An Array-based Melt Curve Analysis Method for the Identification and Classification of Closely Related Pathogen Strains

Overview

Journal Biol Methods Protoc

Publisher Oxford University Press

Specialty Biology

Date 2020 Mar 13

PMID 32161799

Authors

Arjang Hassibi

Jessica Ebert

Sara Bolouki

Alexander Anemogiannis

Gelareh Mazarei

Yuan Li

Kirsten A Johnson

Tran Van

Pallavi Mantina

Taraneh Gharooni

Kshama Jirage

Lei Pei

Ruma Sinha

Arun Manickam

Amin Zia

Pejman Naraghi-Arani

Gary Schoolnik

Robert G Kuimelis

Affiliations

Soon will be listed here.

Abstract

PCR-based techniques are widely used to identify disease causing bacterial and viral pathogens, especially in point-of-care or near-patient clinical settings that require rapid results and sample-to-answer workflows. However, such techniques often fail to differentiate between closely related species that have highly variable genomes. Here, a homogenous (closed-tube) pathogen identification and classification method is described that combines PCR amplification, array-based amplicon sequence verification, and real-time detection using an inverse fluorescence fluorescence-resonance energy transfer technique. The amplification is designed to satisfy the inclusivity criteria and create ssDNA amplicons, bearing a nonradiating quencher moiety at the 5'-terminus, for all the related species. The array includes fluorescent-labeled probes which preferentially capture the variants of the amplicons and classify them through solid-phase thermal denaturing (melt curve) analysis. Systematic primer and probe design algorithms and empirical validation methods are presented and successfully applied to the challenging example of identification of, and differentiation between, closely related human rhinovirus and human enterovirus strains.

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