Deep Phenotyping of Human Knockouts and Population Studies of the APOC3 Pathway
Saleheen, Danish    Rader, Daniel James   
University of Pennsylvania, Philadelphia, PA, United States

Several recent studies indicate that loss of function (LoF) mutations in the apolipoprotein C-III (APOC3) gene offer protection from coronary heart disease (CHD) risk, possibly by reducing circulating triglyceride-rich lipoproteins (TRLs). Inhibition of the apoC-III pathway can provide an attractive therapeutic mechanism to lower CHD risk. There are however many outstanding uncertainties that exist, including impact of apoC-III deficiency on (i) lipoprotein kinetics; (ii) high density lipoprotein remodeling and functionality; (iii) non-lipid related pathways; (iv) the mechanisms by which apoC-III inhibition may reduce CHD risk, (v) the relative contribution of different lipoprotein- associated apoC-III levels on CHD; (vi) liver function and insulin resistance from a safety perspective. In this application, we propose studies to address these gaps by leveraging natural human models of apoC-III deficiency. We have identified the world?s first humans with homozygous APOC3 genetic deficiency who are from an isolated Pakistani village with a high prevalence of consanguinity. Recruitment of all inhabitants in this village (~5000 people) has already been completed; genotyping in a subset has already identified 113 APOC3 knockouts with complete apoC-III deficiency providing opportunities for detailed phenotyping. Specifically, in AIM-1, we will conduct deep phenotyping studies in 113 human APOC3 knockouts (n = 113) and in an equal number of heterozygotes and non-carriers to address the following: (i) role of apoC-III deficiency in modulating protein and lipid composition of TRLs to impact the activity of extracellular lipases; (ii) effect of apoC-III deficiency on subclasses of LDL; (iii) role of apoC-III in modulating Lp(a) levels and composition; and (iv) contribution of apoC-III deficiency to modulation of HDL composition and function. We will also address the consequences of genetic APOC3 deficiency on (iv) systemic lipid and glucose metabolism and a range of proteins related to inflammation and other pathways (v) dose-response association with atherosclerosis.
In AIM -2, we will conduct lipoprotein kinetic studies using isotope tracers on 18 trios of APOC3 null homozygotes, heterozygotes, and non-carriers to evaluate the impact of apoC-III deficiency on kinetics of apoB- containing lipoproteins and production and clearance of HDL apoA-I. We will also generate human iPS cells from 5 APOC3 knockouts and 5 matched/related non-carriers and differentiate them into hepatocytes to evaluate (a) VLDL apoB and TG production (b) TRL and LDL uptake and (c) SRB1 mediated HDL uptake.
In AIM -3, we will measure total plasma apoC-III and lipoprotein-associated (apoB lipoproteins, HDL, and Lp[a]) apoC-III in 5,000 participants from the EPIC-Norfolk cohort (2,500 with incident CHD events). These studies will enable assessment of: (i) disease mediation; (ii) CHD risk progressively adjusted for lipoprotein-associated apoC-III levels and other factors; (iii) dose-response association; (iv) relevance of apoC-III in subgroups (e.g., by T2D); (v) risk prediction beyond traditional CHD risk factors; and (vi) genetic loci associated with apoC-III levels.

Public Health Relevance

We have recently identified the world?s first individuals who carry a mutation in the APOC3 gene that causes them to have a natural deficiency of plasma apolipoprotein C-III (apoC-III) - a pathway which is currently being considered as a therapeutic target in CHD. In this application, we will conduct extensive phenotyping studies in these participants who carry this mutation and matched non-carriers to investigate the biology of the apoC-III and understand any adverse metabolic effects resulting due to natural deficiency of apoC-III. We will also use data from large population based studies to further understand the associations of both plasma apoC-III and mutations in the APOC3 gene with a range of metabolic disorders.