Project description:Gene expression profiling study of normally-aging SAMR1 mice brain cortex with TCQA treatment We used microarrays to detail the global gene expression of SAMR1 mouse brain with TCQA treatment as a control for the senescence-acCELerated mouse prone 8 (SAMP8) model of aging mice

Project description:The present study examines the effects of whale meat extract (WME) supplementation on the senescence-accelerated mouse prone 8 (SAMP8) model at the level of learning memory formation and gene expression profiles genome-wide. Our present study builds up on these previous studies by focusing on two sets of experiments examining WME-supplemented diet, on SAMP8 and SAMR1 (senescence-accelerated mouse resistant 1) learning and memory deficits (experiment 1) and whole-genome DNA microarray-based transcriptomics profiling in conjunction with Ingenuity Pathway Analysis (IPA) (experiment 2). We also examined the SAMP8 and SAMR1 mice fed with the regular (control; low-safflower oil, LSO) diets specifically to know the gene profiles in the brain of the SAMP8 mouse. Results revealed that WME supplementation on SAMP8 mouse resulted in an increase in the level of learning memory formation and positive changes in the transcriptome of the brain, suggested through the observation of recovery of gene expressions in the SAMP8 model over the not-supplemented mouse.

Project description:A growing body of research shows that epigenetic mechanisms are critically involved in normal and pathological aging. The Senescence-Accelerated Mouse Prone 8 (SAMP8) can be considered an useful tool to better understand the dynamics of the global epigenetic landscape during the aging process since its phenotype is not fully explained by genetic factors. Here we investigated dysfunctional age-related transcriptional profiles and epigenetic programming enzymes in the hippocampus of 2- and 9-month-old SAMP8 female mice using the Senescent-Accelerated Resistant 1 (SAMR1) mouse strain as control. SAMP8 mice presented 1,062 genes dysregulated at 2 months of age, and 1,033 genes at 9 months, with 92 genes concurrently dysregulated at both ages in reference to age mated SAMR1. SAMP8 mice showed a significant decrease in global DNA methylation (5-mC) at 2 months while hydroxymethylation (5-hmC) levels were increased in SAMP8 mice at 2 and 9 months of age compared to SAMR1. These changes were accompanied by changes in the expression of several enzymes that regulate 5-mC and methylcytosine oxidation. Acetylated H3 and H4 histone levels were significantly diminished in SAMP8 mice at 2-month-old compared to SAMR1 and altered Histone DeACetylase (HDACs) profiles were detected in both young and old SAMP8 mice. We analyzed 84 different mouse miRNAs known to be altered in neurological diseases or involved in neuronal development. Compared with SAMR1, SAMP8 mice showed 28 and 17 miRNAs differentially expressed at 2 and 9 months of age, respectively, 6 of these miRNAs overlapped at both ages. We used several bioinformatic approaches to integrate our data in mRNA:miRNA regulatory networks and functional predictions for young and aged animals. In sum, our study reveals interplay between epigenetic mechanisms and gene networks that seems to be relevant for the progression towards a pathological aging and provides several potential markers and therapeutic candidates for Alzheimer’s Disease (AD) and age-related cognitive impairment.

Project description:A growing body of research shows that epigenetic mechanisms are critically involved in normal and pathological aging. The Senescence-Accelerated Mouse Prone 8 (SAMP8) can be considered an useful tool to better understand the dynamics of the global epigenetic landscape during the aging process since its phenotype is not fully explained by genetic factors. Here we investigated dysfunctional age-related transcriptional profiles and epigenetic programming enzymes in the hippocampus of 2- and 9-month-old SAMP8 female mice using the Senescent-Accelerated Resistant 1 (SAMR1) mouse strain as control. SAMP8 mice presented 1,062 genes dysregulated at 2 months of age, and 1,033 genes at 9 months, with 92 genes concurrently dysregulated at both ages in reference to age mated SAMR1. SAMP8 mice showed a significant decrease in global DNA methylation (5-mC) at 2 months while hydroxymethylation (5-hmC) levels were increased in SAMP8 mice at 2 and 9 months of age compared to SAMR1. These changes were accompanied by changes in the expression of several enzymes that regulate 5-mC and methylcytosine oxidation. Acetylated H3 and H4 histone levels were significantly diminished in SAMP8 mice at 2-month-old compared to SAMR1 and altered Histone DeACetylase (HDACs) profiles were detected in both young and old SAMP8 mice. We analyzed 84 different mouse miRNAs known to be altered in neurological diseases or involved in neuronal development. Compared with SAMR1, SAMP8 mice showed 28 and 17 miRNAs differentially expressed at 2 and 9 months of age, respectively, 6 of these miRNAs overlapped at both ages. We used several bioinformatic approaches to integrate our data in mRNA:miRNA regulatory networks and functional predictions for young and aged animals. In sum, our study reveals interplay between epigenetic mechanisms and gene networks that seems to be relevant for the progression towards a pathological aging and provides several potential markers and therapeutic candidates for Alzheimer’s Disease (AD) and age-related cognitive impairment.

Project description:The present study examines the effects of whale meat extract (WME) supplementation on the senescence-accelerated mouse prone 8 (SAMP8) model at the level of learning memory formation and gene expression profiles genome-wide. Our present study builds up on these previous studies by focusing on two sets of experiments examining WME-supplemented diet, on SAMP8 and SAMR1 (senescence-accelerated mouse resistant 1) learning and memory deficits (experiment 1) and whole-genome DNA microarray-based transcriptomics profiling in conjunction with Ingenuity Pathway Analysis (IPA) (experiment 2). We also examined the SAMP8 and SAMR1 mice fed with the regular (control; low-safflower oil, LSO) diets specifically to know the gene profiles in the brain of the SAMP8 mouse. Results revealed that WME supplementation on SAMP8 mouse resulted in an increase in the level of learning memory formation and positive changes in the transcriptome of the brain, suggested through the observation of recovery of gene expressions in the SAMP8 model over the not-supplemented mouse. 6-week-old mice (SAMP8 and SAMR1; CLEA, Tokyo, Japan) were housed at the Animal Institution Facility in Showa University, and maintained in individual cages in a ventilated animal room with controlled temperature and relative humidity under a 12-h light: 12-h dark regime (8:00 AM, lights turned on). Mice were fed chow (CE-2, CLEA Japan) and tap water ad libitum until 24-weeks-old. Then, 24-week-old SAMs mice were given experimental diet, LSO diet as a control diet and WME-supplemented diet, both in a powder form. The WME was made from red meat of Antarctic minke whale (Balaenoptera bonaerensis), taken from the Japanese Whale Research Program under Special Permit in the Antarctic-Phase II in 2009/2010 by heat, enzyme and drying treatments. The quality standard of WE were measured by Marugei Co. Ltd. (Hyogo, Japan). SAMP8 mice were randomly given LSO or WME diet, respectively. SAMR1 mice were given LSO diet only until 50-weeks-old. The behavioral tests were performed at the timing of 49-weeks-old for 8 days. At the end of the experiment (50 weeks of age) following the behavioral analysis (open field test, Y-maze test, new object recognition test (NOR), and water-filled multiple T-maze) and the last day of the feeding, the mice were removed from their cages, decapitated and their brains carefully removed on ice. The whole brains were quickly frozen in liquid nitrogen in a sterile freeze tube and stored at -80ºC till extraction of total RNA followed by DNA microarray analysis using a whole-genome mouse chip (Agilent-014868, 4 x 44K (G4122F)) with two-color dye-swap approach in conjunction with IPA bioinformatic analysis. All animal studies were conducted in accordance with the Standards Relating to the Care Management of Experimental Animals” (Notice No. 6 of the Office of Prime Minister dated March 27, 1980) and with approval from the Animal Use Committee of Showa University (Approval Number: #04093).

Project description:Histopathological changes occur in the brainstem during the early stages of Alzheimer's disease (AD), with the pathological changes of the brain lesions ascending progressively in accordance with the Braak staging system. The senescence‑accelerated mouse prone 8 (SAMP8) mouse model has been previously used as a model of age‑dependent neurodegenerative diseases, including AD. In the present study, microRNAs (miRNAs) that were upregulated or downregulated in SAMP8 brainstems were identified using miRNA profiling of samples obtained from miRNA arrays. The preliminary stage of cognitive dysfunction was examined using male 5‑month‑old SAMP8 mice, with age‑matched senescence‑accelerated mouse resistant 1 mice as controls. A Y‑maze alternation test was performed to assess short‑term working memory and miRNA profiling was performed in each region of the dissected brain (brainstem, hippocampus and cerebral cortex). SAMP8 mice tended to be hyperactive, but short‑term working memory was preserved. Two miRNAs were upregulated (miR‑491‑5p and miR‑764‑5p) and two were downregulated (miR‑30e‑3p and miR‑323‑3p) in SAMP8 brainstems. In SAMP8 mice, the expression level of upregulated miRNAs were the highest in the brainstem, wherein age‑related brain degeneration occurs early. It was demonstrated that the order of specific miRNA expression levels corresponded to the progression order of age‑related brain degeneration. Differentially expressed miRNAs regulate multiple processes, including neuronal cell death and neuron formation. Changes in miRNA expression may result in the induction of target proteins during the early stages of neurodegeneration in the brainstem. These findings suggest that studying altered miRNA expression may provide molecular evidence for early age‑related neuropathological changes.

Project description:Microarrays have been used to analyze the effect of voluntary wheel running in the SAMP8 mice using the SAMR1 mouse strain as control. Hippocampal gene expresion of SAMP8 which have been resting or exercising and SAMR1 sedentary.

Project description:Microarrays has been used to analyze the effect of voluntary wheel running in the SAMP8 mice using the SAMR1 mouse strain as control. Cortex gene expresion of SAMP8 which have been resting or exercising and SAMR1 sedentary.

Project description:Astrocytes are key cells in brain aging, helping neurons to undertake healthy aging or otherwise letting them enter into a spiral of neurodegeneration. We aimed to characterize astrocytes cultured from senescence-accelerated prone 8 (SAMP8) mice, a mouse model of brain pathological aging, along with the effects of caloric restriction, the most effective rejuvenating treatment known so far. Analysis of the transcriptomic profiles of SAMP8 astrocytes cultured in control conditions and treated with caloric restriction serum was performed using mRNA microarrays. A decrease in mitochondrial and ribosome mRNA, which was restored by caloric restriction, confirmed the age-related profile of SAMP8 astrocytes and the benefits of caloric restriction. An amelioration of antioxidant and neurodegeneration-related path- ways confirmed the brain benefits of caloric restriction. Studies of oxidative stress and mitochondrial function demonstrated a reduction of oxidative damage and partial improvement of mito- chondria after caloric restriction. In summary, caloric restriction showed a significant tendency to normalize pathologically aged astrocytes through the activation of pathways that are protective against the age-related deterioration of brain physiology. Key words: astrocytes; caloric restriction; mitochondria; oxidative stress; RNA microarrays; SAMP8. Primary cultures enriched in astrocytes were obtained from cerebral cortical tissue from 2-day-old SAMP8 and SAMR1 mice. Astrocyte cultures were established and experiments were routinely carried out after 21 days in culture. Established astrocyte cultures of both SAMR1 and SAMP8 consisted of 85-90% astrocytes, 10-15% microglia and 0.1-1% oligodendroglia. Sera from rats subjected to ad libitum (AL) diet and to CR were obtained as described for the establishment of the CR in vitro model (de Cabo et al., 2003). Serum was heat inactivated at 56°C prior to use in astrocyte culture experiments. Treatment in vitro was performed by adding 10% volume CR or AL serum onto the astrocyte culture medium for 48 h, the cells were harvested and RNA was extracted for the microarray studies. Three biological replicates for each condition were done and RNA was extracted for the microarray studies. Please note that SAM models were developed from AKR/J by Kyoto University. Five litters with severe senescence were selected to further propagate and examine these characteristics. Litters that showed normal aging were selected as a senescence-resistant series (R-series). The genetic background of the SAM mice became suspect after the pathological findings were different from the AKR/J mouse. Each SAM model is genetically different. Each SAM colony was acquired by Harlan by Takeda Chemical Ltd. in 2002. And here is the link to the company site. http://www.harlan.com/products_and_services/research_models_and_services/research_models/sam_inbred_mice/samp8tahsd.hl

Project description:SAMP8 SAMR1 mouse Transcriptome