Targeted, High-Resolution RNA Sequencing of Non-coding Genomic Regions Associated With Neuropsychiatric Functions

• Published in: Frontiers in genetics Vol. 10; p. 309
• Main Authors: Hardwick, Simon A., Bassett, Maya, Kaczorowski, Dominik, Blackburn, James, Barton, Kirston, Bartonicek, Nenad, Carswell, Shaun L., Tilgner, Hagen U., Loy, Clement, Halliday, Glenda, Mercer, Tim R., Smith, Martin A., Mattick, John S.
• Format: Journal Article
• Language: English
• Published: Switzerland Frontiers Media S.A 12.04.2019
• Subjects: brain; Genetics; GWAS; haplotype blocks; long-read sequencing; non-coding RNA; RNA-seq; GWAS; haplotype blocks; RNA-seq; non-coding RNA; brain; long-read sequencing; sequins
• ISSN: 1664-8021; 1664-8021
• DOI: 10.3389/fgene.2019.00309

The human brain is one of the last frontiers of biomedical research. Genome-wide association studies (GWAS) have succeeded in identifying thousands of haplotype blocks associated with a range of neuropsychiatric traits, including disorders such as schizophrenia, Alzheimer’s and Parkinson’s disease. However, the majority of single nucleotide polymorphisms (SNPs) that mark these haplotype blocks fall within non-coding regions of the genome, hindering their functional validation. While some of these GWAS loci may contain cis- acting regulatory DNA elements such as enhancers, we hypothesized that many are also transcribed into non-coding RNAs that are missing from publicly available transcriptome annotations. Here, we use targeted RNA capture (‘RNA CaptureSeq’) in combination with nanopore long-read cDNA sequencing to transcriptionally profile 1,023 haplotype blocks across the genome containing non-coding GWAS SNPs associated with neuropsychiatric traits, using post-mortem human brain tissue from three neurologically healthy donors. We find that the majority (62%) of targeted haplotype blocks, including 13% of intergenic blocks, are transcribed into novel, multi-exonic RNAs, most of which are not yet recorded in GENCODE annotations. We validated our findings with short-read RNA-seq, providing orthogonal confirmation of novel splice junctions and enabling a quantitative assessment of the long-read assemblies. Many novel transcripts are supported by independent evidence of transcription including cap analysis of gene expression (CAGE) data and epigenetic marks, and some show signs of potential functional roles. We present these transcriptomes as a preliminary atlas of non-coding transcription in human brain that can be used to connect neurological phenotypes with gene expression.