Clinical and Genetic Study on a Chinese Patient with Infantile Onset Epileptic Encephalopathy carrying a PPP3CA Null Variant: a case report

Expanding the clinical spectrum of PPP3CA variants - alternative isoforms matter

BACKGROUND

the protein phosphatase 3 catalytic subunit alpha (PPP3CA) gene encodes for the alpha isoform of the calcineurin catalytic subunit, which controls the phosphorylation status of many targets. Currently, 23 pathogenic variants of PPP3CA are known, with clinical manifestations varying by mutation type and domain.

RESULTS

through whole exome sequencing, we found two de novo variants in PPP3CA: a frameshift variant predicted leading to a truncated protein in Pt.1 and a splicing variant in Pt.2 associated with mild phenotype. PPP3CA is ubiquitously expressed with tissue-specificity of; namely, splicing isoform 1 prevailing over isoform 2 in the central nervous system. By analyzing isoform distribution in patient-derived cell lines, we highlight a skewed expression of both isoforms in Pt.1, whereas only isoform 2 shows a moderate reduction in Pt.2. In contrast, we did not observe significant abundance changes at the protein level. Cell lines derived from Pt.1 showed a reduced proliferation, associated with an increase in cell death and the upregulation of the unfolded protein response (UPR) pathway.

CONCLUSION

data suggest that an aberrant PPP3CA protein in Pt.1 could lead to UPR activation resulting in increased cell death. In Pt.2 an imbalance between the two main isoforms possibly explains the peculiar pathological manifestations, such as a moderate developmental delay.

PPP3CA gene-related developmental and epileptic encephalopathy: Expanding the electro-clinical phenotype

PURPOSE

The objective of this study is to characterize the electro-clinical phenotype of individuals affected by the rare PPP3CA gene-related developmental and epileptic encephalopathy (DEE).

METHODS

We provide a detailed electro-clinical description of four previously unreported subjects, with unremarkable structural brain MRI and a normal screening for inborn errors of metabolism, who carry pathogenic variants within the regulatory domain of the PPP3CA gene, which encodes for calcineurin. We also conducted a literature review via PubMed and SCOPUS (up to December 2023) to collect all the studies reporting clinical details of subjects with PPP3CA pathogenic variants within the regulatory domain.

RESULTS

Our in-depth investigation reveals two distinct electro-clinical phenotypes with unique interictal and ictal patterns. Pathogenic variants within the calmodulin-binding domain result in childhood-onset epilepsy with focal and generalized seizures, developmental and intellectual impairments. Pathogenic variants within the regulatory domain lead to early onset drug-resistant severe epilepsy and potentially fatal outcomes. Comparative analysis with existing literature corroborates the notion that truncating mutations, prevalent in the regulatory domain but also possible in the calmodulin-binding domain, consistently associate with more profound disabilities and drug-resistant epilepsy.

CONCLUSION

Our study emphasizes the critical role of pathogenic variants' type and location on the severity of PPP3CA-related DEE. We also speculate, based on peculiar EEG patterns, on potential pathophysiological mechanisms involving calcineurin dysfunction and calcium homeostasis. In order to improve our understanding of this rare DEE, we need both collaborative efforts to gather larger cohorts and further experimental studies.

Potential Role of Protein Kinase FAM20C on the Brain in Raine Syndrome, an In Silico Analysis

FAM20C (family with sequence similarity 20, member C) is a serine/threonine-specific protein kinase that is ubiquitously expressed and mainly associated with biomineralization and phosphatemia regulation. It is mostly known due to pathogenic variants causing its deficiency, which results in Raine syndrome (RNS), a sclerosing bone dysplasia with hypophosphatemia. The phenotype is recognized by the skeletal features, which are related to hypophosphorylation of different FAM20C bone-target proteins. However, FAM20C has many targets, including brain proteins and the cerebrospinal fluid phosphoproteome. Individuals with RNS can have developmental delay, intellectual disability, seizures, and structural brain defects, but little is known about FAM20C brain-target-protein dysregulation or about a potential pathogenesis associated with neurologic features. In order to identify the potential FAM20C actions on the brain, an in silico analysis was conducted. Structural and functional defects reported in RNS were described; FAM20C targets and interactors were identified, including their brain expression. Gene ontology of molecular processes, function, and components was completed for these targets, as well as for potential involved signaling pathways and diseases. The BioGRID and Human Protein Atlas databases, the Gorilla tool, and the PANTHER and DisGeNET databases were used. Results show that genes with high expression in the brain are involved in cholesterol and lipoprotein processes, plus axo-dendritic transport and the neuron part. These results could highlight some proteins involved in the neurologic pathogenesis of RNS.

Clinical evaluation of rare copy number variations identified by chromosomal microarray in a Hungarian neurodevelopmental disorder patient cohort

BACKGROUND

Neurodevelopmental disorders are genetically heterogeneous pediatric conditions. The first tier diagnostic method for uncovering copy number variations (CNVs), one of the most common genetic etiologies in affected individuals, is chromosomal microarray (CMA). However, this methodology is not yet a routine molecular cytogenetic test in many parts of the world, including Hungary. Here we report clinical and genetic data of the first, relatively large Hungarian cohort of patients whose genetic testing included CMA.

METHODS

Clinical data were retrospectively collected for 78 children who were analyzed using various CMA platforms. Phenotypes of patients with disease-causing variants were compared to patients with negative results using the chi squared/Fisher exact tests.

RESULTS

A total of 30 pathogenic CNVs were identified in 29 patients (37.2%). Postnatal growth delay (p = 0.05564), pectus excavatum (p = 0.07484), brain imaging abnormalities (p = 0.07848), global developmental delay (p = 0.08070) and macrocephaly (p = 0.08919) were more likely to be associated with disease-causing CNVs.

CONCLUSION

Our results allow phenotypic expansion of 14q11.2 microdeletions encompassing SUPT16H and CHD8 genes. Variants of unknown significance (n = 24) were found in 17 patients. We provide detailed phenotypic and genetic data of these individuals to facilitate future classification efforts, and spotlight two patients with potentially pathogenic alterations. Our results contribute to unraveling the diagnostic value of rare CNVs.

Case report: A novel PPP3CA truncating mutation within the regulatory domain causes severe developmental and epileptic encephalopathy in a Chinese patient

Introduction

Developmental and epileptic encephalopathy 91 (DEE91; OMIM#617711) is a severe neurodevelopmental disorder caused by heterozygous PPP3CA variants. To the best of our knowledge, only a few DEE91 cases have been reported.

Results

This study reports a boy who experienced recurrent afebrile convulsions and spasms at the age of 2 months. After being given multiple antiepileptic treatments with levetiracetam, adrenocorticotropic hormone (ACTH), prednisone, topiramate, and clonazepam, his seizures were not completely relieved. At the age of 4 months, the patient exhibited delayed neuromotor development and difficulty in feeding; at the age of 6 months, he was diagnosed with developmental regression with recurrent spasms and myoclonic seizures that could respond to vigabatrin. At the age of 1 year and 4 months, the patient showed profound global developmental delay (GDD) with intermittent absence seizures. Whole-exome sequencing (WES) identified a novel loss-of-function variant c.1258_1259insAGTG (p. Val420Glufs^*32) in PPP3CA.

Conclusion

This finding expands the genetic spectrum of the PPP3CA gene and reinforces the theory that DEE91-associated truncating variants cluster within a 26-amino acid region in the regulatory domain (RD) of PPP3CA.

PPP3CA truncating variants clustered in the regulatory domain cause early-onset refractory epilepsy

PPP3CA encodes the catalytic subunit of calcineurin, a calcium-calmodulin-regulated serine-threonine phosphatase. Loss-of-function (LoF) variants in the catalytic domain have been associated with epilepsy, while gain-of-function (GoF) variants in the auto-inhibitory domain cause multiple congenital abnormalities. We herein report five new patients with de novo PPP3CA variants. Interestingly, the two frameshift variants in this study and the six truncating variants reported previously are all located within a 26-amino acid region in the regulatory domain (RD). Patients with a truncating variant had more severe earlier onset seizures compared to patients with a LoF missense variant, while autism spectrum disorder was a more frequent feature in the latter. Expression studies of a truncating variant showed apparent RNA expression from the mutant allele, but no detectable mutant protein. Our data suggest that PPP3CA truncating variants clustered in the RD, causing more severe early-onset refractory epilepsy and representing a type of variants distinct from LoF or GoF missense variants.