RPB0212

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 AGGTTTCAAACTTTACTTGCTTTACATAGA 30 \ 30 53.75 9170.05 \
R TCCTAGGTTGAAGATAACCCACATAATAAG 30 \ 36.7 55.18 9207.08 \

Gene Description

Target Gene GenBank ID
S gene \

Assay Description

Application Assay Primer Designing Software Reaction Time(min) Assay Temperature(℃) Readout System(s) Limit of Detection(LoD) Sensitivity(%) Specificity(%)
\ RPA-CRISPR-Cas12a \ 22 40 Fluorometric detection (Fluorescent metal ion indicator (Calcein)) 5 copies \ \

Publication Description

Year of Publication Title Author(s) Journal PMID DOI
2021 Integrating Reverse Transcription Recombinase Polymerase Amplification with CRISPR Technology for the One-Tube Assay of RNA Wei Feng , Hanyong Peng , Jingyang Xu , Yanming Liu , Kanti Pabbaraju , Graham Tipples, Michael A Joyce , Holly A Saffran , D Lorne Tyrrell , Shawn Babiuk , Hongquan Zhang , X Chris Le Analytical Chemistry 34506127 10.1021/acs.analchem.1c03456

Integrating Reverse Transcription Recombinase Polymerase Amplification with CRISPR Technology for the One-Tube Assay of RNA

Author(s):

Wei Feng , Hanyong Peng , Jingyang Xu , Yanming Liu , Kanti Pabbaraju , Graham Tipples, Michael A Joyce , Holly A Saffran , D Lorne Tyrrell , Shawn Babiuk , Hongquan Zhang , X Chris Le

Journal:

Analytical Chemistry

Year:

2021

Abstract:

CRISPR-Cas systems integrated with nucleic acid amplification techniques improve both analytical specificity and sensitivity. We describe here issues and solutions for the successful integration of reverse transcription (RT), recombinase polymerase amplification (RPA), and CRISPR-Cas12a nuclease reactions into a single tube under an isothermal condition (40 °C). Specific detection of a few copies of a viral DNA sequence was achieved in less than 20 min. However, the sensitivity was orders of magnitude lower for the detection of viral RNA due to the slow initiation of RPA when the complementary DNA (cDNA) template remained hybridized to RNA. During the delay of RPA, the crRNA-Cas12a ribonucleoprotein (RNP) gradually lost its activity in the RPA solution, and nonspecific amplification reactions consumed the RPA reagents. We overcame these problems by taking advantage of the endoribonuclease function of RNase H to remove RNA from the RNA-cDNA hybrids and free the cDNA as template for the RPA reaction. As a consequence, we significantly enhanced the overall reaction rate of an integrated assay using RT-RPA and CRISPR-Cas12a for the detection of RNA. We showed successful detection of 200 or more copies of the S gene sequence of SARS-CoV-2 RNA within 5-30 min. We applied our one-tube assay to 46 upper respiratory swab samples for COVID-19 diagnosis, and the results from both fluorescence intensity measurements and end-point visualization were consistent with those of RT-qPCR analysis. The strategy and technique improve the sensitivity and speed of RT-RPA and CRISPR-Cas12a assays, potentially useful for both semi-quantitative and point-of-care analyses of RNA molecules.