Identification of individuals from low template blood samples using whole transcriptome shotgun sequencing

Forensic Sci Int Genet. 2024 Sep:72:103089. doi: 10.1016/j.fsigen.2024.103089. Epub 2024 Jun 19.

Abstract

Biological trace samples consisting of very few cells pose a challenge to conventional forensic genetic DNA analysis. RNA may be an alternative to DNA when handling low template samples. Whereas each cell only contains two copies of an autosomal DNA segment, the transcriptome retains much of the genomic variation replicated in abundant RNA fragments. In this study, we describe the development of a prototype RNA-based SNP selection set for forensic human identification from low template samples (50 pg gDNA). Whole blood from a subset of the Danish population (41 individuals) and blood stains subjected to degradation at room temperature for up to two weeks were analysed by whole transcriptome shotgun sequencing. Concordance was determined by DNA genotyping with the Infinium Omni5-4 SNP chip. In the 100 protein-coding genes with the most reads, 5214 bi-allelic SNPs with gnomAD minor allele frequencies > 0.1 in the African/African American, East Asian, and (non-Finnish) European populations were identified. Of these, 24 SNPs in 21 genes passed screening in whole blood and degraded blood stains, with a resulting mean match probability of 4.5 ∙ 10-9. Additionally, ancestry informative SNPs and SNPs in genes useful for body fluid identification were identified in the transcriptome. Consequently, shotgun sequencing of RNA from low template samples may be used for a vast host of forensic genetics purposes, including simultaneous human and body fluid identification, leading to direct donor identification in the identified body fluid.

Keywords: Body fluid identification; Human identification; RNA shotgun sequencing; SNPs; Sensitivity; Whole transcriptome sequencing.

MeSH terms

  • Blood Stains
  • DNA Degradation, Necrotic
  • DNA Fingerprinting
  • Denmark
  • Forensic Genetics / methods
  • Gene Frequency
  • Humans
  • Polymorphism, Single Nucleotide*
  • Racial Groups / genetics
  • Transcriptome