Real-time single-base specific detection of the Haemonchus contortus S168T variant associated with levamisole resistance using loop-primer endonuclease cleavage loop-mediated isothermal amplification

Development of a loop-mediated isothermal amplification detection assay for Dictyocaulus viviparus (Bloch, 1782) lungworm: DviLAMP

The bovine lungworm, Dictyocaulus viviparus (Bloch, 1782), is highly pathogenic and disease outbreaks can be difficult to predict and manage. Rapid and accurate diagnosis is vital, but without a sensitive diagnostic test this remains challenging in clinical practice. High performance molecular detection tools are therefore required to improve the diagnosis of this parasite and promote the implementation of strategic control measures. Loop-mediated isothermal amplification (LAMP), a rapid DNA assay, offers potential for field-based detection. Here we report a novel LAMP assay (DviLAMP), that was designed to target the D. viviparus internal transcribed spacer 2 (ITS2) ribosomal DNA region. Firstly, genomic DNA was extracted from a single D. viviparus L1 larva to amplify and clone the ITS2 into the recombinant plasmid (DviITS2). The DviLAMP successfully detected the target, with results shown by gel electrophoresis and real-time analysis, in addition to point-of-care amenable end-point detection: colorimetry and lateral flow dipstick (LFD). Analytical sensitivity can detect 0.5 ng DviITS2 following 45 min of incubation at 64°C, increasing to just 1 pg following 90 min of incubation. Using the same primers, other nematodes of cattle, Ostertagia ostertagi and Cooperia oncophora, were also detectable both by gel electrophoresis and real-time. However, when FITC and biotin tagged primers were incorporated to adapt the DviLAMP to LFD end-point detection, the LFD showed specific detection of D. viviparus. Further development of DviLAMP as a point-of-care test could significantly improve the sensitivity of lungworm diagnosis in the field.

Next-generation sequencing technologies for helminth diagnostics and surveillance in ruminants: shifting diagnostic barriers

Helminth infections in grazing ruminants are a major issue for livestock farming globally, but are unavoidable in outdoor grazing systems and must be effectively managed to avoid deleterious effects to animal health, and productivity. Next-generation sequencing (NGS) technologies are transforming our understanding of the genetic basis of anthelmintic resistance (AR) and epidemiological studies of ruminant gastrointestinal parasites. They also have the potential to not only help develop and validate molecular diagnostic tests but to be directly used in routine diagnostics integrating species-specific identification and AR into a single test. Here, we review how these developments have opened the pathway for the development of multi-AR and multispecies identification in a single test, with widespread implications for sustainable livestock farming for the future.

Visualization and development of colorimetric loop-mediated isothermal amplification for the rapid detection and diagnosis of paramphistome infection: colorimetric PAR-LAMP

Colorimetric detection can be applied to differentiate between positive and negative conditions. It can be coupled with loop-mediated isothermal amplification to diagnose rumen fluke or paramphistome infection, also called colorimetric PAR-LAMP. This study conducted LAMP using three candidate indicator dyes, namely malachite green (MLG), methyl green (MTG), and neutral red (NTR), and the results were observed by the naked eye. The dye concentration was optimized to obtain the most pronounced positive-negative result discrimination. Subsequently, we conducted target sensitivity tests using the DNA of Fischoederius elongatus at different concentrations. To validate the detection accuracy, the result was confirmed by gel electrophoresis. The sensitivity test presented the lowest detectable DNA concentration or limit of detection (LOD), with 1 pg for MLG, 0.5 ng for MTG, and 50 pg for NTR. Different LODs revealed inhibition of LAMP reaction and reduced efficiency of result presentation for colorimetric-based detection, particularly NTR and MTG. For MLG-LAMP, we observed no cross-reaction of non-target DNA and improved reaction with the DNA of Fischoederius cobboldi and Calicophoron sp., with multi-detection. In addition, naked eye observation and agarose gel electrophoresis (AGE) evaluation of the MLG-LAMP results showed a moderate and strong agreement with LAMP-AGE and microscopic examinations. Based on our results, colorimetric PAR-LAMP is a rapid, comfortable, and point-of-care procedure for the diagnosis of paramphistome infection.