Portal de Periódicos da CAPES

First Report of the White Pine Blister Rust Fungus, Cronartium ribicola, Infecting Pinus flexilis on Pine Mountain, Humboldt National Forest, Elko County, Northeastern Nevada

2016; American Phytopathological Society; Volume: 101; Issue: 5 Linguagem: Inglês

10.1094/pdis-10-16-1502-pdn

1943-7692

D. R. Vogler, Patricia E. Maloney, Trevor O. Burt, Jacob Snelling,

Mycorrhizal Fungi and Plant Interactions

HomePlant DiseaseVol. 101, No. 5First Report of the White Pine Blister Rust Fungus, Cronartium ribicola, Infecting Pinus flexilis on Pine Mountain, Humboldt National Forest, Elko County, Northeastern Nevada PreviousNext DISEASE NOTES OPENOpen Access licenseFirst Report of the White Pine Blister Rust Fungus, Cronartium ribicola, Infecting Pinus flexilis on Pine Mountain, Humboldt National Forest, Elko County, Northeastern NevadaD. R. Vogler, P. E. Maloney, T. Burt, and J. SnellingD. R. VoglerSearch for more papers by this author, P. E. MaloneySearch for more papers by this author, T. BurtSearch for more papers by this author, and J. SnellingSearch for more papers by this authorAffiliationsAuthors and Affiliations D. R. Vogler , USDA Forest Service, PSW Research Station, Institute of Forest Genetics, Placerville, CA 95667 P. E. Maloney , Tahoe Environmental Research Center, Incline Village, NV 89451 T. Burt , P. O. Box 2572, Kings Beach, CA 96143 J. Snelling , Oregon State University, Corvallis, OR 97331. Published Online:1 Mar 2017https://doi.org/10.1094/PDIS-10-16-1502-PDNAboutSections ToolsAdd to favoritesDownload CitationsTrack Citations ShareShare onFacebookTwitterLinked InRedditEmailWechat In 2013, while surveying for five-needle white pine cone crops in northeastern Nevada, we observed white pine blister rust, caused by the rust pathogen Cronartium ribicola Fisch., infecting branches and stems of limber pines (Pinus flexilis James) on Pine Mountain (41.76975°N, 115.61622°W), Humboldt National Forest, Elko County, Nevada. Nearby whitebark pines (P. albicaulis Engelm.) were also infected. Pine Mountain rises to 2,636 m, is sparsely forested, and is located 11.25 km west of the Jarbidge Mountains, where infection by blister rust on whitebark pine was first reported at Coon Creek Summit in 2004 (Vogler and Charlet 2004). In mid-June 2014, we revisited Pine Mountain to collect aeciospores from infections on pine; however, no sporulation was observed, though symptoms (branch and stem swellings, bark lesions, and traces of the previous year’s bleached aeciospores) were visible on both pine species. In mid-June 2015, we returned to Pine Mountain and collected several vials of rust aeciospores from sporulating single-branch infections on three limber and two whitebark pines. We also noted active urediniospore production on infected leaves of nearby alternate host Ribes cereum Dougl. The oldest pine infections were on branch internodes dated back to 2005, indicating that the pathogen has been present on Pine Mountain for approximately a decade, but had not been reported. To confirm that the pathogen is C. ribicola, we extracted DNA from ground limber and whitebark pine-host aeciospores, amplified the internal transcribed spacer (ITS) region with basidiomycete-specific primers ITS1f and ITS4b (Gardes and Bruns 1993), and sequenced the PCR products to yield an 869-bp consensus sequence (GenBank accession no. KX574673) that differs by a single nucleotide (0.12%) from the matching segment of a C. ribicola ITS reference sequence (DQ533975), confirming that the fungus collected on both pine hosts at Pine Mountain is C. ribicola. These findings support two conclusions: (1) C. ribicola is spreading westward and establishing upon both known and previously uninfected hosts of the white pine group and on Ribes spp. in the Nevada Great Basin, despite the geographic isolation and small sizes of these forested islands; and (2) discovery of blister rust infection in remote locations may be delayed by a decade or more after the first Ribes plant or pine host has become infected.References:Gardes, M., and Bruns, T. D. 1993. Mol. Ecol. 2:113. https://doi.org/10.1111/j.1365-294X.1993.tb00005.x Crossref, ISI, Google ScholarVogler, D. R., and Charlet, D. A. 2004. Plant Dis. 88:772. Abstract, Google ScholarDetailsFiguresLiterature CitedRelated Vol. 101, No. 5 May 2017SubscribeISSN:0191-2917e-ISSN:1943-7692 Metrics Article History Issue Date: 14 Apr 2017Published: 1 Mar 2017First Look: 9 Nov 2016Accepted: 2 Nov 2016 Pages: 839-839 Information© 2017 The American Phytopathological SocietyCited byIntegrating forest health conditions and species adaptive capacities to infer future trajectories of the high elevation five-needle white pinesForest Ecology and Management, Vol. 521Cronartium ribicola (white pine blister rust)CABI Compendium, Vol. CABI CompendiumLet it snow? Spring snowpack and microsite characterize the regeneration niche of high‐elevation pines13 May 2021 | Journal of Biogeography, Vol. 48, No. 8Species identification of European forest pathogens of the genus Milesina (Pucciniales) using urediniospore morphology and molecular barcoding including M. woodwardiana sp. nov.5 February 2019 | MycoKeys, Vol. 48