The impact of fusarium ear rot in Poland and methods to reduce losses caused by the disease

Maize has a significant economic impact all over the world. Fungi in the genus Fusarium that cause fusarium ear rot of maize have significant effect on the yeld quality and quantity. The main threat is the contamination of grain with the mycotoxins they produce - as these are harmful to humans and animals. Such mycotoxins are a group of secondary metabolites of varied structure, which belong mainly to trichothecenes, fumonisins and zearalenones. As no efficient chemical control read and pink rot in the field is possible, prevention relies on cultural practices and use resistant hybrids. Insects play an important role in the infection, which is why it is recommended to control their prevalence during growing season.

First report of rubbery rot of potato caused by Geotrichum candidum in the United States

Rubbery rot of potato caused by Geotrichum candidum Link is characterized by symptoms of damp, flaccid tubers that feel rubbery when squeezed (Humpreys-Jones 1969), similar in consistency to potato diseases such as pink rot (caused by Phytophthora erythroseptica) and Pythium leak (caused by species of Pythium). In November 2019, several symptomatic tubers of potato variety ‘Ciklamen’ that had been held in storage since harvest and originated from an over-head irrigated, sandy-loam production field in Bingham county, Idaho were submitted to the University of Idaho for diagnosis. Shipping-point inspection records indicated 4-9% of tubers were affected. External symptoms included irregularly shaped, randomly located sunken black-colored lesions on more severely affected rubbery-textured tubers. When cut, internal affected tissue developed a greyish appearance after several minutes. Lens-shaped cavities were apparent in two of the tubers, indicating an advanced infection. A sour-milk smell accompanied the sample. To isolate the pathogen, pieces of tuber tissue approximately 5 mm in diameter were collected from the margins of symptomatic areas and surface-sanitized in sodium hypochlorite (2%) for two minutes, rinsed twice in sterile water and plated onto tap water agar amended with penicillin G (0.2 g/liter) and streptomycin sulfate (0.8 g/liter). After three days at 21°C, colonies having distinct creamy white mycelia, a sweet, juniper-like odor, and hyaline hyphae were consistently associated with diseased tissue. Cylindrical to oval-shaped arthroconidia ranged in size from 6.6-11.0 × 3.2-5.9 μm (mean = 8.4 × 4.7, n=21), within dimensions as reported by Carmichael (1957). No other pathogens including species of Pythium and Phytophthora were recovered from the sample. Pure cultures were obtained by transferring hyphal tips to potato dextrose agar plates. Species identity was confirmed via rDNA ITS sequencing using primers ITS5/4 (White et al., 1990). DNA extraction and PCR conditions were as previously described (Woodhall et al., 2013). Resulting sequences (NCBI accession numbers MT893312 and MT893315) shared 99.4% identity with G. candidum Accession KY103453.1 on GenBank. To confirm pathogenicity, ten tubers (cv. Ciklamen) were inoculated by placing a 10mm2 plug of fully colonized PDA of G. candidum on the tuber surface, and ten tubers were mock inoculated with sterile PDA plugs. After 27 days at 21C in a dew chamber, tubers were examined for symptoms. Eight of the 10 inoculated tubers exhibited a rubbery texture and fluid leaking from tubers when cut, with two tubers also exhibiting a grey internal discoloration and the distinctive smell. Control tubers did not exhibit any symptoms. Isolations were attempted from four symptomatic tubers and G. candidum was successfully recovered from three tubers. The disease has been reported sporadically in the United Kingdom (Humphreys-Jones 1969) and Korea (Kim et al., 2011) and the pathogen occurs worldwide (Carmichael 1957). Though the fungus causes a tomato rot in the United States (US) (Pritchard and Porte, 1923; Bourret et al., 2013), and potatoes with rubbery rot originating from Australia were intercepted at a US port (Farr et al., 2020), the disease has not to our knowledge been documented on potato grown in the US. Because symptoms may be confused with pink rot and Pythium leak, it is critical for producers to obtain a correct diagnosis to facilitate appropriate management strategies.

Розовая гниль картофеля опасное заболевание для южных регионов России

Описано такое заболевание картофеля как розовая гниль картофеля, вызываемое оомицетом Phytophthora erythroseptica. Показаны симптомы заболевания и присутствие возбудителей этого патогена в России и мире. Рекомендовано в случае появления Phytophthora erythroseptica на полях и в картофелехранилищах проведение комплекса мероприятий в рамках интегрированной системы защиты от этого заболевания.Described this disease of the potato pink rot of potatoes caused by Phytophthora erythroseptica oomycetes. The symptoms of the disease and the presence of pathogens of this pathogen in Russia and the world are shown. In case of emerging of Phytophthora erythroseptica in fields and potato storages, the Integrated Disease Management against this pest needs implementing.

Evaluation of the Risk of Development of Fluopicolide Resistance in Phytophthora erythroseptica

Fluopicolide has shown effective pink rot (Phytophthora erythroseptica) control in potato disease management. To efficiently utilize this chemical, the risk of fluopicolide resistance in P. erythroseptica needs to be assessed. In this study, 34 isolates of P. erythroseptica were obtained from symptomatic potato tubers with pink rot in Maine. The sensitivity of these wild-type isolates to fluopicolide was assessed by culturing them on agar medium amended with fluopicolide at various concentrations. The 50% effective concentration (EC50) of fluopicolide for the inhibition of mycelial growth was determined and used to establish a baseline sensitivity of these P. erythroseptica isolates to fluopicolide. The wild-type isolates were sensitive to fluopicolide, with EC50 values ranging from 0.08 to 0.35 μg/ml. By exposing P. erythroseptica zoospores to agar medium containing 100 μg/ml fluopicolide, 6 out of the 34 wild-type isolates produced fluopicolide-resistant mutants. The mutants were transferred to fungicide-free V8 medium consecutively for 10 times, and the 10th transfer of mutants was examined for resistance stability and biological fitness. In general, the mutants had similar or slower growth rates compared with their wild-type parents, and the virulence of some mutants was significantly reduced. The results indicated a low to moderate risk of P. erythroseptica developing resistance to fluopicolide, and suggested a trade-off between fluopicolide resistance and biological fitness in P. erythroseptica.