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Compound Heterozygous Mutations Presented with Quadriparesis and Menopause. A Case Report

Published online by Cambridge University Press:  02 May 2022

Shahab Noorian
Affiliation:
Department of Pediatrics, School of Medicine, Alborz University of Medical Sciences, Karaj, Iran
Sahar Mohammadpoor Nami
Affiliation:
Kamali Hospital, Alborz University of Medical Sciences, Karaj, Iran
Zahra Nouri Ghonbalani
Affiliation:
Vice Chancellor for Research and Technology, Alborz University of Medical Sciences, Karaj, Iran
Nami Mohammadian Khonsari*
Affiliation:
Non-Communicable Diseases Research Center, Alborz University of Medical Sciences, Karaj, Iran
*
Author for correspondence: Nami Mohammadian Khonsari, Email: [email protected]

Abstract

Mitochondrion regulates cellular metabolism with the aid of its respiratory complexes; any defect within these complexes can result in mitochondrial malfunction and various conditions. One such mutation can occur in SLC25A10, resulting in mitochondrial DNA depletion syndrome. It should be noted that the pattern of inheritance of this syndrome is autosomal recessive. However, we present a case with compound heterozygous mutations within this gene resulting in disease. An 18-year-old female was referred to our clinic due to menopause with a medical history of hearing loss, spasticity, hypotonia and quadriparesis. The child’s birth and development were uneventful until the initiation of movement reduction and hypotonia when she was 12 months old. Afterward, the hypotonia progressed to quadriparesis and spasticity throughout the years. Our patient became completely quadriplegic up to the age of 3 and became completely deaf at 10. Her puberty onset was at the age of 9, and no significant event took place until she was 17 years old when suddenly her periods, which were regular until that time, became irregular and ceased after a year; hence, a thorough evaluation began, but similar to her previous evaluations all tests were insignificant. Nonetheless, we suspected an underlying metabolic or genetic defect; thus, we ordered a whole-exome sequencing (WES) workup and found simultaneous heterozygous mutations within SLC25A10, HFE and TTN genes that could explain her condition. When all other tests fail, and we suspect an underlying genetic or metabolic cause, WES can be of great value.

Type
Article
Copyright
© The Author(s) 2022. Published by Cambridge University Press on behalf of International Society for Twin Studies

Through respiration, the mitochondrion regulates cellular metabolism. This function arises from the mitochondrial respiratory complexes, resulting in electron transfer and oxidative phosphorylation. (Osellame et al., Reference Osellame, Blacker and Duchen2012) However, any disruption within these respiratory complexes may result in various conditions based on the nature of the interruption. Genetic mutations, even some nuclear mutations, can affect the mitochondrial function by disrupting coding proteins’ structural and assembly factors essential for mitochondrial function. (Osellame et al., Reference Osellame, Blacker and Duchen2012; Pieczenik & Neustadt, Reference Pieczenik and Neustadt2007) One such gene is SLC25A10, which encodes a mitochondrial integral membrane protein with the same name, functioning as a catalyzer for dicarboxylate transport. Various studies have reported mutations within this gene. Dysfunction within the coded protein can impair the activity of one of these respiratory complexes, called mitochondrial respiratory complex I, resulting in various conditions ranging from fatal diseases in neonates to neurodegenerative disorders in adults (Lash, Reference Lash2015; Pieczenik & Neustadt, Reference Pieczenik and Neustadt2007; Punzi et al., Reference Punzi, Porcelli, Ruggiu, Hossain, Menga, Scarcia, Castegna, Gorgoglione, Pierri, Laera, Lasorsa, Paradies, Pisano, Marobbio, Lamantea, Ghezzi, Tiranti, Giannattasio, Donati and De Grassi2017). To our knowledge, only one autosomal recessive SLC25A10 compound mutation resulting in neurological conditions was reported in a 9-year-old boy (Punzi et al., Reference Punzi, Porcelli, Ruggiu, Hossain, Menga, Scarcia, Castegna, Gorgoglione, Pierri, Laera, Lasorsa, Paradies, Pisano, Marobbio, Lamantea, Ghezzi, Tiranti, Giannattasio, Donati and De Grassi2017). Here, we discuss the second case that resulted from simultaneous mutations in the aforementioned gene resulting in hearing loss, spasticity, hypotonia and quadriparesis in an 18-year-old female referred to us due to menopause.

Case Presentation

An 18-year-old female was referred to our clinic due to menopause with a background of hearing loss, spasticity, hypotonia and quadriparesis. She was the only child of a census (cousins) parents with no history of familial and metabolic diseases, abortions or child deaths. The child’s birth, development and status were uneventful until the initiation of her first symptoms when she was 12 months old when the parents noticed that her movement had decreased and she was slowly losing the ability to hold her head up; the child was referred to a pediatrician due to suspecting developmental regression and metabolic conditions. However, at that time, based on numerous insignificant lab test results (e.g. acidosis, accumulation of metabolites), she was diagnosed with cerebral palsy (CP), which explained some of the symptoms that she already had and some that had yet to come. The hypotonia, which began when she was about one year, progressed to quadriparesis and spasticity throughout the years. Our patient became completely quadriplegic by the age of 3, began losing her hearing, and became completely deaf (bilateral) at the age of 10. It should be noted that quadriparesis and hearing loss, and mild mental retardation were the only findings throughout the years. Her puberty onset was at the age of 9, and no significant event took place until she was 17 years old when suddenly her periods, which were regular until that time, became irregular and ceased after a year; thus, an endocrinologist consult was sought, and she was referred to us. We started a complete assessment of the patient; our only clinical findings were bilateral hearing loss, hypotonia and weak spontaneous movements consistent with her previous diagnosis (CP).

No other abnormalities within the systems were detected. Upon assessment, it was found that she had two episodes of brief generalized tonic–clonic convulsions exacerbated by fever at the ages of 16 and 21 months; no other episode of seizures was reported. Nonetheless, after the second seizure, preventive therapy with phenytoin 5mg/kg divided into three doses per day was initiated and continued till her puberty with dose adjustments. Furthermore, we assessed her growth parameters which were within the normal range for her sex and age throughout the years. Moreover, to rule out any underlying condition and metabolic abnormalities, complete laboratory analyses were ordered, including complete blood count liver function tests, including aspartate aminotransferase, also known as serum glutamic oxaloacetic transaminase, alanine aminotransferase, also known as serum glutamic pyruvic transaminase, prothrombin time, partial thromboplastin time and international normalized ratio, renal function tests (urine analysis, serum creatinine, urine sodium and potassium levels, and 24-hour urine protein levels), arterial blood gas, alongside anion gap, serum glucose, triglyceride, cholesterols, lactate, iron, ammonia, plasma amino acid profile, and electrolytes (calcium, potassium, sodium, phosphorus, chlorine) as well as cerebrospinal fluid glucose, amino acid and ammonia levels. However, all tests were insignificant, and no abnormalities were detected. Nonetheless, we suspected an underlying metabolic or genetic defect. Hence, we ordered a whole-exome sequencing (WES) workup for our patient. The method of WES, as well as the material used, is the same as described by Khonsari, Nami et al. (Reference Khonsari, Nami, Hakak-Zargar and Voth2020) and Noorian et al. (Reference Noorian, Khonsari, Savad, Hakak-Zargar, Voth and Kabir2021). WES results indicated the presence of two heterozygous variants within the SLC25A10 gene as follows: gene/transcript (RefSeq): SLC25A10/NM_001270888.1, variant location chromosome 17 exome 9, variant c.684C>T p.Pro228Pro (synonymous variant) and SLC25A10/NM_001270888.1 variant location chromosome 17 exome 10 variant c.790-37G>A (intronic variant, ClinVar Accession: VCV000446176.2). Other findings included a heterozygous mutation in TTN/NM_001256850.1 variant location chromosome 2 exome 14 variant c.2371-1G>A (splice acceptor variant, ClinVar Accession: VCV000582625.4) and heterozygous mutations in HFE/ NM_000410.4 variant location chromosome 6 exomes 4 and 2 variants p.Cys282Tyr (missense variant, ClinVar Accession: VCV000000009.42) and c.187C>G (p.His63Asp) (missense variant, ClinVar Accession: VCV000000010.42), respectively. The WES result was confirmed with Sanger PCR.

Mutations within the HFE gene can result in conditions such as hemochromatosis, diabetes and even hearing loss due to iron metabolism dysregulation in the body (Barton et al., Reference Barton, Edwards and Acton2015; Castiglione et al., Reference Castiglione, Ciorba, Aimoni, Orioli, Zeri, Vigliano and Gemmati2015).

Mutations within the TTN gene can cause myopathies with vast clinical presentations as they can disrupt titin synthesis in muscles (Savarese et al., Reference Savarese, Maggi, Vihola, Jonson, Tasca, Ruggiero, Bello, Magri, Giugliano, Torella, Evilä, Di Fruscio, Vanakker, Gibertini, Vercelli, Ruggieri, Antozzi, Luque, Janssens and Nigro2018; Spinazzola et al., Reference Spinazzola, Invernizzi, Carrara, Lamantea, Donati, Dirocco, Giordano, Meznaric-Petrusa, Baruffini and Ferrero2009).

Mutations within the SLC25A10 gene can result in mitochondrial DNA depletion syndrome, resulting in mitochondrial respiratory complex I malfunction. This condition can present itself in various forms, such as metabolic abnormalities, muscle weakness, neuropathy, hearing loss, encephalopathy and pubertal abnormalities (El-Hattab & Scaglia, Reference El-Hattab and Scaglia2013).

We also sequenced parental genes as well and confirmed the results with Sanger PCR. The parental test results indicated that the variants NM_001270888.1(SLC25A10):c.684C>T p.Pro228Pro, NM_000410.4(HFE):c.187C>G (p.His63Asp) and NM_001267550.2(TTN):c.2371-1G>A were paternally inherited, and variant NM_001270888.1(SLC25A10):c.(790-37G>A) was maternally inherited. NM_000410.4(HFE):c.845G>A (p.Cys282Tyr) was not detected in the parents. Upon proper medical evaluations, no signs or symptoms within the parents were detected. Hence, with the proper diagnosis, possible outcomes and disabilities were detected, and thus, proper preventive steps were taken.

Discussion

Although this article reports the second case of compound heterozygous autosomal recessive mitochondrial mutations that resulted in disease manifestation (Punzi et al., Reference Punzi, Porcelli, Ruggiu, Hossain, Menga, Scarcia, Castegna, Gorgoglione, Pierri, Laera, Lasorsa, Paradies, Pisano, Marobbio, Lamantea, Ghezzi, Tiranti, Giannattasio, Donati and De Grassi2017), the aim of this report was not to evaluate the function of the gene, nor molecular evaluations, but to discuss the possibility of the hypothesis that regardless of the recessive pattern of inheritance of some genes, compound mutations with similar outcomes and affected organs may have a synergic effect on one another. As seen in some cases, despite the mutations having no known relativity, their compound synergic effect was similar to that of a homozygous case. (Khonsari, Nami et al., Reference Khonsari, Nami, Hakak-Zargar and Voth2020) Moreover, it should be noted that this case is different from the case reported by Punzi et al. (Reference Punzi, Porcelli, Ruggiu, Hossain, Menga, Scarcia, Castegna, Gorgoglione, Pierri, Laera, Lasorsa, Paradies, Pisano, Marobbio, Lamantea, Ghezzi, Tiranti, Giannattasio, Donati and De Grassi2017). As we reported, one of the SLC25A10 mutations was synonymous; thus, it might seem that this mutation is of no clinical significance; however, recent studies indicate that synonymous mutations can result in diseases by affecting mRNA splicing and disrupting protein expression, function and conformation (Brule & Grayhack, Reference Brule and Grayhack2017; Cartegni et al., Reference Cartegni, Chew and Krainer2002; Corrado et al., Reference Corrado, Magri, Bagarotti, Carecchio, Piscosquito, Pareyson, Varrasi, Vecchio, Zonta and Cantello2016; Macaya et al., Reference Macaya, Katsanis, Hefferon, Audlin, Mendelsohn, Roggenbuck and Cutting2009; Sauna & Kimchi-Sarfaty, Reference Sauna and Kimchi-Sarfaty2011). Hence, similar to another case, the presence of some mutations in each parent did not result in a detectable condition; the simultaneous occurrence of the mutations, however, resulted in disease (Khonsari, Nami et al., Reference Khonsari, Nami, Hakak-Zargar and Voth2020).

The excess severity of neurological condition reported by Punzi et al. (Reference Punzi, Porcelli, Ruggiu, Hossain, Menga, Scarcia, Castegna, Gorgoglione, Pierri, Laera, Lasorsa, Paradies, Pisano, Marobbio, Lamantea, Ghezzi, Tiranti, Giannattasio, Donati and De Grassi2017) could be due to the presence of an extra mutation (NM_001270888.1: c.304A > T, p.Lys102) within the SLC25A10 gene, strengthening the hypothesis that compound heterozygous mutations can have a synergic effect despite their recessive pattern of inheritance.

In our patient, the compound effect of both SLC25A10 mutations could explain her menstrual abnormalities. The severe muscle weakness could be due to the synergic effect of SLC25A10 and TTN mutations. Moreover, her hearing loss could be due to the compound effects of HFE and SLC25A10 mutations, as both of them can, in fact, cause hearing loss, as mentioned before.

It is interesting that the father did not have any signs and symptoms despite having various mutations as well. This could be due to the synonymous nature of his SLC25A10 mutation and lacking the compound effects of NM_001270888.1(SLC25A10):c.(790–37G > A) mutation.

Another discussable matter is the usage of WES to detect the underlying cause of some conditions. Some genetic disorders are easily detected due to their particular phenotype. (Buske et al., Reference Buske, Girdea, Dumitriu, Gallinger, Hartley, Trang, Misyura, Friedman, Beaulieu and Bone2015; Khonsari, Hakak-Zargar et al., Reference Khonsari, Hakak-Zargar, Voth and Noorian2020; Pontikos et al., Reference Pontikos, Murphy, Moghul, Arno, Fujinami, Fujinami, Sumodhee, Downes, Webster and Yu2020) However, some conditions cannot easily be detected as they may seem benign or present, similar to another condition (Noorian et al., Reference Noorian, Khonsari, Savad, Hakak-Zargar, Voth and Kabir2021) or such as with this case be the result of compound mutations resembling the disease rising from homozygous mutations but lesser in severity and symptoms. Despite WES being an expensive test, when genetic defects are highly suspected, it can be beneficial (Noorian et al., Reference Noorian, Khonsari, Savad, Hakak-Zargar, Voth and Kabir2021) since proper diagnosis of genetic defects is of great value, since if diagnosed properly, preventive measures can be taken, proper treatment will be possible, and the prognosis of the patient can be determined.

Conclusion

At first, our patient was diagnosed with CP without finding any metabolic or genetic defects. However, due to suspicion of an underlying genetic defect, WES was performed for our patient and the proper diagnosis was made; hence, when all other tests fail, and we suspect an underlying genetic or metabolic condition, WES can be very helpful.

Data

The data presented in this study can be obtained from the corresponding author upon reasonable request.

Authors’ contributions

All authors participated in preparing the manuscript equally.

Financial support

Not applicable.

Conflict of interest

None.

Ethical standards

The Ethics Committee of Alborz University of Medical Sciences approved this case report. Informed consent was obtained from the participants and written informed consent was obtained from her parents regarding the usage of their data for research and publication purposes. All methods were performed in accordance with the relevant guidelines and regulations.

References

Barton, J. C., Edwards, C. Q., & Acton, R. T. (2015). HFE gene: Structure, function, mutations, and associated iron abnormalities. Gene, 574, 179192.10.1016/j.gene.2015.10.009CrossRefGoogle ScholarPubMed
Brule, C. E., & Grayhack, E. J. (2017). Synonymous codons: Choose wisely for expression. Trends in Genetics, 33, 283297.10.1016/j.tig.2017.02.001CrossRefGoogle ScholarPubMed
Buske, O. J., Girdea, M., Dumitriu, S., Gallinger, B., Hartley, T., Trang, H., Misyura, A., Friedman, T., Beaulieu, C., & Bone, W. P. (2015). PhenomeCentral: A portal for phenotypic and genotypic matchmaking of patients with rare genetic diseases. Human Mutation, 36, 931940.CrossRefGoogle ScholarPubMed
Cartegni, L., Chew, S. L., & Krainer, A. R. (2002). Listening to silence and understanding nonsense: Exonic mutations that affect splicing. Nature Reviews Genetics, 3, 285298.10.1038/nrg775CrossRefGoogle ScholarPubMed
Castiglione, A., Ciorba, A., Aimoni, C., Orioli, E., Zeri, G., Vigliano, M., & Gemmati, D. (2015). Sudden sensorineural hearing loss and polymorphisms in iron homeostasis genes: New insights from a case-control study. BioMed Research International, 2015, 834736.10.1155/2015/834736CrossRefGoogle ScholarPubMed
Corrado, L., Magri, S., Bagarotti, A., Carecchio, M., Piscosquito, G., Pareyson, D., Varrasi, C., Vecchio, D., Zonta, A., & Cantello, R. (2016). A novel synonymous mutation in the MPZ gene causing an aberrant splicing pattern and Charcot-Marie-Tooth disease type 1b. Neuromuscular Disorders, 26, 516520.10.1016/j.nmd.2016.05.011CrossRefGoogle ScholarPubMed
El-Hattab, A. W., & Scaglia, F. (2013). Mitochondrial DNA depletion syndromes: Review and updates of genetic basis, manifestations, and therapeutic options. Neurotherapeutics, 10, 186198.10.1007/s13311-013-0177-6CrossRefGoogle ScholarPubMed
Khonsari, N. M., Hakak-Zargar, B., Voth, T., & Noorian, S. (2020). Late infantile form of multiple sulfatase deficiency. Endocrinology, Diabetes & Metabolism Case Reports, 2020, 200128.Google Scholar
Khonsari, N. M., Nami, S. M. P., Hakak-Zargar, B., & Voth, T. (2020). Mutations of uncertain significance in heterozygous variants as a possible cause of severe short stature: A case report. Molecular and Cellular Pediatrics, 7, 16.Google Scholar
Lash, L. H. (2015). Mitochondrial glutathione in diabetic nephropathy. Journal of Clinical Medicine, 4, 14281447.10.3390/jcm4071428CrossRefGoogle ScholarPubMed
Macaya, D., Katsanis, S., Hefferon, T., Audlin, S., Mendelsohn, N., Roggenbuck, J., & Cutting, G. (2009). A synonymous mutation in TCOF1 causes Treacher Collins syndrome due to mis-splicing of a constitutive exon. American Journal of Medical Genetics Part A, 149, 16241627.10.1002/ajmg.a.32834CrossRefGoogle Scholar
Noorian, S., Khonsari, N. M., Savad, S., Hakak-Zargar, B., Voth, T., & Kabir, K. (2021). Whole-exome sequencing in idiopathic short stature: Rare mutations affecting growth. Journal of Pediatric Genetics, 10, 284291.Google ScholarPubMed
Osellame, L. D., Blacker, T. S., & Duchen, M. R. (2012). Cellular and molecular mechanisms of mitochondrial function. Best Practice & Research Clinical Endocrinology & Metabolism, 26, 711723.CrossRefGoogle ScholarPubMed
Pieczenik, S. R., & Neustadt, J. (2007). Mitochondrial dysfunction and molecular pathways of disease. Experimental and Molecular Pathology, 83, 8492.10.1016/j.yexmp.2006.09.008CrossRefGoogle ScholarPubMed
Pontikos, N., Murphy, C., Moghul, I., Arno, G., Fujinami, K., Fujinami, Y., Sumodhee, D., Downes, S., Webster, A., & Yu, J. (2020). Phenogenon: Gene to phenotype associations for rare genetic diseases. PloS One, 15, e0230587.10.1371/journal.pone.0230587CrossRefGoogle ScholarPubMed
Punzi, G., Porcelli, V., Ruggiu, M., Hossain, M. F., Menga, A., Scarcia, P., Castegna, A., Gorgoglione, R., Pierri, C. L., Laera, L., Lasorsa, F. M., Paradies, E., Pisano, I., Marobbio, C. M. T., Lamantea, E., Ghezzi, D., Tiranti, V., Giannattasio, S., Donati, M. A., … De Grassi, A. (2017). SLC25A10 biallelic mutations in intractable epileptic encephalopathy with complex I deficiency. Human Molecular Genetics, 27, 499504.10.1093/hmg/ddx419CrossRefGoogle Scholar
Sauna, Z. E., & Kimchi-Sarfaty, C. (2011). Understanding the contribution of synonymous mutations to human disease. Nature Reviews Genetics, 12, 683691.10.1038/nrg3051CrossRefGoogle ScholarPubMed
Savarese, M., Maggi, L., Vihola, A., Jonson, P. H., Tasca, G., Ruggiero, L., Bello, L., Magri, F., Giugliano, T., Torella, A., Evilä, A., Di Fruscio, G., Vanakker, O., Gibertini, S., Vercelli, L., Ruggieri, A., Antozzi, C., Luque, H., Janssens, S., … Nigro, V. (2018). Interpreting genetic variants in titin in patients with muscle disorders. JAMA Neurology, 75, 557565.CrossRefGoogle ScholarPubMed
Spinazzola, A., Invernizzi, F., Carrara, F., Lamantea, E., Donati, A., Dirocco, M., Giordano, I., Meznaric-Petrusa, M., Baruffini, E., & Ferrero, I. (2009). Clinical and molecular features of mitochondrial DNA depletion syndromes. Journal of Inherited Metabolic Disease, 32, 143158.10.1007/s10545-008-1038-zCrossRefGoogle ScholarPubMed