RPB0223

Pathogen Description

Target Pathogen Pathogen Name NCBI Taxonomy ID Order Family Genus Species Pathogen type
SARS-CoV-2 SARS-CoV-2, 2019-nCoV, COVID-19, COVID-19 virus, SARS2, Wuhan coronavirus, Human coronavirus 2019, COVID19, HCoV-19, SARS-2, SARS-CoV4 2697049 Nidovirales Coronaviridae Betacoronavirus Severe acute respiratory syndrome-related coronavirus virus

Primer Description

Primer Name Sequence(5'-3') Length(bp) Primer Final Concentration(μM) GC Content(%) Predicted Melting Temperature(℃) Molecular Weight(g/moles) Positions in GenBank accession number
F for D614G CACCAGGAACAAATACTTCTAACCAGGTTG 30 10μM 43.33 59.03 9168.05 \
R for D614G CATTAGAACCTGTAGAATAAACACGCCAAG 30 10μM 40 57.18 9201.08 \

Gene Description

Target Gene GenBank ID
D614G NC_045512.2

Assay Description

Application Assay Primer Designing Software Reaction Time(min) Assay Temperature(℃) Readout System(s) Limit of Detection(LoD) Sensitivity(%) Specificity(%)
SARS-CoV-2 point mutation detection platform based on RPA-CRISPR\Cas12a technology. \ \ \ 37 °C CRISPR system \ \ \

Publication Description

Year of Publication Title Author(s) Journal PMID DOI
2024 Iterative crRNA design and a PAM-free strategy enabled an ultra-specific RPA-CRISPR\Cas12a detection platform Xujian Mao,Jian Xu,Jingyi Jiang,Qiong Li,Ping Yao,Jinyi Jiang,Li Gong,Yin Dong,Bowen Tu,Rong Wang,Hongbing Tang,Fang Yao,Fengming Wang communication Biology 39506042 10.1038/s42003-024-07173-7

Iterative crRNA design and a PAM-free strategy enabled an ultra-specific RPA-CRISPR\Cas12a detection platform

Author(s):

Xujian Mao,Jian Xu,Jingyi Jiang,Qiong Li,Ping Yao,Jinyi Jiang,Li Gong,Yin Dong,Bowen Tu,Rong Wang,Hongbing Tang,Fang Yao,Fengming Wang

Journal:

communication Biology

Year:

2024

Abstract:

CRISPR/Cas12a is a highly promising detection tool. However, detecting single nucleotide variations (SNVs) remains challenging. Here, we elucidate Cas12a specificity through crRNA engineering and profiling of single- and double-base mismatch tolerance across three targets. Our findings indicate that Cas12a specificity depends on the number, type, location, and distance of mismatches within the R-loop. We also find that introducing a wobble base pair at position 14 of the R-loop does not affect the free energy change when the spacer length is truncated to 17 bp. Therefore, we develop a new universal specificity enhancement strategy via iterative crRNA design, involving truncated spacers and a wobble base pair at position 14 of the R-loop, which tremendously increases specificity without sacrificing sensitivity. Additionally, we construct a PAM-free one-pot detection platform for SARS-CoV-2 variants, which effectively distinguishes SNV targets across various GC contents. In summary, our work reveals new insights into the specificity mechanism of Cas12a and demonstrates significant potential for in vitro diagnostics.