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: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.

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: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:Two simulated nerve injury models in the rat tibial nerve were compared: the nerve was either cut (denervated, DN group) or crushed but with the nerve sheath intact (re-innervated, RN group). The control group had a preserved and intact tibial nerve. As the high expression of Myh3, Postn, Col6a1 and Cfi (nerve growth factors), the RN group demonstrated superior re-innervation as well. Both differentially expressed genes (DEGs) and proteins (DEPs) were enriched in the PPAR signaling pathway, as well as the energy metabolism.

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.

Project description:In a previous study, we found that H2S alleviates salinity stress in cucumber by maintaining the Na+/K+ balance and by regulating H2S metabolism and the oxidative stress response. However, little is known about the molecular mechanisms behind H2S-regulated salt-stress tolerance in cucumber. Here, an integrated transcriptomic and proteomic analysis based on RNA-seq and 2-DE was used to investigate the global mechanism underlying H2S-regulated salt-stress tolerance. In total, 11 761 differentially expressed genes (DEGs) and 61 differentially expressed proteins (DEPs) were identified. Analysis of the pathways associated with the DEGs showed that salt stress enriched expression of genes in primary and energy metabolism, such as photosynthesis, carbon metabolism and biosynthesis of amino acids. Application of H2S significantly decreased these DEGs but enriched DEGs related to plant-pathogen interaction, sulfur-containing metabolism, cell defense and signal transduction pathways. Notably, changes related to sulfur-containing metabolism and cell defense were also observed through proteome analysis, such as Cysteine synthase 1, Glutathione S-transferase U25-like, Protein disulfide-isomerase and Peroxidase 2. We present the first global analysis of the mechanism underlying H2S regulation of salt-stress tolerance in cucumber through tracking changes in the expression of specific proteins and genes.

Project description:We report the application of RNA sequencing technology for transcriptomics analysis of the effects of electrical stimulation on rat denervated gastrocnemius muscle. Muscle samples were selected for gene expression analyses，corresponding to the following categories: Sham operation rats, (SHAM, n = 3), sciatic nerve injury rats (DN, n = 3), and sciatic nerve injury with electrical stimulation (DN-SM, n = 3). A total of 14,334 genes (DEGs) were detected in this study.

Project description:To determine whether osmotic pressure affects the translation efficiency of Lactobacillus rhamnosus, the ribosome profiling assay was performed to analyze the changes in translation efficiency in L. rhamnosus ATCC 53103. Under osmotic stress, differentially expressed genes (DEGs) involved in fatty acid biosynthesis and metabolism, ribosome, and purine metabolism pathways were co-regulated with consistent expression direction at translation and transcription levels. DEGs involved in the biosynthesis of phenylalanine, tyrosine, and tryptophan, and the phosphotransferase system pathways also were co-regulated at translation and transcription levels, while they showed opposite expression direction at two levels. Moreover, DEGs involved in the two-component system, amino acid metabolism, and pyruvate metabolism pathways were only regulated at the transcription level. And DEGs involved in fructose and mannose metabolism were only regulated at the translation level. The translation efficiency of DEGs involved in the biosynthesis of amino acids was downregulated while in quorum sensing and PTS pathways was upregulated. In addition, the ribosome footprints accumulated in open reading frame regions resulted in impaired translation initiation and elongation under osmotic stress. In summary, L. rhamnosus ATCC 53103 could respond to osmotic stress by translation regulation and control the balance between survival and growth of cells by transcription and translation.

Project description:Diabetic nephropathy (DN) as a common complication of diabetes is the primary cause of end-stage renal disease. Sodium butyrate (NaB) is a short chain fatty acid in the metabolic products of intestinal bacterium, and its kidney protective effect has been reported in DN. However, its underlying mechanism remains unclear. The aim of the present study was to investigate the effect of NaB on globe transcriptome changes in DN. In our study, eight-week-male db/db mice which were established DN mice were randomly divided into two groups: the DN+NaB group (DN mice treated with NaB, 5g/kg/day) and the DN group (DN mice treated with saline). Also, the normal db/m mice were used as NC group. Further, blood glucose, body weight, urinary microalbumin and urinary creatinine of mice were measured in three groups. Whole-transcriptome analysis was performed by RNA sequencing (RNA-Seq) to evaluate profiling of lncRNAs and messenger RNAs (mRNAs). Bioinformatic analysis was performed to predict the potential NaB-related lncRNAs and genes in DN. The expressions of lncRNAs and mRNAs were tested by quantitative real-time polymerase chain reaction (qRT-PCR) in renal tissues and mesangial cells treated with NaB. The results of the present study demonstrated that NaB ameliorated renal dysfunction in DN mice. Moreover, RNA-Seq results identified that 17 lncRNAs and 180 mRNAs reversely changed in DN+NaB group when compared with those in DN group. Additionally, the integrated co-expression networks of NaB-related lncRNAs revealed these lncRNAs interacted with 155 key mRNAs. The co-expression networks of mRNAs associated to immune response, antigen processing and presentation and acute inflammatory response to antigenic stimulus. The qRT-PCR data showed that eight mRNAs and seven lncRNAs were dysexpressed by NaB in DN mice and mesangial cell under high glucose condition. Furthermore, the co-expression network of inflammation related lncRNAs and mRNAs demonstrated that those 17 reversed lncRNAs and 37 mRNAs also play essential roles in inflammatory response. In summary, the present study suggests that NaB ameliorates diabetes induced renal dysfunction and regulates transcriptome changes in DN. NaB related lncRNA-mRNA may play roles in the protective effect of NaB in DN.