| human | Q5 |
| P496 | ORCID iD | 0000-0003-4833-0378 |
| P3829 | Publons author ID | 512926 |
| P1053 | ResearcherID | D-7897-2011 |
| P69 | educated at | University of Aberdeen | Q270532 |
| P108 | employer | University of Aberdeen | Q270532 |
| University of Aberdeen Institute of Medical Sciences | Q85985103 | ||
| P734 | family name | MacCallum | Q21475516 |
| MacCallum | Q21475516 | ||
| MacCallum | Q21475516 | ||
| P735 | given name | Donna | Q1993601 |
| Donna | Q1993601 | ||
| P106 | occupation | researcher | Q1650915 |
| P21 | sex or gender | female | Q6581072 |
| Q93103901 | A Bright Future for Fluorescence Imaging of Fungi in Living Hosts |
| Q37641496 | A novel renal epithelial cell in vitro assay to assess Candida albicans virulence |
| Q33758039 | Adaptation of Candida albicans to environmental pH induces cell wall remodelling and enhances innate immune recognition. |
| Q28552704 | Amplification of TLO Mediator Subunit Genes Facilitate Filamentous Growth in Candida Spp |
| Q64882110 | An ex vivo Human Skin Model to Study Superficial Fungal Infections. |
| Q60907389 | Author Correction: Single human B cell-derived monoclonal anti-Candida antibodies enhance phagocytosis and protect against disseminated candidiasis |
| Q36263959 | Blocking two-component signalling enhances Candida albicans virulence and reveals adaptive mechanisms that counteract sustained SAPK activation |
| Q37933755 | C-type lectin receptors and cytokines in fungal immunity |
| Q33761395 | CO(2) acts as a signalling molecule in populations of the fungal pathogen Candida albicans |
| Q40359564 | Candida albicans Chitin Increases Arginase-1 Activity in Human Macrophages, with an Impact on Macrophage Antimicrobial Functions. |
| Q35913482 | Candida albicans Iff11, a secreted protein required for cell wall structure and virulence |
| Q46447946 | Candida albicans Pmr1p, a secretory pathway P-type Ca2+/Mn2+-ATPase, is required for glycosylation and virulence. |
| Q35535803 | Candida albicans colonization and dissemination from the murine gastrointestinal tract: the influence of morphology and Th17 immunity |
| Q33659008 | Comparative transcript profiling of Candida albicans and Candida dubliniensis identifies SFL2, a C. albicans gene required for virulence in a reconstituted epithelial infection model |
| Q35651454 | Contribution of Fdh3 and Glr1 to Glutathione Redox State, Stress Adaptation and Virulence in Candida albicans |
| Q45908507 | Correction: Differential Adaptation of Candida albicans In Vivo Modulates Immune Recognition by Dectin-1. |
| Q36396796 | Dectin-1 is not required for controlling Candida albicans colonization of the gastrointestinal tract |
| Q35073747 | Different consequences of ACE2 and SWI5 gene disruptions for virulence of pathogenic and nonpathogenic yeasts |
| Q28486281 | Differential adaptation of Candida albicans in vivo modulates immune recognition by dectin-1 |
| Q34484827 | Differential regulation of kidney and spleen cytokine responses in mice challenged with pathology-standardized doses of Candida albicans mannosylation mutants |
| Q40069844 | Differential regulation of the transcriptional repressor NRG1 accounts for altered host-cell interactions in Candida albicans and Candida dubliniensis |
| Q33488522 | Early-expressed chemokines predict kidney immunopathology in experimental disseminated Candida albicans infections |
| Q43438117 | Echinocandin resistance due to simultaneous FKS mutation and increased cell wall chitin in a Candida albicans bloodstream isolate following brief exposure to caspofungin |
| Q37226653 | Ectopic expression of URA3 can influence the virulence phenotypes and proteome of Candida albicans but can be overcome by targeted reintegration of URA3 at the RPS10 locus |
| Q42286250 | Efficacy of caspofungin and voriconazole combinations in experimental aspergillosis. |
| Q44088886 | Efficacy of parenteral itraconazole against disseminated Candida albicans infection in two mouse strains. |
| Q33757983 | Elevated catalase expression in a fungal pathogen is a double-edged sword of iron |
| Q35666505 | Elevated cell wall chitin in Candida albicans confers echinocandin resistance in vivo |
| Q37712267 | Expansion of Foxp3(+) T-cell populations by Candida albicans enhances both Th17-cell responses and fungal dissemination after intravenous challenge. |
| Q46738328 | Functional analysis of the phospholipase C gene CaPLC1 and two unusual phospholipase C genes, CaPLC2 and CaPLC3, of Candida albicans |
| Q33808815 | Functional specialization and differential regulation of short-chain carboxylic acid transporters in the pathogen Candida albicans |
| Q35145107 | Fungal chitin dampens inflammation through IL-10 induction mediated by NOD2 and TLR9 activation. |
| Q27332296 | Fungal iron availability during deep seated candidiasis is defined by a complex interplay involving systemic and local events |
| Q40522408 | GFP as a quantitative reporter of gene regulation in Candida albicans. |
| Q33768787 | Genetic dissection of azole resistance mechanisms in Candida albicans and their validation in a mouse model of disseminated infection |
| Q34888535 | Genome-wide analysis of Candida albicans gene expression patterns during infection of the mammalian kidney. |
| Q51802163 | Genome-wide gene expression profiling and a forward genetic screen show that differential expression of the sodium ion transporter Ena21 contributes to the differential tolerance of Candida albicans and Candida dubliniensis to osmotic stress. |
| Q46790340 | Glycosylphosphatidylinositol-anchored proteases of Candida albicans target proteins necessary for both cellular processes and host-pathogen interactions |
| Q52939255 | Granulocytes govern the transcriptional response, morphology and proliferation of Candida albicans in human blood. |
| Q36302013 | Host carbon sources modulate cell wall architecture, drug resistance and virulence in a fungal pathogen |
| Q36064900 | Host-Imposed Copper Poisoning Impacts Fungal Micronutrient Acquisition during Systemic Candida albicans Infections |
| Q35659934 | Hosting infection: experimental models to assay Candida virulence |
| Q34098943 | Identification of a novel response regulator, Crr1, that is required for hydrogen peroxide resistance in Candida albicans |
| Q34619615 | Immune sensing of Candida albicans requires cooperative recognition of mannans and glucans by lectin and Toll-like receptors |
| Q44088882 | Influence of grapefruit juice on itraconazole plasma levels in mice and guinea pigs. |
| Q61807392 | Inhibition of Classical and Alternative Modes of Respiration in Leads to Cell Wall Remodeling and Increased Macrophage Recognition |
| Q46447435 | Lactate signalling regulates fungal β-glucan masking and immune evasion |
| Q40532174 | Loss of cell wall mannosylphosphate in Candida albicans does not influence macrophage recognition |
| Q35604809 | MAPKKK-independent regulation of the Hog1 stress-activated protein kinase in Candida albicans |
| Q37442471 | Massive induction of innate immune response to Candida albicans in the kidney in a murine intravenous challenge model. |
| Q37109793 | Mnt1p and Mnt2p of Candida albicans are partially redundant alpha-1,2-mannosyltransferases that participate in O-linked mannosylation and are required for adhesion and virulence. |
| Q34886777 | Molecular and proteomic analyses highlight the importance of ubiquitination for the stress resistance, metabolic adaptation, morphogenetic regulation and virulence of Candida albicans |
| Q83430370 | Mouse intravenous challenge models and applications |
| Q44896080 | Mouse model of invasive fungal infection. |
| Q33963715 | Multicenter collaborative study for standardization of Candida albicans genotyping using a polymorphic microsatellite marker. |
| Q52577896 | Multiple functions of DOA1 in Candida albicans. |
| Q35108357 | Murine model for Fusarium oxysporum invasive fusariosis reveals organ-specific structures for dissemination and long-term persistence |
| Q37625016 | Need for early antifungal treatment confirmed in experimental disseminated Candida albicans infection. |
| Q35783942 | Niche-specific activation of the oxidative stress response by the pathogenic fungus Candida albicans. |
| Q34651681 | Niche-specific regulation of central metabolic pathways in a fungal pathogen. |
| Q52566975 | Outer chain N-glycans are required for cell wall integrity and virulence of Candida albicans. |
| Q35216691 | Peroxisomal fatty acid beta-oxidation is not essential for virulence of Candida albicans. |
| Q30806103 | Pho4 mediates phosphate acquisition in Candida albicans and is vital for stress resistance and metal homeostasis |
| Q37122002 | Property differences among the four major Candida albicans strain clades |
| Q34865666 | Role of the Candida albicans MNN1 gene family in cell wall structure and virulence. |
| Q45097420 | Safety aspects of working with Candida albicans-infected mice. |
| Q59789344 | Single human B cell-derived monoclonal anti-Candida antibodies enhance phagocytosis and protect against disseminated candidiasis |
| Q47159606 | Stress-induced nuclear accumulation is dispensable for Hog1-dependent gene expression and virulence in a fungal pathogen. |
| Q40429211 | Temporal events in the intravenous challenge model for experimental Candida albicans infections in female mice. |
| Q38338874 | The Candida albicans CaACE2 gene affects morphogenesis, adherence and virulence |
| Q55339940 | The Cryptococcus neoformans Titan cell is an inducible and regulated morphotype underlying pathogenesis. |
| Q34697820 | The Mnn2 mannosyltransferase family modulates mannoprotein fibril length, immune recognition and virulence of Candida albicans |
| Q35988118 | The Rewiring of Ubiquitination Targets in a Pathogenic Yeast Promotes Metabolic Flexibility, Host Colonization and Virulence |
| Q98394405 | Three Related Enzymes in Candida albicans Achieve Arginine- and Agmatine-Dependent Metabolism That Is Essential for Growth and Fungal Virulence |
| Q33888842 | Wild-type Drosophila melanogaster as an alternative model system for investigating the pathogenicity of Candida albicans |
| Q37406652 | Ybp1 and Gpx3 signaling in Candida albicans govern hydrogen peroxide-induced oxidation of the Cap1 transcription factor and macrophage escape |
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