ライフサイエンスコーパス: chromosome engineering

1 be valuable materials for gene targeting and chromosome engineering.

2 6 in mice using Cre/loxP-mediated long-range chromosome engineering.

3 ession, protein localization, epistasis, and chromosome engineering.

4 el of a human deletion syndrome generated by chromosome engineering.

5 s, in vivo synthetic lethality screening and chromosome engineering.

6 s in vertebrates and as a tool for mammalian chromosome engineering.

7 Using a rapid strategy for Cre-loxP chromosome engineering, a deletion of approximately 370

8 (2020) combine in vivo chromosome engineering and Drosophila genetics to assess

9 nt on the X chromosome of D. melanogaster by chromosome engineering and found that, although the dele

10 is possible to use retroviral gene delivery, chromosome engineering and inducible transgenes to selec

11 Here we have used a combination of chromosome engineering and P1 artificial chromosome tran

12 As new technologies such as chromosome engineering and the creation of transchromoso

13 ation methods in plants will potentiate many chromosome engineering applications.

14 Recent advances in chromosome engineering are now allowing us to create pre

15 We then discuss how promoter editing and chromosome engineering are used in crop breeding for tra

16 the vector can be used for Cre- loxP -based chromosome engineering as well as single knockouts.

17 ch expands the application of Cre-loxP-based chromosome engineering because it not only allows the co

18 In vivo chromosome engineering can be potentially used to achiev

19 have developed three new mouse models using chromosome engineering carrying the genotypes of Dp(10)1

20 Chromosome engineering combines the power of gene target

21 The term "chromosome engineering" describes technologies in which

22 Here, we report an improved scheme of chromosome engineering for efficient elimination of a la

23 Targeted chromosome engineering has facilitated the development o

24 ions, and inversions) into the mouse genome (chromosome engineering) has been established.

25 tion system has been developed for efficient chromosome engineering in Escherichia coli by using elec

26 a highly efficient recombination system for chromosome engineering in Escherichia coli was described

27 is study has demonstrated great potential of chromosome engineering in genome manipulation for plant

28 Chromosome engineering in mice enables the construction

29 Here we use chromosome engineering in mice to show that a single ext

30 9 multiplexing, as well as opportunities for chromosome engineering in the context of hepatobiliary t

31 These developments permit faithful chromosome engineering in the context of metazoan cells.

32 Chromosome engineering is a major focus in the fields of

33 Chromosome engineering is a useful strategy for transfer

34 his system will be especially useful for the chromosome engineering of large heterologous fragment in

35 at-A. comosa chromosome translocations using chromosome engineering procedures.

36 Chromosome engineering produces a reduced eight-chromoso

37 The results will facilitate directed chromosome engineering producing agronomically desirable

38 e a public resource (Mutagenic Insertion and Chromosome Engineering Resource; MICER) for high-through

39 We used mutagenic insertion chromosome engineering resources to generate the Plp1dup

40 We have developed a chromosome engineering strategy that allows the generati

41 We have used a mouse chromosome engineering strategy to create a null mutatio

42 We have used a chromosome engineering strategy to identify a human auto

43 Finally, using a chromosome engineering strategy, we show that only a sub

44 Another chromosome engineering success is the conversion of meio

45 Here, we report a chromosome engineering system for neocentromere formatio

46 des a basis to use autopolyploidization as a chromosome engineering technique to alter the organ deve

47 Here, using chromosome engineering technology, we delete in the germ

48 This new form of chromosome engineering, termed recombineering, has many

49 This review examines recent innovations in chromosome engineering that promise to greatly increase

50 We used chromosome engineering to create mice that were trisomic

51 -2 and Df(11)17-3] using retrovirus-mediated chromosome engineering to create nested deletions.

52 cause DS phenotypes, including CHD, we used chromosome engineering to generate a mapping panel of 7

53 egion further, we utilized Cre-loxP-mediated chromosome engineering to generate a targeted 800 kb del

54 16p11.2 CNVs in a systematic manner, we used chromosome engineering to generate mice harboring deleti

55 Here we use chromosome engineering to generate mouse models with gai

56 ring germ cell development, we used targeted chromosome engineering to generate mutants which either

57 In particular, the use of chromosome engineering to generate new trisomic mouse mo

58 etween homoeologues and is routinely used in chromosome engineering to introgress alien variation int

59 We have used chromosome engineering to replace native centromeric DNA

60 loid cells using CRISPR Targeting), a set of chromosome engineering tools that allow us to eliminate