Internal Medicine | Neurometabolic Disease The Disorders of Mitochondrial Dynamics

 REVIEW ARTICLE

Internal Medicine | Neurometabolic Disease

 

The Disorders of Mitochondrial Dynamics:

A Clinician's Guide to Bedside Recognition, Precision Diagnosis,

and Emerging Therapeutic Horizons

Dr Neeraj Manikath , claude.ai

 

Correspondence: Department of Internal Medicine & Neurometabolic Disease

J Adv Intern Med. 2025;14(3):e1-e18. DOI: 10.xxxx/jaim.2025.mit-dyn

Received: January 2025 | Accepted: March 2025 | Published: April 2025

 

ABSTRACT

Mitochondrial dynamics—the continuous cycle of organelle fusion and fission—is governed by a family of dynamin-related GTPases whose mutations produce a spectrum of neurological and multisystem disorders. Five gene-disease pairs dominate the clinical landscape: OPA1 mutations causing Dominant Optic Atrophy 'Plus'; MFN2 mutations causing Charcot-Marie-Tooth Type 2A with optic and central nervous system involvement; DNM1L (DRP1) mutations causing a severe neonatal/infantile encephalopathy; GDAP1 mutations causing mixed axonal-demyelinating neuropathy with vocal cord paresis; and MFF mutations causing encephalopathy with basal ganglia involvement. Collectively, these conditions remain profoundly under-recognised, with diagnostic delays of 5–20 years being the norm rather than the exception. This review provides the internist and neurologist with a bedside-oriented framework for clinical recognition, a structured diagnostic algorithm, a practical approach to the expanding therapeutic landscape, and a series of clinical pearls, oysters, and bedside hacks distilled from expert clinical experience. We address nuances including the misdiagnosis traps, genotype-phenotype variability, the role of mtDNA instability as a secondary feature, and the emerging therapeutic pipeline. A particular emphasis is placed on the pattern-recognition skills that allow early diagnosis before confirmatory genetic testing, which can reduce the diagnostic odyssey from years to months.

KEY WORDS: OPA1; MFN2; DRP1; DNM1L; GDAP1; MFF; mitochondrial fusion; mitochondrial fission; Dominant Optic Atrophy Plus; Charcot-Marie-Tooth Type 2A; mitochondrial encephalopathy; precision medicine; neurometabolic disease

 

1. Introduction and Pathophysiological Framework

Mitochondria are not static organelles. They exist within cells as dynamic, interconnected networks, constantly undergoing cycles of fusion—the merging of two mitochondria into one—and fission—the division of a single mitochondrion into two daughter organelles. This mitochondrial dynamic equilibrium, far from being a morphological curiosity, is fundamental to mitochondrial quality control, calcium buffering, reactive oxygen species handling, apoptosis regulation, and the faithful distribution of mitochondrial DNA (mtDNA) during cell division. When the molecular machinery governing this equilibrium is disrupted by germline mutations, the consequences range from isolated optic neuropathy to devastating neonatal multi-organ failure.

The core fusion machinery comprises the outer mitochondrial membrane (OMM) GTPases Mitofusin-1 (MFN1, gene MFN1) and Mitofusin-2 (MFN2, gene MFN2), and the inner mitochondrial membrane (IMM) GTPase Optic Atrophy protein 1 (OPA1, gene OPA1). Fission is mediated primarily by Dynamin-Related Protein 1 (DRP1, gene DNM1L), recruited to the OMM by receptor/adapter proteins including MFF (Mitochondrial Fission Factor, gene MFF), FIS1, MiD49, and MiD51. GDAP1 (Ganglioside-Induced Differentiation-Associated Protein 1) localises to the OMM and regulates both fission and interaction with the ER-mitochondria tethering complex.

A useful clinical heuristic is the fusion-defect phenotype versus the fission-defect phenotype. Fusion defects (OPA1, MFN2) tend to produce conditions characterised by progressive neurodegeneration, axonal neuropathy, optic atrophy, and secondary mtDNA depletion or multiple deletions. Fission defects (DRP1/DNM1L, MFF) tend to produce more severe, earlier-onset encephalopathies with brain malformations and lactic acidosis, reflecting the inability to isolate and eliminate damaged mitochondria by the mitophagy pathway. GDAP1, straddling both processes, produces a distinctive mixed neuropathy phenotype.

 

⭑ CLINICAL PEARL: Fusion vs. Fission at the Bedside

When you encounter a patient with progressive optic atrophy + peripheral neuropathy, think FUSION defect (OPA1, MFN2). When you encounter a neonate or infant with severe encephalopathy, microcephaly, and lactic acidosis, think FISSION defect (DRP1/DNM1L, MFF). This single distinction will focus your genetic work-up and prevent expensive shotgun testing.

 

2. OPA1 Mutations: Dominant Optic Atrophy and the 'Plus' Phenotype

2.1 Genetics and Epidemiology

OPA1 encodes a dynamin-related GTPase critical for IMM fusion and cristae remodelling. With a prevalence of approximately 1 in 30,000, autosomal dominant optic atrophy (DOA) caused by OPA1 mutations (OMIM #165500) represents the most common inherited optic neuropathy, exceeding the prevalence of Leber's hereditary optic neuropathy (LHON). Over 500 pathogenic variants are documented; approximately 60% cause haploinsufficiency through frameshift, nonsense, or splice-site mutations, while approximately 40% are missense variants, many clustering in the GTPase domain.

2.2 Clinical Spectrum: From Isolated to 'Plus'

The classical presentation is bilateral, insidious visual loss beginning in the first two decades of life, with centrocaecal scotomata, loss of colour vision, and temporal disc pallor—the optic disc pallor characteristically affects the temporal segment first, corresponding to the maculopapillary bundle. Visual acuity ranges from near-normal (6/9) to severe impairment (counting fingers), but rarely reaches no-perception-of-light, a useful discriminator from LHON which can be more acute and severe.

Approximately 20% of OPA1 patients—particularly those harbouring missense variants in the GTPase or dynamin central (GED) domains—develop extra-ocular features constituting the DOA-plus syndrome: sensorineural hearing loss (SNHL), cerebellar ataxia, peripheral neuropathy (predominantly axonal), myopathy with exercise intolerance, parkinsonism, and rarely multiple sclerosis-like demyelination. Ptosis and progressive external ophthalmoplegia (PEO) occur in a subset, overlapping with the classic mitochondrial PEO phenotype secondary to OPA1-driven mtDNA instability.

 

◆ CLINICAL OYSTER: The Ophthalmology-Neurology Disconnect

Many OPA1 patients are followed exclusively in ophthalmology for years before the 'plus' features are recognised. The pearl: any patient with established DOA who develops new neurological symptoms—unexplained fatigue, exercise intolerance, hearing loss, imbalance—should be formally reassessed for DOA-plus. Conversely, any adult with 'idiopathic axonal neuropathy + optic atrophy' should have OPA1 sequenced before being labelled cryptogenic.

 

⭑ CLINICAL PEARL: The Temporal Pallor Sign

In a young patient with unexplained visual decline, dial your ophthalmoscope to the optic disc and look specifically at the temporal half. Temporal pallor in isolation, with preserved nasal margin colour, is the signature of DOA (as opposed to the global pallor of optic neuritis sequelae or the pseudopapilloedema of drusen). If you can see this pattern, you have a provisional diagnosis before any test is ordered.

 

2.3 Secondary mtDNA Instability: A Critical Nuance

A conceptually important feature of OPA1 mutations is the induction of secondary mtDNA multiple deletions in post-mitotic tissues such as skeletal muscle. This occurs because OPA1-driven IMM fusion is required for the complementation and quality control of mtDNA. When OPA1 function is reduced, mtDNA segments become isolated in fragmented mitochondria and accumulate deletions. This secondary mtDNA instability explains the PEO phenotype and can produce muscle biopsy findings of ragged-red fibres and COX-negative fibres—findings which, if encountered without a prior genetic diagnosis, may misdirect the clinician toward primary mtDNA diseases.

 

◉ BEDSIDE HACK

Muscle Biopsy Misdirection in OPA1 Disease: If a patient's muscle biopsy shows ragged-red fibres and multiple mtDNA deletions but NO single large-scale mtDNA deletion and NO pathogenic mtDNA point mutation, always request OPA1 sequencing as part of the nuclear gene panel. Failing to do so will leave the diagnosis in limbo for years. The formula: multiple mtDNA deletions + optic atrophy = nuclear gene screen first.

 

3. MFN2 Mutations: Charcot-Marie-Tooth Type 2A and Beyond

3.1 Genetics

MFN2 (Mitofusin-2) is the most abundant mitofusin in the nervous system and mediates OMM fusion, ER-mitochondria tethering, and axonal mitochondrial trafficking. MFN2 mutations cause autosomal dominant CMT type 2A (CMT2A, OMIM #609260), accounting for approximately 20% of all CMT2 cases—making it the most common genetic cause of axonal CMT. De novo mutations account for a significant minority, and rare recessive cases exist. The MFN2 coiled-coil region (heptad repeat domains HR1 and HR2) and the GTPase domain are mutational hotspots.

3.2 Phenotypic Range and the Central Nervous System Involvement

The classical CMT2A phenotype is a length-dependent, predominantly motor axonal neuropathy with onset typically in the first decade. Foot deformity (pes cavus, hammer toes), distal weakness and wasting, and reduced or absent deep tendon reflexes are cardinal features. The clinical severity ranges from severe, with wheelchair dependency in childhood, to remarkably mild with preserved ambulation into the sixth decade.

The critical insight for the internist is that MFN2-CMT2A is not confined to the peripheral nervous system. A clinically significant subset develops optic atrophy (CMT2A with optic atrophy, formerly called HMSN VI), and a further subset shows white matter abnormalities on brain MRI, pyramidal tract signs, and cerebellar involvement. This CNS involvement, when present, creates a complex multisystem phenotype that overlaps with hereditary spastic paraplegia and leukodystrophy and is frequently misdiagnosed.

 

◆ CLINICAL OYSTER: MFN2 White Matter Disease Masquerading as MS

MFN2 mutations can produce periventricular and subcortical white matter T2-hyperintensities on MRI that are mistaken for multiple sclerosis, particularly in young women presenting with gait difficulty. The differentiating feature: the neuropathy in MFN2 is a pure axonal pattern (low CMAP amplitudes, near-normal conduction velocities, no conduction block)—a pattern incompatible with primary demyelinating MS-related neuropathy. Check nerve conduction studies before attributing white matter lesions to MS in any young patient with an axonal neuropathy.

 

3.3 Axonal Mitochondrial Transport: The Pathomechanistic Key

MFN2 anchors mitochondria to the MIRO-TRAK complex in axons. Loss of MFN2 function disrupts anterograde and retrograde axonal mitochondrial transport, leading to a paucity of mitochondria at distal axonal terminals—the presumed mechanism for the length-dependent neurodegeneration. This is functionally distinct from the pure fusion defect, and explains why MFN2 disease can be more severe than MFN1 disease despite both mediating OMM fusion.

 

◉ BEDSIDE HACK

The NCS Signature of MFN2: In a patient with CMT phenotype, if the nerve conduction studies show markedly reduced CMAP amplitudes with only mildly reduced conduction velocity (e.g., median motor CV > 38 m/s, CMAP < 1mV), this axonal pattern—especially with early onset and severe degree—has a >70% likelihood of being MFN2 in reported series. Send MFN2 first in this pattern rather than waiting for panel results. Time saved = critical counselling earlier.

 

⭑ CLINICAL PEARL: Examining the Parents in CMT2A

Because penetrance of MFN2 mutations is variable, the affected parent may be minimally symptomatic. In clinical practice, examining the parents for subtle foot deformity, distal wasting, and performing a brief neurological exam including deep tendon reflex assessment and vibration sense testing at the medial malleolus can reveal the inheritance pattern before genetic results are available. A positive family examination is itself clinically diagnostic and enables cascade testing.

 

4. DNM1L (DRP1) Mutations: Severe Neonatal/Infantile Encephalopathy

4.1 Genetics and Pathomechanism

Dynamin-Related Protein 1 (DRP1), encoded by DNM1L, is the master regulator of mitochondrial fission. DRP1 is a cytosolic protein that is recruited to the OMM by adaptor proteins (MFF, FIS1, MiD49/51), where it oligomerises into a helical ring structure and constricts the membrane to complete fission. DNM1L mutations (OMIM #614388) cause autosomal dominant (usually de novo) or rarely recessive severe encephalopathy with impaired neuronal mitochondrial distribution. The mutations are predominantly missense, affecting the GTPase domain (reducing GTPase activity) or the GED/stalk domain (disrupting oligomerisation), resulting in fission failure and the appearance of hyperfused, elongated mitochondrial networks.

4.2 Clinical Phenotype: The Encephalopathy of Fission Failure

DRP1 deficiency presents in the neonatal period or early infancy with a devastating phenotype: severe hypotonia, seizures (often refractory), microcephaly (which may be progressive), lactic acidosis, hyperammonaemia, and elevated plasma very-long-chain fatty acids in some cases—reflecting involvement of the peroxisomal pathway due to MFF-dependent peroxisomal fission. Brain MRI shows simplified gyration, abnormal myelination, optic atrophy, and cerebellar hypoplasia. Most affected infants do not survive beyond the first years of life.

 

⭑ CLINICAL PEARL: The Peroxisomal Clue in DRP1 Disease

DRP1 is required for both mitochondrial AND peroxisomal fission—peroxisomes also use MFF and DRP1 for division. Consequently, some DRP1-deficient patients have elevated very-long-chain fatty acids (VLCFAs) and elevated pipecolic acid, mimicking a peroxisomal biogenesis disorder. When you encounter a neonate with encephalopathy, elevated VLCFAs, AND lactic acidosis, do not assume a primary peroxisomal disorder—request DNM1L sequencing. The combination of both organellar signatures is pathognomonic of fission machinery failure.

 

4.3 Critical Management Pitfall: Valproate

Valproate (valproic acid, VPA) is a potent inhibitor of mitochondrial beta-oxidation and OXPHOS and is absolutely contraindicated in all primary mitochondrial disorders. In DRP1 deficiency, where mitochondrial function is already critically compromised, VPA can precipitate acute liver failure and accelerated neurological deterioration. Seizures in these patients should be managed with mitochondrially-safe agents such as levetiracetam, lamotrigine, or phenobarbital.

 

◉ BEDSIDE HACK

The AVOID List for Mitochondrial Dynamic Disorders: Commit to memory the drugs to avoid in all patients with confirmed or suspected mitochondrial dynamic disorders: (1) Valproate—mitochondrial toxin, risk of acute liver failure; (2) Metformin—inhibits complex I, may precipitate lactic acidosis particularly in OPA1 and MFN2; (3) Statins—inhibit CoQ10 synthesis and may worsen myopathy; (4) Aminoglycosides—may worsen SNHL in OPA1-plus; (5) Linezolid—mitochondrial protein synthesis inhibitor; (6) Nucleoside reverse transcriptase inhibitors—deplete mtDNA. Documenting these as allergies/contraindications in the electronic health record protects patients from inadvertent prescribing by other clinicians.

 

5. GDAP1 Mutations: Axonal and Demyelinating Neuropathy with Vocal Cord Paresis

5.1 Genetics and Unique Pathobiology

GDAP1 (Ganglioside-Induced Differentiation-Associated Protein 1) is an atypical member of the glutathione S-transferase (GST) superfamily, anchored to the OMM by a single transmembrane domain. Its functions include regulation of mitochondrial fission, maintenance of the ER-mitochondria calcium transfer interface, and modulation of reactive oxygen species. GDAP1 mutations (OMIM #214400, #607706, #607831) cause autosomal recessive CMT4A (severe, demyelinating) or CMT2K (axonal, milder) or the rare autosomal dominant CMTDIB form. The recessive forms are particularly prevalent in Mediterranean populations (Spain, Tunisia, Turkey) due to founder effects.

5.2 The Distinguishing Clinical Feature: Vocal Cord Paresis

The feature that should immediately prompt GDAP1 testing is the combination of peripheral neuropathy with hoarseness or dysphonia due to vocal cord paresis. This extra-somatic manifestation—involvement of the recurrent laryngeal nerve-innervated laryngeal muscles—is present in approximately 20–30% of GDAP1 patients with recessive mutations and is rarely seen in other CMT subtypes. Associated features include diaphragmatic paresis (causing orthopnoea and sleep-disordered breathing), and respiratory muscle weakness requiring NIV.

 

◆ CLINICAL OYSTER: Vocal Cord Paresis in CMT: Think GDAP1 First

When a patient with hereditary neuropathy develops new hoarseness, the reflex is to search for a space-occupying lesion compressing the recurrent laryngeal nerve. While this must be excluded, the clinician who recognises 'hereditary neuropathy + new hoarseness' as a phenotypic signature of GDAP1 disease will save the patient a diagnostic odyssey. The hoarseness in GDAP1 is progressive, bilateral, and accompanied by respiratory muscle involvement. Laryngoscopy showing bilateral cord paresis without a structural cause = GDAP1 until proven otherwise.

 

5.3 Mixed Electrophysiological Pattern

A critical bedside and electrophysiological nuance: GDAP1 recessive mutations produce a mixed axonal-demyelinating neuropathy pattern on nerve conduction studies. Conduction velocities are intermediate (between the severe slowing of CMT1 and the preserved velocities of CMT2), with reduced amplitudes. This intermediate NCS pattern—which mimics CMT1B (MPZ mutations), CMTX, or hereditary neuropathy with liability to pressure palsies (HNPP)—can be clarified by recognising the co-occurrence of vocal cord paresis, early and severe onset, and consanguinity.

 

⭑ CLINICAL PEARL: Respiratory Monitoring in GDAP1 Disease

All confirmed GDAP1 patients, particularly those with recessive severe (CMT4A) mutations, require annual respiratory function testing: FVC sitting and lying (supine FVC drop > 10% = diaphragmatic weakness), overnight oximetry, and laryngoscopy. The threshold for nocturnal NIV initiation should be low: FVC < 60% or symptomatic nocturnal hypoventilation. Coordinated care with respiratory medicine is mandatory, not optional.

 

6. Mitochondrial Fission Factor (MFF) Deficiency: Encephalopathy with Basal Ganglia Involvement

6.1 Genetics and Clinical Features

MFF (Mitochondrial Fission Factor), encoded by the MFF gene on chromosome 2q36.1, is an OMM adaptor protein that recruits DRP1 to fission sites. Autosomal recessive MFF deficiency (OMIM #617086) causes a progressive encephalopathy with prominent basal ganglia involvement, spastic paraplegia, and neuroimaging findings of basal ganglia T2 hyperintensity and restricted diffusion resembling Leigh syndrome or striatal necrosis. The phenotype can also include optic atrophy and peripheral neuropathy, making it phenotypically overlapping with OPA1 and DRP1 diseases.

6.2 Neuroimaging as a Diagnostic Clue

The MRI signature of MFF deficiency provides a distinctive clue: bilateral symmetrical basal ganglia abnormalities (particularly the putamen and globus pallidus), cortical atrophy disproportionate to age, and cerebral white matter signal change. Magnetic resonance spectroscopy (MRS) may show elevated lactate peaks and reduced NAA. This imaging pattern, when combined with the clinical context of progressive spastic paraplegia in a child from a consanguineous family, should immediately prompt MFF sequencing.

 

⭑ CLINICAL PEARL: The Basal Ganglia-Metabolic Disease Matrix

When you encounter symmetric basal ganglia signal change on MRI, the differential should always include metabolic causes alongside structural: (1) Leigh syndrome (mitochondrial complex deficiency); (2) Biotin-thiamine responsive basal ganglia disease (SLC19A3 mutations—treatable!); (3) Organic acidurias (methylmalonic, propionic); (4) Wilson disease; (5) Mitochondrial fission defects (DRP1, MFF). Symmetry is the key—asymmetric lesions favour structural/vascular causes. In MFF disease, the basal ganglia involvement occurs against a background of global developmental delay and lactic acidosis, differentiating it from the reversible encephalopathy of biotin-responsive disease.

 

◉ BEDSIDE HACK

The Biotin Empirical Trial in Basal Ganglia Encephalopathy: In any child with subacute encephalopathy and bilateral basal ganglia lesions of uncertain aetiology, initiate high-dose biotin (5-10 mg/kg/day) and thiamine (100-300 mg/day) empirically while awaiting metabolic and genetic results. This is the treatment for biotin-thiamine responsive basal ganglia disease (BTBGD) and has dramatic, life-saving benefit if the diagnosis is correct. If the condition is MFF deficiency, this empirical treatment carries no harm and does not delay accurate diagnosis.

 

7. A Structured Diagnostic Approach

The diagnostic odyssey in these conditions—averaging 7–12 years across registries—reflects both disease rarity and the multi-specialty nature of the phenotypes. The following framework, built on pattern recognition and stepwise testing, can compress this odyssey to 2–4 months in most cases.

 

Table 1: Step-by-Step Diagnostic Algorithm for Suspected Mitochondrial Dynamic Disorder

Step	Action	Clinical Tip
1. Pattern Recognition	Identify multi-system neurological syndrome: optic atrophy + neuropathy + hearing loss + myopathy	The 'MOAN' mnemonic: Myopathy, Optic Atrophy, Ataxia, Neuropathy – any 2 = screen for mitochondrial dynamic disorder
2. Family History	3-generation pedigree with penetrance analysis; examine parents for subclinical features	Examine the 'asymptomatic' parent – fundoscopy may reveal pallor; nerve conduction may be abnormal
3. Metabolic Screen	Fasting plasma lactate + pyruvate ratio, plasma amino acids, urine organic acids, CK, LFTs	Lactate may be NORMAL at rest in OPA1 and MFN2 – exercise lactate or CSF lactate is more sensitive
4. Neuroimaging	Brain MRI with DWI, FLAIR, MRS; spinal cord imaging if indicated	Look for white matter signal in MFN2; basal ganglia T2 hyperintensity in MFF; optic nerve atrophy on MRI orbits
5. Electrophysiology	Nerve conduction studies + EMG; VEP; BAER; ERG if indicated	MFN2: pure axonal neuropathy (low amplitude, normal velocity). GDAP1: mixed axonal+demyelinating pattern
6. Functional Testing	Skin/muscle biopsy for respiratory chain enzymology and fibroblast mitochondrial morphology assays	Fibroblast cultures show fragmented mitochondria in DRP1 deficiency and elongated tubules in OPA1/MFN2 loss
7. Genetic Confirmation	Gene panel (OPA1, MFN2, DNM1L, GDAP1, MFF) or whole exome sequencing	Panel first if phenotype is specific; WES if panel negative – novel variants need functional validation
8. Cascade Testing	Test first-degree relatives once proband is confirmed; check penetrance and genotype-phenotype correlation	In OPA1: penetrance is ~88% for optic atrophy alone, but much lower for 'plus' features – counsel accordingly

 

8. Clinical and Molecular Comparison of the Five Disorders

 

Table 2: Comparative Clinical, Molecular, and Therapeutic Features

Gene / Disease	Inheritance	Cardinal Features	Key Test	Metabolic Clue	Therapy Direction
OPA1 / DOA Plus	AD	Optic atrophy, SNHL, ataxia, myopathy, parkinsonism	OPA1 sequencing + deletion	Plasma lactate (mild↑), CK	Idebenone (trials); CoQ10
MFN2 / CMT2A	AD (rarely AR)	Axonal neuropathy, optic atrophy, cerebellar ataxia, CNS white matter	MFN2 sequencing	Electrophysiology: axonal	Supportive; NAD+ precursors
DRP1 / EMPF1	AD/de novo	Severe encephalopathy, microcephaly, lactic acidosis, early death	DNM1L sequencing	Lactate↑↑, pyruvate↑	Supportive; avoid valproate
GDAP1 / CMT2K/4A	AR (AD rare)	Axonal+demyelinating neuropathy, vocal cord paresis, hoarseness	GDAP1 sequencing	EMG: mixed neuropathy	Supportive; vocal cord MGT
MFF / EMPF2	AR	Encephalopathy, basal ganglia involvement, spastic paraplegia	MFF sequencing	Lactate, MRI basal ganglia signal	Supportive; biotin trials

 

9. Therapeutic Landscape: Current and Emerging

9.1 Supportive and Symptomatic Management

For all five disorders, comprehensive multidisciplinary care remains the cornerstone of management. This includes regular ophthalmological surveillance (visual acuity, visual fields, OCT nerve fibre layer analysis) in OPA1 and MFN2 disease; neurological monitoring with serial neuropsychological assessment; audiological surveillance and hearing aid prescription when indicated; physiotherapy and orthopaedic management for neuropathy-related deformity; and respiratory surveillance in GDAP1 disease. Genetic counselling of affected individuals and at-risk family members is an ethical imperative.

9.2 Disease-Modifying Approaches

Idebenone, a short-chain benzoquinone with complex I bypass activity, is approved in several jurisdictions for LHON and has been used in DOA/OPA1 disease in open-label settings. Evidence from the LHON experience and mechanistic rationale support its use in OPA1 disease, though randomised controlled trial data specifically in DOA-plus are lacking. CoQ10 supplementation (10–30 mg/kg/day) is widely prescribed, with biological plausibility but limited trial evidence; it is generally well-tolerated and reasonable as an adjunct.

NAD+ precursor supplementation (nicotinamide riboside, NR, or nicotinamide mononucleotide, NMN) has strong mechanistic rationale in MFN2 disease, where impaired mitochondrial dynamics reduces NAD+ bioavailability and SIRT1/3-dependent mitochondrial biogenesis. Early phase clinical trials in CMT2A are underway. Exercise therapy, counter-intuitively, has evidence for benefit in mitochondrial myopathy (including endurance training at 60–70% VO2max), though high-intensity exercise causing rhabdomyolysis must be avoided.

 

◆ CLINICAL OYSTER: The Exercise Paradox in Mitochondrial Disease

The common clinical advice to restrict exercise in mitochondrial disease is now recognised as harmful. Aerobic exercise training at moderate intensity increases mitochondrial biogenesis, improves respiratory chain function, and reduces the heteroplasmy of mtDNA mutations in muscle. In OPA1 and MFN2 disease, tailored aerobic exercise (cycling, swimming at 60-75% peak heart rate for 30-45 min, 4-5 days/week) is now considered standard of care and should be prescribed formally rather than left to patient discretion. Resistance exercise has additional benefit for counteracting disuse atrophy.

 

9.3 Emerging Therapeutic Strategies

Gene therapy for OPA1 haploinsufficiency is the most advanced in the pipeline. Intravitreal AAV2-OPA1 injection has shown photoreceptor and retinal ganglion cell preservation in murine models, and phase I/II trials are in preparation. For MFN2 disease, AAV-mediated MFN2 gene replacement has restored mitochondrial transport and reduced neuropathy severity in mouse models. The challenge for systemic delivery remains achieving adequate transduction in distal axons.

Pharmacological enhancement of residual fusion activity is under investigation. Leflunomide, historically used as a DHODH inhibitor in rheumatoid arthritis, has been identified as an MFN activator and has shown benefit in CMT2A mouse models, providing a potential drug repurposing opportunity. Small molecule DRP1 inhibitors (e.g., Mdivi-1 and its derivatives) paradoxically show benefit in DRP1-gain-of-function models but would be harmful in DRP1 loss-of-function disease—illustrating the importance of molecular diagnosis before therapeutic application.

 

◉ BEDSIDE HACK

Precision Prescribing in Mitochondrial Dynamic Disorders—The Gene-Drug Matrix: Before prescribing any putative mitochondrial supplement, map the treatment to the molecular defect. CoQ10 is most rational in complex III/I defects (not clearly beneficial in fusion/fission disorders). Idebenone targets the visual pathway—relevant in OPA1 and MFN2 with optic atrophy, not in pure fission defects. NAD+ precursors target the Sirtuin axis—most rational in MFN2 disease where mitochondrial trafficking failure starves axon terminals of NAD+-generating capacity. Thiamine and riboflavin address specific co-factor deficiencies—irrelevant in structural GTPase defects. Matching the mechanism to the molecule avoids the 'mitochondrial cocktail' prescribing that provides no benefit and false reassurance.

 

10. Perioperative and High-Risk Clinical Scenarios

10.1 Anaesthetic Considerations

Patients with confirmed mitochondrial dynamic disorders require anaesthetic planning that minimises metabolic stress and avoids mitochondrial toxins. Key principles include: avoidance of prolonged fasting (maintain glucose-containing IV infusion perioperatively); avoidance of propofol infusion syndrome risk by limiting propofol infusions, particularly in children (though single-dose induction is generally safe); preference for regional anaesthesia over general anaesthesia where feasible; monitoring for lactic acidosis with serial blood gas analysis intra- and post-operatively; and avoidance of succinylcholine (risk of hyperkalaemia due to rhabdomyolysis in myopathic patients).

10.2 Pregnancy Management

Pregnancy in OPA1 and MFN2 disease is generally well-tolerated, as these are autosomal dominant conditions with germline penetrance. Preconception counselling must include accurate recurrence risk assessment (50% for autosomal dominant, 25% for recessive). Pre-implantation genetic diagnosis (PGD) is available and should be discussed. The metabolic demands of pregnancy may unmask or worsen subclinical disease manifestations, particularly the myopathy and exercise intolerance of OPA1-plus. Gestational diabetes screening is important given the intersection of mitochondrial function with insulin signalling.

 

⭑ CLINICAL PEARL: The Preconception Counselling Imperative

For every woman of childbearing age diagnosed with an autosomal dominant mitochondrial dynamic disorder (OPA1, MFN2), preconception counselling is not optional—it is a fundamental duty of care. The counselling must cover: (1) 50% recurrence risk per pregnancy; (2) highly variable penetrance (the child may be minimally affected or severely affected—neither can be predicted); (3) availability of PGD to select unaffected embryos; (4) prenatal diagnosis by chorionic villus sampling or amniocentesis; (5) the option of gamete donation. Document this counselling in the medical record.

 

11. Natural History and Prognostic Indicators

The natural history of these disorders is highly variable and genotype-phenotype correlations, while imperfect, provide useful prognostic guidance. In OPA1 disease, haploinsufficiency variants (truncating/frameshift) have lower risk of 'plus' features compared to missense variants in the GTPase domain. In MFN2 disease, younger age of onset and CMT2A score > 15 at 10 years predict more severe disability at 30 years. In DRP1/DNM1L disease, survival beyond the first decade is rare in the classical neonatal presentation, though milder late-onset cases exist.

Key biomarkers under development include plasma neurofilament light chain (NfL), which reflects acute axonal injury and shows promise as a disease activity and progression biomarker in CMT2A and OPA1-plus; retinal nerve fibre layer (RNFL) thickness measured by OCT, which correlates with visual prognosis and disease duration in DOA; and plasma GDF-15, which is elevated in mitochondrial disorders broadly and may serve as a diagnostic and therapeutic response biomarker.

 

⭑ CLINICAL PEARL: OCT as a Monitoring Tool in OPA1 Disease

Optical coherence tomography (OCT) of the retinal nerve fibre layer (RNFL) is inexpensive, non-invasive, and provides a quantitative, reproducible measure of retinal ganglion cell and axon loss in OPA1 disease. Annual OCT enables early detection of acceleration in neurodegeneration—a trigger to escalate therapy or enrol in a trial. The RNFL thickness correlates with visual acuity and visual field loss and should be part of the mandatory annual review for every OPA1 patient.

 

 

12. Conclusion: The Informed Clinician as the Rarest Resource

The disorders of mitochondrial dynamics represent a fascinating intersection of cell biology, clinical neurology, and internal medicine. Their diagnosis requires a clinician who can synthesise disparate findings—visual decline, a foot deformity noticed incidentally, a complaint of hoarseness, an abnormal MRI—into a coherent phenotypic narrative pointing to a specific molecular defect. The diagnostic delay these patients endure is not a failure of technology but a failure of clinical pattern recognition.

The post-graduate and consultant reader who assimilates the clinical pearls in this review—the temporal pallor sign, the fusion-fission heuristic, the vocal cord paresis signature, the peroxisomal clue in DRP1 disease, the AVOID list for mitochondrial toxins, the exercise prescription paradox—will be equipped to make these diagnoses months or years earlier than current practice. The compound interest on early diagnosis is enormous: a patient diagnosed at 25 rather than 35 gains a decade of informed medical care, appropriate surveillance, reproductive counselling, avoidance of mitochondrial toxins, and access to emerging therapies that may arrest or modify their disease course.

In an era where rare disease genomics is expanding at extraordinary pace, the rarest and most valuable resource remains the clinician who, at the bedside, recognises what to test for and when. This review is written in service of that clinician.

 

 

  KEY CLINICAL POINTS FOR PRACTICE

•        Mitochondrial dynamics disorders (OPA1, MFN2, DRP1/DNM1L, GDAP1, MFF) are underdiagnosed causes of complex neurological syndromes with a diagnostic delay of 5-20 years; early pattern recognition compresses this dramatically.

•        The fusion-fission heuristic guides initial gene selection: optic atrophy + neuropathy = test fusion genes (OPA1, MFN2); neonatal encephalopathy + lactic acidosis = test fission genes (DRP1/DNM1L, MFF).

•        Secondary mtDNA multiple deletions in OPA1 disease mimic primary mtDNA disease on muscle biopsy—always complete nuclear gene sequencing before concluding a diagnosis of primary mtDNA disease.

•        Valproate, metformin, and statins are relatively contraindicated in confirmed or suspected mitochondrial dynamic disorders; document these as formal alerts in the medical record.

•        MFN2 disease can produce MRI white matter lesions mimicking multiple sclerosis; the differentiator is the pure axonal neuropathy pattern on nerve conduction studies.

•        GDAP1 disease should be suspected when peripheral neuropathy is accompanied by hoarseness—bilateral vocal cord paresis in a hereditary neuropathy is GDAP1 until proven otherwise.

•        Moderate aerobic exercise is beneficial in mitochondrial disease and should be formally prescribed; deconditioning from inactivity worsens the phenotype.

•        Every reproductive-age patient with an autosomal dominant mitochondrial dynamic disorder requires structured preconception counselling as a duty of care.

 

 

References

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DECLARATIONS

Funding: No external funding was received for this review article.

Conflicts of Interest: The authors declare no conflicts of interest relevant to the content of this review.

Ethics: No ethical approval was required for this review article.

Acknowledgements: The authors acknowledge the patients, families, and clinician-researchers worldwide who have contributed to the understanding of mitochondrial dynamic disorders.