Project description:The number of newly-formed neurons declines rapidly during aging. Here we describe an important mechanism that contributes to this decline via Wip1-dependent regulation of neuronal differentiation. We found that Wip1 is expressed in neural stem/progenitor cells (NPCs) of the mouse subventricular zone and its upregulation at physiological levels maintained higher NPC numbers and neuronal differentiation in old mice. This resulted in markedly improved neuron formation and rescued a functional defect in fine odor discrimination in old mice. We identified Dkk3 as a key downstream target of Wip1 and found that its expression in SVZ is restricted to NPCs. Functionally, Dkk3 inhibited neuroblast formation by suppressing Wnt signaling, while deletion of Dkk3 or pharmacological reactivation of the Wnt pathway improved neuron formation and olfactory function in aged mice. We propose that Wip1 controls a Dkk3-dependent inhibition of neuronal differentiation during aging and thus regulating Wip1 levels could prevent certain aspects of functional decline of the aging brain. We found if neurospheres were derived from 18 months old mice, Wip1 transgenic neurospheres were more neurogenic than wt ones. This microarray was a pilot experiment to search the mechanism how Wip1 Transgene promoted neurogenesis, and found Dkk3 as a potential mediator. WT vs Wip1Tg neurospheres were cultured from mouse brain, and gene expression was compared using Illumina mouseWG-6 array

Project description:Hematopoietic stem cell (HSC) aging underlies many age-related hematopoietic disorders. Accumulation of DNA damage is a hallmark of HSC aging. Wild-type p53-induced phosphatase 1 (Wip1) is a homeostatic regulator of DNA damage response. We used microarrays to detail the global programme of gene expression in Wip1 KO HSC Wild-type p53-induced phosphatase 1 (Wip1) knockout HSC and Wild type HSC were selected for RNA extraction and hybridization on Affymetrix microarrays.

Project description:To isolate neuronal progenitor cells (NPCs), forebrains of E13.5 Miz1+/+ or Miz1-delta-POZ embryos were cut in small pieces, digested with trypsin and filtered through sterile gauze. Cells were cultivated in 2:1 DMEM/F12 supplemented with 1xB27 (Life technologies), 20 ng/ul EGF (Biomol), 20 ng/?l basic FGF (Biomol), 1 ug/ml fungizone (Gibco) and Penicillin/Streptomycin (PAA). NPCs were passaged every seven days. RNA expression of different genotypes was compared in sec. and quart. neurospheres.

Project description:Age is the primary risk factor for many chronic diseases and cognitive decline during brain aging may increase dementia risk. Hallmarks of brain aging including neuronal dysfunction and glial contribute to reduced cognitive function, and there is a persistent lack of effective treatments. Bioactive plant compounds called “nutraceuticals” can target age-related cellular processes and may protect cognitive function. Apigenin is a flavone found in plants such as chamomile and can inhibit hallmarks of aging such as cellular senescence, mitochondrial dysfunction, and impaired proteostasis. However, the underlying mechanisms of apigenin in the brain are not fully understood. Here, we characterized brain transcriptome changes in young and old mice given apigenin in drinking water and examined potential mechanisms in human astrocytes. Consistent with previous studies, we observed improved novel object recognition in old mice treated with apigenin versus old controls. Transcriptome analyses in old controls found differentially expressed genes related to immune responses, inflammation, and cytokine regulation versus young. Fewer differences were observed in old apigenin-treated versus old controls, but these changes were related to development, behavior, and antiviral responses. The majority of upregulated genes in old mice were downregulated with apigenin treatment and associated with immune responses. Similarly, the genes that were reduced with aging, but increased in old apigenin-treated mice were related to pathways important for neurological function/disease, cellular maintenance, and homeostatic signaling. We also found that glial cells drove the majority of the transcriptome differences with aging and apigenin-treatment. To explore the mechanism of action for apigenin in glial cells, we treated replicatively aged astrocytes with apigenin and observed reduced markers of inflammation and cellular senescence. Collectively, our data support the role of apigenin as a protector of cognitive and neuronal function protectant through the suppression of neuroinflammatory genes and proteins and may be especially important in non-neuronal cells.

Project description:Hematopoietic stem cell (HSC) aging underlies many age-related hematopoietic disorders. Accumulation of DNA damage is a hallmark of HSC aging. Wild-type p53-induced phosphatase 1 (Wip1) is a homeostatic regulator of DNA damage response. We used microarrays to detail the global programme of gene expression in Wip1 KO HSC

Project description:Physical exercise stimulates adult hippocampal neurogenesis in mammals, and is considered a relevant strategy for preventing age-related cognitive decline in aging humans. However, its mechanism is controversial. Here, by investigating microRNAs (miRNAs) and their downstream pathways, we uncover that downregulation of miR-135a-5p mediates exercise-induced proliferation of adult NPCs in adult neurogenesis in the mouse hippocampus, likely by activation of phosphatidylinositol (IP3) signaling. Specifically, while overexpression of miR-135 prevents exercise-induced proliferation in the adult mouse hippocampus in vivo and in NPCs in vitro, its inhibition activates NPCs proliferation in resting and aged mice. Label free proteomics and bioinformatics analysis identifies 11 potential targets of miR-135 in NPCs, several of them involved in phosphatidylinositol signaling. Thus, miR-135a is key in mediating exercise-induced adult neurogenesis and opens intriguing perspectives toward the therapeutic exploitation of miR-135 to delay or prevent pathological brain ageing.Physical exercise stimulates adult hippocampal neurogenesis in mammals, and is considered a relevant strategy for preventing age-related cognitive decline in aging humans. However, its mechanism is controversial. Here, by investigating microRNAs (miRNAs) and their downstream pathways, we uncover that downregulation of miR-135a-5p mediates exercise-induced proliferation of adult NPCs in adult neurogenesis in the mouse hippocampus, likely by activation of phosphatidylinositol (IP3) signaling. Specifically, while overexpression of miR-135 prevents exercise-induced proliferation in the adult mouse hippocampus in vivo and in NPCs in vitro, its inhibition activates NPCs proliferation in resting and aged mice. Label free proteomics and bioinformatics analysis identifies 11 potential targets of miR-135 in NPCs, several of them involved in phosphatidylinositol signaling. Thus, miR-135a is key in mediating exercise-induced adult neurogenesis and opens intriguing perspectives toward the therapeutic exploitation of miR-135 to delay or prevent pathological brain ageing.

Project description:Neural precursor cells (NPCs) in the mammalian neocortex generate various neuronal and glial cell types in a developmental stage-dependent manner. Most neocortical NPCs lose their neurogenic potential after birth. We have previously shown that high mobility group A (HMGA) proteins confer the neurogenic potential on early-stage NPCs during the midgestation period, although the underlying mechanisms are not fully understood. Here we performed microarray analysis and compared expression profiles between control and HMGA2-overexpressed NPCs. Mouse neocortical neuroepithelial cells were isolated at embryonic day 11.5 and cultured as neurospheres for 9 days in vitro in the presence of fibroblast growth factor (FGF) 2 and epidermal growth factor (EGF). These cells were infected with control or HMGA2-expressing retrovirus, cultured in the presence of FGF and EGF for 3 days. Half of them were collected immediately for microarray analysis, and the other half were cultured in the absence of FGF for 12 h and then collected for microarray analysis.

Project description:Aging is the primary risk factor for most neurodegenerative diseases, including Alzheimer's disease. Major hallmarks of brain aging include neuroinflammation/immune activation and reduced neuronal health/function. These processes contribute to cognitive dysfunction (a key risk factor for Alzheimer's disease), but their upstream causes are incompletely understood. Age-related increases in transposable element (TE) transcripts might contribute to reduced cognitive function with brain aging, as the reverse transcriptase inhibitor 3TC reduces inflammation in peripheral tissues and TE transcripts have been linked with tau pathology in Alzheimer's disease. However, the effects of 3TC on cognitive function with aging have not been investigated. Here, in support of a role for TE transcripts in brain aging/cognitive decline, we show that 3TC: (a) improves cognitive function and reduces neuroinflammation in old wild-type mice; (b) preserves neuronal health with aging in mice and Caenorhabditis elegans; and (c) enhances cognitive function in a mouse model of tauopathy. We also provide insight on potential underlying mechanisms, as well as evidence of translational relevance for these observations by showing that TE transcripts accumulate with brain aging in humans, and that these age-related increases intersect with those observed in Alzheimer's disease. Collectively, our results suggest that TE transcript accumulation during aging may contribute to cognitive decline and neurodegeneration, and that targeting these events with reverse transcriptase inhibitors like 3TC could be a viable therapeutic strategy.

Project description:Normal aging process is accompanied by cognitive decline. Studies have shown that the hypothalamus plays an important role in regulating aging and cognition. However, the exact molecular mechanism remains unclear. Therefore, the present study aimed to identify predictors of aging cognitive decline in the hypothalamus. The behavioral experiment was used to identify learning and memory differences between young and old mice. Transcriptome sequencing was performed on the hypothalamus of young and old mice to identify potential genes.Our data provide the related genes ,which may be potential predictors of cognitive function in the elderly population, which will establish an important foundation for us to further explore the molecular mechanism.

Project description:The decline of brain function during aging is associated with epigenetic changes, including DNA methylation. Lifestyle interventions can improve brain function during aging, but their influence on age-related epigenetic changes is unknown. Using genome-wide DNA methylation sequencing, we here show that environmental enrichment counteracted age-related DNA methylation changes in the hippocampal dentate gyrus of mice. Specifically, environmental enrichment prevented the aging-induced CpG hypomethylation at target sites of the methyl-CpG-binding protein Mecp2, which is known to control neuronal functions. The genes at which environmental enrichment counteracted aging effects have described roles in neuronal plasticity, neuronal cell communication and adult hippocampal neurogenesis and are dysregulated with age-related cognitive decline in the human brain. Our results highlight the rejuvenating effects of environmental enrichment at the level of DNA methylation and give molecular insights into the specific aspects of brain aging that can be counteracted by lifestyle interventions.