Project description:The pathogen and host factors that contribute to the establishment of foot-and-mouth disease virus (FMDV) persistence are currently not understood. Using primary bovine soft palate multilayers in combination with RNA sequencing, we analyzed the transcriptional responses during acute and persistent FMDV infection.

Project description:Mid-cycle C. trachomatis differentially regulates a subset of genes in response to iron-starvation

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.

Project description:Transcriptional response of C.trachomatis to mid-cycle iron-starvation

Project description:Transcriptional response of C.trachomatis to early-cycle and mid-cycle iron-starvation

Project description:Nontypeable Haemophilus influenzae (NTHi) is a commensal microorganism of the normal human nasopharyngeal flora, yet also an opportunistic pathogen of the upper and lower respiratory tracts. Changes in gene expression patterns in response to host microenvironments are likely critical for persistence. One such system of gene regulation is the ability to carefully regulate iron uptake. A central regulatory system that controls iron uptake, mediated by the ferric uptake regulator Fur, is present in multiple bacteria, including NTHi. To understand the regulation of iron homeostasis in NTHi, fur was deleted in the prototypic NTHi clinical isolate, 86-028NP. Using an NTHi-specific microarray, we identified genes whose expression was repressed or activated by Fur. These data comprise transcriptional anaylses of a pediatric isolate of NTHi (86-028NP) an rpsL mutant of 86-028NP, a fur mutant of 86-028NP and a fur mutant of 86-028NPrpsL. NTHi parent and fur mutant strains were grown in defined medium containing 10 M-BM-5g /ml human hemoglobin to mid-log phase. Cells were then harvested and RNA extracted. A total of four biological replicates were generated for these analyses.

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 precise consequences for antiviral memory T cells (TM) generated early in life and allowed to age in the absence of pathogen persistence or potentially confounding heterologous infections remain to date largely unexplored. Here, we have employed microarray analyses to determine the gene expression profiles of LCMV-specific P14 CD8+ TM over a period of up to 400 days after an acute LCMV Armstrong infection.