コーパス検索結果 (1語後でソート)
通し番号をクリックするとPubMedの該当ページを表示します
1 CI, 99.7%-100.0%) for Candida krusei/Candida glabrata.
2 sing purified complexes derived from Candida glabrata.
3 onazole (from 6.1% to 18.4%) against Candida glabrata.
4 ment for invasive candidiasis due to Candida glabrata.
5 xation of constraint specifically in Candida glabrata.
6 3p and Dur31p that are uncharacterized in C. glabrata.
7 pathway mutant flies succumb to injected C. glabrata.
8 n and its importance for the virulence of C. glabrata.
9 expression of C. albicans Dur proteins in C. glabrata.
10 of mice infected intravenously with Candida glabrata.
11 t for reduced Hst 5 uptake and killing in C. glabrata.
12 vigation between genes of C. albicans and C. glabrata.
13 onferred a CRS-MIS phenotype on wild-type C. glabrata.
14 bloodstream infections (BSI) due to Candida glabrata.
15 dida including the distantly related Candida glabrata.
16 and echinocandins in clinical isolates of C. glabrata.
17 hways, but its role is less understood in C. glabrata.
18 us system (CNS) and peripheral tissues of B. glabrata.
19 pport the growth and survival of engulfed C. glabrata.
20 ed Candida albicans, C. parapsilosis, and C. glabrata.
21 ous levels of effectiveness in recovering C. glabrata.
22 ession of RPs in the fungal pathogen Candida glabrata.
23 otic FMNAT from the pathogenic yeast Candida glabrata.
24 he primary sensor of niacin limitation in C. glabrata.
25 ong some Candida species, especially Candida glabrata.
26 ctivator for isolated human NK cells than C. glabrata.
27 y to amphotericin B for C. tropicalis and C. glabrata.
28 f persisters in Candida albicans and Candida glabrata.
29 clinically important human pathogen Candida glabrata.
30 and multi-drug resistance associated with C. glabrata.
31 ion in the life cycle and pathobiology of C. glabrata.
32 88.1% (95% CI, 80.2%-93.7%) for C. krusei/C. glabrata.
33 C. albicans, 2 (96.2) and 0.5 (90.4%) for C. glabrata, 0.25 (99.3) and 0.12 (97.9) for C. parapsilosi
34 ws: for C. albicans, 0.016 and 0.007; for C. glabrata, 0.5 and 0.06; for C. parapsilosis, 0.06 and 0.
35 : for C. albicans, 0.3, 0.1, and 2.1; for C. glabrata, 0.8, 1.3, and 1.6; for C. parapsilosis, 0.0, 1
36 rales [2], Fusarium species [2], and Candida glabrata [1]) occurred, representing 8.3% of patients an
37 ows: C. albicans, 2,567 (43.5%) isolates; C. glabrata, 1,464 (24.8%) isolates; C. parapsilosis, 1,048
38 lation of the common non-albicans species C. glabrata (10.2% to 11.7%), C. tropicalis (5.4% to 8.0%),
39 as active against all Candida spp. except C. glabrata (10.5% non-WT), whereas posaconazole showed dec
40 es of 5 Candida spp. (120 C. albicans, 38 C. glabrata, 10 C. parapsilosis, 12 C. tropicalis, and 7 C.
42 (52%), Candida parapsilosis (23.7%), Candida glabrata (12.7%), Candida tropicalis (5.8%), Candida kru
43 luded 560 isolates of C. albicans, 175 of C. glabrata, 162 of C. parapsilosis, 124 of C. tropicalis,
44 lbicans predominated (48.4%), followed by C. glabrata (18.0%), C. parapsilosis (17.2%), C. tropicalis
45 proven infectious endophthalmitis (2 Candida glabrata, 2 coagulase-negative Staphylococcus, 1 Strepto
46 es of Candida albicans, 2,352 isolates of C. glabrata, 2,195 isolates of C. parapsilosis, 1,841 isola
47 es of Candida albicans, 2,415 isolates of C. glabrata, 2,278 isolates of C. parapsilosis, 1,895 isola
48 .0)/0.5 (97.5), and 2 (95.2)/4 (93.5) for C. glabrata; 2 (99.7)/2 (97.3), 0.5 (98.7)/0.5 (97.8), and
49 0.03 for C. albicans; 32, 2, and 0.5 for C. glabrata; 2, 0.25, and 0.12 for C. parapsilosis; 2, 0.12
50 of Candida (42 Candida albicans, 25 Candida glabrata, 22 Candida parapsilosis, 14 Candida tropicalis
52 isolated species (38%), followed by Candida glabrata (29%), Candida parapsilosis (17%), and Candida
53 ene mutations and included 34 isolates of C. glabrata (4 mutant strains), 32 of C. albicans (1 mutant
54 ate wild-type (WT) from non-WT strains of C. glabrata, 42 of the 55 (76.4%) C. glabrata mutants were
55 (5 isolates), C. krusei (2 isolates), and C. glabrata (44 isolates) that were nonsusceptible (either
56 les inoculated with clinical isolates (40 C. glabrata, 46 C. albicans, 36 C. parapsilosis, 19 C. trop
57 (4 isolates), C. kefyr (2 isolates), and C. glabrata (47 isolates) that were nonsusceptible (NS; eit
59 d, consisting of 258 clinical samples (89 C. glabrata, 79 C. albicans, 23 C. parapsilosis, 18 C. trop
60 ate wild-type (WT) from non-WT strains of C. glabrata, 80% of the C. glabrata mutants were non-WT for
61 C. albicans; 96.0%, 98.9%, and 93.7% for C. glabrata; 90.8%, 98.1%, and 98.1% for C. parapsilosis; 9
62 , we characterize the genome of Biomphalaria glabrata, a lophotrochozoan protostome, and provide time
63 glabrata granulin (BgGRN)] from the snail B. glabrata, a natural host for the human blood fluke Schis
64 gously expressed C. albicans ALS3 in Candida glabrata, a yeast that lacks a close ALS3 ortholog and h
65 e investigate the molecular mechanisms of C. glabrata adaptation to heat stress via adaptive laborato
66 e delineated the fungal ligands to be the C. glabrata adhesins Epa1, Epa6, and Epa7 and demonstrated
67 those in the 1998 trial to have IC due to C. glabrata (adjusted OR: 1.93, 95% CI: 0.20-18.98), while
71 d: FKS hot-spot mutations were found in 5 C. glabrata and 2 C. tropicalis isolates; of these, 5 (incl
72 resent the structures of Atp11p from Candida glabrata and Atp12p from Paracoccus denitrificans, and w
74 was low (1%), but the high percentage of C. glabrata and C. krusei isolates within this group of pat
75 simultaneous identification of C. auris, C. glabrata and C. krusei, at species-level as well as of s
78 s, fluconazole exposure favored growth of C. glabrata and C. tropicalis, while caspofungin generally
79 by recovering two species of Candida (Cornus glabrata and Candida albicans) from Candida-spiked blood
80 T and CLSI results with the exceptions of C. glabrata and caspofungin (85.3%) and C. krusei and caspo
83 ing the human pathogens Candida albicans, C. glabrata and Cryptococcus neoformans, the food spoilage
84 Fluconazole (FLC) resistance is common in C. glabrata and echinocandins are often used as first-line
90 ida species group, 4% for VVC due to Candida glabrata, and 10% for T. vaginalis Sensitivity and speci
92 26 isolates, including 58 C. albicans, 62 C. glabrata, and 53 C. krusei isolates), 35 Cryptococcus ne
93 urate method for identifying C. albicans, C. glabrata, and C. parapsilosis, the three most common Can
95 goencephalitis and colitis caused by Candida glabrata, and Q295* for the patient with Candida albican
96 gion of epithelial adhesin (Epa1) of Candida glabrata, and the carboxyl region of the cell wall prote
97 of the Tom40 protein from the yeast Candida glabrata, and truncated constructs lacking the N- and/or
98 andida species group; 84.7% and 99.1% for C. glabrata; and 96.5% and 95.1% for T. vaginalis Sensitivi
100 d polysaccharide structural analyses that C. glabrata ANP1, MNN2, and MNN11 encode functional ortholo
101 Furthermore, we show that deletion of the C. glabrata Anp1, Mnn2, and Mnn11 mannosyltransferases dire
103 ions with the azole-refractory yeast Candida glabrata are now commonly treated with the echinocandins
108 albicans and with increasing prevalence, C. glabrata, are responsible for the majority of fungal blo
110 nformation and the reference sequence for C. glabrata, as well as orthology relationships that interc
112 C. albicans SC5314 was more virulent than C. glabrata BG2 during IAC, causing a 100% mortality rate f
116 We reviewed records of all patients with C. glabrata bloodstream infection at Duke Hospital over the
121 ssion by diverse microbes, including Candida glabrata, Bordetella pertussis, Escherichia coli, and L.
122 l structures of DHFR from C. albicans and C. glabrata bound to lead compounds, 13 new para-linked com
123 tion of an emerging fungal pathogen, Candida glabrata, by the human NK cytotoxic receptor NKp46 and i
124 eral other low-virulence Candida species (C. glabrata, C. auris, and C. albicans efg1Delta/Delta cph1
125 non- albicans Candida species, including C. glabrata, C. dubliniensis, and C. tropicalis, which are
126 ns, C. auris, C. dubliniensis, C. famata, C. glabrata, C. guilliermondii, C. kefyr, C. krusei, C. lus
128 pathogenic Candida species (C. albicans, C. glabrata, C. parapsilosis, C. tropicalis, C. krusei, C.
129 common Candida spp., such as C. albicans, C. glabrata, C. tropicalis, and the C. parapsilosis group.
130 of fluconazole-R isolates of C. albicans, C. glabrata, C. tropicalis, C. rugosa, C. lipolytica, C. pe
131 (Candida albicans/C. parapsilosis, 100%; C. glabrata/C. krusei, 92.3%; C. tropicalis, 100%) and spec
133 assay detecting Candida albicans and Candida glabrata (CAN-PCR) was compared with the Affirm VPIII Ca
134 dida 7-plex panel (Candida albicans, Candida glabrata, Candida tropicalis, Candida parapsilosis, Cand
137 evisiae, but Ure2p of Candida glabrata (Ure2(glabrata)) cannot, even though the Ure2(glabrata) N-term
139 he crystal structure of the OB4 domain of C. glabrata Cdc13, which revealed a novel mechanism of OB f
142 also report that macrophage-internalized C. glabrata cells express CgFtr1 on the cell membrane indic
143 e, we demonstrate for the first time that C. glabrata cells respond to iron limitation by expressing
145 There is a strong association between C. glabrata chorioamnionitis and assisted fertility techniq
148 S. aureus-C. parapsilosis, and S. aureus-C. glabrata coinoculations resulted in little to no mortali
149 lso present in C. glabrata, their role in C. glabrata colonization and virulence was investigated in
153 rast, the N/Q-rich N-terminal domain of Ure2(glabrata) does not readily form amyloid, and that formed
159 Expression microarray analysis of Candida glabrata following phagocytosis by human neutrophils was
160 004) to 1.8% (2009) for anidulafungin and C. glabrata, from 2.4% (2004) to 5.7% (2009) for micafungin
161 t species, such as Candida auris and Candida glabrata, further threatens the limited armamentarium of
162 Determining the NMR structure of the C. glabrata Gal11A KIX domain provides a detailed understan
164 ole use in the 3 months prior to the IFI, C. glabrata, ganciclovir use in the 3 months prior to the I
166 lly characterize a progranulin [Biomphalaria glabrata granulin (BgGRN)] from the snail B. glabrata, a
168 teraction, the human fungal pathogen Candida glabrata harbors a large family of more than 20 cell wal
173 trate that BgGRN induces proliferation of B. glabrata hemocytes, and specifically drives the producti
174 nd virulence in the pathogenic yeast Candida glabrata Here, we demonstrate PI3-kinase (CgVps34) to be
175 ting the fungal enzymes and the growth of C. glabrata; however, the inhibition of the growth of C. al
176 n encounter with planktonic (non-biofilm) C. glabrata, human neutrophils initially phagocytose the ye
179 involves changes in global SUMOylation in C. glabrata Importantly, loss of the deSUMOylating enzyme C
183 xpression that support the persistence of B. glabrata in the field and may define this species as a s
184 a severe attenuation in the virulence of C. glabrata in the mouse model of invasive candidiasis.
186 single species, the fungal pathogen Candida glabrata, in which a trans mutation has occurred very re
187 and results were compared with those from C. glabrata incubated under conditions of carbohydrate or n
192 d demonstrated that clearance of systemic C. glabrata infections in vivo depends on their recognition
196 onization, the human fungal pathogen Candida glabrata is known to utilize a large family of highly re
200 common with other fungi, the cell wall of C. glabrata is the initial point of contact between the hos
206 isolates decreased, and the proportion of C. glabrata isolates increased, while the proportion of C.
210 itro antifungal exposure failed to detect C. glabrata isolates with echinocandin resistance-associate
211 alis isolates; of these, 5 (including all C. glabrata isolates) had micafungin MICs of >2 microg/ml,
212 in 1.2% of C. albicans isolates, 5.9% of C. glabrata isolates, 0.3% of C. parapsilosis isolates, and
213 es (3.5 to 5.6%) was most prevalent among C. glabrata isolates, as determined using recently establis
214 s low (1% of isolates) but was higher for C. glabrata isolates, ranging from 2.1% isolates resistant
215 ortant cues about the in vitro fitness of C. glabrata isolates, which may lead to genotypic or phenot
222 structures of the Vik1 ortholog from Candida glabrata may provide insight into this mechanism by show
225 ains of C. glabrata, 42 of the 55 (76.4%) C. glabrata mutants were non-WT and 8 of the 55 (14.5%) wer
226 non-WT strains of C. glabrata, 80% of the C. glabrata mutants were non-WT for both agents (96% concor
228 s contained a single fungal species, with C. glabrata (n = 129; 30.8%) being the most common isolate,
230 fied were Candida albicans (n = 85), Candida glabrata (n = 63), and Candida parapsilosis (n = 44).
231 Ure2(glabrata)) cannot, even though the Ure2(glabrata) N-terminal domain is more similar to that of t
232 for the ancestral PHO5 was lost and that C. glabrata neofunctionalized a weak phosphatase to replace
233 ibility was independently associated with C. glabrata, non-Hodgkin's lymphoma, cytomegalovirus (CMV)
234 e required for Toll pathway activation by C. glabrata, only GNBP3, and not psh mutants, are susceptib
235 f VT-1161 against Candida krusei and Candida glabrata, pathogens that are intrinsically resistant to
236 cule inhibitors of the interaction of the C. glabrata Pdr1 activation domain with the C. glabrata Gal
238 previously noted that the snail Biomphalaria glabrata produces a secreted lectin, fibrinogen-related
241 tion of C. albicans (green fluorescence), C. glabrata (red fluorescence), and C. parapsilosis (yellow
242 starvation-inducible acid phosphatase in C. glabrata relative to most yeast species provides an exam
243 , heterologous expression of HYR1 in Candida glabrata rendered the organism more resistant to neutrop
244 Recent reports of BSI due to strains of C. glabrata resistant to both fluconazole and the echinocan
247 s and the higher echinocandin resistance, C. glabrata should be closely monitored in future surveilla
250 tionally, we demonstrate that susceptible B. glabrata snails can be made resistant to infection with
251 nsoni (trematode) infections in Biomphalaria glabrata snails, we competed these three models against
252 enome-wide association study of Biomphalaria glabrata snails, we identify genomic region PTC2 which e
256 breakpoints differentiate wild-type from C. glabrata strains bearing clinically significant FKS1/FKS
258 inical echinocandin resistance among Candida glabrata strains is increasing, especially in the United
259 azole and echinocandin coresistance among C. glabrata strains warrants continued close surveillance.
260 s assessed using a blind collection of 50 C. glabrata strains, including 16 FKS1 and/or FKS2 mutants.
262 on of this quality control system in Candida glabrata suggests that many pathogenic species of fungi
264 s in vertebrates, wild-type flies contain C. glabrata systemic infections yet are unable to kill the
266 elevant for pathogenic fungi such as Candida glabrata that are closely related to S. cerevisiae and c
268 ltispecies episodes, with C. albicans and C. glabrata the most frequently encountered combination.
269 Because beta-Mans are also present in C. glabrata, their role in C. glabrata colonization and vir
271 tivation and re-sensitizes drug-resistant C. glabrata to azole antifungals in vitro and in animal mod
272 nderstanding of the attributes that allow C. glabrata to cause disease will provide insights that can
274 susceptibilities of 1,669 BSI isolates of C. glabrata to fluconazole, voriconazole, anidulafungin, ca
276 egulated in three models of resistance of B. glabrata to infection with Schistosoma mansoni or Echino
278 ere, developmental exposures of Biomphalaria glabrata to selective pharmaceutical 5alpha-reductase in
279 ctional glyoxylate cycle is essential for C. glabrata to utilise certain alternative carbon sources i
282 e, we performed a de novo assembly of the C. glabrata type strain CBS138 using long single-molecule r
283 a showed that disruption of ICL1 rendered C. glabrata unable to utilise acetate, ethanol or oleic aci
284 ccharomyces cerevisiae, but Ure2p of Candida glabrata (Ure2(glabrata)) cannot, even though the Ure2(g
285 a [URE3] prion in S. cerevisiae, but the C. glabrata Ure2p, which does have the conserved sequence,
287 tion between Saccharomyces cerevisiae and C. glabrata We demonstrate that SUMOylation is an essential
288 f SUMOylation in the human pathogen, Candida glabrata We identified the enzymes involved in small ubi
290 d 0.5x MIC on day 2, when viable counts of C glabrata were reduced by 99% and 96%, respectively.
291 ere echinocandin-resistant, and 9 (8 Candida glabrata) were multidrug resistant to both fluconazole a
292 remaining 7 mutants (2 C. albicans and 5 C. glabrata) were susceptible to one of the agents and eith
293 e proportion of infections caused by Candida glabrata, which has reduced susceptibility to fluconazol
294 l resistance has been reported among Candida glabrata, which is also frequently resistant to azole dr
295 eins in Saccharomyces cerevisiae and Candida glabrata, whose sequences have diverged to a degree that
298 utant strains from wild type, but testing C. glabrata with caspofungin should be approached cautiousl