Candida Infection Biology â€“ fungal armoury, battlefields ... - FINSysB

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Poster number: 33 Using zebrafish to study Candida albicans-mediated systemic candidiasis in vivo Thomas Evans, Simon Tazzyman, Timothy J.A. Chico, Martin H. Thornhill, Craig Murdoch. University of Sheffield, Sheffield, UK Candida albicans is a common oral opportunistic pathogen that causes mucocutaneous infections and rarely systemic candidiasis, a nosocomial infection which involves the haematogenous spread of Candida to multiple organs and is associated with high mortality. To cause tissue damage C.albicans must bind to the endothelium of blood vessels, leave the circulation and invade tissues. However, little is known about the mechanisms involved in these processes. This study aimed to use transparent embryonic zebrafish (Danio rerio) as an in vivo infection model in conjunction with an in vitro flow adhesion assay to study how C.albicans bind to the endothelium, leave the circulation and invade tissues. Suspensions of viable or treated C.ablicans were flowed over monolayers of endothelial cells and adherent Candida counted. Zebrafish were injected with C.albicans and mortality determined after 18h. Time-lapse confocal microscopy using fluorescent C.albicans and blood vessels was performed to image dissemination. Viable C.albicans bound to endothelium significantly (p
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FINSysB Conference Candida Infectio
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MONDAY OCTOBER 10 FINSysB Programme
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Full Programme Candida Infection Bi
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WEDNESDAY OCTOBER 12 08:30 Session
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15:00-15:25 Deborah O’Neil [Novab
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Transcriptional rewiring of fungal
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Dissecting the response of Candida
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Transcriptional control of white-op
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Strand asymmetry in Candida genes M
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Survival in the host -mechanisms un
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Revisiting the Hog Pathway of C. gl
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Glucose promotes oxidative stress r
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Friend or Foe: Systems biology appr
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Impact of non-fermentative growth o
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Wednesday, October 12 51
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Candida albicans: Sensing the Host
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Cell wall stress elicits a conserve
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Force-dependent activation of funct
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Deciphering the role of CUG mistran
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Using zebrafish to study Candida al
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The long pentraxin PTX3 as a paradi
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The Tyr238X dectin-1 polymorphism i
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C-type lectin receptor signaling in
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Candida albicans Secreted Aspartic
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The role of pH-regulated antigen 1
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Tackling the Candida spp infection
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scFv Phage Display Library against
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Hyphal development in Candida albic
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The transcription factor Sko1 repre
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Calcineurin Signaling and Membrane
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Functional analysis of H-loop resid
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Poster number: 01 Glucose promotes
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Poster number: 02 The Osmotic Stres
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Poster number: 03 The transcription
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Poster number: 04 Co-infection of a
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Poster number: 05 The N-terminal pa
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Poster number: 06 Impact of non-fer
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Poster number: 07 Candida albicans
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Poster number: 08 Histidine kinase
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Poster number: 09 Phenotypic invest
Page 130 and 131: Poster number: 10 The Role of Hypha
Page 132 and 133: Poster number: 11 Mini-chromosomes
Page 134 and 135: Poster number: 12 Functional analys
Page 136 and 137: Revisiting the Hog Pathway of C. gl
Page 138 and 139: Poster number: 14 Functional analys
Page 140 and 141: Poster number: 15 Target specificit
Page 142 and 143: Poster number: 16 The contributions
Page 144 and 145: Poster number: 17 Dissecting the re
Page 146 and 147: Poster number: 18 A C-terminal hyph
Page 148 and 149: Poster number: 19 Resistance of Can
Page 150 and 151: Poster number: 20 Investigation of
Page 152 and 153: Poster number: 21 Agent based model
Page 154 and 155: Poster number: 22 Candida albicans
Page 156 and 157: Poster number: 23 Fitness Profiling
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Page 160 and 161: Poster number: 24 Characterization
Page 162 and 163: Poster number: 25 Insights into Can
Page 164 and 165: Poster number: 26 Iff2 is a cell su
Page 166 and 167: Poster number: 27 C. glabrata cell
Page 168 and 169: Poster number: 28 Dolichol-dependen
Page 170 and 171: Poster number: 29 Localization of t
Page 172 and 173: Poster number: 30 A Novel Flow Cyto
Page 174 and 175: Poster number: 31 Cell wall stress
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Page 178 and 179: Poster number: 32 Human cells respo
Page 182 and 183: Poster number: 34 Candida albicans
Page 184 and 185: Poster number: 35 The Tyr238X decti
Page 186 and 187: Poster number: 36 Survival of Candi
Page 188 and 189: Poster number: 37 The role of pH-re
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Page 192 and 193: Poster number: 38 Alkali-metal-cati
Page 194 and 195: Poster number: 39 Calcineurin Signa
Page 196 and 197: Poster number: 40 Wall proteins, ab
Page 198 and 199: Poster number: 41 Dynamic assessmen
Page 200 and 201: Poster number: 42 The role of funga
Page 202 and 203: Poster number: 43 Genetic code ambi
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Page 206 and 207: Donohue, Dagmara Vrije Universiteit
Page 208 and 209: Lorenz, Michael University of Texas
Page 210 and 211: Silva, Sónia University of Minho C
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Candida Infection Biology â€“ fungal armoury, battlefields ... - FINSysB

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