ライフサイエンスコーパス: lysogenic

1 al hosts temperate phages must chose between lysogenic and lytic developmental strategies.

2 5 encodes DNA methyltransferases in both the lysogenic and replication modules within its genome.

3 acterial filamentation and initiate lysis in lysogenic bacteria corroborates the hypothesis that the

4 Treatment of lysogenic bacteria with this compound resulted in lysis

5 by two proteins (PblA and PblB) encoded by a lysogenic bacteriophage (SM1).

6 haryngeal cells resulted in the induction of lysogenic bacteriophage as well as the phage-associated

7 dence suggests that salt stress induces this lysogenic bacteriophage by interfering with 434 represso

8 phiSa3ms, a lysogenic bacteriophage encoding the staphylococcal ente

9 The lysogenic bacteriophage MAV1 has been shown to be a viru

10 The lysogenic bacteriophage MAV1, which is associated with t

11 The role lysogenic bacteriophage play in the pathogenesis of the

12 s mediated in part by a lysin encoded by the lysogenic bacteriophage SM1.

13 in demonstrated it to be encoded by the same lysogenic bacteriophage which harbors speC.

14 CTXphi is a filamentous, lysogenic bacteriophage whose genome encodes cholera tox

15 solate of Vibrio cholerae O139 a filamentous lysogenic bacteriophage, choleraphage 493, which inhibit

16 olera, is only pathogenic when it contains a lysogenic bacteriophage, CTXphi, that encodes the toxin

17 indicate that PblA and PblB are encoded by a lysogenic bacteriophage, which could facilitate the diss

18 Lysogenic bacteriophages are major vehicles for the tran

19 Lysogenic bacteriophages may encode enzymes that modify

20 rica, and Vibrio cholerae, are infected with lysogenic bacteriophages that contribute significantly t

21 Lysogenic bacteriophages therefore play a crucial role i

22 ctors were delivered to the cytoplasm of non-lysogenic C. diphtheriae, they integrated into either th

23 involved in DNA metabolism, integration, and lysogenic control.

24 ain-containing proteins possibly involved in lysogenic control.

25 by using animal models, we demonstrated that lysogenic conversion can take place in the mouse respira

26 rvival and pathogenicity of their hosts, via lysogenic conversion factors, and in nutrient redistribu

27 cCD phenocopies, so GamL and Agt are part of lysogenic conversion.

28 In its normal lysogenic cycle, AAV integrates at a site on human chrom

29 hereas it remains the same during the entire lysogenic cycle.

30 enes, indicating its potential to involve in lysogenic cycle.

31 tion of the BTP1 phage O-antigen receptor in lysogenic D23580, and thereby prevents superinfection by

32 The lytic-lysogenic decision in bacteriophage 186 is governed by t

33 eeded to understand the drivers of the lytic-lysogenic decision in viral communities and to test mode

34 a wild-type R17 operator site and undergoes lysogenic development following infection of susceptible

35 22R17, an RNA challenge phage that undergoes lysogenic development in bacterial cells that express th

36 However, the sigE gene was required for lysogenic development of the temperate cyanophage A-4L.

37 nes the phage's choice between the lytic and lysogenic development pathways.

38 During both lytic and lysogenic development, Mx8 expresses a nonessential DNA

39 temperate lambdoid bacteriophage P22 to the lysogenic developmental pathway.

40 at the same relative location as CUS-1; both lysogenic E. coli and Y. pestis strains produce particle

41 romosome, transgenes can be moved into other lysogenic E. coli strains using standard phage-mediated

42 hage stability but also is a requirement for lysogenic establishment.

43 ther of the developmental pathways (lytic or lysogenic) expected of a lambda virion.

44 a key decision between two states: lytic and lysogenic fate.

45 f V. mimicus for the presence of CTXPhi, the lysogenic filamentous bacteriophage that carries the cho

46 CTXphi is a lysogenic filamentous bacteriophage that encodes cholera

47 regulated pilus, which is encoded by another lysogenic filamentous bacteriophage, VPIPhi, was also pr

48 the genome of CTXphi, a V. cholerae-specific lysogenic filamentous bacteriophage.

49 CTXphi is a lysogenic, filamentous bacteriophage.

50 that these mutants, for lack of poly P, are lysogenic for P1 and when infected with phage P1 produce

51 B. subtilis 168 strains that are lysogenic for the SPbeta bacteriophage produce sublancin

52 sultant ampicillin-resistant E. coli strains lysogenic for these phages produced infectious H-19B par

53 gy introduced by Kelly to derive the optimal lysogenic fraction of the total population of phages as

54 During lysogenic growth many temperate bacteriophage genomes ar

55 switch' enables the phage to transition from lysogenic growth to lytic development when triggered by

56 ns at key loci controlling host recognition, lysogenic growth, and possibly host phenotypic modificat

57 ich in viral functions required in lytic and lysogenic growth, as well as unexpected functions such a

58 ut down expression of its lytic genes during lysogenic growth.

59 enes that provide a fitness advantage to the lysogenic host.

60 ic, causing destruction of the host cell, or lysogenic, in which the viral genome is instead stably m

61 es indiscriminate immunity both to lytic and lysogenic infection by temperate phages-compromising the

62 We observed that lysogenic infection of Pseudomonas aeruginosa PA14 with

63 morphology, toxin production, and lytic and lysogenic infection profiles on O157 and non-O157 seroty

64 Two Bacillus subtilis lysogenic libraries were probed by an antibody specific

65 genomes of bacteriophages adopting a pseudo-lysogenic life cycle.

66 r establishment and termination of the viral lysogenic life cycle.

67 To establish a lysogenic lifestyle, the temperate bacteriophage phiC31

68 lts, transcriptional regulation for lambda's lysogenic/lytic switch includes both activation and repr

69 elieved to be regulated by two proteins; the lysogenic maintenance promoting protein CI and the early

70 original host to either inefficient lytic or lysogenic on an alternative host.

71 anism for development of Mu along either the lysogenic or lytic pathway.

72 The fraction of infected cells selecting the lysogenic pathway at different phage:cell ratios, predic

73 a coli cell, after which either a lytic or a lysogenic pathway is followed, resulting in different ce

74 cycle, irrespective of whether the lytic or lysogenic pathway is followed; hence, cell-fate decision

75 within fnbA and fnbB, (iv) the presence of a lysogenic phage within hlb, and (v) the sizes of the res

76 the combination of stx2 alleles (carried on lysogenic phages) and/or the amount of Stx2 made by that

77 proteins resembling structural components of lysogenic phages.

78 ous brown algae have a circular genome and a lysogenic phase in their life cycle.

79 ypes 3, 4, and 24) that differed only by the lysogenic presence of the MM1-1998 phage and did a pheno

80 s known already to enhance repression at the lysogenic promoter PRM, located at OR.

81 sting that the role of alphaCTD at the three lysogenic promoters may be different.

82 The above results were obtained with a lysogenic recipient strain which represses expression of

83 provide a molecular basis for understanding lysogenic regulation in 186.

84 Purified Mu lysogenic repressor (c) also bound to Pm, overlapping th

85 e tail protein of the biologically unrelated lysogenic salmonella phage P22.

86 The lysogenic siphophage varphi11 infects S. aureus SA113.

87 One natural isolate of M. xanthus, the lysogenic source of related phage Mx81, produces a restr

88 Surprisingly, both lytic and lysogenic Spn1 genes were expressed under routine growth

89 d that it affords increased stability to the lysogenic state in response to environmental variations.

90 Stability and induction of the lysogenic state of bacteriophage lambda are balanced by

91 The lysogenic state of bacteriophage lambda is exceptionally

92 The lysogenic state of bacteriophage lambda is maintained by

93 The lysogenic state of phage lambda is maintained by the CI

94 Here we analyze the stability of the lysogenic state of phage lambda.

95 , Stk may be produced by the prophage in the lysogenic state, and, like the YpkA protein of Yersinia

96 ession of the lytic genes, allowing a stable lysogenic state, by binding cooperatively to six operato

97 In the lysogenic state, CI represses the expression of the lyti

98 In the lysogenic state, the CI repressor positively regulates i

99 lambda and following the establishment of a lysogenic state.

100 omosome either to establish or exit from the lysogenic state.

101 n two stable states, the lytic state and the lysogenic state.

102 and thereby to preserve the integrity of the lysogenic state.

103 or copy number; (2) P1 transduction from the lysogenic strain into an appropriate recipient generates

104 recombinant systems, specifically in PhiE125 lysogenic strains of B. mallei and Burkholderia thailand

105 ria toxin (DT), a 58 kDa protein secreted by lysogenic strains of Corynebacterium diphtheriae, causes

106 toxin (DT) is a 58 kDa protein, secreted by lysogenic strains of Corynebacterium diphtheriae, that c

107 inated by purely virulent or dormant (purely lysogenic) strategies.

108 egative host density dependence to the lytic-lysogenic switch.

109 ls of the host density-dependent viral lytic-lysogenic switch.

110 mechanism of control for the phiSa3ms lytic-lysogenic switch.

111 If lysogenic, this phage was maintained extrachromosomally

112 ressor, a dimeric protein that regulates the lysogenic to lytic genetic switch of the phage.

113 The key event in the switch from lysogenic to lytic growth of phage lambda is the self-cl

114 During induction from the lysogenic to lytic state, CI is inactivated, and the two

115 of the cro gene might be unimportant for the lysogenic to lytic switch during induction of the lambda

116 and O(L)) of the phage genome to control the lysogenic to lytic switch.

117 cI, is specifically cleaved to initiate the lysogenic-to-lytic switch.

118 and new ones, for CI regulation of lytic and lysogenic transcription.

119 mbda repressor (CI) maintains the quiescent (lysogenic) transcriptome of bacteriophage lambda in infe