Project description:Diabetic neuropathy (DN) is a common complication of diabetes. While multiple pathways are implicated in the pathophysiology of DN, there are no specific treatments for DN and currently it is not possible to predict DN onset or progression. To examine gene expression signatures related to DN, microarray experiments were performed on a subset of human sural nerves collected during a 52-week clinical trial of acetyl-L-carnitine. A series of bioinformatics analyses analyzed differential gene expression and identified gene networks and pathways potentially responsible for the progression of DN. We identified 532 differentially expressed genes (DEGs) between patient samples with progressing or non-progressing DN, which were functionally enriched in pathways involving defense and inflammatory responses and lipid metabolism. A literature-derived co-citation network of the DEGs revealed gene sub-networks centered on apolipoprotein E (APOE), jun oncogene (JUN), leptin (LEP), serpin peptidase inhibitor E Type 1 (SERPINE1) and peroxisome proliferator-activated receptor gamma (PPARG). DEGs were used to predict DN progression in a test set of patients. Ridge-regression classification models with 14 DEGs achieved an overall accuracy of 92%, correctly classifying the progression status of 11 out of 12 patients. To our knowledge, this is the first study to identify transcriptional changes associated with DN progression in human sural nerves biopsies and describe their potential utility for molecular prediction of DN. Our results identifying the unique gene signature of patients with progressive DN will facilitate the development of new mechanism-based diagnostics and therapies. 18 progressor and 17 non-progressor at 52 weeks

Project description:We perfomed transcriptomic and methylomic analysis of sural nerve biopsies from type 2 diabetic patients with neuropathy. Sural nerve transcriptomic and methylomic profiles were integrated and subsequent biological meaning investigated using KEGG pathway analysis of overlapping differentially expressed genes (DEGs) and differentially methylated genes (DMGs). A gene interation network was also generated including DEGs and DMGs, and common biological pathways were identified.

Project description:We perfomed transcriptomic and methylomic analysis of sural nerve biopsies from type 2 diabetic patients with neuropathy. Sural nerve transcriptomic and methylomic profiles were integrated and subsequent biological meaning investigated using KEGG pathway analysis of overlapping differentially expressed genes (DEGs) and differentially methylated genes (DMGs). A gene interation network was also generated including DEGs and DMGs, and common biological pathways were identified.

Project description:A better understanding of the molecular mechanisms underlying the development and progression of diabetic neuropathy (DN) is essential for the design of mechanism-based therapies. We examined changes in global gene expression to define pathways regulated by diabetes in peripheral nerve. Microarray data for 24 week-old BKS db/db and db/+ mouse sciatic nerve were analyzed to define significantly differentially expressed genes (DEGs); DEGs were further used for functional enrichment analysis and network analysis to identify biological processes and pathways differentially regulated in the db/db nerve. Expression profile clustering was performed to identify co-expressed DEGs. A set of co-expressed lipid metabolism genes was used for promoter sequence analysis.We identified 4,017 DEGs; 2,122 genes were up-regulated and 1,895 genes were down-regulated in the db/db relative to the db+ samples. Over-represented biological processes identified by the functional enrichment analysis include cell cycle, lipid metabolic process, lipid transport, carbohydrate metabolic process, response to stress, apoptosis, axonogenesis and cell adhesion. Pathways regulated in the db/db nerve include lipid metabolism, carbohydrate metabolism, energy metabolism, PPAR signaling, apoptosis, and axon guidance. The majority of DEGs in the glycolysis, TCA cycle, oxidative phosphorylation, fatty acid metabolism, glycerolipid metabolism, mitochondrial fatty acid elongation, lipid transport, adipocytokine signaling, PPAR signaling, and apoptosis pathways are up-regulated, whereas most of the axonogenesis-related genes are down-regulated in db/db nerve. A network of DEGs based on their co-citation in literature identified regulatory relationship between Tnf-α and key genes from the regulated pathways. Promoter sequence analysis identified over-represented transcription factor binding site (TFBS) motifs in the promoter regions of twenty two co-expressed lipid metabolism-related genes suggesting coordinated regulation of these genes by multiple transcription factors (TF). Furthermore, TF binding to these TFBS and differentially regulated in our data are annotated with nervous system development and immune response suggesting possible co-regulation of lipid metabolism, nervous system development and stress response genes. Gene expression changes in our data are consistent with pathological characteristics observed in DN including axon degeneration and demyelination, and support existing hypotheses regarding hyperglycemia mediated nerve damage in DN. Our findings support the role of hyperglycemia-induced oxidative stress and ischemia in nerve injury. Our results also support the hypothesis of oxidized lipid-mediated nerve injury and increased mitochondrial oxidative stress in dyslipidemia. Moreover, our analyses revealed a possible co-regulation mechanism connecting hyperlipidemia, stress response and axonal degeneration. Microarray data for 24 week-old BKS db/db and db/+ mouse sciatic nerve were analyzed to define significantly differentially expressed genes

Project description:Discriminating between diabetic nephropathy (DN) and non-diabetic renal disease (NDRD) can help provide more specific treatments. However, there are no ideal biomarkers for their differentiation. Thus, the aim of this study was to identify biomarkers for diagnosing and predicting the progression of DN by investigating different salivary glycopatterns. LC-MS/MS were used to screen different glycopatterns in patients with DN or NDRD. Bioinformatics analyses were used to identify corresponding glycoproteins and predict their function

Project description:We report the transcriptome analysis of HEI-286 human Schwann cells and MiaPaCa-2 pancreatic cancer cells Nerves stimulate cancer progression for different cancer types, promoting both tumor growth and perineural invasion, a prominent process in pancreatic ductal adenocarcinoma. Yet little is known about how cells in the nerves contribute to cancer progression. Here we demonstrate that Schwann cells, the most abundant cell type in nerves, collectively function as tumor activated Schwann cell tracks (TASTs). Schwann cells in a 3D matrix organize into stellate tracks which serve as a conduit for cancer cell migration. TASTs actively promote pancreatic cancer dissemination during perineural invasion and neoneurogenesis. This key function of TASTs is induced by cancer cells triggering c-Jun activation of Schwann cells, analogous to the reprogramming that promotes nerve repair. In TASTs, dynamic Schwann cell processes wrap around and apply forces directly on cancer cells to enhance cancer motility. We define a model of cancer progression that relies upon collective Schwann cell behavior driven by c-Jun transcriptional reprogramming.

Project description:Two mouse lines, OE/+ and OE/OE were generated expressing graded elevation (6 fold and 28 fold, respectively) of c-Jun protein selectively in Schwann cells. The effects of this on global gene expression and cellular structure in uninjured nerves was analysed during development and in the adult. Changes in gene expression and cellular arrangements were mild but detectable in c-Jun OE/+ mice, while nerves in c-Jun OE/OE mice showed obvious de-myelination and gene expression changes, including up- and down-regulation of genes previously shown to be controlled by c-Jun in Schwann cells.

Project description:A better understanding of the molecular mechanisms underlying the development and progression of diabetic neuropathy (DN) is essential for the design of mechanism-based therapies. We examined changes in global gene expression to define pathways regulated by diabetes in peripheral nerve. Microarray data for 24 week-old BKS db/db and db/+ mouse sciatic nerve were analyzed to define significantly differentially expressed genes (DEGs); DEGs were further used for functional enrichment analysis and network analysis to identify biological processes and pathways differentially regulated in the db/db nerve. Expression profile clustering was performed to identify co-expressed DEGs. A set of co-expressed lipid metabolism genes was used for promoter sequence analysis.We identified 4,017 DEGs; 2,122 genes were up-regulated and 1,895 genes were down-regulated in the db/db relative to the db+ samples. Over-represented biological processes identified by the functional enrichment analysis include cell cycle, lipid metabolic process, lipid transport, carbohydrate metabolic process, response to stress, apoptosis, axonogenesis and cell adhesion. Pathways regulated in the db/db nerve include lipid metabolism, carbohydrate metabolism, energy metabolism, PPAR signaling, apoptosis, and axon guidance. The majority of DEGs in the glycolysis, TCA cycle, oxidative phosphorylation, fatty acid metabolism, glycerolipid metabolism, mitochondrial fatty acid elongation, lipid transport, adipocytokine signaling, PPAR signaling, and apoptosis pathways are up-regulated, whereas most of the axonogenesis-related genes are down-regulated in db/db nerve. A network of DEGs based on their co-citation in literature identified regulatory relationship between Tnf-α and key genes from the regulated pathways. Promoter sequence analysis identified over-represented transcription factor binding site (TFBS) motifs in the promoter regions of twenty two co-expressed lipid metabolism-related genes suggesting coordinated regulation of these genes by multiple transcription factors (TF). Furthermore, TF binding to these TFBS and differentially regulated in our data are annotated with nervous system development and immune response suggesting possible co-regulation of lipid metabolism, nervous system development and stress response genes. Gene expression changes in our data are consistent with pathological characteristics observed in DN including axon degeneration and demyelination, and support existing hypotheses regarding hyperglycemia mediated nerve damage in DN. Our findings support the role of hyperglycemia-induced oxidative stress and ischemia in nerve injury. Our results also support the hypothesis of oxidized lipid-mediated nerve injury and increased mitochondrial oxidative stress in dyslipidemia. Moreover, our analyses revealed a possible co-regulation mechanism connecting hyperlipidemia, stress response and axonal degeneration.

Project description:The mechanisms of diabetic neuropathy (DN) development and progression are not fully understood. We examined global gene expression in the sciatic nerve (SCN) of BKS-db/db mice at 8 and 24 weeks of age to identify genetic pathways altered in peripheral nerves at early and advanced stages of DN. The sets of differentially expressed genes were analyzed to identify enriched biological functions and regulated genetic pathways. Our results suggest that carbohydrate metabolism and lipid metabolism pathways are dysregulated in the db/db SCN at 8 weeks of age. Impairment of Schwann cell-extracellular matrix interaction and axon guidance occurs early in the development of DN, while neurotrophic support, neurotransmitter transport and axonogenesis are impaired at the advanced stage of DN. Gene expression changes also suggest that oxidative stress- and inflammation-mediated nerve damage occurs by 8 weeks. Our analysis identified mechanisms regulated in the early stages of DN. Additionally, interactions between genes from different pathways provide insight into potential relationships among the regulated pathways.

Project description:The mechanisms of diabetic neuropathy (DN) development and progression are not fully understood. We examined global gene expression in the sciatic nerve (SCN) of BKS-db/db mice at 8 and 24 weeks of age to identify genetic pathways altered in peripheral nerves at early and advanced stages of DN. The sets of differentially expressed genes were analyzed to identify enriched biological functions and regulated genetic pathways. Our results suggest that carbohydrate metabolism and lipid metabolism pathways are dysregulated in the db/db SCN at 8 weeks of age. Impairment of Schwann cell-extracellular matrix interaction and axon guidance occurs early in the development of DN, while neurotrophic support, neurotransmitter transport and axonogenesis are impaired at the advanced stage of DN. Gene expression changes also suggest that oxidative stress- and inflammation-mediated nerve damage occurs by 8 weeks. Our analysis identified mechanisms regulated in the early stages of DN. Additionally, interactions between genes from different pathways provide insight into potential relationships among the regulated pathways. RNA extracted from the SCN of four groups of mice: (8 week old db/db (n=8) or db/+ (n=8), and 24 week old db/db (n=6) or db/+ (n=7)) was hybridized to Affymetrix GeneChip microarrays. Gene expression for the two genotypes (db/db vs. db/+) was compared at each age. Gene expression at the early and advanced stages of DN (8 weeks vs. 24 weeks) was also compared for each genotype.