APOL1 variants change C-terminal conformational dynamics and binding to SNARE protein VAMP8
Sethu M. Madhavan, John F. O’Toole, Martha Konieczkowski, Laura Barisoni, David B. Thomas, Santhi Ganesan, Leslie A. Bruggeman, Matthias Buck, John R. Sedor
Sethu M. Madhavan, John F. O’Toole, Martha Konieczkowski, Laura Barisoni, David B. Thomas, Santhi Ganesan, Leslie A. Bruggeman, Matthias Buck, John R. Sedor
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Research Article Nephrology

APOL1 variants change C-terminal conformational dynamics and binding to SNARE protein VAMP8

Abstract

APOL1 variants in African populations mediate resistance to trypanosomal infection but increase risk for kidney diseases through unknown mechanisms. APOL1 is expressed in glomerular podocytes and does not vary with underlying kidney disease diagnoses or APOL1 genotypes, suggesting that the kidney disease–associated variants dysregulate its function rather than its localization or abundance. Structural homology searches identified vesicle-associated membrane protein 8 (VAMP8) as an APOL1 protein interactor. VAMP8 colocalizes with APOL1 in the podocyte, and the APOL1:VAMP8 interaction was confirmed biochemically and with surface plasmon resonance. APOL1 variants attenuate this interaction. Computational modeling of APOL1’s 3-dimensional structure, followed by molecular dynamics simulations, revealed increased motion of the C-terminal domain of reference APOL1 compared with either variant, suggesting that the variants stabilize a closed or autoinhibited state that diminishes protein interactions with VAMP8. Changes in ellipticity with increasing urea concentrations, as assessed by circular dichroism spectroscopy, showed higher conformational stability of the C-terminal helix of the variants compared with the reference protein. These results suggest that reference APOL1 interacts with VAMP8-coated vesicles, a process attenuated by variant-induced reduction in local dynamics of the C-terminal. Disordered vesicular trafficking in the podocyte may cause injury and progressive chronic kidney diseases in susceptible African Americans subjects.

Authors

Sethu M. Madhavan, John F. O’Toole, Martha Konieczkowski, Laura Barisoni, David B. Thomas, Santhi Ganesan, Leslie A. Bruggeman, Matthias Buck, John R. Sedor

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Figure 5

Kidney disease–associated variants are more compatible with a helix-bundle (“closed”) structure compared with the wild type protein.

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Kidney disease–associated variants are more compatible with a helix-bund...
(A) The 3-dimensional structure of the apolipoprotein L1 (APOL1) carboxy terminal region (aa 305–398) was modeled by threading using Iterative Threading ASSEmbly Refinement (I-TASSER). Structures of APOL1-G0 (green), -G1 (cyan), and -G2 (magenta) are overlapped showing similar starting structures. The predicted structure of the carboxy terminal domain has 3 α-helices (H1, H2, and H3) connected by loops. The magnified view demonstrates the position of residues S342 and I384, which are altered in APOL1-G1, and residues N388 and Y389, which are deleted in APOL1-G2. (B) After 40 ns of molecular dynamics (MD) simulations, the final structures were superimposed to show differences in the wild-type and risk variant structures as they evolved during the simulations. (C) Root mean square deviation (RMSD) of α carbon (Cα) atoms relative to the coordinates of initial structure as a function of simulation time shows higher deviation of the APOL1-G0 structure compared with the APOL1-G1 and -G2 variants. (D) Flexibility of backbone Cα atoms, indicated by root mean square fluctuation (RMSF) on the y axis for each residue shown on the x axis. The results represent mean RMSF values in the last 10 ns of two separate MD simulations carried out for 40 ns. Backbone atoms of APOL1-G0 show increased flexibility, as demonstrated by the higher RMSF values compared with the variant proteins, especially in H1 and H3. (E and F) Projection of MD trajectories (40 ns) of the APOL1-G0, -G1, and -G2 carboxy terminal domain (aa 305–398) on the first, second, and third principal components (PC) derived from Cα-only principal component analysis, showing close clustering of the APOL1-G1 and -G2 conformations compared with APOL1-G0.