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1 Department of Kinesiology and Applied Physiology, 2 Department of Molecular, Cellular, and Developmental Biology, University of Colorado, Boulder 80309-0354; and 3 Cardiology Division, University of Colorado Health Sciences Center, Denver, Colorado 80262
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Mutations in the cardiac myosin heavy chain
(MHC) can cause familial hypertrophic cardiomyopathy (FHC). A
transgenic mouse model has been developed in which a missense (R403Q)
allele and an actin-binding deletion in the 
-MHC are expressed in
the heart. We used an isovolumic left heart preparation to study the
contractile characteristics of hearts from transgenic (TG) mice and
their wild-type (WT) littermates. Both male and female TG mice
developed left ventricular (LV) hypertrophy at 4 mo of age. LV
hypertrophy was accompanied by LV diastolic dysfunction, but LV
systolic function was normal and supranormal in the young TG females
and males, respectively. At 10 mo of age, the females continued to
present with LV concentric hypertrophy, whereas the males began to
display LV dilation. In female TG mice at 10 mo of age, impaired LV
diastolic function persisted without evidence of systolic dysfunction.
In contrast, in 10-mo-old male TG mice, LV diastolic function worsened and systolic performance was impaired. Diminished coronary flow was
observed in both 10-mo-old TG groups. These types of changes may
contribute to the functional decompensation typically seen in
hypertrophic cardiomyopathy. Collectively, these results further underscore the potential utility of this transgenic mouse model in
elucidating pathogenesis of FHC.
myosin; isovolumic; diastolic; systolic
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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FAMILIAL HYPERTROPHIC
CARDIOMYOPATHY (FHC) is an autosomal dominant disease,
characterized by ventricular hypertrophy, myocellular disarray,
fibrosis, arrhythmias, and increased occurrence of sudden cardiac death
(8, 9). The disease is genetically heterogeneous, but all
of the known mutant genes encode structural proteins of the sarcomere,
including myosin heavy chain (MHC), essential myosin light chain,
regulatory myosin light chain, myosin binding protein C,
-tropomyosin, troponin T, and troponin I (14). In most
patients with FHC, systolic function is normal or supranormal, whereas diastolic function is impaired (11). However, 10-15%
of patients with symptomatic hypertrophic cardiomyopathy present with a
progressive left ventricular (LV) wall thinning and chamber dilation
that occur in conjunction with systolic dysfunction (10, 15,
17). Approximately 30% of patients with FHC have mutations in
the cardiac 
-MHC gene (21). There are several missense
mutations in this gene. Generally, patients with mutations in the
-MHC gene exhibit uniform hypertrophy, but variable sudden death.
One missense mutation in this gene [arginine to glutamine at position
403 (R403Q)] produces a severe form of FHC in humans
(22).
A number of MHC transgenic (TG) animal models of FHC have been created
in an attempt to understand the pathogenesis of FHC phenotypes
typically seen in humans. Because the ventricular myocardium of mice is
100% -MHC, the appropriate MHC to express as a mutant is in the
context of -MHC rather than -MHC. None of the residues implicated
in FHC differ between - and -MHC. Our MHC TG mouse model consists
of an -MHC R403Q mutation and a deletion in the actin binding domain
of the -MHC. These mice exhibit many of the features seen with FHC
in humans, including LV and right ventricular (RV) hypertrophy,
cellular disarray, and fibrosis (20). Two molecular
markers of compensatory hypertrophy, atrial natriuretic factor
and -skeletal actin mRNA, were upregulated in 3-mo-old female TG
mice (19), but this phenomenon occurred independently of
ventricular hypertrophy. Interestingly, this FHC model displayed gender
differences in which at 3 mo of age both male and female TG mice
developed ventricular hypertrophy. However, by 8 mo of age the hearts
of female TG mice continued to exhibit hypertrophy, whereas the male TG
hearts began to show signs of LV dilation (20).
Quantitative measurements of the internal LV chamber area using
echocardiography demonstrated a significant increase in LV chamber area
in 10-mo-old male TG mice compared with age-matched WT controls
(4).
Another mouse model of FHC introduced the R403Q mutation into one
allele of the -MHC by a "hit-and-run" homologous recombination. The hearts from this FHC mouse model (-MHC403/+) showed
myocyte disarray, fibrosis, diastolic dysfunction, and normal systolic
function. At 4 mo the -MHC403/+ hearts had enlarged
atria but no ventricular hypertrophy (5, 16). However,
subsequent to the original report of no hypertrophy in the
-MHC403/+ model (5, 16), LV hypertrophy was
recently described (3). A myosin binding protein C
(truncation) model has also been shown to exhibit hypertrophy
(24). The -MHC403/+ model had in
vivo LV diastolic dysfunction, whereas the myosin binding protein C
truncation model did not (3). Recently, a TG rabbit model
of FHC with a R403Q mutation in the -MHC was developed. The rabbit
model showed many similarities with human FHC, including LV
hypertrophy, myocellular disarray, and fibrosis; however, to date, no
functional parameters have been investigated in this model
(7).
The present study was designed to investigate whether the functional
characteristics of the -MHC TG mouse hearts resemble human FHC and
to determine the interactive effects of age and gender on LV
contractile performance. We hypothesized that diastolic function would
be impaired in hearts from TG mice independent of gender or age and
that older male mice would show signs of systolic dysfunction as a
result of LV chamber dilation. We found that diastolic function was
indeed impaired in this murine TG model of FHC and that the LV chamber
dilation seen in older male TG mice was associated with systolic dysfunction.
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METHODS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Animals.
The TG mouse model of FHC used in this study expressed a mutant -MHC
with expression driven by a rat -MHC promoter (20). The
transgene coding region contained two mutations, a point mutation R403Q
and a deletion of 59 amino acids in the actin binding site of the
-MHC, bridged by an addition of 9 nonmyosin amino acids. The mutant
MHC protein made up 10-12% of the total myosin in the TG (line
no. 140) mice (20). The heterozygous TG mice and their non-TG wild-type (WT) littermates used in this study were generated by
backcrossing TG mice to C57/B16 mice. PCR-amplified tail DNA and
restriction enzyme digestion was used to genotype each mouse. The
animals were maintained under specific pathogen-free conditions with
food and water ad libidum. All animal protocols were approved by the
institutional animal use and care committee at the University of
Colorado at Boulder.
Isovolumic heart preparation. Isovolumic LV pressure dynamics were recorded from eight different groups of mice: 4-mo-old WT (4WT) males (n = 9) and females (n = 6); 4-mo-old TG (4TG) males (n = 6) and females (n = 8); 10-mo-old WT (10WT) males (n = 6) and females (n = 7); and 10-mo-old TG (10TG) males (n = 8) and females (n = 9). All animals were heparinized (250 units ip) 15 min before administration of an anesthetic dose of pentobarbital sodium (35 mg/kg body wt ip). Under deep anesthesia, hearts were exposed by midline thoracomoty, rapidly excised, and arrested in ice-cold saline solution. Excess tissue was removed, and the aorta fixed to a 21-g stainless steel cannula with 6-O surgical silk suture. Each heart was retrogradely perfused at a constant pressure of 85 mmHg with a Krebs-Henseleit buffer containing (in mM) 117.4 NaCl, 4.7 KCl, 1.2 MgSO4, 2.5 CaCl2, 1.2 KH2PO4, 25.0 NaHCO3, 11.0 glucose, 5.0 pyruvate, and 0.5 EDTA. The buffer was continuously bubbled with 95% O2-5% CO2 at 37°C to yield a pH of 7.4.
A highly compliant custom-made latex balloon was attached to the end of a modified 18-g Teflon catheter and then was connected to pressure tubing that housed a transducer-tipped 3-Fr catheter (Millar Instruments; Houston, TX). The balloon-tubing complex was filled with degassed, distilled water, and an airtight system was achieved. The balloons were made around custom-milled stainless steel molds adjusted to match the dimensions and LV cavity sizes of the hypertrophied and dilated TG hearts. The molds were shaped as asymmetrical prolate ellipsoids, and two different balloon sizes were used in the study. The balloons that fit normal and hypertrophied mouse hearts (all 4-mo-old mice and all female 10-mo-old mice) were formed around a mold 3.1 mm in diameter and 5.8 mm in length, whereas the mold size needed for the balloons to fit the dilated hearts (male 10TG) had a diameter of 3.9 mm and a length of 6.3 mm. The different balloon sizes were used to ensure that our experiments were conducted on the flat portion of the balloon pressure-volume curve. The same balloon size was used within each age and gender grouping, and the same balloon compliance criteria were satisfied in both WT and TG hearts. After retrograde perfusion began, the balloon was inserted into the left ventricle via the mitral valve and secured with a 6-O silk suture. Balloons were inflated to yield 4 different minimum pressures (Pmin) values of 0, 5, 10, and 20 mmHg. The hearts were electrically paced at 300 beats/min (Grass Instruments; Quincy, MA) across the aortic cannula, and a platinum wire was placed in the right ventricle. LV pressure was monitored (Gould Electronics; Cleveland, OH) and recorded (Axon Instruments; Foster City, CA) onto a personal computer during each of the Pmin values. Coronary flow was measured and recorded during each experimental condition. On completion of the experiment, the right and left ventricles were separated, blotted, and weighed. Custom-made software was used to analyze the recorded LV pressure data for Pmin, peak systolic pressure, developed LV pressure (
LVP; peak systolic pressure minus Pmin), time to peak
systolic pressure (TPP), maximum rate of pressure rise
(+dP/dt/LVP), maximum rate of pressure decline
(
dP/dt/LVP), and time to 50 and 90% relaxation. Note
that values for ±dP/dt/LVP functionally represented rate
constants describing pressure increases or decreases.
Statistical analyses.
Data are presented as means ± SE. Statistics were performed with
SPSS 6.1 (SPSS, Chicago, IL), and male and female groups were analyzed
separately. Using ANOVA, comparisons of morphometric data were made
between the two mutation groups and the two age groups. To test for the
effects of mutation, age, and different minimum pressures, repeated
measures ANOVA were performed between the two mutation groups and the
two age groups and across the four groups (Pmin). For all
variables, simple effects were examined to determine significant
differences between the WT and TG subgroups for both 4- and 10-mo-old
mice. To reduce the possibility of committing a type II interpretive
error (a false negative) significance was reported at both the
P 
0.05 and P 0.10 levels (23).
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Heart mass and coronary flow measurements.
Morphological and coronary flow data from the isovolumically perfused
hearts are presented in Table 1. No body
weight differences existed between the WT and TG mice compared with
their own age-matched controls. In the male mice, LV mass tended to be
greater in the TG groups, with 5 and 7% increases in the 4- and
10-mo-groups, respectively (mutation main effect, P = 0.10). In the female mice, LV mass was greater in both 4TG and 10TG
groups relative to their WT counterparts (8 and 28% increases,
respectively). In our study, there was no WT versus TG difference in RV
mass between the male groups, whereas the 10TG females had a
significantly increased RV mass compared with hearts from the 10WT
group (34% increase). When normalizing heart weight (LV and RV weights
combined) to body weight, we found that 4-mo-old male TG mice had an
increased heart weight-to-body weight ratio (simple effect,
P = 0.04) compared with age-matched WT control. At 10 mo of age, however, the heart weight-to-body weight ratio was not
different between the male TG and WT mice (P = 0.15). A
lack of hypertrophy is consistent with previous reports of chamber
dilation in this TG model (4, 20). Among the females, both
4- and 10-mo-old TG mice had larger heart weight-to-body weight ratios
relative to WT mice (mutation main effect, P < 0.001).
In males, relative to WT controls, coronary flow-to-heart weight ratios
were significantly reduced by 16 and 28% in the 4TG and 10TG groups,
respectively. Coronary flow-to-heart weight ratios in female 4TG and
10TG groups were decreased relative to WT controls by 4 and 34%,
respectively (mutation main effect, P = 0.05).
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Isovolumic contractile response to varying minimum pressure.
To assess the effect of the -MHC transgene expression on ventricular
contractile function, various indexes of contraction and relaxation
were measured. LV isovolumic contractile performance was measured over
4 (0, 5, 10, 20 mmHg) different Pmin, chosen to span normal
physiological to heart failure ranges. Figure
1 depicts changes in LVP in response
to changes in Pmin. In hearts from 4-mo-old males (Fig.
1A), LVP was significantly higher in the TG hearts
relative to WT controls. However, by 10 mo of age the TG hearts
developed significantly less LVP compared with age-matched WT hearts
(Fig. 1B; mutation × age interaction,
P = 0.009). Moreover, a differential response by the
male TG hearts to changes in minimum pressure was observed (Fig. 1,
A and B; mutation × Pmin
interaction, P = 0.01). At both 4 mo and 10 mo of age,
the TG hearts had a blunted LVP response to increases in
Pmin compared with WT hearts. In the female hearts (Fig. 1,
C and D), there was no WT versus TG difference in
LVP at either 4 or 10 mo of age. However, similar to the male
hearts, the female 4TG and 10TG hearts also exhibited a blunted LVP
response to increases in Pmin compared with WT hearts
(mutation × Pmin interaction, P = 0.001).
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LVP in the male hearts, normalizing +dP/dt for LVP can reveal more information
about the rate constant of pressure in these hearts. In the male hearts (Fig. 2, A and B),
the constants describing the rates of pressure rise
(+dP/dt/LVP) were greater in the TG groups compared with WT groups, particularly the 4TG group (mutation main effect,
P = 0.05). The maximum rate of pressure development was
faster in female TG hearts compared with WT controls, primarily in the
4-mo-old group (Fig. 2, C and D; mutation main
effect, P < 0.01). Moreover, the effect of age on
+dP/dt/LVP was more pronounced in the female TG group
compared with their WT controls (age main effect, P = 0.07; mutation × age interaction, P = 0.06). At 4 mo, hearts from the female TG mice were hypercontractile; however, by
10 mo of age the rate of LVP development had decreased to normal
levels.
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dP/dt/LVP, was slowed in the male TG
hearts compared with the WT hearts (Fig.
3, A and B;
mutation main effect, P = 0.06). In contrast, in hearts
from female mice, dP/dt/LVP was not affected by the
transgene. Other measures of relaxation are the times to 50 and 90%
relaxation, the latter being more representative of late relaxation.
The male TG hearts took significantly longer times to reach 50 and 90%
relaxation (Fig. 4; mutation main
effects, P = 0.004) at both 4 mo and 10 mo of age.
Similarly, times to 50 and 90% relaxation were prolonged in the female
TG hearts (Fig. 5; mutation main effects,
P = 0.02). Overall, we found that relaxation was not as
severely impaired in the hearts from TG females compared with those
from TG males.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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In the present study, our -MHC TG mouse model of FHC displayed
many age- and gender-dependent morphological and functional differences
in the myocardium (Table 3). These
changes were strikingly similar to those seen in the human disease. To
date, this is the only animal model with a R403Q mutation in the
cardiac MHC that exhibits cardiac hypertrophy along with diastolic
dysfunction and coronary perfusion abnormalities commonly seen in
humans with FHC. Furthermore, our model displays some distinct
phenotypic gender differences, which may have relevance to the
heterogeneous nature of FHC and heart disease in humans (see below).
These results indicate that the -MHC TG mice used in this study may
show promise as a model for investigating the cellular and molecular
defects underlying human FHC.
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Our morphological data were consistent with data from Vikstrom et al. (20), who found that by 3 mo of age, LV mass was increased more in the female TG hearts compared with age-matched TG males and that LV hypertrophy had more than doubled in the females by the time they were 8 mo old. This hypertrophic response was likely representative of a compensatory mechanism that allowed for the preservation of systolic function in TG female mice at all ages. In 10-mo-old TG males, LV mass was similar to that seen in their WT littermates. On the basis of prior morphological and echocardiographic studies, this absence of increase in LV mass in older TG males was likely associated with LV chamber dilation (4, 20). Although we did not directly assess the degree of dilation in the male 10TG hearts, we found that, in preliminary studies, normal-sized balloons used successfully to study hearts from the other groups (including male 10WT hearts) were not large enough to fill the LV cavity in the 10TG hearts to satisfy a flat pressure-volume balloon criterion. To do so, we had to increase the balloon size and volume to fit the dilated hearts (see METHODS). In addition, the diminution in LV systolic function that we observed in 10TG mice is consistent with the idea that LV dilation was present.
Many patients with FHC have small vessel coronary disease (12,
18) and myocardial perfusion abnormalities (13)
that can contribute to myocardial ischemia. Histological
evidence of small vessel coronary disease was found previously in our
TG mouse model (20). We extended those results by finding
that normalized coronary flow was decreased substantially in hearts
from 10-mo-old males (28%) and females (34%). A decrease in coronary
flow may result from one or more of several mechanisms, including a
decreased capillary density (6), small vessel coronary
disease (12, 18), and impaired LV relaxation
(11). Such chronic hypoperfusion, independent of
mechanism, can lead to myocardial ischemia and eventually
result in necrosis, infarction, and LV dysfunction. From a
methodological perspective, it is worth considering the issue of
whether or not the reduction in coronary flow observed in our TG hearts
may have caused an ischemic state that adversely impacted our
assessment of LV contractile function. A reduction in coronary flow
would be expected to expose TG hearts to greater risk of
ischemic injury, particularly in situations where cardiac work
was markedly increased. However, in our preparations we do not believe
this critical point was achieved for two reasons. First, under the
conditions of our experimental protocol, the contractile function of
both TG and WT control hearts were similarly stable over time. Second,
as was recently demonstrated by our lab (4), the TG and WT
preparations used under our baseline conditions were far below their
contractile performance maxima because an isoproterenol challenge
elicited an ~80-100% increase in LVP in both WT and TG preparations.
We used the isovolumic isolated left heart technique to
investigate systolic and diastolic function in hearts from TG mice. A
similar approach was used in another -MHC mutated mouse model of FHC
in which one allele is WT and the other allele is the single amino acid
substitution R403Q. Spindler et al. (16) measured LV
isovolumic contractile performance over a range of perfusate calcium concentrations. In their -MHC403/+ mice
they found diastolic dysfunction but normal systolic function in hearts
from 5- and 6-mo-old males. However, this particular mouse model did
not develop ventricular hypertrophy but instead had atrial
enlargement (5). Moreover, Spindler et al.
(16) found no coronary flow abnormalities in the
-MHC403/+ hearts. Functional studies of the -MHC TG
rabbit model of FHC have been limited to echocardiography
(7). Neither LV end-diastolic dimensions nor LV
end-systolic dimensions were different between the TG and WT rabbits as
measured by echocardiography.
We observed in our model that normal or supranormal systolic function developed into mild systolic dysfunction, and that diastolic function worsened over the same period of time. The dilated hearts in the 10TG male mice had an impaired systolic function, similar to humans with dilated cardiomyopathy (15, 17). Ventricular dilation occurs in ~10% of patients with hypertrophic cardiomyopathy; however, no known studies have investigated the genetic background of these patients (15, 17). In addition, men have a higher incidence of dilated cardiomyopathy compared with women, especially at a younger age (2). In contrast to our 10-mo-old male mice hearts, the female hearts at the same age continued to hypertrophy, had diastolic dysfunction, and had normal systolic function. Human studies of gender differences in the hypertrophied heart found that women often develop a more severe LV hypertrophy in response to hypertrophic stimuli compared with men (1). Studies of men and women with aortic stenosis or long-standing hypertension found that older women developed a more marked concentric hypertrophy, lower levels of wall stress, and normal or supranormal systolic function compared with men with similar disease severity (1).
In summary, the hearts from young TG mice in this study exhibited
cardiac hypertrophy along with LV diastolic dysfunction, but had normal
and supranormal LV systolic function in females and males,
respectively. In female TG hearts, concentric LV hypertrophy progressed
with age and impaired diastolic function persisted in the absence of
systolic dysfunction. In contrast, in male TG mice with advancing age,
mild concentric hypertrophy progressed to ventricular dilation,
diastolic dysfunction worsened, and systolic performance was impaired.
Additionally, at 10 mo of age, coronary flow was diminished in both
male and female TG hearts compared with WT hearts. Thus the -MHC TG
mouse model of FHC used in this study may have great potential for use
in the study of the pathogenesis of human FHC.
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ACKNOWLEDGEMENTS |
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We thank Brittany Brilhart and Nicole Otanicar for technical assistance. Nicole Otanicar conducted portions of this work with the support from the Howard Hughes Undergraduate Research Initiative at the University of Colorado, Boulder, CO.
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FOOTNOTES |
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This work was supported in part by National Heart, Lung, and Blood Institute grants to R. L. Moore (HL-40306) and to L. A. Leinwand (HL-50560) and by the American College of Sports Medicine Foundation Research Grant and Graduate Student Scholarship for Women to M. C. Olsson.
Present address of B. M. Palmer: Dept. of Molecular Physiology and Biophysics, University of Vermont, College of Medicine, Burlington, VT 05405.
Address for reprint requests and other correspondence: R. L. Moore, Dept. of Kinesiology & Applied Physiology, Campus Box 354, Univ. of Colorado, Boulder, CO 80309-0354.
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Received 7 June 2000; accepted in final form 11 October 2000.
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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different from age-matched WT mice at
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