Project description:Health of endothelial cells (EC) is fundamental for function of vital organs. There is evidence accumulating that senescence of EC is associated with aging-related diseases. However, it has not been established whether EC senescence underlies the pathophysiology of aging. Here, we report a mouse model of EC senescence. Inactivation of telomerase (TERT) expression sets the stage for aging and predisposes cells to replicative senescence. TERT maintains telomere length and has telomere-independent effects on cell transcriptome and physiology. We generated mice with TERT gene knock-out (KO) specifically in EC. We analyzed EC from adipose tissues (AT) and skeletal muscle cells from Tert-EC-KO and control mice raised on either chow or high-calorie diet (HCD) and subjected them to RNA sequencing (RNAseq). Single cell RNAseq data were also obtained for subcutaneous and visceral AT. Preliminary analysis of data deposited online indicates that TERT KO induces premature cell senescence and dysfunction. Moreover, HCD feeding exacerbates the effect of TERT loss. We conclude that the Tert-EC-KO mice are a useful model to study EC senescence and its effects on aging-associated organ dysfunction.

Project description:Health of endothelial cells (EC) is fundamental for function of vital organs. However, it has not been established whether EC senescence underlies the pathophysiology of aging. Here, we report a mouse model of EC senescence. Inactivation of telomerase (TERT) expression sets the stage for aging and predisposes cells to replicative senescence. TERT maintains telomere length and has telomere-independent effects on cell transcriptome and physiology. We generated mice with TERT gene knock-out (KO) specifically in EC. We analyzed EC from adipose tissues (AT) and skeletal muscle cells from Tert-EC-KO and control mice raised on either chow or high-calorie diet (HCD) and subjected them to RNA sequencing (RNAseq). Single cell RNAseq data were also obtained for subcutaneous and visceral AT. Preliminary analysis of data deposited online indicates that TERT KO induces premature cell senescence and dysfunction. Moreover, HCD feeding exacerbates the effect of TERT loss. We conclude that the Tert-EC-KO mice are a useful model to study EC senescence and its effects on aging-associated organ dysfunction.

Project description:The binding and contribution of transcription factors (TF) to cell specific gene expression is often deduced from open-chromatin measurements to avoid cost and labour intensive TF ChIP-seq assays.It is important to develop reliable and fast computational methods for accurate TF binding prediction in open-chromatin regions (OCRs). Here, we report a novel segmentation-based method, TEPIC, to predict TF binding by combining sets of OCRs with position weight matrices.TEPIC can be applied to various open-chromatin data, e.g. DNaseI-seq and NOMe-seq, using either peaks or footprints as input.In addition to open-chromatin data, also Histone-Marks (HMs) can be used in TEPIC to identify candidate TF binding sites.TEPIC computes TF affinities and uses open-chromatin/HM signal intensity as quantitative measures of TF binding strength.Using machine learning techniques, we show that incorporating low affinity binding sites improves our ability to explain gene expression variability compared to the standard presence/absence classification of binding sites.Further, we show that both footprints and peaks capture essential TF binding events and lead to a good prediction performance.In our application, gene-based scores computed by TEPIC with one open-chromatin assay nearly reach the quality of several TF ChIP-seq datasets.Finally, we show that these scores correctly predict known transcriptional regulators as illustrated by the application to novel DNaseI-seq and NOMe-seq data for primary human hepatocytes and CD4+ T-cells, respectively.

Project description:The homeostasis of vascular endothelium is crucial for cardiovascular health and endothelial cell (EC) aging and dysfunction could negatively impact vascular function. Leveraging time-series transcriptomic data obtained from endothelial cells (ECs) subjected to physiological pulsatile flow versus pathophysiological oscillatory flow, we performed principal component analysis (PCA) to identify key genes contributing to divergent transcriptional states of ECs under distinct flow patterns. Through bioinformatics analysis, we identified that a long non-coding RNA (lncRNA) RAMP2- AS1 encoded on the antisense of RAMP2, a determinant of endothelial homeostasis and vascular integrity, is a novel regulator essential for EC homeostasis and function. Knockdown of RAMP2-AS1 inhibited EC angiogenesis and promoted EC senescence, as a result of extensive changes of EC transcriptome. Our study demonstrates an integrative approach to quantifying EC aging based on transcriptome changes, which also identified a number of novel regulators, including protein-coding genes and many lncRNAs involved EC functional modulation.

Project description:Chromatin structure plays a pivotal role in facilitating proper control of gene expression. The ability of transcription factors (TF) to bind cis-elements is often associated with accessible chromatin regions. Therefore, identification of these accessible regions throughout plant genomes is important to understanding the relationship between TF binding, chromatin status and the regulation of gene expression. Assay for Transposase Accessible Chromatin sequencing (ATAC-seq) is a recently developed technique used to map open chromatin zones in animal genomes. However, in plants, the existence of cell walls, subcellular organelles and the lack of stable cell lines have prevented routine application of this technique. Here, we describe an assay combining ATAC-seq with Fluorescence-Activated Nuclei Sorting (FANS) to identify and map open chromatin and TF-binding sites in plant genomes. FANS-ATAC-seq compares favorably with published DNaseI sequencing (DNase-seq) results and it only requires 500-50,000 nuclei for accurate identification of open chromatin states.

Project description:Vascular aging, which is characterized by brain endothelial cell (EC) senescence and dysfunction, is known to contribute to various age-related cerebrovascular and neurodegenerative diseases. However, the underlying mechanisms remain unclear. EC-derived microvesicles (EMVs) and exosomes (EEXs) retain the characteristics of parent cells and transfer their contents to modulate the functions of recipient cells, showing potential for evaluation or regulation of vascular aging. Here, as indicated by analyses of senescence-associated beta-galactosidase (SA-β-gal) staining, cerebral blood flow, blood–brain barrier function, aging-related markers and cognitive ability, we found that young primary EC (passage 2-4) released EMVs alleviated mouse cerebrovascular and brain aging more effectively than EEXs. Aged EC (passage 15-16) released EMVs were more effective than their released EEXs at exacerbating mouse cerebrovascular and brain aging. We further revealed that these EMVs regulated cerebrovascular and brain aging by transferring miR-17-5p and modulated EC senescence and function via the miR-17-5p/PI3K/Akt pathway. Clinically, the levels of plasma EMVs and their associated miR-17-5p (EMV-miR-17-5p) were significantly increased or decreased in elderly individuals and were closely correlated with reactive oxygen species (ROS) and vascular aging. Receiver operating characteristic (ROC) analysis revealed that the area under the curve (AUC) was 0.724 for EMVs, 0.77 for EMV-miR-17-5p and 0.815 for their combination for distinguishing vascular aging. Our results identified novel roles for EMVs and showed that these vesicles more effectively modulated vascular and brain aging than did EEXs by regulating EC functions through the miR-17-5p/PI3K/Akt pathway; thus, EMVs and EMV-miR-17-5p are promising biomarkers and therapeutic targets for vascular aging.

Project description:We identify transcription factor BACH1 as a master regulator in vascular cells during aging. BACH1 is upregulated in the aorta of old mice. We find BACH1 is located on open chromatin and BACH1 binds to CDKN1A gene enhancer and activates its transcription in endothelial cells. Finally, BACH1 aggravates endothelial cell senescence under oxidative stress. Thus, these findings demonstrate a crucial regulatory role of BACH1 in vascular aging.

Project description:Gene expression profiling of HUVEC (human umbilical vein EC cell; Lonza), HAEC (human aortic EC cells), HCAEC (human coronary artery EC cells), HPAEC (human pulmonary artery EC cells), HMVEC (human microvascular (dermal) , HASMC ( Human Aortic Smooth Muscle Cells), T cells and Bcells.

Project description:Enteroendocrine cells (EECs) secrete serotonin (enterochromaffin [EC] cells) or specific peptide hormones (non-EC cells) that serve vital metabolic functions. The basis for terminal EEC diversity remains obscure. By forcing activity of the transcription factor (TF) NEUROG3 in 2D cultures of human intestinal stem cells, we replicated physiologic EEC differentiation and examined transcriptional and cis-regulatory dynamics that culminate in discrete cell types. Abundant EEC precursors expressed stage-specific genes and TFs. Before expressing pre-terminal NEUROD1, post-mitotic precursors oscillated between transcriptionally distinct ASCL1+ and HES6hi cell states. Loss of either factor accelerated EEC differentiation substantially and disrupted EEC individuality; ASCL1 or NEUROD1 deficiency had opposing consequences on EC and non-EC cell features. These TFs mainly bind cis-elements that are accessible in undifferentiated stem cells, and they tailor subsequent expression of TF combinations that underlie discrete EEC identities. Thus, early TF oscillations retard EEC maturation to enable accurate diversity within a medically important cell lineage.

Project description:Gene expression profiling of HUVEC (human umbilical vein EC cell; Lonza), HAEC (human aortic EC cells), HCAEC (human coronary artery EC cells), HPAEC (human pulmonary artery EC cells), HMVEC (human microvascular (dermal) , HASMC ( Human Aortic Smooth Muscle Cells), T cells and Bcells. Gene expression profiling of Endothelial cells and Non-endothelial cells in order to identify the genes with preferntial expression to endothelial cells. The experiments are performed in duplicate on both the HT Human Genome U133A and U133B arrays.