Argonaute-mediated system for supersensitive and multiplexed detection of rare mutations

The ability to detect rare mutations has revolutionized diagnosis and monitoring of tumors, but is limited by the shortage of sensitive, cost-effective and high coverage methods for identification of extremely low abundant mutations. Here, we establish a single-tube multiplex PCR system by employing thermophilic Argonaute-derived DNA-guided nuclease for highly efficient rare mutation detection, referred to as A-Star (Argonaute-directed specific target enrichment and detection), that combines the selective cleavage of the wild type DNA in the DNA denaturation step and the followed amplification of mutant DNA during PCR. A-Star enables easy detection and quantitation of rare mutations originally as low as 0.01% in allele frequency with a ⩾ 5500-fold efficiency. We also demonstrate the feasibility of A-Star for detecting oncogenic mutations in complex biological systems such as solid tumors tissues and blood samples. Remarkably, A-Star could achieve the detection of multiple oncogenic genes simultaneously through a simple single-tube reaction. Taken together, our work illustrates a supersensitive and rapid nucleic acid detection system, thereby extending the utility for both research and therapeutic applications.

Development of a 4-valent genotyping assay for direct identification of the most frequent Pseudomonas aeruginosa serotypes from respiratory specimens of pneumonia patients

Pseudomonas aeruginosa is a common cause of nosocomial infections and is associated with high rates of mortality. In order to facilitate rapid and sensitive identification of the most prevalent serotypes of P. aeruginosa, we have developed a 4-valent real-time PCR-based assay using oligonucleotides specific for open-reading frames constituting the O-antigen-specific lipopolysaccharide loci of P. aeruginosa. The assay simultaneously detects and differentiates between each of the four serotypes IATS-O1, -O6, -O11 and serogroup 2 (IATS-O2, -O5, and -O16) with high sensitivity and specificity in a single-tube reaction. No cross-reactivity was observed with other serotypes of P. aeruginosa or other microbial species, and reproducibility was demonstrated regardless of template, i.e. purified DNA, bacterial culture and clinical specimens (broncho-alveolar lavage). The limit of detection of the assay was approximately 100 copies per reaction for IATS-O1, -O2 and -O11, and 50 copies per reaction for IATS-O6. Comparison of the assay specificity with a commercially available slide agglutination kit showed consistent results; however, the number of non-typable isolates was reduced by 15 % using the genotyping assay. Use of the 4-valent genotyping assay in the context of a clinical trial resulted in identification of pneumonia patients positive for the IATS-O11 serotype, and hence eligible for therapy with panobacumab (an investigational monoclonal antibody against the O-polysaccharide of serotype IATS-O11).

Detection ofBacillus sphaericusmosquitocidal toxin genes by multiplex colony PCR

A multiplex colony PCR assay was developed for the detection of 5 genes encoding Bacillus sphaericus mosquito larvicidal toxins, namely binA, binB, mtx1, mtx2, and mtx3. Primers designed for these 5 genes yielded specific PCR amplicons of the expected size from type cultures of B. sphaericus. This method of detecting multiple toxin genes by colony PCR in a single tube reaction is a simple, rapid, and economical technique for identification of highly toxic environmental B. sphaericus isolates.

A multiplex PCR assay for the simultaneous detection and discrimination of the sevenEimeriaspecies that infect domestic fowl

This study reports the development of a novel multiplex PCR assay based on SCAR (Sequence-Characterised Amplified Region) markers for the simultaneous diagnosis of the 7Eimeriaspecies that infect domestic fowl. Primer pairs specific for each species were designed in order to generate a ladder of amplification products ranging from 200 to 811 bp. Sensitivity tests for each species were carried out, showing a detection threshold of 1–5 pg, which corresponds approximately to 2–8 sporulated oocysts. Distinct isolates of the 7Eimeriaspecies from different geographical sources were tested and successfully detected by the assay. All the species were amplified homogeneously, whether or not one of them was present in a high quantity, indicating that there was no cross-interference. The assay was also tested with different sources ofTaqDNA polymerase and thermocycler models, confirming the high reproducibility of the reaction. The economy of consumables and labour represented by a single-tube reaction greatly facilitates the molecular diagnosis of a large number of samples, making it appropriate for field epizootiological surveys. We propose the use of this multiplex PCR assay as a rapid and cost-effective diagnostic method for the detection and discrimination of the 7Eimeriaspecies that infect domestic fowl.