| Reference | Literature Topic | Species | Genes Addressed |
|---|
Basso V, et al. (2017) The two-component response regulator Skn7 belongs to a network of transcription factors regulating morphogenesis in Candida albicans and independently limits morphogenesis-induced ROS accumulation. Mol Microbiol
  | Genomic expression study | C. albicans | |CPH1 |EFG1 |SKN7 |UME6 |
Bernardo RT, et al. (2017) The CgHaa1-Regulon Mediates Response and Tolerance to Acetic Acid Stress in the Human Pathogen Candida glabrata. G3 (Bethesda) 7(1):1-18
| Genomic expression study | C. glabrata | |CAGL0E03740g |CAGL0G05632g |FPS1 |FPS2 |HAA1 |PMA1 |RSB1 |SSA3 |TPO3 |YPS4 |
Cao C, et al. (2017) Global regulatory roles of the cAMP/PKA pathway revealed by phenotypic, transcriptomic and phosphoproteomic analyses in a null mutant of the PKA catalytic subunit in Candida albicans. Mol Microbiol 105(1):46-64
  | Genomic expression study | C. albicans | |AGP2 |ALS3 |ALS4 |AOX2 |BRG1 |CAN1 |CAT1 |CCP1 |CPH1 |CSA2 |CYR1 |DIP5 |ECE1 |ERG13 |MORE |
Chaillot J, et al. (2017) Genome-Wide Screen for Haploinsufficient Cell Size Genes in the Opportunistic Yeast Candida albicans. G3 (Bethesda) 7(2):355-360
| Large-scale phenotype analysis | C. albicans | |ABD1 |ADE6 |AFT2 |AGM1 |AHR1 |ALI1 |ALK6 |ALK8 |ALO1 |ALT1 |APS3 |ARC19 |ARF3 |ARO3 |MORE |
Chebaro Y, et al. (2017) Adaptation of Candida albicans to Reactive Sulfur Species. Genetics 206(1):151-162
| Genomic expression study | C. albicans | |CTA4 |ECM17 |MET16 |SSU1 |ZCF2 |
Dorsaz S, et al. (2017) Identification and Mode of Action of a Plant Natural Product Targeting Human Fungal Pathogens. Antimicrob Agents Chemother 61(9)
| Genomic expression study | C. albicans | |ERG4 |ERG6 |
Leach MD, et al. (2017) Candida albicans Is Resistant to Polyglutamine Aggregation and Toxicity. G3 (Bethesda) 7(1):95-108
| Other large-scale proteomic analysis | C. albicans | |SGT2 |SIS1 |
Markus B, et al. (2017) Proteomic analysis of protein phosphatase Z1 from Candida albicans. PLoS One 12(8):e0183176
| Large-scale protein modification | C. albicans | |EFT2 |PPZ1 |RPP0 |
Nocedal I, et al. (2017) Gene regulatory network plasticity predates a switch in function of a conserved transcription regulator. Elife 6
| Genomic expression study | C. albicans | |NDT80 |
Nunez-Beltran A, et al. (2017) Identification of proteins involved in the adhesionof Candida species to different medical devices. Microb Pathog 107:293-303
| Large-scale protein localization | C. parapsilosis | |CPAR2_207210 |CPAR2_602950 |
| | C. glabrata | |ENO1 |FBA1 |
| | C. albicans | |ENO1 |FBA1 |PGK1 |
Rybak JM, et al. (2017) Loss of C-5 Sterol Desaturase Activity Results in Increased Resistance to Azole and Echinocandin Antifungals in a Clinical Isolate of Candida parapsilosis. Antimicrob Agents Chemother 61(9)
| Genomic expression study | C. parapsilosis | |ERG11 |ERG2 |ERG25 |ERG3 |ERG6 |UPC2 |
| | C. albicans | |ERG11 |ERG2 |ERG24 |ERG25 |ERG3 |ERG5 |ERG6 |UPC2 |
Srivastava A, et al. (2017) Distinct roles of the 7-transmembrane receptor protein Rta3 in regulating the asymmetric distribution of phosphatidylcholine across the plasma membrane and biofilm formation in Candida albicans. Cell Microbiol
| Genomic expression study | C. albicans | |BCR1 |RTA3 |
Tao L, et al. (2017) Integration of the tricarboxylic acid (TCA) cycle with cAMP signaling and Sfl2 pathways in the regulation of CO2 sensing and hyphal development in Candida albicans. PLoS Genet 13(8):e1006949
| Genomic expression study | C. albicans | |EFG1 |RAS1 |SFL2 |TPK1 |TPK2 |
Uppuluri P, et al. (2017) Transcriptional Profiling of C. albicans in a Two Species Biofilm with Rothia dentocariosa. Front Cell Infect Microbiol 7:311
| Genomic expression study | C. albicans | |ALS3 |
Wangsanut T, et al. (2017) Grf10 and Bas1 Regulate Transcription of Adenylate and One-Carbon Biosynthesis Genes and Affect Virulence in the Human Fungal Pathogen Candida albicans. mSphere 2(4)
| Genomic expression study | C. albicans | |BAS1 |GRF10 |
de Barros PP, et al. (2017) Temporal Profile of Biofilm Formation, Gene Expression and Virulence Analysis in Candida albicans Strains. Mycopathologia 182(3-4):285-295
| Genomic expression study | C. albicans | |ALS1 |ALS3 |BCR1 |EFG1 |HWP1 |LIP9 |PLB2 |SAP5 |TEC1 |
Ansari MA, et al. (2016) Anticandidal Effect and Mechanisms of Monoterpenoid, Perillyl Alcohol against Candida albicans. PLoS One 11(9):e0162465
 | Genomic expression study | C. albicans | |CLB4 |CNB1 |CSM3 |DOT5 |GLN3 |HWP1 |KRE62 |RAD57 |RFX2 |SKO1 |SPC98 |TPK1 |VCX1 |
Ansari MA, et al. (2016) Mechanistic insights into the mode of action of anticandidal sesamol. Microb Pathog 98:140-8
| Genomic expression study | C. albicans | |ASH2 |BZZ1 |C1_14240W_A |C3_03830W_A |C4_06800W_A |CDC14 |CR_06960W_A |CSM3 |DLH1 |DUT1 |FTR2 |KAR5 |MSH6 |PCL7 |MORE |
Bohm L, et al. (2016) A Candida albicans regulator of disseminated infection operates primarily as a repressor and governs cell surface remodeling. Mol Microbiol 100(2):328-44
| Genomic expression study | C. albicans | |ZCF21 |
Cabezon V, et al. (2016) Apoptosis of Candida albicans during the Interaction with Murine Macrophages: Proteomics and Cell-Death Marker Monitoring. J Proteome Res 15(5):1418-34
| Large-scale protein detection | C. albicans | |CDC48 |FBA1 |GPM1 |MCA1 |PMM1 |RCT1 |SSB1 |TAL1 |
Degani G, et al. (2016) Genomic and functional analyses unveil the response to hyphal wall stress in Candida albicans cells lacking beta(1,3)-glucan remodeling. BMC Genomics 17:482
| Genomic expression study | C. albicans | |C1_04940C_A |CCN1 |CDC28 |CHS2 |CHS3 |CHS7 |CHS8 |CPP1 |CRH11 |CWH8 |DUN1 |ECM331 |FLC2 |GIN4 |MORE |
Dutton LC, et al. (2016) Transcriptional landscape of trans-kingdom communication between Candida albicans and Streptococcus gordonii. Mol Oral Microbiol 31(2):136-61
| Genomic expression study | C. albicans | |ALS1 |ARG1 |ARG3 |ARG4 |CAT1 |CEK1 |CIP1 |CPA2 |DFG5 |FGR42 |GLR1 |HSP21 |HYR1 |PGA34 |MORE |
Fiorini A, et al. (2016) Candida albicans PROTEIN PROFILE CHANGES IN RESPONSE TO THE BUTANOLIC EXTRACT OF Sapindus saponariaL. Rev Inst Med Trop Sao Paulo 58:25
| Large-scale protein detection | C. albicans | |ASC1 |ENO1 |FBA1 |GPM1 |ILV5 |PDC11 |
Gerwien F, et al. (2016) A Novel Hybrid Iron Regulation Network Combines Features from Pathogenic and Nonpathogenic Yeasts. MBio 7(5)
| Genomic expression study | C. glabrata | |ACO1 |AFT1 |ALG5 |ANP1 |ARB1 |ARG81 |ASK10 |ATM1 |BCK1 |BCY1 |BIG1 |CBK1 |CCC1 |CCH1 |MORE |
Hellwig D, et al. (2016) Candida albicans Induces Metabolic Reprogramming in Human NK Cells and Responds to Perforin with a Zinc Depletion Response. Front Microbiol 7:750
| Genomic expression study | C. albicans | |PRA1 |ZRT1 |
Hernday AD, et al. (2016) Ssn6 Defines a New Level of Regulation of White-Opaque Switching in Candida albicans and Is Required For the Stochasticity of the Switch. MBio 7(1):e01565-15
| Genomic expression study | C. albicans | |EFG1 |SSN6 |WOR1 |WOR2 |
Ikeh MA, et al. (2016) Pho4 mediates phosphate acquisition in Candida albicans and is vital for stress resistance and metal homeostasis. Mol Biol Cell 27(17):2784-801
| Genomic expression study | C. albicans | |C3_00170C_A |C3_01540W_A |C3_02140C_A |C6_03320W_A |GDE1 |GIT1 |GIT2 |GIT3 |GPD2 |PHO100 |PHO112 |PHO113 |PHO4 |RHR2 |MORE |
Jha A and Kumar A (2016) Development and targeting of transcriptional regulatory network controlling FLU1 activation in Candida albicans for novel antifungals. J Mol Graph Model 69:1-7
| Computational analysis | C. albicans | |C1_10910C_A |C2_10230W_A |C6_02280W_A |CPH1 |CTA8 |CTF1 |CWT1 |EFG1 |EFH1 |FLU1 |GCN4 |GRF10 |HAL9 |HAP2 |MORE |
Kakade P, et al. (2016) ZCF32, a fungus specific Zn(II)2 Cys6 transcription factor, is a repressor of the biofilm development in the human pathogen Candida albicans. Sci Rep 6:31124
| Genomic expression study | C. albicans | |ZCF32 |
Khandelwal NK, et al. (2016) Pleiotropic effects of the vacuolar ABC transporter MLT1 of Candida albicans on cell function and virulence. Biochem J 473(11):1537-52
| Genomic expression study | C. albicans | |MLT1 |
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