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Amyotrophic Lateral Sclerosis With Ragged-Red Fibers FREE

Michio Hirano, MD; Corrado Angelini, MD; Pasquale Montagna, MD; Arthur P. Hays, MD; Kurenai Tanji, MD; Hiroshi Mitsumoto, MD; Paul H. Gordon, MD; Ali B. Naini, PhD; Salvatore DiMauro, MD; Lewis P. Rowland, MD
[+] Author Affiliations

Author Affiliations: Departments of Neurology (Drs Hirano, Hays, Tanji, Mitsumoto, Gordon, Naini, DiMauro, and Rowland) and Pathology (Drs Hays and Tanji), Columbia University Medical Center, New York, New York; and Department of Neurology, University of Padova, Padova (Dr Angelini), and Department of Neurological Sciences, University of Bologna, Bologna (Dr Montagna), Italy.


Arch Neurol. 2008;65(3):403-406. doi:10.1001/archneurol.2007.65.
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Published online

ABSTRACT

Background  Motor neuron diseases (amyotrophic lateral sclerosis [ALS] and spinal muscular atrophy [SMA]) have been rarely associated with mitochondrial respiratory chain defects.

Objectives  To describe a patient with typical ALS and the finding of ragged-red fibers in muscle biopsy specimens and to review the literature on respiratory chain defects in ALS and SMA.

Design  Case report and review of the literature.

Setting  Collaboration between tertiary care academic hospitals.

Patient  A 65-year-old man with typical ALS.

Main Outcome Measures  The patient had 10% ragged-red fibers and 3% cytochrome-c oxidase–negative fibers in muscle biopsy specimens but no biochemical defects of respiratory chain enzymes or alterations of mitochondrial DNA (mtDNA).

Results  Amyotrophic lateral sclerosis with ragged-red fibers has been reported in 5 families and is associated with mtDNA mutations in some subjects. Spinal muscular atrophy without mutations in the survival motor neuron gene (SMN; OMIM 600354) has been associated with mtDNA depletion or with mutations in the cytochrome-c oxidase assembly gene (SCO2; OMIM 604377).

Conclusion  Respiratory chain defects can mimic ALS or SMA and should be considered in the differential diagnosis.

Figures in this Article

Mitochondrial dysfunction has an important role in the pathogenesis of familial amyotrophic lateral sclerosis (ALS), in which 20% of patients appear to have toxic gain-of-function mutations in copper-zinc superoxide dismutase 1 (SOD1), a cytosolic and mitochondrial protein. In patients with sporadic ALS, respiratory chain enzyme deficiency has been found in the spinal cord, and accumulation of abnormal mitochondria has been observed in anterior horn cells.1

Primary mitochondrial diseases (ie, those due to defects of the respiratory chain) have been associated with motor neuron disease, including ALS and spinal muscular atrophy (SMA). The neurologic manifestations of primary mitochondrial diseases are diverse and include sensorimotor peripheral polyneuropathy.2 However, purely lower motor neuron disorders are seen infrequently. We describe a patient having what seems to be typical ALS but in whom muscle biopsy specimens showed ragged-red fibers (RRFs), a sign of abnormal mitochondrial proliferation.

METHODS

PATIENT

The patient was a businessman who worked in the agricultural industry of Italy until age 58 years. After retiring, he was an enthusiastic golfer and a ballroom dancer. At age 60, he noticed twitching of his thigh muscles and stiffness of the legs. At age 64, he had calf cramps, and his legs had become weak by age 65. He also had cramps in the arms and used a cane to walk. He had to use his arms for support on rising from chairs. He experienced a fall and had difficulty rising. He had no cognitive problems, weight loss, paresthesias, dysarthria, dysphagia, dyspnea, or bladder or bowel symptoms.

On examination in Italy at age 63 years, findings included profuse fasciculations in all 4 limbs, proximal arm weakness, and distal more than proximal leg weakness, worse on the right. Sensation was normal. Tendon reflexes were brisk, with bilateral Babinski signs. Cognition and cranial nerve functions were normal. Laboratory data included the following abnormal levels: creatine kinase (466 U/L; normal, <190 U/L), aspartate aminotransferase (78 U/L; reference range, 10-45 U/L), alanine aminotransferase (71 U/L; reference range, 10-50 U/L), γ-glutamyltransferase (218 U/L; reference range, 3-65 U/L), and alkaline phosphatase (148 U/L; reference range, 56-128) (to convert these levels to microkatals per liter, multiply by 0.0167). His anti–myelin-associated glycoprotein (MAG) IgM titer was 1:4700 (reference range, <1:1000), but his anti-MAG IgG and anti-GM1 titers were normal. His antinuclear antibody titer was greater than 1:20. The following findings were normal or negative: anti–hepatitis B surface antigen, C3-C4, anti-Sm, anti-Jo1, anti-Scl70, anti-SSA, anti-SSB, and cryoglobulin levels. His cerebrospinal fluid protein level was 8.1 g/dL (reference range, 6.0-8.0 g/dL) (to convert to grams per liter, multiply by 10.0), and his γ-globulin level was 21% (normal range, 11%-18.6%), with no oligoclonal bands.

Results of nerve conduction studies of motor nerves in the legs showed decreased amplitudes, and electromyography demonstrated moderate denervation in the legs but not in the glutei, suggesting motor neuropathy in the legs. Study findings in the arms were normal. The following results were normal or negative: spirometry, electrocardiogram, neuropsychological testing, and brain single-photon emission computed tomography perfusion with technetium Tc 99m.

One year later, the findings were similar. Nerve conduction studies and the electrocardiogram revealed slight slowing of sural sensory nerves and denervation in the 4 limbs. Transcranial motor-evoked potentials showed central conduction defects to the legs. Cerebrospinal fluid glucose and protein levels and cell counts were normal. His serum γ-glutamyltransferase level was elevated (204 U/L). Brain magnetic resonance imaging was unremarkable. Cervical magnetic resonance imaging revealed diffuse degenerative changes at C3-C7 without cord compression and a C4-C5 disk protrusion in the left paramedian posterior region.

At age 65 years, he had taken prednisone (75 mg/d for 4 weeks) without benefit. After tapering the dosage, he experienced greater weakness. He was taking 25 mg/d when examined by us.

There was no family history of ptosis, seizures, hearing loss, cardiomyopathy, ophthalmoplegia, diabetes mellitus, strokes at young ages, or neuromuscular disease. His general physical examination showed no abnormalities. He was alert with normal speech, language, and memory. Cranial nerve functions were normal, including the tongue, which showed no atrophy or fasciculation. Atrophy of the quadriceps was more prominent on the right. Many fasciculations were seen in the quadriceps, fewer in the calves, and rare twitches in the triceps. Tone in the legs was slightly increased. There was slight weakness of the deltoids and biceps but not of the wrist, triceps, or hand muscles. Distal leg muscles were slightly weak, more on the left. No tremor was seen. He had a mild right steppage gait and mild right circumduction. He could not walk on the toes or heels. Sensation was normal. Tendon reflexes were overactive throughout, with clonus at the ankles, bilateral Hoffmann signs, a right Babinski reflex, and bilateral tensor fascia lata responses.

HISTOCHEMISTRY AND BIOCHEMISTRY

Histochemical study of muscle biopsy specimens using 8-μm-thick frozen sections was performed as previously described.3 Biochemical analysis was performed in a 10% muscle homogenate using published procedures.4

MOLECULAR ANALYSIS

Total DNA was extracted by standard protocol (PUREGENE; Gentra Systems, Inc, Minneapolis, Minnesota) following the manufacturer's instructions. Direct sequencing of the 22 transfer RNA (tRNA) genes of mitochondrial DNA (mtDNA) was performed (ABI Prism 310 Genetic Analyzer using the Big Dye Terminator Cycle Sequencing Reaction Kit; Perkin-Elmer Applied Biosystems, Foster City, California).

RESULTS

Muscle biopsy specimens revealed neurogenic changes, with 10% RRFs and 3% cytochrome-c oxidase (COX)–negative fibers (Figure). The activities of the respiratory chain complexes were normal in a muscle extract (data not shown). Southern blot analysis of mtDNA showed no large-scale rearrangement or depletion, whereas the more sensitive “long polymerase chain reaction” revealed faint abnormal bands indicative of multiple mtDNA deletions. This is probably a normal finding in a 65-year-old subject. Sequencing of the whole mtDNA showed no pathogenic mutations.

Place holder to copy figure label and caption
Figure.

Cross sections of frozen muscle specimens stained for succinate dehydrogenase (SDH) reaction (A) and for cytochrome-c oxidase (COX) reaction (B). Scattered fibers stain intensely for SDH, a sign of mitochondrial proliferation, whereas other fibers are COX negative (arrows).

Graphic Jump Location

COMMENT

The clinical findings of the patient were compatible with ALS. The findings of RRFs and COX-negative fibers in muscle biopsy specimens suggested a mitochondrial motor neuron disease or 2 independent disorders. The mitochondrial proliferation revealed by the RRFs was not severe enough to be reflected in increased activity of citrate synthase, a marker of mitochondrial mass. Despite the presence of COX-negative fibers, the activities of all respiratory chain complexes were normal.

That primary mitochondrial dysfunction can cause motor neuron disease is an idea based on only a few cases. The first was in a family described by Dobkin and Verity5 in 1976. The propositus had dysarthria and dysphagia from childhood. His hands became weak at age 28 years, and he manifested almost purely a motor syndrome (but he had paresthesias and slowing of sural nerve conduction). A muscle biopsy specimen showed 3% RRFs, and electron microscopy demonstrated clusters of normal and giant mitochondria. His mother had a similar syndrome. Her autopsy results showed no loss of motor neurons in the brain, but anterior horn cells were depleted. The maternal grandmother of the propositus also had an autopsy performed because of weight loss and “anorexia nervosa,” but the spinal cord was not examined. This was the first reported family with SMA and mitochondriopathy. The evidence of maternal inheritance was compatible with an mtDNA mutation, but mitochondrial genetics was to come of age only 10 years later.6

The next report was in 1991, when Rowland et al7 mentioned a case in a series of patients with mitochondrial diseases. This was the same patient described in detail by Pons et al8 in 1996 as an example of the myopathic variant of mtDNA depletion syndrome due to mutations in the thymidine kinase 2 nuclear gene (TK2; OMIM 188250).9 Additional infants with TK2 mutations had the SMA phenotype, confirming the importance of sequencing this gene in infants with SMA but without mutations in the SMN gene.10,11

In the meantime, Comi et al12 described a man who had developed spastic paraparesis at age 29 years. At age 32, an electromyogram showed widespread denervation. His cerebrospinal fluid protein level rose from 5.7 to 8.0 g/dL in 1 year, and his serum lactate level was borderline high. Succinate dehydrogenase stains showed a pattern of RRFs, and biochemical analysis demonstrated isolated decreased COX activity (43% of normal). Sequencing showed a 5–base pair microdeletion in the mtDNA-encoded subunit I of COX, the first described mtDNA mutation in a motor neuron disease. A description of 3 similar cases followed. Finsterer13 described a mother and 2 daughters with symptoms consistent with ALS, COX-negative fibers, and ultrastructurally abnormal mitochondria in muscle, without mutations in the SOD1 gene (OMIM 147450) but with as many as 3 different mtDNA mutations, one in the tRNAIle gene (OMIM 590045), a second in the cytochrome b gene (OMIM 516020), and a third in the adenosine triphosphatase 6 gene (516060).

Fetoni et al14 described a man who was believed to have monomelic amyotrophy but had bilaterally overactive reflexes. The patient had diabetes mellitus, and other family members had hearing loss in a pattern of maternal inheritance. His serum lactate level was normal, but muscle biopsy specimens showed COX-negative fibers and RRFs, as well as a pattern of denervation. A mutation in the tRNASer(UCN) gene (OMIM 590080) of mtDNA was found in the patient and in a maternal niece.

Rubio-Gozalbo and colleagues15 described a child who had a severe lower motor neuron syndrome from birth and had died at age 5 months without an autopsy. The SMN gene was normal, excluding conventional SMA, but his lactate levels were high in serum and in cerebrospinal fluid. Muscle biopsy specimens showed no RRFs but demonstrated diffuse COX deficiency. The coexistence of cardiomyopathy in this child suggests that he may have had a deficiency of the nuclear-encoded COX assembly protein SCO2, as 2 other infants with SMA, and cardiomyopathy, and no mutations in the SMN gene.16,17

Borthwick et al18 described a 73-year-old man who had limb weakness for 6 months before he died of cardiac arrest while under study. He had diabetes mellitus and had undergone placement of a pacemaker after a myocardial infarction. Autopsy results showed normal motor cortex and corticospinal tracts. The number of anterior horn cells was undiminished, but many showed chromatolysis without inclusions, failing to confirm the clinical diagnosis of adult-onset progressive muscular atrophy. The findings of COX-deficient motor neurons suggested the possibility of a mitochondrial disorder. This was confirmed by mtDNA sequencing, which showed a heteroplasmic mutation in the tRNAIle gene. Although this was 1 of 3 mutant genes in the patient described by Finsterer,13 the mutation was different (J. Finsterer, MD, PhD, e-mail communication, August 2, 2007).

There seems to be little doubt now that disorders of the mitochondrial respiratory chain can cause lower motor neuron disorders compatible with SMA of children, progressive muscular atrophy of adults, or ALS. The abnormalities may be mutations in mtDNA or in nuclear genes controlling respiratory chain complexes (SCO2) or mtDNA replication (TK2). The diversity of clinical syndromes is matched by inconsistent findings biochemically and genetically, without a clear genotype-phenotype correlation.

ARTICLE INFORMATION

Correspondence: Michio Hirano, MD, Department of Neurology, Columbia University Medical Center, 3-317 Russ Berrie Medical Science Pavilion, 1150 St Nicholas Ave, New York, NY 10032 (mh29@columbia.edu).

Accepted for Publication: October 4, 2007.

Author Contributions:Study concept and design: Hirano, DiMauro, and Rowland. Acquisition of data: Hirano, Angelini, Montagna, Hays, Tanji, Naini, DiMauro, and Rowland. Analysis and interpretation of data: Hirano, Mitsumoto, Gordon, Naini, and Rowland. Drafting of the manuscript: Hirano, Gordon, and Rowland. Critical revision of the manuscript for important intellectual content: Hirano, Angelini, Montagna, Hays, Tanji, Mitsumoto, Gordon, Naini, DiMauro, and Rowland. Administrative, technical, and material support: Hirano, Angelini, Tanji, and Gordon. Study supervision: Mitsumoto, Gordon, Naini, and DiMauro.

Financial Disclosure: None reported.

Funding/Support: This study was supported by grant HD32062 from the National Institutes of Health and by the Marriott Mitochondrial Disorders Clinical Research Fund (Drs Hirano, Naini, and DiMauro).

REFERENCES

Beal  MF Mitochondria take center stage in aging and neurodegeneration. Ann Neurol 2005;58 (4) 495- 505
PubMed Link to Article
Hays  APOskoui  MTanji  KKaufmann  PBonilla  E Mitochondrial neurology, II: myopathies and peripheral neuropathies. DiMauro  SHirano  MSchon  EAMitochondrial Medicine. London, England Informa Healthcare2006;45- 74
Tanji  KBonilla  E Optical imaging techniques (histochemical, immunohistochemical, and in situ hybridization staining methods) to visualize mitochondria. Methods Cell Biol 2001;65311- 332
PubMed
DiMauro  SServidei  SZeviani  M  et al.  Cytochrome c oxidase deficiency in Leigh syndrome. Ann Neurol 1987;22 (4) 498- 506
PubMed Link to Article
Dobkin  BHVerity  MA Familial progressive bulbar and spinal muscular atrophy: juvenile onset and late mortality with ragged-red fibers. Neurology 1976;26 (8) 754- 763
PubMed Link to Article
DiMauro  S Mitochondrial medicine. Biochim Biophys Acta 2004;1659 (2-3) 107- 114
PubMed Link to Article
Rowland  LPBlake  DHirano  M  et al.  Clinical syndromes associated with ragged red fibers. Rev Neurol (Paris) 1991;147 (6-7) 467- 473
PubMed
Pons  RAndreetta  FWang  CH  et al.  Mitochondrial myopathy simulating spinal muscular atrophy. Pediatr Neurol 1996;15 (2) 153- 158
PubMed Link to Article
Oskoui  MDavidzon  GPascual  J  et al.  Clinical spectrum of mitochondrial DNA depletion due to mutations in the thymidine kinase 2 gene. Arch Neurol 2006;63 (8) 1122- 1126
PubMed Link to Article
Mancuso  MSalviati  LSacconi  S  et al.  Mitochondrial DNA depletion: mutations in thymidine kinase gene with myopathy and SMA. Neurology 2002;59 (8) 1197- 1202
PubMed Link to Article
Mancuso  MFilosto  MHirano  MDiMauro  S Spinal muscular atrophy and mtDNA depletion. Acta Neuropathol 2003;105 (6) 621- 622
PubMed
Comi  GPBordoni  ASalani  S  et al.  Cytochrome c oxidase subunit I microdeletion in a patient with motor neuron disease. Ann Neurol 1998;43 (1) 110- 116
PubMed Link to Article
Finsterer  J Mitochondriopathy mimicking amyotrophic lateral sclerosis. Neurologist 2003;9 (1) 45- 48
PubMed Link to Article
Fetoni  VBriem  ECarrara  FMora  MZeviani  M Monomelic amyotrophy associated with the 7472insC mutation in the mtDNA tRNASer(UCN) gene. Neuromuscul Disord 2004;14 (11) 723- 726
PubMed Link to Article
Rubio-Gozalbo  MESmeitink  JAMRuitenbeek  W  et al.  Spinal muscular atrophy–like picture, cardiomyopathy, and cytochrome c oxidase deficiency. Neurology 1999;52 (2) 383- 386
PubMed Link to Article
Salviati  LSacconi  SRasalam  MM  et al.  Cytochrome c oxidase deficiency due to a novel SCO2 mutation mimicking Werdnig-Hoffman disease. Arch Neurol 2002;59862- 865
Link to Article
Tarnopolsky  MABourgeois  JMFu  MH  et al.  Novel SCO2 mutation (G1521A) presenting as a spinal muscular atrophy type I phenotype. Am J Med Genet A 2004;125 (3) 310- 314[published correction appears in Am J Med Genet A. 2004;130(2):218].
Link to Article
Borthwick  GMTaylor  RWWalls  TJ  et al.  Motor neuron disease in a patient with a mitochondrial tRNAIle mutation. Ann Neurol 2006;59 (3) 570- 574
PubMed Link to Article

Figures

Place holder to copy figure label and caption
Figure.

Cross sections of frozen muscle specimens stained for succinate dehydrogenase (SDH) reaction (A) and for cytochrome-c oxidase (COX) reaction (B). Scattered fibers stain intensely for SDH, a sign of mitochondrial proliferation, whereas other fibers are COX negative (arrows).

Graphic Jump Location

Tables

References

Beal  MF Mitochondria take center stage in aging and neurodegeneration. Ann Neurol 2005;58 (4) 495- 505
PubMed Link to Article
Hays  APOskoui  MTanji  KKaufmann  PBonilla  E Mitochondrial neurology, II: myopathies and peripheral neuropathies. DiMauro  SHirano  MSchon  EAMitochondrial Medicine. London, England Informa Healthcare2006;45- 74
Tanji  KBonilla  E Optical imaging techniques (histochemical, immunohistochemical, and in situ hybridization staining methods) to visualize mitochondria. Methods Cell Biol 2001;65311- 332
PubMed
DiMauro  SServidei  SZeviani  M  et al.  Cytochrome c oxidase deficiency in Leigh syndrome. Ann Neurol 1987;22 (4) 498- 506
PubMed Link to Article
Dobkin  BHVerity  MA Familial progressive bulbar and spinal muscular atrophy: juvenile onset and late mortality with ragged-red fibers. Neurology 1976;26 (8) 754- 763
PubMed Link to Article
DiMauro  S Mitochondrial medicine. Biochim Biophys Acta 2004;1659 (2-3) 107- 114
PubMed Link to Article
Rowland  LPBlake  DHirano  M  et al.  Clinical syndromes associated with ragged red fibers. Rev Neurol (Paris) 1991;147 (6-7) 467- 473
PubMed
Pons  RAndreetta  FWang  CH  et al.  Mitochondrial myopathy simulating spinal muscular atrophy. Pediatr Neurol 1996;15 (2) 153- 158
PubMed Link to Article
Oskoui  MDavidzon  GPascual  J  et al.  Clinical spectrum of mitochondrial DNA depletion due to mutations in the thymidine kinase 2 gene. Arch Neurol 2006;63 (8) 1122- 1126
PubMed Link to Article
Mancuso  MSalviati  LSacconi  S  et al.  Mitochondrial DNA depletion: mutations in thymidine kinase gene with myopathy and SMA. Neurology 2002;59 (8) 1197- 1202
PubMed Link to Article
Mancuso  MFilosto  MHirano  MDiMauro  S Spinal muscular atrophy and mtDNA depletion. Acta Neuropathol 2003;105 (6) 621- 622
PubMed
Comi  GPBordoni  ASalani  S  et al.  Cytochrome c oxidase subunit I microdeletion in a patient with motor neuron disease. Ann Neurol 1998;43 (1) 110- 116
PubMed Link to Article
Finsterer  J Mitochondriopathy mimicking amyotrophic lateral sclerosis. Neurologist 2003;9 (1) 45- 48
PubMed Link to Article
Fetoni  VBriem  ECarrara  FMora  MZeviani  M Monomelic amyotrophy associated with the 7472insC mutation in the mtDNA tRNASer(UCN) gene. Neuromuscul Disord 2004;14 (11) 723- 726
PubMed Link to Article
Rubio-Gozalbo  MESmeitink  JAMRuitenbeek  W  et al.  Spinal muscular atrophy–like picture, cardiomyopathy, and cytochrome c oxidase deficiency. Neurology 1999;52 (2) 383- 386
PubMed Link to Article
Salviati  LSacconi  SRasalam  MM  et al.  Cytochrome c oxidase deficiency due to a novel SCO2 mutation mimicking Werdnig-Hoffman disease. Arch Neurol 2002;59862- 865
Link to Article
Tarnopolsky  MABourgeois  JMFu  MH  et al.  Novel SCO2 mutation (G1521A) presenting as a spinal muscular atrophy type I phenotype. Am J Med Genet A 2004;125 (3) 310- 314[published correction appears in Am J Med Genet A. 2004;130(2):218].
Link to Article
Borthwick  GMTaylor  RWWalls  TJ  et al.  Motor neuron disease in a patient with a mitochondrial tRNAIle mutation. Ann Neurol 2006;59 (3) 570- 574
PubMed Link to Article

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