Project description:This study focused on transcription in the medial PFC (mPFC) as a function of age and cognition. Young and aged F344 rats were characterized on tasks, attentional set shift and spatial memory, which depend on the mPFC and hippocampus, respectively. Differences in transcription associated with age and cognitive function were examined using RNA sequencing to construct transcriptomic profiles for the mPFC, white matter, and region CA1 of the hippocampus. The results indicate regional differences in vulnerability to aging associated with increased expression of immune and defense response genes and a decline in synaptic and neural activity genes. Importantly, we provide evidence for region specific transcription related to behavior. In particular, expression of transcriptional regulators and neural activity-related immediate-early genes (IEGs) are increased in the mPFC of aged animals that exhibit delayed set shift behavior; relative to age-matched animals that exhibit set shift behavior similar to younger animals. The study contains 11 young and 20 aged rats for the mPFC and CA1 samples, which were used to investigate expression patterns associated with aging and behavior. White matter samples were used to investigate an age-related effect with 8 young and 9 aged rats.

Project description:Aging is associated with progressive tissue dysfunction, leading to frailty and mortality. Characterizing aging features, such as changes in gene expression and dynamics, shared across tissues or specific to each tissue, is crucial for understanding systemic and local factors contributing to the aging process. We performed RNA-sequencing on 13 tissues at 6 different ages in the African turquoise killifish, the shortest-lived vertebrate that can be raised in captivity. This comprehensive, sex-balanced 'atlas' dataset reveals the varying strength of sex-age interactions across killifish tissues and identifies age-altered biological pathways that are evolutionarily conserved. Demonstrating the utility of this resource, we discovered that the killifish head kidney exhibits a myeloid bias during aging, a phenomenon more pronounced in females than in males. In addition, we developed tissue-specific 'transcriptomic clocks' and identified biomarkers predictive of chronological age. We show the importance of sex-specific clocks for selected tissues and use the tissue clocks to evaluate a dietary intervention in the killifish. Our work provides a comprehensive resource for studying aging dynamics across tissues in the killifish, a powerful vertebrate aging model.

Project description:With advancing age, senescent cells accumulate as they are not efficiently cleared by the immune system anymore. Via a senescence-associated secretory phenotype, chronic senescent cells alter the microenvironment, creating an unfavorable milieu for neurogenesis and neurorepair. Using an innovative and rapid aging model, the African turquoise killifish, we have previously demonstrated a dramatic decline in neurogenic potential of non-glial progenitors with age. Even after traumatic brain injury, progenitor proliferation and neuron production was very low in aged killifish in comparison to young adult killifish, and overall neurorepair was incomplete. In the present study, we validated if the senolytic cocktail dasatinib and quercetin (D+Q) could reboot the neurogenic output by clearing chronic senescent cells from the aged killifish brain to re-create the necessary supportive environment. Our results confirm that the aged killifish telencephalon holds a very high senescent cell burden, which we could diminish by short-term systemic D+Q treatment. As a consequence of D+Q administration, proliferation of non-glial progenitors increased and more new neurons were generated and migrated into the parenchyma after injury. Injury-induced inflammation and glial scarring, a phenomenon only seen in aged killifish, remained unaltered. Senolytic treatment with D+Q might thus hold promise for improving brain function in aged populations, and is especially interesting for reviving the neurogenic potential of an already aged central nervous system.

Project description:Killifish are among the shortest-lived vertebrates and are considered a promising model organism for aging. However, so far virtually nothing is known about its DNA methylome, which is frequently used for age and health status predictions in mammals. Here, we provide a comprehensive whole-genome killifish methylation map covering different tissues, age groups, and species. We show that the methylome of all individuals follows the typical, bimodal distribution of either high or low methylation rates. Furthermore, we find the major methylation variance within a species is driven by cell type-specific methylation and small but detectable aging related dynamics separating the age groups.

Project description:Aging and DNA damage increase the risk of chronic inflammation and autoimmunity, yet their molecular underpinnings remain unclear. Here, we uncover a DNA damage-driven mechanism in macrophages that triggers immune autoreactivity. Using Er1Lyz2/- animals with a macrophage-specific DNA repair defect in ERCC1-XPF, we demonstrate that monocyte-derived macrophages with persistent DNA damage activate the immune system, drive polyclonal T-cell responses, and generate anti-nuclear autoantibodies. Proteomic and immunopeptidomic analyses reveal a distinct MHC-II antigen repertoire in these macrophages, enriched in nuclear and ribosomal peptides, relying on autophagy for nuclear cargo delivery to MHC-II. Aged macrophages exhibit a similar lysosomal cargo profile, linking autophagy-driven nuclear antigen presentation to immune activation. Notably, inhibiting autophagy in Er1Lyz2/⁻ mice suppresses autoimmune features, pinpointing autophagy-facilitated nuclear antigen processing as a central driver of age-related autoimmunity. These findings establish DNA damage-induced autophagy in macrophages as a pivotal mechanism linking aging to autoimmunity, and unveiling potential targets for interventions to mitigate age-related immune dysregulation.

Project description:Introduction: Aging is associated with progressive loss of renal function and vascular structure, with and without chronic kidney disease. However, the mechanisms driving renal vascular aging and potential therapeutic interventions remain poorly understood. Methods: To model this state-of-affairs, we used African turquoise killifish (Nothobranchius furzeri), a naturally short-lived vertebrate. We then inhibited the sodium-glucose co-transporter 2 inhibition (SGLT2i) to test a potential therapeutic intervention. Histological, immunofluorescent, and 3D vascular imaging were used to evaluate glomerular, tubular, and vascular changes. Single-nuclei transcriptomic profiling was performed on whole kidneys to identify age- and treatment-associated molecular signatures. Results: Aged killifish kidneys exhibited hallmark features of human renal aging, including glomerulosclerosis, tubular fibrosis, and vascular rarefaction. Functional changes included increased proteinuria and altered tubular transporter expression. Transcriptomic profiling revealed a metabolic shift from oxidative phosphorylation to glycolysis and upregulation of pro-inflammatory pathways. Aged vasculature also displayed a marked reduction in tight junctions and cell–cell contacts. Dapagliflozin attenuated age-related vascular rarefaction, preserved functional peritubular capillary networks, and reduced albuminuria by restoring a youthful transcriptional profile and enhancing intercellular signaling. However, fish lifespan was not extended. Conclusion: This study establishes the killifish as a translational model for investigating renal vascular aging. We show that SGLT2i preserves renal microvascular structure and function, reduces proteinuria, and reprograms the aged transcriptome. These results support a vascular-protective role of SGLT2i in mitigating age-related renal deterioration.

Project description:Studies on somatic mutations in cloned animals have revealed slight genetic variances between clones and their originals but have yet to identify the precise effects of these differences within the organism. Somatic mutations contribute to aging and are implicated in tumor development and other age-related diseases. To explore this, we compared whole genome sequencing data of an original dog with cloned dogs, identifying 8,155 candidate somatic mutations. By analyzing mutational signatures and rates within relevant genes, we identified potential associations with aging. Further analysis of 239 homozygous mutations within 189 genes revealed significant enrichment of traits related to chronotype, adult body size, height, spherical equivalent or myopia, and age at first sexual intercourse, suggesting these genes play roles in both growth and aging, as indicated by changes during adolescence.

Project description:Engulfment by macrophages is critical for waste clearance in the vertebrate brain. Understanding clearance mechanisms may open new therapeutic possibilities to counter brain aging and neurodegenerative diseases. However, few in vivo models exist to study engulfment in the brain and characterize this process during aging and across species. Here we present a genetic model for secretion of a fluorescent protein by neurons in the brain of the African turquoise killifish, the shortest-lived vertebrate that can be bred in captivity. We use this model to identify a population of brain macrophages in the killifish responsible for engulfment of material from the brain extracellular space. Intriguingly, many of these cells bear similarities to mammalian border-associated and monocyte-derived macrophages, rare subsets of macrophages in mouse and human brains noted for their engulfment capabilities. We also find that in our model, killifish brain macrophages decline in engulfment capacity with age. This work highlights how vertebrate brain macrophages, particularly those at brain border regions, can play a critical role in clearance and provides an opportunity to test interventions that can boost engulfment by these macrophages to promote brain resilience in old age and disease.

Project description:We utilize single-cell sequencing (scSeq) of lymphocyte immune repertoires and transcriptomes to quantitatively profile the adaptive immune response in COVID-19 patients of varying age. Our scSeq analysis defines the adaptive immune repertoire and transcriptome in convalescent COVID-19 patients and shows important age-related differences implicated in immunity against SARS-CoV-2.

Project description:Killifish transcriptomic aging atlas