Development of an Innovative and Sustainable One-step Method for Rapid Plant DNA Isolation for Targeted PCR Using Magnetic Ionic Liquids

Overview

Journal Plant Methods

Publisher Biomed Central

Specialty Biology

Date 2019 Mar 23

PMID 30899320

Citations 6

Authors

Arianna Marengo

Cecilia Cagliero

Barbara Sgorbini

Jared L Anderson

Miranda N Emaus

Carlo Bicchi

Cinzia M Bertea

Patrizia Rubiolo

Affiliations

Soon will be listed here.

Abstract

Background: Nowadays, there is an increasing demand for fast and reliable plant biomolecular analyses. Conventional methods for the isolation of nucleic acids are time-consuming and require multiple and often non-automatable steps to remove cellular interferences, with consequence that sample preparation is the major bottleneck in the bioanalytical workflow. New opportunities have been created by the use of magnetic ionic liquids (MILs) thanks to their affinity for nucleic acids.

Results: In the present study, a MIL-based magnet-assisted dispersive liquid-liquid microextraction (maDLLME) method was optimized for the extraction of genomic DNA from (L.) Heynh leaves. MILs containing different metal centers were tested and the extraction method was optimized in terms of MIL volume and extraction time for purified DNA and crude lysates. The proposed approach yielded good extraction efficiency and is compatible with both quantitative analysis through fluorimetric-based detection and qualitative analysis as PCR amplification of multi and single locus genes. The protocol was successfully applied to a set of plant species and tissues.

Conclusions: The developed MIL-based maDLLME approach exhibits good enrichment of nucleic acids for extraction of template suitable for targeted PCR; it is very fast, sustainable and potentially automatable thereby representing a powerful tool for screening plants rapidly using DNA-based methods.

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