在衰老过程中细胞内水平变化最大的氨基酸会改变裂殖酵母的时序寿命。

Amino Acids Whose Intracellular Levels Change Most During Aging Alter Chronological Life Span of Fission Yeast.

机构信息

Institute of Healthy Ageing, Department of Genetics, Evolution & Environment, University College London, UK.

The Francis Crick Institute, London, UK.

出版信息

J Gerontol A Biol Sci Med Sci. 2021 Jan 18;76(2):205-210. doi: 10.1093/gerona/glaa246.

DOI:10.1093/gerona/glaa246

PMID:32991693

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7812441/

Abstract

Amino acid deprivation or supplementation can affect cellular and organismal life span, but we know little about the role of concentration changes in free, intracellular amino acids during aging. Here, we determine free amino acid levels during chronological aging of nondividing fission yeast cells. We compare wild-type with long-lived mutant cells that lack the Pka1 protein of the protein kinase A signalling pathway. In wild-type cells, total amino acid levels decrease during aging, but much less so in pka1 mutants. Two amino acids strongly change as a function of age: glutamine decreases, especially in wild-type cells, while aspartate increases, especially in pka1 mutants. Supplementation of glutamine is sufficient to extend the chronological life span of wild-type but not of pka1Δ cells. Supplementation of aspartate, on the other hand, shortens the life span of pka1Δ but not of wild-type cells. Our results raise the possibility that certain amino acids are biomarkers of aging, and their concentrations during aging can promote or limit cellular life span.

摘要

氨基酸缺乏或补充会影响细胞和生物个体的寿命，但我们对衰老过程中游离细胞内氨基酸浓度变化的作用知之甚少。在这里，我们确定了非分裂裂殖酵母细胞的时序衰老过程中的游离氨基酸水平。我们将野生型与缺乏蛋白激酶 A 信号通路蛋白 Pka1 的长寿突变体细胞进行比较。在野生型细胞中，总氨基酸水平随衰老而下降，但在 pka1 突变体中下降得少得多。两种氨基酸随年龄变化明显：谷氨酰胺减少，尤其是在野生型细胞中，而天冬氨酸增加，尤其是在 pka1 突变体中。谷氨酰胺的补充足以延长野生型细胞的时序寿命，但不能延长 pka1Δ 细胞的寿命。另一方面，天冬氨酸的补充缩短了 pka1Δ 细胞但不缩短野生型细胞的寿命。我们的结果提出了这样一种可能性，即某些氨基酸是衰老的生物标志物，它们在衰老过程中的浓度可以促进或限制细胞寿命。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0cc9/7812441/a3969e7d8ec2/glaa246_fig1.jpg

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在衰老过程中细胞内水平变化最大的氨基酸会改变裂殖酵母的时序寿命。

Amino Acids Whose Intracellular Levels Change Most During Aging Alter Chronological Life Span of Fission Yeast.

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