Lipid metabolism plays an essential role in the survival and adaptation of animals under variable environmental conditions. Lipids are important macromolecules that store energy, serve as structural components, and function as signaling molecules (Watts and Ristow 2017; Papsdorf and Brunet 2019). Defects in lipid metabolism are linked to various diseases and aging in eukaryotes. Therefore, understanding the regulation of this process is critical to modulating disease progression (Wymann and Schneiter 2008).
We have shown earlier that lipid metabolism in C. elegans is regulated by an Axin family member, PRY-1 (Ranawade et al. 2018). While the signaling network of PRY-1 in this process remains to be investigated, Axin family of proteins are known to function in both WNT dependant and independent pathways to regulate various developmental events (Mallick, et al. 2019). Our transcriptomic analysis of both mRNA and miRNA genes revealed that PRY-1 is involved in lipid synthesis by affecting the expression of genes such as fatty acid desaturases (
fat-5,
fat-6, and
fat-7) and vitellogenins (
vit-1,
vit-2,
vit-3,
vit-4,
vit-5 and
vit-6) (Ranawade et al. 2018; Mallick, et al. 2019).
Vitellogenins are yolk lipoproteins, similar to mammalian apolipoprotein B, that bind to complex lipids and aid in their transportation from the intestine to the gonad (Kimble and Sharrock 1983; Grant and Hirsh 1999). Moreover,
vit-2 has been shown to negatively regulate longevity and such a role of
vit-2 depends on autophagy, lysosomal lipases, DAF-16/FOXO and HLH-30/TFEB (Seah et al. 2016). In this study, we report a new, adult-specific role of
vit-2 in
pry-1-mediated regulation of lipid levels and lifespan. We analyzed the transcript levels of vit genes in
day-1 and
day-4 adults and found that
vit-2 was the only vitellogenin whose expression was significantly upregulated in
pry-1 mutants (Figure 1A). This suggested to us that
vit-2 is negatively regulated by
pry-1 and may be involved in
pry-1-mediated adult-specific processes. To investigate this further, we examined whether
vit-2 knockdown during adulthood can rescue the lipid and lifespan defect (Mallick, et al. 2020) of
pry-1 mutants. This was done using a
vit-1 dsRNA that also knocks down
vit-2 due to the sequence similarity (Ranawade et al. 2018). The results showed that the knockdown of
vit-1/2 during adulthood significantly rescued lipid levels in
pry-1(
mu38) (almost 2-fold) (Figures 1B and 1C). Similar experiments in wildtype animals showed a modest increase (by 1.2-fold). We also examined the lifespan phenotype following
vit-1/2 RNAi and observed a marked rescue of the lifespan defect (Mallick et al. 2020) in
pry-1(
mu38) (102% increase in mean lifespan). The wildtype animals showed a comparatively lower increase in the mean lifespan (16.6%) (Figures 1F and 1G). Overall, these findings show that
vit-2 functions downstream of
pry-1 to regulate both lipid levels and lifespan.