In particular, rapid methods that can be performed in the field, minimizing the delay between sampling and diagnosis, could reduce the spread of this pathogen. The most common method for rapid detection of P. sojae, which is found globally, was NVP-LDE225 in vivo developed based on conventional polymerase chain reaction (PCR)(Wang et al., 2006). However, this method might not be suitable for developing countries because of the high-tech equipment required, elaborate and complicated assay procedures, expensive reagents, time requirements, and the frequency of false-positives. Therefore, there is a growing demand for simple and economical molecular tests. In this study, we developed an alternative amplification method that can
be used in Rucaparib concentration the field to detect P. sojae in the absence of a thermal cycler.
Loop-mediated isothermal amplification (LAMP) of DNA is a novel technique that uses a set of four or six primers and the strand displacement activity of Bst DNA polymerase to amplify DNA with high specificity under isothermal conditions (Notomi et al., 2000). LAMP products can be monitored by measuring the increased turbidity (due to the production of large amounts of magnesium pyrophosphate) in real time, and visualized by gel electrophoresis or by adding hydroxynaphthol blue (HNB) prior to amplification (Ma et al., 2010). The simplicity of the LAMP method, which does not require a thermal cycler, makes it suitable for field testing. Although this method has been applied in the field of microbiology for detection and identification of bacteria (Pan et al., 2011), viruses (Parida et al., 2004) and fungi (Niessen & Vogel, 2010), the technique has not been applied to P. sojae. LAMP is simple once the appropriate primers have been designed based on the target gene (Notomi et al., 2000). PCR-based and quantitative real-time PCR-based methods for the detection of P. sojae have CHIR-99021 in vitro been described based on ribosomal gene sequences (Wang et al., 2006). However, rRNA gene sequences from closely related species are highly
conserved, limiting the development of species-specific detection primers. As a result, a new target with high specificity and efficiency is required to distinguish between closely related species for rapid detection of P. sojae. With the development of Phytophthora genomics and numerous molecular targets, the identification efficiency of Phytophthora species has increased significantly. We identified a new P. sojae identifiable target, named. A3aPro is a 300-bp deletion element in the upstream (1.5 kb in the promoter region) of the avirulence gene Avr3a in P. sojae Race 7, as compared with Race 2 and 12 (Supporting Information, Fig. S1). Further bioinformatics analysis showed it is a transposon-like element whose high-identity copies were commonly distributed in the sequenced P. sojae genome but absent in non-P. sojae species. We acquired the A3aPro sequence in the P.