A variety of commercial instruments are available for sampling and quantifying microscopic airborne organisms from the environment. Although most samplers are highly sensitive, they are also expensive, costing thousands of dollars per unit, a price that is out of reach for many researchers, especially those looking to design experiments with replication. While looking at options to monitor pine stands for the presence of Fusarium circinatum, the causal agent of pitch canker disease, on multiple sites with several units per site, we developed a simple, low-cost spore trap that allows surveying spore abundance in outdoor environments. The trap consists of a rotating motor that holds a metal rod and two petroleum jelly-coated microscope slides. As the motor rotates, the slides collect airborne particles. To test whether the traps allowed detection of F. circinatum spores, we placed six traps on three sites: an actively-managed slash pine commercial stand located in Lake Butler, FL, a semi-managed loblolly and slash pine stand near Gainesville, FL, and a site with little perturbance at Goethe State Forest, FL, consisting of mainly slash pine trees. The slides were replaced weekly, and F. circinatum was detected by quantitative PCR using species-specific primers. Results show detection of low levels ( X ¯ = 1.7–77.1 picograms ± SE = 0.3–39.7) of the pathogen spores with high reproducibility. These traps offer a low-cost solution to spore, pollen, or small insect trapping experiments for initial or general assessment of a pathogen or species population. Their low cost has the added benefit that multiple traps can be deployed per experiment, thus increasing statistical power by using multiple replications.
Numerous cankers on small branches showing dieback were observed on live oak (Quercus virginiana) trees in September 2010 in Marion County, FL. Approximately 24 12-year-old landscape trees planted on a farm displayed symptoms. Samples were collected from six of the symptomatic trees and returned to the laboratory for processing. Isolations were made from canker margins after surface sterilization of samples in 2.5% sodium hypochlorite and by plating on potato dextrose agar (PDA). A suspect Botryosphaeriaceae sp. (based on colony morphology) was consistently isolated from the symptomatic branches from all six trees sampled. Fungal colonies consisted of plentiful, white, aerial mycelium that turned dark olive after 5 to 7 days at 23°C with the underside of the cultures turning black (1). Total genomic DNA from three representative Botryosphaeriaceae sp. isolates was extracted and the internal transcribed spacer (ITS1-5.8s-ITS2) region of the rDNA (GenBank Accessions Nos. JF798638, JF798639, and JF798640) using the primers ITS1 and ITS4 (3) and a portion of the β-tubulin gene (Bt), (GenBank Accession Nos. JF798641, JF798642, and JF798641) using the primers Bt2a and Bt2b (2) were amplified, sequenced, and deposited in GenBank. BLASTn searches of the ITS-rDNA sequences resulted in 100% homology (467 of 467, 467 of 467, and 540 of 540, respectively) with Diplodia corticola isolate CBS 112074 (GenBank Accession No. AY268421). BLASTn searches of the Bt sequences resulted in 99, 98, and 99% (391 of 393, 396 of 400, and 392 of 394, respectively) matches with D. corticola strain UCD2397TX, GenBank Accession No. GU294724. To complete Koch's postulates, nine seedlings of Q. virginiana, 0.6 to 0.9 cm in diameter at ground line maintained in a greenhouse, were inoculated with isolate PL949 (GenBank Accession Nos. JF798638 and JF798641) by making a 1.5-cm incision with a single-edge razor blade into the xylem 10 cm above ground line. Inoculations were done by placing mycelial plugs (1 × 0.25 cm) from cultures on PDA in the incision with the mycelium facing the center of the stem. Wounds were sealed by wrapping them with Parafilm. Three negative controls were mock inoculated as previously described except sterile PDA plugs were used. Eight weeks postinoculation, the lengths of the necrotic lesions were measured. Mean lesion length of the inoculated seedlings was 41.2 cm ± SE 4.5 and ranged between 27 and 63 cm. The negative control inoculations showed no necrotic lesions. Three of the inoculated seedlings were plated on PDA in an effort to reisolate the inoculated fungus. D. corticola was reisolated from each and all had the same ITS sequence as D. corticola strain CBS 112074. To our knowledge, this is the first report of D. corticola causing cankers on Q. virginiana and the first report of the disease occurring in Florida. D. corticola has been reported to cause cankers and dieback in several Quercus spp. in Greece, Hungary, Italy, Morocco, Portugal, and Spain and has recently been reported to cause cankers on Q. chrysolepis and Q. agrifolia in California. References: (1) A. Alves et al. Mycologia. 96:598, 2004. (2) N. L. Glass and G. C. Donaldson. Appl. Environ. Microbiol. 61:1323, 1995. (3) T. J. White et al. PCR Protocols: A Guide to Methods and Applications. Academic Press, San Diego, 1990.
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