Development of a universal endogenous qPCR control for eukaryotic DNA samples

Cecilia Mittelberger; Lisa Obkircher; Vicky Oberkofler; Alan Ianeselli; Christine Kerschbamer; Andreas Gallmetzer; Yazmid Reyes-Dominguez; Thomas Letschka; Katrin Janik

doi:10.1186/s13007-020-00597-2

Development of a universal endogenous qPCR control for eukaryotic DNA samples

Plant Methods. 2020 Apr 16:16:53. doi: 10.1186/s13007-020-00597-2. eCollection 2020.

Authors

Cecilia Mittelberger¹, Lisa Obkircher¹, Vicky Oberkofler¹, Alan Ianeselli¹, Christine Kerschbamer¹, Andreas Gallmetzer², Yazmid Reyes-Dominguez², Thomas Letschka¹, Katrin Janik¹

Affiliations

¹ Applied Genomics and Molecular Biology, Institute for Plant Health, Laimburg Research Centre, Pfatten, Italy.
² Virology and Diagnostics, Institute for Plant Health, Laimburg Research Centre, Pfatten, Italy.

Abstract

Background: Phytoplasma are obligate intracellular plant-pathogenic bacteria that infect a broad range of plant species and are transmitted by different insect species. Quantitative real-time PCR (qPCR) is one of the most commonly used techniques for pathogen detection, especially for pathogens that cannot be cultivated outside their host like phytoplasma. PCR analysis requires the purification of total DNA from the sample and subsequent amplification of pathogen DNA with specific primers. The purified DNA contains mainly host DNA and only a marginal proportion is of phytoplasmal origin. Therefore, detection of phytoplasma DNA in a host DNA background must be sensitive, specific and reliable and is highly dependent on the quality and concentration of the purified DNA. DNA quality and concentration and the presence of PCR-inhibitors therefore have a direct impact on pathogen detection. Thus, it is indispensable for PCR-based diagnostic tests to validate the DNA preparation and DNA integrity before interpreting diagnostic results, especially in case that no pathogen DNA is detected. The use of an internal control allows to evaluate DNA integrity and the detection of PCR-inhibiting substances. Internal controls are generally host-specific or limited to a defined group of related species. A control suitable for the broad range of phytoplasma hosts comprising different insect and plant species is still missing.

Results: We developed a primer and probe combination that allows amplification of a conserved stretch of the eukaryotic 28S rDNA gene. The developed endogenous qPCR control serves as a DNA quality control and allows the analysis of different eukaryotic host species, including plants, insects, fish, fungi, mammals and human with a single primer/probe set in single- or multiplex assays.

Conclusions: Quality and performance control is indispensable for pathogen detection by qPCR. Several plant pathogens are transmitted by insects and have a broad range of host species. The newly developed endogenous control can be used with all so far tested eukaryotic species and since multiplexing is possible, the described primer and probe set can be easily combined with other PCR-based pathogen detection systems.

Keywords: Endogenous control; Pathogen detection; Phytoplasma; Quantitative real-time PCR; Reference gene.