Abstract
Kidney failure occurs in 5–13% of individuals with sickle cell disease and is associated with early mortality. Two APOL1 alleles (G1 and G2) have been identified as risk factors for sickle cell disease nephropathy. Both risk alleles are prevalent in individuals with recent African ancestry and have been associated with nephropathic complications in other diseases. Despite the association of G1 and G2 with kidney dysfunction, the mechanisms by which these variants contribute to increased risk remain poorly understood. Previous work in zebrafish models suggest that the G2 risk allele functions as a dominant negative, whereas the G1 allele is a functional null. To understand better the cellular pathology attributed to APOL1 G2, we investigated the in vivo effects of the G2 risk variant on distinct cell types using RNA sequencing. We surveyed APOL1 G2 associated transcriptomic alterations in podocytes and vascular endothelial cells isolated from zebrafish larvae expressing cell-type specific reporters. Our analysis identified many transcripts (n = 7,523) showing differential expression between APOL1 G0 (human wild-type) and APOL1 G2 exposed podocytes. Conversely, relatively few transcripts (n = 107) were differentially expressed when comparing APOL1 G0 and APOL1 G2 exposed endothelial cells. Pathway analysis of differentially expressed transcripts in podocytes showed enrichment for autophagy associated terms such as “Lysosome” and “Phagosome”, implicating these pathways in APOL1 G2 associated kidney dysfunction. This work provides insight into the molecular pathology of APOL1 G2 nephropathy which may offer new therapeutic strategies for multiple disease contexts such as sickle cell nephropathy.
Highlights
Individuals of African descent are at greater risk for developing end-stage renal disease (ESRD) than individuals of European descent [1]
We conducted transcriptomic analysis of fluorescence activated cell sorting (FACS) purified podocytes and vascular endothelial cells from 4 dpf zebrafish larvae exposed at the 1–4 cell stage to Apolipoprotein L1 (APOL1) G0 mRNA, APOL G2 mRNA, or phenol red (n = 3 pools of 100 larvae per cell type, per condition, Fig 1)
Independent alignment of sequenced reads against human APOL1 mRNA revealed no persistent human mRNA in injected samples, suggesting that the injected human mRNA is lost by 4 dpf
Summary
Individuals of African descent are at greater risk for developing end-stage renal disease (ESRD) than individuals of European descent [1]. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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