Lee Benjamin P, Pilling Luke C, Emond Florence, Flurkey Kevin, Harrison David E, Yuan Rong, Peters Luanne L, Kuchel George A, Ferrucci Luigi, Melzer David, Harries Lorna W
RNA-Mediated Mechanisms of Disease.
Epidemiology and Public Health, Institute of Biomedical and Clinical Sciences, University of Exeter Medical School, University of Exeter, Devon, UK.
Aging Cell. 2016 Oct;15(5):903-13. doi: 10.1111/acel.12499. Epub 2016 Jun 30.
Dysregulation of splicing factor expression and altered alternative splicing are associated with aging in humans and other species, and also with replicative senescence in cultured cells. Here, we assess whether expression changes of key splicing regulator genes and consequent effects on alternative splicing are also associated with strain longevity in old and young mice, across 6 different mouse strains with varying lifespan (A/J, NOD.B10Sn-H2(b) /J, PWD.Phj, 129S1/SvlmJ, C57BL/6J and WSB/EiJ). Splicing factor expression and changes to alternative splicing were associated with strain lifespan in spleen and to a lesser extent in muscle. These changes mainly involved hnRNP splicing inhibitor transcripts with most changes more marked in spleens of young animals from long-lived strains. Changes in spleen isoform expression were suggestive of reduced cellular senescence and retained cellular proliferative capacity in long-lived strains. Changes in muscle isoform expression were consistent with reduced pro-inflammatory signalling in longer-lived strains. Two splicing regulators, HNRNPA1 and HNRNPA2B1, were also associated with parental longevity in humans, in the InCHIANTI aging study. Splicing factors may represent a driver, mediator or early marker of lifespan in mouse, as expression differences were present in the young animals of long-lived strains. Changes to alternative splicing patterns of key senescence genes in spleen and key remodelling genes in muscle suggest that correct regulation of alternative splicing may enhance lifespan in mice. Expression of some splicing factors in humans was also associated with parental longevity, suggesting that splicing regulation may also influence lifespan in humans.
剪接因子表达失调和可变剪接改变与人类及其他物种的衰老相关,也与培养细胞中的复制性衰老有关。在此,我们评估关键剪接调节基因的表达变化以及对可变剪接的后续影响是否也与不同寿命的老年和幼年小鼠品系的寿命相关,这些小鼠品系共有6种,寿命各不相同(A/J、NOD.B10Sn-H2(b)/J、PWD.Phj、129S1/SvlmJ、C57BL/6J和WSB/EiJ)。剪接因子表达和可变剪接变化与脾脏中的品系寿命相关,在肌肉中相关性稍弱。这些变化主要涉及hnRNP剪接抑制因子转录本,大多数变化在长寿品系幼年动物的脾脏中更为明显。脾脏异构体表达的变化表明长寿品系中细胞衰老减少且细胞增殖能力得以保留。肌肉异构体表达的变化与长寿品系中促炎信号传导减少一致。在基安蒂衰老研究中,两种剪接调节因子HNRNPA1和HNRNPA2B1也与人类的父母寿命相关。剪接因子可能代表小鼠寿命的驱动因素、介导因素或早期标志物,因为长寿品系的幼年动物中存在表达差异。脾脏中关键衰老基因和肌肉中关键重塑基因的可变剪接模式变化表明,正确调节可变剪接可能会延长小鼠的寿命。人类中一些剪接因子的表达也与父母寿命相关,这表明剪接调节也可能影响人类的寿命。
