Rickettsia species identified in adult, host-seeking Dermacentor occidentalis (Acari: Ixodidae) from Baja California, Mexico, and Oregon and Washington, United States.

The Pacific Coast tick (Dermacentor occidentalis Marx, 1892) is a frequently encountered and commonly reported human-biting tick species that has been recorded from most of California and parts of southwestern Oregon, southcentral Washington, and northwestern Mexico. Although previous investigators have surveyed populations of D. occidentalis for the presence of Rickettsia species across several regions of California, populations of this tick have not been surveyed heretofore for rickettsiae from Baja California, Oregon, or Washington. We evaluated 1,367 host-seeking, D. occidentalis adults collected from 2015 to 2022 by flagging vegetation at multiple sites in Baja California, Mexico, and Oregon and Washington, United States, using genus- and species-specific assays for spotted fever group rickettsiae. DNA of Rickettsia 364D, R. bellii, and R. tillamookensis was not detected in specimens from these regions. DNA of R. rhipicephali was detected in D. occidentalis specimens obtained from Ensenada Municipality in Baja California and southwestern Oregon, but not from Washington. All ompA sequences of R. rhipichephali that were amplified from individual ticks in southwestern Oregon were represented by a single genotype. DNA of the Ixodes pacificus rickettsial endosymbiont was amplified from specimens collected in southwestern Oregon and Klickitat County, Washington; to the best of our knowledge, this Rickettsia species has never been identified in D. occidentalis. Collectively, these data are consistent with a relatively recent introduction of Pacific Coast ticks in the northernmost extension of its recognized range.

Factors Influencing Distribution of Coccidioides immitis in Soil, Washington State, 2016.

Coccidioides immitis and Coccidioides posadasii are causative agents of Valley fever, a serious fungal disease endemic to regions with hot, arid climate in the United States, Mexico, and Central and South America. The environmental niche of Coccidioides spp. is not well defined, and it remains unknown whether these fungi are primarily associated with rodents or grow as saprotrophs in soil. To better understand the environmental reservoir of these pathogens, we used a systematic soil sampling approach, quantitative PCR (qPCR), culture, whole-genome sequencing, and soil chemical analysis to identify factors associated with the presence of C. immitis at a known colonization site in Washington State linked to a human case in 2010. We found that the same strain colonized an area of over 46,000 m2 and persisted in soil for over 6 years. No association with rodent burrows was observed, as C. immitis DNA was as likely to be detected inside rodent holes as it was in the surrounding soil. In addition, the presence of C. immitis DNA in soil was correlated with elevated levels of boron, calcium, magnesium, sodium, and silicon in soil leachates. We also observed differences in the microbial communities between C. immitis-positive and -negative soils. Our artificial soil inoculation experiments demonstrated that C. immitis can use soil as a sole source of nutrients. Taken together, these results suggest that soil parameters need to be considered when modeling the distribution of this fungus in the environment. IMPORTANCE Coccidioidomycosis is considered a highly endemic disease for which geographic range is likely to expand from climate change. A better understanding of the ecological niche of Coccidioides spp. is essential for generating accurate distribution maps and predicting future changes in response to the changing environment. Our study used a systematic sampling strategy, advanced molecular detection methods, and soil chemical analysis to identify environmental factors associated with the presence of C. immitis in soil. Our results demonstrate the fungus can colonize the same areas for years and is associated with chemical and microbiological soil characteristics. Our results suggest that in addition to climate parameters, soil characteristics need to be considered when building habitat distribution models for this pathogen.

Real-time PCR quantification of Rhizoctonia solani AG-3 from soil samples.

Rhizoctonia solani anastomosis group 3 (AG-3) causes several diseases of potato, including black scurf and stem canker, affecting potato production in the Skagit Valley, Washington, and around the world. Primers for a SYBR-Green II-based real-time polymerase chain reaction (qPCR) assay were designed from sequences of the nuclear internal transcribed spacer (ITS) regions of fungal isolates of potato and onion from the Pacific Northwest, USA. The primers preferentially amplified R. solani AG-3 DNA, compared to DNA from R. solani AG-4, AG-5 and AG-8. In silico analysis of primer-template duplex stability indicated that the assay also will detect R. solani AG-3 isolates from pea and onion in Washington State and from diverse crop species around the world, but not R. solani AG-9 and AG-2-1. The assay was used to quantify R. solani AG-3 populations in pathogen-infested field soils after temporary flooding rotation, a practice found to be effective for reducing Sclerotinia sclerotiorum and R. solani AG-3 in potatoes in growth chamber studies. Population densities of the pathogen were not significantly reduced in saturated (flooded) soils relative to fallow. However, the qPCR approach was more sensitive and quantitative than the toothpick baiting method for diagnosis of these soil samples. Accurate detection and quantification of R. solani AG-3 in soil will facilitate the development of integrated management plans for Rhizoctonia diseases of potato.