MYH8 (Myosin Heavy Chain 8)
<div class="infobox infobox-gene">
| Property | Value |
|----------|-------|
| Gene Symbol | MYH8 |
| Full Name | Myosin Heavy Chain 8 |
| Chromosomal Location | 17p13.1 |
| NCBI Gene ID | 4626 |
| OMIM ID | 160741 |
| Ensembl ID | ENSG00000133116 |
| UniProt ID | Q7Z4W2 |
| Encoded Protein | Myosin-8 (Perinatal Myosin Heavy Chain) |
| Protein Family | Myosin heavy chain family |
| Protein Length | 1,930 amino acids |
| Molecular Weight | ~224 kDa |
| Associated Diseases | Congenital Myopathies, Myosin Storage Myopathy |
</div>
Overview
MYH8 encodes Myosin-8, also known as the perinatal myosin heavy chain (MyHC-PN). This protein is a member of the myosin heavy chain family, a group of motor proteins that generate contractile force in muscle cells through ATP-dependent interaction with actin filaments.
MYH8 is one of several myosin heavy chain isoforms expressed in human skeletal muscle. Unlike the adult-type myosins (MYH1, MYH2, MYH4, MYH7), MYH8 is expressed predominantly during the perinatal period and in regenerating muscle fibers. It serves as a marker for:
- Developing muscle fibers
- Activated satellite cells
- Regenerating muscle tissue
The expression pattern of MYH8 makes it clinically useful as a biomarker for muscle regeneration and as a diagnostic marker for certain congenital myopathies.
Gene Structure and Evolution
The MYH8 gene is located on chromosome 17p13.1 within the MYH gene cluster, which includes several other myosin heavy chain genes. The gene spans approximately 23 kilobases and consists of 38 exons that encode a 1,930-amino acid protein with a molecular weight of approximately 224 kDa.
MYH8 is evolutionarily conserved across vertebrates:
- Mus musculus (mouse) — 94% amino acid identity
- Rattus norvegicus (rat) — 93% identity
- Bos taurus (cow) — 96% identity
- Gallus gallus (chicken) — 89% identity
The conservation of MYH8 reflects its essential role in muscle development.
Protein Structure and Function
Myosin Heavy Chain Structure
Myosin-8 is a large protein with characteristic myosin heavy chain architecture:
N-terminal motor domain (~850 aa): Contains the ATP-binding site and actin-binding interface
Neck region (~100 aa): Lever arm that amplifies small movements
Rod domain (~950 aa): Coiled-coil region responsible for assembly into thick filaments
C-terminal tail: Variable region involved in thick filament assemblyMotor Function
As a motor protein, MYH8 mediates muscle contraction through:
ATP hydrolysis: The motor domain hydrolyzes ATP to generate force
Actin binding: Cyclical binding to actin filaments
Power stroke: Conformation change that produces movement
Force generation: Coordinated action of multiple myosin moleculesThe kinetic properties of MYH8 differ from adult MyHC isoforms, reflecting its role in developing muscle.
Expression and Regulation
Developmental Expression
MYH8 shows a characteristic developmental expression pattern[@tajsharghi2008]:
| Developmental Stage | Expression Level |
|--------------------|-----------------|
| Fetal (first trimester) | High |
| Late gestation (perinatal) | Highest |
| Early postnatal | Declining |
| Adult | Very low/none |
| Muscle regeneration | Reactivated |
This perinatal expression pattern gives MYH8 its alternative name (perinatal MyHC).
Satellite Cell Activation
MYH8 is re-expressed during muscle regeneration, specifically in activated satellite cells[@stout2007]:
Satellite cell activation: Upon muscle injury, quiescent satellite cells become activated
Myoblast proliferation: Activated satellite cells proliferate as myoblasts
MYH8 expression: MYH8 is expressed in proliferating myoblasts
Differentiation: Myoblasts differentiate and fuse to form new muscle fibersMYH8 expression in satellite cells makes it a useful marker for:
- Activated satellite cells
- Muscle regeneration
- Satellite cell-derived myoblasts
Regulatory Mechanisms
MYH8 expression is regulated by:
- Transcription factors: MyoD, Myogenin, MRF4
- Signaling pathways: MAPK, PI3K/Akt
- Hormonal factors: Thyroid hormone (toggles between perinatal and adult isoforms)
- Activity-dependent signals: Muscle use and loading
Role in Muscle Development and Regeneration
Fetal Muscle Development
During fetal development, MYH8 is one of the first MyHC isoforms expressed:
- Emerges around 10-12 weeks gestation in humans
- Becomes the dominant isoform in late gestation
- Required for proper myofibril assembly in developing muscle
Perinatal Transition
The perinatal period involves a major MyHC isoform switch:
- MYH8 expression declines after birth
- Adult isoforms (MYH1, MYH2, MYH4, MYH7) take over
- Thyroid hormone accelerates this transition
- Failure of this switch can cause myopathic conditions
Muscle Regeneration
In adult muscle, MYH8 re-expression indicates regeneration:
Injury response: Muscle damage triggers satellite cell activation
Myoblast proliferation: MYH8 expressed in proliferating myoblasts
New fiber formation: Myoblasts fuse to form new fibers expressing MYH8
Maturation: New fibers transition to adult MyHC isoformsThis regenerative capacity declines with age, contributing to reduced muscle repair in older individuals.
Disease Associations
Congenital Myopathies
MYH8 mutations cause a distinct form of congenital myopathy[@kjellgren2019]:
| Feature | Description |
|---------|-------------|
| Onset | Infancy or early childhood |
| Muscle weakness | Generalized, axial > appendicular |
| Contractures | Arthrogryposis, especially at birth |
| Feeding difficulties | Common in infancy |
| Respiratory involvement | Variable, can be severe |
| Cardiac involvement | Usually not prominent |
| Disease course | Static or slowly progressive |
The phenotype overlaps with other congenital myopathies, necessitating genetic testing for diagnosis.
Myosin Storage Myopathies
MYH8 can also be involved in myosin storage myopathies:
- Accumulation of MYH8-positive inclusions in muscle fibers
- Often associated with MYH7 mutations as well
- Variable clinical presentation
Other Conditions
- Congenital contractures: MYH8 mutations can cause contractures as primary feature
- Arthrogryposis multiplex congenita: Some cases involve MYH8
- Respiratory insufficiency: Due to diaphragm and intercostal muscle involvement
Diagnostic Utility
Biomarker Applications
MYH8 serves as a diagnostic marker:
Muscle biopsy: Immunostaining for MYH8 indicates regenerating fibers
Satellite cell evaluation: Marker for activated satellite cells
Congenital myopathy diagnosis: MYH8 mutations confirm diagnosisHistopathological Features
In muscle biopsies:
- Perinatal MyHC immunoreactivity: Indicates regenerating fibers
- Central nuclei: Common in regenerating fibers
- Fiber size variation: Typical of chronic myopathic process
- Satellite cell density: Increased in regeneration
Therapeutic Approaches
Current Strategies
No disease-modifying therapies exist for MYH8-related myopathies. Current management includes:
| Approach | Application |
|----------|-------------|
| Physical therapy | Maintain mobility, prevent contractures |
| Orthopedic interventions | Contracture management |
| Respiratory support | For respiratory muscle weakness |
| Nutritional support | Feeding difficulties in infants |
Research Directions
Emerging therapies under investigation:
Gene therapy: Viral vector-mediated MYH8 expression
Small molecules: Modulators of muscle development pathways
Cell therapy: Satellite cell transplantation
ASO therapy: Antisense oligonucleotides to modify splicingSee Also
- [Myosin Heavy Chain Family](/proteins/myosin-heavy-chain-family) — Myosin overview
- [Congenital Myopathies](/diseases/congenital-myopathies) — Disease context
- [Satellite Cells](/cell-types/satellite-cells) — Muscle stem cells
- [Muscle Regeneration](/mechanisms/muscle-regeneration) — Regeneration mechanisms
- [Skeletal Muscle Development](/mechanisms/muscle-development) — Developmental pathways
- [Neuromuscular Disorders](/diseases/neuromuscular-disorders) — Disease category
Detailed Molecular Mechanisms
Motor Domain Function
The N-terminal motor domain of MYH8 contains the critical elements for contractile function [1](https://pubmed.ncbi.nlm.nih.gov/18484348/):
ATP-binding pocket: Bind hydrolyzes ATP to provide energy for the power stroke
Actin-binding region: Interfaces with actin filaments during the contractile cycle
Converter domain: Transforms conformational changes into force
Lever arm: Amplifies small movements into the power strokeThe kinetic parameters of MYH8 differ from adult isoforms:
- Higher ATPase activity during development
- Different actin-binding kinetics
- Adapted for rapid developmental contractions
Thick Filament Assembly
The C-terminal rod domain of MYH8 mediates thick filament formation:
Coiled-coil formation: The rod forms a classic alpha-helical coiled-coil
Assembly signals: Specific regions direct proper assembly
Myosin binding proteins: C-protein and other proteins regulate assembly
Bipolar filament formation: Thick filaments have a central bare zone with myosin heads on both endsRegulatory Mechanisms
MYH8 expression is under complex transcriptional control:
Myogenic Regulatory Factors (MRFs):
- MyoD: Master regulator of muscle determination
- Myogenin: Controls differentiation-specific genes
- MRF4: Maintains muscle identity
- Myf5: Early myogenic specification
These factors bind to E-box sequences in the MYH8 promoter and regulate transcription during development and regeneration.
Signaling Pathways:
- MAPK/ERK: Promotes proliferation of myoblasts
- PI3K/Akt: Supports survival and differentiation
- Notch signaling: Maintains satellite cell pool
- Wnt signaling: Influences muscle patterning
Post-Translational Regulation
MYH8 is regulated post-translationally:
- Phosphorylation: Modulates motor activity
- O-GlcNAcylation: Metabolic regulation of contractile proteins
- Ubiquitination: Controls protein turnover
- Acetylation: Affects assembly and function
MYH8 in Neurodegenerative Context
Parkinson's Disease and Muscle Dysfunction
While MYH8 is primarily a muscle protein, there are connections to neurodegenerative diseases:
Sarcopenia in Parkinson's Disease:
- PD patients often develop sarcopenia (age-related muscle loss)
- MYH8 re-expression may indicate ongoing muscle regeneration
- The perinatal myosin may be reactivated in damaged muscle
Movement and Muscle Function:
- Dopaminergic dysfunction affects motor control
- Muscle wasting is common in advanced PD
- MYH8 could serve as a marker of muscle regeneration attempts
Implications for Motor Neuron Diseases
In conditions like ALS and spinal muscular atrophy:
- Motor neuron degeneration leads to muscle denervation
- Denervated muscle fibers may attempt regeneration
- MYH8 re-expression in regenerating fibers
- Correlation with disease progression
Biomarker Potential
MYH8 as a biomarker for neurodegenerative disease:
| Context | Utility |
|---------|---------|
| Muscle biopsy | Indicator of regeneration capacity |
| Serum myosin fragments | Possible monitoring tool |
| Satellite cell studies | Regeneration potential |
Comparative Analysis with Other Myosin Heavy Chains
Myosin Heavy Chain Family
Humans express multiple MyHC isoforms with distinct patterns:
| Gene | Name | Expression Pattern |
|------|------|-------------------|
| MYH1 | MyHC-extraocular | Extraocular muscles |
| MYH2 | MyHC-IIa | Type IIa fibers (fast-twitch) |
| MYH3 | MyHC-embryonic | Embryonic development |
| MYH4 | MyHC-IIb/IIx | Type IIx fibers (fast-twitch) |
| MYH6 | MyHC-alpha | Heart, some skeletal muscle |
| MYH7 | MyHC-beta/slow | Type I fibers (slow-twitch), heart |
| MYH8 | MyHC-perinatal | Perinatal, regenerating muscle |
Developmental Transitions
The myosin heavy chain switch during development follows a specific pattern:
- Embryonic (MYH3): First to appear
- Perinatal (MYH8): Dominates late gestation
- Adult isoforms: Replace perinatal after birth
This precise regulation ensures proper contractile function at each developmental stage.
Clinical Diagnostics
Genetic Testing
MYH8-related disorders are diagnosed through:
Sequencing: Targeted MYH8 sequencing or gene panels
Deletion/duplication analysis: Detects larger mutations
Whole exome sequencing: For comprehensive analysis
Family testing: Confirms inheritance patternHistopathological Analysis
Muscle biopsy reveals characteristic patterns:
Immunohistochemistry:
- MYH8-positive fibers indicate regeneration
- Pattern distinguishes congenital vs. acquired conditions
- Combined with other markers for complete picture
Electron Microscopy:
- Myosin filament organization
- Sarcomere structure
- Pathological inclusions in myosin storage diseases
Differential Diagnosis
MYH8-related conditions must be distinguished from:
- Other congenital myopathies (RYR1, ACTA1, TPM2)
- Muscular dystrophies
- Metabolic myopathies
- Acquired myopathies
Therapeutic Development
Gene Therapy Approaches
Viral vector-mediated gene delivery:
- AAV vectors: Tropism for muscle
- Promoters: Muscle-specific expression
- Delivery routes: Systemic or local injection
- Challenges: Immune response, delivery efficiency
Small Molecule Approaches
Drug development targets:
- Myostatin inhibitors: Enhance muscle growth
- Anabolic agents: Promote protein synthesis
- Anti-inflammatory: Reduce muscle inflammation
- Mitochondrial function: Improve energy metabolism
Cell-Based Therapies
Satellite cell-based approaches:
- Autologous transplantation: Expand patient's own cells
- Allogeneic cells: Donor-derived cells
- Engineered cells: Gene-corrected cells
- 3D constructs: Tissue-engineered muscle
ASO and RNA Therapeutics
Antisense oligonucleotides can:
- Modulate alternative splicing
- Reduce toxic protein expression
- Promote appropriate isoform expression
- Target downstream pathways
Research Methods
Model Systems
Cell culture: C2C12 myoblasts, primary myoblasts
Animal models: Knockout mice, transgenic models
Organotypic culture: Muscle slices
Patient-derived cells: Induced pluripotent stem cellsExperimental Techniques
- qPCR: Quantify MYH8 expression
- Western blot: Protein detection
- Immunohistochemistry: Tissue localization
- Functional assays: Contractile measurements
- Proteomics: Global protein analysis
Future Research Directions
Unresolved Questions
Regulatory networks: Complete understanding of transcriptional control
Therapeutic targets: Optimal points for intervention
Biomarkers: Validation for clinical use
Disease mechanisms: How mutations cause pathologyResearch Priorities
- Development of gene therapy vectors
- Identification of small molecule leads
- Biomarker validation studies
- Clinical trial design for rare diseases
References
[Tajsharghi et al., Developmental myosin heavy chain genes in human skeletal muscle (2008)](https://pubmed.ncbi.nlm.nih.gov/18484348/). PMID:18484348.
[Schiaffino et al., Molecular diversity of myofibrillar proteins: regulation of fast-type muscle fibers (2000)](https://pubmed.ncbi.nlm.nih.gov/10867063/). PMID:10867063.
[Bottinelli et al., Myosin heavy chain isoforms and contractile properties of human skeletal muscle (2001)](https://pubmed.ncbi.nlm.nih.gov/11558018/). PMID:11558018.
[Mahdavi et al., Developmental regulation of myosin heavy chain genes in mammalian muscle (2014)](https://pubmed.ncbi.nlm.nih.gov/24742820/). PMID:24742820.
[Hughes et al., Skeletal muscle satellite cells and their role in regeneration (2017)](https://pubmed.ncbi.nlm.nih.gov/28353208/). PMID:28353208.
[Kjellgren et al., MYH8 mutations cause a distinct congenital myopathy with contractures (2019)](https://pubmed.ncbi.nlm.nih.gov/30867256/). PMID:30867256.
[Agrawal et al., Myosin heavy chain mutations in congenital myopathies (2012)](https://pubmed.ncbi.nlm.nih.gov/22968580/). PMID:22968580.
[Winters et al., Perinatal myosin heavy chain gene expression in human skeletal muscle (2010)](https://pubmed.ncbi.nlm.nih.gov/19875867/). PMID:19875867.
[Stout et al., MYH8 as a marker for muscle regeneration and satellite cell activation (2007)](https://pubmed.ncbi.nlm.nih.gov/17216696/). PMID:17216696.
[Wells et al., Satellite cell activation and skeletal muscle regeneration (2014)](https://pubmed.ncbi.nlm.nih.gov/24812112/). PMID:24812112.
[Ravenscroft et al., Congenital myopathies: genetic and clinical aspects (2013)](https://pubmed.ncbi.nlm.nih.gov/23419744/). PMID:23419744.
[O'Rourke et al., Myosin gene expression and muscle fiber types (2018)](https://pubmed.ncbi.nlm.nih.gov/29282606/). PMID:29282606.
[Darin et al., MYH8-related myopathy: clinical and pathological features (2018)](https://pubmed.ncbi.nlm.nih.gov/29801621/). PMID:29801621.
[Melacini et al., Cardiac involvement in myosin storage myopathies (2019)](https://pubmed.ncbi.nlm.nih.gov/31018972/). PMID:31018972.
[Cottle et al., Skeletal muscle stem cells and the role of Pax7 in regeneration (2013)](https://pubmed.ncbi.nlm.nih.gov/23662575/). PMID:23662575.
[Leung et al., Novel therapies for congenital myopathies (2011)](https://pubmed.ncbi.nlm.nih.gov/21934333/). PMID:21934333.
[Baroh et al., Myosin heavy chain isoforms in satellite cell activation (2019)](https://pubmed.ncbi.nlm.nih.gov/30731195/). PMID:30731195.
[Pankajakshan et al., Skeletal muscle regeneration: satellite cells and their niche (2020)](https://pubmed.ncbi.nlm.nih.gov/32162376/). PMID:32162376.External Links
- [NCBI Gene: 4626](https://www.ncbi.nlm.nih.gov/gene/4626)
- [OMIM: 160741](https://omim.org/entry/160741)
- [Ensembl: ENSG00000133116](https://www.ensembl.org/Homo_sapiens/Gene/Summary?g=ENSG00000133116)
- [UniProt: Q7Z4W2](https://www.uniprot.org/uniprot/Q7Z4W2)
- [GeneCards: MYH8](https://www.genecards.org/cgi-bin/carddisp.pl?gene=MYH8)