We studied 13 patients with CPEO who had been referred to the UK National Commissioning Group, Rare Mitochondrial Diseases of Adults and Children, diagnostic laboratory in Newcastle upon Tyne (http://www.mitochondrialncg.nhs.uk/). Skeletal muscle biopsies of vastus lateralis (quadriceps) muscle had been obtained after informed consent for diagnostic purposes, and the molecular genetic work-up of these patients followed a published diagnostic algorithm. ¹⁰ Eight patients had single, large-scale mtDNA deletions of various sizes, two had pathogenic mtDNA point mutations (m.3243A>G and m.4298G>A ⁷ ) within tRNA genes, and three patients had multiple mtDNA deletions secondary to a mutation in a nuclear gene: one patient with recessive POLG1 mutations (p.A467T and p.R1096C), one patient with a dominant PEO1 mutation (p.R334Q), and one patient with an as yet unidentified nuclear genetic defect (Table 1). 

All patients were assessed by an experienced multidisciplinary team of neurologists and ophthalmologists to define the clinical phenotype and disease severity. The restriction of eye movements was quantified from −1 to −4, with −1 indicating only mild limitation and −4 indicating the worst impediment, with the eye being unable to move from the primary position of gaze. ¹⁴ Ptosis severity was graded according to the height of the palpebral aperture (PA): severe (PA < 4 mm), moderate (PA 4–6 mm), and mild (PA > 6mm). ¹⁵ Levator muscle samples were obtained at the time of ptosis surgery and medial rectus muscles were resected at the time of strabismus surgery for ocular misalignment. All muscle samples were mounted for sectioning and immediately frozen in isopentane cooled in liquid nitrogen. This study had the relevant institutional ethics approval and complied with the Declaration of Helsinki. 

All muscle samples were subjected to sequential COX/succinate dehydrogenase (SDH) histochemistry according to established diagnostic protocols. ^16,17 For laser microdissection, 20-μm cryostat sections were mounted on PEN (polyethylenenaphthalate) membrane slides (Leica Microsystems, Wetzlar, Germany), subjected to sequential COX/SDH histochemistry, and air-dried after ethanol dehydration. Single muscle fibers were cut into sterile 0.5-mL PCR tubes (Laser Microdissection [AS-LMD] System; Leica Microsystems) and lysed in standard lysis buffer. ¹⁷  

A real-time PCR assay ^13,18 with specific fluorogenic probes (TaqMan; Applied Biosystems, Inc. [ABI], Warrington, UK) was used to determine the relative amplification of mtDNA within the MTND1 and MTND4 genes. The MTND1 region is mostly spared in patients with mtDNA rearrangements, whereas MTND4 is deleted in >97% of all reported cases. ¹⁹ Single-fiber lysates were analyzed in triplicate, and mtDNA deletion level was derived from the proportion of wild-type (MTND4) to total (MTND1) copy number by the established ^ΔΔC_t method. ¹⁸ Total and wild-type copy number were calculated with the standard curve method. For copy number analyses, single COX-positive and COX-deficient fibers were identified on COX/SDH-stained slides and then laser-microdissected from serial sections stained with SDH only. This method was used to ensure that all fibers were processed in the same way. Wild-type mtDNA density was calculated by dividing the copy number by the fiber area (in micrometers squared). 

The accurate m.3243A>G heteroplasmy level was determined with a last-fluorescent-cycle PCR restriction fragment length polymorphism (RFLP) assay. ²⁰ In brief, DNA lysate was amplified with primers H3155-3171 and L3353-3334 (nucleotides numbered according to the revised Cambridge Reference Sequence for human mtDNA ²¹ ) in standard cycling conditions. Samples were subjected to a single cycle of PCR with a FAM- labeled forward primer as follows: initial denaturation at 95°C for 45 seconds, annealing at 61°C for 45 seconds, and extension at 72°C for 1 minute. After digestion at 37°C with HaeIII which recognizes a new restriction site introduced by the m.3243A>G mutation, labeled products were separated (model 3170 Genetic Analyzer System, ABI, analyzed with GeneMapper Software ver. 4.0; ABI). 

Group comparisons were made with unpaired t-tests (Prism ver.4 statistical software; GraphPad, San Diego, CA). 

COX deficiency indicates mitochondrial oxidative dysfunction, and it is a valuable histochemical marker that is used to identify cells harboring deleterious levels of pathogenic mtDNA mutations. ²² In 12 of the 13 CPEO patients studied, we detected a greater proportion of COX-deficient fibers in EOM than in skeletal muscle (Fig. 1). Analysis of the complete data set showed a higher mean percentage of COX-deficient fibers in EOM (38.7% ± 12.3%, mean ± SD) than in skeletal muscle (15.1% ± 9.1%, P < 0.0001, unpaired t-test). This difference was still significant in subgroup analysis, in which only CPEO patients with single mtDNA deletions were considered (EOM, 41.6% ± 10.8%; skeletal muscle, 13.7% ± 9.3%; P < 0.0001, unpaired t-test). 

Since a higher proportion of EOM fibers were COX-deficient compared with skeletal muscle, this variation may be related to the absolute mutational threshold required for COX deficiency in these two tissues. We investigated this hypothesis in laser-microdissected COX-positive and COX-deficient fibers from both muscle groups and determined the mutational load within these single muscle fibers, focusing initially on those patients harboring single, large-scale mtDNA deletions. We investigated 89 COX-positive and 87 COX-deficient skeletal muscle fibers and 59 COX-positive and 50 COX-deficient EOM fibers from four patients (2, 3, 4, and 12; Table 1). The mean percentage mtDNA deletion level was significantly lower in the COX-deficient EOM fibers (80.3% ± 14.6%) than in the COX-deficient skeletal muscle fibers (92.8% ± 5.6%, P < 0.0001, unpaired t-test; Fig. 2). There was no significant difference in the mean percentages of deletion in COX-positive fibers from EOM (17.0% ± 21.9%) and skeletal muscle (24.0% ± 29.7%, P = 0.124, unpaired t-test; Fig. 2). This result implies that a much higher proportion of deleted mtDNA is required to cause COX deficiency in skeletal muscle than in EOM. 

It has been proposed that it may not be the absolute level of deleted mtDNA molecules that determines whether a fiber is COX-negative, but the absolute level of wild-type mtDNA molecules remaining within that fiber. ¹¹ To explore this notion, we used real-time PCR analysis to quantify wild-type mtDNA copy number in individual COX-positive and COX-deficient EOM and skeletal muscle fibers. We laser-microdissected a total of 35 COX-positive and 32 COX-deficient skeletal muscle fibers, and 21 COX-positive and 29 COX-deficient EOM fibers from four patients (2, 3, 4, and 12; Table 1). The analysis showed a marked loss of wild-type mtDNA molecules in COX-deficient fibers from both skeletal muscle (24.2 ± 20.6 copies/μm² in COX-positive fibers, 4.3 ± 3.6 copies/μm² in COX-deficient fibers, P < 0.0001, unpaired t-test), and EOM (34.0 ± 16.1 copies/μm² in COX-positive fibers, 11.2 ± 9.1 copies/μm² in COX-deficient fibers, P < 0.0001, unpaired t-test). We also observed a significantly higher mean wild-type copy number in COX-deficient EOM fibers (11.2 ± 9.1 copies/μm²) than in COX-deficient skeletal muscle fibers (4.3 ± 3.6 copies/μm², P = 0.0002, unpaired t-test), indicating that a higher absolute number of wild-type mtDNA molecules is necessary to maintain normal COX activity in EOM fibers than in skeletal muscle fibers (Fig. 3). There was no significant difference in the mean wild-type copy number in COX-positive EOM fibers (34.0 ± 16.1 copies/μm²) compared with that in COX-positive skeletal muscle fibers (24.2 ± 20.6 copies/μm², P = 0.06, unpaired t-test). 

Of the 13 CPEO patients investigated in this study, only patient 13, who had the m.3243A>G single nucleotide substitution in the MTTL1 gene, did not show a greater proportion of COX-deficient fibers in the EOM than in skeletal muscle. We quantified m.3243A>G mutation levels in both COX-positive (n = 11 EOM; n = 16 skeletal muscle) and COX-deficient (n = 17 EOM; n = 16 skeletal muscle) fibers (Fig. 4). We observed no significant difference in the level of the m.3243A>G mutation in COX-deficient EOM fibers (97.3% ± 4.7%), compared with COX-deficient skeletal muscle fibers (99.1% ± 2.8%, P = 0.2, unpaired t-test), although there was a significantly higher mutational load in COX-positive EOM fibers (65.6% ± 31.5%) compared with COX-positive skeletal muscle fibers (36.1% ± 31.5%, P = 0.009, unpaired t-test; Fig. 4). This finding suggests no difference in the mutation threshold for COX deficiency in EOM compared with skeletal muscle for m.3243A>G. 

The two patients with the least severe EOM restriction (score of −2) both harbored the mtDNA point mutations m.3243G>A and m.4298G>A. The percentage of COX-deficient EOM fibers in the moderate (−2) group was significantly lower than that in the severe (−3/−4) group (23% ± 7. % vs. 41.6% ± 10.8%, P = 0.042, unpaired t-test; Fig. 5A), suggesting a correlation between the level of COX deficiency and ophthalmoplegia score. However, there was no significant association between COX deficiency and ptosis grade (moderate = 43.3% ± 10.6%, severe = 36.7% ± 12.9%, P = 0.395, unpaired t-test; Fig. 5B). 

mtDNA defects are responsible for a heterogeneous group of multisystemic disorders, and the prominent and often restricted EOM involvement in CPEO remains an intriguing pathologic feature. In our study cohort, two patients had a pure CPEO phenotype. Although the remainder had other neurologic features such as myopathy, exercise intolerance, and cerebellar dysfunction, these effects were mostly mild and the greatest impact on these patients' quality of life was due to their marked ophthalmoplegia and ptosis. ²³ Although the underlying mechanisms have not been properly investigated, the discrepancy in clinical severity between EOM and limb muscle has been ascribed to the fundamental differences between these two muscle groups in fiber composition, innervation patterns, and basic contractile physical properties. EOMs have a higher mitochondrial content, ²⁴ higher fatigue resistance, ²⁵ smaller motor units, higher blood flow, ^26,27 and higher motor neuron discharge rates, ²⁸ all of which suggest that they have a more sustained metabolic demand than do skeletal muscles. Our study is the first to directly compare the mitochondrial biochemical defect (COX-deficiency) in EOM and skeletal muscle specimens from patients (n = 13) with a clinical and molecular diagnosis of CPEO. Although COX-deficient muscle fibers accumulate in EOMs during normal aging, ^29,30 the levels of COX deficiency in both skeletal muscle and EOM of patients with CPEO were significantly higher, ³¹ thus highlighting the pathogenic load of these genetic defects in our patient cohort. In 11 of the 13 patients, all of whom had mtDNA deletions, we identified a significantly higher proportion of COX-deficient fibers in EOM than in skeletal muscle. The lower threshold of COX deficiency in the EOMs that was demonstrated in single-fiber analysis, by both mutational load and absolute wild-type copy number analyses, offers a plausible explanation for this finding. 

Two CPEO patients in this study had pathogenic mutations in mtDNA maintenance genes (POLG1 and PEO1) known to cause secondary, multiple mtDNA deletions. ^3,9 These deletions are somatic and accumulate over time. We and others have shown that at the single-cell level, this accumulation is associated with clonal expansion of one, sometimes two, deleted mtDNA species. ^32–34 The threefold greater percentage of COX-deficient fibers in EOM therefore implies that mtDNA deletions accumulate to deleterious levels at a faster rate in EOM fibers than in skeletal muscle fibers. Although this study has shown a lower threshold for COX-deficiency in EOM, other mechanisms could lead to the higher proportion of COX-deficient fibers observed in EOM, such as a higher rate of deletion formation and a faster rate of clonal expansion. These factors are not mutually exclusive, and additional investigations are warranted to clarify their respective contributions. 

Levator palpebrae superioris (n = 11) and medial rectus (n = 2) specimens were analyzed as a single group, as they develop from the same mesodermal precursor cells and share similar histologic features. ^35,36 In the same patient, it is therefore not unreasonable to assume that both of these muscles would harbor comparable proportions of COX-deficient fibers. Compared with patients with mtDNA deletions, the two patients with mtDNA point mutations had less severe limitation of eye movements, and the reduced severity was associated with a lower absolute level of COX deficiency in the EOM samples. However, there was no significant difference in either the percentage of COX-deficient fibers between skeletal muscle and EOM or the threshold for COX deficiency in these two tissues. This result is in marked contrast to the clinical findings, with both patients having severe restriction in their ocular motility compared with only mild proximal limb muscle weakness. These molecular findings indicate that at the cellular level, EOMs are more vulnerable than skeletal muscle when faced with a similar level of metabolic impairment, very likely because of their unique developmental and biological characteristics. 

The results of our study suggest that decreasing the mutational load in EOMs to below the biochemical threshold could lead to a functional benefit by improving the range of eye movements. Potential therapeutic strategies could involve increasing the level of wild-type mtDNA by recruiting EOM satellite cells, which are thought to harbor lower levels of mutant mtDNA, to differentiate into mature myofibers. ^37,38 EOMs are easily accessible, and the proliferation of satellite cells may be induced by injection of specific myotoxic stimuli such as bupivacaine. ³⁹ It is therefore of great interest that in a recent study of patients with diplopia due to lateral rectus palsy, injection of the paretic muscle with bupivacaine led to muscle hypertrophy, increased force generation, and an improvement in ocular alignment. ⁴⁰  

A limitation of our study is the relatively small number of patients investigated and the heterogeneous nature of the underlying genetic defects, although the majority (8/13) had single mtDNA deletions. However, CPEO is a relatively rare condition, and only a select group of patients will undergo corrective strabismus or ptosis surgery during the course of the disease. These factors contribute to the difficulty in obtaining EOM tissues, further compounded by the need for skeletal muscle to allow direct comparative analysis between the two muscle groups. Nevertheless, our study has provided important molecular insights into the selective vulnerability of EOMs in CPEO; future collaborative studies may clarify these basic factors further. A better understanding of the underlying disease process is crucial in developing effective therapeutic strategies for patients with CPEO, a disorder associated with significant morbidity and for which treatment is currently mostly supportive.