Dystrophin is coded for by the DMDgene – the largest known human gene, covering 2.4
megabases (0.08% of the human genome) at
locusXp21. The
primary transcript in muscle measures about 2,100
kilobases and takes 16 hours to transcribe;[7] the
mature mRNA measures 14.0 kilobases.[8] The 79-
exon muscle transcript[9] codes for a protein of 3685 amino acid residues.[10]
Spontaneous or inherited mutations in the dystrophin gene can cause different forms of
muscular dystrophy, a disease characterized by progressive muscular wasting. The most common of these disorders caused by genetic defects in dystrophin is
Duchenne muscular dystrophy.
Function
Dystrophin is a protein located between the
sarcolemma and the outermost layer of
myofilaments in the muscle fiber (
myofiber). It is a cohesive protein, linking
actin filaments to other
support proteins that reside on the inside surface of each muscle fiber's plasma membrane (sarcolemma). These support proteins on the inside surface of the sarcolemma in turn links to two other consecutive proteins for a total of three linking proteins. The final linking protein is attached to the fibrous
endomysium of the entire muscle fiber. Dystrophin supports muscle fiber strength, and the absence of dystrophin reduces muscle stiffness, increases sarcolemmal deformability, and compromises the mechanical stability of costameres and their connections to nearby myofibrils. This has been shown in recent studies where biomechanical properties of the sarcolemma and its links through costameres to the contractile apparatus were measured,[11] and helps to prevent muscle fiber injury. Movement of thin filaments (actin) creates a pulling force on the extracellular connective tissue that eventually becomes the tendon of the muscle. The dystrophin associated protein complex also helps scaffold various signalling and channel proteins, implicating the DAPC in regulation of signalling processes.[12]
Pathology
Dystrophin deficiency has been definitively established as one of the root causes of the general class of
myopathies collectively referred to as
muscular dystrophy. The deletions of one or several exons of the dystrophin DMD gene cause Duchenne and Becker muscular dystrophies.[13] The large
cytosolic protein was first identified in 1987 by
Louis M. Kunkel,[14] after concurrent works by Kunkel and Robert G. Worton to characterize the mutated gene that causes Duchenne muscular dystrophy (DMD).[15][16] At least 9 disease-causing mutations in this gene have been discovered.[17]
Normal skeletal muscle tissue contains only small amounts of dystrophin (about 0.002% of total muscle protein),[14] but its absence (or abnormal expression) leads to the development of a severe and currently incurable constellation of symptoms most readily characterized by several aberrant intracellular signaling pathways that ultimately yield pronounced myofiber
necrosis as well as progressive muscle weakness and fatigability. Most DMD patients become wheelchair-dependent early in life, and the gradual development of cardiac hypertrophy—a result of severe myocardial fibrosis—typically results in premature death in the first two or three decades of life. Variants (
mutations) in the DMD gene that lead to the production of too little or a defective, internally shortened but partially functional dystrophin protein, result in a display of a much milder dystrophic phenotype in affected patients, resulting in the disease known as
Becker's muscular dystrophy (BMD). In some cases, the patient's phenotype is such that experts may decide differently on whether a patient should be diagnosed with DMD or BMD. The theory currently most commonly used to predict whether a variant will result in a DMD or BMD phenotype, is the reading frame rule.[18]
Though its role in airway smooth muscle is not well established, recent research indicates that dystrophin along with other subunits of dystrophin glycoprotein complex is associated with phenotype maturation.[19]
Research
A number of
models are used to facilitate research on DMD gene defects. These include the
mdx mouse, GRMD (golden retriever muscular dystrophy) dog, and HFMD (hypertrophic feline muscular dystrophy) cat.[20]
The mdx mouse contains a nonsense mutation in exon 23, leading to a shortened dystrophin protein.[21] Levels of dystrophin in this model is not zero: a variety of mutation alleles exist with measurable levels certain of dystrophin isoforms.[20] Muscle degeneration pathology is most easily visible in the diaphragm.[22] Generally, clinically relevant pathology is observed with older mdx mice.[22]
The GRMD dog is one of several existing dystrophin-deficient dogs identified where substantial characterization has been performed.[23] Clinically relevant pathology can be observed at 8 weeks after birth, with continued gradual deterioration of muscle function.[24] Muscle histology is most analogous to clinical presentation of DMD in humans with necrosis, fibrosis and regeneration.[25]
The HFMD cat has a deletion in the promoter region of the DMD gene.[26] Muscle histology shows necrosis but no fibrosis.[27] Extensive hypertrophy has been observed which is thought to be responsible for shorter lifespans.[28][27] Due to the hypertrophy, this model may have limited uses for DMD studies.
^Aartsma-Rus A, Van Deutekom JC, Fokkema IF, Van Ommen GJ, Den Dunnen JT (August 2006). "Entries in the Leiden Duchenne muscular dystrophy mutation database: an overview of mutation types and paradoxical cases that confirm the reading-frame rule". Muscle & Nerve. 34 (2): 135–44.
doi:
10.1002/mus.20586.
PMID16770791.
S2CID42303520.
^Sharma P, Tran T, Stelmack GL, McNeill K, Gosens R, Mutawe MM, Unruh H, Gerthoffer WT, Halayko AJ (January 2008). "Expression of the dystrophin-glycoprotein complex is a marker for human airway smooth muscle phenotype maturation". American Journal of Physiology. Lung Cellular and Molecular Physiology. 294 (1): L57–68.
doi:
10.1152/ajplung.00378.2007.
PMID17993586.
^Sicinski P, Geng Y, Ryder-Cook AS, Barnard EA, Darlison MG, Barnard PJ (June 1989). "The molecular basis of muscular dystrophy in the mdx mouse: a point mutation". Science. 244 (4912): 1578–80.
Bibcode:
1989Sci...244.1578S.
doi:
10.1126/science.2662404.
PMID2662404.
^
abStedman HH, Sweeney HL, Shrager JB, Maguire HC, Panettieri RA, Petrof B, et al. (August 1991). "The mdx mouse diaphragm reproduces the degenerative changes of Duchenne muscular dystrophy". Nature. 352 (6335): 536–9.
Bibcode:
1991Natur.352..536S.
doi:
10.1038/352536a0.
PMID1865908.
S2CID4302451.
^"Duchenne Muscular Dystrophy and Becker Muscular Dystrophy: Diagnostic Principles". Duchenne Muscular Dystrophy. CRC Press. 2006-02-27. pp. 105–118.
doi:
10.3109/9780849374456-7.
ISBN978-0-429-16351-7.
^Valentine BA, Cooper BJ, de Lahunta A, O'Quinn R, Blue JT (December 1988). "Canine X-linked muscular dystrophy. An animal model of Duchenne muscular dystrophy: clinical studies". Journal of the Neurological Sciences. 88 (1–3): 69–81.
doi:
10.1016/0022-510X(88)90206-7.
PMID3225630.
S2CID6902011.