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Show Journal of Neuro- Ophthalmology 15( 1): 20- 25, 1995. 1995 Raven Press, Ltd., New York Supranuclear Eye Movement Dysfunction in Mitochondrial Myopathy with tRNALEU Mutation Sudha R. Gupta, M. D., Mitchell Brigell, Ph. D., Meena Gujrati, M. D., and John M. Lee, M. D., Ph. D. A patient with multiple neurological deficits and biopsy-proven mitochondrial myopathy with mutation of tRNALEU at nucleotide 3243 was referred for eye movement evaluation. He had restricted range of voluntary motions in all directions and full range of eye movements on passive rotation of head while fixating a visual target. Eye movement recordings revealed decreased horizontal and vertical saccadic velocities and markedly decreased smooth pursuit gain in both directions. The vestibulo- ocular reflex showed gain abnormalities with many saccadic intrusions on the smooth reflex response. His brother, with similar mutation, was clinically asymptomatic. However, his eye movement recordings revealed slow horizontal saccadic velocities leftward and normal saccadic velocities rightward in both eyes as well as in upward and downward direction. Smooth pursuit and vestibulo- ocular reflexes were within normal limits. Although eye movement abnormalities are seen commonly in mitochondrial myopathies, the exact mechanism is not known. Our cases suggest supranuclear dysfunction as one of the mechanisms for ophthalmopare-sis. Key Words: Mitochondrial myopathy- Ophthalmoplegia- Supranuclear palsy. From the Department of Neurology ( S. R. G., M. B.) and Pathology ( Section of Neuropathology) ( M. G., J. M. L.), VA Hines Hospital, Hines; and Loyola University Medical Center, May-wood, Illinois, U. S. A. Address correspondence and reprint requests to Dr. Sudha R. Gupta, Neurology Service ( 127), VA Hospital, Hines, IL 60141, U. S. A. Mitochondrial encephalomyopathies are a group of disorders due to defects in the mitochondrial metabolism. These disorders usually involve multiple organ systems, often dominated by muscle and brain dysfunction because of a greater dependence of these tissues on oxidative metabolism ( 1,2). Although extraocular muscle dysfunction is very common, the exact mechanism of ophthalmo-paresis in these disorders is not known. Both neuropathic and myopathic processes have been hypothesized ( 3- 11). We report a case of documented mitochondrial myopathy with tRNALEU mutation and his brother with similar mutation. Both had ophthalmoparesis due to supranuclear eye movement dysfunction. CASE REPORTS Casel Case 1 is a 49- year- old right- handed man developed new onset of generalized seizures in February 1992. Recurrent seizures continued in spite of various anticonvulsant therapy. In September 1992, progressive gait difficulty was noted. In January 1993, h e was admitted with urinary retention and fecal impaction. The past history was significant for presence of diabetes mellitus since 1984 and bilateral hearing loss since childhood. There was no family history of seizures, hearing loss, gait disorder, or other significant medical or neurological illness. On examination in June 1993, he was alert with explosive dysarthric speech. The pupils were 4 mm and reacted normally to light and accommodation. Funduscopic examination did not show any abnormality. He had moderate to severe bilateral hearing loss. Diffuse muscle wasting was seen 20 MITOCHONDRIAL MYOPATHY 21 without any focal atrophy, fasciculation, or weakness. The muscle stretch reflexes were hyperactive with bilateral extensor plantar response. Position sense was impaired in toes. He had mild limb ataxia with a wide- based gait. Neuropsychological testing revealed mild mental retardation with superimposed mild dementia. Magnetic resonance imaging of the brain showed diffuse cerebral and cerebellar atrophy, enlarged cisterna magna, and bilateral basal ganglia calcification. An electroencephalogram showed diffuse slowing. Electromyography and nerve conduction studies showed de-myelinating neuropathy. Blood tests revealed hyponatremia, hyperkalemia, decreased aldosterone level, and normal levels of Cortisol, lactate, pyruvate, and very long chain fatty acids. Workup for a systemic malignancy was negative. Sural nerve and quadriceps muscle biopsy was performed. The hematoxylin and eosin stained sections of the muscle revealed marked variation of fiber size, many angulated atrophic fibers, numerous nuclear bags, and a number of the fibers having basophilic stippling in subsarcolemmal areas. Modified Gomori Trichrome stained sections showed numerous FIG. 1. Modified Gomori Trichrome- stained frozen section of a ragged red fiber and angulated muscle fibers ( x200). FIG. 2. Electron micrograph of abnormal paracrystal-line inclusions in muscle mitochondria ( x60,000). ragged red fibers with eosinophilic subsarcolemmal accumulations in approximately 2% of the muscle fibers examined ( Fig. 1). DPNH and cytochrome oxidase stains revealed increased subsarcolemmal staining in scattered fibers. ATPase stains at pH 9.4 and 4.6 revealed atrophic fibers of both types, but no evidence of type grouping or group atrophy was noted. The ultrastructural examination of the muscle revealed numerous subsarcolemmal intramitochondrial paracrystalline inclusions ( Fig. 2). Many of the inclusions showed a " parking lot" configuration. In addition, there were a number of mitochondria with abnormal cristae and concentric inclusions. The sural nerve biopsy revealed mild to focal moderate loss of large myelinated fibers ( Fig. 3). There was some loss of small myelinated and unmyelinated fibers, as well. There was no evidence of inflammation, metachromatic granules, or amyloid deposition. A sample of muscle was sent to Dr. S. DiMauro's laboratory ( Columbia University College of Physicians and Surgeons, New York). Southern blot analysis revealed a point mutation in the tRNA ( LEU [ UUR]) at position 3243, which is associated with / Neuro- Ophthalmol, Vol. 15, No. 1, 1995 22 S. R. GUPTA ET AL. FIG. 3. Epon- embedded osmium stained cross section of sural nerve. Note loss of large and small myelinated fibers ( x400). MELAS ( mitochondrial encephalopathy, lactic acidosis, and strokelike episodes). Clinical examination of eye movements revealed a restricted range of voluntary motion in all directions. Upward gaze was restricted to 20% of full range and downward gaze was restricted to approximately 50% of full range. Horizontal gaze was less affected with both directions of lateral gaze restricted to 70% of full range. Despite the restriction of voluntary gaze, a full range of eye motion was demonstrated when the patient was instructed to fixate at a visual target while his head was passively rotated. All eye movements were conjugate, and alternate cover testing showed the eyes to be orthophoric in all fields of gaze. No pathologic nystagmus was observed and convergence was present. Eye movements were recorded using direct- current electro- oculography ( ICS Medical, Schaumburg IL). Saccadic eye movements were obtained to red light- emitting diode targets that appeared at random time intervals at a random location between 5 and 35 degrees in the left or right visual field. A sample of the patient's horizontal eye movements is shown in Fig. 4. Sac-cades were generally accurate without evidence of dysmetria. However, saccadic velocities were slower than age matched normal data, with only 11.6% of all horizontal saccades reaching normal peak velocities. The extent of the saccadic slowing increased as amplitude of the saccades increased. Vertical saccades showed decreased peak velocity that was similar to that obtained with horizontal movement. Horizontal smooth pursuit was elicited to sinusoidal oscillation of a visual target at frequencies between .2 Hz and .7 Hz over a range of 40 degrees. As can be seen in Fig. 5, pursuit gain was markedly decreased in both horizontal directions for all frequencies of oscillation. Peak eye movement velocity was never greater than 30% of peak target velocity. The patient was not drowsy during the pursuit task and appeared to give max- Horizontal. Eue Posituon Pew. Velocity IJJ Hi- HCEftii, 2tt 4:: flSNQJWLx^ Sijhtwafd • ysHciiM Lef tware" CD i: 5 3 SACCADt flM? LJTUi? E 13 25 FIG. 4. Horizontal saccadic eye movement results. Top: Eye movement recordings. Upward deflections represent rightward movement. Signals are recorded across both eyes ( outer canthus to outer canthus) in the tracing. The solid line indicates target position and the dotted line represents eye position. Bottom: Saccadic peak velocity as a function of saccade amplitude. Each dot represents the velocity of a single sac-cade. The hatched area indicates abnormally slow saccadic velocity relative to an age- matched normal population. / Neuro- Ophtlulmol, Vol. 15, No. 1, 1995 MITOCHONDRIAL MYOPATHY 23 Horizontal Ew Position Frequency^ 8.30 Hz . r^ ekj, riu Gain R Gun- 1.24 L Sain- I. 35 398 A3 Phase Shift= - 15.** 1.25- 5 1. B9 if ft 73- f 19 .25 . '# isas& Rj. gfiT^ 3gT • • " • • • ' • * • . . . • • • • « . ' . " ; • ' ;. :::::::- Jt- KGP^ L. T EgjfSSra 9.7 8. S 8.5 8.+ 8.3 fl. 2 B.£ 3.3 8.4 9.5 TMGtT r£ EHJEKCY C. HZi .6 8.7 CvcLei: 36 FIG. 5. Results of smooth pursuit eye movements. Top: Target position { solid line) and eye position { dotted line) are shown for horizontal sinusoidal target oscillation at 0.3 Hz. Note the low gain of the pursuit eye velocity with many catch- up saccades interposed. Bottom: Mean pursuit gain as a function of leftward and rightward target frequency. The hatched area indicates abnormal gain relative to age- matched normal population. imum effort. Optokinetic nystagmus showed a decreased velocity of both slow and fast phases. The vestibulo- ocular reflex obtained with active head shaking in the vertical and horizontal directions showed gain abnormalities with many saccadic intrusions on the smooth reflex response. Case 2 Case 2 is a 47- year- old brother of Case 1 who has been diabetic since 1986 and has tRNALEU mutation similar to Case 1. Although clinically asymptomatic, his clinical examination revealed left ptosis, which has been present since head trauma at the age of 3 years. Alternate cover testing showed evidence of large exophoria. The patient also held his head with a right head tilt. Pupils were equal in diameter and briskly reactive to light without relative afferent defect. Eye movements were recorded using direct- current electro- oculography. Recordings of horizontal saccadic eye movements showed conjugate slow saccades leftward and normal saccadic velocities rightward OU ( Fig. 6). Recording of vertical eye movements suggested saccadic velocities within normal limits for both upward and downward direction. Smooth pursuit and vestibulo- ocular reflexes were also within normal limits. DISCUSSION Disorders of mitochondrial metabolism can occur due to defects in the transport system across the mitochondrial membrane, defects of substrate utilization, defects in the Kreb's cycle, or defects in the oxidation- phosphorylation system. Mitochondrial encephalomyopathies can also result from specific deficiencies of complex I to IV of the respiratory chain ( 1). Because there are hundreds or thousands of copies of mitochondrial DNA in each cell, the phenotypic expression of a mitochondri-ally encoded gene depends on the relative proportion of the mutant and the wild- type mitochondrial DNA within any given cell. Clinically mitochondrial encephalomyopathies are grouped into various subgroups with considerable overlap ( 12,13). These include MELAS ( 14,15); MERRF ( myoclonus epilepsy with ragged red fiber myopathy) ( 16,17), I Neuro- Ophthnlmol, Vol. 15, No. 1, 1995 24 S. R. GUPTA ET AL. Horiionrai fye Position m m t Lit- L2fl 3 •• 8 l u - r T = T 7 ^ 7 7 = : sea us • A Accuracy l 3 3 i , . : 3 , , - , \ ABNORMAL Llfl i-i HI •- 94 F L' MDSttAL m \ m HightwnT i " Tefti^ rT ; i Jeak Uelocity U u a a- NORMfiL W. 35 35* 25 15 5 " 5 15" SflCCflOE ftMPLITUDE ( DEO :::: n3HCR « lnl/ Leftward 35 Latere « 9- o G J • K itJH- 9 j X v M - X v ' • " • : ! •!•'•!• ' ICvXyJJI- Iv'Xy! !' J* Xv.*! v. .•.'. .•."!" c^ BHGR^ ftL:^::^ >::'-:>•>:>:; \ m m 35 35 fright Ma nT" Leftward' 35 25 IS 5 5 15 25 SACCflDE AHPLITUOE ( DEO 25 15 5 5 15 25 35 SACCftDE AHPLITUDE (& EG> FIG. 6. Horizontal saccadic eye movement parameters for Case 2. Top Left: Slowing of leftward saccades. Top Right: Graphic quantification of this slowing. Bottom: Normal accuracy and latency parameters of horizontal saccades. CPEO ( chronic progressive external ophthalmoplegia), including KSS ( Kearns- Sayer syndrome ( 7); NARP ( neuropathy, ataxia, and retinitis pigmentosa) ( 18); LHON ( Leber's hereditary optic neuropathy) ( 19,20); and Leigh's syndrome ( 21). Recently, deletions, depletions, and mutations of mitochondrial DNA transfer RNA have been documented in these disorders ( 2,22,23). While opthalmoparesis is one of the cardinal features of CPEO and KSS it can be seen in other subgroups, including MELAS ( 24). There has been controversy in the literature regarding whether the ophthalmoplegia observed in mitochondrial myopathies is secondary to abnormality in the eye muscles or is neurogenic. The biopsy of extraocular muscles have shown evidence of myopathic changes or nonspecific degeneration ( 3,9). Atrophy of abducens nerve and neuronal degeneration in oculomotor nucleus have also been reported ( 10,11). Based on these results the mechanism of ophthalmoparesis is considered to be of peripheral origin ( myopathic or neuropathic), even though spongiform changes have also been seen in cortex, white matter, optic radiation, and basal ganglia structures ( 6). Several of the eye movement findings in cases reported here suggest a supranuclear component to the ophthalmoplegia. In Case 1, the range of voluntary movement was restricted, although a full range of motion was obtained by vestibulo-ocular reflex. The dissociation of voluntary and reflex ophthalmoplegia has been classically cited as evidence for a supranuclear component to the ophthalmoplegia ( 25- 27). Another suggestion of a central component to this patient's ophthalmoplegia comes from the asymmetric involvement of vertical and horizontal movement. Jampel and colleagues ( 28) have previously suggested that myopathic involvement of the superior rectus muscle should force the resting position of the eyes into downgaze. They furthermore suggest it is unlikely that a myopathic process would affect the superior rectus while sparing the levator palpebri. Finally, although this patient's saccadic velocity profile does not differentiate myopathic from neurogenic ophthalmoplegia, the relative sparing of saccadic velocity when compared to pursuit velocity is suggestive of a supranuclear disorder. The extraocular muscles were able to move the eyes with a peak velocity of over 300 deg/ s during saccadic eye / Neuro- Ophtlmlmol, Vol. 15, No. 1, 1995 MITOCHONDRIAL MYOPATHY 25 movements ( Fig. 4), yet the eyes could not follow a smooth pursuit target requiring a peak velocity of only 16 deg/ s and much less acceleration of the eye ( Fig. 5). It would be expected that pursuit would be spared relative to saccades in a purely myopathic process. In Case 2 slow leftward saccades in both eyes and normal rightward saccadic velocities indicate a partial left gaze palsy due to dysfunction in the left paramedian pontine reticular formation ( 29). In this patient the normal velocity of right-ward and vertical saccades suggests the absence of significant involvement of the extra- ocular muscles. Thus, supranuclear eye movement dysfunction can precede peripheral involvement in patients with mitochondrial myopathy. In summary, both of these cases have supranuclear dysfunction of eye movements. 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