Project description:A combinatorial attack strategy uncovers a molecular rationale for treating inflammatory cardiomyopathy

Project description:We performed a systematic computational network-based analysis of large-scale F. verticillioides RNA-seq datasets to identify gene subnetwork modules associated with virulence and fumonisin regulation.

Project description:Using RNA-Seq datasets, we identified subnetwork modules (group of genes) and key functional (hub) genes associated with the fungal pathogenicity by developing a computational pipeline with network-based comparative analusis approach

Project description:To validate the predicted Sh2b3 derived gene regulatory subnetwork using integrative network approach in human population study, we examined the gene expression levels of whole blood in WT (wild-type) and Sh2b3-/- mice by RNA sequencing, and identified the differentially expressed genes. RNA sequencing whole blood samples from 4 WT and 4 Sh2b3-/- mice.

Project description:Glioblastoma multiforme (GBM) is the most aggressive type of brain tumor with poor survival rate and temozolomide (TMZ) has been used as the standard chemotherapy for GBM treatment. However, a large number of patients either respond poorly to TMZ and/or develop resistance after long-term use, urging the need for the development of potent drugs with novel mechanisms of action. Here, using high-throughput compound screening (HTS), we found azathioprine, an immunosuppressive medication, to be a promising therapeutic agent for TMZ-resistant GBM treatment. Through integrative genome-wide analysis and global proteomic analysis, we identified the elevated lipid metabolism due to hyperactive EGFR/AKT/SREBP-1 signaling pathway being inhibited by azathioprine. In addition, azathioprine causes ER stress-induced apoptosis. Orthotopic xenograft models injected with patient-derived GBM cells exhibits reduced tumor volumes and increased apoptosis by azathioprine. These overall data indicate that azathioprine could be a powerful therapeutic option for TMZ-resistant GBM patients.

Project description:Glioblastoma multiforme (GBM) is the most aggressive type of brain tumor with poor survival rate and temozolomide (TMZ) has been used as the standard chemotherapy for GBM treatment. However, a large number of patients either respond poorly to TMZ and/or develop resistance after long-term use, urging the need for the development of potent drugs with novel mechanisms of action. Here, using high-throughput compound screening (HTS), we found azathioprine, an immunosuppressive medication, to be a promising therapeutic agent for TMZ-resistant GBM treatment. Through integrative genome-wide analysis and global proteomic analysis, we identified the elevated lipid metabolism due to hyperactive EGFR/AKT/SREBP-1 signaling pathway being inhibited by azathioprine. In addition, azathioprine causes ER stress-induced apoptosis. Orthotopic xenograft models injected with patient-derived GBM cells exhibits reduced tumor volumes and increased apoptosis by azathioprine. These overall data indicate that azathioprine could be a powerful therapeutic option for TMZ-resistant GBM patients.

Project description:To validate the predicted Sh2b3 derived gene regulatory subnetwork using integrative network approach in human population study, we examined the gene expression levels of whole blood in WT (wild-type) and Sh2b3-/- mice by RNA sequencing, and identified the differentially expressed genes.

Project description:Expression profiling of 559T(proneural subtype of glioblastoma), 592T(mesenchymal subtype of glioblastoma) and normal human astrocyte (NHA) Glioblastoma multiforme (GBM) is the most aggressive type of brain tumor with poor survival rate and temozolomide (TMZ) has been used as the standard chemotherapy for GBM treatment. However, a large number of patients either respond poorly to TMZ and/or develop resistance after long-term use, urging the need for the development of potent drugs with novel mechanisms of action. Here, using high-throughput compound screening (HTS), we found azathioprine, an immunosuppressive medication, to be a promising therapeutic agent for TMZ-resistant GBM treatment. Through integrative genome-wide analysis and global proteomic analysis, we identified the elevated lipid metabolism due to hyperactive EGFR/AKT/SREBP-1 signaling pathway being inhibited by azathioprine. In addition, azathioprine causes ER stress-induced apoptosis. Orthotopic xenograft models injected with patient-derived GBM cells exhibits reduced tumor volumes and increased apoptosis by azathioprine. These overall data indicate that azathioprine could be a powerful therapeutic option for TMZ-resistant GBM patients.

Project description:Purpose: Epigenetic regulation contributes to pathogenesis of neurondegenerative disease. We found that dis-regulation of a 242-gene subnetwork related to DNA methylation regulated neuronal differentiation are common in AD and HD. There are two DNA methyltransferases, DNMT1 and DNMT3A, in the subnetwork. DNMT1 is one of top hub genes in the network and likely to play a key regulatory role in the subnetwork. To validate that DNMT1 is a key regulator for the subnetwork, and DNMT3A not as one, we constructed two brain-specific conditional knockout mice. Methods: Cortices were dissected from Dnmt1 conditional knockout (CKO), Dnmt3a CKO, and respective littermate control mice at 18 weeks. RNA was isolated from three biological replicates for each genotype using TRIzol (Invitrogen) extraction and isopropanol precipitation. RNA samples were resuspended in water and further purified with RNeasy columns with on-column DNase treatment (Qiagen). RNA purity was assessed by measuring the A260/A280 ratio using a NanoDrop and RNA quality checked using an Agilent 2100 Bioanalyzer (Agilent Technologies). Approximately 250 ng of total RNA per sample were used for library construction by the TruSeq RNA Sample Prep Kit (Illumina) and sequenced using the Illumina HiSeq 2500 instrument according to the manufacturer's instructions. Sequence reads were aligned to mouse genome assembly mm10 and quantified using Cufflinks. Results: Genes differentially expressed in CKO mice compared to littermate control mice, or the Dnmt1 CKO signature, including GSN (the genes with the largest number of connection in the subnetwork) and SOX10 (a key transcription factor of myelination), significantly overlaps with the subnetwork. Broadly, the Dnmt1 CKO signature is enriched for genes involved in GO biological processes immune response, lipid metabolism, endocytosis, glial cell differentiation, and nerve ensheatment, consistent with biological function of the subnetwork. Moreover, the Dnmt1 CKO mice show increased predilection to seizures, an incidence also increased in patients with AD (Amatniek et al, 2006) as well as juvenile form of HD (Cloud et al, 2012). In contrast, the Dnmt3a CKO signature does not overlap with the subnetwork (p=0.07) and is not enriched for any GO biological process. Conclusions: These results suggest the Dnmt1 regulates common genes related with AD and HD while Dnmt3a has little effect. All of the mice used in this study were handled in accordance with IACUC-approved protocols. Dnmt1flox/flox (Fan et al, 2001; Jackson-Grusby et al, 2001) and Dnmt3aflox/flox (Nguyen et al, 2007) mice were backcrossed onto a C57BL/6 background and crossed with Olig1-cre mice to generate Dnmt1 conditional knockout (Olig1cre/+;Dnmt1flox/flox) and littermate control (Olig1+/+;Dnmt1flox/flox) mice, and Dnmt3a conditional knockout (Olig1cre/+;Dnmt3aflox/flox) and littermate control (Olig1+/+;Dnmt3aflox/flox) mice.

Project description:The therapeutic potential of neurotrophic factors has been hampered by their inability to achieve adequate tissue penetration. Brain blood vessels, however, could be an alternative target for neuro-salvage therapies by virtue of their close proximity to neurons. Here we show that hemizygous deletion of Rac1 in mouse endothelial cells (ECs) attenuates brain injury and edema following focal cerebral ischemia. To explore the mechanisms whereby decrease of Rac1 in ECs provide neuroprotection, ECs were derived from Rac1+/+ and Rac1+/- mice. Microarray analysis was performed to determine the differential gene expression between Rac1+/+ and Rac1+/- ECs. Rac1+/+ and Rac1+/- ECs were cultured to subconfluence. Total RNA was extracted and reverse transcribed. Rac1+/+ (n = 2) and Rac1+/- (n = 2) EC cDNAs were labeled with Cy3 and Cy5, respectively, and equimolar mixtures of labeled Rac1+/+ and Rac1+/- probes were hybridized to 2 slides (sample #21648, #21649). Additionally, Rac1+/+ (n = 2) and Rac1+/- (n=2) EC cDNAs labeled with Cy5 and Cy3 (dye-swapping) were hybridized to 2 slides (sample #21650, #21651). Comparison of signal intensities between Rac1+/+ (channel 2) and Rac1+/- (channel 1) was conducted on each slide (sample), and the ratio of intensities from 4 slides were statistically assessed for each gene feature to investigate differential gene expression.