A Deep Exon Cryptic Splice Site Promotes Aberrant Intron Retention in a Von Willebrand Disease Patient

A translationally silent single nucleotide mutation in exon 44 (E44) of the von Willebrand factor (VWF) gene is associated with inefficient removal of intron 44 in a von Willebrand disease (VWD) patient. This intron retention (IR) event was previously attributed to reordered E44 secondary structure that sequesters the normal splice donor site. We propose an alternative mechanism: the mutation introduces a cryptic splice donor site that interferes with the function of the annotated site to favor IR. We evaluated both models using minigene splicing reporters engineered to vary in secondary structure and/or cryptic splice site content. Analysis of splicing efficiency in transfected K562 cells suggested that the mutation-generated cryptic splice site in E44 was sufficient to induce substantial IR. Mutations predicted to vary secondary structure at the annotated site also had modest effects on IR and shifted the balance of residual splicing between the cryptic site and annotated site, supporting competition among the sites. Further studies demonstrated that introduction of cryptic splice donor motifs at other positions in E44 did not promote IR, indicating that interference with the annotated site is context dependent. We conclude that mutant deep exon splice sites can interfere with proper splicing by inducing IR.

An infant case of pseudohypoaldosteronism type1A caused by a novel NR3C2 variant

Pseudohypoaldosteronism type1A (PHA1A) is the renal form of pseudohypoaldosteronism with autosomal dominant inheritance. PHA1A is caused by haploinsufficiency of the mineralocorticoid receptor, which is encoded by NR3C2. We encountered an infant who was diagnosed with PHA1A due to hyponatremia, hyperkalemia, and poor weight gain in the neonatal period. She carried a novel heterozygous mutation (NM_000901.5: c.1757 + 1 G > C) in the splice donor site of IVS-2 in NR3C2.

Molecular and genetic dissection of recursive splicing

Intronic ratchet points (RPs) are abundant within long introns in the Drosophila genome and consist of juxtaposed splice acceptor and splice donor (SD) sites. Although they appear to encompass zero-nucleotide exons, we recently clarified that intronic recursive splicing (RS) requires a cryptic exon at the RP (an RS-exon), which is subsequently always skipped and thus absent from mRNA. In addition, Drosophila encodes a smaller set of expressed exons bearing features of RS. Here, we investigate mechanisms that regulate the choice between RP and RS-exon SDs. First, analysis of Drosophila RP SD mutants demonstrates that SD competition suppresses inclusion of cryptic exons in endogenous contexts. Second, characterization of RS-exon reporters implicates exonic sequences as influencing choice of RS-exon usage. Using RS-exon swap and mutagenesis assays, we show exonic sequences can determine RS-exon inclusion. Finally, we provide evidence that splicing can suppress utilization of RP SDs to enable RS-exon expression. Overall, multiple factors can influence splicing of Drosophila RS-exons, which usually result in their complete suppression as zero-nucleotide RPs, but occasionally yield translated RS-exons.

Whole Genome Sequencing of Diamond Blackfan Anemia Syndrome Patients Detects Mutations That Alter mRNA Splicing

Diamond Blackfan anemia syndrome (DBAS) is a rare, heritable bone marrow failure syndrome characterized by severe macrocytic anemia, congenital anomalies and predisposition to cancer, most often diagnosed during infancy. More than 98% of DBAS patients with a molecular diagnosis have mutations in a gene encoding one of the ~80 ribosomal proteins (RP) leading to haploinsufficiency. A molecular diagnosis in a patient with DBAS is critical for a definitive diagnosis, the identification of compatible related transplant donors, and developing reproductive strategies for families. Targeted sequencing of RP genes, single nucleotide polymorphism comparative genome hybridization (SNP array) to detect >30 kb deletions (Farrar et al. Blood. 2011) and exome sequencing (WES) (Ulrisch et al. Am J Hum Genet. 2018) has identified RP mutations in ~80% of patients, leaving ~20% of patients with DBAS without a molecular diagnosis. Targeted sequencing and WES focus on only coding sequences. We hypothesized that remaining 20% of DBAS mutations were in the non-coding regions of RP genes, such as promoters or introns. To test this hypothesis, we collected DNA with informed consent for whole genome sequencing (WGS) analysis from 14 patients with no molecular diagnosis after targeted sequencing, SNP array or WES. On average, we aligned ~3.2x10 7 paired end reads of 250 base pairs for each patient (~65X coverage). We focused our analysis on the sequences in and around the RP genes. To identify deletions, we used a suite of detection tools: DELLY, GRIDSS, MANTA, and LUMPY. More than 90% of deletions identified by any 2 of these tools were confirmed by PCR. We identified 5 deletions in the introns of RP genes, ranging from 11 to 467 base pairs in length, which we hypothesized disrupted splicing of the nascent RNA transcript. To test this, we created minigenes in which we replaced exon 2 of a gamma globin gene with either the WT or mutant RP exon. All wild type exons spliced normally. A 467 base pair deletion in RPL27 exon 3 was sufficient to prevent the correct splicing of that intron. Examination of the eCLIP data for RNA binding proteins revealed that spliceosome complex proteins (including SF3B1, SF3B4 and EFTUD2) and Dead-box RNA helicases bind in the deleted region. A 28 base pair deletion in exon 3 of RPL6 removes a polypyrimidine tract that is a critical part of the 3' splice junction consensus sequence, which we presume is also deleterious. The other 3 intronic deletions did not disrupt splicing. We also identified 2 causative point mutations. A point mutation 5 bases into intron 1 of the RPS26 gene changes a base in the 5' splice donor consensus sequence, which activated a cryptic splice donor in the 5' untranslated region. This aberrant splice removes the ATG initiation codon causing an untranslatable RNA. In another patient, we identified a mutation in exon 1 of the RPS27 gene, judged to be a benign amino acid change. This mutation disrupted splicing.by activating a cryptic splice donor site in the 5' untranslated region which removes the ATG initiation codon and causes a frame shift. We were referred two patients with possible duplications of the RPL35a gene. To identify duplications, we employed MinION long read single molecule sequencing. We had an average read length of ~ 6-10kb with the longest read being 1.3Mb. Overall coverage was >85X. We used minimap2 to align the reads to the reference human genome and used SNIFFLES to call the variants. One patient was the parent of DBAS-affected patient with no history of anemia. In this patient, we identified a duplication of 400 kb that included the entire RPL35a region along with genes on either side. We conclude that this duplication is not likely to cause DBA. The second patient was diagnosed with DBAS. In this patient, we identified a duplication of 4 kb including exons 1 and 2 of RPL35a We conclude that this duplication disrupts the RPL35a gene and is a likely cause of DBA. Whole genome sequencing of 15 DBAS patients identified 5 likely causative mutations in RP genes, confirming that most genetically undiagnosed cases of DBAS will involve known genes encoding RP. We conclude that the pipeline for obtaining a molecular diagnosis for DBAS from targeted sequencing, SNP array, and exome sequencing to whole genome sequencing. Disclosures Vlachos: Novartis: Membership on an entity's Board of Directors or advisory committees. Lipton: Celgene: Membership on an entity's Board of Directors or advisory committees.

Prenatal Diagnosis of Holt–Oram Syndrome With a Novel Mutation of TBX5 Gene: A Case Report

Background: Holt–Oram syndrome (HOS) is an autosomal dominant disorder caused by mutations of TBX5 gene.Case presentation: We report a fetus with HOS diagnosed sonographically at 23 weeks of gestation. The fetal parents are non-consanguineous. The fetus exhibited short radius and ulna, inability to supinate the hands, absence of the right thumb, and heart ventricular septal defect (VSD), while the fetal father exhibited VSD and short radius and ulna only. Fetal brother had cubitus valgus and thumb adduction, except for VSD, short radius and ulna. The pregnancy was terminated. Whole-exome sequencing (WES) revealed a novel mutation in the TBX5 (c.510+1G>A) in the fetus inherited from the father. The variant (c.510+1G>A) occurs at splice donor and may alter TBX5 gene function by impact on splicing. It was not previously reported in China.Conclusion: Our case reported a novel mutation in TBX5, which expanded the known genetic variants associated with HOS.

Genetic landscape of 125 pharmacogenes in Chinese from the Chinese Millionome Database

Inter-individual differences of drug responses could be attributed to genetic variants of pharmacogenes such as cytochrome P450 (CYP), phase 2 enzymes, and transporters. In contrast to extensive studies on the genetic polymorphisms of CYP gene, genetic mutation spectrum of other pharmacogenes was under-representative in the pharmacogenetics investigations. Here we studied the genetic variations of 125 pharmacogenes including drug transporters, non-CYP phase 1 enzymes, phase 2 enzymes, nuclear receptors and others in Chinese from the Chinese Millionome Database (CMDB), of which 38,188 variants were identified. Computational analyses of the 2554 exonic variants found 617 deleterious missense variants, 91.1% of which were rare, and of the 54 loss-of-function (splice acceptor, splice donor, start lost, and stop gained) variants, 53 (98.1%) were rare. These results suggested an enrichment of rare variants in functional ones for pharmacogenes. Certain common functional variants including NUDT15 13:48611934 G/A (rs186364861), UGT1A1 2:234676872 C/T (rs34946978), and ALDH2 12:112241766 G/A (rs671) were population-specific for CMDB Chinese because they were absent (with a zero of variant allele frequency) or very rare in other gnomAD populations. These findings might be useful for the further pharmacogenomics research and clinical application in Chinese.

Case Report: A Novel Mutation in NFKB1 Associated With Pyoderma Gangrenosum

Pyoderma gangrenosum (PG) is a rare, destructive inflammatory skin disease of which a painful nodule or pustule breaks down to form a progressively enlarging ulcer. Ulcerations associated with PG may occur after trauma or injury to the skin. The etiology has not been clearly elucidated. Our report described a PG patient with a heterozygous splice-donor-site mutation in NFKB1 (c.730+5G>A) causing the absence of exon 8 and the formation of truncated p105 (p.Asp191_Lys244delinsGlu; p105delEx8), which led to distinct symptoms of high fever and excessive inflammation in wound area after routine surgical procedures. The functional analysis showed that the variant caused reduced phosphorylation of p105 and resulted in the decreased processing of p105 to p50. We conclude that the patient's symptoms were caused by dysregulation of the NF-κB signaling pathway.

A De Novo Mosaic PHEX Variant Causing Sporadic X-Linked Hypophosphatemic Rickets in a 2-Year-Old Girl

Pathogenic variants in the PHEX gene are causative of X-linked hypophosphatemic rickets (XLH). We present a case of a 2-year-old girl with hypophosphatemic rickets with genu varum and short stature without any family history of XLH. Next generation sequencing of the PHEX gene identified a splice donor variant, NM_000444.6:c.1173 + 5G > A in intron 10. This variant had a mosaic pattern with only 22% of the sequence reads showing the variant allele and was not present in the girl's parents, both of whom had a normal phenotype. This is a sporadic case of a de novo mosaic splice-site variant in the PHEX gene.

Case Report: Two Novel Frameshift Mutations in SLC20A2 and One Novel Splice Donor Mutation in PDGFB Associated With Primary Familial Brain Calcification

Primary familial brain calcification (PFBC, OMIM#213600), also known as Fahr's disease, is characterized by bilateral and symmetric brain calcification in the basal ganglia (globus pallidus, caudate nucleus, and putamen), thalamus, subcortical white matter, and cerebellum. PFBC can be caused by loss-of-function mutations in any of the six known causative genes. The most common clinical manifestations include movement disorders, cognitive impairment, and neuropsychiatric signs that gradually emerge in middle-aged patients. To broaden the PFBC mutation spectrum, we examined nine members of a family with PFBC and two sporadic cases from clinical departments, and sequenced all PFBC-causative genes in the index case. Two novel frameshift mutations in SLC20A2 [NM_001257180.2; c.806delC, p.(Pro269Glnfs*49) and c.1154delG, p.(Ser385Ilefs*70)] and one novel splice donor site mutation (NM_002608.4, c.456+1G>C, r.436_456del) in PDGFB were identified in the patient cohort. c.806delC co-segregated with brain calcification and led to SLC20A2 haploinsufficiency among the affected family members. The c.456+1G>C mutation in PDGFB resulted in aberrant mRNA splicing, thereby forming mature transcripts containing an in-frame 21 base pair (bp) deletion, which might create a stably truncated protein [p.(Val146_Gln152del)] and exert a dominant negative effect on wild-type PDGFB. All three mutations were located in highly conserved regions among multiple species and predicted to be pathogenic, as evaluated by at least eight common genetic variation scoring systems. This study identified three novel mutations in SLC20A2 and PDGFB, which broadened and enriched the PFBC mutation spectrum.