Cardiac troponin T mutations result in allele-specific phenotypes in a mouse model for hypertrophic cardiomyopathy
Jil C. Tardiff, … , Jeffrey Robbins, Leslie A. Leinwand
Jil C. Tardiff, … , Jeffrey Robbins, Leslie A. Leinwand
Published August 15, 1999
Citation Information: J Clin Invest. 1999;104(4):469-481. https://doi.org/10.1172/JCI6067.
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Article

Cardiac troponin T mutations result in allele-specific phenotypes in a mouse model for hypertrophic cardiomyopathy

Abstract

Multiple mutations in cardiac troponin T (cTnT) can cause familial hypertrophic cardiomyopathy (FHC). Patients with cTnT mutations generally exhibit mild or no ventricular hypertrophy, yet demonstrate a high frequency of early sudden death. To understand the functional basis of these phenotypes, we created transgenic mouse lines expressing 30%, 67%, and 92% of their total cTnT as a missense (R92Q) allele analogous to one found in FHC. Similar to a mouse FHC model expressing a truncated cTnT protein, the left ventricles of all R92Q lines are smaller than those of wild-type. In striking contrast to truncation mice, however, the R92Q hearts demonstrate significant induction of atrial natriuretic factor and β-myosin heavy chain transcripts, interstitial fibrosis, and mitochondrial pathology. Isolated cardiac myocytes from R92Q mice have increased basal sarcomeric activation, impaired relaxation, and shorter sarcomere lengths. Isolated working heart data are consistent, showing hypercontractility and diastolic dysfunction, both of which are common findings in patients with FHC. These mice represent the first disease model to exhibit hypercontractility, as well as a unique model system for exploring the cellular pathogenesis of FHC. The distinct phenotypes of mice with different TnT alleles suggest that the clinical heterogeneity of FHC is at least partially due to allele-specific mechanisms.

Authors

Jil C. Tardiff, Timothy E. Hewett, Bradley M. Palmer, Charlotte Olsson, Stephen M. Factor, Russell L. Moore, Jeffrey Robbins, Leslie A. Leinwand

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Figure 2

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Expression of WT-Myc and R92Q-Myc proteins in cardiac tissue. (a) Coomas...
Expression of WT-Myc and R92Q-Myc proteins in cardiac tissue. (a) Coomassie-stained SDS-PAGE gel of myofibrils isolated from non-Tg (NT), WT-Myc (WT), and 3 independent R92Q-Myc lines. A total of 5 μg myofibril protein was loaded per lane. Addition of the c-myc epitope tag decreases the mobility of the Tg protein (Tg) and allows unambiguous identification. Percentages (30%, 67%, 92%) represent Tg/endogenous cTnT ratios for the 3 R92Q-Myc lines. (b) Western blot analysis of myofibrils subjected to the same SDS-PAGE conditions as noted in a. Identical blots were probed with either a c-myc or cTnT mAb as indicated. The cTnT MAb detects both Tg and endogenous cTnT, and their relative positions are marked by arrows. The additional band immediately above the cTnT band (seen best in the NT lane) represents a known murine cTnT isoform. Note the progressive decrease in endogenous cTnT protein amounts among the 3 R92Q-Myc lines. (c) Myofibrils were purified from mouse hearts, subjected to SDS-PAGE, and Coomassie stained. Myofibrillar stoichiometry is maintained in all Tg lines. (d) Fractionation of cTnT. Three separate fractions were analyzed (T = total, S = supernatant, and P = pellet). Immunoblots of fractions from non-Tg (NT), WT-Myc (WT), and R92Q-67% (R92Q-Myc) were loaded for equal signal intensity and probed with either a cTnT (non-Tg) or c-myc (WT-Myc and R92Q-Myc) mAb as indicated. No Tg protein was detected in the S fraction for either WT-Myc or R92Q-Myc. (e) Transgene protein incorporation. Shown are confocal images of isolated adult cardiac myocytes probed with either c-myc (top; R92Q-67%) or TnT (bottom; non-Tg) mAb. ×4,300.