Abstract
Background
Autosomal recessive hereditary spastic paraplegias (HSP) are a rare group of hereditary neurodegenerative disorders characterized by spasticity with or without other symptoms. SPG11 gene is the most common cause of autosomal recessive HSP. We report a case of autosomal recessive spastic paraplegia type 76 due to heterozygous variants of CAPN1 in an Argentinean subject.
Case Presentation
A 38-year-old Argentinean female presented with progressive gait problems and instability of 15-year duration. Oculomotor abnormalities, ataxia, bradykinesia, cervical dystonia, and lower limb pyramidal signs were observed. Brain MRI was unremarkable. Whole-exome sequencing analysis identified two heterozygous variants in CAPN1.
Conclusions
Clinicians should screen for CAPN1 mutation in a young female patient without significant family history with a spastic paraplegia syndrome associated with other symptoms.
1. Background
Hereditary spastic paraplegias (HSP) are a group of heterogeneous degenerative disorders characterized by lower limb spasticity and weakness due to progressive degeneration of corticospinal tracts [1]. HSP can present as a pure form only with pyramidal symptoms, or as a complex form associated with other symptoms. HSP are transmitted in all modes of inheritance [2]. The autosomal dominant mode of inheritance is the most prevalent representing 70% of cases. Mutation in SPAST gene accounts for 40% of the autosomal dominant HSP. In the recessive HSP, the most frequent mutation is in SPG11. We report a case of autosomal recessive spastic paraplegia type 76 (SPG76, OMIM #616907) due to heterozygous variants of CAPN1 in an Argentinean subject.
2. Case Presentation
A 38-year-old Argentinean female presented with slowly progressive unsteadiness noticed first at age 23. She reported pronounced instability and gait problems as disease progressed. Her gait problems were described as short steps, with starting hesitation, fear of falling, and needing to hold from walls to avoid falling. She also reported several falls, dizziness, neck pain, and constipation. Symptoms progressed over the years affecting her mobility and functionality. She currently needs assistance for moving around. No relevant medical, family, or psychosocial history was reported. No past interventions were reported.
On neurological examination (Video 1), she presented dysarthria, interrupted slow horizontal and vertical eye movements, and slow horizontal saccades. She manifested spasticity and hyperreflexia more pronounced in her lower extremities. Mild cervical dystonia with bradykinesia was also observed. She showed ataxic symptoms more pronounced on her left upper extremity. Gait was spastic and no cognitive abnormalities were observed.
Brain MRI with and without contrast was unremarkable. Due to the presence of a slowly progressive adult onset spastic-ataxia syndrome, associated with other neurological abnormalities, and facing the challenge of poor financial access, we decided to optimize our resources studying the patient using whole-exome sequencing (CentoDX™, Centogene AG, Germany). The analysis identified two variants in CAPN1 (MIM:114220) considered as probably pathogenic Class 2, according to the American College of Medical Genetics and Genomics criteria. She was heterozygous for a splicing mutation in intron 16 (c.1729+1G>A) and a second splicing mutation in intron 12 (c.1353+2T>C). Carrier testing in the parents was not performed. Due to the strong phenotypic overlap between the symptoms and previously reported cases, we consider the detected variants as pathogenic of SPG76.
3. Discussion
We report two pathogenic variants of CAPN1 gene and the first case affecting two noncoding regions (introns) in a Latin-American patient. Table 1 describes all SPG76 reported cases in the literature [3, 4]. We observed that female patients are more commonly (67%) affected, with a mean age of onset of 19.8 years (Min. = 5, Max. = 39), most had family history of consanguinity (71%), and most were homozygous (77%). All initiated with lower limb spasticity, 85% reported upper limb spasticity, 58% showed ataxia, and 41% reported dysarthria. Our case also presented with oculomotor abnormalities. Three cases showed cerebellar atrophy and 1 spinal atrophy on MRI.
Table 1.
Clinical and genetical characteristics of SPG76 cases reported in the literature.
| Ethnicity | Age at onset | Age at diagnosis | Gender | Lower limbs spasticity | Upper limbs spasticity | Ataxia | Dysarthria | Oculomotor Impairment | Exon or Intron affected | Mutation | Type | Heterozygous /Homozygous | Consanguinity | Brain MRI | NCS and SSEP | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1 | Latin American | NA | NA | NA | + | + | - | - | - | - | c.1176G>A p.Trp392∗ |
Stop gain mutation | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 2 | Latin American | NA | NA | NA | + | + | - | - | - | - | c.1176G>A p.Trp392∗ |
NA | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 3 | Latin American | NA | NA | NA | + | + | - | - | - | - | c.1176G>A p.Trp392∗ |
NA | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 4 | Latin American | 22 | 37 | F | + | + | - | - | - | - | c.1176G>A p.Trp392∗ |
NA | Homozygous | - | NA | NA |
|
| ||||||||||||||||
| 5 | Caucasian | 20 | 46 | F | + | + | + | - | - | - | c.675C>A p.Tyr225∗ |
Novel LoF Mutation | Homozygous | - | NA | NA |
|
| ||||||||||||||||
| 6 | Caucasian | 35 | 51 | M | + | + | + | - | - | - | c.675C>A p.Tyr225∗ |
Novel LoF Mutation | Homozygous | - | NA | NA |
|
| ||||||||||||||||
| 7 | Latin American | 30 | 42 | F | + | + | + | - | - | - | c.1176G>A p.Trp392∗ c.618_619delAG p.Gly208Glnfs∗7 |
LoF Mutation | Heterozygous | + | NA | NA |
|
| ||||||||||||||||
| 8 | Latin American | 38 | - | M | + | + | + | - | - | - | c.1176G>A p.Trp392∗ |
LoF Mutation | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 9 | Arab | 20 | 31 | F | + | + | - | + | - | Ex:8 | c.884G>C p.Arg295Pro |
LoF Mutation | Homozygous | + | NA | Normal |
|
| ||||||||||||||||
| 10 | Arab | NA | NA | NA | NA | NA | NA | NA | NA | Ex:8 | c.884G>C p.Arg295Pro |
LoF Mutation | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 11 | Arab | NA | NA | NA | NA | NA | NA | NA | NA | Ex:8 | c.884G>C p.Arg295Pro |
LoF Mutation | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 12 | Arab | 35 | 47 | M | + | + | - | + | - | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | NA | Moderate Sensory Axonal Neuropathy |
|
| ||||||||||||||||
| 13 | Arab | 36 | 44 | F | + | + | + | + | - | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | NA | Moderate Sensory Axonal Neuropathy |
|
| ||||||||||||||||
| 14 | Arab | 22 | 42 | M | + | + | - | + | - | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | Normal | NA |
|
| ||||||||||||||||
| 15 | Arab | 39 | 40 | M | + | + | + | + | - | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 16 | Arab | NA | NA | NA | NA | NA | NA | NA | NA | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 17 | Arab | NA | NA | NA | NA | NA | NA | NA | NA | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 18 | Arab | NA | NA | NA | NA | NA | NA | NA | NA | Ex:14 | c.1579C>T p.Gln527 |
Stop variant | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 19 | Caucasian | 24 | 30 | F | + | - | - | - | - | Ex:4 | c.406delC p.Pro136Argfs∗40 |
Deletion | Heterozygous | - | NA | Normal |
|
| ||||||||||||||||
| 20 | Caucasian | 33 | 35 | M | + | - | - | - | - | Ex:4 | c.406delC p.Pro136Argfs∗40 |
Deletion | Heterozygous | - | Atrophy of spinal cord | NA |
|
| ||||||||||||||||
| 21 | Caucasian | 19 | 22 | F | + | + | + | - | - | Ex:4 | c.1605+5G>A | Mutation Splicing | Heterozygous | - | Normal | NA |
|
| ||||||||||||||||
| 22 | Indian | 33 | 43 | F | + | + | + | + | - | Ex:3 | c.337+1G>A | Splice Mutation | Homozygous | + | Mild cerebellar atrophy | Normal |
|
| ||||||||||||||||
| 23 | Indian | NA | NA | F | NA | NA | NA | NA | NA | Ex:3 | c.337+1G>A | Splice Mutation | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 24 | Caucasian | 29 | 39 | F | + | + | + | + | + | Ex:6 | c.759+1G>A | Donor splice site | Homozygous | + | Mild cerebellar vermal atrophy | NA |
|
| ||||||||||||||||
| 25 | Caucasian | 33 | 37 | F | + | + | + | + | - | Ex:6 | c.759+1G>A | Donor splice site | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 26 | Caucasian | 5 | 16 | M | + | - | - | - | - | - | c.221GNA/ p.(G74D) c.911CNT/ p.(T304M) c.1418GNT/ p.(R473L) |
missense | Heterozygous | - | Normal | Normal |
|
| ||||||||||||||||
| 27 | Arab | 21 | 37 | F | + | + | + | + | - | - | c.994G>A P.Gly.332Arg |
NA | Homozygous | + | Normal | Normal |
|
| ||||||||||||||||
| 28 | Arab | 30 | 54 | F | + | + | + | + | - | Ex10 | c. 1176G>A p. Trp392 |
Nucleotide substitution | Heterozygous | + | Normal | Normal |
|
| ||||||||||||||||
| 29 | Arab | 15 | 30 | F | + | + | + | + | - | Ex:10 | c. 1176G>A p. Trp392 |
Nucleotide substitution | Heterozygous | + | Normal | Normal |
|
| ||||||||||||||||
| 30 | Asian | 37 | 42 | F | + | + | + | - | - | - | c.2118+1G>T | Donor Splice site | Homozygous | NA | NA | NA |
|
| ||||||||||||||||
| 31 | Caucasian | 23 | 23 | M | + | - | - | - | - | - | c.397C>T | NA | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 32 | Caucasian | 20 | 20 | F | + | - | - | - | - | - | c.397C>T | Mutation in DYSF | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 33 | Asian | 37 | 37 | M | + | + | + | - | - | - | c.843+1G>C | Donor Splice Site | Homozygous | + | NA | NA |
|
| ||||||||||||||||
| 34 | Caucasian | 13 | 14 | F | + | + | + | - | - | Ex: 13 | c.1534C>T p.Arg512Cys |
NA | Homozygous | - | Small midbrain and ponds, cerebellar atrophy | Delayed cortical wave defective conduction of large sensory fibers |
|
| ||||||||||||||||
| 35 (our case) | Latin American | 23 | 38 | F | + | + | + | + | + | In: 12 and 16 | c.1729+1G>A c.1353+2T>C |
Donor Splice Mutation | Heterozygous | NA | Normal | NA |
Abbreviations. F: female, M: male, +: present, -: absent, LoF: loss of function, DYSF: dysferlin, MRI: magnetic resonance image, C: cerebral, S: spinal, NCS: nerve conduction studies, SSEP: somatosensory evoked potentials, NA: not available.
In comparison with other published cases, we found similarities in that all of them presented lower limb spasticity and ataxia. The difference from our case was the oculomotor abnormalities, which was also reported in only one other case [5]. We suggest that the combined phenotype of spasticity and ataxia with oculomotor abnormalities, in a young female patient of Arab origin, could be a diagnostic clue for SPG76. The age of onset of our case was similar to that previously reported. All of the subjects experienced pronounced instability and gait problems as disease progresses [6].
CAPN1 mutations account for 2.2% of autosomal recessive HSP. CAPN1 is located in chromosome 11q13 and encodes calpain 1, a calcium-activated cysteine protease that is widely present in the central nervous system. The exact role of calpain 1 in humans is unclear; however, studies in animal models suggest that calpain 1 is involved in synaptic plasticity, neuronal migration, neuronal necrosis, and maintenance [7].
4. Conclusions
Our report adds to the clinical and genetical spectrum of CAPN1-related SPG76 disorders. We recommend clinicians to consider screening for CAPN1 in a young female patient with spastic paraplegia with additional neurological symptoms without significant family history.
Acknowledgments
We would like to thank the patient for authorizing us to use her clinical data to make it available for the medical community.
Abbreviations
- HSP:
Hereditary spastic paraplegia
- SPAST:
Spastin gene
- SPG:
Spastic paraplegia gene
- CAPN1:
Calpain 1 gene
- MRI:
Magnetic resonance imaging.
Data Availability
All data generated or analyzed during the case report are included in the published article.
Consent
Written informed consent was obtained from the patient for publication of this case report and any accompanying images or videos.
Conflicts of Interest
The authors report no financial or nonfinancial conflicts of interest.
Authors' Contributions
Daniel Martinez-Ramirez and Jesus Eduardo Garcia-Berlanga were responsible for conception, organization, and execution. All the authors were responsible for the preparation of the manuscript: writing of the first draft, review and critique, and reading and approving the final version of the manuscript.
Supplementary Materials
Video Legends: We can observe interrupted slow horizontal and vertical eye movements with slow horizontal saccades. She had spasticity and hyperreflexia more pronounced in lower extremities. She also showed bilateral Hoffman and Trömner signs, with clonus in lower extremities, and presence of Babinski sign bilaterally. She presented cervical dystonia with laterocollis to the left, and mild bradykinesia was observed during rapid movements. Finger to nose test showed dyssynergia and hypometric movements, rapid alternating movements with dysdiadochokinesia, past pointing, and finger chasing with dyssynergia and dysmetria more pronounced on left upper extremity. Gait was spastic type with scissoring legs.
References
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Video Legends: We can observe interrupted slow horizontal and vertical eye movements with slow horizontal saccades. She had spasticity and hyperreflexia more pronounced in lower extremities. She also showed bilateral Hoffman and Trömner signs, with clonus in lower extremities, and presence of Babinski sign bilaterally. She presented cervical dystonia with laterocollis to the left, and mild bradykinesia was observed during rapid movements. Finger to nose test showed dyssynergia and hypometric movements, rapid alternating movements with dysdiadochokinesia, past pointing, and finger chasing with dyssynergia and dysmetria more pronounced on left upper extremity. Gait was spastic type with scissoring legs.
Data Availability Statement
All data generated or analyzed during the case report are included in the published article.