ライフサイエンスコーパス: genetic process

1 The formation of crossovers is a fundamental genetic process.

2 ly, its shape reflects underlying population genetic processes.

3 strands, is crucial in modulating a host of genetic processes.

4 e critical to the regulation of cellular and genetic processes.

5 tween natural selection and other population genetic processes.

6 biomolecular "switches", regulating various genetic processes.

7 irm its relation to certain pathological and genetic processes.

8 from the passenger strand may regulate many genetic processes.

9 erstanding the molecular mechanisms of these genetic processes.

10 s interfering with DNA replication and other genetic processes.

11 tous phenomenon which is critical in various genetic processes.

12 -binding proteins, feature in many regulated genetic processes.

13 ecule is often crucial for the regulation of genetic processes.

14 Population genetic processes also affect the evolution of genomes.

15 Instead, the code may be a record of genetic process and patterns of mutation before the radi

16 ges play central roles in a great variety of genetic processes and increase the rate of evolutionary

17 We sought to identify the population genetic processes and molecular genetic events that caus

18 refore, a better understanding of population genetic processes and their effect on biogeography is ne

19 vitable consequence of complex developmental-genetic processes and thus requires no explanation in te

20 scent with modification, that evolution is a genetic process, and that humans are closely related to

21 e foundation for deeper understanding of the genetic processes behind M. robertsii adaptive phenotype

22 ragmentation of parasites and the population genetics processes behind their diversification in an ef

23 long-term monitoring of different molecular-genetic processes by nuclear imaging techniques in human

24 disequilibrium generated by other population genetic processes by virtue of being nonoverlapping as w

25 s show that other demographic and population genetic processes can account for this observation, thes

26 rstanding these organism-level and molecular genetic processes can be used for crop plant improvement

27 Two distinct population genetic processes can produce ecological specialization-

28 ed a new understanding of the historical and genetic processes crucial to rapid phenotypic evolution

29 Regulation of fundamental genetic processes demands dynamic participation of trans

30 f natural selection, but do these population-genetic processes drive the movement of genes to the nuc

31 ation where it modulates both epigenetic and genetic processes engaged by cocaine.

32 taxa to be made, as some of the fundamental genetic processes for constructing the trunk segments ar

33 ested for PET imaging of different molecular-genetic processes for potential clinical use.

34 We show that the ancestral genetic process in a large population without recombinat

35 ued research on the cellular, molecular, and genetic process in tumorigenesis is rapidly evolving.

36 As understanding of molecular and genetic processes in cancer evolves, so does appreciatio

37 y independent roles for both demographic and genetic processes in driving colonisation success.

38 t approach for multimodal in vivo imaging of genetic processes in the vasculature.

39 Understanding of cellular, molecular, and genetic processes in tumorigenesis is evolving rapidly.

40 is increased understanding of molecular and genetic processes in tumorigenesis.

41 me are critical to understanding fundamental genetic processes including cell division and gene regul

42 on (HJ) is a central intermediate in various genetic processes including homologous and site-specific

43 unction is a central intermediate in various genetic processes including homologous, site-specific re

44 on (HJ) is a central intermediate of various genetic processes, including homologous and site-specifi

45 In this review, it is argued that many genetic processes, including ploidy, dominance, heritabi

46 proximately 450 million years ago as a rapid genetic process independent of antigenic selection.

47 de insights into the regulatory mechanism of genetic processes involving HJs.

48 embrane proteins were produced by a two-step genetic process, involving cloning of Omp genes in V. ch

49 The population-genetic processes leading to the genetic degeneration of

50 atest challenges in biology, because it is a genetic process much more important than thought at the

51 regulate these intracellular biochemical and genetic processes remain to be fully understood.

52 Genetic processes require direct interactions between pr

53 his organization is likely to influence many genetic processes, requiring access to the underlying DN

54 the initial groundwork for understanding the genetic processes responsible for triplet repeat mutatio

55 on while remaining fully permissive to other genetic processes such as recombination or integration.

56 r homologous genetic recombination and other genetic processes such as replication and repair.

57 supercoiling plays an important role in many genetic processes such as replication, transcription, an

58 interpreting the data in terms of population genetics processes such as genetic drift, balancing and

59 evolution that combines both demographic and genetic processes, such as gene flow and migration, gene

60 Furthermore, population genetic processes, such as selective sweeps, background

61 Homologous recombination is a universal genetic process that plays multiple roles in the biology

62 nkage disequilibrium, reviews the population genetic processes that affect it and describes some of i

63 d offer a good opportunity to understand the genetic processes that allow the maintenance of polymorp

64 dels of the interplay between nongenetic and genetic processes that contribute to the emergence of dr

65 d to fundamental insights into the molecular genetic processes that govern cancer initiation, progres

66 erns they observe in terms of the population genetic processes that have given rise to them; here, th

67 an be divided into two categories: intrinsic genetic processes that lead to the preferential rearrang

68 ological diversity in animals and one of the genetic processes that might have contributed to this is

69 ps between species, to expose the population-genetic processes that operate along its branches.

70 In order to gain better insight into the genetic processes that underlie variation in complex phe

71 r in disease genes expand by a non-Mendelian genetic process to cause several human hereditary syndro

72 the possible contribution of epigenetic and genetic processes to these irreversible changes.

73 Whether or not these population genetic processes translate to more species at macroevol

74 germ-line and somatic events have elucidated genetic processes underlying premalignant progression an

75 rofit from a new focus on the search for the genetic processes underlying specific cognitive function

76 The results shed light on the population genetic processes underlying the formation of nascent sp

77 , and in our understanding of the population genetic processes which are involved in their evolution.