Molecular inversion probe: a new tool for highly specific detection of plant pathogens.

Highly specific detection methods, capable of reliably identifying plant pathogens are crucial in plant disease management strategies to reduce losses in agriculture by preventing the spread of diseases. We describe a novel molecular inversion probe (MIP) assay that can be potentially developed into a robust multiplex platform to detect and identify plant pathogens. A MIP has been designed for the plant pathogenic fungus Fusarium oxysporum f.sp. conglutinans and the proof of concept for the efficiency of this technology is provided. We demonstrate that this methodology can detect as little as 2.5 ng of pathogen DNA and is highly specific, being able to accurately differentiate Fusarium oxysporum f.sp. conglutinans from other fungal pathogens such as Botrytis cinerea and even pathogens of the same species such as Fusarium oxysporum f.sp. lycopersici. The MIP assay was able to detect the presence of the pathogen in infected Arabidopsis thaliana plants as soon as the tissues contained minimal amounts of pathogen. MIP methods are intrinsically highly multiplexable and future development of specific MIPs could lead to the establishment of a diagnostic method that could potentially screen infected plants for hundreds of pathogens in a single assay.

Methylsorb: a simple method for quantifying DNA methylation using DNA-gold affinity interactions.

The analysis of DNA methylation is becoming increasingly important both in the clinic and also as a research tool to unravel key epigenetic molecular mechanisms in biology. Current methodologies for the quantification of regional DNA methylation (i.e., the average methylation over a region of DNA in the genome) are largely affected by comprehensive DNA sequencing methodologies which tend to be expensive, tedious, and time-consuming for many applications. Herein, we report an alternative DNA methylation detection method referred to as "Methylsorb", which is based on the inherent affinity of DNA bases to the gold surface (i.e., the trend of the affinity interactions is adenine > cytosine ≥ guanine > thymine).1 Since the degree of gold-DNA affinity interaction is highly sequence dependent, it provides a new capability to detect DNA methylation by simply monitoring the relative adsorption of bisulfite treated DNA sequences onto a gold chip. Because the selective physical adsorption of DNA fragments to gold enable a direct read-out of regional DNA methylation, the current requirement for DNA sequencing is obviated. To demonstrate the utility of this method, we present data on the regional methylation status of two CpG clusters located in the EN1 and MIR200B genes in MCF7 and MDA-MB-231 cells. The methylation status of these regions was obtained from the change in relative mass on gold surface with respect to relative adsorption of an unmethylated DNA source and this was detected using surface plasmon resonance (SPR) in a label-free and real-time manner. We anticipate that the simplicity of this method, combined with the high level of accuracy for identifying the methylation status of cytosines in DNA, could find broad application in biology and diagnostics.

Molecular inversion probe-based SPR biosensing for specific, label-free and real-time detection of regional DNA methylation.

DNA methylation has the potential to be a clinically important biomarker in cancer. This communication reports a real-time and label-free biosensing strategy for DNA methylation detection in the cancer cell line. This has been achieved by using surface plasmon resonance biosensing combined with the highly specific molecular inversion probe based amplification method, which requires only 50 ng of bisulfite treated genomic DNA.

Accurate detection of methylated cytosine in complex methylation landscapes.

Monitoring DNA methylation can be a useful biomarker for disease diagnosis and prognosis. However, monitoring the methylation status of a specific cytosine biomarker is often confounded by heterogeneous peripheral DNA methylation. To address this issue, molecular inversion probes were designed with inosine strategically positioned to complement suspected DNA methylation sites. This enabled the methylation status of a specific cytosine to be accurately measured with a high level of specificity, irrespective of adjacent epigenetic modifications.

Epiallele quantification using molecular inversion probes.

The location and level of DNA methylation within a genome is emerging as an important biomarker for cancer diagnosis. Despite its potential, it is difficult to comprehensively analyze the epialleles that are often found in a biological sample. Therefore, an assay utilizing molecular inversion probes was designed and used to expose and quantify epialleles in heterogeneously methylated bisulphite treated genomic DNA. Different CpG dinucleotides were able to be rapidly quantified with high resolution, sensitivity and specificity over a large dynamic range using rapid flow cytometric readout of multiplexable microbead DNA biosensors.

Considerations of solid-phase DNA amplification.

Solid-phase (SP) polymerase chain reaction (PCR) is an increasingly popular tool used to produce immobilized DNA for a variety of applications, including high-throughput DNA sequencing and SNP analysis. Despite its usefulness, the mechanism of DNA amplification using immobilized primers has not been thoroughly explored. Herein, we describe a SP-PCR process that was designed to explore and better understand some limitations of SP-DNA amplification. The rate of SP-DNA amplification was measured, and the ability to exponentially amplify DNA on a surface was demonstrated. Approximately 50 amol of DNA was amplified to detectable levels using SP-PCR. The mechanism and some limitations of the reaction were investigated by measuring the density of the primer on the surface prior to amplification and the amount of immobilized amplicon produced after SP-PCR. This enabled some of the practical limitations of the reaction to be addressed within a logical theoretical framework.

Quantitative considerations for suspension array assays.

A novel format of a multiplex microbead assay that is capable of accurately and reproducibly measuring small changes in 10(8) copies of a nucleic acid is reported herein. The dynamic range of the assay was 32-fold greater than conventional multiplex microbead assays. The assay was modeled mathematically which enabled the accuracy of DNA quantification to be formally analysed using a logical theoretical framework. The assay was also evaluated on RNA extracts taken from stimulated macrophages, to demonstrate that changes in gene expression can be accurately monitored in a biological system. We believe the reproducibility and accuracy of the assay presented herein will be useful for high-throughput, multiplex sensitive detection of nucleic acids over a large dynamic range in a research or diagnostic setting.