RNA Sequencing and Target Long-read Sequencing Reveal an Intronic Transposon Insertion Causing Aberrant Splicing

Overview

Journal J Hum Genet

Specialty Genetics

Date 2023 Dec 15

PMID 38102195

Authors

Ryota Kawakami

Takuya Hiraide

Kazuki Watanabe

Sachiko Miyamoto

Kota Hira

Kazuyuki Komatsu

Hidetoshi Ishigaki

Kimiyoshi Sakaguchi

Masato Maekawa

Keita Yamashita

Tokiko Fukuda

Isao Miyairi

Tsutomu Ogata

Hirotomo Saitsu

Affiliations

Soon will be listed here.

Abstract

More than half of cases with suspected genetic disorders remain unsolved by genetic analysis using short-read sequencing such as exome sequencing (ES) and genome sequencing (GS). RNA sequencing (RNA-seq) and long-read sequencing (LRS) are useful for interpretation of candidate variants and detection of structural variants containing repeat sequences, respectively. Recently, adaptive sampling on nanopore sequencers enables target LRS more easily. Here, we present a Japanese girl with premature chromatid separation (PCS)/mosaic variegated aneuploidy (MVA) syndrome. ES detected a known pathogenic maternal heterozygous variant (c.1402-5A>G) in intron 10 of BUB1B (NM_001211.6), a known responsive gene for PCS/MVA syndrome with autosomal recessive inheritance. Minigene splicing assay revealed that almost all transcripts from the c.1402-5G allele have mis-splicing with 4-bp insertion. GS could not detect another pathogenic variant, while RNA-seq revealed abnormal reads in intron 2. To extensively explore variants in intron 2, we performed adaptive sampling and identified a paternal 3.0 kb insertion. Consensus sequence of 16 reads spanning the insertion showed that the insertion consists of Alu and SVA elements. Realignment of RNA-seq reads to the new reference sequence containing the insertion revealed that 16 reads have 5' splice site within the insertion and 3' splice site at exon 3, demonstrating causal relationship between the insertion and aberrant splicing. In addition, immunoblotting showed severely diminished BUB1B protein level in patient derived cells. These data suggest that detection of transcriptomic abnormalities by RNA-seq can be a clue for identifying pathogenic variants, and determination of insert sequences is one of merits of LRS.

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