ライフサイエンスコーパス: intestinal bacteria

1 gulation of the immune response to commensal intestinal bacteria.

2 tor-kappaB, are involved in the detection of intestinal bacteria.

3 s of oligosaccharides fermented by different intestinal bacteria.

4 Mucolytic potential is widespread among intestinal bacteria.

5 on of small-molecule metabolites produced by intestinal bacteria.

6 the host immune system in the gut and in the intestinal bacteria.

7 ding changes the composition and behavior of intestinal bacteria.

8 ngle epitope, which act together to regulate intestinal bacteria.

9 motherapy and immunotherapy is influenced by intestinal bacteria.

10 to the anaerobic growth requirements of most intestinal bacteria.

11 W and PflD, which are widespread among human intestinal bacteria.

12 al stimulation that can functionally replace intestinal bacteria.

13 atory agent cyclophosphamide (CTX) relies on intestinal bacteria.

14 enteropathy and the prevalence of pathogenic intestinal bacteria.

15 s.IMPORTANCE Butyrate is a lipid produced by intestinal bacteria.

16 utualistic relationship between the host and intestinal bacteria.

17 uld be attenuated in the complete absence of intestinal bacteria.

18 s an exaggerated immune response directed at intestinal bacteria.

19 promotes colonic neurogenesis, regulated by intestinal bacteria.

20 fense that protects against dissemination of intestinal bacteria.

21 lin or to different commensal and pathogenic intestinal bacteria.

22 on of IgM and complement-mediated control of intestinal bacteria.

23 e suggests a connection between diet and the intestinal bacteria.

24 tory IgA (SIgA) is found in association with intestinal bacteria.

25 IgT coated most intestinal bacteria.

26 ce points to the various mechanisms by which intestinal bacteria act on distal tumors and how to harn

27 Intestinal bacteria aid host health and limit bacterial

28 The reduction of intestinal bacteria also significantly improved the grow

29 y be due to excessive hydrogen production by intestinal bacteria altering the partial pressure of nit

30 ently, the O-protease OpeRATOR, derived from intestinal bacteria and expressed in Escherichia coli, h

31 Vancomycin altered the abundance of intestinal bacteria and fungi, measured by 16S and 18S r

32 n part, by the interaction between commensal intestinal bacteria and gut-associated lymphoid tissue (

33 cells, and the interrelationship between the intestinal bacteria and Tfh cell responses in the gut.

34 ng the complex interactions between resident intestinal bacteria and the immune system could improve

35 Intestinal barrier derangement allows intestinal bacteria and their products to translocate to

36 at host innate immune signaling can modulate intestinal bacteria and ultimately the host's susceptibi

37 ulting in tissue infiltration of 'symbiotic' intestinal bacteria and viruses that essentially become

38 tyrate, a short-chain fatty acid produced by intestinal bacteria, and lipoteichoic acid, a cell wall

39 of principles governing the localization of intestinal bacteria, and spatial relationships between b

40 Interestingly, RA was produced by intestinal bacteria, and the loss of bacterial-intrinsic

41 Our findings demonstrate that intestinal bacteria are critical for regulating allergic

42 strates that a substantial proportion of the intestinal bacteria are culturable.

43 inant daidzein metabolites produced by human intestinal bacteria are equol and O-desmethylangolensin.

44 Since intestinal bacteria are important for metabolism of nitr

45 Because intestinal bacteria are potent modulators of systemic im

46 Intestinal bacteria are required for development of gut-

47 Protein toxins released by certain intestinal bacteria are the cause of many diarrhoeal dis

48 Intestinal bacteria are thought to play a role in the pa

49 bacteriophage (phages) to eliminate targeted intestinal bacteria as an alternative to a broad-spectru

50 Enterococcus faecalis strains are resident intestinal bacteria associated with invasive infections,

51 ealed that neomycin altered the abundance of intestinal bacteria bearing gamma-d-glutamyl-meso-diamin

52 resent a major nutrient source, not just for intestinal bacteria but also for microorganisms that occ

53 RegIIIgamma binds intestinal bacteria but lacks the complement recruitment

54 matic activity leads to growth inhibition of intestinal bacteria by causing local tryptophan depletio

55 hat commensal fungi can functionally replace intestinal bacteria by conferring protection against inj

56 is a short-chain fatty acid produced by the intestinal bacteria by the fermentation of nondigestible

57 how a marked proportion of oxygen-sensitive intestinal bacteria can be transmitted between individua

58 Our study highlights how protective intestinal bacteria can modify microbial-associated mole

59 Given that intestinal bacteria can produce ethanol, the aim of this

60 Interestingly, intestinal bacteria can promote infection of several mam

61 Thus, introduction of immunogenic intestinal bacteria can promote Tfh-associated anti-tumo

62 is or defective host defense toward invasive intestinal bacteria can result in chronic inflammation.

63 A recent study in mice suggests that intestinal bacteria can trigger mammary carcinoma.

64 An improved understanding of how intestinal bacteria cause disease has become increasingl

65 Finally, new understanding of how intestinal bacteria cause disease is revealing that ente

66 Reviewed here are the varied ways that intestinal bacteria cause disease, which provide fundame

67 The Human intestinal Bacteria Collection (HiBC) contains 340 strai

68 Importantly, we found the intestinal bacteria contain glycolipids which can be pre

69 Our findings indicate that intestinal bacteria contribute to the development of NSA

70 t of progenitor cell responses to pathogenic intestinal bacteria could provide a measure of predispos

71 TMAO is produced by hepatic processing of intestinal bacteria-derived trimethylamine (TMA) followi

72 The absence of intestinal bacteria did not affect the incidence of alph

73 In animal models, intestinal bacteria drive colitis and in humans certain

74 Intestinal bacteria drive the formation of lymphoid tiss

75 Abnormal composition of intestinal bacteria--"dysbiosis"-is characteristic of Cr

76 Intestinal bacteria employ microbial metabolites from th

77 tively, these data demonstrate that resident intestinal bacteria enhance the stability of beta-cateni

78 unication system where compounds produced by intestinal bacteria, especially short-chain fatty acids,

79 Small intestinal bacteria exhibit distinct gluten metabolic pa

80 rmfree or colonized with a limited number of intestinal bacteria failed to develop inflammatory bowel

81 Intestinal bacteria ferment dietary fibers into short-ch

82 d to a considerable interest in manipulating intestinal bacteria for therapeutic benefit, and trials

83 Intestinal bacteria form a resident community that has c

84 rier in Rd8 mice led to the translocation of intestinal bacteria from the lower gastrointestinal (GI)

85 Analysis of intestinal bacteria from the terminal ilea of Nod2-defic

86 , and to microbial products derived from the intestinal bacteria, has resulted in a distinctive local

87 In summary, these intestinal bacteria have been highlighted as novel tools

88 Intestinal bacteria have been implicated in the pathogen

89 Human intestinal bacteria have many roles in human health, mos

90 We hypothesized that intestinal bacteria impact the pathogenesis of multiple

91 IgA coating uniquely identifies colitogenic intestinal bacteria in a mouse model of microbiota-drive

92 to equol and O-desmethylangolensin (ODMA) by intestinal bacteria in approximately 30-50% and 80-90% o

93 Bifidobacteria are the dominant intestinal bacteria in breastfed infants.

94 bacillus plantarum and its interactions with intestinal bacteria in mice undergoing switches between

95 Animal models suggest a role for intestinal bacteria in supporting the systemic immune re

96 microbiota, focusing on the role of resident intestinal bacteria in the development of immune respons

97 scuss the roles of known and novel commensal intestinal bacteria in the pathogenesis of inflammatory

98 Dysregulated immune responses to commensal intestinal bacteria, including Escherichia coli, contrib

99 gated whether oral inoculation with specific intestinal bacteria increased colon inflammation in the

100 sion, these results support the concept that intestinal bacteria induce endogenous signals that play

101 ring the fermentation of fiber by endogenous intestinal bacteria, induces mitochondrial function-depe

102 Intestinal bacteria influence mammalian physiology, but

103 Our results suggest that translocation of intestinal bacteria into liver may be involved as a one

104 Escape of intestinal bacteria into the ascites is involved in the

105 Increased translocation of intestinal bacteria is a hallmark of chronic liver disea

106 ses vs controls, we found that reactivity to intestinal bacteria is a normal property of the human CD

107 In this review the intestinal bacteria is discussed in the context of devel

108 innate immune inflammatory response against intestinal bacteria is sufficient to induce colon cancer

109 Although the inability to control intestinal bacteria is thought to underlie IBD, the role

110 Resident intestinal bacteria likely play an important role in the

111 tyrate, a short-chain fatty acid produced by intestinal bacteria, lipoteichoic acid, a cell wall comp

112 Although intestinal bacteria live deep within the body, they are

113 Thus, symbiotic intestinal bacteria modulate antiviral immunity and leve

114 accumulating to support the hypothesis that intestinal bacteria not only exchange resistance genes a

115 nce elicitor of systemic immune responses to intestinal bacteria observed in a loss-of-tolerance mode

116 al reservoir of particular importance is the intestinal bacteria of food-producing animals.

117 ing of the impact of translocating commensal intestinal bacteria on mucosal-associated T cell respons

118 eview examines the influence of signals from intestinal bacteria on the homeostasis of the mammalian

119 impact of less-virulent antibiotic-resistant intestinal bacteria on the outcome of CDI.

120 We investigated whether intestinal bacteria or their products affect the adult E

121 ed that stress promotes the translocation of intestinal bacteria or their toxins into the systemic co

122 Our observations suggest that the intestinal bacteria, or the factors they produce, can af

123 rapidly respond to commensal and pathogenic intestinal bacteria, parasites and food components by po

124 a selective force in the evolution of their intestinal bacteria, particularly by increasing the prev

125 Here, we analyzed the intestinal bacteria presented in normal and infected wor

126 ation after antibiotic-mediated depletion of intestinal bacteria prevents colitis and influenza, thus

127 Thus, intestinal bacteria, prior to detectable shifts in commu

128 Host intestinal bacteria produce its precursor trimethylamine

129 Accumulating evidence suggests that intestinal bacteria promote enteric virus infection in m

130 robiota.IMPORTANCE Recent data indicate that intestinal bacteria promote intestinal infection of seve

131 Which intestinal bacteria provide resistance to C. difficile i

132 ead to exaggerated inflammatory responses to intestinal bacteria, raising the possibility that defect

133 verse IS elements insert into the genomes of intestinal bacteria regardless of human host lifestyle.

134 ggravate chronic inflammation via effects on intestinal bacteria regulating gut permeability to visce

135 diarrheal disease, but their effect on other intestinal bacteria remains unexplored.

136 Furthermore, the reduction in intestinal bacteria resulted in the elimination of the e

137 chain fatty acids (SCFA) are metabolites of intestinal bacteria resulting from fermentation of dieta

138 Using these collections, we found that intestinal bacteria selected on the basis of high coatin

139 tem targets non-self rather than self, these intestinal bacteria should be considered foreign and the

140 n probiotics, nutritional components and the intestinal bacteria should be considered when examining

141 ses against a panel of taxonomically diverse intestinal bacteria species in sera from TN-10 participa

142 ponses influence host health, yet only a few intestinal bacteria species that induce cognate adaptive

143 entage of them become colonized by resistant intestinal bacteria such as extended-spectrum beta-lacta

144 ns that are highly specific for target Ag on intestinal bacteria, suggesting that an aberrant T cell

145 ry bowel disease, is attributed, in part, to intestinal bacteria that may initiate and perpetuate muc

146 overactive immunity to a subset of resident intestinal bacteria that mediate multiple inflammatory c

147 MIA phenotypes in offspring require maternal intestinal bacteria that promote TH17 cell differentiati

148 e contact at birth with maternal vaginal and intestinal bacteria, the authors proposed that this coul

149 s review, we explore a more sinister side of intestinal bacteria; their role as traffickers in antibi

150 However, the enzymes that allow intestinal bacteria to access sulfite from taurine have

151 New evidence has implicated the lack of intestinal bacteria to be responsible for the degradatio

152 To determine if fenugreek utilizes intestinal bacteria to offset the adverse effects of hig

153 ta indicate that enteric viruses can utilize intestinal bacteria to promote viral replication and pat

154 ve identified molecular cues propagated from intestinal bacteria to the brain that can affect neurolo

155 a, which may contribute to the adaptation of intestinal bacteria to the mucosal environment in health

156 ot clear how LACC1 balances defenses against intestinal bacteria vs intestinal inflammation or what c

157 Furthermore, supplement of killed intestinal bacteria was able to restore ConA-mediated NK

158 at colonization of GF mice with a variety of intestinal bacteria was capable of reducing T1D in MyD88

159 oxidative derivative of choline produced by intestinal bacteria, was positively associated with rect

160 erplay between the mucosal immune system and intestinal bacteria, we investigated the role of MIF in

161 The expanded intestinal bacteria were required for the parasite-induc

162 These antibody responses link human intestinal bacteria with T1D progression, adding predict

163 n of SAAs from meat to sulfide production by intestinal bacteria with use of both a model culture sys

164 utrient release acts as a source of fuel for intestinal bacteria, with implications for gut inflammat