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Title: Myoclonic Epilepsy and RaggedRed Fibers


1
Myoclonic Epilepsy and Ragged-Red Fibers
  • Presented by
  • Diana Baek diana.baek_at_utoronto.ca
  • Wendy Li wenndy.li_at_utoronto.ca
  • Vickie Chang vickie.chang_at_utoronto.ca

2
Myoclonic Epilepsy and Ragged-Red Fibres (MERRF)
  • A multisystem disorder
  • Characterized by myoclonus (involuntary twitching
    of a muscle), followed by generalized epilepsy,
    ataxia weakness and dementia.
  • Onset childhood, occurs after normal early
    development.

3
MERRF
  • Maternally inherited
  • Pathological changes in neurons of the
    dentato-rubral and the spinocerebellar pathways.
  • Pathological changes also in the inferior olivary
    nuclei and in skeletal muscle.
  • Generation of ragged red fibres is indicative of
    proliferation and subsarcolemmal accumulation of
    mitochondria.

4
MERRF- Signs and Symptoms
Table 1. Signs and Symptoms seen in 62
individuals with MERRF
5
MERRFClinical Diagnosis
  • Based on the following four canonical features
  • Myoclonus
  • Generalized epilepsy
  • Ataxia
  • Ragged-red fibres in the muscle biopsy
  • Other manifestations
  • Hearing loss, peripheral neuropathy, dementia,
    short stature, exercise intolerance, optic
    atrophy

6
Cause of MERRF
  • An A to G transition mutation at nucleotide pair
    8344 in human mitochondrial DNA (mtDNA)
  • Mutation alters the T?C loop of the tRNALys gene
  • Mutations of tRNA sequence can affect the
    primary, secondary and tertiary folding of the
    structure
  • Posttranscriptional modification in the wobble
    position at uridine was decreased in tRNALys
    mutation

7
Diagrammatic presentation of tRNALYS, showing
position of A-to-G base substitution in
pseudouridine loop of tRNA. This
affects the mitochondrial protein synthesis.
8
Modified Uridine
Uridine modification is important in the
codon-anticodon interaction
9
The significance of the wobble position.
  • MERRF-mutant tRNAlys will be unable to do its
    translational activity due to impaired
    codon-anticodon interaction of the unmodified
    uridine
  • Unmodified anticodon UUU is unable to translate
    its codon AAR
  • It is also unable to bind to the ribosome which
    ultimately leads to mitochondrial dysfunction

10
Introduction to mtDNA
  • Human mitochondrial DNA (mtDNA) contains genes
    required for mitochondrial protein biosynthesis
  • Specifically, mtDNA has tRNA genes for each of
    the 20 amino acids and codes for subunits of the
    respiratory complex
  • 7 subunits of complex 1
  • 1 subunit of complex III
  • 3 subunits of complex IV
  • 2 subunits of complex V

11
Introduction to mtDNA contd
  • Defect of tRNA leads to defective oxidative
    complex production
  • Associated with defects in oxidative
    phosphorylation complexes I and IV
  • Severity of the defect varies due to heteroplasmy
    mtDNA mutation

12
Possible cause of the mutation
  • The side effect of oxidative phosphorylation
    generation of reactive oxygen species (ROS)
  • MtDNA is located in the mitochondrial matrix and
    undergoes oxidative stress due to its close
    proximity to the respiratory chain complexes in
    the inner membrane ? high mutation rate

13
A closer look at the mitochondria
14
Treatment of MERRF
  • No cure, treatment is symptomatic
  • Valoproic acid, clonazepam, piracetam and
    levetiracetam for myoclonus and epilepsy
  • Possible treatments to improve mitochondrial
    function include coenzyme Q10, vitamin B
    complexes, vitamin C, folate, vitamin E, and
    levo-carnitine

15
Treatment of MERRF contd
  • Co-enzyme Q 10 transfers electrons from complex I
    to complex II and generates a proton gradient
    that supports ATP synthesis.  It is also a potent
    free radical scavenger.  Theoretically, it can
    work in respiratory chain defects by bypassing
    the defective respiratory chain complexes, acting
    as pure electron acceptors, and by acting as free
    radical scavengers.  The suggested dosage is
    60-300mg/day
  • Vitamin B complexes, particularly vitamin B1
    (thiamine) at 50-200mg/day and vitamin B2
    (riboflavin) at 50-600mg/day
  • Vitamin C at 100-2000mg in divided doses

16
Treatment of MERRF contd
  • Folate at 1-10mg/day
  • Vitamin E at 200-1200 IU/day in divided doses
  • Levo-carnitine at 100-200mg/kg/day in divided
    doses, maximum 1000 mg tid
  • The efficacy of these treatments are theoretical
    and require further research

17
Summary
  • Myoclonic Epilepsy and Ragged-Red Fiber (MERRF)
    is maternally inherited
  • Characterized by myoclonus (involuntary twitching
    of a muscle), followed by generalized epilepsy,
    ataxia weakness and dementia
  • Caused by an A to G transition mutation at
    nucleotide pair 8344 in human mitochondrial DNA
    (mtDNA)
  • Mutation alters the T?C loop of the tRNALys gene

18
Summary contd
  • Posttranscriptional modification in the wobble
    position at uridine was decreased in tRNALys
    mutation
  • Defect of tRNA leads to defective oxidative
    complex production, this is associated with
    defects in oxidative phosphorylation complexes I
    and IV
  • No cure, treatment is symptomatic
  • Valoproic acid, clonazepam, piracetam and
    levetiracetam for myoclonus and epilepsy
  • Possible treatments to improve mitochondrial
    function include coenzyme Q10, vitamin B
    complexes, vitamin C, folate, vitamin E, and
    levo-carnitine

19
References
  • Fernando Scaglia, Lee-Jun C. Wong. Human
    mitochondrial transfer RNAs Role of pathogenic
    mutation in disease. 2008. Muscle Nerve 372
    150-171.
  • Yasukawa T, Suzuki T, Ishii N, Ueda T, Ohta S,
    Watanabe K 2000. Wobble modification defect in
    tRNA disturbs codonanticodon interaction in a
    mitochondrial disease. FEBS Lett 467175178.
  • DiMauro S and Hirano M. MERRF. http//www.ncbi.nlm
    .nih.gov/bookshelf/br.fcgi?bookgenepartmerrf.
    Gene Review 2005
  • Zhou L, Chomyn A, Attardi G, Miller C.A.
    Myoclonic Epilepsy and Ragged Red Fibers(MERRF)
    Syndrome Selective Vulnerability of CNS Neurons
    Does Not Correlate with the Levels of
    Mitochondrial tRNAlys Mutation in Individual
    Neuronal Isolates. The Journal of Neuroscience.
    1997 17(20) 7746-7753.
  • Zupanc ML, Legros B.  Progressive myoclonic
    epilepsy.  The Cerebellum. 2004. 3 156-171.
  • Wyllie E, Gupta A, Lachhwani DK.  Chapter 26 The
    Myoclonic Epilepsies.  The treatment of Epilepsy
    Principles and Practice. 4th Edition. Lippincott
    Williams and Wilkins.  2005. 422.
  • Wallace D., Zheng X, Lott M, Shoffner J, Hodge J,
    Kelley R, Epstein C, and Hopkins L. Familial
    Mitochondrial Encephalomyopathy (MERRF) Genetic,
    Pathophysiological, and Biochemical
    Characterization of a Mitochondrial DNA Disease.
    1988, Cell. 55 601-610.
  • Noer A, Sudoyo H, Lertrit P, Thyagarajan D,
    Utthanaphol P, Kapsa R, Byrne E and Marzuki S. A
    tRNALYS Mutation in the mtDNA Is the Causal
    Genetic Lesion Underlying Myoclonic Epilepsy and
    Ragged-Red Fiber (MERRF) Syndrome. 1991. Am J
    Hum Genet. 49 715-722.
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