Figure 1. Genes responsible for ether lipid biosynthesis are necessary for biguanide-induced lifespan extension.

(A) C. elegans ether lipid synthesis is catalyzed by three enzymes: fatty acyl reductase FARD-1, acyltransferase ACL-7, and alkylglycerone phosphate synthase ADS-1 (adapted from Figure 1 of Shi et al., 2016 and Dean and Lodhi, 2018). The latter two are localized to the peroxisomal lumen. (B–D) Missense, loss-of-function mutations in fard-1 (B), acl-7 (C), and ads-1 (D) in C. elegans suppress phenformin-induced lifespan extension. (E–G) A deficiency of ether lipid synthesis in fard-1 (E), acl-7 (F), and ads-1 (G) worm mutants blunts metformin-induced lifespan extension. Results are representative of three biological replicates. *, p<0.05; **, p<0.01; ***, p<0.001; ****, p<0.0001 by log-rank analysis. Note that (B–D) and (E–G) contain the same wild-type (wt) controls as they are visualized from the same replicate of the study. See also Figure 1—figure supplement 1 and refer to Supplementary file 1 for tabular survival data and biological replicates. (H–I) Normalized concentrations of phenformin (H) and metformin (I) in vehicle, 4.5 mM phenformin, or 50 mM metformin-treated wt C. elegans versus fard-1, acl-7, and ads-1 mutants. n=3 biological replicates; ***, p<0.004 by two-tailed Student’s t-test with Bonferroni correction for multiple hypothesis testing. Box represents 75th/25th percentiles, while whisker represents higher/lower hinge ± [1.5 * interquartile range (IQR)].

Figure 1—figure supplement 1. Reduced function of genes responsible for ether lipid biosynthesis partially suppresses biguanide effects of growth and lifespan without affecting biguanide levels.

(A) RNA interference (RNAi) knockdown of fard-1 and acl-7 induces resistance to growth inhibition by 160 mM metformin treatment in C. elegans. *, p<0.05, by two-way ANOVA, n=2 biological replicates. (B–C) RNAi knockdown of fard-1 (B) and acl-7 (C) in C. elegans partially suppresses phenformin’s effect on lifespan extension. For (B and C), results are representative of three biological replicates. Note that (B–C) contain the same wild-type controls as they are visualized from the same replicate of the study. ****, p<0.0001 by log-rank analysis; for tabular survival data and biological replicates see also Supplementary file 1. (D) Log fold change (LogFC) of phenformin abundance in samples treated with 4.5 mM phenformin versus vehicle reveals that the increase in phenformin levels in wild-type and three ether lipid deficient mutants is similar. (E) LogFC of metformin abundance in samples treated with 50 mM metformin versus vehicle shows that metformin increases are similar across all four strains. n = 3 biological replicates. Bars represent mean and 95% confidence intervals.

Figure 1—figure supplement 2. The use of 5-fluoro-2′-deoxyuridine (FUdR) in lifespan analyses does not impact the observed epistases between the ether lipid machinery and biguanide-mediated lifespan extension.

Lifespans performed without the use of FUdR to inhibit progeny formation corroborate that a deficiency of ether lipid synthesis in fard-1 (A/D), acl-7 (B/E), and ads-1 (C/F) worm mutants negates both metformin (top row) and phenformin (bottom row)-induced lifespan extension. Loss-of-function mutants for fard-1, acl-7, and ads-1 are compared to wild-type (wt) treated with vehicle control (veh) versus 50 mM metformin (met) or 4.5 mM phenformin (phen). Results are representative of three biological replicates. *, p<0.05; **, p<0.01; ***, p<0.001; ****, p<0.0001 by log-rank analysis. Note that A/D, B/E, and C/F contain the same vehicle controls as they are visualized from the same replicate of the study. Please refer to Supplementary file 1 for tabular survival data and biological replicate summary statistics.