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More on the Mechanisms by Which Reducing Age-Related Peroxisome Loss Extends Life


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Posted Today, 10:22 AM


You might recall that last year researchers demonstrated an age-related decline in peroxisome number in cells. Peroxisomes carry out a range of functions related to oxidative and lipid metabolism, but are relatively poorly researched in the context of aging. The decline in number of peroxisomes modestly accelerates the pace of aging, as researchers found that forcing a normalization of the number of peroxisomes via prx-11 inhibition extended life in nematode worms. Here, the same researchers provide an update on how they think that this all works under the hood, providing evidence for peroxisome counts to affect life span via mitochondrial function.

Peroxisomes execute essential functions in cells, including detoxification and lipid oxidation. Despite their centrality to cell biology, the relevance of peroxisomes to aging remains understudied. We recently reported that peroxisomes are degraded en masse via pexophagy during early aging in the nematode Caenorhabditis elegans, and we found that downregulating the peroxisome-fission protein PRX-11/PEX11 prevents this age-dependent pexophagy and extends lifespan. Here, we further investigated how prx-11 inhibition promotes longevity.

Remarkably, we found that reducing peroxisome degradation with age led to concurrent improvements in another organelle: the mitochondrion. Animals lacking prx-11 function showed tubular, youthful mitochondria in older ages, and these enhancements required multiple factors involved in mitochondrial tubulation and biogenesis, including FZO-1/Mitofusin, UNC-43 protein kinase, and DAF-16/FOXO. Importantly, mutation of each of these factors negated lifespan extension in prx-11-defective animals, indicating that pexophagy inhibition promotes longevity only if mitochondrial health is co-maintained.

We also found that experimental perturbation of mitochondria precipitated faster pexophagy with aging, implying bidirectionality in signaling between these two organelles. Our data support a model in which peroxisomes and mitochondria track together with age and interdependently influence animal lifespan.

Link: https://doi.org/10.18632/aging.206395


View the full article at FightAging




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