RESUMO
Moniliophthora perniciosa causes a destructive disease known as witches' broom disease of cacao (WBDC). WBDC has been responsible for major reductions in production or even total abandonment of cacao plantations in most countries that it has invaded. To date, however, the disease is known only from the cacao-producing regions of South America, and a few Central American and Caribbean countries. It is not known from the Eastern Hemisphere and remains a major threat should it invade West Africa or Southeast Asia, where the majority of the world's chocolate production now occurs. In 2019 a pink pigmented mushroom was found fruiting from unidentified twigs in the Serra Vamba of Angola. The specimen was identified as M. perniciosa based on morphological and molecular analyses. Although Angola is not a major cacao-producing country, the presence of the fungus in the Eastern Hemisphere could be of global concern and may indicate the need for quarantine in Angola and vigilance in neighboring countries.
RESUMO
Jewelweed (Impatiens spp., Balsaminaceae) is a common native annual plant within Pennsylvania wetland ecosystems, many of which are under threat from invasive non-native plants, and is an important wetland indicator plant (code FACW; facultative wetland). In May 2014, rust disease symptoms on native jewelweed (Impatiens capensis Meerb.) were observed within a small (0.1 ha) wet area in York County, southeastern Pennsylvania (39.9080648oN, -77.2472024oW). Rust symptoms were noted on most jewelweed plants within the wet area. Foliar symptoms included chlorosis and premature defoliation; infected stems were distorted. Infected leaves and stems contained orange, erumpent aecia with white fragmented peridia (Fig. 1). Symptomatic leaves and stem sections were collected from five infected plants within one small (5 X 5 m) plot in the center of the wet area and taken to the laboratory for microscopic observations and morphological measurements. Mean aecia diameter was 299.2 ± 55.0 µm (n = 60). Aeciospores were single-celled, orange, and generally globose (Fig. 2) with a mean diameter of 24.4 ± 1.4 µm, (n = 60). Disease symptomology and aecia morphology were consistent with Puccinia recondita Dietel & Holw. DNA extraction (from infected stem material), polymerase chain reactions, and DNA sequencing of the 28S region of the nuclear ribosomal DNA repeat was conducted following protocols in Aime (2006) and Aime et al. (2018). The sequence shares 99.34% identity (903 / 909 bp) with P. recondita (BPI 910319) collected in California (KY798399). A voucher specimen has been deposited in the Arthur Fungarium at Purdue University (PUR N24229) with corresponding 28S sequence (GenBank accession OR648406). P. recondita has been reported on native I. capensis in Indiana (Koslow and Clay 2010) and North Carolina (Grand 1985), but not in Pennsylvania to the best of our knowledge (Farr and Rossman 2022). If this rust disease becomes severe on native jewelweeds in Pennsylvania, it may adversely affect our ability to accurately classify native wetlands in the state. In addition, P. recondita is a heteroecious rust that is a major pathogen of grain crops of economic importance (i.e., wheat, barley, oats), which are grown in southeastern Pennsylvania near the infested area. Further research is warranted to understand if native, annual jewelweed can serve as a secondary or alternate host to cause rust disease in major cereal crops.
RESUMO
Limonium sinuatum (Plumbaginaceae) is the most commonly cultivated recognizable cut flower crop in the genus Limonium. It is known by several common names including statice and sea lavender, due to its lilac-colored flowers and the fact that it naturally inhabits mainly coastal areas (Mellesse et al, 2013). Limonium sinuatum is native to the Mediterranean, although as a popular garden plant, has been naturalized in other parts of the world including coastal areas of California (USDA NRCS 2020). Cultivated L. sinuatum is used in fresh and dry flower arrangements in the Americas, comprising approximately 20% of the floriculture cultivated area in Ecuador (Vega and Morales 2011; Abascal Cañas 2017). In December 2014, L. sinuatum plants in the public park "Baños del Inca" in Cajamarca, Peru (S 7 9'46"; W 78 27'53"), were found infected with a rust disease. The plants were scattered in the park but infection incidence was 100% as individual plants were all found to be infected (Fig 1). Based on the percentage of symptomatic areas, including the yellow halos around pustules, calculated with ImageJ (Collins, 2007) from field photographs, the disease severity was estimated to be 58.9% in average, ranging from 19.8% up to 90.0%. Uredinia were present on both sides of the leaves as well as on stems and were roundish, oblong, pulverulent, and cinnamon brown in color; urediniospores 25.5 to 35.0 × 22.5 to 31.0 µm, were globoid to ellipsoid; urediniospore walls were cinnamon-brown, 2.5 to 3.0 µm thick, densely verrucose, with 2 to 3 equatorial germ pores. Few telia were present on leaves; these were scattered roundish or oblong, and greyish in color; teliospores 26.5 to 41.0 × 16.0 to 25.0 µm, were ellipsoid to obovoid, mostly attenuated at the apex; teliospore walls were colorless, 2-3 µm thick at sides, and up to 10 µm thick at apex. Teliospores readily germinated in sori producing basidia and basidiospores (Fig. 2). The rust features and dimensions of rust spores are consistent with available descriptions of Uromyces savulescui Rayss (Guyot 1951; Vakalounakis and Malathrakis 1987). To confirm identity, a 576 bp region of the 28S subunit of the ribosomal DNA repeat was sequenced following previously published protocols and primers (Aime 2006, Aime et al. 2018). The resulting sequence (GenBank Accession No. OR291160) shared 99.83% (573/574 bp) identity with a sequence deposited as Uromyces limonii (DC.) Lev. (accession KY764194, BPI910295, Demers et al. unpublished) from L. sinuatum in Ethiopia. However, U. limonii produces orange uredinia, thin-walled yellow-orange urediniospores, teliospores with mostly light chestnut brown wall and infects different hosts (Savile and Conners 1951). It is likely that KY764194 represents a misannotated record of U. savulescui. While Koch's postulates can be a useful tool for establishing causality in certain infectious diseases, their use may be limited when it comes to rust diseases based on old herbarium specimens. In our case, due to the age of the specimen, which is almost nine years old, various other methods were employed to identify the pathogen. These methods included microscopic examination for morphological criteria of the urediniospores and teliospores, as well as molecular techniques like 28S rDNA sequencing. Rust disease on L. sinuatum has been previously reported in Ecuador but the causal agent was identified as a Puccinia sp. and reported that the rust was able to destroy entire plots in humid conditions (Vega and Morales 2011). Whether this report also represent U. savulescui is not certain, but given that the urediniospores of Puccinia species are generally 2-celled, it is unlikely. García-Hernández et al. (2008) reported U. limonii on Limonium spp. from Chile, and Coca (2020) also reported U. limonii on Limonium sp., from Bolivia. However, judging from the photomicrographs (Coca 2020), the rust in the latter report is definitely U. savulescui and not U. limonii. Uromyces savulescui has been previously reported from the Mediterranean region and the Canary Islands (Vakalounakis and Malathrakis 1987). To our knowledge there is no report of this rust in the Americas, excepting the probable misidentifications already listed herein. The specimen has been deposited in the Arthur Fungarium at Purdue University as PURN15037.
RESUMO
Coffee leaf rust (CLR), caused by Hemileia vastatrix Berk. & Broome (Zaghouaniaceae) is considered the most significant fungal disease of Coffea arabica L. (Rubiaceae), from which berries are harvested and processed to obtain coffee beverage (Talhinhas et al. 2017). In Florida, coffee plants are mainly used as ornamentals due to their fragrant flowers; however, there are ongoing field trials evaluating the adaptability of plants for coffee production to climate conditions in the state (Crane et al. 2005). In November 2021, young seedlings of C. arabica var. caturra from a residence in Naples (Collier County) in southwest Florida were discovered with signs of rust fungus. Minute, yellow, suprastomatal sori 53-81 µm in diam were formed on the abaxial leaf surface, forming blotches. Light-yellow urediniospores measured 29-31 × 20-29 µm, with a reniform or "hunchbacked" shape, had thick walls measuring 1.5-2.5 µm in height, and were dorsally echinulate, the individual spikes measuring 2.5-3.3 µm in height. Spikes were scattered over most of the dorsal surface and form a dense ridge separating the dorsal from the smooth ventral side. (e-Xtra Fig. 1). Symptoms and signs are consistent with published descriptions of CLR produced by H. vastatrix (Ritschel 2005). To confirm the identification, DNA sequencing of the large subunit (LSU) of the ribosomal repeat was done following the protocols of Aime (2006) (GenBank accession number OR296753-OR296754). The Florida specimen shares 100% sequence identity (887/728 bp) with other accessions of H. vastatrix in congruence with maximum likelihood phylogenetic analysis performed in RAxMLv8.0.0 (Stamatakis 2014) (e-Xtra Fig. 2). In addition to CLR, Hemileia coffeicola Maubl. & Roger, causal agent of powdery rust of coffee, produces similar leaf spots on coffee but has a restricted geographical distribution. This agent is found only above 500 m a.s.l. in central Africa (Silva et al. 2006) and produces larger urediniospores (34-40 × 20-28 µm) (Maublanc & Roger 1934) in sori are scattered in abaxial leaf surface giving a powdery appearance. Hemileia vastatrix has been reported from almost every major coffee growing country of the world as well as Hawaii and Puerto Rico (Keith et al. 2022, Ramirez-Camejo et al., 2022). This is the first report of CLR in the continental USA, however, CLR poses a limited threat to the USA agriculture in view of the fact coffee is not commercially grown within the continental USA. A voucher was made of dried symptomatic leaves and deposited at Plant Industry Gainesville Herbarium (PIHG 15712, 16332) and the Arthur Fungarium at Purdue University (PUR N23473). The remaining infested coffee seedlings were destroyed after phytopathological diagnosis, and the pathogen has been absent from all additional screenings since November 2021.
RESUMO
The recent description of the putative fungal pathogen of greenheart trees, Xylaria karyophthora (Xylariaceae, Ascomycota), prompted a study of its secondary metabolism to access its ability to produce cytochalasans in culture. Solid-state fermentation of the ex-type strain on rice medium resulted in the isolation of a series of 19,20-epoxidated cytochalasins by means of preparative high-performance liquid chromatography (HPLC). Nine out of 10 compounds could be assigned to previously described structures, with one compound being new to science after structural assignment via nuclear magnetic resonance (NMR) assisted by high-resolution mass spectrometry (HRMS). We propose the trivial name "karyochalasin" for the unprecedented metabolite. The compounds were used in our ongoing screening campaign to study the structure-activity relationship of this family of compounds. This was done by examining their cytotoxicity against eukaryotic cells and impact on the organization of networks built by their main target, actin-a protein indispensable for processes mediating cellular shape changes and movement. Moreover, the cytochalasins' ability to inhibit the biofilm formation of Candida albicans and Staphylococcus aureus was examined.
Assuntos
Xylariales , Cromatografia Líquida de Alta Pressão , Actinas/metabolismo , Citocalasinas/química , Citocalasinas/farmacologiaRESUMO
Common groundsel (Senecio vulgaris L.), is an aster native to Eurasia and is now a common weed in gardens, roadsides and vacant lots worldwide. In 2001, Scholler and Toike were first to report that common groundsel was a host for the rust fungus Puccinia lagenophorae Cooke in North America (Scholler and Toike 2001). This report from California was followed by reports of P. lagenophorae infections on common groundsel in New York, Oklahoma, and Oregon (Little-field et al. 2005). In 2007, Bruckart et al. published the first report of this host-pathogen combi-nation in Canada (Bruckart et al. 2007). To our knowledge, there are no published reports of P. lagenophorae on common groundsel in Pennsylvania (Farr and Rossman 2022). In May 2022, symptomatic common groundsel plants were observed in Biglerville, Adams Co., southern Penn-sylvania (N 39.9268047, E 77.2473878). Host plants exhibited conspicuous aecia on deformed stems (Fig. 1). Disease symptomology and morphology were consistent with P. langenophorae (Scholler and Toike 2001). P. lagenophorae is an autoecious rust that forms aecia and telia, but only aecia are typically formed on Senecio spp.; telia were not noted during our observations. Aecia were orange, cup-shaped, bordered by fragmented recurved peridia (Fig. 1), and they had mean diameters 262.9 ± 20.9 X 175.2 ± 22.2 µm (n = 20). Aeciospores were orange, oval, with mean diameters of 16.5 ± 0.97 X 11.5 ± 1.08 µm (n = 20). Fungal DNA was extracted from symptomatic stems. Polymerase chain reaction and sequencing of the 28S region of the nuclear ribosomal DNA repeat were conducted with primers Rust2inv and LR6 following protocols in Aime (2006). The sequence shared 100% identity (909 / 909 bp) with 8 sequences of P. la-genphorae in GenBank, including one on Ozothamnus cordatus from Perth, Western Australia, Australia (KF690699), vouchered in the Queensland Plant Pathology Herbarium (BRIP 57770), Brisbane, Queensland, Australia. A voucher specimen has been preserved in the Arthur Fungari-um at Purdue University (PUR N24039) with corresponding 28S sequence (GenBank accession OP718536).
RESUMO
Global forests are increasingly being threatened by altered climatic conditions and increased attacks by pests and pathogens. The complex ecological interactions among pathogens, microbial communities, tree hosts and the environment are important drivers of forest dynamics. Little is known about the ecology of forest pathology and related microbial communities in temperate forests of the southern hemisphere. In this study, we used next-generation sequencing to characterize sapwood-inhabiting fungal communities in North Patagonian Nothofagus forests and assessed patterns of diversity of taxa and ecological guilds across climatic, site and host variables (health condition and compartment) as a contribution to Nothofagus autecology. The diversity patterns inferred through the metabarcoding analysis were similar to those obtained through culture-dependent approaches. However, we detected additional heterogeneity and greater richness with culture-free methods. Host species was the strongest driver of fungal community structure and composition, while host health status was the weakest. The relative impacts of site, season, plant compartment and health status were different for each tree species; these differences can be interpreted as a matter of water availability. For Nothofagus dombeyi, which is distributed across a wide range of climatic conditions, site was the strongest driver of community composition. The microbiome of N. pumilio varied more with season and temperature, a relevant factor for forest conservation in the present climate change scenario. Both species carry a number of potential fungal pathogens in their sapwood, whether they exhibit symptoms or not. Our results provide insight into the diversity of fungi associated with the complex pathobiome of the dominant Nothofagus species in southern South America.
Los bosques del mundo están cada vez más amenazados por las condiciones climáticas alteradas y el aumento de los ataques de plagas y patógenos. Las complejas interacciones ecológicas entre los patógenos, las comunidades microbianas, los árboles hospedantes y el medio ambiente son impulsores importantes de la dinámica forestal. Poco se sabe sobre la ecología de la patología forestal y las comunidades microbianas relacionadas en los bosques templados del hemisferio sur. En este estudio, utilizamos la secuenciación Illumina para caracterizar las comunidades de hongos que habitan en la albura en los bosques de Nothofagus de la Patagonia Norte y evaluamos los patrones de diversidad de taxones y gremios ecológicos a través de variables climáticas, de sitio y de hospedante (identidad, condición de salud y compartimento) como una contribución a la autoecología de los Nothofagus. Los patrones de diversidad inferidos a través del análisis metabarcoding fueron similares a los obtenidos a través de enfoques dependientes de cultivo. Sin embargo, detectamos mayor heterogeneidad y mayor riqueza con métodos independientes de cultivo. La especie hospedante fue el modelador más fuerte de la estructura y composición de la comunidad fúngica, mientras que el estado de salud del hospedante fue el más débil. El impacto relativo del sitio, la estación, el compartimento y el estado de salud fueron diferentes para cada especie de árbol; estas diferencias pueden interpretarse en clave de disponibilidad de agua. Para N. dombeyi, que se distribuye a lo largo de una amplia gama de condiciones climáticas, el sitio fue el principal modelador de la composición de la comunidad. El micobioma de Nothofagus pumilio varió más con la estación y la temperatura, un factor relevante para la conservación de los bosques en el escenario actual de cambio climático. Ambas especies portan una serie de patógenos fúngicos potenciales en su albura, ya sea que muestren síntomas o no. Nuestros resultados brindan una idea de la diversidad de hongos asociados con el complejo patobioma de las especies dominantes de Nothofagus en el sur de América del Sur.
Assuntos
Micobioma , Micobioma/genética , Biodiversidade , Florestas , Árvores/microbiologia , América do Sul , Fungos/genética , Microbiologia do SoloRESUMO
Rosa multiflora Thunb. is a perennial shrub native to eastern Asia. It is commonly found on habitat margins, such as forest edges, streams, and roadsides (CABI n.d.). Due to its aromatic flowers, its usefulness in erosion control, and as a living livestock fence, R. multiflora was introduced to North America as an ornamental in the early 1800's (Hindal and Wong 1988). However, R. multifora, grows rapidly and frequently outcompetes native species, and is therefore considered invasive in North America (Hindal and Wong 1988). In May 2020 Phragmidium rosae-multiflorae Dietel, or rose rust, was collected from R. multiflora in Patton Woods Park, a small residential park in Patton Township, Centre Co., PA, USA (40° 47' 28.40" N; 77° 55' 33.37" W). P. rosae-multiflorae is an autoecious macrocyclic rust fungus known to occur on R. multiflora in the plant's native range. To our knowledge, there are no previously published records of P. rosae-multiflorae in North America. The host exhibited conspicuous aecia on the stems and petioles. Aecia were caeoma form, orange, irregular, erumpant, and pulverulent. Aeciospores were one-celled, verrucose, hyaline to pale yellow, variable in shape, ranging from ellipsoidal to globose (Fig.1), measuring 22.5 ± 3 × 15.5 ± 5 µm (n = 30). Disease symptomology and aecia are consistent with P. rosae-multiflorae Dietel (Wei 1988; Liu et. al 2020). Fungal DNA was extracted from infected petioles. Polymerase chain reaction and sequencing of the 28S region of the nuclear ribosomal DNA repeat was conducted with primers Rust2inv and LR6 following protocols in Aime (2006). The sequence shares 98.77% identity (900 / 487 bp) with P. Rosae-multiflorae from China (MN264739). A voucher specimen has been preserved in the Arthur Fungarium at Purdue University (PUR N23123) with corresponding 28S sequence (GenBank accession #MZ323415). The recorded occurrence of P. rosae-multiflorae on R. multiflora in North America is significant, given the ecological impact of the host plant as an invasive species and need for biocontrol. While no formally published records of this fungus in North America exist, there are putative occurrences across the northeastern United States reported on Global Biodiversity Information Facility (GBIF) and the Maryland Biodiversity Project websites.
RESUMO
Peru is the second largest producer of organic cocoa and one of the most important suppliers of fine aroma cocoa beans in the world (Sánchez et al. 2019). The fine aroma cocoa produced by smallholder farmers in the Bagua and Utcubamba Provinces, Amazonas Department, under the name of "Cacao Amazonas Peru", is protected by the Peruvian appellation rules (Díaz-Valderrama et al. 2020). Despite this importance, native diseases of the crop (Theobroma cacao) are poorly documented due to difficulty of access in this region. In November 2020 we conducted expeditions into Imaza District (4°47'09.4"S 78°16'51.6"W), a significant producer of fine aroma cocoa in terms of number of cultivated plots (4,651 out of 6,505 total in the Bagua Province) (INEI 2012). We visited 20 farms of < 2-ha in size; in 19 of these small farms, T. cacao trees were found infected with a white fungal thread blight and rhizomorphs covering branches and leaves. Disease incidence ranged from 90 to nearly 100%, and severity exceeded 80% on the eight farms with the most deficient phytosanitary management. Heavily infected leaves were hanging on branches by mycelial threads, harboring tiny (0.5 to 5.3 mm broad) white mushrooms. These symptoms and signs correspond to the thread blight disease constellation (TBD) of cacao caused by various species of Marasmius and Marasmiellus (Amoako-Attah et al. 2020). Mushrooms lacked a collarium, and their stipes were absent or rudimentary (< 2-mm long) and eccentric, consistent with Marasmius tenuissimus (Tan et al. 2009). Axenic cultures were obtained by surface sterilization of mycelium threads with 2% NaClO, rinsed three times in sterile water, plated on potato dextrose agar medium (PDA), and incubated for 7 days at 25°C. Hyphae was non-pigmented with clamp connections, consistent with the genus Marasmius. We extracted the DNA of isolate INDES-AFHP31 using the Wizard® Purification Kit (Promega Corp., Madison, Wisconsin) and sequenced the rDNA internal transcribed spacer 1 and 2 intervening the 5.8S subunit (ITS), and the 28S subunit (LSU) (Accession numbers: OM720123 and OM720135) according to Aime and Phillips-Mora (2005). The ITS and LSU sequences were 97.92 to 98.79% and 99.07 to 99.30% identical, respectively, with published sequences from M. tenuissimus from Ghana (Amoako-Attah et al. 2020). The pathogenicity test was conducted by inoculation of ten healthy cacao leaves with 7-day-old mycelium PDA discs of isolate INDES-AFHP31. An equal number of healthy cacao leaves were inoculated with PDA discs without mycelium as control. The observation of TBD symptoms and signs in the non-control set of cacao leaves starting at 3 days post inoculation, and the re-isolation of the same fungus from infected tissue confirmed its pathogenicity on cacao. Isolate INDES-AFHP31 was deposited as a dried culture into the herbarium Kuélap of the Universidad Nacional Toribio Rodríguez de Mendoza de Amazonas (voucher KUELAP-2251). Marasmius tenuissimus was originally reported from dead and living twigs and leaves of unidentified dicotyledonous trees from Indonesia, Brazil, and Bolivia (Singer 1976). However, it was first associated with TBD of cacao in Ghana in 2020, being the most frequently TBD-causing fungus isolated in the country (Amoako-Attah et al. 2020). Its discovery in 19 of the 20 surveyed cacao farms in Imaza District, Amazonas, Peru, reveals its importance as a cacao pathogen in the Western hemisphere.
RESUMO
Rumex crispus L. (curled dock) is a noxious weed in both grasslands (mainly pastures) and arable lands, but is also an early colonizer of many disturbed areas in lowland and upland regions. Rumex crispus is of agricultural significance because it competes with sown or native pasture and crops species and occupies areas that could be utilized by more palatable crop species. Rumex crispus can grow on almost all soil types but less often on peat and acidic soils. The range of altitude to which the species has become adapted varies from sea level to 3,500 m (Zaller 2004). This plant species has Eurasian origin and is widely distributed through temperate regions of North America as an introduced species. There is no previous rust report on R. crispus in Canada. On other Rumex species two Puccinia species viz. Puccinia acetosae (Schumach.) Körn., and P. ornata Arthur & Holw., have been previously reported from Canada (Farr & Rossman 2022). During the recent field survey from southern British Columbia, Langley, heavily rust infected leaves of R. crispus were observed. Uredinia and telia were present on both sides of the leaf mainly on the lower side. Uredinia early exposed, brown, and pulverulent. Urediniospores were obovoid, ellipsoid or oblong, measuring 20-28 × 17-23 µm. Urediniospore walls are yellowish brown to brown, 1.5-2 µm thick; covered in evenly distributed echinulae, spaced 2 to 3 µm apart, with smooth (non-echinulate) patches at the equator of the urediniospores. Urediniospores with 2- (mostly 3 and less often 2) germ pores, usually supraequatorial (at the upper part of the spore), or distributed irregularly (scattered), or 2 germ pores supraequatorial, one equatorial or all germ pores equatorial, germ pores covered with flat papilla. Telia similar to the uredinia, dark brown. Teliospores more or less globoid, ellipsoid, broadly ellipsoid, obovoid or oblong, 25--36 × 15-23 µm, brownish yellow to brown, smooth, 2-3 um thick, with apical or sup-apical germ pore, covered with a hemispherical, yellowish papilla, pedicels colorless, short. The above-mentioned characters fit Majewski's (1977) description for Uromyces rumicis (Schumach.) G. Winter. To confirm identity, the first 903 bp of the 5' end of the 28S rDNA of the above specimen was amplified following protocols of Aime (2006) and Aime et al. (2018) (GenBank accession no. ON166844). BLAST queries of the sequence shared 99.56% identity (900/903) with U. rumicis (GenBank accession no. KY764197). To our knowledge this is the first report of U. rumicis from Canada (Farr and Rossma 2022). There is only one previous published report of this rust species in North America made by French (1989) who reported U. rumicis on R. crispus from California. Uromyces rumicis is quite common on Rumex species including R. crispus in Eurasia and has also been reported on this host from Africa (Farr and Rossman 2022). It appears that the above rust fungus species may have been introduced to the North America by accompanying its host plant. A voucher specimen of infected R. crispus with U. rumicis was deposited at Arthur Fungarium (PUR) under the accession number PUR N24014. Uromyces rumicis is a heteromacrocyclic rust with aecial state on Ranunculaceae members especially Ranunculus ficaria L. This species is another introduced plant in North America. However, there is no report of the aecial state of this rust in North America to date. Existence of only two reports of U. rumicis in California and British Columbia, making it likely that U. rumicis became established in the West Coast of North America probably no earlier than the second half of the 20th century.
RESUMO
In Michigan, corn (Zea mays) is grown on 2.35 million acres with an annual production valued at $1.36 billion dollars (USDA-NASS). Southern rust is caused by the obligate biotrophic fungus Puccinia polysora Underw. and is often ranked in the top five most destructive corn diseases in the southern U.S. (Mueller et al. 2020). Yield losses due to southern rust in the northern U.S. have been considerable and estimated to be 231 million bushels from 2016 to 2019. In 2020 and 2021, corn leaf samples exhibiting signs typical of infection by P. polysora were collected from commercial production fields across Michigan. In 2020, samples were collected from two counties, Branch and Hillsdale. In 2021, samples were collected from 10 additional counties, Allegan, Barry, Calhoun, Eaton, Ingham, Kent, Montcalm, Shiawassee, Tuscola, and Van Buren. Uredinia of P. polysora were observed aggregated primarily on the upper leaf surface, light cinnamon brown to bright orange, ovular, and surrounded by yellow halos. Urediniospores were yellow to gold in the center, hyaline along the outer membrane, ellipsoid to obovoid, with short echinulations on the surface when viewed at 40x magnification under a light microscope. Urediniospores (n=180) measured 17 to 28 x 26 to 38 µm. No telia were observed. To confirm identification, the large subunit (28S) rDNA was amplified and sequenced with rust specific primers as described in Aime (2006) and Aime et al. (2018) on a sample collected from Shiawassee County in 2021. The resulting DNA sequence (GenBank Accession No. OL468037) shared 99.79% identity (932/934 bp) with P. polysora voucher BPI 863756 (GenBank Accession No. GU058024; Dixon et al. 2010). This report serves as the first documentation of southern rust in Michigan and an initial survey of its distribution throughout the state. Because of the ability of P. polysora spores to travel long distances via wind (Cammack 1959), it is likely that disease was present but not detected in additional counties not included in this report. Although widespread yield losses due to southern rust have not been documented in Michigan, there have been anecdotal reports of 30 bushels per acre losses in grain corn and 30% loss of tonnage from silage fields. Understanding the distribution of southern rust can help inform future disease management and corn breeding research. Furthermore, the distribution of southern rust is projected to move poleward by 15° by 2100 due to increasing global temperatures (Ramirez-Cabral et al. 2017), and the movement of southern rust into northern corn growing regions should be documented. Additional Michigan counties with confirmations of southern rust will continue to be reported via the corn IPMpipe https://corn.ipmpipe.org/.
RESUMO
A new genus and three new species of Agaricales are described from the Pakaraima Mountains of Guyana in the central Guiana Shield. All three of these new species fruit on the ground in association with species of the ectomycorrhizal (ECM) tree genus Dicymbe (Fabaceae subfam. Caesalpinioideae) and one species has been shown to form ectomycorrhizas. Multi-locus molecular phylogenetic analyses place Guyanagarika gen. nov. within the Catathelasma clade, a lineage in the suborder Tricholomatineae of the Agaricales. We formally recognize this 'Catathelasma clade' as an expanded family Catathelasmataceae that includes the genera Callistosporium, Catathelasma, Guyanagarika, Macrocybe, Pleurocollybia, and Pseudolaccaria. Within the Catathelasmataceae, Catathelasma and Guyanagarika represent independent origins of the ectomycorrhizal habit. Guyanagarika is the first documented case of an ECM Agaricales genus known only from the Neotropics.
Assuntos
Agaricales/classificação , Agaricales/isolamento & purificação , Fabaceae/microbiologia , Micorrizas/classificação , Micorrizas/isolamento & purificação , Guiana , Tipagem de Sequências Multilocus , FilogeniaRESUMO
Study of the genus Gomphidius from recent material from Asia and North America has been carried out using traditional taxonomy combined with molecular systematics. Two new species of Gomphidius (G. borealis and G. pseudoflavipes) are described, one from Eastern Siberia and a second from rarely collected habitats in the Western United States. One taxon has the longest spores reported for the genus and the second species appears to be associated with a Siberian larch.
RESUMO
Melanomphalia thermophila (Sing.) Sing. is a rarely collected agaric previously known only from Florida and Brazil. This taxon was originally described as a species of Tubaria and much of Singer's rationale for placing Tubaria within the Crepidotaceae (Imai) Sing. was based on anatomical similarities between T. thermophila and Crepidotus (Fr.) Staude. In later works, T. thermophila was transferred to Melanomphalia M.P. Christ., again forming the basis upon which Singer placed Melanomphalia within the Crepidotaceae. Based on examination of newly collected specimens from Puerto Rico and Panama, type studies, and nuclear large subunit rDNA analysis, we conclude that this taxon is, in fact, a centrally stipitate Crepidotus. Melanomphalia thermophila is transferred to Crepidotus, fully described and illustrated.
