Expanding the ataxia with oculomotor apraxia type 4 phenotype.

Ataxia with oculomotor apraxia type 4 (AOA4) is an autosomal recessive (AR) disorder recently delineated in a Portuguese cohort and caused by mutations in the PNKP (polynucleotide kinase 3'-phosphatase) gene.(1) AOA4 is a progressive, complex movement disorder that includes hyperkinetic features, eye movement abnormalities, polyneuropathy, varying degrees of cognitive impairment, and obesity. PNKP mutations were initially discovered to be the cause of the severe nonprogressive syndrome microcephaly, early-onset intractable seizures, and developmental delay (MCSZ).(2) Here we describe a patient with compound heterozygous PNKP mutations presenting with an AOA4 phenotype. New features that we report include both mutations, presence of chorea, absence of oculomotor apraxia (OMA), and slow disease progression.

Ataxia with oculomotor apraxia type 4 (AOA4) is an autosomal recessive (AR) disorder recently delineated in a Portuguese cohort and caused by mutations in the PNKP (polynucleotide kinase 3′-phosphatase) gene.[1] AOA4 is a progressive, complex movement disorder that includes hyperkinetic features, eye movement abnormalities, polyneuropathy, varying degrees of cognitive impairment, and obesity. PNKP mutations were initially discovered to be the cause of the severe nonprogressive syndrome microcephaly, early-onset intractable seizures, and developmental delay (MCSZ).[2] Here we describe a patient with compound heterozygous PNKP mutations presenting with an AOA4 phenotype. New features that we report include both mutations, presence of chorea, absence of oculomotor apraxia (OMA), and slow disease progression.

Case description.

The patient, a 28-year-old Swedish woman, was affected by insidious dystonia and chorea since the age of 5 (video at Neurology.org/ng). These hyperkinesias receded spontaneously over time. Learning disabilities were noticed during primary school and an assessment at age 12 concluded that the patient met the criteria for pervasive developmental disorder, which motivated attendance at a special school. From this point, progressive ataxia was documented. At age 15, progressive weakness and areflexia were found. Electroneurography 2 years later revealed widespread sensorimotor polyneuropathy, which was more severe in her legs. This predominant feature led to finger contractures, distal muscle wasting, and bilateral foot drop necessitating the use of foot orthosis. Gait has become severely impaired over time; the patient has depended on a wheelchair for mobility since the age of 25 and is able to walk only with support. A recent examination yielded a Scale for the Assessment and Rating of Ataxia score of 22.5 and an Inventory of Non-Ataxia Symptoms score of 5. Leg weakness and complete loss of proprioception and vibration in the feet are evident upon examination. Eye examination revealed broken smooth pursuit and nystagmus but absence of OMA; video-oculography found increased saccade latency. The patient went through a gastric binding procedure 4 years ago because of obesity. Her body mass index then was 39.4 and decreased to 30.1 postsurgery. Hypoalbuminemia and hypercholesterolemia were present before this procedure; 2 years ago a mild elevation of α-fetoprotein (AFP) was found but her immunoglobulin levels were normal (table e-1). Treatment with simvastatin was started and the patient was recommended a protein-enriched diet. Brain MRIs at ages 17 and 28 displayed progressive cerebellar atrophy (figure 1). Polyglutamine spinocerebellar ataxias and Friedreich ataxia were ruled out first. Colony-stimulating assay, Western blot of the ataxia-telangiectasia mutated (ATM) protein, sequencing, and multiplex ligation-dependent probe amplification analysis of the APTX and SETX genes were normal, ruling out ataxia telangiectasia (AT), AOA1, and AOA2. Whole-exome sequencing of the patient and her parents revealed 2 new compound heterozygous variants, c.1196T>C (p.Leu399Pro) and c.1385G>C (p.Arg462Pro), in the kinase domain of the PNKP gene (supplemental data, figure e-1). Both variants were confirmed by Sanger sequencing and predicted to be pathogenic by an in silico analysis. Reduced cellular levels of PNKP protein were found in Epstein-Barr virus–transformed lymphocytes derived from the patient (figure e-2).

Figure 1

Midsagittal T1-weighted brain MRI from a 28-year-old woman affected by ataxia with oculomotor apraxia type 4

This section displays moderate cerebellar atrophy but no evidence of brainstem atrophy.

Discussion.

Phenotype heterogeneity in AOA4 is similar to that in other diseases in the AOA disease spectrum.[3] All the patients described in the Portuguese cohort displayed ataxia, predominant polyneuropathy, OMA, and cerebellar atrophy.[1] Some also had brainstem atrophy. However, there are some unique features in AOA4. For instance, dystonia that receded completely over time was the first symptom in the Portuguese patients and in our patient. Extrapyramidal hyperkinesias are usually persistent in the AOA disease spectrum. In our patient, the presence of chorea and the absence of OMA are described for the first time in AOA4. Also of note in our patient is the slower disease progression rate: time to wheelchair was 20 years compared to the average of 13 years in the Portuguese cohort.[1] Some patients with AOA4 had laboratory abnormalities found in both AOA1 and AOA2, such as hypercholesterolemia, hypoalbuminemia, and elevated AFP levels. What also makes AOA4 different from other AOA diseases is the striking presence of obesity in some, as also seen in our patient (tables e-2 and e-3). AOA4 is the second most common AR ataxia disorder in Portugal; its prevalence in other countries is still unknown.[1] Like other genes in the AOA disease spectrum, the PNKP gene encodes a DNA-repairing enzyme.[2,4,5] Despite this and in contrast to AT, there is no evidence of increased risk for malignancies or immunodeficiency in those with PNKP mutations. In AT there is a correlation between ATM activity and phenotype severity.[6] Whether this is also the case in PNKP mutations remains to be studied. Similar to MCSZ, we found reduced levels of PNKP protein in AOA4.[2] All mutations associated with AOA4 are located in the kinase domain of PNKP. Only 2 cases with the same homozygous mutation (c.1250_1266dup) in this region have been described: in 1 case it was associated with MCSZ and in a second it was associated with combined features of MCSZ and AOA4.[2,7] The remaining mutations associated with MCSZ are located in the forkhead and phosphatase domains.