Automating Citrus Budwood Processing for Downstream Pathogen Detection Through Instrument Engineering.

ABSTRACT

Graft-transmissible, phloem-limited pathogens of citrus such as viruses, viroids, and bacteria are responsible for devastating epidemics and serious economic losses worldwide. For example, the citrus tristeza virus killed over 100 million citrus trees globally, while "Candidatus Liberibacter asiaticus" has cost Florida $9 billion. The use of pathogen-tested citrus budwood for tree propagation is key for the management of such pathogens. The Citrus Clonal Protection Program (CCPP) at the University of California, Riverside, uses polymerase chain reaction (PCR) assays to test thousands of samples from citrus budwood source trees every year to protect California's citrus and to provide clean propagation units to the National Clean Plant Network. A severe bottleneck in the high-throughput molecular detection of citrus viruses and viroids is the plant tissue processing step. Proper tissue preparation is critical for the extraction of quality nucleic acids and downstream use in PCR assays. Plant tissue chopping, weighing, freeze-drying, grinding, and centrifugation at low temperatures to avoid nucleic acid degradation is time-intensive and labor-intensive and requires expensive and specialized laboratory equipment. This paper presents the validation of a specialized instrument engineered to rapidly process phloem-rich bark tissues from citrus budwood, named the budwood tissue extractor (BTE). The BTE increases sample throughput by 100% compared to current methods. In addition, it decreases labor and the cost of equipment. In this work, the BTE samples had a DNA yield (80.25 ng/µL) that was comparable with the CCPP's hand-chopping protocol (77.84 ng/µL). This instrument and the rapid plant tissue processing protocol can benefit several citrus diagnostic laboratories and programs in California and become a model system for tissue processing for other woody perennial crops worldwide.