ライフサイエンスコーパス: transferred DNA

1 tiation of complementary strand synthesis on transferred DNA.

2 cause of the increased nuclear import of the transferred-DNA.

3 This report identifies intergenerically transferred DNA and its source in bacteria, and further

4 athogens, albeit with much less horizontally transferred DNA and lacking 357 genes present in E. coli

5 tion factors and thereby silencing laterally transferred DNA and protecting the genome against double

6 The transferred DNA appears to be intact in the majority of

7 ssion, rather than differential selection of transferred DNA, as an explanation of observed phylogene

8 TnERL, a Bacteroides conjugative transposon, transferred DNA by an Hfr-type mechanism during conjugat

9 ther show how a template DNA provided on the transferred DNA can be used to introduce specific mutati

10 e VirD2 protein and, consequently, the VirD2/transferred DNA complex.

11 The guide RNA can also be encoded by the transferred DNA, enabling its production in the recipien

12 This transferred DNA encodes the synthesis of indole acetic a

13 sferring and integrating an oncogenic T-DNA (transferred DNA) from its tumor-inducing (Ti) plasmid in

14 Each cell containing the newly transferred DNA has a very high selective advantage unti

15 r complementary strand synthesis of incoming transferred DNA in E. coli, while plasmid-specific mecha

16 Transferred DNA insertion lines exhibited consistent def

17 psis (Arabidopsis thaliana) sequence-indexed transferred DNA insertion mutants, we found disruption o

18 Analysis of two independently generated transferred DNA insertional lines in PTD showed that the

19 d that Arabidopsis thaliana plants harboring transferred DNA insertional mutations in the sole protot

20 ntified mutant Arabidopsis plants containing transferred DNA insertions in the gene encoding a phloem

21 We transferred DNA into a second recipient strain (E. faeci

22 regulon once it has fulfilled its mission to transferred DNA into plant cells.

23 ms plants by transferring and integrating T-(transferred) DNA into the host genome.

24 Physiological analysis of a transferred DNA knockout mutant for AtALMT1 as well as e

25 ic enterics in having an island of laterally transferred DNA next to mutS.

26 ens transfers a piece of its Ti plasmid DNA (transferred DNA or T-DNA) into plant cells during crown

27 reas the second class includes insertions of transferred-DNA or transposon elements.

28 d from microspores transfected with the full transferred DNA/protein complex.

29 The transferred DNA sequences (T-DNA regions) are delimited

30 or perhaps ligation of the ends of the newly transferred DNA strand.

31 e recipient cell, covalently attached to the transferred DNA strand.

32 Successful transport of the transferred DNA (T-DNA) and integration of the DNA into

33 transform plants, Agrobacterium exports its transferred DNA (T-DNA) and several virulence (Vir) prot

34 The integration of transferred DNA (T-DNA) and the formation of complex ins

35 gall tumors on various plants by delivering transferred DNA (T-DNA) and virulence proteins into host

36 Before the bacterial transferred DNA (T-DNA) can integrate into the plant gen

37 ng a single-stranded DNA (ssDNA) copy of the transferred DNA (T-DNA) element, the T-strand, in a comp

38 cells, the bacterium exports a well defined transferred DNA (T-DNA) fragment and a series of virulen

39 a single-stranded (ss) copy of the bacterial transferred DNA (T-DNA) from its Ti (tumor-inducing) pla

40 asmid-encoded bacterial genes located on the transferred DNA (T-DNA) in the plant genome.

41 Over 225,000 independent Agrobacterium transferred DNA (T-DNA) insertion events in the genome o

42 Integration of Agrobacterium tumefaciens transferred DNA (T-DNA) into the plant genome is the las

43 The transferred DNA (T-DNA) is stably inherited and expresse

44 flowering, while co-suppression lines and a transferred DNA (T-DNA) knockout line showed earlier flo

45 The transferred DNA (T-DNA) of Agrobacterium tumefaciens ser

46 The transferred DNA (T-DNA) portion of the Agrobacterium tum

47 Analysis of Agrobacterium-transferred DNA (T-DNA) revealed strong correlations bet

48 mutants correlated with the loss and gain of transferred DNA (T-DNA) transfer functions, which is con

49 Agrobacterium tumefaciens transferred DNA (T-DNA) transfer requires that the virul

50 ium tumefaciens delivers its single-stranded transferred DNA (T-strand) into the host cell nucleus, w

51 The rcn1 mutation was transferred-DNA (T-DNA) tagged and sequences flanking th

52 right border of the tumor-inducing plasmid's transferred-DNA (T-DNA), suggesting bona fide T-DNA tran

53 teria translocate an oncogenic piece of DNA (transferred DNA, T-DNA) into plant cells at the infectio

54 ld result in the preferential degradation of transferred DNA that had not been properly cleaved in th

55 hes developed over the past decade to detect transferred DNA that may be involved in adaptation to ne

56 virB operon is required for the transfer of transferred DNA to the plant host, and the trb system en

57 in vitro-prepared nano-complex consisting of transferred DNA, virulence protein D2, and recombination

58 A donor, the estimated minimal length of the transferred DNA was > or = 123 kb in one recombinant but