| Reference | Species | Genes Addressed |
|---|
Arsic Arsenijevic V, et al. (2025) Prevalence of Candida and Other Yeasts in Vulvovaginal Infections during Pregnancy: A 10-Year Serbian Survey. Mycopathologia 190(5):86
CGD Papers Entry Pubmed Entry |
Carolus H, et al. (2025) Epistasis at the cell surface: what is the role of Erg3 loss-of-function in acquired echinocandin resistance? mBio :e0141925
CGD Papers Entry Pubmed Entry | C. auris | |ERG3 |
| C. glabrata | |ERG3 |FKS2 |
Consuegra-Asprilla JM, et al. (2025) Virulence of Candida spp. Isolates From Patients With Recurrent Vulvovaginal Candidosis Is Associated With the Number of Episodes. Mycoses 68(2):e70031
CGD Papers Entry Pubmed Entry | C. albicans | |PRA1 |
Dishan A, et al. (2025) Candida species covered from traditional cheeses: Characterization of C. albicans regarding virulence factors, biofilm formation, caseinase activity, antifungal resistance and phylogeny. Food Microbiol 127:104679
CGD Papers Entry Pubmed Entry | C. albicans | |ERG11 |GSC1 |GSL1 |HSP90 |PLB1 |
Ejaz H, et al. (2025) Investigation of multi-drug resistant Candida auris using species-specific molecular markers in immunocompromised patients from a tertiary care hospital in Quetta, Pakistan. PLoS One 20(4):e0319485
CGD Papers Entry Pubmed Entry | C. auris | |ITS1 |ITS2 |
El-Dawy EGAM, et al. (2025) Characterization and virulence of yeasts associated with neonatal thrush. BMC Microbiol 25(1):366
CGD Papers Entry Pubmed Entry | C. albicans | |PLB1 |SAP1 |
| C. glabrata | |PLB1 |
| C. parapsilosis | |CPAR2_209720 |
| C. dubliniensis | |Cd36_62110 |Cd36_63430 |
Gutzmann DJ, et al. (2025) Cwh8 moonlights as a farnesyl pyrophosphate phosphatase and is essential for farnesol biosynthesis in Candida albicans. MBio :e0229025
CGD Papers Entry Pubmed Entry Web Supplement Data | C. albicans | |ALD6 |ARE2 |ARG11 |BIO2 |BTA1 |CCC1 |CDR1 |CEK2 |CRH11 |CWH8 |DAL52 |DIP5 |DPP1 |DPP2 |MORE |
Meral Ocal M, et al. (2025) Myricetin Exerts Antibiofilm Effects on Candida albicans by Targeting the RAS1/cAMP/EFG1 Pathway and Disruption of the Hyphal Network. J Fungi (Basel) 11(5)
CGD Papers Entry Pubmed Entry | C. albicans | |ALS3 |CYR1 |ECE1 |EFG1 |HGC1 |HWP1 |RAS1 |UME6 |
Montenegro I, et al. (2025) Anticandidal activity of Clinopodium chilense essential oil. Front Pharmacol 16:1634250
CGD Papers Entry Pubmed Entry | C. albicans | |ALS9 |ERG11 |
Aydin M, et al. (2024) Rosmarinic Acid Exhibits Antifungal and Antibiofilm Activities Against Candida albicans: Insights into Gene Expression and Morphological Changes. J Fungi (Basel) 10(11)
CGD Papers Entry Pubmed Entry | C. albicans | |ALS3 |CYR1 |ECE1 |EFG1 |HGC1 |HWP1 |RAS1 |UME6 |
Corbu VM, et al. (2024) Phenotypic and Genotypic Characterization of Resistance and Virulence Markers in Candida spp. Isolated from Community-Acquired Infections in Bucharest, and the Impact of AgNPs on the Highly Resistant Isolates. J Fungi (Basel) 10(8)
CGD Papers Entry Pubmed Entry | C. albicans | |ALS1 |ALS3 |HWP1 |
Makled AF, et al. (2024) Characterization of Candida species isolated from clinical specimens: insights into virulence traits, antifungal resistance and molecular profiles. BMC Microbiol 24(1):388
CGD Papers Entry Pubmed Entry | C. albicans | |ALS1 |HWP1 |
| C. glabrata | |HLP |