Pathogenic variants in TNNC2 cause congenital myopathy due to an impaired force response to calcium
Martijn van de Locht, … , Carsten G. Bönnemann, Coen A.C. Ottenheijm
Martijn van de Locht, … , Carsten G. Bönnemann, Coen A.C. Ottenheijm
Published March 23, 2021
Citation Information: J Clin Invest. 2021;131(9):e145700. https://doi.org/10.1172/JCI145700.
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Research Article Genetics Muscle biology

Pathogenic variants in TNNC2 cause congenital myopathy due to an impaired force response to calcium

Abstract

Troponin C (TnC) is a critical regulator of skeletal muscle contraction; it binds Ca2+ to activate muscle contraction. Surprisingly, the gene encoding fast skeletal TnC (TNNC2) has not yet been implicated in muscle disease. Here, we report 2 families with pathogenic variants in TNNC2. Patients present with a distinct, dominantly inherited congenital muscle disease. Molecular dynamics simulations suggested that the pathomechanisms by which the variants cause muscle disease include disruption of the binding sites for Ca2+ and for troponin I. In line with these findings, physiological studies in myofibers isolated from patients’ biopsies revealed a markedly reduced force response of the sarcomeres to [Ca2+]. This pathomechanism was further confirmed in experiments in which contractile dysfunction was evoked by replacing TnC in myofibers from healthy control subjects with recombinant, mutant TnC. Conversely, the contractile dysfunction of myofibers from patients was repaired by replacing endogenous, mutant TnC with recombinant, wild-type TnC. Finally, we tested the therapeutic potential of the fast skeletal muscle troponin activator tirasemtiv in patients’ myofibers and showed that the contractile dysfunction was repaired. Thus, our data reveal that pathogenic variants in TNNC2 cause congenital muscle disease, and they provide therapeutic angles to repair muscle contractility.

Authors

Martijn van de Locht, Sandra Donkervoort, Josine M. de Winter, Stefan Conijn, Leon Begthel, Benno Kusters, Payam Mohassel, Ying Hu, Livija Medne, Colin Quinn, Steven A. Moore, A. Reghan Foley, Gwimoon Seo, Darren T. Hwee, Fady I. Malik, Thomas Irving, Weikang Ma, Henk L. Granzier, Erik-Jan Kamsteeg, Kalyan Immadisetty, Peter Kekenes-Huskey, José R. Pinto, Nicol Voermans, Carsten G. Bönnemann, Coen A.C. Ottenheijm

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Figure 3

Histology of F1:P1 spinal accessory muscle biopsy at age 16 years (left) and F2:P1 vastus lateralis muscle biopsy at age 9 years (right).

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Histology of F1:P1 spinal accessory muscle biopsy at age 16 years (left)...
(A and B) H&E staining shows mild myofiber size variability in both patients. (C and D) Gömöri trichrome staining shows no signs of nemaline rods in myofibers of both patients. (E and F) Staining of NADH in muscle cross sections shows larger slow-twitch fibers (dark blue, indicated with “I.”) than fast-twitch fibers (light blue, indicated with “II.”) in both patients. (G) Graph showing the myofiber minFeret of slow-twitch versus fast-twitch myofibers in control subjects (C), F1:P1, and F2:P1. (H) Graph showing the proportion of slow-twitch versus fast-twitch myofibers in control subjects (C), F1:P1, and F2:P1. The dark shading indicates the proportion of slow-twitch fibers and the light shading indicates the proportion of fast-twitch fibers. (I and J) Electron microscopy images show no abnormalities, and an intact myofibrillar structure in both patients. (K) Top: Typical example of a low-angle x-ray diffraction pattern obtained from 28 fast-twitch myofibers of F1:P1 mounted and aligned in 1 plane between 2 halves of an electron microscopy grid. Note the well-resolved equatorial and meridional reflections. Arrows indicate the actin layer line 6 (ALL6) and Tn3 reflections. Bottom: Myosin heavy chain isoform composition of the myofibers in the grids, showing successful segregation of fast- and slow-twitch fibers from F1:P1 (grid = protein content of F1:P1 grids; hom = muscle homogenate from human diaphragm muscle; 2X and 2A = fast-twitch myosin heavy chain isoforms; slow = slow-twitch myosin heavy chain isoform). Spacing of the ALL6 reflection (L) and the Tn3 reflection (M) are comparable between slow- and fast-twitch myofibers. Each symbol represents data from 1 set of grids containing 28 myofibers. Data are depicted as mean ± SEM.