Gene Targets to Halt Cognitive Decline


Researchers have identified potential mechanisms that allow long-lived mutants of the model organism Caenorhabditis elegans to preserve learning and memory abilities later in life, while some exhibit cognitive decline.

The study, previously published as a Reviewed Preprint in eLife, with a revised version appearing today, is described as of fundamental importance by the editors. They say it provides compelling evidence for the mechanisms by which C. elegans worms with a mutation in the daf-2 gene maintain cognitive function later in life better than their typical counterparts.

The findings could inform strategies to combat the cognitive decline associated with ageing in humans.

Cognitive Decline: A Growing Public Health Concern as Society Age

“As our society ages, cognitive decline is becoming an increasingly significant public health concern, with global cases of dementia expected to triple by 2050 according to research presented at the 2021 Alzheimer’s Association International Conference,” says lead author Yifei Weng, doctoral candidate in the Department of Molecular Biology, Princeton University, New Jersey, US. “Understanding and preventing the underlying issues of neuronal structure and behavioural decline associated with ageing is therefore crucial for societal health.”

C. elegans is a commonly used model organism in biology, and is particularly useful for studying the effects of ageing, given its simple nervous system and short lifespan. Many of the genes for neuronal function in mammals are conserved in C. elegans, making discoveries in the species potentially applicable to humans.

The Insulin/IGF-1-like signalling (IIS)/FOXO pathway is a signalling system that regulates growth, metabolism and lifespan, and is highly conserved across species. The daf-2 Insulin/IGF-1 receptor is a key part of this pathway – worms with a genetic mutation in this receptor (daf-2 worms) both have better memory in early adulthood and also show a significant extension of learning and memory span with age, although the mechanisms by which the latter occurs are not yet understood. Therefore, Weng and colleagues sought to identify how ageing daf-2 worms stave off cognitive decline in older age.

First, they investigated the changes in gene expression that typically occur in C. elegans neurons. They used a sequencing technique called RNA-seq to analyse neurons isolated from adult worms at days one and eight of adulthood – when the worms have already lost learning and memory capacity. In the aged worms, they observed decreased activity in genes related to neuronal function, and increased activity in genes involved in protein breakdown, production and gene regulation. To test whether specific increased expression of these genes with age was advantageous or disadvantageous, the team reduced the expression of three genes whose activity is higher in aged animals and performed behavioural assays. Reducing the expression of each of the three genes improved the memory performance of the worms. This indicates that some neuronal genes that increase with age can have a negative impact on learning and memory, and reducing their expression may be beneficial to the animal.

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The extended cognitive ability of daf-2 worms has previously been shown to be reliant on the DAF-16/FOXO transcription factor. So, the team compared the genetic profile of neurons isolated from eight-day-old daf-2 worms with those isolated from worms of the same age with a loss-of-function mutation of the DAF-16 transcription factor (daf-16;daf-2 worms). They observed 570 upregulated and 814 downregulated genes in the daf-2 neurons compared to those from the daf-16;daf-2 worms. Many of the upregulated genes were related to stress responses, including heat stress, oxidative stress, metal stress, and proteolysis – a process that involves genes helping to break down proteins and that is essential for maintaining cellular health and function. To confirm this, the team reduced the expression of the eight most likely responsible genes in C. elegans to assess their effect on cognitive function. Of the eight genes tested, the reduction of three of them significantly reduced the worms’ learning ability. Those genes, plus the reduction of two additional genes – C44B7.5 and alh-2 – significantly reduced the worms’ short-term memory capacity.

Perhaps even more interestingly, daf-2-regulated genes in aged neurons do not match those from young neurons – that is, they are new targets of the IIS/FOXO pathway. The team found that of the top 100 upregulated genes, 36 have corresponding genes in mammals. Of these 36 genes with conserved protein in mammals, 32 of them (89{75697363d893e1edef84ec354d532c3f24107c3d140ee7dc7a797c3c33c7ef25}) have been found to have functions in promoting neuronal health. These mammalian homologs protect neurons against protein aggregation and harmful metabolites, maintain synaptic organisation and neuronal homeostasis, facilitate neuronal injury repair, and maintain normal neuronal function. Together, these genes may be neuroprotective and protect neurons from accumulation of environmental harm during ageing, a new mechanism by which daf-2 worms protect their neurons with age.

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“Our data suggest that genes that are differentially regulated in eight-day-old daf-2 mutants may aid in slowing neuronal function decline and behavioural changes associated with ageing,” says senior author Coleen Murphy, Director of the Lewis-Sigler Institute of Integrative Genomics and Professor of Molecular Biology at Princeton University. “Furthermore, memory maintenance with age might require additional genes that function in promoting stress resistance and neuronal resilience.”

“This study provides a greater understanding of the mechanisms underlying neuronal ageing, and could provide useful insights to aid the development of ageing interventions,” adds Weng.

Source-Eurekalert





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