Project description:Background: Skin aging is associated with intrinsic processes that compromise structure of the extracellular matrix while promoting loss of functional and regenerative capacity. These processes are accompanied by a large-scale shift in gene expression, but underlying mechanisms are not understood and conservation of these mechanisms between humans and mice is uncertain. Results: We used genome-wide expression profiling to investigate the aging skin transcriptome. In humans, age-related shifts in gene expression were sex-specific. In females, aging increased expression of transcripts associated with T-cells, B-cells and dendritic cells, and decreased expression of genes in regions with elevated Zeb1, AP-2 and YY1 motif density. In males, however, these effects were contrasting or absent. When age-associated gene expression patterns in human skin were compared to those in tail skin from CB6F1 mice, overall human-mouse correspondence was weak. Moreover, inflammatory gene expression patterns were not induced with aging of mouse tail skin, and well-known aging biomarkers were in fact decreased (e.g., Clec7a, Lyz1 and Lyz2). These unexpected patterns and weak human-mouse correspondence may be due to decreased abundance of antigen presenting cells in mouse tail skin with age. Conclusions: Aging is generally associated with a pro-inflammatory state, but we have identified an exception to this pattern with aging of CB6F1 mouse tail skin. Aging therefore does not uniformly heighten inflammatory status across all mouse tissues. Furthermore, we identified both intercellular and intracellular mechanisms of transcriptome aging, including those that are sex- and species-specific. We used Affymetrix microarrays to evaluate genome-wide expression in tail skin from young (5 month) and old (30 month) CB6F1 mice (males and females). Genome-wide expression was evaluated in tail skin from young (5 months) and old (30 months) CB6F1 mice of both sexes. Samples were collected simultaneously but RNA samples were processed in two separate batches.

Project description:Aging in multicellular organisms is characterized by gradual decline of organ functionality. To study the aging process, we used mRNA sequencing (mRNA-seq) to identify gene expression changes during aging in healthy mice. Skeletal muscle tissues of wild-type mice at 3 months and 24 months of age were collected and mRNA-seq libraries were prepared and sequenced on a HiSeq2500 by single-end sequencing with 100 bp read length. Analysis of the expression profiles of aged skeletal muscle tissues showed decreased mRNA levels of genes function in lipid metabolism, peptidase activity and response to stimulus.

Project description:To gain new insights into molecular changes in skeletal muscle aging and disease with a special focus on differential alternative splicing and senescence, we performed RNA-seq on tibialis muscles from 15 months old (adult, a) and 27 months old (old, o) rats. Whole (w) muscle samples were prepared for both age groups (w/a and w/o). Additionally, for both age groups, muscle fibers were isolated. For adult rats, this resulted in one group (f/a). For old rats, fibers were subjected to Laser capture microdissection guided by expression of aging markers Tmem158 and Cdkn1a, giving rise to two groups, aging marker-positive fibers (f/o+) and aging marker-negative fibers (f/o-). The entire experiment comprises 5 groups (w/a, w/o, f/a, f/o+, f/o-), with 5 animals per group, ie. 25 samples total.

Project description:Aging human skin undergoes significant morphological and functional changes such as wrinkle formation, reduced wound healing capacity, and altered epidermal barrier function. Besides known age-related alterations like DNA-methylation changes, metabolic adaptations have been more recently linked to impaired skin function in old humans. Understanding of these metabolic adaptations in aged skin are of special interest, because topical treatments could reverse age-dependent metabolic changes of human skin in vivo to affect age associated skin disorders. Results: We investigated the global metabolic adaptions in human skin during aging with a combined transcriptomic and metabolomic approach applied to epidermal tissue samples of young and old human volunteers. Our analysis confirmed known age-dependent metabolic alterations, e.g. reduction of coenzyme Q10 levels, and also revealed novel age effects that are seemingly important for skin maintenance. Integration of donor-matched transcriptome and metabolome data highlighted transcriptionally-driven alterations of metabolism during aging such as altered activity in upper glycolysis and glycerolipid biosynthesis or decreased protein and polyamine biosynthesis. Together, we identified several age-dependent metabolic alterations that might affect cellular signaling, epidermal barrier function, and skin structure and morphology. Conclusion: Our study provides a global resource on the metabolic adaptations and its transcriptional regulation during aging of human skin. Thus, it represents a first step towards an understanding of the impact of metabolism on impaired skin function in aged humans and therefore will potentially lead to improved treatments of age related skin disorders

Project description:A gradual decline in renal function occurs even in healthy aging individuals. In addition to aging per se, concurrent metabolic syndrome and hypertension, which are common in the aging population, can induce mitochondrial dysfunction, and inflammation, which collectively contribute to age-related kidney disease. Here we studied the role of the nuclear hormone receptors, the estrogen related receptors (ERRs) in regulation of age-related mitochondrial dysfunction and inflammation. ERRs are decreased in aging human and mouse kidneys and preserved in aging mice with lifelong caloric restriction (CR). Our studies identified ERRs as important modulators of age-related mitochondrial dysfunction and inflammation. ERRα, ERRβ, and ERRγ levels are decreased in the aging kidney. Remarkably, only a 4-week treatment of 21-month-old mice with the pan ERR agonist reversed the age-related increases in albuminuria and podocyte loss, mitochondrial dysfunction and inflammatory cytokines, including the cGAS-STING and STAT3 signaling pathways. A 3-week treatment of 21-month-old mice with a STING inhibitor reversed the increases in inflammatory cytokines and the senescence marker p21 but also unexpectedly reversed the age-related decreases in PGC-1α, ERRα, mitochondrial complexes and Mcad expression.

Project description:Age-related decline in brain endothelial cell (BEC) function critically contributes to cerebrovascular and neurodegenerative disease. Comprehensive atlases of the BEC transcriptome have become available but results from proteomic profiling are lacking. To gain insights into endothelial pathways affected by aging, we developed a magnetic-activated cell sorting (MACS)-based mouse BEC enrichment protocol compatible with high-resolution mass-spectrometry based proteomics. In this experiment, first we have compared MACS sorted BECs across multiple time points between 3 and 18 months of age. Using unsupervised cluster analysis, we found a segregation of age-related protein dynamics with biological functions including a downregulation of vesicle-mediated transport. Our approach uncovered changes not picked up by transcriptomic studies such as accumulation of vesicle cargo and receptor ligands including Apoe. Therefor in our next proteomics experiment we compared BECs from 3-months-old Apoe-KO and WT mice and found 111 and 103 proteins to be up- and downregulated, respectively. Comparing the BEC proteomic signature of young Apoe-KO mice with the signature of aged (18-months-old) WT mice we found a positive correlation suggesting an accelerating effect of Apoe deficiency on BEC aging.

Project description:Skin aging is a process of structural and compositional remolding that can be manifested as wrinkling and sagging. Remarkably, the dermis plays a dominant role in the process of skin aging. Recent studies suggest that microRNAs (miRNAs) may play a role in the regulation of gene expression in organism aging. However, studies about age-related miRNAs in human skin remain limited. In order to obtain an overall view of miRNAs expression in human aged dermis, we have investigated the alteration of microRNAs during aging by examining biopsies of human dermis from 12 young and aged donors, and demonstrated that numerous microRNAs showed significant alteration in dermis tissue. Normal human dermal tissue from 12 consenting individuals. Old group vs young group. Old group: with the age over 60 years old; young group: with the age below 10 years old; each group was constituted of 6 individuals.

Project description:In the human hematopoietic system, aging is associated with decreased bone marrow cellularity, decreased adaptive immune system function, and increased incidence of anemia and other hematological disorders and malignancies. Recent studies in mice suggest that changes within the hematopoietic stem cell (HSC) population during aging contribute significantly to the manifestation of these age-associated hematopoietic pathologies. While the mouse HSC population has been shown to change both quantitatively and functionally with age, changes in the human HSC and progenitor cell populations during aging have not yet been characterized. Gene expression profiling revealed that aged human HSC transcriptionally up-regulate genes associated with cell cycle, myeloid lineage specification, and myeloid malignancies. These age-associated alterations in the frequency, function, and gene expression profile of human HSC are significantly similar to those changes observed in mouse HSC, suggesting that hematopoietic aging is an evolutionarily conserved process.

Project description:An effective healing response is critical to healthy aging. Thus, the connection of regeneration and aging is needed to understand the complicated age-related healing process. Energy metabolism has been a common hallmark of both studies. In recent years, it become an emerging factor of skin homeostasis. Adenine nucleotide translocase-2 (ANT2) is a known cell proliferation marker and mediator of ATP import into mitochondria for energy homeostasis. Although energy homeostasis and the maintenance of mitochondrial function are critical for wound healing, the role of ANT2 in wound healing has not been elucidated. We found that ANT2 expression decreased during aging in mouse skin as well as during cellular senescence. Interestingly, overexpression of ANT2 in aged mouse skin promoted the healing of full-thickness cutaneous wounds. In addition, upregulation of ANT2 in replicative senescent human diploid dermal fibroblasts (HDFs) induced cell proliferation and migration, which are critical for the wound healing process. Furthermore, overexpression of ANT2 increased ATP production rate by activating the glycolysis pathway and also increased mitophagy, both of which are involved in energy homeostasis. Notably, ANT2-mediated upregulation of HSPA6 in aged HDFs inhibited the expression of pro-inflammatory genes that mediate cellular senescence and mitochondrial damage. This study demonstrates a new physiological role of ANT2 in skin wound healing via regulation of cell proliferation, energy homeostasis, and inflammation. Thus, our study links energy metabolism to skin homeostasis and identifies a genetic factor for improving wound healing with aging model.

Project description:In the human hematopoietic system, aging is associated with decreased bone marrow cellularity, decreased adaptive immune system function, and increased incidence of anemia and other hematological disorders and malignancies. Recent studies in mice suggest that changes within the hematopoietic stem cell (HSC) population during aging contribute significantly to the manifestation of these age-associated hematopoietic pathologies. While the mouse HSC population has been shown to change both quantitatively and functionally with age, changes in the human HSC and progenitor cell populations during aging have not yet been characterized. Gene expression profiling revealed that aged human HSC transcriptionally up-regulate genes associated with cell cycle, myeloid lineage specification, and myeloid malignancies. These age-associated alterations in the frequency, function, and gene expression profile of human HSC are significantly similar to those changes observed in mouse HSC, suggesting that hematopoietic aging is an evolutionarily conserved process. In order to elucidate the properties of an aged human hematopoietic system that may predispose to age-associated hematopoietic dysfunction, we evaluated HSC and other hematopoietic progenitor populations from healthy, hematologically normal young and elderly human bone marrow samples. We found that aged human HSC increase in frequency, are less quiescent, and exhibit myeloid-biased differentiation potential compared to young HSC.