Project description:Calorie restriction (CR) enhances longevity and mitigates aging phenotypes in numerous species. Physiological responses to CR are cell-type specific and variable throughout the lifespan; however, the mosaic of molecular changes responsible CR benefits remain unclear, particularly in brain regions susceptible to deterioration throughout aging. Thus, we examined the influence of long-term CR on the CA1 hippocampal region, a key learning and memory brain area that is vulnerable to age-related pathologies, such as Alzheimer’s disease (AD). Through mRNA sequencing and NanoString nCounter analysis, we demonstrate that one year of CR feeding suppresses an age-dependent signature of 882 genes functionally associated with synaptic transmission-related pathways, including calcium signaling, long-term potentiation (LTP), and Creb signaling in wild-type mice. By comparing the influence of CR on hippocampal CA1 region transcriptional profiles at younger- (5 months) and older-adult (15 months) timepoints, we identify conserved upregulation of proteome quality control and calcium buffering genes, including heat shock 70 kDa proteins 1b and 5 (Hspa1b and Hspa5), protein disulfide isomerase family A members 4 and 6 (Pdia4 and Pdia6), and calreticulin (Calr). Expression levels of putative neuroprotective factors, klotho (Kl) and transthyretin (Ttr), are also elevated by CR throughout adulthood, although the global CR-specific expression profiles at young and older timepoints are highly divergent. At a previously unachieved resolution, our results demonstrate conserved activation of neuroprotective gene signatures and broad CR-suppression of age-dependent hippocampal CA1 region expression changes, indicating that CR functionally maintains a more youthful transcriptional state within hippocampal CA1 throughout aging. Hippocampal CA1 region mRNA profiles of younger- (5 months) and older-adult (15 months) mice on calorie-restricted (CR) and normal (AD) diets were generated by deep sequencing using Illumina HiSeq 2500.

Project description:Aging is associated with low-grade chronic systemic inflammation. Elevated peripheral serum cytokines and chemokines contribute to age-related diseases and correlate with cognitive decline. This study compared the effects of repeated lipopolysaccharide (LPS) treatment in young rats to age-related changes in hippocampal-dependent cognition, synaptic transmission, and transcription. Young (5-7 months) Fischer 344 X Brown Norway hybrid rats were injected intraperitoneally once a week for 6-7 weeks with either LPS (1 mg/kg) or vehicle. Older (14-16 months) rats received a similar injection schedule of vehicle. Older-vehicle animals and young-LPS rats exhibited impaired retention of spatial memory. Examination of the transcriptome of the CA1 and the dentate gyrus indicated that older-vehicle and young-LPS animals exhibited an increase in immune response genes. In contrast to aging, young-LPS animals exhibited an increased expression of genes related to the synapse. Even though young-LPS animals increased the expression of synaptic genes, LPS treatment reduced hippocampal CA3-CA1 total synaptic response and N-methyl-D-aspartate receptor (NMDAR)-mediated component of the synaptic response. Interestingly, the decrease in NMDAR function was not redox-sensitive. This study demonstrates that repeated exposure to LPS has long-term effects on hippocampal synaptic transmission and memory; however, young animals exhibited transcriptional recovery after LPS treatment. Recovery likely results from the acute nature of repeated LPS injections, relative to chronic systemic inflammation observed during aging.

Project description:The project examined age-related change in hippocampal gene expression in Fisher 344 x Brown Norway F1 rats from the NIA aging colony (Adult = 12M, Aged = 24M). CA1, CA3, and DG specific dissections were examined from one cohort of animals and from a second cohort whole hippocampus was used. Hippocampal gene expression with aging in a rat model was examined between Adult (12M) and Aged animals (24M)

Project description:Aging and increased amyloid burden are major risk factors for cognitive diseases such as Alzheimer's Disease (AD). An effective therapy does not yet exist. Here we use mouse models for age-associated memory impairment and amyloid deposition to study transcriptome and cell type-specific epigenome plasticity at the systems level in the brain and in peripheral organs. We show that at the level of epigenetic gene-expression aging and amyloid pathology are associated with inflammation and impaired synaptic function in the hippocampal CA1 region. While inflammation is associated with increased gene-expression that is linked to a subset of transcription factors, de-regulation of plasticity genes is mediated via different mechanisms in the amyloid and the aging model. Amyloid pathology impairs histone-acetylation and decreases expression of plasticity genes while aging affects differential splicing that is linked to altered H4K12 acetylation at the intron-exon junction in neurons but not in non-neuronal cells. We furthermore show that oral administration of the clinically approved histone deacetylase inhibitor Vorinostat not only restores spatial memory, but also exhibits an anti-inflammatory action and reinstates epigenetic balance and transcriptional homeostasis at the level of gene expression and exon usage. This is the first systems-level investigation of transcriptome plasticity in the hippocampal CA1 region in aging and AD models and of the effects of an orally dosed histone deacetylase inhibitor. Our data has important implications for the development of minimally invasive and cost-effective therapeutic strategies against age-associated cognitive decline. In fact, our data strongly suggest to test Vorinostat in patients suffering from AD.

Project description:Aging and increased amyloid burden are major risk factors for cognitive diseases such as Alzheimer's Disease (AD). An effective therapy does not yet exist. Here we use mouse models for age-associated memory impairment and amyloid deposition to study transcriptome and cell type-specific epigenome plasticity at the systems level in the brain and in peripheral organs. We show that at the level of epigenetic gene-expression aging and amyloid pathology are associated with inflammation and impaired synaptic function in the hippocampal CA1 region. While inflammation is associated with increased gene-expression that is linked to a subset of transcription factors, de-regulation of plasticity genes is mediated via different mechanisms in the amyloid and the aging model. Amyloid pathology impairs histone-acetylation and decreases expression of plasticity genes while aging affects differential splicing that is linked to altered H4K12 acetylation at the intron-exon junction in neurons but not in non-neuronal cells. We furthermore show that oral administration of the clinically approved histone deacetylase inhibitor Vorinostat not only restores spatial memory, but also exhibits an anti-inflammatory action and reinstates epigenetic balance and transcriptional homeostasis at the level of gene expression and exon usage. This is the first systems-level investigation of transcriptome plasticity in the hippocampal CA1 region in aging and AD models and of the effects of an orally dosed histone deacetylase inhibitor. Our data has important implications for the development of minimally invasive and cost-effective therapeutic strategies against age-associated cognitive decline. In fact, our data strongly suggest to test Vorinostat in patients suffering from AD.

Project description:Aging and increased amyloid burden are major risk factors for cognitive diseases such as Alzheimer's Disease (AD). An effective therapy does not yet exist. Here we use mouse models for age-associated memory impairment and amyloid deposition to study transcriptome and cell type-specific epigenome plasticity at the systems level in the brain and in peripheral organs. We show that at the level of epigenetic gene-expression aging and amyloid pathology are associated with inflammation and impaired synaptic function in the hippocampal CA1 region. While inflammation is associated with increased gene-expression that is linked to a subset of transcription factors, de-regulation of plasticity genes is mediated via different mechanisms in the amyloid and the aging model. Amyloid pathology impairs histone-acetylation and decreases expression of plasticity genes while aging affects differential splicing that is linked to altered H4K12 acetylation at the intron-exon junction in neurons but not in non-neuronal cells. We furthermore show that oral administration of the clinically approved histone deacetylase inhibitor Vorinostat not only restores spatial memory, but also exhibits an anti-inflammatory action and reinstates epigenetic balance and transcriptional homeostasis at the level of gene expression and exon usage. This is the first systems-level investigation of transcriptome plasticity in the hippocampal CA1 region in aging and AD models and of the effects of an orally dosed histone deacetylase inhibitor. Our data has important implications for the development of minimally invasive and cost-effective therapeutic strategies against age-associated cognitive decline. In fact, our data strongly suggest to test Vorinostat in patients suffering from AD.

Project description:The project examined age-related change in hippocampal gene expression in Fisher 344 x Brown Norway F1 rats from the NIA aging colony (Adult = 12M, Aged = 24M). CA1, CA3, and DG specific dissections were examined from one cohort of animals and from a second cohort whole hippocampus was used.

Project description:The aim of this study was to investigate whether the differences in memory decline associated with aging are a result of differences in gene expression. We first categorized age-unimpaired and age-impaired rats based on their performance in the Morris Water Maze and then isolated messenger RNA from the CA1 hippocampal region of each animal to interrogate Affymetrix microarrays. Microarray analysis (p<0.005) identified a set of 50 genes that were transcribed differently in age-unimpaired animals that had successfully learned a spatial task compared to aged learning-impaired animals and a variety of groups designed to control for all non-learning aspects of exposure to the water maze paradigm. Keywords: behavior comparison, age comparison

Project description:The aim of this study was to investigate whether the differences in memory decline associated with aging are a result of differences in gene expression. We first categorized age-unimpaired and age-impaired rats based on their performance in the Morris Water Maze and then isolated messenger RNA from the CA1 hippocampal region of each animal to interrogate Affymetrix microarrays. Microarray analysis (p<0.005) identified a set of 50 genes that were transcribed differently in age-unimpaired animals that had successfully learned a spatial task compared to aged learning-impaired animals and a variety of groups designed to control for all non-learning aspects of exposure to the water maze paradigm. Experiment Overall Design: a total of 79 samples were analyzed including aged and young rats. One chip was interrogated per animal. Analysis of aged rat data includes 44 samples. Controls include cage controls, yoked controls (no platform), visible platform controls.

Project description:Sustained caloric restriction (CR) extends lifespan in animal models but the mechanism and primary tissue target(s) have not been identified. Gene expression changes with aging and CR were examined in both heart and subcutaneous white adipose tissue (WAT) of F344 male rats using Affymetrix® RAE 230 arrays and validated by qRT-PCR on 18 genes. In heart, age- associated changes but not CR-associated changes in old. In WAT, genes were identified where the aging change is suppressed by CR (candidate markers of healthy aging) and those affected by CR but not normal aging (candidate longevity assurance genes). 10-21% of age-associated genes were regulated in common between tissues. Gene set enrichment analysis (GSEA) revealed coordinate small magnitude changes in ribosomal, proteasomal, and mitochondrial genes with similarities between heart and WAT. Further analysis revealed PPARgamma as a potential upstream regulator of altered gene expression in old CR WAT. These results demonstrate a reduced mRNA response to CR with age in heart relative to WAT. In WAT, we identified candidate CR mimetic targets and candidate markers of healthy aging. These data suggest a role for subcutaneous WAT in the effects of CR and strengthen the role for PPAR signaling in aging and CR while indicating that the effects of CR in heart can occur independent of global changes in mRNA level. Experiment Overall Design: Tissues (n=5-7 animals per group) were obtained from the NIH-NIA aging rodent tissue bank. According to supplier records, animals were housed in a specific pathogen free barrier facility under contract with BioReliance. AL animals were housed 3 per cage and CR animals were housed singly. CR (60% of AL) was initiated at 4 months of age with a switch from the NIH 31 to NIH fortified diet. F344 male rats were sacrificed at 4 months (4AL) or 28 months of age (28AL, 28CR). Animals with gross tumor pathologies were excluded from the study. All animals were euthanized by CO2 asphixiation and tissues were frozen in liquid nitrogen then stored at –80°C. Subcutaneous WAT was collected from the abdominal region. Recorded body weights differed dramatically between the 3 groups (4AL = 253±8 g, 28AL = 382±20 g, 28CR = 288±7 g) and heart weight as a fraction of body weight was not significantly different between the groups (data not shown). The apical ~1/3 of the heart was homogenized for the expression studies. Sections from the cut face were stained with haematoxylin and eosin to confirm expected aging-associated pathology changes.