Author
Listed:
- Ira W. Deveson
(Garvan Institute of Medical Research
University of New South Wales)
- Bindu Swapna Madala
(Garvan Institute of Medical Research)
- James Blackburn
(Garvan Institute of Medical Research
University of New South Wales)
- Chris Barker
(Garvan Institute of Medical Research)
- Ted Wong
(Garvan Institute of Medical Research)
- Kirston M. Barton
(Garvan Institute of Medical Research)
- Martin A. Smith
(Garvan Institute of Medical Research
University of New South Wales)
- D. Neil Watkins
(Garvan Institute of Medical Research
University of New South Wales
St Vincent’s Hospital)
- Tim R. Mercer
(Garvan Institute of Medical Research
University of New South Wales
Altius Institute for Biomedical Sciences)
Abstract
Chirality is a property describing any object that is inequivalent to its mirror image. Due to its 5′–3′ directionality, a DNA sequence is distinct from a mirrored sequence arranged in reverse nucleotide-order, and is therefore chiral. A given sequence and its opposing chiral partner sequence share many properties, such as nucleotide composition and sequence entropy. Here we demonstrate that chiral DNA sequence pairs also perform equivalently during molecular and bioinformatic techniques that underpin genetic analysis, including PCR amplification, hybridization, whole-genome, target-enriched and nanopore sequencing, sequence alignment and variant detection. Given these shared properties, synthetic DNA sequences mirroring clinically relevant or analytically challenging regions of the human genome are ideal controls for clinical genomics. The addition of synthetic chiral sequences (sequins) to patient tumor samples can prevent false-positive and false-negative mutation detection to improve diagnosis. Accordingly, we propose that sequins can fulfill the need for commutable internal controls in precision medicine.
Suggested Citation
Ira W. Deveson & Bindu Swapna Madala & James Blackburn & Chris Barker & Ted Wong & Kirston M. Barton & Martin A. Smith & D. Neil Watkins & Tim R. Mercer, 2019.
"Chiral DNA sequences as commutable controls for clinical genomics,"
Nature Communications, Nature, vol. 10(1), pages 1-13, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-09272-0
DOI: 10.1038/s41467-019-09272-0
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