White matter lesions in spastic paraplegia with mutations in SPG5/CYP7B1

Hereditary spastic paraplegias (HSPs) are relatively frequent disorders presenting great genetic heterogeneity. The recent identification of mutations in SPG5/CYP7B1 in six autosomal recessive kindred linked to the SPG5 locus on chromosome 8q prompted us to test the relative frequency of SPG5/CYP7B1 variants in 12 families and in sporadic HSP patients by high-resolution melting screening combined with direct sequencing. We present two patients who harbored three mutations (including two novel variants) in SPG5/CYP7B1 and white matter involvement evidenced at brain MRI. In HSP patients in whom no other genes were mutated, screening of SPG5/CYP7B1 seems to have a low diagnostic yield in autosomal recessive (8%) and sporadic (<1%) cases, even in those with complicated clinical features.     

Autosomal recessive spastic paraplegia (SPG45) with mental retardation maps to 10q24.3–q25.1

Hereditary spastic paraplegias (HSPs) are characterized by progressive spasticity in the lower limbs. They are clinically heterogeneous, and pure forms as well as complicated forms with other accompanying clinical findings are known. HSPs are also genetically heterogeneous. We performed clinical and genetic studies in a consanguineous family with five affected members. A genome scan using 405 microsatellite markers for eight members of the family identified candidate gene loci, and subsequent fine mapping in 16 members identified the gene locus responsible for the HSP. The clinical manifestations were very early onset spastic paraplegia (SPG) accompanied by mental retardation and ocular signs. The gene locus was identified as the interval 102.05–106.64 Mbp on chromosome 10. Gene MRPL43 was analyzed in the patients. No mutation but high levels of mRNA were detected. We have mapped a novel autosomal recessive complicated form of HSP (SPG45) to a 4.6-Mbp region at 10q24.3–q25.1 with multipoint logarithm of odds scores >4.5.     

Analysis of CYP7B1 in non-consanguineous cases of hereditary spastic paraplegia

Hereditary spastic paraplegia (HSP) is a neurodegenerative condition defined clinically by lower limb spasticity and weakness. Homozygous mutations in CYP7B1 have been identified in several consanguineous families that represented HSP type 5 (SPG5), one of the many genetic forms of the disease. We used direct sequencing and multiplex ligation-dependent probe amplification to screen for CYP7B1 alterations in apparently sporadic HSP patients (n = 12) as well as index patients from non-consanguineous families with recessive (n = 8) and dominant (n = 8) transmission of HSP. One sporadic patient showing HSP as well as optic atrophy carried a homozygous nonsense mutation. Compound heterozygosity was observed in a recessive family with a clinically pure phenotype. A heterozygous missense change segregated in a small dominant family. We also found a significant association of a known coding polymorphism with cerebellar signs complicating a primary HSP phenotype. Our findings suggest CYP7B1 alterations to represent a rather frequent cause of HSP that should be considered in patients with various clinical presentations.     

Targeted next generation sequencing in SPAST-negative hereditary spastic paraplegia

Molecular characterization is important for an accurate diagnosis in hereditary spastic paraplegia (HSP). Mutations in the gene SPAST (SPG4) are the most common cause of autosomal dominant forms. We performed targeted next generation sequencing (NGS) in a SPAST-negative HSP sample. Forty-four consecutive HSP patients were recruited from an adult neurogenetics clinic in Sydney, Australia. SPAST mutations were confirmed in 17 subjects, and therefore 27 SPAST-negative patients were entered into this study. Patients were screened according to mode of inheritance using a PCR-based library and NGS (Roche Junior 454 sequencing platform). The screening panel included ten autosomal dominant (AD) and nine autosomal recessive (AR) HSP-causing genes. A genetic cause for HSP was identified in 25.9 % (7/27) of patients, including 1/12 classified as AD and 6/15 as AR or sporadic inheritance. Several forms of HSP were identified, including one patient with SPG31, four with SPG7 (with one novel SPG7 mutation) and two with SPG5 (including two novel CYP7B1 frameshift mutations). Additional clinical features were noted, including optic atrophy and ataxia for patients with SPG5 and ataxia and a chronic progressive external ophthalmoplegia-like phenotype for SPG7. This protocol enabled the identification of a genetic cause in approximately 25 % of patients in whom one of the most common genetic forms of HSP (SPG4) was excluded. Targeted NGS may be a useful method to screen for mutations in multiple genes associated with HSP. More studies are warranted to determine the optimal approach to achieve a genetic diagnosis in this condition.     

NIPA1 mutation in complex hereditary spastic paraplegia with epilepsy

Background and purpose: Hereditary spastic paraplegia (HSP) is a group of clinically and genetically heterogeneous neurodegenerative disorders characterized in the ‘pure’ phenotype by progressive spasticity and weakness of the lower limbs. In the ‘complex’ phenotype, additional neurologic symptoms or signs are found. Mutations in the NIPA1 gene have been reported to cause spastic paraplegia type 6 (SPG6) in 10 families. SPG6 is a rare form of autosomal dominantly inherited HSP associated with a pure phenotype; however, in one complex SPG6 family, idiopathic generalized epilepsy (IGE) has been described and in addition, recurrent microdeletions at 15q11.2 including NIPA1 have been identified in patients with IGE. The purpose was to identify NIPA1 mutations in patients with pure and complex HSP. Methods: Fifty‐two patients with HSP were screened for mutations in NIPA1. Results: One previously reported missense mutation c.316G>A, p.Gly106Arg, was identified in a complex HSP patient with spastic dysarthria, facial dystonia, atrophy of the small hand muscles, upper limb spasticity, and presumably IGE. The epilepsy co‐segregated with HSP in the family. Conclusion: NIPA1 mutations were rare in our population of patients with HSP, but can be found in patients with complex HSP. Epilepsy might be more common in SPG6 than in other forms of HSP because of a genetic risk factor closely linked to NIPA1.     

Genetics of hereditary spastic paraplegias

Hereditary spastic paraplegias (HSPs) are clinically and genetically highly heterogeneous. The key symptom of spastic paraparesis of lower limbs can be complicated by a variety of signs and symptoms including cognitive impairment, optic atrophy, cerebellar ataxia, peripheral nerve involvement, or seizures. At least 48 loci have been identified, termed SPG1-SPG48. Ten genes for autosomal dominant HSP are currently known, SPG4 being by far the most common subtype accounting for ～50% of cases. SPG3 is especially common in young-onset cases. Autosomal recessive HSP seems to be even more heterogeneous. The known 12 autosomal recessive HSP genes collectively explain about one third of cases only. The most common causes for pure autosomal recessive HSP are SPG7 and SPG5. Mental retardation and thin corpus callosum on magnetic resonance imaging point toward SPG11 and SPG15. The authors provide an overview on clinical, neurophysiologic, and neuroradiologic characteristics of the more common HSP subtypes. More details are given in the tables for quick reference, and a genetic testing strategy is proposed.     

Clinical and genetic findings in a series of Italian children with pure hereditary spastic paraplegia

Background: Hereditary spastic paraplegias (HSP) are a group of neurodegenerative disorders characterized by progressive lower extremity spastic weakness. SPG7, SPG4 and SPG3A are some of the autosomal genes recently found as mutated in recessive or dominant forms of HSP in childhood. SPG31 is more often associated with a pure spastic paraplegia phenotype, but genotype–phenotype correlation is still unclear. The aims of the current study was: (i) to verify the mutational frequency of SPG4, SPG3A, SPG31 and SPG7 genes in our very‐well‐selected childhood sample, and (ii) to improve our knowledge about the clinical and electrophysiological HSP phenotypes and their possible correlation with a specific mutation. Methods: A sample of 14 Italian children affected by pure HSP (mean age at diagnosis 5.9 years) was extensively investigated with electrophysiological, neuroradiological and genetic tests. Results: Three SPG4 mutations were identified in three patients: two novel missense mutations, both sporadic, and one multiexonic deletion already reported. A novel large deletion in SPG31 gene involving exons 2–5 was also detected in one young patient. No mutations in the SPG7 and in the SPG3A genes were found. Conclusions: Our data confirm that HSP represent a heterogeneous group of genetic neurodegenerative disorders, also in sporadic or autosomal recessive early onset forms. Multiplex Ligation‐dependent Probe Amplification‐based mutation screening for SPG4 and SPG31 genes would be added to sequencing‐based screening of SPG4, SPG31 and SPG3A genes in the routine diagnosis of HSP children.     

Sensory ataxia as a prominent clinical presentation in three families with mutations in CYP7B1

Pathogenic mutations in CYP7B1 account for SPG5, an autosomal recessive hereditary spastic paraplegia characterized by a complex phenotype including visual problems and cerebellar dysfunction. Sensory ataxia is not usually regarded as a typical clinical feature of SPG5. The purpose of this study was to describe six patients showing features of sensory ataxia as the prominent and/or initial symptoms of SPG5. Six patients from three distinct pedigrees (three women, three men; age 49.5 ± 18.2 years), all presenting gait unsteadiness and frequent falls since childhood, underwent clinical and molecular investigations. All showed marked sensory ataxic gait with positive Romberg's sign, as well as severely impaired position and vibration sense. Comparatively minor signs of pyramidal involvement were also detected. In four of the patients, brain MRI showed white matter hyperintensities on T2-weighted images. An already reported homozygous c.889A>G (p.T297A) mutation in SPG5/CYP7B1 was found in five patients from two families, whereas the remaining case harbored the novel c.250_251delC/p.L84Ffs*6 and c.266A>C/p.Y89S variants. Marked and enduring sensory ataxia can be a pivotal sign in SPG5, and expands the phenotypic spectrum associated with mutations in CYP7B1.     

Mutations in CYP2U1, DDHD2 and GBA2 genes are rare causes of complicated forms of hereditary spastic paraparesis

Complicated hereditary spastic paraplegias (HSP) are a heterogeneous group of HSP characterized by spasticity associated with a variable combination of neurologic and extra-neurologic signs and symptoms. Among them, HSP with thin corpus callosum and intellectual disability is a frequent subtype, often inherited as a recessive trait (ARHSP-TCC). Within this heterogeneous subgroup, SPG11 and SPG15 represent the most frequent subtypes. We analyzed the mutation frequency of three genes associated with early-onset forms of ARHSP with and without TCC, CYP2U1/SPG56, DDHD2/SPG54 and GBA2/SPG46, in a large population of selected complicated HSP patients by using a combined approach of traditional-based and amplicon-based high-throughput pooled-sequencing. Three families with mutations were identified, one for each of the genes analyzed. Novel homozygous mutations were identified in CYP2U1 (c.1A>C/p.Met1?) and in GBA2 (c.2048G>C/p.Gly683Arg), while the homozygous mutation found in DDHD2 (c.1978G>C/p.Asp660His) had been previously reported in a compound heterozygous state. The phenotypes associated with the CYP2U1 and DDHD2 mutations overlap the SPG56 and the SPG54 subtypes, respectively, with few differences. By contrast, the GBA2 mutated patients show phenotypes combining typical features of both the SPG46 subtype and the recessive ataxia form, with marked intrafamilial variability thereby expanding the spectrum of clinical entities associated with GBA2 mutations. Overall, each of three genes analyzed shows a low mutation frequency in a general population of complicated HSP (<1 % for either CYP2U1 or DDHD2 and approximately 2 % for GBA2). These findings underline once again the genetic heterogeneity of ARHSP-TCC and the clinical overlap between complicated HSP and the recessive ataxia syndromes.     

Further clinical and genetic characterization of SPG11: hereditary spastic paraplegia with thin corpus callosum

Hereditary spastic paraplegias (HSPs) are a heterogeneous group of neurodegenerative disorders leading to progressive spasticity of the lower limbs. Clinically, HSPs are divided into "pure" and "complicated" forms. In pure HSP, the spasticity of the lower limbs is the sole symptom, whereas in complicated forms additional neurological and non-neurological features are observed. Genetically, HSPs are divided into autosomal dominant (AD), autosomal recessive (AR) and X-linked (XL) forms. Up to date, 30 different HSPs are linked to different chromosomal loci and 11 genes could be defined for AR-HSP, AD-HSP and XL-HSP. SPG11, an AR-HSP (synonym: HSP11), is a complicated HSP associated with a slowly progressive spastic paraparesis, mental impairment and the development of a thin corpus callosum (TCC) during the course of the disease. SPG11 has been previously linked to chromosomal region 15q13 - 15. First, we applied rigid diagnostic criteria to systematically examine 20 Turkish families with autosomal recessive HSP for characteristic features of SPG11. We detected four large Turkish families with AR-HSP and TCC consistent with SPG11. Subsequent genetic linkage analysis of those 4 families refines the SPG11 locus further down to a small region of 2.93 cM with a maximum lod score of 11.84 at marker D15S659 and will guide further candidate gene analysis.     

A novel locus for pure recessive hereditary spastic paraplegia maps to 10q22.1-10q24.1

The hereditary spastic paraplegias (HSPs) are a group of clinically and genetically heterogeneous disorders characterized by progressive lower-limb spasticity. In this study, we performed linkage analysis on an autosomal recessive pure HSP family and mapped the disease to chromosome 10q22.1-10q24.1, a locus partially overlapping the existing SPG9 locus. We have either identified a novel locus for pure recessive HSP (SPG27), or we have found the first case of allelic disorders with different mode of inheritance in HSP. If the disorders are indeed allelic, our results have reduced the SPG9 interval by 3Mb with D10S536 and D10S1758 as flanking markers.     

SPG11 spastic paraplegia

Autosomal recessive hereditary spastic paraplegia (AR HSP) with thin corpus callosum (TCC) is a rare neurodegenerative disorder often caused by mutations in the gene encoding for spatacsin at the SPG11 locus on chromosome 15q. The disease is characterized by progressive spastic paraparesis and mental retardation which occur during the first two decades of life and frequently with peripheral neuropathy. Brain magnetic resonance imaging (MRI) reveals typical TCC with periventricular white matter changes. We describe two patients, of Turkish descent, from the same consanguineous family and affected with SPG11 in association with unusual early-onset parkinsonism. Parkinsonism occurred during the very early stages of SPG11 in both patients, being in one the inaugural symptom of the disease presented as a resting tremor with akinesia, rigidity and expressing an initial moderate levodopa-response that progressively weakened. The second patient presented a resting tremor with mild akinesia and no levodopa-response. Both patients were affected with progressive spastic paraparesis which had initially occurred at 15 and 12 years of age, respectively, in association with mild mental retardation and an axonal polyneuropathy. TCC with periventricular white matter changes (PWMC) was evident by MRI and ¹²³I-ioflupane SPECT was abnormal. Genetic analysis detected for both patients a new c.704_705delAT, p.H235RfsX12 homozygous mutation in SPG11. This report provides evidence that parkinsonism may initiate SPG11-linked HSP TCC and that SPG11 may cause juvenile parkinsonism.     

Complicated hereditary spastic paraplegia with thin corpus callosum (HSP-TCC) and childhood onset

The hereditary spastic paraplegias (HSPs) are a group of rare disorders with the predominant clinical feature of progressive spastic paraplegia. They are subdivided into pure and complicated forms according to whether the disorder is associated with other neurological abnormalities. We report on two unrelated female Caucasian patients with complicated HSP, aged 16 and 24 years, who showed progressive gait disturbance with spasticity and ataxia as well as cognitive impairment. Onset of symptoms was at age 3 and 10 years, respectively. MRI revealed mild diffuse non-progressive T (2)-signal alterations of cerebral white matter and thinning of the body and genu of the corpus callosum. Some similarity of clinical symptoms and MRI patterns with the phenotype of Mast syndrome prompted a mutation analysis of the SPG21 gene, encoding maspardin, which revealed a wild-type sequence in both patients. Clinical and neuroradiological features in our patients are diagnostic for complicated autosomal recessive hereditary spastic paraplegia with thin corpus callosum (HSP-TCC, SPG11). This disorder, characterized by a typical MRI pattern and a progressive spastic paraplegia that may be associated with dementia and ataxia, may have an onset in early childhood and probably is one of the more common forms of complicated HSP.     

Targeted disruption of the Mast syndrome gene SPG21 in mice impairs hind limb function and alters axon branching in cultured cortical neurons

Mast syndrome (SPG21) is a childhood-onset, autosomal recessive, complicated form of hereditary spastic paraplegia (HSP) characterized by dementia, thin corpus callosum, white matter abnormalities, and cerebellar and extrapyramidal signs in addition to spastic paraparesis. A nucleotide insertion resulting in premature truncation of the SPG21 gene product maspardin underlies this disorder, likely leading to loss of protein function. In this study, we generated SPG21−/− knockout mice by homologous recombination as a possible animal model for SPG21. Though SPG21−/− mice appeared normal at birth, within several months they developed gradually progressive hind limb dysfunction. Cerebral cortical neurons cultured from SPG21−/− mice exhibited significantly more axonal branching than neurons from wild-type animals, while comprehensive neuropathological analysis of SPG21−/− mice did not reveal definitive abnormalities. Since alterations in axon branching have been seen in neurons derived from animal models of other forms of HSP as well as motor neuron diseases, this may represent a common cellular pathogenic theme.     

Identification of a Mutation in SPG11 in an Iranian Patient with Spastic Paraplegia and Ears of the Lynx Sign

Hereditary spastic paraplegia (HSP) includes a number of inherited disorders which are characterized by stiffness in the lower extremities and progressive gait disturbance. Mutations in terms of spastic gait genes (SPGs) are responsible for occurrence of different types of HPS with autosomal recessive, X-linked recessive, and autosomal dominant modes of inheritance. In the current case report, we identified a mutation in SPG11 gene in a female patient with progressive stiffness of lower extremities and atrophy of corpus callosum and the “lynx ear” sign in brain MRI. Whole exome sequencing (WES) revealed a homozygote frameshift deletion variant in SPG11 gene (NM001160227: exon 28: c.4746delT, p.N1583Tfs*23). This variant is a null variant classified as a pathogenic variant (PVS1) according to ACMG standards and guidelines. The frequency of this variant in 1000G, ExAC, and Iranome databases was 0. This study shows the role of WES in the identification of disease-causing mutations in a disease such as HSP which can be caused by diverse mutations in several genes.     

Peripheral nerve involvement in hereditary spastic paraplegia characterized by quantitative magnetic resonance neurography

Background and objectives

Hereditary spastic paraplegias (HSPs) are heterogenous genetic disorders. While peripheral nerve involvement is frequent in spastic paraplegia 7 (SPG7), the evidence of peripheral nerve involvement in SPG4 is more controversial. We aimed to characterize lower extremity peripheral nerve involvement in SPG4 and SPG7 by quantitative magnetic resonance neurography (MRN).

Methods

Twenty-six HSP patients carrying either the SPG4 or SPG7 mutation and 26 age-/sex-matched healthy controls prospectively underwent high-resolution MRN with large coverage of the sciatic and tibial nerve. Dual-echo turbo-spin-echo sequences with spectral fat-saturation were utilized for T2-relaxometry and morphometric quantification, while two gradient-echo sequences with and without an off-resonance saturation rapid frequency pulse were applied for magnetization transfer contrast (MTC) imaging. HSP patients additionally underwent detailed neurologic and electroneurographic assessments.

Results

All microstructural (proton spin density [ρ], T2-relaxation time, magnetization transfer ratio) and morphometric (cross-sectional area) quantitative MRN markers were decreased in SPG4 and SPG7 indicating chronic axonopathy. ρ was superior in differentiating subgroups and identifying subclinical nerve damage in SPG4 and SPG7 without neurophysiologic signs of polyneuropathy. MRN markers correlated well with clinical scores and electroneurographic results.

Conclusions

MRN characterizes peripheral nerve involvement in SPG4 and SPG7 as a neuropathy with predominant axonal loss. Evidence of peripheral nerve involvement in SPG4 and SPG7, even without electroneurographically manifest polyneuropathy, and the good correlation of MRN markers with clinical measures of disease progression, challenge the traditional view of the existence of HSPs with isolated pyramidal signs and suggest MRN markers as potential progression biomarkers in HSP.     

Clinical phenotype of hereditary spastic paraplegia due to KIF1C gene mutations across life span

Hereditary spastic paraplegias (HSPs) are a group of genetic disorders resulting in pyramidal tract impairment, predominantly in lower limbs. KIF1C gene has recently been identified as one of the genetic causes of HSP and associated with pure or complicated HSP. We present three patients with complicated HSP from two unrelated families, who had early onset progressive cerebellar signs and developed pyramidal tract signs during follow-up. Whole exome sequencing in these patients followed by segregation analysis identified novel truncating KIF1C mutations (c.463C> T; p.R155¹ and c.2478delA; p.Ala828Argfs¹13). Neuroimaging findings showed cerebral and upper cervical spinal atrophy, bilateral symmetrical pyramidal tract involvement, and focal cerebral white matter lesions. Patients with KIF1C mutations may present with cerebellar signs and pyramidal findings may emerge later, therefore complicated HSP should be considered in the differential diagnosis of unidentified cases with cerebellar dysfunction.     

A novel homozygous mutation in ATP13A2 gene causing pure hereditary spastic paraplegia

SPG78 is a subtype of hereditary spastic paraplegia(HSP) caused by ATP13A2 gene mutations. SPG78 was reported as complicated HSP in several cases, but was never associated with pure HSP. Here we report the first Chinese patient carrying a novel homozygous nonsense mutation in ATP13A2 presenting with pure HSP.     

Hereditary spastic paraplegia with cerebellar ataxia: a complex phenotype associated with a new SPG4 gene mutation

Complex forms of hereditary spastic paraplegia (HSP) are rare and usually transmitted in an autosomal recessive pattern. A family of four generations with autosomal dominant hereditary spastic paraplegia (AD-HSP) and a complex phenotype with variably expressed co-existing ataxia, dysarthria, unipolar depression, epilepsy, migraine, and cognitive impairment was investigated. Genetic linkage analysis and sequencing of the SPG4 gene was performed and electrophysiologic investigations were carried out in six individuals and positron emission tomography (PET) in one patient. The disease was linked to the SPG4 locus on chromosome 2p as previously reported for pure HSP. Sequence analysis of the SPG4 (spastin) gene identified a novel 1593 C > T (GLN490Stop) mutation leading to premature termination of exon 12 with ensuing truncation of the encoded protein. However, the mutation was only identified in those individuals who were clinically affected by a complex phenotype consisting of HSP and cerebellar ataxia. Other features noted in this kindred including epilepsy, cognitive impairment, depression, and migraine did not segregate with the HSP phenotype or mutation, and therefore the significance of these features to SPG4 is unclear. Electrophysiologic investigation showed increased central conduction time at somatosensory evoked potentials measured from the lower limbs as the only abnormal finding in two affected individuals with the SPG4 mutation. Moreover, PET of one patient showed significantly relatively decreased regional cerebral blood flow in most of the cerebellum. We conclude that this kindred demonstrates a considerable overlap between cerebellar ataxia and spastic paraplegia, emphasizing the marked clinical heterogeneity of HSP associated with spastin mutations.