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Arquivos de Neuro-Psiquiatria

Print version ISSN 0004-282X

Arq. Neuro-Psiquiatr. vol.61 no.2A São Paulo June 2003

http://dx.doi.org/10.1590/S0004-282X2003000200019 

Myotonia congenita and myoadenylate deaminase deficiency

Case report

 

Miotonia congênita e deficiência de mioadenilato deaminase: relato de caso

 

 

Rosana Herminia ScolaI; Fabio Massaiti IwamotoII; Carlos Henrique CamargoII; Walter Oleschko ArrudaIII; Lineu Cesar WerneckIV

Division of Neurology and Neuromuscular Disorders, Hospital de Clínicas of the Universidade Federal do Paraná (UFPR), Curitiba PR, Brazil
IAssociate Professor
Division of Neurology and Neuromuscular Disorders, Hospital de Clínicas of the Universidade Federal do Paraná (UFPR), Curitiba PR, Brazil
IIResident
Division of Neurology and Neuromuscular Disorders, Hospital de Clínicas of the Universidade Federal do Paraná (UFPR), Curitiba PR, Brazil
IIIAssistant Professor
Division of Neurology and Neuromuscular Disorders, Hospital de Clínicas of the Universidade Federal do Paraná (UFPR), Curitiba PR, Brazil
IVProfessor of Neurology

 

 


ABSTRACT

Approximately 1-2% of the population has a deficiency of the enzyme myoadenylate deaminase. Early reports suggested that patients with myoadenylate deaminase deficiency had various forms of myalgia, and exercise intolerance. However, a deficiency of the enzyme has been described in many conditions, including myopathies, neuropathies, and motor neuron disease. We report a patient with clinical diagnosis of myotonia congenita and absent myoadenylate deaminase reaction on the muscle biopsy. This is the first description of myoadenilate deaminase deficiency with myotonia congenita. Myoadenylate deaminase deficiency is the most common enzymatic deficit of muscle, and the association with other neuromuscular diseases is coincidental.

Key words: myotonia congenita, myoadenilate deaminase, muscle biopsy.


RESUMO

Aproximadamente 1-2% da população apresenta deficiência de mioadenilato deaminase (MAD). Estudos iniciais sugeriam que pacientes com deficiência de MAD apresentavam várias formas de mialgias e intolerância ao exercício. Contudo, a deficiência de MAD já foi descrita em várias situações, incluindo miopatias, neuropatias e doenças do neurônio motor. Relatamos um paciente com o diagnóstico clínico de miotonia congênita e deficiência de MAD na biópsia muscular. Essa é a primeira descrição de deficiência de MAD associada a miotonia congênita. A deficiência de MAD é o déficit enzimático mais comum nos músculos esqueléticos e sua associação com diversas doenças neuromusculares é apenas coincidência.

Palavras-chave: miotonia congênita, mioadenilato deaminase, biópsia muscular.


 

 

Approximately 1-2% of the population has a deficiency of the enzyme myoadenylate deaminase (MAD)1. This condition is inherited as an autosomal recessive trait. Early reports suggested that patients with MAD deficiency had a syndrome of myalgia, and exercise intolerance2. However, deficiency of the MAD has been described in many conditions, including myopathies, neuropathies, and motor neuron disease3. We report a patient with clinical diagnosis of myotonia congenita and absent myoadenylate deaminase reaction on the muscle biopsy.

 

CASE

A 12-year-old boy presented since the age of 4 years episodes of myotonia, mild muscular weakness, and learning disability. He had normal achievement of motor milestones. His parents were healthy, and unrelated. His younger sister has diagnosed myotonia congenita, and atypical Rett syndrome. General physical examination was normal. On neurological examination, he presented normal cranial nerves, normal muscle bulk and tonus, muscular strength grade IV+ (Medical Research Council), symmetrical +/IV deep tendon reflexes, myotonia on hands, brachial biceps and deltoids (triggered by percussion), and difficulty in starting gait due to myotonia. Coordination, and sensation were normal. Complete blood count, serum muscle enzymes, and lactic acid were normal. Needle electromyography showed myopathic features and myotonic discharges in all tested muscles. The muscle biopsy disclosed decreased type 2B fibers, and absent histochemical reaction for myoadenylate deaminase (Figure). Phenytoin was started with moderate symptom improvement.

 

 

DISCUSSION

In 1978, Fishbein et al. described MAD deficiency in skeletal muscle of 5 patients with exercise-related muscle cramps, and myalgias2. In skeletal muscle MAD catalyzes the deamination of adenosine monophosphate (AMP) to inosine monophosphate (IMP) and ammonia. One proposed role of MAD is to prevent a large increase in AMP, thereby attenuating accumulation of adenosine diphosphate (ADP) and inhibitory influence of low ATP/ADP ratio on muscle function. In accordance with the proposed function of MAD, the absence of the enzyme would be expected to be associated with exercise intolerance1. MAD deficiency is generally caused by a homozygous point mutation, a C ® T transition at nucleotide 34 in the second exon of the MAD gene in the chromosome 1, which results in a premature termination codon in exon 2, and thus in a severely truncated enzyme4.

The classical clinical findings associated with MAD deficiency correspond to those of a metabolic myopathy with exercise-related symptoms such as early fatigue, muscle pain, and muscle cramps. In typical cases, the symptoms are either induced or aggravated by exercise. However, there is a wide variation in the severity of symptoms and age at onset, and asymptomatic cases have been described5.

MAD deficiency is the most common among known enzymatic deficits of muscle, and may occur in association with other neuromuscular diseases. Absence of MAD occurs in approximately 2% of muscle biopsy submitted to pathologic examination for suspected neuromuscular disease6. MAD deficiency have been described in muscle biopsy of patients with polyneuropathy, infantile spinal muscular atrophy, congenita myopathy with type-2 fiber atrophy, facioscapulohumeral myopathy, polymyositis, dermatomyositis, myotonic dystrophy, limb-girdle muscular dystrophy, dystrophinopathies, systemic sclerosis, McArdle's disease, phosphofructokinase deficiency, and hyperornithinaemia with gyrate atrophy of the retina3,7-9.

MAD deficiency associated with other neuromuscular disorders was previously thought to be the result of a limitation in MAD transcript availability, secondary to the pathological abnormalities in a variety of neuromuscular or rheumatological disorders. Verzijl et al.7 found that isolated MAD deficiency and MAD deficiency associated with other neuromuscular disorders had the same underlying molecular DNA defect. In the latter cases, MAD deficiency is merely a chance association, due, a concurrence of the frequently occurring mutant MAD allele with another neuromuscular disorder.

Currently, considering the high frequency of the mutant allele in the general population, even the association of MAD deficiency with exercise intolerance is controversial and could be coincidental. Norman's study demonstrated that the prevalence of MAD deficiency in the healthy population was 2%1. Moreover, healthy individuals with MAD deficiency had normal exercise tolerance.

Our patient has clinical and histopathological features of myotonia congenita. Patients with myotonia congenita present myotonias, which usually occur when initiating a rapid motion, such as starting to run. The myotonia often decreases as the motion is continued. Myotonia congenita occurs in two forms: autosomal dominant (Thomsen's disease) and autosomal recessive (Becker's disease)10. Clinical classification as either Thomsen's or Becker's disease is entirely based on inheritance patterns, but transient weakness is more common in Becker's myotonia. Both disorders are chloride channelopathies, and many mutations in the chloride channel gene (CLCN1) have been described in Thomsen's disease11,12.

Analyzing the molecular basis of the three diseases, there are no clear-cut similarities among them that clearly justify their occurrence in our patient and his family. Myoadenylate deaminase deficiency is the most common metabolic disorder of skeletal muscle in the Caucasian population, affecting approximately 2% of all individuals has been attributed to a single mutant allele characterized by double C to T transitions at nucleotides +34 and +143 in mRNA encoded by the AMPD1 gene13. Mutations in the muscle chloride channel gene CLCN1, cause myotonia congenita, an inherited disorder of skeletal muscle excitability leading to a delayed relaxation after muscle contraction12. In some 80% of girls with Rett Syndrome, there are mutations in the methyl-CpG-binding protein-2 (MECP2) gene on Xq2814.

Determining the mode of inheritance is not easy and requires the carefully investigation of family members because dominant mutations show variable penetrance and may present with very mild symptoms10-13.

This is the first description of MAD deficiency with myotonia congenita. Since this enzyme defect is very common, patients with other neuromuscular disorders can present a coincidental MAD deficiency. The clinical significance of MAD deficiency associated with other neuromuscular disorders remains unknown. Whether patients with neuromuscular disorders and MAD deficiency have different clinical features or course from those without MAD deficiency was not evaluated. However, the similar frequencies of MAD deficiency in patients with exercise intolerance, in patients with other neuromuscular complaints, and in healthy volunteers suggest that MAD deficiency cannot be considered a disease in itself.

 

REFERENCES

1. Norman B, Glenmark B, Jansson E. Muscle AMP deaminase deficiency in 2% of a healthy population. Muscle Nerve 1995;18:239-241.        [ Links ]

2. Fishbein WN, Armbrustmacher VW, Griffin JL. Myoadenilate deaminase deficiency: a new disease of muscle. Science 1978;200:545-548.        [ Links ]

3. Mercelis R, Martin JJ, de Barsy T, Van den Berghe G. Myoadenylate deaminase deficiency: absence of correlation with exercise intolerance in 452 muscle biopsies. J Neurol 1987;234:385-389.        [ Links ]

4. Morisaki T, Gross M, Morisaki H, Pongratz D, Zöllner N, Holmes EW. Molecular basis of AMP deaminase deficiency in skeletal muscle. Proc Natl Acad Sci USA 1992;89:6457-6461.        [ Links ]

5. Gross M. Clinical heterogeneity and molecular mechanisms in inborn muscle AMP deaminase deficiency. J Inher Metab Dis 1997;20:186-192.        [ Links ]

6. Sabina RL, Fishbein WN, Pezeshkpour G, Clarke PRH, Holmes EW. Molecular analysis of the myoadenilate deaminase deficiencies. Neurology 1992;42:170-179.        [ Links ]

7. Verzijl HTFM, van Engelen BGM, Luyten JAFM, et al. Genetic characteristics of myoadenilate deaminase deficiency. Ann Neurol 1998;44:140-143.        [ Links ]

8. Kar NC, Pearson CM. Muscle adenylate deaminase deficiency. Report of six new cases. Arch Neurol 1981;38:279-281.        [ Links ]

9. Bruno C, Minetti C, Shanske S, et al. Combined defects of muscle phosphofructokinase and AMP deaminase in a child with myoglobinuria. Neurology 1998;50:296-298.        [ Links ]

10. Ptacek LJ, Johnson KJ, Griggs RC. Genetics and physiology of the myotonic muscle disorders. N Engl J Med 1993;328:482-489.        [ Links ]

11. Koty PP, Pegoraro E, Hobson G, et al. Myotonia and the muscle chloride channel: dominant mutations show variable penetrance and founder effect. Neurology 1996;47:963-968.        [ Links ]

12. Warnstedt M, Sun C, Poser B, et al. The myotonia congenita mutation A331T confers a novel hyperpolarization-activated gate to the muscle chloride channel ClC-1. J Neurosci 2002;22:7462-7470.        [ Links ]

13. Gross M, Rotzer E, Kolle P, et al. A G468-T AMPD1 mutant allele contributes to the high incidence of myoadenylate deaminase deficiency in the Caucasian population. Neuromuscul Disord 2002;12:558-565.        [ Links ]

14. Hoffbuhr K, Devaney JM, LaFleur B, et al. MeCP2 mutations in children with and without the phenotype of Rett syndrome. Neurology 2001;56:1486-1495.        [ Links ]

 

 

Received 14 June 2002, received in final form 15 October 2002
Accepted 4 November 2002

 

 

Dr. Rosana H. Scola - Neuromuscular Disorders Division, Hospital de Clinicas UFPR - Rua General Carneiro 181 - 80069-900 Curitiba PR - Brazil. FAX: 55 41 264 3606. E-mail: scola@hc.ufpr.br