Heteromultivalency enables enhanced detection of nucleic acid mutations.
Brendan R DealRong MaSteven NarumHiroaki OgasawaraYuxin DuanJames T KindtKhalid SalaitaPublished in: Nature chemistry (2023)
Detecting genetic mutations such as single nucleotide polymorphisms (SNPs) is necessary to prescribe effective cancer therapies, perform genetic analyses and distinguish similar viral strains. Traditionally, SNP sensing uses short oligonucleotide probes that differentially bind the SNP and wild-type targets. However, DNA hybridization-based techniques require precise tuning of the probe's binding affinity to manage the inherent trade-off between specificity and sensitivity. As conventional hybridization offers limited control over binding affinity, here we generate heteromultivalent DNA-functionalized particles and demonstrate optimized hybridization specificity for targets containing one or two mutations. By investigating the role of oligo lengths, spacer lengths and binding orientation, we reveal that heteromultivalent hybridization enables fine-tuned specificity for a single SNP and dramatic enhancements in specificity for two non-proximal SNPs empowered by highly cooperative binding. Capitalizing on these abilities, we demonstrate straightforward discrimination between heterozygous cis and trans mutations and between different strains of the SARS-CoV-2 virus. Our findings indicate that heteromultivalent hybridization offers substantial improvements over conventional monovalent hybridization-based methods.
Keyphrases
- nucleic acid
- genome wide
- single molecule
- sars cov
- dna methylation
- copy number
- escherichia coli
- living cells
- dna binding
- wild type
- label free
- structural basis
- high density
- quantum dots
- squamous cell carcinoma
- small molecule
- single cell
- air pollution
- papillary thyroid
- photodynamic therapy
- respiratory syndrome coronavirus
- mass spectrometry
- squamous cell
- coronavirus disease
- transcription factor
- simultaneous determination