TY - JOUR
T1 - Mutations in MYLPF Cause a Novel Segmental Amyoplasia that Manifests as Distal Arthrogryposis
AU - University of Washington Center for Mendelian Genomics
AU - Chong, Jessica X.
AU - Talbot, Jared C.
AU - Teets, Emily M.
AU - Previs, Samantha
AU - Martin, Brit L.
AU - Shively, Kathryn M.
AU - Marvin, Colby T.
AU - Aylsworth, Arthur S.
AU - Saadeh-Haddad, Reem
AU - Schatz, Ulrich A.
AU - Inzana, Francesca
AU - Ben-Omran, Tawfeg
AU - Almusafri, Fatima
AU - Al-Mulla, Mariam
AU - Buckingham, Kati J.
AU - Harel, Tamar
AU - Mor-Shaked, Hagar
AU - Radhakrishnan, Periyasamy
AU - Girisha, Katta M.
AU - Nayak, Shalini S.
AU - Shukla, Anju
AU - Dieterich, Klaus
AU - Faure, Julien
AU - Rendu, John
AU - Capri, Yline
AU - Latypova, Xenia
AU - Nickerson, Deborah A.
AU - Warshaw, David M.
AU - Janssen, Paul M.L.
AU - Amacher, Sharon L.
AU - Bamshad, Michael J.
N1 - Funding Information:
We thank the families for their participation and support. Sequencing for families A and B was provided by the University of Washington Center for Mendelian Genomics (UW-CMG) and was funded by NHGRI and NHLBI grants UM1 HG006493 and U24 HG008956 , by the Office of the Director, NIH under Award Number S10OD021553 , and by the National Institute of Child Health and Human Development ( 1R01HD048895 to M.J.B.). We thank the Ohio State Rightmire Hall zebrafish staff for excellent animal care and husbandry and Mark Nilan and Mika Gallati for zebrafish care and mutant identification at the University of Maine. We thank Sarah Shepherd for assistance during initial mylpfa oz43 construction. Zebrafish work was funded by NIH grants GM088041 and GM117964 (to S.L.A.), an NIH T32 training grant NS077984 and an Ohio State Pelotonia postdoctoral fellowship (to J.C.T.), Ohio State Edward Mayers and Elizabeth Wagner research scholarships (to E.M.T.), and NIH HL150953 and AR067279 (to D.M.W.). The Ohio State Neuroscience Imaging Core facilities are supported by NIH grants P30-NS045758 , P30-NS104177 , and S10-OD010383 . We acknowledge the DNA Sequencing Shared Resource at The Ohio State University Comprehensive Cancer Center. This work was also supported by the Indian Council of Medical Research, Government of India (No. 5/13/58/2015/NCD-III ). The F310 antibody developed by Frank Stockdale was obtained from the Developmental Studies Hybridoma Bank, created by the NICHD of the NIH and maintained at The University of Iowa, Department of Biology. The authors are grateful to Mrs. Séverine Drouhin and to the Molecular Biology Facility of the Grenoble University Hospital, France for technical assistance. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.
Funding Information:
We thank the families for their participation and support. Sequencing for families A and B was provided by the University of Washington Center for Mendelian Genomics (UW-CMG) and was funded by NHGRI and NHLBI grants UM1 HG006493 and U24 HG008956, by the Office of the Director, NIH under Award Number S10OD021553, and by the National Institute of Child Health and Human Development (1R01HD048895 to M.J.B.). We thank the Ohio State Rightmire Hall zebrafish staff for excellent animal care and husbandry and Mark Nilan and Mika Gallati for zebrafish care and mutant identification at the University of Maine. We thank Sarah Shepherd for assistance during initial mylpfaoz43 construction. Zebrafish work was funded by NIH grants GM088041 and GM117964 (to S.L.A.), an NIH T32 training grant NS077984 and an Ohio State Pelotonia postdoctoral fellowship (to J.C.T.), Ohio State Edward Mayers and Elizabeth Wagner research scholarships (to E.M.T.), and NIH HL150953 and AR067279 (to D.M.W.). The Ohio State Neuroscience Imaging Core facilities are supported by NIH grants P30-NS045758, P30-NS104177, and S10-OD010383. We acknowledge the DNA Sequencing Shared Resource at The Ohio State University Comprehensive Cancer Center. This work was also supported by the Indian Council of Medical Research, Government of India (No.5/13/58/2015/NCD-III). The F310 antibody developed by Frank Stockdale was obtained from the Developmental Studies Hybridoma Bank, created by the NICHD of the NIH and maintained at The University of Iowa, Department of Biology. The authors are grateful to Mrs. S?verine Drouhin and to the Molecular Biology Facility of the Grenoble University Hospital, France for technical assistance. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.
Publisher Copyright:
© 2020 American Society of Human Genetics
PY - 2020/8/6
Y1 - 2020/8/6
N2 - We identified ten persons in six consanguineous families with distal arthrogryposis (DA) who had congenital contractures, scoliosis, and short stature. Exome sequencing revealed that each affected person was homozygous for one of two different rare variants (c.470G>T [p.Cys157Phe] or c.469T>C [p.Cys157Arg]) affecting the same residue of myosin light chain, phosphorylatable, fast skeletal muscle (MYLPF). In a seventh family, a c.487G>A (p.Gly163Ser) variant in MYLPF arose de novo in a father, who transmitted it to his son. In an eighth family comprised of seven individuals with dominantly inherited DA, a c.98C>T (p.Ala33Val) variant segregated in all four persons tested. Variants in MYLPF underlie both dominant and recessively inherited DA. Mylpf protein models suggest that the residues associated with dominant DA interact with myosin whereas the residues altered in families with recessive DA only indirectly impair this interaction. Pathological and histological exam of a foot amputated from an affected child revealed complete absence of skeletal muscle (i.e., segmental amyoplasia). To investigate the mechanism for this finding, we generated an animal model for partial MYLPF impairment by knocking out zebrafish mylpfa. The mylpfa mutant had reduced trunk contractile force and complete pectoral fin paralysis, demonstrating that mylpf impairment most severely affects limb movement. mylpfa mutant muscle weakness was most pronounced in an appendicular muscle and was explained by reduced myosin activity and fiber degeneration. Collectively, our findings demonstrate that partial loss of MYLPF function can lead to congenital contractures, likely as a result of degeneration of skeletal muscle in the distal limb.
AB - We identified ten persons in six consanguineous families with distal arthrogryposis (DA) who had congenital contractures, scoliosis, and short stature. Exome sequencing revealed that each affected person was homozygous for one of two different rare variants (c.470G>T [p.Cys157Phe] or c.469T>C [p.Cys157Arg]) affecting the same residue of myosin light chain, phosphorylatable, fast skeletal muscle (MYLPF). In a seventh family, a c.487G>A (p.Gly163Ser) variant in MYLPF arose de novo in a father, who transmitted it to his son. In an eighth family comprised of seven individuals with dominantly inherited DA, a c.98C>T (p.Ala33Val) variant segregated in all four persons tested. Variants in MYLPF underlie both dominant and recessively inherited DA. Mylpf protein models suggest that the residues associated with dominant DA interact with myosin whereas the residues altered in families with recessive DA only indirectly impair this interaction. Pathological and histological exam of a foot amputated from an affected child revealed complete absence of skeletal muscle (i.e., segmental amyoplasia). To investigate the mechanism for this finding, we generated an animal model for partial MYLPF impairment by knocking out zebrafish mylpfa. The mylpfa mutant had reduced trunk contractile force and complete pectoral fin paralysis, demonstrating that mylpf impairment most severely affects limb movement. mylpfa mutant muscle weakness was most pronounced in an appendicular muscle and was explained by reduced myosin activity and fiber degeneration. Collectively, our findings demonstrate that partial loss of MYLPF function can lead to congenital contractures, likely as a result of degeneration of skeletal muscle in the distal limb.
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U2 - 10.1016/j.ajhg.2020.06.014
DO - 10.1016/j.ajhg.2020.06.014
M3 - Article
C2 - 32707087
AN - SCOPUS:85088965068
SN - 0002-9297
VL - 107
SP - 293
EP - 310
JO - American Journal of Human Genetics
JF - American Journal of Human Genetics
IS - 2
ER -