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.

Effect of Application Method and Rate on Residual Efficacy of Mefenoxam and Phosphorous Acid Fungicides in the Control of Pink Rot of Potato

Experiments were conducted to examine the effectiveness of rate and method of phosphorous acid application for controlling pink rot of potato (Solanum tuberosum) caused by Phytophthora erythroseptica. Replicated small-plot and replicated split commercial field trials were established in commercial production fields in Minnesota from 2006 to 2009. Fungicides were applied in-furrow at planting, or as one, two, or three foliar applications via ground sprayer, irrigation system (chemigation), or fixed-wing aircraft. Phosphorous acid efficacy was compared to mefenoxam, the fungicide commonly utilized to manage pink rot, either by determining natural infections in the field or by inoculating eyes of harvested tubers using a mefenoxam-sensitive and -resistant isolate of P. erythroseptica via postharvest challenge inoculation. In replicated small plot trials, both in-furrow and two foliar applications of mefenoxam controlled tuber rot in the field, and significantly controlled tuber rot in storage. Phosphorous acid also reduced tuber rot in the field when applied two or three times to the foliage. Although phosphorous acid was ineffective when applied in-furrow, one, two, and three foliar applications and a postharvest application of phosphorous acid controlled mefenoxam-sensitive and -resistant isolates of P. erythroseptica during storage for 187 days, while mefenoxam failed to control the resistant isolate. In replicated split commercial field trials, two aerial applications of phosphorous acid were as effective as three applications in reducing pink rot incidence in tubers inoculated postharvest. Three aerial applications were as effective as three chemigation applications in replicated split commercial field trials in 2008, but provided significantly greater protection than chemigation in 2009.

Competitive Parasitic Fitness of Mefenoxam-Sensitive and -Resistant Isolates of Phytophthora erythroseptica under Fungicide Selection Pressure

A 2-year field and laboratory experiment was initiated to study the competitive parasitic fitness of mefenoxam-resistant (50% effective concentration [EC50] > 100 μg ml–1) and mefenoxam-sensitive (EC50 = 0.07 μg ml–1) isolates of Phytophthora erythroseptica with equal aggressiveness. The competitive ability of the mefenoxam-resistant and -sensitive isolates was tested under no selection pressure (nonfungicide treated) as well as under the influence of mefenoxam and non-mefenoxam (phosphorous acid) fungicides. P. erythroseptica isolates were combined in four ratios of mefenoxam-resistant (R) to mefenoxam-susceptible (S) (0R:0S, 1R:1S, 3R:1S, and 1R:3S) and subsequently infested into the soil at the time of planting. In-furrow mefenoxam applications were applied to the soil immediately following infestation with P. erythroseptica. Phosphorous acid was applied at tuber initiation and 14 days after tuber initiation. Noninfested, nonfungicide-treated plots served as controls. P. erythroseptica isolates recovered from field-infected pink rot tubers at harvest and 3 to 4 weeks after harvest were tested for mefenoxam sensitivity in vitro. In vivo studies were performed by challenge inoculating a zoospore suspension in the four ratios described above onto potato tubers harvested from nontreated, phosphorous acid-treated, or mefenoxam-treated field plots. These field plots were not infested with P. erythroseptica at planting. Results from both field and in vivo studies demonstrate that mefenoxam-resistant isolates of P. erythroseptica are as fit as sensitive isolates in the absence of selection pressure or in the presence of a phosphorous acid fungicide treatment. Under mefenoxam selection pressure, mefenoxam-resistant P. erythroseptica isolates were more parasitically fit than -sensitive isolates. These studies suggest the lack of an apparent fitness penalty in mefenoxam-resistant P. erythroseptica populations under field conditions and that these isolates could be stable in most agroecological systems. Based on these results, mefenoxam-based fungicides are no longer recommended for the management of pink rot once mefenoxam-resistant P. erythroseptica populations are detected in a specific field.