ライフサイエンスコーパス: host-pathogen interaction

1 pression mediated by RosE is required during host pathogen interaction.

2 expression of bacterial genes important for host pathogen interaction.

3 r the extracellular matrix in regulating the host-pathogen interaction.

4 the battle for survival has shaped a complex host-pathogen interaction.

5 cted link between cellular reprogramming and host-pathogen interaction.

6 strategy generally applicable to studies of host-pathogen interaction.

7 he need for better understanding this unique host-pathogen interaction.

8 and collagen-alginate matrix to dissect the host-pathogen interaction.

9 ignificantly affect bacterial physiology and host-pathogen interaction.

10 TI and renal scarring based on research into host-pathogen interaction.

11 from host serum and the incorporation of the host-pathogen interaction.

12 PGLs play key roles in pathogenicity and host-pathogen interaction.

13 or pathologic inflammation in asthma and for host-pathogen interaction.

14 of the host's metabolic resources is a core host-pathogen interaction.

15 ociated molecular patterns, which govern the host-pathogen interaction.

16 4E phosphorylation is a key component of the host-pathogen interaction.

17 ns where in genes previously associated with host pathogen interactions.

18 of C. jejuni cell surface glycoconjugates in host pathogen interactions.

19 recognition, pathogenesis inflammation, and host pathogen interactions.

20 our understanding of infectious diseases and host pathogen interactions.

21 sents a new and unique biological process of host pathogen interactions.

22 ential to provide deeper insights into other host-pathogen interactions.

23 ction for AGMO-dependent lipid metabolism in host-pathogen interactions.

24 e mechanisms of viral immune suppression and host-pathogen interactions.

25 izable for further examination of additional host-pathogen interactions.

26 studies of alphavirus molecular biology and host-pathogen interactions.

27 y arms race, as observed for genes governing host-pathogen interactions.

28 peroxynitrite, both of which are involved in host-pathogen interactions.

29 A (vsRNA) analysis for getting insights into host-pathogen interactions.

30 obust model systems that enable the study of host-pathogen interactions.

31 relevant route of infection when addressing host-pathogen interactions.

32 lcineurin programs different outcomes during host-pathogen interactions.

33 de all the harder by the added complexity of host-pathogen interactions.

34 Competition for iron influences host-pathogen interactions.

35 afish an attractive model host to understand host-pathogen interactions.

36 ming and infection opens up a new premise in host-pathogen interactions.

37 ogrammed cell death is an important facet of host-pathogen interactions.

38 elegans have provided detailed insight into host-pathogen interactions.

39 ing a mechanistic understanding of migratory host-pathogen interactions.

40 of coding capacity and profoundly influences host-pathogen interactions.

41 g adhesive or immune-modulatory functions in host-pathogen interactions.

42 lanarians as a powerful system for analyzing host-pathogen interactions.

43 ons including 23 genes that are essential to host-pathogen interactions.

44 which results in functional consequences for host-pathogen interactions.

45 s whose populations are strongly affected by host-pathogen interactions.

46 antimicrobial resistance but may also impact host-pathogen interactions.

47 cell adhesion, cell-cell communication, and host-pathogen interactions.

48 n unsuspected role for the nervous system in host-pathogen interactions.

49 oups, this means that they experience strong host-pathogen interactions.

50 7 cells as a small intestinal model to study host-pathogen interactions.

51 phospholipases play many important roles in host-pathogen interactions.

52 ignal molecules involved in reproduction and host-pathogen interactions.

53 g of V. para. infections and more generally, host-pathogen interactions.

54 enic infection and quantify their impacts on host-pathogen interactions.

55 els are simple experimental systems to study host-pathogen interactions.

56 ignificantly affect bacterial physiology and host-pathogen interactions.

57 adds to understanding of complex network of host-pathogen interactions.

58 cted component in determining the outcome of host-pathogen interactions.

59 for new pathogen discovery and research into host-pathogen interactions.

60 he postulated roles of this metalloenzyme in host-pathogen interactions.

61 upregulated has additional implications for host-pathogen interactions.

62 ication of virulence determinants or explore host-pathogen interactions.

63 entric access, analysis and visualization of host-pathogen interactions.

64 rphisms alter RopB function and modulate GAS host-pathogen interactions.

65 and improved integration and presentation of host-pathogen interactions.

66 toskeletal remodeling, sugar metabolism, and host-pathogen interactions.

67 agronomically important model of biotrophic host-pathogen interactions.

68 uent and the potential impact it may have on host-pathogen interactions.

69 or cell-cell recognition and adhesion and in host-pathogen interactions.

70 ystems biology approach toward understanding host-pathogen interactions.

71 odel a unique tool for understanding mucosal host-pathogen interactions.

72 ng the community ecology and epidemiology of host-pathogen interactions.

73 the evolutionary and population dynamics of host-pathogen interactions.

74 ions and impact significantly the outcome of host-pathogen interactions.

75 l but also important molecules implicated in host-pathogen interactions.

76 ted xylose residues are important for normal host-pathogen interactions.

77 ost immune responses and are associated with host-pathogen interactions.

78 understanding the dynamics of sex ratios and host-pathogen interactions.

79 n of iron homeostasis is a major strategy in host-pathogen interactions.

80 stems are infamous for their contribution to host-pathogen interactions.

81 nt when choosing a macrophage model to study host-pathogen interactions.

82 MCV is very poorly characterized in terms of host-pathogen interactions.

83 hematophagy, pathogen transmission, and tick-host-pathogen interactions.

84 nation of TB is our lack of understanding of host-pathogen interactions.

85 as9 screens to discover processes underlying host-pathogen interactions.

86 of m(6)A in the immune system or its role in host-pathogen interactions.

87 ther highlighting the pivotal role of S1P in host-pathogen interactions.

88 pathogenicity, antimicrobial resistance and host-pathogen interactions.

89 ations and new understandings of biology and host-pathogen interactions.

90 the importance of cell-cycle control during host-pathogen interactions.

91 lular architecture and mechanisms underlying host-pathogen interactions.

92 the potential for in-depth visualization of host-pathogen interactions.

93 ggestive of an involvement of this enzyme in host/pathogen interactions.

94 globulin related gene and may be involved in host-pathogen interaction, a well-known target of balanc

95 biochemistry of gene regulation involved in host-pathogen interactions, a quantitative understanding

96 ysis (GSEA) as an engine to globally map the host-pathogen interaction across two cell types.

97 osure of the antigen and a potential role in host-pathogen interaction, active immunization of mice w

98 We also introduced a novel Host-Pathogen Interaction Alignment (HPIA) algorithm and

99 resultant disease is the outcome of complex host-pathogen interactions, an integrated, quantitative

100 ance when evaluating other animal models for host-pathogen interaction and by taking greater advantag

101 Here we focus on the biology of the host-pathogen interaction and discuss new and evolving s

102 n host cells that unveil new features of the host-pathogen interaction and may also be exploited as a

103 Proteins that mediate the host-pathogen interaction and subvert the immune respons

104 l provide the best opportunity to understand host-pathogen interaction and the most powerful approach

105 has begun to outline the complexity of this host-pathogen interaction and to reveal how the homeosta

106 viruses, the Gn tail has been implicated in host-pathogen interaction and viral assembly.

107 d with regard to the evolution of virulence, host-pathogen interactions and antifungal drug therapies

108 ese finding provide targets for the study of host-pathogen interactions and applied research into alt

109 These proteins are a key factor in host-pathogen interactions and are required by certain p

110 host proteins and can be applied to examine host-pathogen interactions and develop host-based therap

111 ses, including translation, gene regulation, host-pathogen interactions and environmental sensing.

112 a better understanding of the complexity of host-pathogen interactions and have identified some of t

113 est the involvement of HbN in modulating the host-pathogen interactions and immune system of the host

114 ant-model design to advance understanding of host-pathogen interactions and immunity.

115 used on protein structure-function analyses, host-pathogen interactions and in developing vaccines.

116 ese responses is important for understanding host-pathogen interactions and informing vaccine design.

117 e an active cell wall glycoconjugate driving host-pathogen interactions and participating in the immu

118 These genomes provide insights into host-pathogen interactions and potential for new drug ta

119 important resource for the investigation of host-pathogen interactions and reductive evolution in on

120 r, these data introduce a novel regulator of host-pathogen interactions and secreted-protein producti

121 e complex and contextual role of anorexia in host-pathogen interactions and suggest that microbes hav

122 he natural route of infection for studies of host-pathogen interactions and suggest that the detrimen

123 ediated signaling represents a mechanism for host-pathogen interactions and that Epac1 is a potential

124 be important for increased understanding of host-pathogen interactions and the development of future

125 it through these pathways affects downstream host-pathogen interactions and the generation of an immu

126 romising model could facilitate the study of host-pathogen interactions and the investigation of the

127 ra has revolutionized approaches to defining host-pathogen interactions and the investigation of the

128 ssue systems to advance our understanding of host-pathogen interactions and the role of human genetic

129 To better understand the role of LPS in host-pathogen interactions and to elucidate the antigeni

130 development that has led to new insights in host-pathogen interactions and, as well, led to insight

131 m pathogen biology, evolutionary dynamics of host--pathogen interactions, and the ecology of infectio

132 ch as leukocyte trafficking, cell migration, host-pathogen interaction, and hemostasis.

133 anism of exNef secretion, identifies a novel host-pathogen interaction, and introduces an HIV-derived

134 cluding liver development, disease modeling, host-pathogen interactions, and drug metabolism and toxi

135 is of GBPs, which mediate mammalian biology, host-pathogen interactions, and immune recognition of gl

136 ide is an immunodominant antigen, can define host-pathogen interactions, and is under consideration a

137 C platform can be used to uncover aspects of host-pathogen interactions, and it has the potential to

138 henotype may apply to artificial selections, host-pathogen interactions, and other biomedically relev

139 urrent use in understanding diarrhea-causing host-pathogen interactions, and potential future applica

140 system (i.e., the more trophic interactions, host-pathogen interactions, and the like there are [i.e.

141 is a receptor for PLA of Y. pestis, and this host-pathogen interaction appears to play a key role in

142 Accessible models for host-pathogen interaction are emerging from full genome

143 However, the biophysical details of this host-pathogen interaction are unclear.

144 Carbohydrate-mediated host-pathogen interactions are essential to bacterial an

145 Host-pathogen interactions are important model systems f

146 In vitro models that mimic in vivo host-pathogen interactions are needed to evaluate candid

147 onsequences of altered FA composition during host-pathogen interactions are poorly understood.

148 y, some outer membrane proteins that mediate host-pathogen interactions are strongly regulated by con

149 We exploited this well-defined host-pathogen interaction as the basis for a high-throug

150 man variation and point to genes involved in host-pathogen interactions as common targets.

151 sed as a model to offer unique insights into host-pathogen interactions as well as a platform to effi

152 ng a highly informative means to investigate host-pathogen interactions as well as assess potential n

153 n the context of bacterial virulence and the host-pathogen interaction, as small molecule inhibitors

154 sor for PGN and provides an understanding of host-pathogen interactions at the molecular level.

155 To further understand host-pathogen interactions at this site, we used mass sp

156 In summary, we have discovered a novel host-pathogen interaction between C. elegans and S. malt

157 We also identified a novel host-pathogen interaction between cyclin F and Vif prote

158 nce of these in vivo results and explore the host-pathogen interaction between DCs and cell-free HTLV

159 Each intervention modulates the host-pathogen interaction, but has both beneficial and h

160 obiota plays an important role in modulating host-pathogen interactions, but little is known about th

161 Mammalian LBs display an important role in host-pathogen interactions, but the role of parasite LBs

162 -seq approach was deployed to understand the host-pathogen interaction by identifying differentially

163 down-regulated protein 9 (NEDD9)-govern the host-pathogen interaction by regulating the uptake of C.

164 Habitat loss regulates host-pathogen interactions by altering biotic and abioti

165 The subsequent host-pathogen interaction can result in eradication, lat

166 , we explore how better understanding of the host-pathogen interaction can substantially enhance, and

167 disease, focusing on infectious diseases and host-pathogen interactions, cancer, and rare genetic dis

168 We describe a computational study of host-pathogen interaction demonstrating that stochastic

169 The host-pathogen interaction drives infectious disease dyna

170 ssues challenge an overly simplistic view of host-pathogen interaction during mucosal infection, but

171 s transmitted via the respiratory route, the host-pathogen interactions during acute VZV infection in

172 l systems-level datasets designed to dissect host-pathogen interactions during influenza A infection

173 The regulation of host-pathogen interactions during Mycobacterium tubercul

174 Host-pathogen interactions during the chronic infection

175 grated use of these approaches can elucidate host-pathogen interactions during this infection and can

176 of host hybridization and clines in altering host-pathogen interactions, dynamics that can have impor

177 resolve sepsis heterogeneity by considering host-pathogen interactions, enabling progress towards a

178 By looking at both sides of the host-pathogen interaction equation, we hope to provide c

179 should find its wide application to studying host-pathogen interactions for any other interconnected

180 s for use in diagnosis and interference with host-pathogen interactions for the purpose of disease co

181 tion for TDP2 and suggest an unusual role in host-pathogen interactions for this cellular enzyme.

182 galectins play multiple roles in regulating host-pathogen interactions; for example, galectins can p

183 sponds with host divergence, suggesting that host-pathogen interaction has led to co-evolution.

184 Mapping host-pathogen interactions has proven instrumental for u

185 alivary glands and other tissues involved in host-pathogen interactions has revealed a wide range of

186 malian GTPase defines further how intimately host pathogen interactions have coevolved through simila

187 m repeat-containing proteins associated with host-pathogen interactions have been identified in Ehrli

188 er, the highly human-specific nature of most host-pathogen interactions hinders the in vivo establish

189 proteins (ECMp) plays important roles during host-pathogen interaction, however its genetic regulatio

190 Detection of host-pathogen interactions (HPIs) and mapping the re-wir

191 Currently, the experimental data on host-pathogen interactions (HPIs) are scattered across m

192 nd pathophysiological cell functions such as host-pathogen interactions, immune regulation, and tumor

193 omics approaches have provided insights into host-pathogen interactions, immunogenetics, and viral ev

194 long been recognized as mediators of initial host-pathogen interactions important for the progression

195 Previous studies of the host-pathogen interaction in CDI have utilized either si

196 temperatures is likely a crucial feature of host-pathogen interaction in cold-blooded animals.

197 Understanding the complex nature of the host-pathogen interaction in each of these contexts is e

198 studies provide additional insights into the host-pathogen interaction in pneumonic Burkholderia infe

199 Here, we investigated mechanisms of host-pathogen interaction in the peripheral nerve lesion

200 dicating that the T6SS-5 is important in the host-pathogen interaction in these cells.

201 in a model of periodontitis and reveal a new host-pathogen interaction in which P. gingivalis activat

202 f the mechanisms of astrovirus infection and host-pathogen interactions in a genetically manipulable

203 Progress in the understanding of host-pathogen interactions in A. fumigatus and patients

204 portant for helical shape, colonization, and host-pathogen interactions in C. jejuni Therefore, chang

205 selection pressure as a result of long-term host-pathogen interactions in certain regions or populat

206 e organism to gain a better understanding of host-pathogen interactions in chronic respiratory infect

207 and mammals allows for the modeling of human host-pathogen interactions in Drosophila.

208 that environmental heterogeneity can mediate host-pathogen interactions in fragmented landscapes, and

209 strates the value of proteomics in unveiling host-pathogen interactions in genetically challenging mi

210 revealed much about the role of P and about host-pathogen interactions in infected cells.

211 ble the field to obtain in-depth analysis of host-pathogen interactions in infection models.

212 portance of the human fibrinolytic system in host-pathogen interactions in invasive GAS infections.

213 holds promise for gaining new insights into host-pathogen interactions in malaria.

214 ul investigations of the immune response and host-pathogen interactions in Mycobacterium tuberculosis

215 otein processing can be an important part of host-pathogen interactions in other systems, suggesting

216 e the knowledge from experimental studies of host-pathogen interactions in several diseases to build

217 Host-pathogen interactions in the decidua during this ea

218 t into the inflammatory mediators regulating host-pathogen interactions in the female genital tract.

219 eraged this animal model to characterize the host-pathogen interactions in the ganglia during both ac

220 disease outcomes and likely indicate initial host-pathogen interactions in the gut mucosa.

221 These studies provide novel insights into host-pathogen interactions in the sensory ganglia during

222 Host-pathogen interactions in tuberculosis should be stu

223 Few studies have examined host-pathogen interactions in wildlife from an immunolog

224 By investigating host-pathogen interactions in zebrafish using intravital

225 of immune cell evolution and development and host-pathogen interactions in zebrafish.

226 ovide insights into the factors that mediate host-pathogen interactions in zygomycosis and establish

227 alpha-glucan degradation contributes to GAS host-pathogen interaction, including how GAS uses human

228 lycans are involved in processes that affect host-pathogen interactions, including adhesion, recognit

229 The host-pathogen interactions induced by Salmonella Typhi a

230 How host-pathogen interactions influence the development of

231 These host-pathogen interactions involve outer membrane protei

232 s MicroReview, the contribution of Mn to the host-pathogen interaction is reviewed, and key questions

233 cus on epidemiology, ecological modeling and host-pathogen interactions is expected to yield a better

234 ole(s) of these non-sialic acid molecules in host-pathogen interactions is poorly understood.

235 ogenicity derived from these analyses of Y2H host-pathogen interactions is the identification of euka

236 eutralizing antibodies; however, its role in host-pathogen interactions is unknown.

237 Despite the high evolutionary pressure in host-pathogen interactions, it is still widely assumed t

238 utionary change is likely to destabilize the host-pathogen interaction leading to population cycles.

239 l biomarker discovery requires understanding host-pathogen interactions leading to biomarker expressi

240 n extended to the most essential outcomes of host-pathogen interactions: namely, infection and diseas

241 and abiotic factors that potentially affect host-pathogen interactions: natural vegetation, canopy d

242 lpB will facilitate future investigations of host-pathogen interactions occurring during H. pylori in

243 , providing direct evidence that this unique host-pathogen interaction occurs in vivo.

244 ed only in the distinct environment in which host-pathogen interaction occurs.

245 and used it to explore similarities between host-pathogen interactions of B. mallei, Yersinia pestis

246 cular epidemiology, virulence potential, and host-pathogen interactions of K. pneumoniae.

247 deoxy sugars in cell-surface recognition and host-pathogen interactions of the genus Bacillus.

248 llular functions that participate in complex host-pathogen interactions or processes related to disea

249 factors,which play an important role in the host-pathogen interaction process.

250 Host-pathogen interactions provide valuable systems for

251 pathogenic bacteria play important roles in host-pathogen interactions ranging from interfering with

252 ase, the distinct mechanisms that govern the host-pathogen interaction remain enigmatic, particularly

253 n into uninfected areas, the dynamics of the host-pathogen interaction remain unknown.

254 altered to affect the biological outcome of host-pathogen interactions remain speculative.

255 , the functions of most pathogenic ncRNAs in host-pathogen interactions remain unclear.

256 but the molecular interface involved in this host-pathogen interaction remains poorly characterized.

257 The precise role of this FH fragment in the host-pathogen interaction remains to be determined.

258 significance of pathogenic noncoding RNAs in host-pathogen interactions remains largely unclear.

259 cation of bio-threat agents and the study of host-pathogen interactions require a high-resolution det

260 Ongoing research on host-pathogen interactions reveals a promising capabilit

261 es (ORFs) involved have functions related to host-pathogen interaction, so genotype-specific evolutio

262 al relevance of cell lines, particularly for host-pathogen interaction studies, is debatable.

263 host cells, a new and flourishing avenue of host-pathogen interaction studies.

264 l, but have not been extended to incorporate host-pathogen interactions, such as immunosuppression or

265 anism has already been demonstrated in other host-pathogen interaction systems, this is the first rep

266 , for questions about specific mechanisms of host-pathogen interaction that cannot be answered feasib

267 rotocol to identify important aspects of the host-pathogen interaction that determine the outcome of

268 uggest that this phenomenon reflects a novel host-pathogen interaction that is central to infection w

269 o Pneumocystis stimulation, but the upstream host-pathogen interactions that activate AEC signaling c

270 ndings support a role for YapE in modulating host-pathogen interactions that are important for coloni

271 Herein, we review the specific host-pathogen interactions that contribute to cardiac dy

272 till unraveling the molecular details of the host-pathogen interactions that enable this virus to esc

273 l studies have allowed us to reconstruct the host-pathogen interactions that have shaped Tetherin and

274 ancing our mechanistic knowledge base of the host-pathogen interactions that influence disease outcom

275 The focus of this review is to consider the host-pathogen interactions that influence neurotropic in

276 h disease pathogenesis and immunity, but the host-pathogen interactions that mediate these effects ar

277 tic markers and may provide insight into the host-pathogen interactions that occur during T. pallidum

278 The host-pathogen interactions that occur in the skin may ha

279 Little is known about the specific host-pathogen interactions that occur when S. aureus fir

280 At present the identity of host-pathogen interactions that promote successful bacte

281 S6(Pro) This work provides new insights into host-pathogen interactions that regulate stress pathways

282 cs as a platform to identify and study novel host-pathogen interactions that shape the outcome of an

283 ndings provide new insights into features of host-pathogen interactions that shape viral evolution, a

284 ment plays a critical role in regulating the host-pathogen interaction through modulation of the fung

285 to its ability to form biofilms and modulate host-pathogen interactions through the secretion of viru

286 Glycans play key roles in host-pathogen interactions; thus, knowing the N-glycomic

287 ide a platform for in silico manipulation of host-pathogen interactions to gain insight into this inf

288 e adapted to assess other host-commensal and host-pathogen interactions using genomic and transcripto

289 Despite their relevance in host/pathogen interactions, very little is known about t

290 My drive to study host-pathogen interactions was to find alternatives for

291 ze the effect of titan cell formation on the host-pathogen interaction, we utilized a previously desc

292 icry and diversifying selection-hallmarks of host-pathogen interactions-were identified within host a

293 l contribute greatly to our understanding of host-pathogen interactions while reducing the number of

294 Applications of PIR technology in host-pathogen interactions will enable researchers study

295 he population and evolutionary dynamics of a host-pathogen interaction with free-living stages are ex

296 This study presents a novel host-pathogen interaction with implications for infectio

297 P will affect the population dynamics of the host-pathogen interaction, with previous theoretical wor

298 Host-pathogen interactions within lesions are a dynamic

299 s a potentially attractive resource to study host-pathogen interactions without the need for animal e

300 cally leads to resistance in an incompatible host-pathogen interaction, yet no gene-for-gene resistan