Mitochondrial complex I is central to the pathological reactive oxygen species (ROS) production that underlies cardiac ischemia-reperfusion (IR) injury. ND6-P25L mice are homoplasmic for a disease-causing mtDNA point mutation encoding the P25L substitution in the ND6 subunit of complex I. The cryo-EM structure of ND6-P25L complex I revealed subtle structural changes that facilitate rapid conversion to the "deactive" state, usually formed only after prolonged inactivity. Despite its tendency to adopt the "deactive" state, the mutant complex is fully active for NADH oxidation, but cannot generate ROS by reverse electron transfer (RET). ND6-P25L mitochondria function normally, except for their lack of RET ROS production, and ND6-P25L mice are protected against cardiac IR injury in vivo. Thus, this single point mutation in complex I, which does not affect oxidative phosphorylation but renders the complex unable to catalyse RET, demonstrates the pathological role of ROS production by RET during IR injury

Aksentijević, Dunja

Bridges, Hannah R

Burger, Nils

Grba, Daniel N

Hirst, Judy

James, Andrew M

Krieg, Thomas

Kula-Alwar, Duvaraka

Mottahedin, Amin

Murphy, Michael P

Prag, Hiran A

Viscomi, Carlo

Yin, Zhan

Apollo (Cambridge)

Structural basis for a complex I mutation that blocks pathological ROS production.

Yin, Z

Burger, N

Kula-Alwar, D

Aksentijević, D

Bridges, HR

Prag, HA

Grba, DN

Viscomi, C

James, AM

Mottahedin, A

Krieg, T

Murphy, MP

Hirst, J

Queen Mary Research Online

Funder: RCUK | MRC | Medical Research Foundation; doi: https://doi.org/10.13039/501100009187Abstract: Mitochondrial complex I is central to the pathological reactive oxygen species (ROS) production that underlies cardiac ischemia–reperfusion (IR) injury. ND6-P25L mice are homoplasmic for a disease-causing mtDNA point mutation encoding the P25L substitution in the ND6 subunit of complex I. The cryo-EM structure of ND6-P25L complex I revealed subtle structural changes that facilitate rapid conversion to the “deactive” state, usually formed only after prolonged inactivity. Despite its tendency to adopt the “deactive” state, the mutant complex is fully active for NADH oxidation, but cannot generate ROS by reverse electron transfer (RET). ND6-P25L mitochondria function normally, except for their lack of RET ROS production, and ND6-P25L mice are protected against cardiac IR injury in vivo. Thus, this single point mutation in complex I, which does not affect oxidative phosphorylation but renders the complex unable to catalyse RET, demonstrates the pathological role of ROS production by RET during IR injury

Bridges, Hannah R.

Prag, Hiran A.

Grba, Daniel N.

James, Andrew M.

Murphy, Michael P.

 1 Supplementary  Information Structural basis for a complex I mutation that blocks pathological ROS production  Zhan Yin1, Nils Burger1, Duvaraka Kula-Alwar2, Dunja Aksentijević3,4, Hannah R. Bridges1, Hiran A. Prag1, Daniel N. Grba1, Carlo Viscomi1, Andrew M. James1, Amin Mottahedin1,2,5, Thomas Krieg2, Michael P. Murphy1,2* & Judy Hirst1*   1MRC Mitochondrial Biology Unit, University of Cambridge, Cambridge Biomedical Campus, CB2 0XY, UK 2Department of Medicine, University of Cambridge, Cambridge, CB2 0QQ, UK 3William Harvey Research Institute, Barts and The London School of Medicine and Dentistry, Queen Mary University of London, Charterhouse Square, London, EC1M 6BQ, UK 4Centre for Inflammation and Therapeutic Innovation, Queen Mary University of London, Charterhouse Square, London, EC1M 6BQ, UK. 5Department of Physiology, Institute of Neuroscience and Physiology, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden       2   Supplementary Fig. 1. Classification and Refinement Scheme for Cryo-EM Data Processing for ND6-P25L-CI and the deactive State of WT-CI.  (A) ND6-P25L-CI. (B) Deactive state of WT-CI. Based on the relative positions of subunit NDUFA10 and NDUFA5 the 7.4 Å resolution map from a minor class of ND6-P25L-CI particles is also in a deactive-like state, and the 3.7 Å resolution map from a minor class in the deactive preparation of WT-CI most likely results from a mixed class of active- and deactive-like particles. Related to Figure 1.   3    Supplementary Fig. 2 Resolution Estimates of the Cryo-EM Density Maps for the ND6-P25L-CI and the deactive state of WT-CI. (A, C) ND6-P25L-CI. (B, D) Deactive state of WT-CI. In (A) and (B), local resolutions were estimated using the Local Resolution function in RELION with default parameters and shown using UCSF Chimera according to the color bar. In (C) and (D) the estimated global map resolutions, defined where the red FSC line = 0.143, are 3.8 and 3.2 Å, respectively. In both cases, the refined models agree well with the maps, as shown by the map vs. model FSC curves (blue). Related to Figure 1.       4    Supplementary Fig 3. Models and densities for ND6 TMHs 2 and 3 showing the relative positions of bulky residues and the mutation site. (A) side view from the membrane plane; (B) top view from the matrix side. Densities were rendered 2 Å from the model in UCFS Chimera at thresholds of 0.0162, 0.0238, and 0.0161 for ND6-P25L, deactive and active, respectively. The mesh was surfaced smoothed with two iterations with a factor of 0.3. Residues are shown as transparent except for P/L25, F67 and Y69. Related to Figure 1.     5   Supplementary Fig. 4. Structural adjustments associated with rotation of the ND6-TMH3 π bulge.  The rotation of the ND6-TMH3 π bulge in the ND6-P25L complex I (wheat) (and also in the deactive wild-type enzyme, not shown) when it adopts an -helical structure in the active state (red) results in an upward motion and reorientation of bulky residues F67 and Y69. There is an accompanying shift in the upper portion of ND1-TMH4, resulting in Y127 forming a binding pocket (yellow highlight) for the Cys39 on the ND3-TMH1–2 loop, along with NDUFS2-H55. This binding site is formed when ordered ND1-TMH5–6, NDUFS2 and ND3-TMH2–3 loops are present in the active site. All of these loops are disordered and exposed to the matrix in the ND6-P25L enzyme and in the deactive state (not shown), resulting in destabilization of the Cys39-binding pocket (note the partial ND1-TMH5–6 loop of the ND6-P25L enzyme in the destroyed binding pocket), straightening of ND1-TMH4 and formation of the ND6–TMH3 π bulge. The ubiquinone catalytic ligands (Y108 and H59) and the terminal N2 cluster are shown for reference. Colored arrows indicate the general motion observed in transitions to the active state (red) and the P25L/deactive states (wheat). Related to Figure 1.    6  Supplementary Fig. 5 Quantification of Mitochondrial H2O2 Production.  (A, B) The rates of H2O2 production by isolated heart mitochondria at 37 °C in the O2K Oxygraph, during respiration on (A) glutamate/malate (0.5 mM) and (B) upon subsequent addition of succinate (10 mM). Mitochondria were isolated from four hearts and pooled to provide a single test sample. The data are mean averages ± S.E.M. (A, n = 8, B, n = 3, technical replicates) evaluated using an unpaired, two-tailed Student’s t-test (**, p < 0.01). In A, p = 0.439 and in B, p = 0.001. One of the replicates is shown in Figure 3F. (C, D) The rates of H2O2 production by isolated heart mitochondria at room temperature in the Amplex Red plate reader assay, during respiration on (C) glutamate/malate (0.5 mM) and (D) upon subsequent addition of succinate (10 mM). Rotenone or FCCP (at 5 M) were added as indicated. The data are mean averages ± S.E.M. (n = 3, where each replicate is from an independent mitochondrial preparation on a different heart) evaluated using a two-way ANOVA test with Tukey’s multiple comparisons correction (****, p < 0.0001). The p values in C are: 0.939, 0.875 and 0.999, respectively.  The p values in D are: <0.0001, 0.993 and 0.999, respectively. Related to Figure 3.  7 Supplementary Table 1  Cryo-EM Data Collection, Refinement and Validation Statistics. Related to Figure 1.     WT Deactive EMD-11810 PDB 7AK5 ND6-P25L EMD-11811 PDB 7AK6  Data collection and processing   Magnification  37,600 130,000 Voltage (kV) 300 300 Electron exposure (e–/Å2) 50 50 Defocus range (μm) -2.2 to -3.4 -1.5 to -3.0 Pixel size (Å) 1.350 1.054 Symmetry imposed C1 C1 Initial particle images (no.) 148,440 42,622 Final particle images (no.) 50,184 26,638 Map resolution (Å)  FSC threshold 3.18 0.143 3.83 0.143 Map resolution range (Å) 2.9 to 7.6 3.5 to 8.2 Map sharpening B factor (Å2) -23 -74    Refinement   Initial model used  PDB 6ZR2 PDB 6ZR2 Model resolution (Å)  FSC threshold 3.2 0.5 3.9 0.5 Model composition  Nonhydrogen atoms  Protein residues  Ligands  65,903 8,070 28  65,341 8,063 21 B factors mean (Å2)  Protein  Ligand  42.79 38.24  58.21 57.59 R.m.s. deviations  Bond lengths (Å)  Bond angles (°)  0.003 0.587  0.004 0.605 Validation  MolProbity score  Clashscore, all atoms  Poor rotamers (%)   1.80 7.25 0.01  2.1 10.83 0 Ramachandran plot  Favored (%)  Allowed (%)  Disallowed (%)  94.05 5.94 0.01  89.91 10.07 0.01 EMRinger 2.66 2.19         8 Supplementary Table 2  Summary of the models for the subunits of deactive and ND6 mouse complex I. Where the values differ they are given first for the deactive model, then in brackets for the ND6 model. Related to Figure 1.  Subunit Chain Total residues Modeled residues % Modeled Qscore Notes        NDUFV1 F 444 10-437 96.4 0.63 (0.54) FMN, 4Fe4S NDUFV2 E 217 5-216 97.7 0.61 (0.51) 2Fe2S NDUFS1 G 704 7-692 (6-693) 97.7 (97.4) 0.65 (0.55) 2Fe2S, 2 x 4Fe4S NDUFS2 D 430 1-38, 46-54, 61-430 (1-39, 46-54, 60-430)  97.4 (97.0) 0.69 (0.58) Dimethyl-Arg85 NDUFS3 C 228 7-213 (8-214) 90.8 (90.8) 0.69 (0.59)  NDUFS7 B 189 35-189 82.0 0.68 (0.58) 4Fe4S NDUFS8 I 178 1-178 100 0.69 (0.59) 2 x 4Fe4S no sidechains 8-14 ND1 H 318 1-60, 67-206, 214-318 (1-203, 214-318) 96.9 (95.9) 0.66 (0.55) N-formyl ND2 N 345 1-344 99.7 0.67 (0.56) N-formyl ND3 A 115 1-26, 49-115 (1-25, 51-115)  78.2 (80.9) 0.65 (0.52) N-formyl ND4 M 459 1-459 100 0.67 (0.56) N-formyl ND4L K 98 1-98 100 0.66 (0.56) N-formyl ND5 L 607 1-606 99.8 0.64 (0.53) N-formyl ND6 J 172 1-171 99.4 0.62 (0.50) N-formyl no sidechains 108-112 NDUFV3 s 69 30-68 56.5 0.62 (0.53)  NDUFS4 Q 133 9-133 94.0 0.67 (0.57)  NDUFS5 e 105 1-104 99.0 0.66 (0.55) 2 x Cys-Cys (no Cys-Cys) NDUFS6 R 96 1-94 97.9 0.68 (0.57) Zn2+ NDUFA1 a 70 1-68 97.2 0.67 (0.55)  NDUFA2 S 98 14-95 83.7 0.58 (0.48)  NDUFA3 b 83 2-83 (1-83) 100 (98.8) 0.62 (0.51)  NDUFA5 V 115 4-115 97.4 0.62 (0.53)  NDUFA6 W 130 17-130 87.7 0.63 (0.52)  NDUFA7 r 112 1-73, 90-112 85.7 0.66 (0.55) N-acetyl NDUFA8 X 171 1-171 100 0.65 (0.55) (2 x Cys-Cys) NDUFA9 P 342 1-185, 200-249, 280-323, 334-342 (1-185, 199-249, 279-323, 334-342) 85.1 (84.2) 0.62 (0.53) NADPH NDUFA10 O 320 2-320 (1-320) 100 (99.7) 0.65 (0.54) ATP NDUFA11 Y 140 1-140 100 0.63 (0.50) 2 x Cys-Cys (1 x Cys-Cys) NDUFA12 q 145 2-144 (1-144) 99.3 (98.6) 0.68 (0.56) N-acetyl NDUFA13 Z 143 5-143 97.2 0.65 (0.55)  NDUFAB1 T 88 11-82 (10-82) 83.0 (81.8) 0.47 (0.37) 4’-phosphopantethine +  3-hydroxyundecanoate NDUFAB1 U 88 1-88 100 0.59 (0.48) NDUFB1 f 56 4-54 (5-54) 89.3 (91.1) 0.61 (0.50)  NDUFB2 j 72 7-68 (6-68) 87.5 (86.1) 0.60 (0.48)  NDUFB3 k 103 18-94 (17-94) 75.7 (74.8) 0.58 (0.50)  NDUFB4 m 128 4-128 97.7 0.63 (0.52)  NDUFB5 h 143 7-143 95.8 0.67 (0.56)  NDUFB6 i 127 2-35, 64-124 (1-35, 64-124) 75.6 (74.8) 0.60 (0.49) N-acetyl NDUFB7 o 136 2-115 (2-112) 81.6 (83.8) 0.56 (0.47)  NDUFB8 l 157 2-157 99.4 0.65 (0.54)  NDUFB9 n 178 1-176 98.9 0.64 (0.52)  NDUFB10 p 175 4-171 96.0 0.63 (0.52) 2 x Cys-Cys NDUFB11 g 122 19-120 (21-121)  82.7 (83.6) 0.64 (0.54)  NDUFC1 c 49 2-47 93.9 0.61 (0.51)  NDUFC2 d 120 1-119 99.1 0.66 (0.56)            

Structural basis for a complex I mutation that blocks pathological ROS production

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Structural basis for a complex I mutation that blocks pathological ROS production.

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