Mitochondrial Short-Chain Enoyl-Coa Hydratase 1 Deficiency

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2021-01-18

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Summary

Clinical characteristics.

Mitochondrial short-chain enoyl-CoA hydratase 1 deficiency (ECHS1D) represents a clinical spectrum in which several phenotypes have been described:

The most common phenotype presents in the neonatal period with severe encephalopathy and lactic acidosis and later manifests Leigh-like signs and symptoms. Those with presentation in the neonatal period typically have severe hypotonia, encephalopathy, or neonatal seizures within the first few days of life. Signs and symptoms typically progress quickly and the affected individual ultimately succumbs to central apnea or arrhythmia.
A second group of affected individuals present in infancy with developmental regression resulting in severe developmental delay.
A third group of affected individuals have normal development with isolated paroxysmal dystonia that may be exacerbated by illness or exertion.

Across all three groups, T₂ hyperintensity in the basal ganglia is very common, and may affect any part of the basal ganglia.

Diagnosis/testing.

The diagnosis of ECHS1D is established in a proband by the identification of biallelic pathogenic variants in ECHS1 on molecular genetic testing or low short-chain enoyl-CoA hydratase (SCEH) activity using cultured skin fibroblasts.

Management.

Treatment of manifestations: Treatment of severe metabolic acidosis with bicarbonate therapy; hyperammonemia (which may be related to severe acidosis or low ATP from impaired aerobic oxidation) may be addressed by treatment of the metabolic acidosis and/or consideration of hemodialysis. Inadequate nutrition may require feeding therapy; placement of a feeding tube may be considered. Paroxysmal dystonia may respond to benzodiazepines, whereas chronic dystonia may require botulinum toxin injections. Treatment of dystonia with levodopa may also be considered. Standard treatment for seizures, cardiomyopathy, pulmonary hypertension, optic atrophy, sensorineural hearing loss, and developmental delay.

Surveillance: At least annual echocardiogram, dilated eye examination, and audiologic evaluation. Routine monitoring for neurologic symptoms and developmental issues. Assessment of acid/base status and blood lactate level with all illnesses or metabolic stressors.

Agents/circumstances to avoid: Mitochondrial toxins (i.e., valproic acid, prolonged propofol infusions); ketogenic diet.

Genetic counseling.

ECHS1 deficiency is inherited in an autosomal recessive manner. At conception, each sib of an affected individual has a 25% chance of being affected, a 50% change of being an asymptomatic carrier, and a 25% chance of being unaffected and not a carrier. Carrier testing for at-risk relatives, prenatal testing for a pregnancy at increased risk, and preimplantation genetic testing are possible if the ECHS1 pathogenic variants in the family are known.

Diagnosis

No consensus clinical diagnostic criteria for ECHS1 deficiency (ECHS1D) have been published.

Suggestive Findings

Mitochondrial short-chain enoyl-CoA hydratase 1 deficiency (ECHS1D) should be suspected in individuals with clinical features of Leigh syndrome and/or exercise-induced dystonia who have supportive brain MRI and biochemical findings, including early-onset lactic acidosis.

Clinical features

Neurologic
- Developmental delay, often severe [Sakai et al 2015, Tetreault et al 2015, Huffnagel et al 2018, Aretini et al 2018]
- Infantile encephalopathy (may be epileptic), hypotonia, and/or spasticity [Ferdinandusse et al 2015, Haack et al 2015, Bedoyan et al 2017, Aretini et al 2018]
- Dystonia (exercise induced) and/or choreoathetotic movements [Korenke et al 2016, Olgiati et al 2016, Mahajan et al 2017]
Growth. Failure to thrive, which may present prenatally as intrauterine growth restriction and/or oligohydramnios in the most severe cases [Ganetzky et al 2016, Bedoyan et al 2017]
Cardiorespiratory
- Hypertrophic or dilated cardiomyopathy [Haack et al 2015, Ganetzky et al 2016, Nair et al 2016, Nouguès et al 2017]
- Pulmonary hypertension [Ferdinandusse et al 2015]
Ophthalmologic
- Optic atrophy [Haack et al 2015, Aretini et al 2018]
- Nystagmus [Tetreault et al 2015]
- Glaucoma [Ferdinandusse et al 2015]
- Strabismus [Aretini et al 2018]
- Corneal clouding [Ganetzky et al 2016]
Other
- Sensorineural hearing loss [Haack et al 2015, Tetreault et al 2015]
- Nonspecific dysmorphic features or structural abnormalities (no consistent pattern has emerged) [Haack et al 2015, Ganetzky et al 2016]

Brain MRI findings

T₂ hyperintense signal in the basal ganglia (especially putamen and globus pallidus) [Ferdinandusse et al 2015, Haack et al 2015, Tetreault et al 2015, Korenke et al 2016]
Cerebral atrophy [Ferdinandusse et al 2015, Huffnagel et al 2018]
Agenesis or thinning of the corpus callosum [Ferdinandusse et al 2015, Haack et al 2015, Ganetzky et al 2016]
High lactate with normal lactate to pyruvate ratio peak on MR-spectroscopy [Peters et al 2014, Haack et al 2015, Tetreault et al 2015]

Biochemical features

Lactic acidosis. Pyruvate may be mildly elevated, elevated proportionally to the lactate, or normal [Ferdinandusse et al 2015, Sakai et al 2015, Ganetzky et al 2016, Bedoyan et al 2017].
Abnormal urine organic acids, including elevations of:
- 2-methyl-2,3-dihydoxybutyrate [Ferdinandusse et al 2015, Haack et al 2015, Bedoyan et al 2017]
- Branched-chain ketoacids [Bedoyan et al 2017]
- 3-hydroxyisovalerate [Huffnagel et al 2018]
- 3-methylglutaconic acid, ketones, and lactate [Bedoyan et al 2017]
Elevations of urine acryloyl-cysteamine, acryloyl-l-cysteamine, N-acetyl-acryloyl-cysteine, methacryl-cysteamine, methacryl-cysteamine, or N-acetyl-methacryl-l-cysteamine [Peters et al 2014, Peters et al 2015, Yamada et al 2015, Huffnagel et al 2018]
While plasma acylcarnitine profile is often normal, slight elevations of C4 acylcarnitines may be seen [Ganetzky et al 2016, Nair et al 2016, Bedoyan et al 2017].
If performed, muscle or fibroblast electron transport chain function (ETC) is typically normal, although mild decreases in complex I, III, IV, or multiple complexes, with residual activity above 30% of control function, can be seen [Haack et al 2015, Sakai et al 2015, Tetreault et al 2015, Bedoyan et al 2017, Aretini et al 2018, Fitzsimons et al 2018].

Note: Muscle biopsy is not required to make a diagnosis of ECHS1D.

Establishing the Diagnosis

The diagnosis of ECHS1D is established in a proband by identification of biallelic pathogenic variants in ECHS1 on molecular genetic testing (see Table 1).

Molecular genetic testing approaches can include a combination of gene-targeted testing (single-gene testing or multigene panel) and comprehensive genomic testing (exome sequencing, exome array, genome sequencing) depending on the phenotype.

Gene-targeted testing requires that the clinician determine which gene(s) are likely involved, whereas genomic testing does not. Because the phenotype of ECHS1D is broad, individuals with the distinctive biochemical findings described in Suggestive Findings are likely to be diagnosed using gene-targeted testing (see Option 1), whereas those with a phenotype indistinguishable from many other inherited disorders with lactic acidosis, Leigh syndrome, and/or dystonia are more likely to be diagnosed using genomic testing (see Option 2).

Option 1

When the phenotypic and laboratory findings suggest the diagnosis of ECHS1D, molecular genetic testing approaches can include single-gene testing or use of a multigene panel:

Single-gene testing. Sequence analysis of ECHS1 detects small intragenic deletions/insertions and missense, nonsense, and splice site variants; typically, exon or whole-gene deletions/duplications are not detected. Perform sequence analysis first. If only one or no pathogenic variant is found, perform gene-targeted deletion/duplication analysis to detect intragenic deletions or duplications.
A mitochondrial disease, Leigh syndrome, or lactic acidosis multigene panel that includes ECHS1 and other genes of interest (see Differential Diagnosis) is most likely to identify the genetic cause of the condition at the most reasonable cost while limiting identification of variants of uncertain significance and pathogenic variants in genes that do not explain the underlying phenotype. Note: (1) The genes included in the panel and the diagnostic sensitivity of the testing used for each gene vary by laboratory and are likely to change over time. (2) Some multigene panels may include genes not associated with the condition discussed in this GeneReview. (3) In some laboratories, panel options may include a custom laboratory-designed panel and/or custom phenotype-focused exome analysis that includes genes specified by the clinician. (4) Methods used in a panel may include sequence analysis, deletion/duplication analysis, and/or other non-sequencing-based tests.
For an introduction to multigene panels click here. More detailed information for clinicians ordering genetic tests can be found here.

Option 2

When the phenotype is indistinguishable from many other inherited disorders characterized by early epileptic encephalopathy, Leigh Syndrome, or lactic acidosis, comprehensive genomic testing (which does not require the clinician to determine which gene[s] are likely involved) is the best option. Exome sequencing is most commonly used; genome sequencing is also possible.

If exome sequencing is not diagnostic (particularly if only one pathogenic variant has been identified), an exome array (when clinically available) may be considered to detect (multi)exon deletions or duplications that cannot be detected by sequence analysis.

For an introduction to comprehensive genomic testing click here. More detailed information for clinicians ordering genomic testing can be found here.

Table 1.

Molecular Genetic Testing Used in ECHS1 Deficiency

Gene ¹	Method	Proportion of Probands with Pathogenic Variants ² Detectable by Method
ECHS1	Sequence analysis ³	30/31
ECHS1	Gene-targeted deletion/duplication analysis ⁴	1/31 ⁵

1.: See Table A. Genes and Databases for chromosome locus and protein.
2.: See Molecular Genetics for information on allelic variants detected in this gene.
3.: Sequence analysis detects variants that are benign, likely benign, of uncertain significance, likely pathogenic, or pathogenic. Variants may include small intragenic deletions/insertions and missense, nonsense, and splice site variants; typically, exon or whole-gene deletions/duplications are not detected. For issues to consider in interpretation of sequence analysis results, click here.
4.: Gene-targeted deletion/duplication analysis detects intragenic deletions or duplications. Methods used may include quantitative PCR, long-range PCR, multiplex ligation-dependent probe amplification (MLPA), and a gene-targeted microarray designed to detect single-exon deletions or duplications.
5.: One affected individual had a larger deletion that included ECHS1 and adjacent genes [Aretini et al 2018].

Clinical Characteristics

Clinical Description

Mitochondrial short-chain enoyl-CoA hydratase 1 deficiency (ECHS1D) has been reported in 40 individuals representing 31 families [Peters et al 2014, Ferdinandusse et al 2015, Haack et al 2015, Sakai et al 2015, Yamada et al 2015, Ganetzky et al 2016, Nair et al 2016, Olgiati et al 2016, Al Mutairi et al 2017, Balasubramaniam et al 2017, Bedoyan et al 2017, Mahajan et al 2017, Fitzsimons et al 2018]. ECHS1D represents a clinical spectrum in which several phenotypes have been described. The most common phenotype is presentation in the neonatal period with severe encephalopathy and lactic acidosis and later-onset Leigh-like signs and symptoms. A small number of affected individuals have normal development, exercise-induced dystonia, and basal ganglia abnormalities on MRI [Olgiati et al 2016, Mahajan et al 2017].

Age of onset is soon after birth in a majority of reported individuals (median age of onset: 1 day; range 1 day - 8 years, n=40); only five reported individuals have presented after the first year of life. In five affected individuals, prenatal signs (intrauterine growth restriction and/or oligohydramnios) were identified; two of those individuals were born prematurely [Ganetzky et al 2016, Nair et al 2016, Fitzsimons et al 2018].

Common clinical manifestations are summarized in Table 2 and discussed below.

Table 2.

Common Clinical Manifestations of ECHS1 Deficiency

Clinical Manifestation		Frequency
Neurologic ¹	Signal abnormalities in the basal ganglia	28/32 (88%)
	Developmental delay	27/32 (84%)
	Hypotonia	21/30 (70%)
	Dystonia	15/29 (52%)
	Seizures	12/23 (52%)
	Encephalopathy	12/31 (39%)
	Ataxia/choreoathetosis	5/25 (20%)
Growth	Failure to thrive	20/32 (62%)
	Microcephaly	7/30 (23%)
	Intrauterine growth restriction	5/27 (18%)
Cardiovascular	Cardiomyopathy	9/15 (60%)
Cardiovascular	Pulmonary hypertension	3/14 (21%)
Ophthalmologic	Nystagmus	10/31 (32%)
	Optic atrophy	8/27 (30%)
	Corneal clouding	1/27 (4%)
Other	Sensorineural hearing loss	13/27 (48%)
	Apnea	7/37 (19%)
	Liver steatosis &/or hepatomegaly	5/6 (83%)
Biochemical/ Enzymatic	Lactic acidemia	27/36 (75%)
Biochemical/ Enzymatic	Low PDC activity (in cultured fibroblasts)	5/12 (42%)

1.: Neurologic manifestations were seen in all 40 individuals reported [Ganetzky et al 2016, Nair et al 2016, Fitzsimons et al 2018].

Neurologic. Most affected individuals reported have presented with severe hypotonia, encephalopathy, or neonatal seizures within the first few days of life. In this scenario, signs and symptoms typically progress quickly and the affected individual ultimately succumbs to central apnea or arrhythmia [Haack et al 2015, Ganetzky et al 2016, Nair et al 2016, Bedoyan et al 2017]. Affected individuals who survive the neonatal period typically have continued truncal hypotonia but develop limb spasticity. They tend to have severe static developmental delay.

A second group of affected individuals present in infancy (after the neonatal period up to age 24 months) with developmental regression [Tetreault et al 2015, Yamada et al 2015, Fitzsimons et al 2018], typically leading to severe developmental delay.

There have been two reports of individuals with isolated paroxysmal dystonia and otherwise normal development. In one report, two of three affected individuals were sibs, one of whom had learning disabilities [Olgiati et al 2016]. The other (unrelated) reported individual had attention deficit with hyperactivity disorder [Mahajan et al 2017].

Dystonia, or less commonly choreoathetosis and/or ataxia, is usually chronically present, but is exacerbated by illness or exertion [Tetreault et al 2015, Olgiati et al 2016].

Across all three phenotypes, T₂ hyperintensity in the basal ganglia is very common (88%) and may affect any part of the basal ganglia. This is seen even in those whose clinical presentation is limited to paroxysmal exercise-induced dystonia [Olgiati et al 2016, Mahajan et al 2017].

Growth. Most children with ECHS1 deficiency require enteral feeding tubes due to severe developmental delay and hypotonia. Dysphagia has been reported in three individuals, one of whom suffered aspiration events [Ferdinandusse et al 2015, Yamada et al 2015].

Cardiac. Cardiomyopathy may be dilated or hypertrophic. In two affected individuals, cardiac hypertrophy was transient [Ferdinandusse et al 2015, Fitzsimons et al 2018]. Three individuals with pulmonary hypertension have been reported [Ferdinandusse et al 2015, Nair et al 2016]. Two other individuals have had terminal bradycardiac arrhythmias in the setting of lactic acidosis. It is unclear whether this was due to a predisposition to arrhythmia or secondary to overwhelming metabolic acidosis [Ganetzky et al 2016, Al Mutairi et al 2017].

Sensorineural hearing loss. Hearing loss may be found incidentally by audiologic screening. Hearing loss may be mild and is often stable. Two affected individuals required hearing aids for severe hearing loss [Tetreault et al 2015, Aretini et al 2018].

Liver dysfunction. Hepatomegaly or hepatosplenomegaly has been seen in multiple infantile cases. Liver steatosis is often present in those who have had postmortem examinations. However, no individuals with clinically significant liver dysfunction have been reported [Ferdinandusse et al 2015, Ganetzky et al 2016, Bedoyan et al 2017, Fitzsimons et al 2018].

Biochemical and enzymatic features

Lactate levels may be extremely high, causing metabolic acidosis as the primary clinical finding [Haack et al 2015, Ganetzky et al 2016, Nair et al 2016, Al Mutairi et al 2017, Bedoyan et al 2017]. However, in cases with onset after the neonatal period, lactic academia may be intermittent [Huffnagel et al 2018].
Two affected individuals have had moderate hyperammonemia in the setting of profound neonatal metabolic stress, potentially related to their severe metabolic acidosis and/or low ATP secondary to impaired aerobic oxidation. Levels have been reported ranging from 150 to 800 µmol/L in cases with a concommittent pH < 7.1 [Ferdinandusse et al 2015, Nair et al 2016].
Elevated creatine kinase (CK) levels (hyperCKemia) to about 3,000 IU/L in a critically ill newborn [Ferdinandusse et al 2015] and transient mild hypoglycemia [Olgiati et al 2016] have also been reported.
In affected individuals, low pyruvate dehydrogenase complex (PDC) activity in cultured fibroblasts is noted in about 40% of cases [Bedoyan et al 2017]. Low PDC activity has also been noted in lymphocytes as well as liver and skeletal muscle [Ferdinandusse et al 2015, Bedoyan et al 2017].

Other manifestations. Variable dysmorphic facial features and structural anomalies have each been reported in a few affected individuals.

Facial features are variable, but may include a long philtrum, similar to what is seen in individuals with pyruvate dehydrogenase deficiency [Ganetzky et al 2016, Balasubramaniam et al 2017].
The only recurrent structural abnormality is thinning or absence of the corpus callosum [Ganetzky et al 2016, Bedoyan et al 2017, Fitzsimons et al 2018].
The following have each been described in one affected individual:
- Hypospadias [Ganetzky et al 2016]
- Gastroschisis [Haack et al 2015]
- Cutis laxa [Balasubramaniam et al 2017]
- Hypertrichosis [Fitzsimons et al 2018]
- Abnormal lung septation, multiple splenules, and a preauricular tag [Ganetzky et al 2016]

Prognosis. The prognosis of neonatal-onset ECHS1 deficiency is poor. Of the 18 reported neonatal cases, 16 (89%) are deceased, mostly within days to weeks of birth from overwhelming lactic acidosis, apnea, hypotension, or bradycardia. Of the 13 later-onset cases, five are deceased (38%), all in early childhood.

In contrast, those with the paroxysmal dystonia phenotype have been mildly affected with no reported deaths and relatively normal cognitive development. There is likely a broad spectrum between the infantile phenotype and the paroxysmal dystonia phenotype, as individuals with paroxysmal dystonia have been diagnosed after metabolic decompensation [Olgiati et al 2016] or stroke-like episodes [Authors, unpublished observation], but this is not yet clear.

Genotype-Phenotype Correlations

All affected individuals with the paroxysmal dystonia phenotype have been compound heterozygous for the pathogenic c.518C>T variant and a second pathogenic variant [Korenke et al 2016, Olgiati et al 2016, Mahajan et al 2017]. The c.518C>T variant, however, has not been identified in affected individuals with other, more severe clinical phenotypes [Bedoyan et al 2017].

Prevalence

ECHS1 deficiency is rare; the exact prevalence and incidence are unknown.

To date, 40 affected individuals representing 31 families from different ethnic backgrounds / geographic locations – including European, East Asian, French Canadian, and Middle Eastern – have been reported [Nair et al 2016]. No affected individuals of African heritage have yet been reported.

Additional data are required to determine if the c.538A>G (p.Thr180Ala) variant is a French Canadian founder variant [Sharpe & McKenzie 2018].

Differential Diagnosis

Table 3.

Disorders to Consider in the Differential Diagnosis of ECHS1 Deficiency (ECHS1D)

DiffDx Disorder	Gene(s)	MOI	Clinical Features of DiffDx Disorder
DiffDx Disorder	Gene(s)	MOI	Overlapping w/ECHS1D	Distinguishing from ECHS1D
Pyruvate dehydrogenase complex (PDC) deficiency (OMIM PS312170)	DLAT LIAS PDHA1 PDHB PDHX PDP1	AR XL	Pyruvate dehydrogenase complex deficiency Lactic acidosis ↑ pyruvate Normal lactate to pyruvate ratio Long philtrum Corpus callosum hypoplasia	May be a complete phenocopy ¹ Individuals w/ECHS1D may have abnormal acylcarnitine profile or urine organic acids not typically seen in primary PDC deficiency.
3-hydroxyisobutyryl-CoA hydrolase deficiency (HIBCHD) (OMIM 250620)	HIBCH	AR	Lactic acidosis Basal gangliar lesions ↑ 2-methyl-2,3-dihydroxybutyrate	Organic acid abnormalities typically more pronounced in HIBCH
FBXL4-related encephalomyopathic mitochondrial DNA depletion syndrome	FBXL4	AR	Neonatal/primary lactic acidosis Variable cardiomyopathy	FBXL4 deficiency typically has more striking hyperammonemia. ATP synthase deficiency typically has more prominent 3-methylglutaconic aciduria. ECHS1D may be suspected (rather than FBXL4 or TMEM70 deficiency) if 2-methyl-2,3-dihydroxybutyrate is present or lactate-to-pyruvate ratio is normal.
Mitochondrial complex V (ATP synthase) deficiency, nuclear type 2 (OMIM 614052)	TMEM70
Mitochondrial complex I deficiency due to ACAD9 deficiency (OMIM 611126)	ACAD9
Other Leigh syndromes (see Nuclear Gene-Encoded Leigh Syndrome Overview & Mitochondrial DNA-Associated Leigh Syndrome and NARP)	>60 genes	AR mt XL	T₂ hyperintensity of the basal ganglia Dystonia Developmental regression Lactic acidosis	ECHS1D may be clinically indistinguishable from other Leigh syndromes.
Paroxysmal exercise-induced dyskinesia & epilepsy (see Glucose Transporter Type 1 Deficiency Syndrome)	SLC2A1	AD AR ²	Paroxysmal exercise-induced dystonia	Normal brain MRI
Paroxysmal kinesogenic dyskinesia (see PRRT2-Associated Paroxysmal Movement Disorders)	PRRT2	AD AR ²	Paroxysmal dystonia (may be exercise induced)	Normal brain MRI
Familial paroxysmal nonkinesigenic dyskinesia	PNKD	AD	Paroxysmal dystonia (may be exercise induced)	Normal brain MRI
Pyruvate carboxylase deficiency	PC	AR	↑ lactate, pyruvate, & ammonia	More striking hyperammonemia Ketonuria Normal organic acids

: AD = autosomal dominant; AR = autosomal recessive; DiffDx = differential diagnosis; MOI = mode of inheritance; mt = mitochondrial; XL = X-linked
1.: Bedoyan et al [2017], Nouguès et al [2017]
2.: Autosomal recessive inheritance is rare.

Management

Evaluations Following Initial Diagnosis

To establish the extent of disease and needs in an individual diagnosed with mitochondrial short-chain enoyl-CoA hydratase 1 deficiency (ECHS1D), the evaluations summarized in Table 4 (if they have not already been completed) are recommended.

Table 4.

Recommended Evaluations Following Initial Diagnosis in Individuals with ECHS1 Deficiency

System/Concern	Evaluation	Comment
Neurologic	Brain MRI/MRS to evaluate for basal ganglia involvement & structural brain anomalies
Neurologic	Electroencephalogram to evaluate for epileptic encephalopathy	In those w/neonatal or infantile form
Growth/ Gastrointestinal	Nutritional eval Swallowing assessment Liver ultrasound to evaluate for hepatosplenomegaly	Nutritional & swallowing evals should be performed in all affected persons, but liver ultrasound is only necessary in neonates.
Cardiovascular	Echocardiogram to evaluate for cardiomyopathy in those w/neonatal form	Measurement of pulmonary artery pressure is important to evaluate for pulmonary hypertension.
Ophthalmologic	Dilated eye exam to evaluate for optic atrophy & other findings	In all affected persons
Audiologic	Audiologic eval for sensorineural hearing loss	In all affected persons
Biochemical	Lactate & blood gas to evaluate acid/base status	In all affected persons
	Blood glucose level Urine organic acids	FindZebra contact@findzebra.com