ライフサイエンスコーパス: bacterial physiology

1 This is an additional role for c-di-GMP in bacterial physiology.

2 essenger c-di-AMP plays an important role in bacterial physiology.

3 aling molecules that control many aspects of bacterial physiology.

4 s the way for novel approaches to manipulate bacterial physiology.

5 derstanding sRNA silencing in the context of bacterial physiology.

6 dered undesirable in quantitative studies of bacterial physiology.

7 ications for bacterial membrane function and bacterial physiology.

8 d other fundamental aspects of gram-positive bacterial physiology.

9 eption to c-di-GMP turnover in regulation of bacterial physiology.

10 ng channels has changed our understanding of bacterial physiology.

11 n about the impact of protein acetylation on bacterial physiology.

12 hypothesis that acetylation broadly impacts bacterial physiology.

13 it is a peptidase with a unique function in bacterial physiology.

14 te, a molecule that plays important roles in bacterial physiology.

15 analysis provides valuable information about bacterial physiology.

16 rates has contributed to understanding basic bacterial physiology.

17 the inner membrane is an important aspect of bacterial physiology.

18 vation may have deleterious consequences for bacterial physiology.

19 hput sequencing and molecular measurement of bacterial physiology.

20 arch for the specific function(s) of LeuO in bacterial physiology.

21 at our screen is uncovering novel aspects of bacterial physiology.

22 hich this essential second messenger impacts bacterial physiology and adaptation to changing environm

23 The need to couple information about bacterial physiology and ecology with innovative technol

24 implications for both basic understanding of bacterial physiology and for the classification of bacte

25 s in addition to Ccm, which are critical for bacterial physiology and growth.

26 ing and redox signaling significantly affect bacterial physiology and host-pathogen interaction.

27 sing and quorum sensing significantly affect bacterial physiology and host-pathogen interactions.

28 lay important roles as a second messenger in bacterial physiology and infections.

29 However, the role of H-NS in bacterial physiology and its mechanism of action are sti

30 important but yet-uncharacterized aspects of bacterial physiology and may provide targets for anti-mi

31 mental systems that incorporate knowledge of bacterial physiology and metabolism with insights from b

32 cal analysis, biochemistry, genetic screens, bacterial physiology and molecular computation.

33 onine (Thr) and tyrosine (Tyr) is central to bacterial physiology and pathogenesis, and that the corr

34 um-sensing systems has a crucial function in bacterial physiology and pathogenesis.

35 bacteria and plays a multifunctional role in bacterial physiology and pathogenesis.

36 ction of CRISPR-Cas systems as regulators of bacterial physiology and provide a framework with which

37 highlight the intimate relationship between bacterial physiology and resistance to innate immune kil

38 However, their role in bacterial physiology and signalling has been largely neg

39 tants revealed that the beneficial effect on bacterial physiology and survival was mediated by the ab

40 rve as a signaling molecule which can affect bacterial physiology and survival.

41 for studying the role of essential genes in bacterial physiology and virulence in both genetically t

42 nmental conditions is an essential aspect of bacterial physiology and virulence.

43 an intergenic region can dramatically affect bacterial physiology and virulence.

44 these systems may have broader functions in bacterial physiology, and it is unknown if they regulate

45 central roles in many fundamental aspects of bacterial physiology, and they are important determinant

46 nisms, to reveal novel phenotypes related to bacterial physiology, and to probe the role of bacterial

47 on cell envelope biogenesis and maintenance, bacterial physiology, antibiotic resistance and virulenc

48 the global effects of vancomycin exposure on bacterial physiology are poorly understood.

49 logies have transformed our understanding of bacterial physiology as well as the contribution of the

50 e broad implications to our understanding of bacterial physiology, as the glassy behavior of the cyto

51 teria to define broadly the effects of NO on bacterial physiology, as well as to identify the functio

52 rane protein (OMP) biogenesis is critical to bacterial physiology because the cellular envelope is vi

53 e TA systems are involved not only in normal bacterial physiology but also in pathogenicity of bacter

54 As a lysogen, the prophage alters the bacterial physiology by increasing the rates of respirat

55 uggest that PG may play an essential role in bacterial physiology by maintaining the anionic characte

56 somally encoded toxin-antitoxin (TA) loci in bacterial physiology has been under debate, with the tox

57 ies to assess the importance of hopanoids in bacterial physiology have never been performed.

58 rones that appear to play important roles in bacterial physiology; however, it is not known how these

59 teract with NO is essential to understanding bacterial physiology in many habitats, including pathoge

60 ation and, more importantly, that control of bacterial physiology in response to the plant and surrou

61 r virulence due to their roles in regulating bacterial physiology in the context of stress.

62 verse molecular activities to interfere with bacterial physiology in various, yet ill-defined, biolog

63 Major changes in bacterial physiology including biofilm and spore formati

64 they play key roles in important aspects of bacterial physiology, including genomic stability, forma

65 rther studies into how this GTPase regulates bacterial physiology, including persistence.

66 Potassium (K(+) ) plays a vital role in bacterial physiology, including regulation of cytoplasmi

67 ukaryotes and bacteria; however, its role in bacterial physiology is unclear.

68 n function, suggesting that novel aspects of bacterial physiology may play a part in biofilm formatio

69 ing the integration of three core aspects of bacterial physiology: metabolism, growth, and cell cycle

70 -GMP) has emerged as a prominent mediator of bacterial physiology, motility, and pathogenicity.

71 ght has become a puzzling and novel issue in bacterial physiology, particularly among bacterial patho

72 bacterial genomes and play critical roles in bacterial physiology, pathogenicity, and antibiotic resi

73 chromosomal toxin-antitoxin (TA) modules in bacterial physiology remains enigmatic despite their abu

74 First, our emerging insight into bacterial physiology suggests new pathways that might be

75 fascinating insights into the links between bacterial physiology, the expression of virulence genes,

76 se, we propose its acetylation may influence bacterial physiology through effects on gene expression.

77 itions of natural habitats can interact with bacterial physiology to promote the evolution of coopera

78 ene-expression data indicate that agr adapts bacterial physiology to stationary growth and, furthermo

79 ion is thus crucial for our understanding of bacterial physiology under various stress conditions.

80 roteins and RNA riboswitches, which regulate bacterial physiology upon binding to nucleotides, have b

81 In the present work the role of MazF in bacterial physiology was studied by using an inactive, a

82 interrogate the impact of cell morphology on bacterial physiology, we used fluorescence-activated cel

83 Combining measurements of bacterial physiology with analysis of published data on

84 hown to play an increasingly diverse role in bacterial physiology, yet much remains to be learned abo