Transcriptome Analysis Revealed Impaired cAMP Responsiveness in PHF21A-Deficient Human Cells

De novo variants in PHF21A cause intellectual developmental disorder with behavioral abnormalities and craniofacial dysmorphism with or without seizures: A case report and literature review

PURPOSE

PHF21A has been associated with intellectual developmental disorder with behavioral abnormalities and craniofacial dysmorphism with or without seizures (IDDBCS). Here, we report a new patient with IDDBCS and review previously reported patients.

METHODS

We reviewed the phenotypic and genetic spectrum of the newly diagnosed patient and previously reported patients with IDDBCS.

RESULTS

Among 12 patients (11 whose cases were previously reported and the patient whose case we report here), all patients (100%) had intellectual disability (ID) and motor development delay. Three of 8 patients (37.5%) for whom information on cognition was available had severe ID; ID was moderate in two patients (25%) and mild in three patients (37.5%). Seven of the 12 patients (58.33%) had an epileptic phenotype, and the majority (5/7, 71.42%) of affected individuals developed developmental and epileptic encephalopathy (DEE). Of the 5 patients with DEE, three developed infantile epileptic spasm syndrome (IESS). The seizures of 2 patients (2/5, 40%) were controlled by antiseizure medications. Overgrowth, ADHD, hypotonia, ASD, and sleep disorders were observed in 100%, 77.78%, 70%, 50%, and 33.33% of patients, respectively. All of the variants (100%) were de novo heterozygous variants. Three of the 12 patients (25%) had the same variant (p.Arg580*). The most common types of variants were frameshift variants (7/12, 58.33%), followed by nonsense variants (4/12, 33.33%) and missense variants (1/12, 8.33%). Genotype-phenotype relationships for IDDBCS were uncertain, as phenotypic variability was observed among patients with the same variant (p.Arg580*). The patient whose case we report here had a novel PHF21A gene variant (p.Gln97fs*20), which caused neurodevelopmental delay, macrocephaly, and IESS.

CONCLUSION

The core phenotypes of IDDBCS include neurodevelopmental delay (intellectual disability and impaired motor skills), craniofacial abnormalities, and overgrowth. ADHD, hypotonia, epilepsy, ASD, and sleep disorders are common symptoms of IDDBCS. Notably, DEE is the dominant phenotype of epilepsy, especially IESS. PHF21A may be a candidate gene for DEE. De novo variants are the main mode of inheritance. The most common types of variants are frameshift variants, and the variant p.Arg580* in PHF21A is located at a mutation hot spot.

PHF21A Related Disorder: Description of a New Case

PHF21A (PHD finger protein 21A) gene, located in the short arm of chromosome 11, encodes for BHC80, a component of the Lysine Specific Demethylase 1, Corepressor of REST (LSD1-CoREST) complex. BHC80 is mainly expressed in the human fetal brain and skeletal muscle and acts as a modulator of several neuronal genes during embryogenesis. Data from literature relates PHF21A variants with Potocki-Shaffer Syndrome (PSS), a contiguous gene deletion disorder caused by the haploinsufficiency of PHF21A, ALX4, and EXT2 genes. Clinical cardinal features of PSS syndrome are multiple exostoses (due to the EXT2 involvement), biparietal foramina (due to the ALX4 involvement), intellectual disability, and craniofacial anomalies (due to the PHF21A involvement). To date, to the best of our knowledge, a detailed description of PHF21A-related disorder clinical phenotype is not described in the literature; in fact, only 14 subjects with microdeletion frameshift or nonsense variants concerning only PHF21A gene have been reported. All reported cases did not present ALX4 or EXT2 variants, and their clinical features did not fit with PSS diagnosis. Herein, by using Exome sequencing, and Sanger sequencing of the region of interest, we describe a case of a child with a paternally inherited (mosaicism of 5%) truncating variant of the PHF21A gene (c.649_650del; p.Gln217ValfsTer6), and discuss the new evidence. In conclusion, these patients showed varied clinical expressions, mainly including the presence of intellectual disability, epilepsy, hypotonia, and dysmorphic features. Our study contributes to describing the genotype-phenotype spectrum of patients with PHF21A-related disorder; however, the limited data in the literature have been unable to provide a precise diagnostic protocol for patients with PHF21A-related disorder.

The Genetic Control of Stoichiometry Underlying Autism

Autism is a common and complex neurologic disorder whose scientific underpinnings have begun to be established in the past decade. The essence of this breakthrough has been a focus on families, where genetic analyses are strongest, versus large-scale, case-control studies. Autism genetics has progressed in parallel with technology, from analyses of copy number variation to whole-exome sequencing (WES) and whole-genome sequencing (WGS). Gene mutations causing complete loss of function account for perhaps one-third of cases, largely detected through WES. This limitation has increased interest in understanding the regulatory variants of genes that contribute in more subtle ways to the disorder. Strategies combining biochemical analysis of gene regulation, WGS analysis of the noncoding genome, and machine learning have begun to succeed. The emerging picture is that careful control of the amounts of transcription, mRNA, and proteins made by key brain genes-stoichiometry-plays a critical role in defining the clinical features of autism.

11p11.12p12 duplication in a family with intellectual disability and craniofacial anomalies

Background

Potocki–Shaffer syndrome (PSS) is a rare contiguous gene deletion syndrome marked by haploinsufficiency of genes in chromosomal region 11p11.2p12. Approximately 50 cases of PSS have been reported; however, a syndrome with a PSS-like clinical phenotype caused by 11p11.12p12 duplication has not yet been reported.

Methods

11p11.12p12 duplication syndrome was identified and evaluated using a multidisciplinary protocol. Diagnostic studies included intelligence testing, thorough physical examination, electroencephalography (EEG), magnetic resonance imaging (MRI) of the brain, ultrasonography, biochemical tests and karyotype analysis. Next-generation sequencing analysis clarified the location of the chromosomal variations, which was confirmed by chromosome microarray analysis (CMA). Whole-exome sequencing (WES) was performed to exclude single nucleotide variations (SNVs). A wider literature search was performed to evaluate the correlation between the genes contained in the chromosomal region and clinical phenotypes.

Results

The proband was a 36-year-old mother with intellectual disability (ID) and craniofacial anomalies (CFA). She and her older son, who had a similar clinical phenotype, both carried the same 11p11.12p12 duplication with a copy number increase of approximately 10.5 Mb (chr11:40231033_50762504, GRCh37/hg19) in chromosome bands 11p11.12p12. In addition, she gave birth to a child with a normal phenotype who did not carry the 11p11.12p12 duplication. By literature research and DECIPHER, we identified some shared and some distinct features between this duplication syndrome and PSS. One or more of ALX4, SLC35C1, PHF21A and MAPK8IP1 may be responsible for 11p11.12p12 duplication syndrome.

Conclusions

We present the first report of 11p11.12p12 duplication syndrome. It is an interesting case worth reporting. The identification of clinical phenotypes will facilitate genetic counselling. A molecular cytogenetic approach was helpful in identifying the genetic aetiology of the patients and potential candidate genes with triplosensitive effects involved in 11p11.12p12 duplication.

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

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.