Project description:Primary afferent collateral sprouting (PACS) is a process whereby non-injured primary afferent neurons respond to some stimulus by extending new branches from existing axons. In the model used here (spared dermatome), the intact sensory neurons respond to the denervation of adjacent areas of skin by sprouting new axon branches into that adjacent denervated territory. Neurons of both the central and peripheral nervous systems undergo this process, which contributes to both adaptive and maladaptive plasticity. Investigations of gene expression changes associated with PACS can provide a better understanding of the molecular mechanisms controlling this process. Consequently, it can be used to develop treatment for spinal cord injury to promote functional recovery. In this study, we sought to identify gene expression changes in PACS using 20 Affymetrix Rat Genome 230 2.0 microarrays. The experiments were designed to discover global gene expression changes in non-injured DRG neurons undergoing PACS. T11 DRG neurons remained intact and undergo PACS after the cutaneous nerves of the adjacent segments (T9, T10, T12, and T13) were injured and regeneration of those injured nerves prevented by ligation. Thus, the T9, T10, T12, and T13 dermatomes were denervated, but the T11 dermatome remained intact. Axons of the T11dermatome (and thus housed in the T11 dorsal root ganglion (DRG)), extended new branches to innervate the T9, T10, T12, and T13 dermatomes. N.B.: This is NOT a spared root experiment. ALL spinal roots were non-injured. Peripheral nerves were used. A total of 20 Affymetrix Rat Genome 230 2.0 microarrays were analyzed: six naïve controls, seven replicates at day 7 post-surgery (presumed to represent an â??initiation phaseâ??), and seven replicates at day 14 post-surgery (presumed to represent a â??maintenance phaseâ??). DRGs were NOT pooled onto microarrays. Each animal had its own microarray with T11 DRG sample which underwent 2-round amplification. After quality control analysis, one of the naïve control microarrays was removed from further analysis.

Project description:This study aimed to quantify the regulation of transcripts in the hairy skin of the back of adult rats in the condition of loss of sensory and autonomic (sympathetic) innervation (i.e., denervated). Denervated skin has reduced wound healing capacity, reduced proliferation of epidermal progenitor cells, and also expresses factors that regulate ingrowth of sensory and sympathetic axons from neighboring regions of innervated skin. It was expected that this quantification f transcript regulation would offer insight into the general and specific mechanisms that may contribute to these important biological processes. All animals were adult (200-250g) Sprague-Dawley female rats. Three conditions were examined. Groups were naive (n=6), 7-day denervated skin (n=5), and 14-day (n=5) denervated skin. Denervation preparations: Full-thickness incision along long-axis of the body 1cm to right of midline (to avoid injuring skin to be sampled). Incision was centered rostro-caudally on the T13 (thoracic 13) costo-vertebral angle so as to allow access to the T9-L2 (lumbar 2) cutaneous nerves. Skin was reflected to the left and the left T9, T10, L1, and L2 dorsal and lateral cutaneous nerves were isolated, ligated with 7-0 monofilament suture close to their exit from the body wall, and transected. Approximately 5mm of the distal portion of the nerve was resected. The T11 nerves were left unperturbed and were not isolated from the surrounding fascia. This generated two strips of skin that were devoid of sensory and autonomic innervation (those strips served by the T9 and T10 nerves, and by the L1 and L2 nerves). Between these denervated strips of skin was a strip of skin that retained the sensory and autonomic axons supplied by T11 nerves. The denervated zones were identified by mapping the cutaneous trunk muscle (CTM) reflex (see Petruska-JC et al. (2013) Journal of Comparative Neurology; Diamond-J et al., (1992) J Neuroscience), and the border marked with pen and remarked every few days. The samples were taken from the rostral (T9/10) denervated zone. Samples from naive animals (no denervation) were taken from the same region, using the dorsal cutaneous nerves as registration landmarks. Animals displayed no signs of overgrooming of the denervated skin. Because the CTM inserts onto the dermis of this region of skin, samples necessarily include both skin and underlying CTM (which is innervated from another source so was not denervated in the experiment).

Project description:This SuperSeries is composed of the following subset Series: GSE16598: Tumor T1 Sectors GSE16599: Tumor T2 Sectors GSE16600: Tumor T3 Sectors GSE16601: Tumor T4 Sectors GSE16602: Tumor T5 Sectors GSE16603: Tumor T6 Sectors GSE16604: Tumor T7 Sectors GSE16605: Tumor T8 Sectors GSE16606: Tumor T9 Sectors GSE16607: Tumor T10 Sectors GSE16608: Tumor T11 Sectors GSE16609: Tumor T12 Sectors GSE16610: Tumor T13 Sectors GSE16611: Tumor T14 Sectors GSE16663: Tumor T15 Sectors GSE16664: Tumor T16 Sectors GSE16665: Tumor T17 Sectors GSE16667: Tumor T18 Sectors GSE16668: Tumor T19 Sectors GSE16669: Tumor T20 Sectors ROMA CGH experiments were conducted on four to six dissected sectors (S1-S6) from single primary ductal carcinomas (T1-T20). T1-T4 were analyzed by sectoring and analysis by ROMA. T5-T20 were analyzed using the Sector-Ploidy-Profiling (SPP) Approach. SPP involves macro-dissecting the tumor, flow-sorting nuclei by differences in total genomic DNA content and profiling the genome of the tumor subpopulations. The genomic DNA from each tumor was labeled with Cy5 and a reference fibroblast genome was labeled with Cy3 and cohybridized to a ROMA microarray (85K or 390K). Experiments were performed in color-reversal by dye-swapping samples and hybridizing the labeled DNA to a second microarray for T1-T15 experiments, but not for T16-T20 experiments.

Project description:To further explore the expression of circRNA, lncRNA and mRNA in mice with spinal cord contusion injury, we have employed microarray analysis as a discovery platform to identify circRNAs and lncRNAs with the potential to play role in the pathophysiology process of secondary injuryd after spinal cord injury. Three days after spinal cord injuryI, eight mice (SCI group, n=4; sham group, n=4) were anesthetized and the T9-T10 spinal cord segments centered on and enclosing the injured site were collected. And then total RNA was extracted and used for microarray detection. Four circRNAs from the top 30 differently expressed circRNAs were selected for real-time PCR. The expression patterns of these circRNAs were consistent with the microarray data validating the expression pattern observed by microarray analysis.

Project description:apoE-deficient mice were fed a Western-type diet enriched with linoleic acid (control), cis-9, trans-11-CLA or trans-10, cis-12-CLA (1.0 % wt/wt) for 12 weeks and their hepatic gene expression was analysed using DNA microarrays Experiment Overall Design: Three experimental designs using different genetic models as well as dietary conditions were carried out. In the first experiment, twenty nine three month-old homozygous apoE knockout male mice with a C57BL/6JxOLA129 genetic background, bred at the Unidad Mixta de Investigación, Zaragoza, were randomly assigned to a control (n=10), c9,t11-CLA-enriched (n=10) or t10,c12-CLA-enriched (n=9) diet. All mice had similar baseline plasma cholesterol concentrations. The mice were fed the different experimental semi-purified diets for 12 weeks. All three diets were isocaloric and isonitrogenous; fat provided 30% of the energy intake. The control diet contained 1.0 % (wt/wt) linoleic acid while the others contained an equivalent amount of either c9,t11-CLA or t10,c12-CLA, as previously described. All diets were prepared by Unilever (Vlaardingen, The Netherlands) and stored in an N2 atmosphere at â??20ºC. Fresh food was provided daily

Project description:Objective: To quantify changes in adipogenic gene expression in the presence of ritonavir (RTV) or tenofovir (TDF), and determine whether conjugated linoleic acid (CLA) isomers (cis9,trans11 or trans10,cis12) can mitigate detrimental effects of antiretoviral drugs. Methods: Affymetrix Mouse Genome 430 2.0 microarray was used to investigate gene expression in 3T3-L1 adipocytes treated with (1) RTV, TDF or ethanol control, or (2) ritonavir +c9,t11-CLA, ritonavir+t10,c12-CLA or ritonavir+DMSO control. RT-PCR validation of Pparg, Adipoq and Retn was carried out. ELISA and DNA binding ELISA were used to investigate secreted proteins and Pparg binding to its gene response element. Oil Red O staining was used to investigate triglyceride accumulation. Results: No effect was observed for TDF. Expression of 389 genes was altered more than 5-fold in the presence of RTV. Down-regulated genes included Pparg, Adipoq, Retn, Cfd and Cidec. Pparg and Adipoq down-regulation were confirmed by RT-PCR. PPAR-γ binding to its gene response element, adiponectin protein secretion and triglyceride accumulation were decreased by RTV. t10,c12-CLA in the presence of RTV decreased the expression of Ppargand Adipoq in microarray and RT-PCR. c9,t11-CLA increased PPAR-γ binding to its gene response element. Both isomers increased triglyceride storage in the presence of RTV. Conclusion: Ritonavir altered genes involved in adipocyte differentiation, lipid accumulation and glucose metabolism. Down-regulation of Pparg may be mediated by changes in Cepba and regulatory genes Pparg1c and Nr1h3. 3T3-L1 adipocytes were treated with ritonavir (20μM; n=4), tenofovir (1μM; n=4) or vehicle control (ethanol 0.1%; n=4) for 5 days and in a second experiment with ritonavir (20 µM) +c9,t11-CLA (100μM; n=4), ritonavir (20 µM) +t10,c12-CLA (100μM; n=4) or ritonavir+fatty acid vehicle control (DMSO 0.1%; n=4) for 5 days.

Project description:Peripheral nerves provide a supportive growth environment for developing and regenerating axons and are essential for maintenance and repair of many non-neural tissues. This capacity has largely been ascribed to paracrine factors secreted by nerve-resident Schwann cells. Here, we used single-cell transcriptional profiling to identify ligands made by different injured rodent nerve cell types and have combined this with cell-surface mass spectrometry to computationally model potential paracrine interactions with peripheral neurons. These analyses show that peripheral nerves make many ligands predicted to act on peripheral and CNS neurons, including known and previously uncharacterized ligands. While Schwann cells are an important ligand source within injured nerves, more than half of the predicted ligands are made by nerve-resident mesenchymal cells, including the endoneurial cells most closely associated with peripheral axons. At least three of these mesenchymal ligands, ANGPT1, CCL11, and VEGFC, promote growth when locally applied on sympathetic axons. These data therefore identify an unexpected paracrine role for nerve mesenchymal cells and suggest that multiple cell types contribute to creating a highly pro-growth environment for peripheral axons.

Project description:Peripheral nerves provide a supportive growth environment for developing and regenerating axons and are essential for maintenance and repair of many non-neural tissues. This capacity has largely been ascribed to paracrine factors secreted by nerve-resident Schwann cells. Here, we used single-cell transcriptional profiling to identify ligands made by different injured rodent nerve cell types and have combined this with cell-surface mass spectrometry to computationally model potential paracrine interactions with peripheral neurons. These analyses show that peripheral nerves make many ligands predicted to act on peripheral and CNS neurons, including known and previously uncharacterized ligands. While Schwann cells are an important ligand source within injured nerves, more than half of the predicted ligands are made by nerve-resident mesenchymal cells, including the endoneurial cells most closely associated with peripheral axons. At least three of these mesenchymal ligands, ANGPT1, CCL11, and VEGFC, promote growth when locally applied on sympathetic axons. These data therefore identify an unexpected paracrine role for nerve mesenchymal cells and suggest that multiple cell types contribute to creating a highly pro-growth environment for peripheral axons.

Project description:Peripheral nerves provide a supportive growth environment for developing and regenerating axons and are essential for maintenance and repair of many non-neural tissues. This capacity has largely been ascribed to paracrine factors secreted by nerve-resident Schwann cells. Here, we used single-cell transcriptional profiling to identify ligands made by different injured rodent nerve cell types and have combined this with cell-surface mass spectrometry to computationally model potential paracrine interactions with peripheral neurons. These analyses show that peripheral nerves make many ligands predicted to act on peripheral and CNS neurons, including known and previously uncharacterized ligands. While Schwann cells are an important ligand source within injured nerves, more than half of the predicted ligands are made by nerve-resident mesenchymal cells, including the endoneurial cells most closely associated with peripheral axons. At least three of these mesenchymal ligands, ANGPT1, CCL11, and VEGFC, promote growth when locally applied on sympathetic axons. These data therefore identify an unexpected paracrine role for nerve mesenchymal cells and suggest that multiple cell types contribute to creating a highly pro-growth environment for peripheral axons.

Project description:Peripheral nerves provide a supportive growth environment for developing and regenerating axons and are essential for maintenance and repair of many non-neural tissues. This capacity has largely been ascribed to paracrine factors secreted by nerve-resident Schwann cells. Here, we used single-cell transcriptional profiling to identify ligands made by different injured rodent nerve cell types and have combined this with cell-surface mass spectrometry to computationally model potential paracrine interactions with peripheral neurons. These analyses show that peripheral nerves make many ligands predicted to act on peripheral and CNS neurons, including known and previously uncharacterized ligands. While Schwann cells are an important ligand source within injured nerves, more than half of the predicted ligands are made by nerve-resident mesenchymal cells, including the endoneurial cells most closely associated with peripheral axons. At least three of these mesenchymal ligands, ANGPT1, CCL11, and VEGFC, promote growth when locally applied on sympathetic axons. These data therefore identify an unexpected paracrine role for nerve mesenchymal cells and suggest that multiple cell types contribute to creating a highly pro-growth environment for peripheral axons.