ライフサイエンスコーパス: lac operon

1 the Escherichia coli lactose uptake network (lac operon).

2 observed in autocatalytic systems (e.g. the lac operon).

3 highest affinity for the lac PI site in the lac operon.

4 hanism might contribute to regulation of the lac operon.

5 els of Th-lymphocyte differentiation and the lac operon.

6 ase expression that trigger induction of the lac operon.

7 ng in the regulation of the Escherichia coli lac operon.

8 genetic systems, including the prototypical lac operon.

9 positive feedback architecture, such as the lac operon.

10 protein that regulates transcription of the lac operon.

11 m, whether polymorphic or monomorphic at the lac operon.

12 expression that was first documented in the lac operon.

13 d for adaptive point mutation in the E. coli lac operon.

14 se analogues as measured by induction of the lac operon.

15 ct in a fully additive manner in vivo at the lac operon.

16 We show that this approach applied to the lac operon accurately predicts the system behavior for a

17 is under the transcriptional control of the lac operon and is inducible with isopropyl-1-thio-beta-D

18 nor increased sensitivity to inducers of the lac operon and nonmetabolizable sugar analogues.

19 nsights into the detailed functioning of the lac operon and reveal an efficient avenue to incorporate

20 ors that allow regulated expression from the lac operon and T7 promoters whose biology is well unders

21 er the past half-century, the details of the lac operon and the allosteric model have been tested usi

22 of this procedure by using it to analyze the lac operon and the gene for cytochrome c.

23 One sequence was derived from the bacterial lac operon and the other was created by re-encoding the

24 oli B/r were used; one has wild-type spc and lac operons and the other has a lac operon deletion, a w

25 lex environments, population dynamics of the lac operon, and the synchronization of genetic oscillato

26 the stable recruitment of CENP-A to a LacO (Lac operon) array at a noncentromeric locus.

27 ting environments using the Escherichia coli lac operon as a model system for genotype-environment in

28 this phenomenon occurs with the chromosomal lac operon as well.

29 ffect was investigated by placing the mutant lac operon at many sites in the genome of Salmonella ent

30 , which is analogous to the induction of the lac operon at subsaturating inducer concentrations in la

31 This behaviour requires that the lac operon be located on an F' plasmid.

32 ated CCR when lactose was used to induce the lac operon, but resulted in reduced lac gene expression

33 ion of transcription of the Escherichia coli Lac operon by the Lac repressor (LacR) is accompanied by

34 Deletion of each gene in the lac operon caused various alterations in expression of a

35 recombinant expression systems that utilize lac operon control elements to modulate gene expression

36 hage T7 RNA polymerase gene is expressed via lac operon control elements, exhibits leaky expression t

37 We have constructed a series of monocopy lac operon control region constructs in which the primar

38 We constructed monocopy lac operon control regions in which the operators O1-lac

39 type spc and lac operons and the other has a lac operon deletion, a wild-type spc operon, and a Pspc-

40 Stochastic simulations of the lac operon demonstrated that the predicted effects of tr

41 scriptional and translational fusions to the lac operon demonstrated that while FljA inhibits fliC tr

42 its bistability, a key characteristic of the lac operon dynamics.

43 The Escherichia coli lactose (lac) operon encodes the first genetic switch to be disco

44 ta-galactosidase played an important role in lac operon evolution.

45 Here, we reinvestigate lac operon expression in single cells using a combined e

46 larities to and differences from that of the lac operon first described 50 years ago by Novick and We

47 The induction of the lac operon follows cooperative kinetics.

48 It has recently been reported that a lac operon fusion to the hemA promoter of E. coli is ind

49 cay of the rplN section of mRNA from the spc-lac operon fusion was coupled to the decay of the downst

50 Analysis of mlrA-lac operon fusions demonstrated that mlrA was positively

51 The near absence of regulation of hemA-lac operon fusions suggested a posttranscriptional contr

52 cripts by RNase T2 protection assays and for lac operon fusions to either the flgAMN or flgMN promote

53 e response to heme starvation of a number of lac operon fusions to the hemA promoters of both E. coli

54 twofold) increase in the expression of hemA-lac operon fusions; thus HemA regulation is mediated eit

55 coli protein abundance upon induction of the lac operon genes using isopropyl beta-D-thiogalactopyran

56 p a reaction network for the dynamics of the lac operon genetic switch and derive corresponding deter

57 A population with a silent chromosomal lac operon gives rise to Lac+ revertant colonies that ac

58 The lac operon has been a paradigm for genetic regulation wi

59 For the last several decades, the lac operon has served as a valuable model for studying t

60 The DNA sequence of the lac operon has three lac repressor recognition sites in

61 been used to describe the regulation of the lac operon in E. coli and the lysis/lysogeny switch of p

62 We use the lac operon in Escherichia coli as a prototype system to

63 ) efficiently represses transcription of the lac operon in Escherichia coli by binding to two distant

64 In many cases, such as in the lac operon in Escherichia coli, this regulation is achie

65 e discovery of adaptive amplification at the lac operon in Escherichia coli.

66 ystems, and suggest that derepression of the lac operon in the absence of inducer may be part of a ge

67 nd operator (DNA) and its interplay with the lac operon inducer isopropyl beta-D-1-thiogalactopyranos

68 isomerization of lactose to allolactose, the lac operon inducer.

69 egulatory elements from the Escherichia coli lac operon into the B. burgdorferi genome.

70 The lac operon is a model system for understanding how effec

71 The lac operon is a paradigm for understanding how metabolit

72 The Escherichia coli lac operon is regulated by a positive feedback loop whos

73 e to produce allolactose (the inducer of the lac operon) is slower with the mutant than with the nati

74 why allolactose, the natural inducer for the lac operon, is the preferred product of transglycosylati

75 y than the naturally occurring switch of the lac operon; it is less leaky and can be induced more eff

76 on of bacterial cells with a mutation in the lac operon (lac-) accumulates Lac+ revertants during pro

77 sed on the CRP-binding site sequences of the lac operon (lacDNA) and of the gal operon (galDNA).

78 In the presence of gratuitous inducers, the lac operon of Escherichia coli exhibits bistability.

79 The lac operon of Escherichia coli is positively regulated b

80 The lac operon of Escherichia coli is the paradigm for gene

81 A newly discovered site resides in the lac operon of Escherichia coli.

82 The lac operon of the bacterium Escherichia coli has been a

83 the fhuA polymorphism, and consequently the lac operon polymorphism, was lost between 86 and 219 gen

84 nterotoxin A (sea) promoter or the S. aureus lac operon promoter sequences.

85 omoter approach utilizing the staphylococcal lac operon promoter.

86 The lactose (lac) operon promoter is positively regulated by the cata

87 The Escherichia coli lac operon provides a classic paradigm for understanding

88 dence of looping-dependent repression of the lac operon provides insight into DNA deformation energet

89 of 13 chemostat cultures monomorphic for the lac operon retained the neutral fhuA polymorphism for 45

90 ism of how an Escherichia coli cell with the lac operon switches from one phenotype to another.

91 IBCG, an inducer of genes controlled by the lac operon system in bacterial cells, was achieved in 5

92 cellular processes, an inducible p21 vector (lac operon system) was transfected into the rat pheochro

93 mework is applied to the extensively studied lac operon system, the SOS response system and the araBA

94 ection when two different naturally isolated lac operons (TD2 and TD10) are used.

95 These findings explain control points in the lac operon that minimize the cost of lac permease activi

96 (2) For lacZ mRNA from the lac operon, the endonuclease inactivation reaction was n

97 ping with components of the Escherichia coli lac operon to monitor DNA flexibility in living cells.

98 Our laboratory recently engineered the lac operon to replace the primary operator O1-lac with t

99 l inducer/repressor motifs homologous to the lac operon to the recently discovered interfering RNAs.

100 hat would restore function to an inactivated lac operon unexpectedly yielded fusions in which lac was

101 technology derived from the Escherichia coli Lac operon, uninduced transgenes are kept in a repressed

102 scriptional and translational fusions to the lac operon using FLP mediated site-specific recombinatio

103 In 46 strains, the lac operon was inserted within a small chromosomal dupli

104 During exponential growth, lacZ mRNA of the lac operon was translated about twice as frequently as l

105 by chance, I generated strains in which the lac operon was transposed from its normal position on th

106 Within a simple mathematical model for the lac operon, we show that regulation based on DNA looping

107 niversary of the landmark publication of the lac operon with a review that provides a current view of

108 been known that gratuitous induction of the lac operon with non-metabolizable lactose analogues gene

109 oring stochastic epigenetic switching in the lac operon (with and without an error-prone transcriptio