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Literature DB >> 6378095

Factors affecting spore formation in a Candida albicans strain.

Abstract

Growth and spore formation of Candida albicans Y-45 was enhanced by low oxygen tension. Mycelium and chlamydospores were abundantly found on rice infusion-Tween 80 agar within 48 to 96 h, and abundant chlamdospore production occurred most rapidly under reduced oxygen tension and incubation at 30 degrees C. Zn, Mg, Mn, anf Fe were tested for their ability to promote filamentation in C. albicans Y-45. Filamentation under conditions of low Mg and high Mn suggested that morphogenesis is possibly correlated with the presence of salts of these heavy metals.

Entities: Chemical Species

Mesh：

Substances：
Culture Media

Year: 1984 PMID： 6378095 PMCID： PMC240240 DOI： 10.1128/aem.47.6.1341-1342.1984

Source DB: PubMed Journal: Appl Environ Microbiol ISSN： 0099-2240 Impact factor: 4.792

8 in total

1. SOME OBSERVATIONS ON THE CYTOLOGY OF CANDIDA ALBICANS.

Authors: A BAKERSPIGEL
Journal: J Bacteriol Date: 1964-01 Impact factor: 3.490

2. The chlamydospores of Candida albicans: comparison of three media for their induction.

Authors: J D POLLACK; R W BENHAM
Journal: J Lab Clin Med Date: 1957-08

3. Optimum conditions for initiation of filamentation in Candida albicans.

Authors: E G Evans; F C Odds; M D Richardson; K T Holland
Journal: Can J Microbiol Date: 1975-03 Impact factor: 2.419

4. The effect of growth medium of filament production in Candida albicans.

Authors: E G Evans; F C Odds; M D Richardson; K T Holland
Journal: Sabouraudia Date: 1974-03

5. Experimental maduromycosis. I. Infection of mice with Phialophora jeanselmei.

Authors: V K Rao; C R Prasad
Journal: Mycopathol Mycol Appl Date: 1973-09-28

6. Factors affecting filamentation in Candida albicans: changes in respiratory activity of Candida albicans during filamentation.

Authors: G A Land; W C McDonald; R L Stjernholm; L Friedman
Journal: Infect Immun Date: 1975-07 Impact factor: 3.441

7. Factors affecting filamentation in Candida albicans: relationship of the uptake and distribution of proline to morphogenesis.

Authors: G A Land; W C McDonald; R L Stjernholm; T L Friedman
Journal: Infect Immun Date: 1975-05 Impact factor: 3.441

8. Formation of aerial hyphae in Candida albicans.

Authors: V Iralu
Journal: Appl Microbiol Date: 1971-09

8 in total

1. Efficacy of surface-generated nitric oxide against Candida albicans adhesion and biofilm formation.

Authors: Benjamin J Privett; Steven T Nutz; Mark H Schoenfisch
Journal: Biofouling Date: 2010-11 Impact factor: 3.209

2. Simple method for separating the chlamydoconidia of Candida albicans from its mycelium.

Authors: V Vidotto; M Bruatto; M G Gallo
Journal: Mycopathologia Date: 1988-07 Impact factor: 2.574

3. FoSTUA, encoding a basic helix-loop-helix protein, differentially regulates development of three kinds of asexual spores, macroconidia, microconidia, and chlamydospores, in the fungal plant pathogen Fusarium oxysporum.

Authors: Toshiaki Ohara; Takashi Tsuge
Journal: Eukaryot Cell Date: 2004-12

8. Characterization of a Candida albicans Mutant Defective in All MAPKs Highlights the Major Role of Hog1 in the MAPK Signaling Network.

Authors: Inês Correia; Duncan Wilson; Bernhard Hube; Jesús Pla
Journal: J Fungi (Basel) Date: 2020-10-17

8 in total

Factors affecting spore formation in a Candida albicans strain.

1. SOME OBSERVATIONS ON THE CYTOLOGY OF CANDIDA ALBICANS.

2. The chlamydospores of Candida albicans: comparison of three media for their induction.

3. Optimum conditions for initiation of filamentation in Candida albicans.

4. The effect of growth medium of filament production in Candida albicans.

5. Experimental maduromycosis. I. Infection of mice with Phialophora jeanselmei.

6. Factors affecting filamentation in Candida albicans: changes in respiratory activity of Candida albicans during filamentation.

7. Factors affecting filamentation in Candida albicans: relationship of the uptake and distribution of proline to morphogenesis.

8. Formation of aerial hyphae in Candida albicans.

1. Efficacy of surface-generated nitric oxide against Candida albicans adhesion and biofilm formation.

2. Simple method for separating the chlamydoconidia of Candida albicans from its mycelium.

3. FoSTUA, encoding a basic helix-loop-helix protein, differentially regulates development of three kinds of asexual spores, macroconidia, microconidia, and chlamydospores, in the fungal plant pathogen Fusarium oxysporum.

4. Chlamydospore formation in Candida albicans requires the Efg1p morphogenetic regulator.

5. Release from quorum-sensing molecules triggers hyphal formation during Candida albicans resumption of growth.

6. Candida species Rewired Hyphae Developmental Programs for Chlamydospore Formation.

7. Prophenoloxidase-Mediated Ex Vivo Immunity to Delay Fungal Infection after Insect Ecdysis.

8. Characterization of a Candida albicans Mutant Defective in All MAPKs Highlights the Major Role of Hog1 in the MAPK Signaling Network.