Project description:The interaction between fungal pathogen and host during infection is a complex and dynamic process. To resolve this, we chose the zebrafish model organism as the host to study C. albicans infection via systems biology approach. Transcriptome microarray data and histological analysis of surviving fish were sampled at different post-infection time points. The dynamic variations of significant genes expression profiles in C. albicans and zebrafish were concurrently analyzed by principal component analysis (PCA). The PCA results clearly indicated that the infection of C. albicans can be divided into three phases that include adhesion, invasion and damage phases. The results were highly consistent with subsequent histological analysis. Furthermore, we found the primary ontology function of genes with significant variations in both C. albicans and zebrafish is iron related. Most of the iron related genes in C. albicans were over-expressed in late stage, while most of the iron related genes in zebrafish were suppressed at the same phase of infection. It suggested that the iron homeostasis function of the host was shut-down when massive hemorrhage in zebrafish occurred during later stages of infection. At the same time, the iron scavenging function of C. albicans was activated. This implied the competition for iron is an important issue between the host and the fungal pathogen during infection. When we administered excess iron into the microenvironment of infection site, the infection process was significantly delayed. That indicated the virulence of C. albicans is correlated with its protein-bond iron scavenging strategies. Our finings not only provided dynamic mechanistic views of the iron competition but also highlighted the potential regulatory schemes in fungal pathogenesis.

Project description:The interaction between fungal pathogen and host during infection is a complex and dynamic process. To resolve this, we chose the zebrafish model organism as the host to study C. albicans infection via systems biology approach. Transcriptome microarray data and histological analysis of surviving fish were sampled at different post-infection time points. The dynamic variations of significant genes expression profiles in C. albicans and zebrafish were concurrently analyzed by principal component analysis (PCA). The PCA results clearly indicated that the infection of C. albicans can be divided into three phases that include adhesion, invasion and damage phases. The results were highly consistent with subsequent histological analysis. Furthermore, we found the primary ontology function of genes with significant variations in both C. albicans and zebrafish is iron related. Most of the iron related genes in C. albicans were over-expressed in late stage, while most of the iron related genes in zebrafish were suppressed at the same phase of infection. It suggested that the iron homeostasis function of the host was shut-down when massive hemorrhage in zebrafish occurred during later stages of infection. At the same time, the iron scavenging function of C. albicans was activated. This implied the competition for iron is an important issue between the host and the fungal pathogen during infection. When we administered excess iron into the microenvironment of infection site, the infection process was significantly delayed. That indicated the virulence of C. albicans is correlated with its protein-bond iron scavenging strategies. Our finings not only provided dynamic mechanistic views of the iron competition but also highlighted the potential regulatory schemes in fungal pathogenesis. Each fish was intraperitoneally injected with C. albicans cells and these infected fish were collected at 0.5, 1, 2, 4, 6, 8, 12, 16, 18 hpi. 0.625M-NM-<g of Cy3 cRNA for C. albicans array and 1.65 M-NM-<g of Cy3 cRNA for zebrafish array was fragmented to an average size of about 50-100 nucleotides by incubation with fragmentation buffer at 60M-BM-0C for 30 minutes. Each time points contain three biological repeat. For C. albicans array, each biological repeat has two technical replicates.

Project description:The interaction between fungal pathogen and host during infection is a complex and dynamic process. To resolve this, we chose the zebrafish model organism as the host to study C. albicans infection via systems biology approach. Transcriptome microarray data and histological analysis of surviving fish were sampled at different post-infection time points. The dynamic variations of significant genes expression profiles in C. albicans and zebrafish were concurrently analyzed by principal component analysis (PCA). The PCA results clearly indicated that the infection of C. albicans can be divided into three phases that include adhesion, invasion and damage phases. The results were highly consistent with subsequent histological analysis. Furthermore, we found the primary ontology function of genes with significant variations in both C. albicans and zebrafish is iron related. Most of the iron related genes in C. albicans were over-expressed in late stage, while most of the iron related genes in zebrafish were suppressed at the same phase of infection. It suggested that the iron homeostasis function of the host was shut-down when massive hemorrhage in zebrafish occurred during later stages of infection. At the same time, the iron scavenging function of C. albicans was activated. This implied the competition for iron is an important issue between the host and the fungal pathogen during infection. When we administered excess iron into the microenvironment of infection site, the infection process was significantly delayed. That indicated the virulence of C. albicans is correlated with its protein-bond iron scavenging strategies. Our finings not only provided dynamic mechanistic views of the iron competition but also highlighted the potential regulatory schemes in fungal pathogenesis. Each fish was intraperitoneally injected with C. albicans cells and these infected fish were collected at 0.5, 1, 2, 4, 6, 8, 12, 16, 18 hpi. 0.625M-NM-<g of Cy3 cRNA for C. albicans array and 1.65 M-NM-<g of Cy3 cRNA for zebrafish array was fragmented to an average size of about 50-100 nucleotides by incubation with fragmentation buffer at 60M-BM-0C for 30 minutes. Each time points contain three biological repeat. For C. albicans array, each biological repeat has two technical replicate.

Project description:The interaction between fungal pathogen and host innnate and adaptive immunity during infection is a complex and dynamic process. To resolve this, we chose the zebrafish model organism as the host to study C. albicans infection via systems biology approach. Transcriptome microarray data and histological analysis of surviving fish were sampled at different post-infection time points. Time-course microarray data following primary and secondary infection of zebrafish by Candida albicans were obatined. From this set of data, we constructed two intracellular protein–protein interaction (PPI) networks for primary and secondary responses of the host.

Project description:The interaction between fungal pathogen and host innnate and adaptive immunity during infection is a complex and dynamic process. To resolve this, we chose the zebrafish model organism as the host to study C. albicans infection via systems biology approach. Transcriptome microarray data and histological analysis of surviving fish were sampled at different post-infection time points. Time-course microarray data following primary and secondary infection of zebrafish by Candida albicans were obatined. From this set of data, we constructed two intracellular proteinM-bM-^@M-^Sprotein interaction (PPI) networks for primary and secondary responses of the host. Each fish in the first group was intraperitoneally injected with 1 M-CM-^W 10E5 and 1 M-CM-^W 10E7 CFU C. albicans at day 0 and 14, respectively. These infected fish were collected at 1, 2, 3, 6, 14, 17.5, 21 dpi (day post infection). For the second group, a second injection of C. albicans was given on 14th day of the first infeciton, and the repeated infeceted fish were collected at 2, 6, 12, 18, 24, 30, 36, 42 hours post second injection. 1.65 M-NM-<g of Cy3 cRNA for zebrafish array was fragmented to an average size of about 50-100 nucleotides by incubation with fragmentation buffer at 60M-BM-0C for 30 minutes. Each time points contain two biological repeats.

Project description:Candida albicans is a commensal of the urogenital tract and the predominant cause of vulvovaginal candidiasis (VVC). Roughly, 70% of otherwise healthy women succumb to VVC at least once in their life time. Elevated oestrogen levels are associated with C. albicans colonisation of the vagina and symptomatic infection. However, little is known about how C. albicans adapts to oestrogen. Here, we investigate how adaptation of C. albicans to elevated concentrations of oestrogen on the C. albicans host-pathogen interaction. Growth of C. albicans in physiological relevant concentrations of oestrogen promoted fungal innate immune evasion through reduction of both macrophage and neutrophil phagocytosis. Oestrogen-induced innate immune evasion was mediated via inhibition of opsonophagocytosis through enhanced Gpd2 dependent acquisition of Factor H on the fungal cell surface. The zebrafish larval model of infection confirmed that in vivo oestrogen and Gpd2 promote pathogenicity. Understanding the impact of oestrogen on C. albicans host-pathogen interaction will help improve our knowledge on how oestrogen promotes VVC.

Project description:To understand the dynamic physiological changes in host and pathogen that occur during infection, some of which might be driving the ability of C. albicans to trigger macrophage cell death, we performed dual RNA-seq of C. albicans-infected bone marrow-derived mouse macrophages over a time course. We chose three time points corresponding to: (i) early events post-phagocytosis of C. albicans (approximately 1 h post infection), (ii) fungal escape following caspase 1-dependent pyroptosis (approximately 6 h post infection), and (iii) the transition to the rapid Phase II death (approximately 9 h post-infection).

Project description:The opportunistic fungal pathogen Candida albicans is a common cause of life-threatening nosocomial bloodstream infections. In the murine model of systemic candidiasis the kidney is the primary target organ while the fungal load declines over time in liver and spleen. To get a better understanding of the organ-specific differences in host-pathogen interaction during systemic murine candidiasis, we performed a time-course gene expression profiling to investigate the differential responses of murine kidney, liver and spleen and determined the fungal transcriptome in liver and kidney. We clearly demonstrate a delayed immune response on the transcriptional level in kidney accompanied by late induction of fungal stress response genes in this organ. In contrast, early upregulation of the proinflammatory response in the liver was associated with a fungal transcriptional profile resembling that of phagocytosed cells, suggesting that the resident phagocytic system contributes significantly to fungal control in the liver. Although no visible filamentation occurred in the liver, C. albicans hypha-associated genes were upregulated, indicating an uncoupling of gene expression and morphology during infection of this organ. In vitro the induction of hypha-associated gene expression in yeast cells led to altered interaction with macrophages, suggesting that the observed transcriptional changes affect host-pathogen interaction in vivo. Consistently, the combination of host and pathogen transcriptional data in an inference network model implied that C. albicans cell wall remodeling and metabolism were connected to the immune responses in kidney and liver. Furthermore, the network suggested links between fungal iron acquisition and amino acid metabolism in the kidney and host organ homeostasis. Thus, this work provides novel insights into the organ-specific host-pathogen interactions during systemic C. albicans infection.

Project description:The opportunistic fungal pathogen Candida albicans is a common cause of life-threatening nosocomial bloodstream infections. In the murine model of systemic candidiasis the kidney is the primary target organ while the fungal load declines over time in liver and spleen. To get a better understanding of the organ-specific differences in host-pathogen interaction during systemic murine candidiasis, we performed a time-course gene expression profiling to investigate the differential responses of murine kidney, liver and spleen and determined the fungal transcriptome in liver and kidney. We clearly demonstrate a delayed immune response on the transcriptional level in kidney accompanied by late induction of fungal stress response genes in this organ. In contrast, early upregulation of the proinflammatory response in the liver was associated with a fungal transcriptional profile resembling that of phagocytosed cells, suggesting that the resident phagocytic system contributes significantly to fungal control in the liver. Although no visible filamentation occurred in the liver, C. albicans hypha-associated genes were upregulated, indicating an uncoupling of gene expression and morphology during infection of this organ. In vitro the induction of hypha-associated gene expression in yeast cells led to altered interaction with macrophages, suggesting that the observed transcriptional changes affect host-pathogen interaction in vivo. Consistently, the combination of host and pathogen transcriptional data in an inference network model implied that C. albicans cell wall remodeling and metabolism were connected to the immune responses in kidney and liver. Furthermore, the network suggested links between fungal iron acquisition and amino acid metabolism in the kidney and host organ homeostasis. Thus, this work provides novel insights into the organ-specific host-pathogen interactions during systemic C. albicans infection.

Project description:The opportunistic fungal pathogen Candida albicans is a common cause of life-threatening nosocomial bloodstream infections. In the murine model of systemic candidiasis the kidney is the primary target organ while the fungal load declines over time in liver and spleen. To get a better understanding of the organ-specific differences in host-pathogen interaction during systemic murine candidiasis, we performed a time-course gene expression profiling to investigate the differential responses of murine kidney, liver and spleen and determined the fungal transcriptome in liver and kidney. We clearly demonstrate a delayed immune response on the transcriptional level in kidney accompanied by late induction of fungal stress response genes in this organ. In contrast, early upregulation of the proinflammatory response in the liver was associated with a fungal transcriptional profile resembling that of phagocytosed cells, suggesting that the resident phagocytic system contributes significantly to fungal control in the liver. Although no visible filamentation occurred in the liver, C. albicans hypha-associated genes were upregulated, indicating an uncoupling of gene expression and morphology during infection of this organ. In vitro the induction of hypha-associated gene expression in yeast cells led to altered interaction with macrophages, suggesting that the observed transcriptional changes affect host-pathogen interaction in vivo. Consistently, the combination of host and pathogen transcriptional data in an inference network model implied that C. albicans cell wall remodeling and metabolism were connected to the immune responses in kidney and liver. Furthermore, the network suggested links between fungal iron acquisition and amino acid metabolism in the kidney and host organ homeostasis. Thus, this work provides novel insights into the organ-specific host-pathogen interactions during systemic C. albicans infection.