� 2007 Wiley-Liss, Inc. American Journal of Medical Genetics Part A 143A:2662 – 2667 (2007)

Homozygosity for a Novel Splice Site Mutation in the
Cardiac Myosin-Binding Protein C Gene Causes Severe

Neonatal Hypertrophic Cardiomyopathy

Baozhong Xin,1 Erik Puffenberger,2 John Tumbush,1 J.R. Bockoven,3 and Heng Wang1,4,5*
1
Das Deutsch Center (DDC) Clinic for Special Needs Children, Middlefield, Ohio

2The Clinic for Special Children, Strasburg, Pennsylvania
3The Heart Center, Akron Children’s Hospital, Akron, Ohio

4Department of Pediatrics, Rainbow Babies & Children’s Hospital, Cleveland, Ohio
5
Department of Molecular Cardiology, Cleveland Clinic Foundation, Cleveland, Ohio

Received 29 May 2007; Accepted 1 July 2007

Hypertrophic cardiomyopathy is typically inherited in an
autosomal dominant pattern and has a variable age of onset
and prognosis. Mutations in the myosin-binding protein C
(MYBPC3) gene are one of the most frequent genetic causes
of the disease. Patients with MYBPC3 mutations generally
have a late onset and a relatively good prognosis. We report
here more than 20 Old Order Amish children with severe
neonatal hypertrophic cardiomyopathy caused by a novel
homozygous splice site mutation in the MYBPC3 gene.
The affected children typically presented with signs and
symptoms of congestive heart failure during the first 3 weeks
of life. Echocardiography revealed hypertrophic non-
obstructive cardiomyopathy. These children had a life span
averaging 3–4 months. All patients died from heart failure
before 1 year of age unless they received a heart transplant.
A genome-wide mapping study was performed in three
patients. The disease related gene was localized to a 4.6 Mb

region on chromosome 11p11.2-p11.12. This homozygous
block contained MYBPC3, a previously identified cardiomy-
opathy related gene. We identified a novel homozygous
mutation, c.3330 þ 2T > G, in the splice-donor site of
MYBPC3 intron 30. The mutation resulted in skipping of
the 140-bp exon 30, which led to a frame shift and premature
stop codon in exon 31 (p.Asp1064GlyfsX38). We have found
a substantial incidence of this phenotype in Old Order Amish
communities. It is also concerning that many unidentified
heterozygous individuals who are at risk for development of
hypertrophic cardiomyopathy do not receive proper medical
attention in the communities. � 2007 Wiley-Liss, Inc.

Key words: hypertrophic cardiomyopathy; MYBPC3; Old
Order Amish; Mennonite

How to cite this article: Xin B, Puffenberger E, Tumbush J, Bockoven JR, Wang H. 2007. Homozygosity
for a novel splice site mutation in the cardiac myosin-binding protein C gene causes severe neonatal

hypertrophic cardiomyopathy. Am J Med Genet Part A 143A:2662– 2667.

INTRODUCTION

Hypertrophic cardiomyopathy, clinically defined
as thickening of the myocardial wall in the absence
of other causes for left ventricular hypertrophy,
affects one of every 500 people [Maron et al., 1995;
Zou et al., 2004]. The disease, generally being
inherited in an autosomal dominant pattern, has
a broad spectrum of clinical manifestations from
a benign asymptomatic course to a malignant
course with serious arrhythmias, heart failure, and
sudden cardiac death. Genetic causes of hyper-
trophic cardiomyopathy are also fairly diverse with
more than 400 mutations identified in at least
nine genes encoding sarcomeric proteins [Ho and
Seidman, 2006; Ashrafian and Watkins, 2007].

One of most common genetic causes for hyper-
trophic cardiomyopathy involves mutations in cardiac
myosin-binding protein C (MYBPC3) gene [Charron
et al., 1998; Niimura et al., 1998, 2002; Erdmann et al.,
2001, 2003; Konno et al., 2003; Richard et al., 2003;
Van Driest et al., 2004]. There are approximately

This article contains supplementary material, which may be viewed
at the American Journal of Medical Genetics website at http://
www.interscience.wiley.com/jpages/1552-4825/suppmat/index.html.

*Correspondence to: Heng Wang, M.D., Ph.D., DDC Clinic for Special
Needs Children, PO Box 845, 15809 Madison Road, Middlefield, OH
44062. E-mail: wang@ddcclinic.org

DOI 10.1002/ajmg.a.31981



150 mutations identified so far as listed in the
website (http://www.cardiogenomics.org) devel-
oped by Genomics of Cardiovascular Development
[2007], Adaptation, and Remodeling program since
the first disease-causing mutations were found in
1995 [Bonne et al., 1995; Watkins et al., 1995]. Cardiac
myosin-binding protein C is a sarcomeric protein
belonging to the intracellular immunoglobulin super-
family [Einheber and Fischman, 1990]. By binding to
the myosin heavy chain and cytoskeleton protein
titin, Cardiac myosin-binding protein C contributes to
the structural integrity of the sarcomere. The protein
may also play a role in regulating cardiac contractility
[Flashman et al., 2004]. In general, patients with
hypertrophic cardiomyopathy caused by MYBPC3
gene mutations seem to have a more favorable clinical
profile, characterized by a late onset and a relatively
good prognosis [Niimura et al., 1998]. The clinical
expression of the mutations in the MYBPC3 is
often delayed until middle age or old age. Homo-
zygous mutation in the MYBPC3 gene causing severe
hypertrophic cardiomyopathy has not been reported
to our knowledge, although two cases of severe
hypertrophic cardiomyopathy caused by compound
heterozygous mutations have been found recently
[Lekanne Deprez et al., 2006].

Here we describe a cohort of patients with
severe hypertrophic cardiomyopathy presenting in
the neonatal period, caused by homozygosity for a
novel mutation in the MYBPC3 gene.

MATERIALS AND METHODS

Subjects

The study was approved by DDC Clinic for Special
Needs Children (DDC Clinic) Institutional Review
Board. All 23 affected infants were Old Order Amish,
with 20 of them from the Geauga County settlement
in Ohio, one from the Holmes County settlement
in Ohio, and two from a settlement in New York.
The patients were clinically evaluated by at least
one clinician in the list of authors and the diagnosis
of hypertrophic cardiomyopathy was established
based on family history, physical examination, and
the characteristic clinical course of the disease.
Confirmation was made by both electrocardiogram
and two-dimensional echocardiography reviewed
by pediatric cardiologists. DNA samples from three
patients, their parents and siblings were acquired
with informed consent. All three patients died
before the study was completed. One of them
expired before the study started, thus the DNA
sample preserved by another research laboratory
was transferred to us per parent’s request.

Genotyping and Mutation Detection

The DNA isolation, genotyping, linkage analysis
and mutation detection were performed as described

previously [Puffenberger et al., 2004; Strauss et al.,
2005, 2006]. Polymerase chain reaction (PCR)
primers were designed to amplify each of the
34 protein-coding exons and their flanking intronic
sequences of MYBPC3. Primer sequences are pro-
vided in Table 1 of online supplementary material,
which is published as supporting information on the
AJMG web site (see the online Table 1 at http://www.
interscience.wiley.com/jpages/1552-4825/suppmat/
index.html).

RNA Isolation and cDNA Amplification

Total RNA was isolated from whole blood using
QIAamp RNA blood kit (QIAGEN, Valencia, CA)
according to the manufacturer’s protocol. The cDNA
was synthesized and amplified using primers F3113
and R3479 located in exons 29 and 31. The primers
were determined according to the mRNA sequence
NM_000256.

RESULTS

Clinical Phenotype

The children affected with hypertrophic cardio-
myopathy were typically born after an uneventful
pregnancy and delivery. They were usually full term
with birth weight, length and occipitofrontal circum-
ference all within normal ranges. There were no
significant dysmorphic features noticed in any of
those newborns at birth and afterwards. All patients
passed the routine State Newborn Screening. A
routine chromosomal analysis was performed on at
least one newborn, which was reported as normal.

Approximately one third of the affected infants in
this cohort presented with respiratory distress, an
audible heart murmur or gallop rhythm soon after
birth, which led to further evaluation before or soon
after discharge from the hospital. The remaining
two thirds of infants presented to the primary care
physicians’ office during the first 1–3 weeks of life
with poor feeding, excessive sweating during feed-
ing, lethargy, difficulty with breathing, irritability
and intermittent perioral cyanosis. Abnormal find-
ings from the initial physical examinations often
included excessive sweating, poor perfusion with
prolonged capillary refill time, tachypnea, sinus
tachycardia, gallop rhythm and enlarged liver. Chest
X rays showed cardiomegaly. Echocardiography
revealed hypertrophic non-obstructive cardio-
myopathy in the right or left ventricle or in both
ventricles with ventricular dysfunction. Mild to
moderate ventricular dilation was observed in some
patients. Except for small ventricular defects discov-
ered in several patients, a normal segmental anatomy
without other significant structural heart defects was
found in all the patients.

The heart failure initially found in all our
patients was progressive despite treatment with

MYBPC3 HOMOZYGOSITY CAUSES SEVERE CARDIOMYOPATHY 2663

American Journal of Medical Genetics Part A: DOI 10.1002/ajmg.a



beta-blockers, diuretics and inotropes. All patients
died from heart failure before 1 year of age unless
they received a heart transplant. The life span of the
affected children ranged from seven to 319 days
(average 120 days with a median of 89 days for
20 infants with such information available to us).
Two patients who successfully received heart trans-
plants remained fairly healthy except for some minor
transplant related issues.

Genotyping and Mapping

We carried out a genome-wide mapping analysis
using the Affymetrix GeneChip Mapping 10K SNP
Arrays to identify the disease locus with three
affected children from different families (Fig. 1).
A large, shared block of homozygous SNPs was
identified on chromosome 11p11.2-p11.12 in the
three affected individuals (see the online Fig. S1
at http://www.interscience.wiley.com/jpages/1552-
4825/suppmat/index.html). The homozygous seg-
ment contains 12 contiguous SNPs and spans 4.6 Mb.
Examination of the minimal shared region which was
flanked by SNPs rs1401417 and rs1916207 in the
affected individuals, revealed 96 known or predicted
genes based on both the NCBI and Celera annota-
tions, 37 of which are characterized. Among these
genes, a known hypertrophic cardiomyopathy-
related gene, MYBPC3, was selected for mutation
analysis.

Mutation Analysis

Genomic DNA sequence analysis of the MYBPC3
gene in one affected patient revealed a novel
homozygous mutation in the consensus splice
donor site of intron 30, c.3330 þ 2T > G (Fig. 2).
Further sequencing analysis revealed that all three
patients from the pedigrees (Fig. 1) were homozy-
gous for the mutation, their parents were hetero-
zygous, and no unaffected siblings (n ¼ 8) were
homozygous for the change (Fig. 2).

RNA Analysis

To further investigate the consequence of this
mutation at the transcript level, lymphocyte RNA
from two heterozygous carriers was amplified by RT-
PCR. Amplification of MYBPC3 cDNA with primers
F3113 and R3479 yielded two products: the expected
367-bp fragment and an abnormal shorter product
(Fig. 3). Direct sequencing of the PCR products
after gel extraction revealed skipping of the 140-bp
exon 30 in the shorter fragment which led to a
frame shift and premature stop codon in exon
31 (p.Asp1064GlyfsX38). As a control, amplification
of lymphocyte RNA from two homozygous normal
individuals only gave rise to the expected 367-bp
product (Fig. 3).

DISCUSSION

In this study, we performed whole-genome
linkage analysis and mutational analysis in three
patients who suffered from severe unexplained
hypertrophic cardiomyopathy from three consan-
guineous families. We mapped the disease locus to a
4.6 Mb region on chromosome 11p11.2-p11.12. We
further identified a novel homozygous mutation,
c.3330 þ 2T > G, in a putative splice-donor site of the
MYBPC3 gene within this region that is associated
with this severe condition.

The c.3330 þ 2T > G mutation in the MYBPC3
gene has not been reported previously or been
listed on the public database (http://www.
cardiogenomics.org). Due to the unavailability of
RNA or protein samples from cardiac tissue of the
affected individuals at the current time, the con-
sequence of the mutation was determined using
lymphocyte RNA from heterozygous carriers of the
c.3330 þ 2T > G mutation. It was demonstrated that
the mutated allele produces an aberrant transcript
with skipping of the associated exon 30. Skipping of
the 140-bp exon 30 led to a frame shift. The aberrant
mRNA was predicted to encode a truncated protein

FIG. 1. Pedigrees of the three families used in the mapping study and mutational analysis of hypertrophic cardiomyopathy. The probands are indicated with an arrow
in each family.

2664 XIN ET AL.

American Journal of Medical Genetics Part A: DOI 10.1002/ajmg.a



(p.Asp1064GlyfsX38). As a consequence, 211 amino
acids of the conserved COOH terminus are deleted.
We expect the same consequences of the splice
donor site mutation in the myocardium.

Cardiac myosin-binding protein C is composed of
11 domains referred to as C0–C10 [Carrier et al.,
1997]. Previous functional studies have demon-
strated that the major myosin binding domain is
located within the C10 consisting of the last 102
amino acids [Okagaki et al., 1993; Alyonycheva et al.,
1997]. The c.3330 þ 2T > G mutation is predicted to
produce a truncated protein with complete missing
of C10 domain, which is required for the incorpo-
ration of cardiac myosin-binding protein C into the A
band, titin interaction and myosin binding [Freiburg
and Gautel, 1996; Gilbert et al., 1996]. It is speculated
that homozygosity of the mutation reported in the
present study acts as null alleles and leads to
complete loss of function of cardiac myosin-binding
protein C, which may explain the severity of the
disease phenotype in these patients. Indeed, all
individuals affected with the disease present with
signs and symptoms of heart failure during the
neonatal period with an average life span of 3–
4 months, and all patients die before 1 year of age
unless they receive a heart transplant. A recent

report has described two lethal cases of neonatal
hypertrophic cardiomyopathy caused by compound
heterozygoity for MYBPC3 mutations [Lekanne
Deprez et al., 2006]. However, this is the first time,
to our knowledge, that a homozygous mutation in
the MYBPC3 gene is reported causing a severe type
of hypertrophic cardiomyopathy.

It is noted that majority of children (20) affected by
this severe neonate hypertrophic cardiomyopathy
in this study are from the Geauga settlement of
Ohio and all of them were born during the last
16 years. Based on the number of Amish births in this
settlement during this interval, we estimate that
a birth incidence of the disease is approximately
1 in 350. By using the Hardy-Weinberg equilibrium
and the incidence estimate, the heterozygous
carrier frequency is calculated as approximately
10%. However, we are somewhat surprised with
the prevalence of this severe type of hypertrophic
cardiomyopathy beyond this settlement. During the
study, we have been contacted by affected Amish
families or health professionals from Delaware,
Illinois, Indiana, Kentucky, Mississippi, New York,
North Carolina and Pennsylvania with many similar
cases as we reported here. The genotype of these
affected children remains to be determined, but may
be reasonably speculated as the same as reported
here. In fact, we have been contacted by two
Mennonite families from different states, and each
of them has one deceased child with hypertrophic
cardiomyopathy. Not unexpectedly, DNA analysis in
one of the Mennonite couples with an affected infant
has revealed that both parents carry the same single
c.3330 þ 2T > G mutation in the MYBPC3 gene.
Thus, we speculate that this infant suffered from
the same type of hypertrophic cardiomyopathy as
well, thus the disease also affects the Mennonite
Community. It has been illustrated that Old Order
Amish and Old Order Mennonite populations
have unique genetic heritages despite a common
religious and geographic history [Puffenberger,
2003]. The hypertrophic cardiomyopathy presented
in this study might be one of a few diseases where

FIG. 2. Identification of c.3330 þ 2T > G mutation in the MYBPC3 gene. Partial sequence of the boundary region of exon and intron 30 is shown and the three
genotypes with respect to c.3330 þ 2T > G mutation are presented (arrows). [Color figure can be viewed in the online issue, which is available at
www.interscience.wiley.com.]

FIG. 3. Detection of the aberrant transcript as a consequence of
c.3330 þ 2T > G mutation. The MYBPC3 cDNA was amplified by RT-PCR from
lymphocyte RNA from homozygous normal individuals (N) and heterozygous
carriers (C) using primers F3113 and R3479 located in exons 29 and 31.
Samples from heterozygous carriers contain the normal 367-bp product and
also a 227-bp product resulting from skipping of the 140-bp exon 30. M, DNA
molecular marker.

MYBPC3 HOMOZYGOSITY CAUSES SEVERE CARDIOMYOPATHY 2665

American Journal of Medical Genetics Part A: DOI 10.1002/ajmg.a



identical mutations segregate in both populations,
as is the case for Crigler-Najjar syndrome and
propionic acidemia in the Amish and Mennonites
of Lancaster County, PA. Higher prevalence and
larger geographic distribution of severe hyper-
trophic cardiomyopathy might imply more distant
common ancestors.

In the past, many genetic disorders identified in
the Old Order Amish and Mennonite communities
have been autosomal recessive diseases related
to the founder effect [McKusick, 1978; Morton
et al., 2003; Puffenberger, 2003], and the parents
of probands generally do not have any signs or
symptoms of the disease. Here, we are apparently
dealing with disorder with a disease inherited in
an autosomal dominant pattern with very severe
phenotype in the homozygotes. Although incom-
plete penetrance often occurs in this autosomal
dominant disorder, it remains concerning that many
unidentified heterozygotes in the community are
carrying a single c.3330 þ 2T > G mutation and
therefore might have, or have the potential to
develop hypertrophic cardiomyopathy. Indeed, we
have noticed many reports of cardiac symptoms,
such as chest pain, fatigue and palpitation from
probands’ parents or relatives during the study.
These individuals, presumably being heterozygotes
of c.3330 þ 2T > G mutation, have been one of our
major concerns throughout the study. Notably, a
previously reported mutation c.3330 þ 5G > C, very
similar to the mutation c.3330 þ 2T > G found in this
study, has been documented as a cause of hyper-
trophic cardiomyopathy in those heterozygous
carriers [Watkins et al., 1995]. The consequence
of being a heterozygous carrier of c.3330 þ 2T > G
mutation during a lifetime is still to be determined,
but we expect that certain individuals, particularly
those middle age and older, might be affected to
some degree. At least three direct family members
of the affected infants have died from sudden
cardiac death at middle age to our knowledge. It is
disconcerting that many individuals with alarming
symptoms do not receive proper medical attention in
this Amish community. While we are working on
further understanding the pathology of both homo-
zygosity and heterzygosity of this particular muta-
tion, we believe that it is equally important to work
with these individuals who are heterozygous carrier
of c.3330 þ 2T > G mutation to better define the
clinical course of the disease. There is an urgent need
to develop a practical strategy to deliver medical
services to these individuals who often do not have
health insurance.

ACKNOWLEDGMENTS

We thank the Amish and Mennonite families in this
report for their support. This study would not have
been possible without the invaluable assistance of

family members. We are indebted to many pediatric
cardiologists who provided outstanding and com-
passionate care to the children affected by the
disease, particularly Dr. Chandrakant R. Patel
of Akron Children’s Hospital, Dr. Kenneth Zahka
of Rainbow Babies & Children’s Hospital, and Dr.
Gerard J. Boyle of Children’s Hospital of Cleveland
Clinic among others. We are grateful for the help of
Dr. Andrew Crosby’s laboratory at St. George’s
Hospital Medical School, London in the isolation
of three DNA samples. We appreciate Mr. Joe Weaver
for his genealogy consultation and Dr. Lawrence
Greksa of Case Western Reserve University for
his demographic consultation. The study was sup-
ported in part by The Elisabeth Severance Prentiss
Foundation.

REFERENCES

Alyonycheva TN, Mikawa T, Reinach FC, Fischman DA. 1997.
Isoform-specific interaction of the myosin-binding proteins
(MyBPs) with skeletal and cardiac myosin is a property of the
C-terminal immunoglobulin domain. J Biol Chem 272:20866–
20872.

Ashrafian H, Watkins H. 2007. Reviews of translational medicine
and genomics in cardiovascular disease: New disease
taxonomy and therapeutic implications cardiomyopathies:
Therapeutics based on molecular phenotype. J Am Coll
Cardiol 49:1251–1264.

Bonne G, Carrier L, Bercovici J, Cruaud C, Richard P, Hainque B,
Gautel M, Labeit S, James M, Beckmann J, Weissenbach J,
Vosberg HP, Fiszman M, Komajda M, Schwartz K. 1995.
Cardiac myosin binding protein-C gene splice acceptor site
mutation is associated with familial hypertrophic cardiomy-
opathy. Nat Genet 11:438–440.

Carrier L, Bonne G, Bahrend E, Yu B, Richard P, Niel F, Hainque
B, Cruaud C, Gary F, Labeit S, Bouhour JB, Dubourg O,
Desnos M, Hagege AA, Trent RJ, Komajda M, Fiszman M,
Schwartz K. 1997. Organization and sequence of human
cardiac myosin binding protein C gene (MYBPC3) and
identification of mutations predicted to produce truncated
proteins in familial hypertrophic cardiomyopathy. Circ Res
80:427–434.

Charron P, Dubourg O, Desnos M, Bennaceur M, Carrier L,
Camproux AC, Isnard R, Hagege A, Langlard JM, Bonne G,
Richard P, Hainque B, Bouhour JB, Schwartz K, Komajda M.
1998. Clinical features and prognostic implications of familial
hypertrophic cardiomyopathy related to the cardiac myosin-
binding protein C gene. Circulation 97:2230–2236.

Einheber S, Fischman DA. 1990. Isolation and characterization of
a cDNA clone encoding avian skeletal muscle C-protein: An
intracellular member of the immunoglobulin superfamily.
Proc Natl Acad Sci USA 87:2157–2161.

Erdmann J, Raible J, Maki-Abadi J, Hummel M, Hammann J,
Wollnik B, Frantz E, Fleck E, Hetzer R, Regitz-Zagrosek V.
2001. Spectrum of clinical phenotypes and gene variants in
cardiac myosin-binding protein C mutation carriers with
hypertrophic cardiomyopathy. J Am Coll Cardiol 38:322–
330.

Erdmann J, Daehmlow S, Wischke S, Senyuva M, Werner U,
Raible J, Tanis N, Dyachenko S, Hummel M, Hetzer R, Regitz-
Zagrosek V. 2003. Mutation spectrum in a large cohort of
unrelated consecutive patients with hypertrophic cardiomy-
opathy. Clin Genet 64:339–349.

Flashman E, Redwood C, Moolman-Smook J, Watkins H. 2004.
Cardiac myosin binding protein C: Its role in physiology and
disease. Circ Res 94:1279–1289.

2666 XIN ET AL.

American Journal of Medical Genetics Part A: DOI 10.1002/ajmg.a



Freiburg A, Gautel M. 1996. A molecular map of the interactions
between titin and myosin-binding protein C. Implications for
sarcomeric assembly in familial hypertrophic cardiomyop-
athy. Eur J Biochem 235:317–323.

Genomics of Cardiovascular Development. 2007. Adaptation,
and Remodeling. NHLBI Program for Genomic Applications.
Harvard Medical School. http://www.cardiogenomics.org.

Gilbert R, Kelly MG, Mikawa T, Fischman DA. 1996. The carboxyl
terminus of myosin binding protein C (MyBP-C, C-protein)
specifies incorporation into the A-band of striated muscle.
J Cell Sci 109:101–111.

Ho CY, Seidman CE. 2006. A contemporary approach to
hypertrophic cardiomyopathy. Circulation 113:e858–e862.

Konno T, Shimizu M, Ino H, Matsuyama T, Yamaguchi M, Terai H,
Hayashi K, Mabuchi T, Kiyama M, Sakata K, Hayashi T, Inoue
M, Kaneda T, Mabuchi H. 2003. A novel missense mutation in
the myosin binding protein-C gene is responsible for hyper-
trophic cardiomyopathy with left ventricular dysfunction and
dilation in elderly patients. J Am Coll Cardiol 41:781–786.

Lekanne Deprez RH, Muurling-Vlietman JJ, Hruda J, Baars MJ,
Wijnaendts LC, Stolte-Dijkstra I, Alders M, van Hagen JM. 2006.
Two cases of severe neonatal hypertrophic cardiomyopathy
caused by compound heterozygous mutations in the MYBPC3
gene. J Med Genet 43:829–832.

Maron BJ, Gardin JM, Flack JM, Gidding SS, Kurosaki TT, Bild DE.
1995. Prevalence of hypertrophic cardiomyopathy in a
general population of young adults. Echocardiographic
analysis of 4111 subjects in the CARDIA Study. Circulation
92:785–789.

McKusick VA, editor. 1978. Medical genetics studies of the Amish:
Selected papers. Baltimore, MD: Johns Hopkins University
Press.

Morton DH, Morton CS, Strauss KA, Robinson DL, Puffenberger
EG, Hendrickson C, Kelley RI. 2003. Pediatric medicine and
the genetic disorders of the Amish and Mennonite people of
Pennsylvania. Am J Med Genet Part C Semin Med Genet
121C:5–17.

Niimura H, Bachinski LL, Sangwatanaroj S, Watkins H, Chudley
AE, McKenna W, Kristinsson A, Roberts R, Sole M, Maron BJ,
Seidman JG, Seidman CE. 1998. Mutations in the gene for
cardiac myosin-binding protein C and late-onset familial
hypertrophic cardiomyopathy. N Engl J Med 338:1248–1257.

Niimura H, Patton KK, McKenna WJ, Soults J, Maron BJ, Seidman
JG, Seidman CE. 2002. Sarcomere protein gene mutations in
hypertrophic cardiomyopathy of the elderly. Circulation
105:446–451.

Okagaki T, Weber FE, Fischman DA, Vaughan KT, Mikawa T,
Reinach FC. 1993. The major myosin-binding domain of
skeletal muscle MyBP-C (C protein) resides in the COOH-
terminal, immunoglobulin C2 motif. J Cell Biol 123:619–
626.

Puffenberger EG. 2003. Genetic heritage of the Old Order
Mennonites of southeastern Pennsylvania. Am J Med Genet
Part C Semin Med Genet 121C:18–31.

Puffenberger EG, Hu-Lince D, Parod JM, Craig DW, Dobrin SE,
Conway AR, Donarum EA, Strauss KA, Dunckley T, Cardenas
JF, Melmed KR, Wright CA, Liang W, Stafford P, Flynn CR,
Morton DH, Stephan DA. 2004. Mapping of sudden infant
death with dysgenesis of the testes syndrome (SIDDT) by a
SNP genome scan and identification of TSPYL loss of function.
Proc Natl Acad Sci USA 101:11689–11694.

Richard P, Charron P, Carrier L, Ledeuil C, Cheav T, Pichereau C,
Benaiche A, Isnard R, Dubourg O, Burban M, Gueffet JP,
Millaire A, Desnos M, Schwartz K, Hainque B, Komajda
M. 2003. Hypertrophic cardiomyopathy: Distribution of
disease genes, spectrum of mutations, and implications
for a molecular diagnosis strategy. Circulation 107:2227–
2232.

Strauss KA, Puffenberger EG, Craig DW, Panganiban CB, Lee AM,
Hu-Lince D, Stephan DA, Morton DH. 2005. Genome-wide
SNP arrays as a diagnostic tool: Clinical description, genetic
mapping, and molecular characterization of Salla disease in an
Old Order Mennonite population. Am J Med Genet Part A
138A:262–267.

Strauss KA, Puffenberger EG, Huentelman MJ, Gottlieb S, Dobrin
SE, Parod JM, Stephan DA, Morton DH. 2006. Recessive
symptomatic focal epilepsy and mutant contactin-associated
protein-like 2. N Engl J Med 35:1370–1377.

Van Driest SL, Vasile VC, Ommen SR, Will ML, Tajik AJ, Gersh BJ,
Ackerman MJ. 2004. Myosin binding protein C mutations and
compound heterozygosity in hypertrophic cardiomyopathy.
J Am Coll Cardiol 44:1903–1910.

Watkins H, Conner D, Thierfelder L, Jarcho JA, MacRae C,
McKenna WJ, Maron BJ, Seidman JG, Seidman CE. 1995.
Mutations in the cardiac myosin binding protein-C gene on
chromosome 11 cause familial hypertrophic cardiomyopathy.
Nat Genet 11:434–437.

Zou Y, Song L, Wang Z, Ma A, Liu T, Gu H, Lu S, Wu P, Zhang Y,
Shen L, Cai Y, Zhen Y, Liu Y, Hui R. 2004. Prevalence of
idiopathic hypertrophic cardiomyopathy in China: A popula-
tion-based echocardiographic analysis of 8080 adults. Am
J Med 116:14–18.

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