Skip to main content

Genotype-phenotype correlations and expansion of the molecular spectrum of AP4M1-related hereditary spastic paraplegia

Abstract

Background

Autosomal recessive hereditary spastic paraplegia (HSP) due to AP4M1 mutations is a very rare neurodevelopmental disorder reported for only a few patients.

Methods

We investigated a Greek HSP family using whole exome sequencing (WES).

Results

A novel AP4M1A frameshift insertion, and a very rare missense variant were identified in all three affected siblings in the compound heterozygous state (p.V174fs and p.C319R); the unaffected parents were carriers of only one variant. Patients were affected with a combination of: (a) febrile seizures with onset in the first year of life (followed by epileptic non-febrile seizures); (b) distinctive facial appearance (e.g., coarse features, bulbous nose and hypomimia); (c) developmental delay and intellectual disability; (d) early-onset spastic weakness of the lower limbs; and (e) cerebellar hypoplasia/atrophy on brain MRI.

Conclusions

We review genotype-phenotype correlations and discuss clinical overlaps between different AP4-related diseases. The AP4M1 belongs to a complex that mediates vesicle trafficking of glutamate receptors, being likely involved in brain development and neurotransmission.

Background

Clinically and genetically heterogeneous neurological disorders constitute huge challenges for clinicians and geneticists as the number of genes associated with a wide range of overlapping phenotypes is constantly increasing. For the molecular diagnosis of these disorders gene-by-gene screens are progressively being replaced by more time and cost effective next generation sequencing approaches (candidate gene panels or whole-exome sequencing) [1, 2]. Hereditary spastic paraplegias (HSPs) are an example of such a heterogeneous group of disorders, for which more than 70 loci have already been mapped and yet the landscape of HSP loci and genes is far from complete [3]. HSPs are characterized by progressive spasticity and weakness of the lower limbs due to corticospinal tract dysfunction. HSPs are broadly classified as uncomplicated or complicated on the basis of the presence of additional clinical features such as intellectual disability, seizures, ataxia, peripheral neuropathy and visual defects [4].

HSP-associated genes are involved in a wide variety of primary molecular functions, resulting for example in disturbances in vesicle formation and membrane trafficking including selective uptake of proteins into vesicles when such genes are mutated [4]. This is the case for the subunits of the heterotetrameric adaptor protein complex 4 (AP-4). AP-4 is composed of two large chains beta-4 (AP4B1; MIM#607245) and epsilon-4 (AP4E1; MIM#607244), a medium mu-4 chain (AP4M1; MIM#602296), and a small sigma-4 chain (AP4S1; MIM#607243).

AP-4 complex-mediated trafficking is thought to play a crucial role in brain development and functioning. All genes encoding for the proteins part of this complex have been associated with genetic forms of HSP (e.g. AP4B1 [SPG47], AP4M1 [SPG50], AP4E1 [SPG51], and AP4S1 [SPG52]) [4, 5]. We hereby report on a Greek family with SPG50 (MIM#612936) caused by two heterozygous AP4M1 variants in a compound heterozygous state. We also discuss on the genotype-phenotype correlations and the spectrum of AP4-related diseases.

Methods

Subjects

We have studied a Greek family (Fig. 1) composed of three affected siblings born to healthy parents, who presented with complicated HSP. History of previous neurological disease was unremarkable in the family and the pedigree suggested an autosomal recessive inheritance. Thorough neurological examination and follow-up were carried out at the Departments of Neurology of the AHEPA Hospital and Papageorgiou Hospital by some of the authors (GX, TK, GD, MS, TB and HH). This study was approved by the UCLH institutional-research-board. After informed consent, we collected blood samples from the patients and their parents, and extracted DNA using standard procedures. Additional informed consent was obtained from all individual participants for whom identifying information is included in this manuscript.

Fig. 1
figure 1

The three siblings affected by complicated HSP due to AP4M1 compound heterozygous mutation. a Note facial coarse features, convergent bilateral strabismus, prominent and bulbous nose, and wide mouth in all the three siblings; (b) In the left panel familial pedigree (the asterisks specify the sequenced individuals with the arrow pointing to the proband) with black and white symbols indicating affected and unaffected individuals, respectively; in the right panel electropherograms illustrating the AP4M1 variants identified in our family; (c) A schematic representation of the AP4M1 gene and protein depicting the location of the mutations found in our family (in red) and those previously reported in the literature (in black) for this gene (MIM#602296), and highlighting the MHD, which is a protein-protein interaction module. HSP = Hereditary Spastic Paraplegia. MHD = mu homology domain

Genetic analysis

To investigate the genetic cause of the disease in this family, whole-exome sequencing (WES) was performed in the proband (Fig. 1b: II-3) and his father (Fig.1b: I-1). Nextera Rapid Capture Enrichment kit (Illumina) was used according to the manufacturer instructions. Libraries were sequenced in an Illumina HiSeq3000 using a 100-bp paired-end reads protocol. Sequence alignment to the human reference genome (UCSC hg19), and variants call and annotation were performed using an in-house pipeline as described elsewhere [6]. The raw list of single nucleotide variants (SNVs) and indels was then filtered. Only exonic and donor/acceptor splicing variants were considered. In accordance with the pedigree and phenotype, priority was given to rare variants [<1% in public databases, including 1000 Genomes project, NHLBI Exome Variant Server, Complete Genomics 69, and Exome Aggregation Consortium (ExAC v0.2)] fitting a recessive model (i.e. homozygous in the proband but heterozygous in the father or compound heterozygous in the proband but not in the father), and located in genes previously associated with HSP [3, 7].

The AP4M1A mutations (in exons 6 and 12) identified by WES in the proband were confirmed by traditional Sanger sequencing and also segregation analysis of the mutation in the family was performed. Detailed conditions of sequencing analysis are available upon request.

Results

Clinico-radiological phenotype

The three affected siblings (Fig. 1b: II-1, II-2 and II-3) have a phenotype consisting of complicated HSP. All of them showed early-onset and severe spastic lower limb weakness, brisk deep tendon reflexes, presence of Babinski sign and severe gait difficulties. The older male and the female (Fig. 1b: II-1 and II-2, respectively) need assistance to stand up. Only the younger male (Fig. 1b: II-3) is able to stand up independently and walk a few steps unassisted. The gait is characterized by feet dragging, shaking and leg scissoring. All three siblings have upper limbs weakness, more obvious in the proximal muscle groups, especially for the two older siblings. The facial muscles are hypotonic with reduced facial expressions. The facial appearance of the three siblings is characterized by coarse features, a prominent and bulbous nose and a wide mouth (Fig. 1a; left panel patient II-1, middle panel patient II-3, right panel patient II-2).

Interestingly, all affected siblings present hypometric and slow vertical saccades, especially at the upward gaze. Some limb ataxia is also present. There are no prominent extrapyramidal signs.

All three siblings have severe intellectual disability. Additional cognitive/behavioral abnormalities include apathy, reduced motor planning and/or initiation, attention-deficit disorder. An impairment of speech is also present, especially for the older male who has very poor language skills.

All siblings were born without any adverse perinatal events and had normal development during the first months of their lives. All three presented febrile tonic-clonic seizures during the first year of life, which were soon followed by epileptic non-febrile seizures. Developmental delay was noticed since early infancy. Only the younger brother (Fig. 1b; patient II-3) managed to walk independently during childhood but later his motor skills also started to gradually decline. The language and social skills of all three siblings were also lagging behind during their childhood and eventually showing some serious deficits by their puberty.

Spastic Paraplegia Rating Scale (SPRS) [8] was assessed for all 3 siblings: the older male and the female (Fig. 1b: II-1 and II-2, respectively) both scored 40 out of a maximum of 52, while the younger male (Fig. 1b: II-3) scored 35/52.

Other disorders presenting with spastic paraparesis (e.g. abetalipoproteinemia, funicular myelosis, multiple sclerosis, AIDS, lues, adrenoleucodystrophy, etc.) were excluded after an extensive diagnostic work-up that included brain magnetic resonance imaging (MRI), cerebrospinal fluid (CSF) analysis, nerve conduction and evoked potentials studies, electromyography (EMG), electroencephalography (EEG), serum vitamin B12 and E levels, serum arylsulphatase, galactocerebrosidase and very long chain fatty acids (VLCFA) levels, HTLV-1 antibodies, HIV and syphilis serology.

The brain MRI showed cerebellar hypoplasia/atrophy and downsloping splenium of the corpus callosum (Fig. 2).

Fig. 2
figure 2

Brain MRI of the three affected siblings. a T2-weighted coronal scan of the older male patient (Fig. 1b: II-1) demonstrates cerebellar hypoplasia/atrophy with the impression of a cleft in the lateral cerebellar hemisphere. Note that the brainstem volume is preserved; (b, c, d) T1-weighted sagittal scans with contrast of all three siblings (Fig. 1b: II-1, II-2 and II-3, respectively) show slight hypoplasia/atrophy of the cerebellar vermis. Also, there is downsloping splenium of the corpus callosum

Nerve conduction studies showed no evidence of peripheral neuropathy. Somatosensory evoked potentials (SSEPs) of median and tibial nerve were remarkable for prolongation of cortical latencies (N13-N20 and P40, respectively).

EEG was reported normal for the three siblings, without findings of focal slowing or seizure-like activity. More specifically, EEG recordings showed background of 9 to 10 hertz alpha activity, maximal over the posterior head region. These activities were symmetric on both sides and attenuated with eye opening. No focal slowing was seen and no seizure-like activity was observed during the recording. Patient entered into periods of drowsiness and light sleep. No abnormality was seen.

All clinical and radiological features are summarized in Table 1, and compared to other cases of HSP due to AP4M1 mutations previously reported in literature.

Table 1 Summary of clinical and radiological features of patients with AP4M1 mutations

Sequence analysis

WES generated a total of 136,968,572 (proband, Fig. 1b: II-3) and 145,150,172 (father, Fig. 1b: I-1) unique reads, with an average on target depth over 160 reads, and >98% of the target bases covered at least 10X. A total of 24,872 (proband) and 25,228 (father) exonic/splicing variants were detected. After applying our filtering strategy described above, we identified two heterozygous AP4M1 (SPG50) variants in the proband, a novel frameshift insertion (c.521dupT; p.V174fs in exon 6), and a very rare (<2.5 × 10−5 in public databases) missense variant (c.955 T > C; p.C319R in exon 12). Only one of these variants was present in the father (c.955 T > C; p.C319R). No other rare homozygous or compound heterozygous variants were found in genes of relevance for the phenotype, including all know HSP genes. The AP4M1frameshift variant causes a very premature stop codon, truncating the protein (if expressed at all) to 179 amino acids (wild-type: 453 amino acids), just before the mu homology domain (MHD) which is an essential protein-protein interaction module (Fig. 1c). The missense variant lays on a highly conserved position (GERP++ score [9] of 4.75) of the MHD domain, and is predicted to be damaging by several prediction tools (including SIFT [10], PolyPhen2 [11], and MutationTaster [12]). Segregation analysis by Sanger sequencing showed that all three affected siblings have both variants, whereas the father carries only the missense and the mother carries only the frameshift (Fig. 1b), confirming that the compound heterozygous state of these variants is segregating with the phenotype.

Discussion

Very few patients and families have been described in the literature with mutations in the AP4M1 gene. The reported phenotype is mainly characterized by the combination of infantile hypotonia, developmental delay, intellectual disability, early-onset spastic paraplegia, and variable white matter and cerebellar involvement on brain MRI; only four pathogenic AP4M1 mutations (Fig.1c) have been reported to date in SPG50 patients [5, 13,14,15,16,17].

Our pedigree is compatible with an autosomal recessive complicated spastic paraplegia, and the two variants we identified in the AP4M1 gene, segregating with the phenotype, are very likely the cause of the phenotype in this family. Copy number variants (CNVs) involving the AP4M1 gene have also been implicated in developmental disabilities or congenital anomalies [18, 19]. The AP4M1 gene is highly expressed in the brain especially during foetal development (see Additional file 1: Figure S1), and disruption of its function compromises proper brain development and likely impairs neuronal excitability.

Notably, patients with biallelic loss-of-function mutations of AP4M1 have been initially reported with a phenotype presenting at birth with severe infantile hypotonia and diffuse white matter loss on brain MRI. For this reason it has been postulated that the genetic defect in these patients results in abnormal cycling of glutamate receptors, mimicking glutamate-mediated perinatal white matter injury [13]. Interestingly, the affected siblings from our family showed a milder presentation, with normal muscular tone during their infancy and no white matter involvement on their brain MRI, similarly to the other few patients reported with recessive missense mutations in AP4M1 [5]. It is therefore possible that in our cases the missense mutation inherited on the paternal allele resulted in a milder phenotype because of a residual function of the gene, compared to the most severe cases where homozygous splicing mutations have been identified as the cause of the disorder [13].

Interestingly, the earliest manifestation in the natural history of the disease in our patients were tonic-clonic seizures (precipitated by fever), which appeared since the first months after birth. Of note, febrile seizures with onset in the first year of life represent common features of AP4B1 deficiency, an overlapping (autosomal recessive) HSP phenotype (SPG47; MIM#614066) caused by mutations in the gene encoding the large b4 chain of the AP-4 complex [20].

It has been shown that the loss or structural change of a single AP-4 subunit impairs the integrity of the entire AP-4 complex [21]. Consequently, mutations in any of the AP-4 subunits would presumably have similar downstream effects on vesicular glutamate receptor transport and neurotransmission, resulting in similar clinical presentations (e.g., altered neuronal excitability and risk of developing infantile febrile seizures in both AP4B1- and AP4M1 -related phenotypes). These observations are further corroborated by the few patients reported with recessive missense mutations in AP4M1, who also presented seizures (precipitated by fever) during their first year of life [5].

Conclusions

We reported on genotype-phenotype correlations in SPG50, basing on a Greek family with three affected individuals and the few previously reported patients, and also expanded the molecular spectrum associated with this phenotype. Further studies will be needed to investigate the role of AP-4 in brain development and neurotransmission and to fully understand the pathophysiology of childhood epilepsy in these patients.

Abbreviations

AIDS:

Acquired immune deficiency syndrome

AP-4:

Adaptor protein complex 4

CNVs:

Copy number variants

CSF:

Cerebrospinal fluid

DNA:

Deoxyribonucleic acid

EEG:

Electroencephalography

EMG:

Electromyography

ExAC:

Exome Aggregation Consortium

GERP++:

Genomic Evolutionary Rate Profiling

HIV:

Human immunodeficiency virus

HSP:

Hereditary spastic paraplegia

HTLV-1:

Human T-cell lymphotropic virus type 1

Indels:

Small insertions and deletions

MHD:

Mu homology domain

MIM:

Online Mendelian Inheritance in Man database reference number

MRI:

Magnetic resonance imaging

NHLBI:

National Heart, Lung, and Blood Institute from the National Institutes of Health

PolyPhen2:

Polymorphism Phenotyping v2 algorithm

SIFT:

Sorting tolerant from intolerant algorithm

SNVs:

Single nucleotide variants

SPG47:

Spastic paraplegia type 47

SPG50:

Spastic paraplegia type 50

SPG51:

Spastic paraplegia type 51

SPG52:

Spastic paraplegia type 52

SPRS:

Spastic paraplegia rating scale

SSEPs:

Somatosensory evoked potentials

VLCFA:

Very long chain fatty acids

WES:

Whole-exome sequencing

References

  1. Bettencourt C, Lopez-Sendon JL, Garcia-Caldentey J, Rizzu P, Bakker IM, Shomroni O, Quintans B, Davila JR, Bevova MR, Sobrido MJ, Heutink P, de Yebenes JG. Exome sequencing is a useful diagnostic tool for complicated forms of hereditary spastic paraplegia. Clin Genet. 2014;85:154–8.

    Article  CAS  PubMed  Google Scholar 

  2. Morgan S, Shoai M, Fratta P, Sidle K, Orrell R, Sweeney MG, Shatunov A, Sproviero W, Jones A, Al-Chalabi A, Malaspina A, Houlden H, Hardy J, Pittman A. Investigation of next-generation sequencing technologies as a diagnostic tool for amyotrophic lateral sclerosis. Neurobiol Aging. 1600;2015(36):e1605–8.

    Google Scholar 

  3. Novarino G, Fenstermaker AG, Zaki MS, Hofree M, Silhavy JL, Heiberg AD, Abdellateef M, Rosti B, Scott E, Mansour L, Masri A, Kayserili H, Al-Aama JY, Abdel-Salam GM, Karminejad A, Kara M, Kara B, Bozorgmehri B, Ben-Omran T, Mojahedi F, Mahmoud IG, Bouslam N, Bouhouche A, Benomar A, Hanein S, Raymond L, Forlani S, Mascaro M, Selim L, Shehata N, Al-Allawi N, Bindu PS, Azam M, Gunel M, Caglayan A, Bilguvar K, Tolun A, Issa MY, Schroth J, Spencer EG, Rosti RO, Akizu N, Vaux KK, Johansen A, Koh AA, Megahed H, Durr A, Brice A, Stevanin G, Gabriel SB, Ideker T, Gleeson JG. Exome sequencing links corticospinal motor neuron disease to common neurodegenerative disorders. Science. 2014;343:506-511.

  4. Fink JK. Hereditary spastic paraplegia: clinico-pathologic features and emerging molecular mechanisms. Acta Neuropathol. 2013;126:307–28.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  5. Tuysuz B, Bilguvar K, Kocer N, Yalcinkaya C, Caglayan O, Gul E, Sahin S, Comu SGunel M. Autosomal recessive spastic tetraplegia caused by AP4M1 and AP4B1 gene mutation: expansion of the facial and neuroimaging features. Am J Med Genet A. 2014;164A:1677–85.

    Article  PubMed  Google Scholar 

  6. Mencacci NE, Rubio-Agusti I, Zdebik A, Asmus F, Ludtmann MH, Ryten M, Plagnol V, Hauser AK, Bandres-Ciga S, Bettencourt C, Forabosco P, Hughes D, Soutar MM, Peall K, Morris HR, Trabzuni D, Tekman M, Stanescu HC, Kleta R, Carecchio M, Zorzi G, Nardocci N, Garavaglia B, Lohmann E, Weissbach A, Klein C, Hardy J, Pittman AM, Foltynie T, Abramov AY, Gasser T, Bhatia KPWood NW. A missense mutation in KCTD17 causes autosomal dominant myoclonus-dystonia. Am J Hum Genet. 2015;96:938–47.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  7. Bettencourt C, Quintans B, Ros R, Ampuero I, Yanez Z, Pascual SI, de Yebenes JGSobrido MJ. Revisiting genotype-phenotype overlap in neurogenetics: triplet-repeat expansions mimicking spastic paraplegias. Hum Mutat. 2012;33:1315–23.

    Article  CAS  PubMed  Google Scholar 

  8. Schule R, Holland-Letz T, Klimpe S, Kassubek J, Klopstock T, Mall V, Otto S, Winner BSchols L. The spastic paraplegia rating scale (SPRS): a reliable and valid measure of disease severity. Neurology. 2006;67:430–4.

    Article  CAS  PubMed  Google Scholar 

  9. Davydov EV, Goode DL, Sirota M, Cooper GM, Sidow ABatzoglou S. Identifying a high fraction of the human genome to be under selective constraint using GERP++. PLoS Comput Biol. 2010;6:e1001025.

    Article  PubMed  PubMed Central  Google Scholar 

  10. Kumar P, Henikoff SNg PC. Predicting the effects of coding non-synonymous variants on protein function using the SIFT algorithm. Nat Protoc. 2009;4:1073–81.

    Article  CAS  PubMed  Google Scholar 

  11. Adzhubei I, Jordan DM, Sunyaev SR. Predicting functional effect of human missense mutations using PolyPhen-2. Curr Protoc Hum Genet. 2013;Chapter 7:Unit7 20.

    PubMed  Google Scholar 

  12. Schwarz JM, Rodelsperger C, Schuelke MSeelow D. MutationTaster evaluates disease-causing potential of sequence alterations. Nat Methods. 2010;7:575–6.

    Article  CAS  PubMed  Google Scholar 

  13. Verkerk AJ, Schot R, Dumee B, Schellekens K, Swagemakers S, Bertoli-Avella AM, Lequin MH, Dudink J, Govaert P, van Zwol AL, Hirst J, Wessels MW, Catsman-Berrevoets C, Verheijen FW, de Graaff E, de Coo IF, Kros JM, Willemsen R, Willems PJ, van der Spek PJ, Mancini GM. Mutation in the AP4M1 gene provides a model for neuroaxonal injury in cerebral palsy. Am J Hum Genet. 2009;85:40–52.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  14. Jameel M, Klar J, Tariq M, Moawia A, Altaf Malik N, Seema Waseem S, Abdullah U, Naeem Khan T, Raininko R, Baig SM, Dahl N. A novel AP4M1 mutation in autosomal recessive cerebral palsy syndrome and clinical expansion of AP-4 deficiency. BMC Med Genet. 2014;15:133.

    Article  PubMed  PubMed Central  Google Scholar 

  15. Langouet M, Siquier-Pernet K, Sanquer S, Bole-Feysot C, Nitschke P, Boddaert N, Munnich A, Mancini GM, Barouki R, Amiel JColleaux L. Contiguous mutation syndrome in the era of high-throughput sequencing. Mol Genet Genomic Med. 2015;3:215–20.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  16. Najmabadi H, Hu H, Garshasbi M, Zemojtel T, Abedini SS, Chen W, Hosseini M, Behjati F, Haas S, Jamali P, Zecha A, Mohseni M, Puttmann L, Vahid LN, Jensen C, Moheb LA, Bienek M, Larti F, Mueller I, Weissmann R, Darvish H, Wrogemann K, Hadavi V, Lipkowitz B, Esmaeeli-Nieh S, Wieczorek D, Kariminejad R, Firouzabadi SG, Cohen M, Fattahi Z, Rost I, Mojahedi F, Hertzberg C, Dehghan A, Rajab A, Banavandi MJ, Hoffer J, Falah M, Musante L, Kalscheuer V, Ullmann R, Kuss AW, Tzschach A, Kahrizi K, Ropers HH. Deep sequencing reveals 50 novel genes for recessive cognitive disorders. Nature. 2011;478:57–63.

    Article  CAS  PubMed  Google Scholar 

  17. Alazami AM, Patel N, Shamseldin HE, Anazi S, Al-Dosari MS, Alzahrani F, Hijazi H, Alshammari M, Aldahmesh MA, Salih MA, Faqeih E, Alhashem A, Bashiri FA, Al-Owain M, Kentab AY, Sogaty S, Al Tala S, Temsah MH, Tulbah M, Aljelaify RF, Alshahwan SA, Seidahmed MZ, Alhadid AA, Aldhalaan H, AlQallaf F, Kurdi W, Alfadhel M, Babay Z, Alsogheer M, Kaya N, Al-Hassnan ZN, Abdel-Salam GM, Al-Sannaa N, Al Mutairi F, El Khashab HY, Bohlega S, Jia X, Nguyen HC, Hammami R, Adly N, Mohamed JY, Abdulwahab F, Ibrahim N, Naim EA, Al-Younes B, Meyer BF, Hashem M, Shaheen R, Xiong Y, Abouelhoda M, Aldeeri AA, Monies DMA, Ikuraya FS. Accelerating novel candidate gene discovery in neurogenetic disorders via whole-exome sequencing of prescreened multiplex consanguineous families. Cell Rep. 2015;10:148–61.

    Article  CAS  PubMed  Google Scholar 

  18. Miller DT, Adam MP, Aradhya S, Biesecker LG, Brothman AR, Carter NP, Church DM, Crolla JA, Eichler EE, Epstein CJ, Faucett WA, Feuk L, Friedman JM, Hamosh A, Jackson L, Kaminsky EB, Kok K, Krantz ID, Kuhn RM, Lee C, Ostell JM, Rosenberg C, Scherer SW, Spinner NB, Stavropoulos DJ, Tepperberg JH, Thorland EC, Vermeesch JR, Waggoner DJ, Watson MS, Martin CL, Ledbetter DH. Consensus statement: chromosomal microarray is a first-tier clinical diagnostic test for individuals with developmental disabilities or congenital anomalies. Am J Hum Genet. 2010;86:749–64.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  19. Kaminsky EB, Kaul V, Paschall J, Church DM, Bunke B, Kunig D, Moreno-De-Luca D, Moreno-De-Luca A, Mulle JG, Warren ST, Richard G, Compton JG, Fuller AE, Gliem TJ, Huang S, Collinson MN, Beal SJ, Ackley T, Pickering DL, Golden DM, Aston E, Whitby H, Shetty S, Rossi MR, Rudd MK, South ST, Brothman AR, Sanger WG, Iyer RK, Crolla JA, Thorland EC, Aradhya S, Ledbetter DH, Martin CL. An evidence-based approach to establish the functional and clinical significance of copy number variants in intellectual and developmental disabilities. Genet Med. 2011;13:777–84.

    Article  PubMed  PubMed Central  Google Scholar 

  20. Finsterer J, Loscher W, Quasthoff S, Wanschitz J, Auer-Grumbach MStevanin G. Hereditary spastic paraplegias with autosomal dominant, recessive, X-linked, or maternal trait of inheritance. J Neurol Sci. 2012;318:1–18.

    Article  PubMed  Google Scholar 

  21. Kim MY, Jeong BC, Lee JH, Kee HJ, Kook H, Kim NS, Kim YH, Kim JK, Ahn KYKim KK. A repressor complex, AP4 transcription factor and geminin, negatively regulates expression of target genes in nonneuronal cells. Proc Natl Acad Sci U S A. 2006;103:13074–9.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

Download references

Acknowledgements

We are grateful to the patients and family for their contribution.

Funding

This study was supported by The Wellcome Trust in equipment and strategic award (Synaptopathies) funding (WT093205 MA and WT104033AIA), and by the Intramural Research Program of the National Institute on Aging, National Institutes of Health, Department of Health and Human Services (project ZO1 AG000957).

Availability of data and materials

Please contact authors for data requests.

Author information

Authors and Affiliations

Authors

Contributions

CB and VS were involved in the study design, data analysis and manuscript drafting. SE performed Sanger sequencing. DH and MF performed exome sequencing. AMP participated in the data analysis. TB participated in clinical evaluation of the patients and manuscript drafting. VC, MS, GD, and TK participated in clinical evaluation of the patients. HH, ABS, and GX were involved in the study design, performed clinical evaluation of the patients and critical evaluation of the manuscript. All authors read and approved the final manuscript.

Corresponding authors

Correspondence to Conceição Bettencourt, Vincenzo Salpietro or Henry Houlden.

Ethics declarations

Ethics approval and consent to participate

This study was approved by the UCLH institutional-research-board and informed consent was obtained from participants.

Consent for publication

Consent for publication was obtained from participants.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Additional file

Additional file 1: FigureS1.

Expression of the AP4M1 gene in several regions of the human brain throughout development and aging. Note the higher expression levels during fetal development (birth is marked with a vertical solid line). Data from the Human Brain Transcriptome (HBT) project (http://hbatlas.org). CBC - cerebellar cortex, MD - mediodorsal nucleus of the thalamus, STR - striatum, AMY - amygdala, HIP - hippocampus, and NCX – neocortex. (PDF 68 kb)

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Bettencourt, C., Salpietro, V., Efthymiou, S. et al. Genotype-phenotype correlations and expansion of the molecular spectrum of AP4M1-related hereditary spastic paraplegia. Orphanet J Rare Dis 12, 172 (2017). https://doi.org/10.1186/s13023-017-0721-2

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/s13023-017-0721-2

Keywords