Aims: It is unknown whether long-term low-density lipoprotein cholesterol (LDL-c) lowering increases lifespan and longevity in a general population not selected for elevated cardiovascular risk. The present study aimed to investigate the overall and gene-specific effect of circulating LDL-c levels on lifespan and longevity in a general population.
Methods: Leveraging data from the Global Lipids Genetics Consortium (n = 173 082), we identified genetic variants to proxy LDL-c levels generally, and also through perturbation of particular drug targets (HMGCR, NPC1L1 and PCSK9). We investigated their association with lifespan (n = 1 012 240) using Mendelian randomization, and replicated results using the outcome of longevity to the 90th vs. 60th percentile age (11 262 cases/25 483 controls).
Results: A 1-standard deviation increase in genetically proxied LDL-c was associated with 1.2 years lower lifespan (95% confidence interval [CI] -1.55, -0.87; P = 3.83 × 10-12 ). Findings were consistent in statistical sensitivity analyses, and when considering the outcome of longevity (odds ratio for survival to the 90th vs 60th percentile age 0.72, 95% CI 0.64, 0.81, P = 7.83 × 10-8 ). Gene-specific Mendelian randomization analyses showed a significant effect of LDL-c modification through PCSK9 on lifespan (-0.99 years, 95% CI -1.43, 0.55, P = 6.80 × 10-6 ); however, estimates for HMGCR and NPC1L1 were underpowered.
Conclusions: This genetic evidence supports that higher LDL-c levels reduce lifespan and longevity. In a general population that is not selected for increased cardiovascular risk, there is likely to be a net lifespan benefit of LDL-c lowering therapies, particularly for PCSK9 inhibitors, although randomized controlled trials are necessary before modification of clinical practice.
Keywords: HMGCR; LDL-c; Mendelian randomization; NPC1L1; PCSK9; lifespan.
© 2021 British Pharmacological Society.