Single-cell proteomics of human bone marrow, FACS panel 2
Acne meta-analysis
Background: Short-Term Fasting (STF) is an intervention reducing the intake of calories, without causing undernutrition or micronutrient-related malnutrition. It aims to systemically improve resilience against acute stress. Several (pre-)clinical studies have suggested protective effects of STF, marking the systemic effects STF can induce in respect to surgery and ischemia-reperfusion injury. In addition, STF also affects the number of circulating immune cells. We aim to determine the effect of STF on the abundance and phenotype of different immune cell populations. Methods: Thirty participants were randomly selected from the FAST clinical trial, including living kidneys donors, randomised to a STF-diet or control arm. In an observational cohort sub-study we prospectively included 30 patients who donated blood samples repeatedly during study runtime. Using flow cytometry analyses, immune cell phenotyping was performed on peripheral blood mononuclear cells. Three panels were designed to investigate the presence and activation status of peripheral T cells, B cells, dendritic cells (DCs) and myeloid cells. Results: Eight participants were excluded due to sample constraints. Baseline characteristics showed no significant differences, except for fasting duration. Weight changes were minimal and non-significant across different time intervals, with slight trends towards long-term weight loss pre-surgery. Glucose, insulin, and β-hydroxybutyrate levels differed significantly between groups, reflecting adherence to the fasting diet. Flow cytometry analysis revealed no baseline differences between groups, with high variability within each group. We observed significant changes in immune cell populations due to fasting, particularly in B cells, T cells, and DCs. Discussion: In this study, we found that STF changes the levels and phenotype of immune cells, reducing abundance and activation of T cells and regulatory T cells, increased presence of (naïve) B cells, and elevation of type 1 conventional DCs. Further research should focus on the clinical implications of the changes in immune cell populations and significance of these observed immunological changes. Background: Short-Term Fasting (STF) is an intervention reducing the intake of calories, without causing undernutrition or micronutrient-related malnutrition. It aims to systemically improve resilience against acute stress. Several (pre-)clinical studies have suggested protective effects of STF, marking the systemic effects STF can induce in respect to surgery and ischemia-reperfusion injury. In addition, STF also affects the number of circulating immune cells. We aim to determine the effect of STF on the abundance and phenotype of different immune cell populations. Methods: Thirty participants were randomly selected from the FAST clinical trial, including living kidneys donors, randomised to a STF-diet or control arm. In an observational cohort sub-study we prospectively included 30 patients who donated blood samples repeatedly during study runtime. Using flow cytometry analyses, immune cell phenotyping was performed on peripheral blood mononuclear cells. Three panels were designed to investigate the presence and activation status of peripheral T cells, B cells, dendritic cells (DCs) and myeloid cells. Results: Eight participants were excluded due to sample constraints. Baseline characteristics showed no significant differences, except for fasting duration. Weight changes were minimal and non-significant across different time intervals, with slight trends towards long-term weight loss pre-surgery. Glucose, insulin, and β-hydroxybutyrate levels differed significantly between groups, reflecting adherence to the fasting diet. Flow cytometry analysis revealed no baseline differences between groups, with high variability within each group. We observed significant changes in immune cell populations due to fasting, particularly in B cells, T cells, and DCs. Discussion: In this study, we found that STF changes the levels and phenotype of immune cells, reducing abundance and activation of T cells and regulatory T cells, increased presence of (naïve) B cells, and elevation of type 1 conventional DCs. Further research should focus on the clinical implications of the changes in immune cell populations and significance of these observed immunological changes.
The data is for non-commercial use only.
This dataset includes DNA methylation profiles from 112 young with Type 1 Diabetes (T1D) at T1D diagnosis, who were longitudinally monitored for hyperglycemia over an average duration of 3 years. These datasets were generated using whole-genome bisulfite sequencing. It includes 1872 fastq files (i.e. 936 paired-end fastq files) generated through 150 bp paired-end sequencing on Illumina HiSeqX.
Whole exome sequencing (WES) was performed on baseline (before low-dose 5-aza treatment) blood and tumor paired samples from 12 participants with head and neck cancer who were refractory to anti-PD-1 therapy. DNA extractions were performed by the Broad Institute of MIT and Harvard using Qiagen AllPrep DNA/RNA kits (Cat. 80204). In total, 24 150-bp pair-end WES data were generated by Illumina.
Single cell sequencing of expanded regulatory T cells (Tregs) in 8 APS-1 patients and 8 age and gender matched controls (same patients and controls as for global gene expression and TCR sequencing, excluding one for each group (control sample and patient sample #13)). Each Sample has two technical repeats. 10x Genomics Target Hybridization Kit and Human Immunology Panel was used with GEX libraries.
These samples were sequenced at the Broad Institute on an Illumina HiSeqX at 30x -- PCR Free. The CRAMS and VCF are as produced by Broad. The VCFs produced were generated by the Broad using GATK.
To investigate chromatin accessibility in ccRCC, we performed ATAC-seq in 3 ccRCC cell lines (786-O, A498, UMRC-2), and 1 normal kidney epithelium cell line (HK-2), cultured under normoxic (20% O2) and hypoxic (0.05% O2) conditions
10X genomics chromium single-cell ATAC+RNA (Multiome) was use to prepare single-nucleus RNA- and ATAC-seq libraries, sequenced on an Illumina NovaSeq 6000 platform. BAM files are provided. Samples from 6 donors were sequenced after sorting for primitive HSPCs in 5 libraries; each library comprises a single donor, except one with cells from 1 male and 1 female donor.
