Whole transcriptome sequencing of the aging rat brain reveals dynamic RNA changes in the dark matter of the genome

Wood, Shona H.; Craig, Thomas; Li, Yang; Merry, B.J.; Magalhães, João Pedro de

doi:10.1007/s11357-012-9410-1

Cited by 100 publications

(75 citation statements)

References 43 publications

(58 reference statements)

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“…The U-shaped cluster is enriched for cell cycle and DNA replication genes (Table S4), suggesting that the oldest group on average shows lower levels of cellular stress than the animals sampled at median lifespan, possibly because they delayed or escaped age-dependent dysfunctions, as it is the case for human centenarians (Evert et al ., 2003). Inversions in the direction of age-dependent gene expression are prominent in the postnatal primate cortex (Somel et al ., 2010; Colantuoni et al ., 2011) and also observed in the rat brain (Wood et al ., 2013). One of these turning points is observed around the age of 60 years in humans (Colantuoni et al ., 2011).…”

Section: Discussionmentioning

confidence: 99%

RNA‐seq of the aging brain in the short‐lived fish N. furzeri – conserved pathways and novel genes associated with neurogenesis

et al. 2014

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The brains of teleost fish show extensive adult neurogenesis and neuronal regeneration. The patterns of gene regulation during fish brain aging are unknown. The short-lived teleost fish Nothobranchius furzeri shows markers of brain aging including reduced learning performances, gliosis, and reduced adult neurogenesis. We used RNA-seq to quantify genome-wide transcript regulation and sampled five different time points to characterize whole-genome transcript regulation during brain aging of N. furzeri. Comparison with human datasets revealed conserved up-regulation of ribosome, lysosome, and complement activation and conserved down-regulation of synapse, mitochondrion, proteasome, and spliceosome. Down-regulated genes differ in their temporal profiles: neurogenesis and extracellular matrix genes showed rapid decay, synaptic and axonal genes a progressive decay. A substantial proportion of differentially expressed genes (∼40%) showed inversion of their temporal profiles in the last time point: spliceosome and proteasome showed initial down-regulation and stress-response genes initial up-regulation. Extensive regulation was detected for chromatin remodelers of the DNMT and CBX families as well as members of the polycomb complex and was mirrored by an up-regulation of the H3K27me3 epigenetic mark. Network analysis showed extensive coregulation of cell cycle/DNA synthesis genes with the uncharacterized zinc-finger protein ZNF367 as central hub. In situ hybridization showed that ZNF367 is expressed in neuronal stem cell niches of both embryonic zebrafish and adult N. furzeri. Other genes down-regulated with age, not previously associated with adult neurogenesis and with similar patterns of expression are AGR2, DNMT3A, KRCP, MEX3A, SCML4, and CBX1. CBX7, on the other hand, was up-regulated with age.

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Section: Discussionmentioning

confidence: 99%

RNA‐seq of the aging brain in the short‐lived fish N. furzeri – conserved pathways and novel genes associated with neurogenesis

et al. 2014

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“…Many splicing factors show age‐related changes in their expression that correlate with changes in alternative splicing during aging (Harries et al, 2011; Lee et al, 2016; Mazin et al, 2013; Rodríguez et al, 2016; Tollervey et al, 2011; Wood, Craig, Li, Merry, & Magalhães, 2013). For example, as many as one‐third of all splicing factors exhibit altered expression with age in human blood (Holly et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Proper splicing contributes to visual function in the aging Drosophila eye

et al. 2018

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Changes in splicing patterns are a characteristic of the aging transcriptome; however, it is unclear whether these age‐related changes in splicing facilitate the progressive functional decline that defines aging. In Drosophila, visual behavior declines with age and correlates with altered gene expression in photoreceptors, including downregulation of genes encoding splicing factors. Here, we characterized the significance of these age‐regulated splicing‐associated genes in both splicing and visual function. To do this, we identified differential splicing events in either the entire eye or photoreceptors of young and old flies. Intriguingly, aging photoreceptors show differential splicing of a large number of visual function genes. In addition, as shown previously for aging photoreceptors, aging eyes showed increased accumulation of circular RNAs, which result from noncanonical splicing events. To test whether proper splicing was necessary for visual behavior, we knocked down age‐regulated splicing factors in photoreceptors in young flies and examined phototaxis. Notably, many of the age‐regulated splicing factors tested were necessary for proper visual behavior. In addition, knockdown of individual splicing factors resulted in changes in both alternative splicing at age‐spliced genes and increased accumulation of circular RNAs. Together, these data suggest that cumulative decreases in splicing factor expression could contribute to the differential splicing, circular RNA accumulation, and defective visual behavior observed in aging photoreceptors.

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“…Wood et al [52] used RNA-seq to sequence the cerebral cortex transcriptome in 6-, 12-and 28-month-old rats, and revealed that protein coding genes related to MHC II presentation and serotonin biosynthesis were differentially expressed in aging. Dillman et al [53] reported a high-resolution transcriptome dataset of mouse cerebral cortex at embryonic and adult stages using RNA-Seq and found many differences in gene expression, splicing, and RNA editing between embryonic and adult cerebral cortex, such as cell cycle, DNA damage response and repair in embryonic brain and immune response in adult brain.…”

Section: Evidence For Molecular Inflammation In the Aging Process As mentioning

confidence: 99%

Anti-inflammatory Action of Calorie Restriction Underlies the Retardation of Aging and Age-Related Diseases

Kim

Lee

Park

et al. 2015

Healthy Ageing and Longevity

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Calorie restriction (CR) is known to extend lifespan and has anti-oxidative properties that lead to physiological and biological resistance against diseases and stress. This chapter reviews the molecular mechanisms of CR's anti-inflammatory actions during aging. The crux of CR's ability to attenuate age-related chronic inflammation is related to its power to maintain redox status by modulating oxidative stress during aging. Here, for better molecular insights, key transcription factors such as FoxO, Nrf2, and PPARs induced by CR are described for their modulation of the age-related inflammation response. In addition, recent analyses by systems biology on chronic inflammation, age-related pro-inflammatory gene activation, and CR's suppression produced evidence identifing various target genes, target molecules, and their networks. The wide implication of the proinflammatory process under

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Whole transcriptome sequencing of the aging rat brain reveals dynamic RNA changes in the dark matter of the genome

Cited by 100 publications

References 43 publications

RNA‐seq of the aging brain in the short‐lived fish N. furzeri – conserved pathways and novel genes associated with neurogenesis

RNA‐seq of the aging brain in the short‐lived fish N. furzeri – conserved pathways and novel genes associated with neurogenesis

Proper splicing contributes to visual function in the aging Drosophila eye

Anti-inflammatory Action of Calorie Restriction Underlies the Retardation of Aging and Age-Related Diseases

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