer progression

126 Focusing on the evolution of the Earth, genetic evolution, the evolution of the brain, and cultu

127 l be needed to completely characterize human genetic evolution, these uniparentally inherited loci ar

128 Thus, we find adaptive convergent genetic evolution to be a key driver of regulatory chang

129 ks cultural evolution to group selection and genetic evolution to individual selection, this associat

130 n swine in the U.S. is surveilled to monitor genetic evolution to inform intervention efforts and aid

131 more common than note substitutions, unlike genetic evolution where the reverse is true.

132 ad, and can be caused by either (i) parallel genetic evolution, where independently evolved convergen

133 ate rates of CD4 T cell loss correlated with genetic evolution within three of four subjects.