Project description:Datasets of Arabidopsis thaliana samples used to test the MPLEx method

Project description:Datasets of unicyanobacterial community samples used to test the MPLEx method.

Project description:Datasets of Sulfolobus acidocaldarius samples used to test the MPLEx method.

Project description:Datasets of human urine samples used to test the MPLEx method.

Project description:Datasets of Shewanella oneidensis samples used to test the MPLEx method.

Project description:Datasets of Calu-3 cells used to test the MPLEx method.

Project description:This project consists in 3 datasets: - Samples from adult mouse brains (Hippocampus, Cortex and Cerebellum): Cul3 +/- or +/+; 5 animals per condition. - Samples from embryonic mouse cortex: either Cul3 +/- or +/+ - Samples from embryonic mouse cortex: Cul3 fl/fl Emx-1-Cre ("hom"); Cul3 +/fl Emx1-Cre ("het") or Cul3+/fl ("control")

Project description:Here we used mass spectrometry-based proteomics technology to explore SEPs with potential function in five brain regions of the mouse. SEPs with unique peptides were identified in hippocampus, frontal cortex, temporal cortex, occipital cortex and parietal cortex.

Project description:We used the Illumina 450KMethylation BeadChip to measure DNA methylation at 485,512 loci across the genome for 40 postmortem brain samples. The purpose of our study was to identify differentially methylated regions (DMRs) associated with autism. Samples included 16 temporal cortex brain tissue samples (6 cases and 10 controls), 11 prefrontal cortex brain tissue samples (6 cases and 5 controls), and 13 cerebellum brain tissue samples (7 cases and 6 controls).

Project description:Brain aging causes a progressive decline in functional capacity and is a strong risk factor for dementias such as Alzheimer’s disease. To characterize age-related proteomic changes in the brain, we used quantitative proteomics to examine brain tissues, cortex and hippocampus, of mice at three age points (3, 15, and 24 months old), and quantified more than 7,000 proteins in total with high reproducibility. We found that many of the proteins upregulated with age were extracellular proteins, such as extracellular matrix proteins and secreted proteins, associated with glial cells. On the other hand, many of the significantly downregulated proteins were associated with synapses, particularly postsynaptic density, specifically in the cortex but not in the hippocampus. Our datasets will be helpful as resources for understanding the molecular basis of brain aging.