ライフサイエンスコーパス: salmonellae

1 y and vaccine development against pathogenic Salmonellae.

2 lence by manipulating the mouse host and the salmonellae.

3 xpression of a variety of unrelated genes in salmonellae.

4 ted in equivalent virulence of Spv+ and Spv- salmonellae.

5 uired very recently, after speciation of the salmonellae.

6 tions elicited by typhoidal and nontyphoidal salmonellae.

7 y slightly attenuated relative to InvA+ Spv- salmonellae.

8 eased in vivo replication rate for wild-type salmonellae.

9 ancestor of all the contemporary lineages of salmonellae.

10 caused by groups A, B, C, and D nontyphoidal salmonellae.

11 ctions mediated by enteric pathogens such as salmonellae.

12 ved in typhoid toxin islets found in diverse salmonellae.

13 e important for gastrointestinal survival of salmonellae.

14 reagents suitable for serotyping strains of salmonellae.

15 morphine pellet followed by inoculation with salmonellae.

16 to kill the vast majority of nontransformed salmonellae.

17 Of the serotyped salmonellae, 14% (21/152) were Salmonella enterica serov

18 difications reduce TLR4-signaling as part of Salmonellae adaptation to host environments.

19 n increased splenic infection with wild-type salmonellae after oral inoculation; however, Spv- salmon

20 aneously in wild-type and MsbB- strain 14028 salmonellae and accounts for about one-third of all of t

21 emonstrate specific binding affinity between salmonellae and cholesterol.

22 synthetic pathway is shared by virtually all salmonellae and must be maintained by selection, yet no

23 ease caused by the intramacrophage pathogens salmonellae and mycobacteria.

24 alters how macrophages recognize or process salmonellae and prevents the rapid onset of proinflammat

25 Intracellular pathogenic organisms such as salmonellae and shigellae are able to evade the effects

26 ncreased early (0 to 4 h) blood clearance of salmonellae and significantly decreased numbers of bacte

27 g challenge with the intracellular pathogens salmonellae and Staphylococcus aureus.

28 The long-standing association between Salmonellae and their animal hosts has resulted in the a

29 s complex in overall structure than those of salmonellae and Vibrio cholerae.

30 The salmonellae are a diverse group of bacteria within the f

31 Nontyphoidal Salmonellae are a major cause of life-threatening bacter

32 Upon interaction with epithelial cells salmonellae are able to elicit transepithelial signallin

33 Nontyphoidal salmonellae are among the leading causes of food-borne d

34 Salmonellae are associated with a wide spectrum of invas

35 Non-subspecies I salmonellae are commensals of cold-blooded vertebrates a

36 Nontyphoidal salmonellae are enteric pathogens that cause acute gastr

37 Salmonellae are enterobacteria that have the unique abil

38 Salmonellae are gastrointestinal pathogens of man and an

39 Salmonellae are gram-negative bacteria that cause gastro

40 Nontyphoidal Salmonellae are highly prevalent food-borne pathogens.

41 Salmonellae are pathogenic bacteria that cause significa

42 ractory to boosting with orally administered salmonellae at 7 weeks.

43 Mice infected with salmonellae become hypersusceptible to endotoxin.

44 ex, subspecies I, to which 99% of pathogenic salmonellae belong.

45 lt suggested an existing interaction between salmonellae, bile, and eukaryotic cell invasion.

46 during biofilm development, specifically how salmonellae bind to cholesterol, and suggest a target fo

47 We have previously demonstrated that salmonellae, but not Escherichia coli or Yersinia entero

48 Salmonellae can exist in an asymptomatic carrier state i

49 These data suggest that salmonellae can sense and respond to bile to increase re

50 Salmonellae can use ethanolamine (EA) as a sole source o

51 o involve fewer virulence genes than that of Salmonellae, complex virulence-regulatory networks have

52 teric bacterial pathogens, including group B salmonellae, conjugates composed of the detoxified LPS o

53 Salmonellae coordinate SPI-1 expression with anatomical

54 The reasons why non-subspecies I salmonellae do not circulate in populations of warm-bloo

55 portant role in vivo in host defense against salmonellae during the early stages of infection.

56 as essential to xenophagic clearance and the Salmonellae effector SopF that inhibits bacterial cleara

57 Genome comparisons of the closely related salmonellae emphasize the insights that can be gleaned f

58 Salmonellae encode two virulence-associated TTSS.

59 Salmonellae encode two virulence-associated type III sec

60 During infection of their hosts, salmonellae enter intestinal epithelial cells.

61 Salmonellae establish infection and avoid clearance by t

62 We have shown that salmonellae form bile-mediated biofilms on human gallsto

63 We have previously demonstrated that salmonellae form biofilms on human gallstones and choles

64 ge, and we have previously demonstrated that salmonellae form biofilms on human gallstones in vitro.

65 In our assays, salmonellae formed full biofilms on the surfaces of gall

66 tion into susceptible BALB/c mice, wild-type salmonellae grew at the expected rate of approximately 1

67 Salmonellae have been shown to be competent for conjugat

68 As enteric pathogens, the salmonellae have developed systems by which they can sen

69 Previous studies on the O-Ag capsule of salmonellae have focused primarily on its role in bacter

70 Diverse salmonellae have the potential to cause disease and may

71 l drive a revolution in the understanding of Salmonellae in many different niches that are critical f

72 ce, epidemiology, and genetic relatedness of salmonellae in nondomestic birds.

73 mine if the spv genes affected the growth of salmonellae in nonphagocytic cells, an invA::aphT mutati

74 var Typhi (S. Typhi) differs from most other salmonellae in that it causes a life-threatening systemi

75 hesis for the creation of lactose-fermenting salmonellae in the environment is presented.

76 ice survived asymptomatically with pbgA-lpxC salmonellae in their livers and spleens for months, but

77 To gain further insight into salmonellae in these hosts, 22 Salmonella isolates from

78 ing infection of the gastrointestinal tract, salmonellae induce cytokine production and inflammatory

79 addition of 5'-methylthioadenosine increased Salmonellae-induced cell death.

80 ride, are important for host defense against Salmonellae infection.

81 Salmonellae initiate disease through the invasion of hos

82 d enzyme methods can cluster closely related salmonellae into epidemiologically relevant hierarchies.

83 fied ST313 lineage of invasive non-typhoidal Salmonellae (iNTS).

84 esistance to antimicrobial agents within the salmonellae is a worldwide problem that has been associa

85 inal study of antimicrobial resistance among salmonellae isolated from swine, we studied 484 Salmonel

86 or pathogenicity of several bacteria and for Salmonellae lacking components of AcrAB-TolC, expression

87 In the case of salmonellae, many virulence factors are regulated via Ph

88 Specific factors unique to nontyphoidal salmonellae may also be important for stimulation of the

89 e a unique niche in which lactose-fermenting salmonellae may arise.

90 Upon infection with salmonellae, mucosal expression of CCL2 is rapidly up-re

91 MsbB- salmonellae mutate extragenically to EGTA-tolerant deriv

92 ears, Streptococcus pneumoniae, nontyphoidal salmonellae (NTS), and Hib were the most frequently isol

93 ens of community-acquired BSI are nontyphoid salmonellae (NTS), Streptococcus pneumoniae, Escherichia

94 For Salmonellae, one such regulatory system is PhoP-PhoQ, wh

95 yphimurium or its flagella, but not by other salmonellae or S. typhimurium mutants unable to synthesi

96 We isolated nontyphoidal salmonellae organisms from blood (n = 35), bone marrow (

97 Nontyphoidal salmonellae, particularly Salmonella enterica serovar Ty

98 The Salmonellae PhoP-PhoQ virulence regulators induce resist

99 The Salmonellae PhoQ sensor kinase senses the mammalian phag

100 In a previous study, we reported that salmonellae possess the ability to stimulate tumor necro

101 Escherichia coli or Yersinia enterocolitica, salmonellae rapidly induce TNF-alpha expression in these

102 Attenuated salmonellae represent attractive candidates for the deli

103 ted that CCL2(-/-) macrophages infected with salmonellae resulted in dysregulated cytokine production

104 sive bacterial infection caused by typhoidal Salmonellae (Salmonella enterica serovars Typhi and Para

105 of typhoid toxin produced by a non-typhoidal Salmonellae serotype.

106 ococcus pneumoniae (eight) and non-typhoidal salmonellae (seven).

107 Invasion-defective salmonellae still exhibited the Spv phenotype.

108 teria, while animals infected with wild-type salmonellae succumbed within 1 week.

109 In contrast, other pathogenic salmonellae, such as S. enterica serovars Typhimurium an

110 There is evidence of multidrug resistance in salmonellae that warrants vigilant monitoring and survei

111 ridization analysis revealed that, among the salmonellae, the fim gene cluster is present in all isol

112 Unlike other Salmonellae, the intracellular bacterial human pathogen

113 Compared to the OMs of the wild-type salmonellae, the OMs of the pbgA mutants had increased l

114 ribution of SPI-3 sequences varies among the salmonellae: the right end of the island, which harbors

115 al epithelial cells and are thought to allow salmonellae to enter and cross the intestinal epithelium

116 eature of salmonella pathogenesis and allows salmonellae to enter intestinal epithelial cells.

117 lial cell (IEC) lines, the capacity of these salmonellae to invade IECs, and the ability of the bacte

118 ich hilA and invasion genes are required for salmonellae to overcome a host clearance response elicit

119 , it was unclear which signals are sensed by salmonellae to promote PhoQ-mediated virulence.

120 viruses, but Campylobacter and nontyphoidal Salmonellae together account for about one fourth of cas

121 After ingestion, salmonellae traverse the upper digestive tract and initi

122 eudomonas aeruginosa, Klebsiella pneumoniae, Salmonellae typhi, Candida albicans, Rhizopus stolonifer

123 Previous studies have shown that attenuated salmonellae utilized as vaccine vectors engender strong

124 promoter exhibited negligible impairment of Salmonellae virulence.

125 ealed that the TNFalpha-inducing activity of salmonellae was associated with flagellin, a major compo

126 rface fibre produced by Escherichia coli and salmonellae, was proposed on the basis of genetic eviden

127 nellae after oral inoculation; however, Spv- salmonellae were defective at increasing splenic infecti

128 Furthermore, MMG-grown salmonellae were more resistant to acid stress and macro

129 InvA- Spv+ salmonellae were not significantly affected for splenic

130 ed with the wild-type strain, and InvA- Spv- salmonellae were only slightly attenuated relative to In

131 of T cells and B cells on the Spv phenotype, salmonellae were orally inoculated into nude and SCID BA

132 Overall, 70% (142/203) of the salmonellae were pansusceptible.

133 Salmonellae were recovered from nasal lymphoid tissues,

134 The results show that >200-fold more salmonellae were recovered in livers of the latter group

135 In the latter (heavily infected), salmonellae were seen within mononuclear cells, indicati

136 Furthermore, in contrast to most Salmonellae, which can infect a broad range of hosts, S.

137 However, salmonellae, which have a core that is chemically dissim

138 Unlike infections with most other Salmonellae, which result in self-limiting gastroenterit

139 rom challenge with a lethal dose of virulent salmonellae, with a dramatic reduction in bacterial numb

140 ions is known to directly kill intracellular salmonellae within macrophages.

141 nd possibly by inhibiting the replication of salmonellae within other macrophages.

142 The intricate web of interconnected salmonellae within this ecosystem underscores the import