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Review

New Insights into Potocki-Shaffer Syndrome: Report of Two Novel Cases and Literature Review

1
Department of Medical Sciences, University of Torino, 10126 Turin, Italy
2
Medical Genetics Unit, Città della Salute e della Scienza, University Hospital, 10126 Turin, Italy
3
Department of Public Health and Paediatrics, University of Torino, 10126 Turin, Italy
4
Centre de Génétique Humaine, Université de Franche-Comté, 25000 Besançon, France
5
Service de Pédiatrie, CHU, 25000 Besançon, France
6
Oncobiologie Génétique Bioinformatique, PCBio, Centre Hospitalier Universitaire de Besançon, 25000 Besançon, France
7
UMR-Inserm 1231 GAD, Génétique des Anomalies du développement, Université de Bourgogne Franche-Comté, 21000 Dijon, France
8
Fédération Hospitalo-Universitaire Médecine Translationnelle et Anomalies du Développement (FHU TRANSLAD), Centre Hospitalier Universitaire de Dijon et Université de Bourgogne Franche-Comté, 21000 Dijon, France
*
Author to whom correspondence should be addressed.
Brain Sci. 2020, 10(11), 788; https://doi.org/10.3390/brainsci10110788
Submission received: 31 August 2020 / Revised: 16 October 2020 / Accepted: 27 October 2020 / Published: 28 October 2020
(This article belongs to the Collection Collection on Developmental Neuroscience)

Abstract

:
Potocki-Shaffer syndrome (PSS) is a rare non-recurrent contiguous gene deletion syndrome involving chromosome 11p11.2. Current literature implies a minimal region with haploinsufficiency of three genes, ALX4 (parietal foramina), EXT2 (multiple exostoses), and PHF21A (craniofacial anomalies, and intellectual disability). The rest of the PSS phenotype is still not associated with a specific gene. We report a systematic review of the literature and included two novel cases. Because deletions are highly variable in size, we defined three groups of patients considering the PSS-genes involved. We found 23 full PSS cases (ALX4, EXT2, and PHF21A), 14 cases with EXT2-ALX4, and three with PHF21A only. Among the latter, we describe a novel male child showing developmental delay, café-au-lait spots, liner postnatal overgrowth and West-like epileptic encephalopathy. We suggest PSS cases may have epileptic spasms early in life, and PHF21A is likely to be the causative gene. Given their subtle presentation these may be overlooked and if left untreated could lead to a severe type or deterioration in the developmental plateau. If our hypothesis is correct, a timely therapy may ameliorate PSS phenotype and improve patients’ outcomes. Our analysis also shows PHF21A is a candidate for the overgrowth phenotype.

Graphical Abstract

1. Introduction

Structural genetic variation is a class of sequence alterations typically spanning more than 1 kb [1]. They include quantitative variations such as copy number variations (CNVs), the most prevalent type of structural variation, and other alterations, including chromosomal rearrangements. They can span from thousands to millions of bases whose copy number varies between different individuals, and are the result of DNA gains or losses [2,3].
CNVs can be responsible for genomic disorders, Mendelian diseases associated with large gains, and losses of genetic material [4]. A number of well-delineated genomic disorders are presently known and can be divided into two main categories: recurrent genomic disorders, which span the same region and originate independently de novo in different patients, and the non-recurrent genomic disorders, whose extension is different in each patient although the disease-associated gene(s) is/are always included. Recurrent rearrangements are caused by nonallelic homologous recombination (NAHR) between flanking low-copy repeats (LCRs), or repetitive elements such as LINE and HERV elements [5,6]. Non-recurrent rearrangements are caused by more complex mechanisms, such as non-homologous end joining (NHEJ), fork stalling, and template switching (FoSTeS)/microhomology-mediated BIR (MMBIR) [7]. Their breakpoints are therefore variable hampering the identification of the causative gene associated with the disease.
Genomic disorders can include both (i) contiguous gene deletions or duplications as seen in Williams-Beuren syndrome (MIM# 194050), where more than one causative gene is present [8] or (ii) CNVs of genes or portions of genes (exons) leading to Mendelian disorders (e.g., Rubinstein-Taybi syndrome; MIM# 180849) [9].
The main molecular mechanism is related to changes in dosage sensitive genes, in other words, genes whose dosage is critical to determine a healthy phenotype. Both deletions leading to haploinsufficiency or duplications leading to triplosensitivity can lead to a phenotype [10]. The identification of causative genes within the critical region of a genomic disorder is complex. It can rely on the availability of haploinsufficiency scores provided by the GnomAD consortium [11], and the detection of several affected subjects with a deleted/duplicated region showing overlap on a few candidate genes.
We focused our attention on the Potocki-Shaffer syndrome (PSS), a rare non-recurrent contiguous gene deletion syndrome mapping on 11p11.2 (MIM# 601224) [12,13]. The classical phenotype comprises multiple exostoses, biparietal foramina, and neurodevelopmental delay as cardinal features. Craniofacial abnormalities, epilepsy, tapering fingers, eye and hearing abnormalities, hypothyroidism, immunodeficiency, and genital malformations in males have also been reported [14].
Current literature implies a critical minimal region with haploinsufficiency of three genes: aristaless-like homeobox 4 (ALX4, MIM* 605420), exostosin 2 (EXT2, MIM* 60821), and PHD finger protein 21A (PHF21A, MIM* 608325). In rare cases, the deletion extends centromerically causing overlap with the WAGR syndrome (Wilms’ tumor, aniridia, genitourinary anomalies/gonadoblastoma and mental retardation) [15,16,17]. Haploinsufficiency for PAX6 (causing aniridia, MIM# 106210) [18] and WT1 genes (predisposing Wilms’ tumor, genital abnormalities, and nephropathies, MIM# 194072) [19] lead to the main WAGR features.
Here, we report a critical revision of the literature grouping describing patients in three categories based on the presence of the PSS-associated genes within the deletion (ALX4, EXT2, and PHF21A; EXT2-ALX4; and PHF21A only). We also describe a novel PSS female patient (Decipher 286390) and the third smallest de novo 11p11.2 microdeletion spanning PHF21A (Decipher 415213) in a male with developmental delay (DD), intellectual disability (ID), café-au-lait spots, liner postnatal overgrowth, and West-like pharmacoresistant epilepsy. These latter cases are instrumental to better define the role of PHF21A in the phenotype.

2. Materials and Methods

Genomic DNA was isolated from peripheral blood using a standard procedure (Qiagen, Hilden, Germany) and quantified by Nanodrop spectrophotometer (Thermo Scientific, Waltham, MA, USA). We performed array-CGH with a 60 K whole-genome oligonucleotide microarray following the manufacturer’s protocol. Slides were scanned using a G2565BA scanner (Agilent Technologies, Santa Clara, CA, USA) and analyzed using CytoGenomics version 5.0.2.5 (Agilent Technologies, Santa Clara, CA, USA) with the statistical algorithm ADM-2 and a sensitivity threshold of 6.0. At least three consecutive aberrant probes identified significant copy-number changes. We compared our findings to known CNVs listed in the Database of Genomic Variants (DGV, http://projects.tcag.ca/variation) and in the DECIPHER database (https://decipher.sanger.ac.uk/). TaqMan real-time quantitative PCR (qPCR) analysis (was used to measure copy number variants at 11p11.2 in genomic DNA on the gene PEX16 (NM_057174.3, exon 11), primers 5′-cagagcctggtgaacagtga; 5′-aggatgcagggcttaaagtg; #36 UPL probe (Roche Diagnostics, Risch-Rotkreuz, Switzerland); with RnaseP reference gene, VIC-labeled pre-designed TaqMan gene expression assays (P/N 4316844, Applied Biosystems, Thermo Fisher Scientific, Waltham, MA, USA). We carried out the reaction with an ABI 7500 Fast real-time PCR machine using the ABI TaqMan Universal PCR master mix according to the manufacturer’s instructions (Applied Biosystems, Thermo Scientific, Waltham, MA, USA). Efficiencies of the assays were similar and in a range of 90–110%. Samples from affected individuals and unrelated healthy controls were run in triplicate. The mean Ct value was used for calculations using the ΔΔCt method [20].
All subjects gave their informed consent for inclusion before participation. The study was conducted in accordance with the Declaration of Helsinki.
We identified all potentially relevant articles, limited to English-language studies by searching PubMed (https://pubmed.ncbi.nlm.nih.gov/), and an additional hand search of the reference lists from the obtained articles. We considered abstracts at international conferences only if they reported relevant cases. If some crucial information were not provided or they were not feasible at the time of writing the article, all eligible authors were contacted, with a second mail as a reminder if responses were not received. The search was performed up to December 2019 with an up-to-date e-alert from each search platform.
We extracted the characteristic and additional phenotypic elements from each study. Furthermore, we concentrated on describing the dysmorphology traits, reporting the most frequent features. If the growth parameters [21] were accessed in several time periods after birth, only the last one was included. An array-CGH and newer data were preferred over FISH examinations.
In order to construct one scheme of all reported PSS deletions, we have converted the FISH-BAC clones in the GRCh37/hg19 using their distal coordinates as a minimal zone of the deletion (further details in Supplementary Table S1).

3. Results

3.1. Case Report 1 (Decipher 286390)

She is the unique child born by caesarian section from non-consanguineous European parents (father from France and mother of Spanish origin). Her prenatal course was uncomplicated. The family history was negative for other individuals with neurodevelopmental disorders except for a cousin of the mother who had a son with mild to moderate intellectual disability. At birth, neonatal hypotonia was noticed and a cerebral CT-scan revealed a thin corpus callosum. Multiple exostoses were reported. Epilepsy started at the age of 8 years, and it was initially treated with lamotrigine. At the age of 12 years, she presented a status epilepticus secondary to Haemophilus influenzae septic shock associated with acute respiratory distress syndrome (ARDS) (detailed description in Supplementary File S1). On the last visit (patient is now in her twenties) the epilepsy was under control with a cocktail of anti-epileptic drugs.
She had a severe global developmental delay. She crawled on all four limbs but did not master chair-to-floor transfers and the use of the wheelchair. She could walk with difficulty using a walker. She has a quick and efficient prehension, but she does not have the resources for instrumental use of objects. In terms of language, she can say several single words but not structured sentences. She has sleep apnea and an IgA immune deficiency treated by injection of gamma globulins, discovered at 12 years old during her hospitalization. No known gene in the deleted interval is associated with immunodeficiency.
At birth, her growth parameters were weight 2970 g (−0.87 SD), height 51 cm (+0.56 SD), and occipoto frontal circumference (OFC) 34 cm (−0.54 SD). At 12 years, weight 31 kg (−3 SD), height 134 cm (−2 SD), body mass index (BMI) 17 kg/m2 (25–50th centile). At 20 years, weight 37 kg (−3 SD), height 141 cm (−3.4 SD); BMI 18.6, 17 kg/m2 (10–25th centile), and OFC 53 cm (−1.20 SD). Her dysmorphic features are described on Figure 1.
The array-CGH detected a deletion overlapping the PSS critical region with a min-max size of 8–9.1 Mb (array (GRCh37) 11p11.12 (42272129x2, 42333416_50378802x1, 51379160x2)). The inheritance of the deletion could not be tested. FISH analysis confirmed a deletion 11p11.2p11.2 (RP11-70A9-RP11-465I24), in line with previous array-CGH data.

3.2. Case Report 2 (Decipher 415213)

Patient was a male born at term (Apgar 9/9, 42nd gestational week with vaginal delivery; birth weight 4070 g (>85th centile); length 52 cm (50th centile); head circumference 33 cm (<15th centile)) from non-consanguineous healthy parents. He was hospitalized at 10 months of age due to apyretic convulsive crises followed by hypotonia, somnolence, and developmental delay. His mother reported daily episodes of short duration with quick muscle contraction of the arms, and a fixed look as if the “child was scared”. There was no family history of malformation, epilepsy, or developmental delay.
The electroencephalography (EEG) (awake/sleep) in the first days of his hospital admission demonstrated an interictal hypsarrhythmia characterized by slow chaotic high voltage delta and theta activity (prominent in the right temporo-parietal region), mono/polymorphic preceded by multifocal frequent bouffés type PO, PPO spike complexes (Figure 2). Due to an EEG pattern indicative of West syndrome, the patient was administrated ACTH, cortisone, and phenobarbitone. After the arterial hypertension, most likely a side effect from the ACTH, a diuretic and calcium-antagonist were prescribed.
Beside the Magnetic Resonance Imaging (MRI) signs of benign external hydrocephalus and bilateral mastoiditis with modest micellar sinusopathy and minimal pericardial effusion on electrocardiogram. All other examinations were in normal ranges (sensory evoked potentials, metabolic profiles, echo and computer tomography (CT) scan).
Currently (5 years of age), the patient presents a linear postnatal overgrowth with severe intellectual disability (weight 23 kg (90–97th centile), height 121 cm (>97th centile; father 176 cm, mother 170 cm), and head circumference of 53.5 cm (90–97th centile)).
Using array-CGH, we detected a de novo 323–472 kb microdeletion, partially overlapping the PSS critical region (arr(GRCh37) 11p11.2(45553929x2,45670806_45993729x1,46027199x2)dn) The deletion was confirmed by real-time quantitative PCR (qPCR), and encompassed eight protein coding genes: C11orf94, CHST1, CRY2, GYLTL1B, MAPK8IP1, PEX16, PHF21A, and SLC35C1.

3.3. Review of Reported PSS Cases

We selected 18 published articles for a total of forty 11p11.2 deletions, including the two reported here [12,13,15,16,17,22,23,24,25,26,27,28,29,30,31,32,33,34]. All are represented in Figure 3 using the UCSC Genome Browser custom track (Supplementary Table S1). In three, the WAGR critical region was included [15,16,17]. We excluded all PSS cases carrying an additional pathogenic deletion or duplication [35,36]. Reports of the patients with heterozygous deletions which appeared as early as 1977 [37] or those where no sufficient data was provided even after contacting the authors [38] were also excluded.
Detailed clinical data including dysmorphology was obtained for each patient when available (Supplementary Tables S1–S3).
We noted that the deletions described are highly variable. To perform a better genotype-phenotype correlation, we divided cases into three groups based on the involvement of the three PSS critical genes. We found 23 full PSS cases (ALX4, EXT2, and PHF21A), 14 cases with EXT2-ALX4, and three with only PHF21A. The minimal deletion reported by Chuang et al. [24] did not affect ALX4/EXT2; however, the patients had biparietal foramina and multiple exostosis, and thus were classified as complete PSS deletion.
Half of the patients (20/40) had reports of their birth parameters (Table 1). The majority had weight/height or head circumference adequate for their age (15/20); three were small, and two were large for their gestational age at birth (>90th centile or 2 SD above the mean weight, length, or both). Postnatal overgrowth was observed in four patients, and two did not catch up to expected parameters despite the normal parameters at birth.
Developmental delay was noted in half of the patients (22/40); isolated language delay in one, additional autistic traits in patient 3 by Wuyts et al. [25], and in the follow-up of patient III-1 by Shaffer et al. [13] (Table 1; Supplementary Table S1).
At the neurologic examination, hypotonia was the most prevalent finding detected in 16 patients, although the definition was not consistent. We found epilepsy in 14 cases, clinically very heterogeneous by etiology and definition (Table 1). Notably, all except one showed severe deterioration on the developmental plateau and intellectual disability (Table 1).
Various brain anomalies were seen on MRIs such as thin (n = 5), absent (n = 2), or hypoplastic corpus callosum (n = 1) (Table 1; Supplementary Table S1). Prominent cerebrospinal fluid spaces were detected in six patients (Table 1). Other brain anomalies were dysplasia/hypoplasia of the cerebellar cortex/vermis (five patients), choroid plexus cyst (two patients), and an unusual report of meningoencephalocele (Table 1; Supplementary Table S1).
Genitourinary anomalies such as micropenis (9/28) and cryptorchidism (8/28) were frequent findings in males. Strabismus (12/40) and nystagmus (5/40) were prevailing from the ocular anomalies (Table 1; Supplementary Table S1).
Among 28 patients with dysmorphic features, brachycephaly was commonly reported in 17 patients (61%), followed by broad forehead and epicanthus present in 12 (43%), followed by downturned mouth, prominent nasal bridge, high forehead, sparse lateral eyebrows, and short philtrum (Table 2). Tapering fingers and brachydactyly were hand anomalies reported in a minority (Supplementary Table S3).

4. Discussion

In contiguous genes syndromes, the identification of the causative genes responsible for the phenotype relies on the availability of patients with different but overlapping deletions/duplications and on functional or genetic data of the genes spanning the CNV. In Potocki-Shaffer syndrome, three genes are reported to be causative: ALX4, ELX2, and PHF21A. We aimed at improving genotype-phenotype correlation on the syndrome and revised literature data collecting a total of 40 cases.
Patients with a deletion involving ALX4, ELX2, and PHF21A genes had the cardinal PSS features: biparietal foramina, multiple exostosis, and intellectual disability and craniofacial anomalies associated with ALX4, ELX2, and PHF21A, respectively. The haploinsufficiency of ALX4 [39] was also suggested to explain the micropenis in some of the males with PSS.
SLC35C1 [23], PEX16 [23], and GYLT1B [40,41] have been proposed as candidate genes for the hypotonia reported in most of the PSS patients. Actually, these genes are not haploinsufficient (pLI scores close to 0 [42]), and they unlikely can contribute to this condition.
We were particularly interested in the role of PHF21A in PSS. Disrupting variants hitting PHF21A, such as balanced translocations [22], truncating [43], or missense variants [44] are reported in patients with intellectual developmental disorder and craniofacial dysmorphism. Notably, PHF21A disruption has also been associated with hypotonia, and different types of epilepsy among which West-like epileptic encephalopathy [43]. West syndrome (WS) [45] includes a triad composed of infantile spasms (epilepsy) [46], hypsarrhythmia (EEG pattern), and intellectual disability. The infantile spasms of WS are subtle and short, they disappear by the age of 2 years and are often overlooked if not recognized by trained and experienced eyes. Their early diagnosis and a shorter delay to treatment are essential for evading their long term morbidity such as intellectual disability or a more severe type of epilepsy [47].
We noted that West syndrome was also diagnosed in patient 1 (Decipher code 415213), at the initial stage of disease (10 months of age), suggesting this feature is present in early phases of PSS. We analyzed the reports of epilepsy/seizures in the whole PSS literature cohort, but we were unable to find further cases with infantile spasms/WS. We think that the age of the probands at diagnosis is likely the most relevant explanation, because of the early onset of infantile spasms and subtle clinical presentation [13,34]. In some cases, a poor clinical description [23], or different deletion sizes [29] may have hidden the WS features. On the other hand, we found two neonates, while searching infantile spasms among cases with PHF21A point mutations (one truncating and one missense variant) [43,44]. Our observation needs future clinical confirmation; however, if infantile spasms are truly present in the early phases of PSS and remain untreated, they could lead to intellectual disability or to more severe types of epilepsy described in this disease. Since PHF21A strongly correlates with intellectual disability, we suggest that it could also be the leading gene for the infantile spasms and epilepsy.
The histone methyl reader protein (BHC80) [48] encoded by PHF21A is best known for its role in regulation of a huge number of neuronal genes during embryogenesis [49,50], and it is particularly important in the development of nerve cells [51] and bone structures of the face [22]. It is a well conserved gene and is highly intolerant to variation (pLI = 1.0; Z-score = 2.86, GnomAD ver.2.1.1 http://gnomad.broadinstitute.org/). This reader protein is part of LSD-coREST [52] complex and recognizes the epigenetic marks on core H3K4 through specialized motifs [53], which researchers speculate helps keep the histone demethylated and the genes turned off (repressed) [53,54]. These target genes have a specific cis-regulatory elements known as repressor element-1 (RE1) or neural restrictive silencer (NRS) [55]. Among them are SCN2A [52] or SCN3A [22,56], sodium channel encoding genes, strongly associated with epileptic encephalopathy [57]. The PHF21A haploinsufficiency is indeed altering the expression of these genes, as it was demonstrated in patients’ derived PHF21A haploinsufficient cell lines [22,56].
Concerning dysmorphological traits such as brachy/microcephaly and mild micrognathia, the role for PHF21A was supported by the generation and rescue of a zebrafish model, where PHF21A orthologous suppression produced abnormalities in the development of the head, face, and jaw [22]. Yet, these features were not present in all patients with a deletion affecting PHF21A, suggesting incomplete penetrance.
Birth/postnatal overgrowth, present in some of the PSS cases, could also be associated with PHF21A haploinsufficiency. A recent report on disorders associated to overgrowth with intellectual disability (OGID) showed that 14 genes were involved [58]. Perturbation of epigenetic regulation was the main pathogenic mechanism. Interestingly, most of these genes have motifs recognized by the LSD-coREST complex where PHF21A is taking part [59,60].

5. Conclusions

We are presenting a detailed systematic review of all reported PSS cases, including two novel ones. The phenotype is confirmed heterogeneous, but we highlighted the possibility that infantile spasms are present before 2 years of age. We highlight the importance of confirming this observation by prompt examination of PSS cases. An early diagnosis of infantile spasms may shorten the delay to treatment and subsequently lower or even abolish the risk of intellectual disability [61,62]. This goal could be achieved in case of a suspect or in families at risk by:
-
a detailed clinical examination of neonates, particularly focused on getting a full neurological assessment
-
a complete video-EEG recording
-
a magnetic resonance (MR) study of the brain
We also suggest the inclusion of PHF21A into gene panels for infantile spasms, performing prompt genetic testing and EEG in suspected patients, and in probands from at-risk families.
Web Resources

Supplementary Materials

The following are available online at https://www.mdpi.com/2076-3425/10/11/788/s1, Supplementary File S1: EEG Performed during Hospitalization because of a Status Epilepticus Secondary to a Haemophilus Influenzae Septic Shock (Decipher Patient 286390); Supplementary Table S1: position and phenotype; Supplementary Table S2: Summary statistics of the clinical presentation. Supplementary Table S3: Dysmorphic features.

Author Contributions

Conceptualization, S.T. and A.B.; array-CGH and PCR (qPCR) for Case report 2, E.D.G.; clinical investigation for Case report 2 (Decipher 415213), G.B.F. and D.C.; complete investigation for Case report 1 (Decipher 286390), G.D. and P.K.; writing—original draft, S.T.; writing—review and editing, S.T. and A.B.; supervision, A.B. and L.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research received funding specifically appointed to the Department of Medical Sciences from the Italian Ministry for Education, University and Research (Ministero dell’Istruzione, dell’Università e della Ricerca—MIUR) under the program “Dipartimenti di Eccellenza 2018—2022”, project code D15D18000410001.

Acknowledgments

The authors are thankful to all participants and families for their time and contributions.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Photography of patient 1 (Decipher 286390) at 20 years old. She has a high and broad forehead, sparse lateral eyebrows, long nose with prominent nasal bridge, short and smooth philtrum, thin lips, prominent chin with horizontal crease, quite large mouth, and a short neck. There is a large abduction and an external rotation of the two hips.
Figure 1. Photography of patient 1 (Decipher 286390) at 20 years old. She has a high and broad forehead, sparse lateral eyebrows, long nose with prominent nasal bridge, short and smooth philtrum, thin lips, prominent chin with horizontal crease, quite large mouth, and a short neck. There is a large abduction and an external rotation of the two hips.
Brainsci 10 00788 g001
Figure 2. Electroencephalography (EEG): interictal hypsarrhythmia. Slow high voltage of delta and theta activity (circles on the left), mono/polymorphic preceded by multifocal PO (arrows on the left), PPO spike (arrows on the right).
Figure 2. Electroencephalography (EEG): interictal hypsarrhythmia. Slow high voltage of delta and theta activity (circles on the left), mono/polymorphic preceded by multifocal PO (arrows on the left), PPO spike (arrows on the right).
Brainsci 10 00788 g002
Figure 3. Scheme for the 40 known deletions encompassing the Potocki-Shaffer syndrome (PSS) critical region. In red, the extension of the minimal deleted region. Vertical light blue lines indicate the borders of the critical PSS region, spanning the PHF21A, ALX4, and EXT2 genes. Black vertical lines indicate the redefined critical region for ID/DD in PSS: a ~1.1 Mb region containing 12 annotated genes between markers D11S554 and D11S1319 [22]. On the left side, the PAX6 and WT1 genes associated with Wilms’ tumor, aniridia, genitourinary anomalies/gonadoblastoma and mental retardation syndrome (WAGR). Note that some of the red bars indicate more than one case in the same family.
Figure 3. Scheme for the 40 known deletions encompassing the Potocki-Shaffer syndrome (PSS) critical region. In red, the extension of the minimal deleted region. Vertical light blue lines indicate the borders of the critical PSS region, spanning the PHF21A, ALX4, and EXT2 genes. Black vertical lines indicate the redefined critical region for ID/DD in PSS: a ~1.1 Mb region containing 12 annotated genes between markers D11S554 and D11S1319 [22]. On the left side, the PAX6 and WT1 genes associated with Wilms’ tumor, aniridia, genitourinary anomalies/gonadoblastoma and mental retardation syndrome (WAGR). Note that some of the red bars indicate more than one case in the same family.
Brainsci 10 00788 g003
Table 1. Clinical characteristic of PSS cases reported in the literature.
Table 1. Clinical characteristic of PSS cases reported in the literature.
Decipher 286390Decipher 415213McCoolLabonneSohnKim GC14361MontgomeryPalkaRomeikeBremondChuang Patient 1Chuang Patient 2Chuang Patient 3Wakui PSS03Wakui PSS04Wakui PSS08
PSS+ ++ ++ + &+ &+ & ++
ALX/EXT4 + + +
PHF21A + + +
Birth parameters
SGA/Undergrowth----+n.a--n.an.an.an.an.an.an.an.a
Appropriate+++--n.a-+n.an.an.an.an.an.an.an.a
LGA/Overgrowth---+-n.a+-n.an.an.an.an.an.an.an.a
Postnatal growth
Undergrowth+---+n.a--n.a- †n.an.an.a++n.a
Appropriate-----n.a-+n.a+n.an.an.a--n.a
Overgrowth-+++-n.a+-n.a-n.an.an.a--n.a
Neurodevelopment
Developmental delay+++ »++++++-+---++
Intellectual disability++--+-++++-++---
Language delay----------------
Neurological findings
Hypotonia+---+++-------+-
Epilepsy++---- °-++ *--++---
MRI findings
Corpus callosum+-------+------+
Prominent CSF spaces--------+-------
Other brain anomalies-+------+-------
Genitourinary
Micropenis---+------+---+-
Cryptorchidism-----+--+---+-+-
Ocular anomalies
Cataract---------+------
Strabismus--+-+-----+-----
Nystagmus----+----+------
Hearing anomalies
hearing loss-----+----------
OtherIgA deficiency;
sleep apnea
Café-au-lait spotsRecurrent infections PtosisPectus excavatum. Recurrent otitis mediaPectus excavatum. Cardiomyopathy;
Osteochondromas;
Anemia
Bilateral aniridia; Kidney tumor;
Obesity
Umbilical hernia Bowing of lower extremitiesUmbilical hernia;
Myopia;
Recurrent
infections
Wilms’ tumor;
Aniridia
Wakui PSS10Wakui PSS12Wakui PSS13Wuyts patient 1Wuyts patient 2Wuyts patient 3Chien 3 patientsHall 3 patientsWuyts 4 patientsBartsch Patient 2Bartsch Patient 6–8PotockyMcGaughranShaffer III-1Shaffer III-2Shaffer
II-4
PSS++++ ++ + +++++
ALX/EXT4 + ++ +
PHF21A
Birth parameters
SGA/Undergrowthn.a-+---n.an.an.a----+ ^n.a-
Appropriaten.a+-+++n.an.an.a++++-n.a+ ^
LGA/Overgrowthn.a-----n.an.an.a-----n.a-
Postnatal growth
Undergrowth--+--+n.an.an.a----+ ^n.a-
Appropriate++-++-n.an.an.a++++-n.a+ ^
Overgrowth------n.an.an.a-----n.a-
Neurodevelopment
Developmental delay-++++++----+-+ ^--
Intellectual disability---++++--+-+++++
Language delay+--+---------+ ^--
Neurological findings
Hypotonia--+++++--+---+++
Epilepsy---+-+- º-+ ΅+---+ ^-+
MRI findings
Corpus callosum++----+---------
Prominent CSF spaces--+---+------+ ^--
Other brain anomalies-+-+-+--+ ΅----+ ^-+
Genitourinary
Micropenis+----++ º--+--+--+
Cryptorchidism--+---- º-----+--+
Ocular anomalies
Cataract------------+---
Strabismus+-+-+++--+-+-+-+
Nystagmus----++---+------
Hearing anomalies
hearing loss-++-------- ---+ ^
OtherDeceased from multiorgan failureSmall testisVSD;
Recurrent infections
High myopia;
Obesity
Anal atresia and fistula;
VSD
Myopia;
Acrocephalosyndactyly;
Adipose
7625 Asthma;
Hyperactivity
Adipose appearanceCafé-au-lait spots Capillary hemangiomaBilateral ptosisAniridia;
Wilms’ tumor;
Short stature
Borderline hypothyroidism;
Simian crease
borderline high TSH;
Simian crease;
Obese
Adipose appearance;
Aggressive behavior
Notes: SGA, small for gestational age; LGA, large for gestational age; n.a, not available; VSD, ventricular septal defect; », history of developmental delay; °, history of static encephalopathy; *, information for antiepileptic drugs; †, height 2.4 SD; &, minimal deletion does not affect the ALX/EXT4; º, micropenis only in the index case; report of mother’s two brothers of febrile seizures and epilepsy; the older had right-side cryptorchidism, whereas the younger umbilical hernia; ΅, epilepsy only in the proband; CT performed only in the proband and his father (IV-1 and III-1); ^, additional information from Swarr et al., 2009 [14]. The first three rows indicate which of the three critical PSS genes is involved in the deletion: PSS indicates the deletion spans at least ALX4, EXT2, PHF21A.
Table 2. Dysmorphology of PSS reported patients in the literature.
Table 2. Dysmorphology of PSS reported patients in the literature.
Dysmorphologyn%PSSALX/EXT4PHF21A
Brachycephaly17611421
Broad forehead1243911
Epicanthus1243912
Downturned mouth11391100
High forehead1036820
Prominent nasal bridge10361000
Sparse lateral eyebrows932810
Short philtrum932711
Microcephaly829800
Hypoplastic nares621510
Broad nasal tip518500
Low set ears518410
Large/protuberant ears518311
Telecanthus414400
Upslanting palpebral fissures414400
Thin lips414301
Micrognathia414211
Turricephaly311201
Broad nasal bridge311201
Short neck311300
Small nose27200
Small mouth27101
Full cheeks27011
Prominent chin27110
Downslanted palpebral fissures13010
TOTAL28
Notes: PSS is Potocki-Shaffer syndrome.
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Trajkova, S.; Di Gregorio, E.; Ferrero, G.B.; Carli, D.; Pavinato, L.; Delplancq, G.; Kuentz, P.; Brusco, A. New Insights into Potocki-Shaffer Syndrome: Report of Two Novel Cases and Literature Review. Brain Sci. 2020, 10, 788. https://doi.org/10.3390/brainsci10110788

AMA Style

Trajkova S, Di Gregorio E, Ferrero GB, Carli D, Pavinato L, Delplancq G, Kuentz P, Brusco A. New Insights into Potocki-Shaffer Syndrome: Report of Two Novel Cases and Literature Review. Brain Sciences. 2020; 10(11):788. https://doi.org/10.3390/brainsci10110788

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Trajkova, Slavica, Eleonora Di Gregorio, Giovanni Battista Ferrero, Diana Carli, Lisa Pavinato, Geoffroy Delplancq, Paul Kuentz, and Alfredo Brusco. 2020. "New Insights into Potocki-Shaffer Syndrome: Report of Two Novel Cases and Literature Review" Brain Sciences 10, no. 11: 788. https://doi.org/10.3390/brainsci10110788

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