Project description:Candida albicans is a diploid human fungal pathogen that displays significant genomic and phenotypic heterogeneity over a range of virulence traits and in the context of a variety of environmental niches. Here, we show that the effects of Rob1 on biofilm and filamentation virulence traits is dependent on both the specific environmental condition and the clinical strain of C. albicans. The C. albicans reference strain SC5314 is a ROB1 heterozygote with two alleles that differ by a single nucleotide polymorphism at position 946 resulting in a serine or proline containing isoform. An analysis of 224 sequenced C. albicans genomes indicates that SC5314 is the only ROB1 heterozygote documented to date and that the dominant allele contains a proline at position 946. Remarkably, the ROB1 alleles are functionally distinct and the rare ROB1946S allele supports increased filamentation in vitro and increased biofilm formation in vitro and in vivo, suggesting it is a phenotypic gain-of-function allele. SC5314 is amongst the most highly filamentous and invasive strains characterized to date. Introduction of the ROB1946S allele into a poorly filamenting clinical isolate increases filamentation and conversion of an SC5314 laboratory strain to a ROB1946S homozygote increases in vitro filamentation and biofilm formation. In a mouse model of oropharyngeal infection, the predominant ROB1946P allele establishes a commensal state while the ROB1946S phenocopies the parent strain and invades into the mucosae. These observations provide an explanation for the distinct phenotypes of SC5314 and highlight the role of heterozygosity as a driver of C. albicans phenotypic heterogeneity.

Project description:Candida albicans can stochastically switch between two phenotypes, white and opaque. Opaque cells are the sexually competent form of C. albicans and therefore undergo efficient polarized growth and mating in the presence of pheromone. In contrast, white cells cannot mate, but are induced - under a specialized set of conditions - to form biofilms in response to pheromone. In this work, we compare the genetic regulation of such "pheromone-stimulated" biofilms with that of "conventional" C. albicans biofilms. In particular, we examined a network of six transcriptional regulators (Bcr1, Brg1, Efg1, Tec1, Ndt80, and Rob1) that mediate conventional biofilm formation for their potential roles in pheromone-stimulated biofilm formation. We show that four of the six transcription factors (Bcr1, Brg1, Rob1, and Tec1) promote formation of both conventional and pheromone-stimulated biofilms, indicating they play general roles in cell cohesion and biofilm development. In addition, we identify the master transcriptional regulator of pheromone-stimulated biofilms as C. albicans Cph1, ortholog of Saccharomyces cerevisiae Ste12. Cph1 regulates mating in C. albicans opaque cells, and here we show that Cph1 is also essential for pheromone-stimulated biofilm formation in white cells. In contrast, Cph1 is dispensable for the formation of conventional biofilms. The regulation of pheromone- stimulated biofilm formation was further investigated by transcriptional profiling and genetic analyses. These studies identified 206 genes that are induced by pheromone signaling during biofilm formation. One of these genes, HGC1, is shown to be required for both conventional and pheromone-stimulated biofilm formation. Taken together, these observations compare and contrast the regulation of conventional and pheromone-stimulated biofilm formation in C. albicans, and demonstrate that Cph1 is required for the latter, but not the former.

Project description:Candida albicans can stochastically switch between two phenotypes, white and opaque. Opaque cells are the sexually competent form of C. albicans and therefore undergo efficient polarized growth and mating in the presence of pheromone. In contrast, white cells cannot mate, but are induced - under a specialized set of conditions - to form biofilms in response to pheromone. In this work, we compare the genetic regulation of such "pheromone-stimulated" biofilms with that of "conventional" C. albicans biofilms. In particular, we examined a network of six transcriptional regulators (Bcr1, Brg1, Efg1, Tec1, Ndt80, and Rob1) that mediate conventional biofilm formation for their potential roles in pheromone-stimulated biofilm formation. We show that four of the six transcription factors (Bcr1, Brg1, Rob1, and Tec1) promote formation of both conventional and pheromone-stimulated biofilms, indicating they play general roles in cell cohesion and biofilm development. In addition, we identify the master transcriptional regulator of pheromone-stimulated biofilms as C. albicans Cph1, ortholog of Saccharomyces cerevisiae Ste12. Cph1 regulates mating in C. albicans opaque cells, and here we show that Cph1 is also essential for pheromone-stimulated biofilm formation in white cells. In contrast, Cph1 is dispensable for the formation of conventional biofilms. The regulation of pheromone- stimulated biofilm formation was further investigated by transcriptional profiling and genetic analyses. These studies identified 206 genes that are induced by pheromone signaling during biofilm formation. One of these genes, HGC1, is shown to be required for both conventional and pheromone-stimulated biofilm formation. Taken together, these observations compare and contrast the regulation of conventional and pheromone-stimulated biofilm formation in C. albicans, and demonstrate that Cph1 is required for the latter, but not the former. 4 condition experiment: white and opaque cells in planktonic and pheromone-induced biofilm conditions with and without alpha pheromone. WT strain (P37005), the tec1 mutant strain and the cph1 mutant strain

Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Eukaryotic DNA is packaged into chromatin in the nucleus, which restricts the binding of transcription factors (TFs) to the target DNA sites. FOXA1 functions as a pioneer TF to bind condensed chromatin and initiates the opening of local chromatin for gene expression. However, the principles of how FOXA1 recruits to and unpacks the condensed chromatin remain elusive. Here, we revealed that FOXA1 intrinsically undergoes phase separation through its N-PrLD and C-IDR regions, identified as phase separation region (PSR). Notably, the phase separation property confers FOXA1 the ability to dissolve the chromatin condensates. In addition, the DNA-binding capacity of FOXA1 contributes to its phase separation property. Further genome-wide investigation showed that FOXA1 is recruited to and unpacks the condensed chromatin by its PSR to regulate the function of breast cancer cells. This work provides a principal example of how pioneer TFs function to initiate competent chromatin states by phase separation.

Project description:Candida albicans is the most prevalent fungal pathogen of humans, causing a variety of diseases ranging from superficial mucosal infections to deep-seated systemic infections. Mucus, the gel that coats all wet epithelial surfaces, accommodates Candida albicans as part of the regular microbiome where C. albicans resides asymptomatically in healthy humans. Through a series of in vitro experiments combined with genome-wide transcriptional profiling, we show that mucin biopolymers, the main gel-forming constituents of mucus, induce a new oval-shaped morphology in C. albicans in which a range of genes related to adhesion, filamentation, and biofilm formation are down-regulated. We also show that corresponding phenotypes are suppressed, rendering Candida incapable of forming biofilms on a range of different synthetic surfaces and human epithelial cells. Our data suggests that mucins can manipulate Candida physiology and we hypothesize that they are key regulators for retaining Candida in the host-compatible, commensal state. 3 biological replicates grown in log phase in the presence and absence of mucin for 8 hours. Experiments were performed using RPMI 1640 (Gibco 31800-089) buffered with 165mM MOPS and supplemented with 0.2% NaHCO3 and 2% glucose with and without 0.5% mucin.

Project description:The opportunistic pathogenic fungus Candida albicans can cause devastating infections in severely compromised patients. Its ability to undergo a morphogenetic transition from yeast to filamentous forms allows it to penetrate tissues and cause damage, and the expression of a number of pathogenetic mechanisms are also coordinately regulated with this yeast-to-hyphae conversion. Therefore, it is widely considered that filamentation represents one of the main virulence factors of C. albicans. We have previously identified N-[3-(allyloxy)-phenyl]-4-methoxybenzamide (compound 9029936) as the lead compound in a series of small molecule inhibitors of C. albicans filamentation, and characterized its activity, both in vitro and in vivo, as a promising candidate for the development of alternative anti-virulence strategies for the treatment of C. albicans infections. Here we have performed RNA sequencing analysis of samples obtained from C. albicans cells grown under filament-inducing conditions in the presence or absence of this compound. Overall treatment with compound 9029936 resulted in 618 up-regulated and 702 down-regulated genes. Not surprisingly some of the top down-regulated genes included well characterized genes associated with filamentation and virulence such as SAP5, ECE1 (candidalysin), and ALS3, as well as genes that impact metal chelation and utilization. Gene ontology analysis revealed an over-representation of cell adhesion, iron transport, filamentation, biofilm formation, and pathogenesis processes among down-regulated genes as result of treatment with this leading compound. Interestingly, the top up-regulated genes pointed to an enhancement of vesicular transport pathways, and in particular SNARE interactions.

Project description:Candida albicans can form biofilm on the surface of indwelling medical devices. Biofilm formation is an importanat clinical problem because biofilm-grown cells have decreased susceptibility to antifungal agents. Microarray technology was used to identify changes in gene expression during biofilm development. Two biofilm substrates (denture and catheter) were used, with two C. albicans strains tested on each substrate. Three phases of biofilm development were studies: early (6 h), intermediate (12 h), and mature (48 h). Planktonic specimens were collected at the same time points. Comparison between biofilm and planktonic cell transcriptional profiles at each time point showed differential expression of approximately 3% of the genome in biofilm. Fewer than half of these genes were up-regulated in biofilm, compared to planktonic cells. Transcriptional profiles were also analyzed over the time course of biofilm development. Genes up-regulated during the early phase (6 h) primarily were involved in glycolytic and non-glycolytic carbohydrate assimilation, and amino acid metabolism. The largest number of differentially expressed genes were identified at the intermediate phase (12 h) of biofilm development where the largest increase in biofilm biomass occurs. Genes up-regulated at 12 h were involved in transcription, protein synthesis/translation, energy generation, cellular transport, and nucleotide metabolism. At mature phase (48 h), few genes were up-regulated compared to the 12 h time point. These data define phase-dependent changes in gene expression that occur during biofilm development and show how genes belong to different, but interconnected, functional categories regulate the morphology and phenotype of C. albicans biofilm Keywords: phase-dependent gene expression; comparative genomic hybridization; cell type comparison