Predicting the risk of cucurbit downy mildew in the eastern United States using an integrated aerobiological model.

Cucurbit downy mildew caused by the obligate oomycete, Pseudoperonospora cubensis, is considered one of the most economically important diseases of cucurbits worldwide. In the continental United States, the pathogen overwinters in southern Florida and along the coast of the Gulf of Mexico. Outbreaks of the disease in northern states occur annually via long-distance aerial transport of sporangia from infected source fields. An integrated aerobiological modeling system has been developed to predict the risk of disease occurrence and to facilitate timely use of fungicides for disease management. The forecasting system, which combines information on known inoculum sources, long-distance atmospheric spore transport and spore deposition modules, was tested to determine its accuracy in predicting risk of disease outbreak. Rainwater samples at disease monitoring sites in Alabama, Georgia, Louisiana, New York, North Carolina, Ohio, Pennsylvania and South Carolina were collected weekly from planting to the first appearance of symptoms at the field sites during the 2013, 2014, and 2015 growing seasons. A conventional PCR assay with primers specific to P. cubensis was used to detect the presence of sporangia in rain water samples. Disease forecasts were monitored and recorded for each site after each rain event until initial disease symptoms appeared. The pathogen was detected in 38 of the 187 rainwater samples collected during the study period. The forecasting system correctly predicted the risk of disease outbreak based on the presence of sporangia or appearance of initial disease symptoms with an overall accuracy rate of 66 and 75%, respectively. In addition, the probability that the forecasting system correctly classified the presence or absence of disease was ≥ 73%. The true skill statistic calculated based on the appearance of disease symptoms in cucurbit field plantings ranged from 0.42 to 0.58, indicating that the disease forecasting system had an acceptable to good performance in predicting the risk of cucurbit downy mildew outbreak in the eastern United States.

Sensitivity and Efficacy of Boscalid, Fluazinam, and Thiophanate-Methyl for White Mold Control in Snap Bean in New York.

White mold (Sclerotinia sclerotiorum) of leguminous crops in New York is generally managed with preventive applications of fungicides. However, no research has been conducted during the last decade to assess the sensitivity of the S. sclerotiorum population to fungicides or compare their performance under field conditions. The sensitivity of S. sclerotiorum to boscalid, fluazinam, and thiophanate-methyl was assessed in 151 isolates from 15 fields across New York using an agar dilution method with discriminatory concentrations. In addition, the effective concentration at which mycelial growth is reduced by 50% (EC50) was estimated for one representative isolate from each field. The efficacy of commercial formulations of each fungicide on white mold incidence in plants and pods was also tested in two field trials (2015 and 2016). The EC50 values ranged from 0.068 to 0.219, 0.001 to 0.002, and 1.23 to 2.15 µg/ml for boscalid, fluazinam, and thiophanate-methyl, respectively. Evidence of resistance was not found using the discriminatory concentration tests. The mycelial growth inhibition relative to the control ranged from 56 to 83%, 66 to 84%, and 53 to 83% at discriminatory concentrations of boscalid (5 µg a.i./ml), fluazinam (0.05 µg a.i./ml), and thiophanate-methyl (5 µg a.i./ml), respectively. Fourteen isolates with mycelial growth inhibition lower than 60% at 5 µg/ml of thiophanate-methyl, did not exhibit point mutations within a partial sequence of the ß-tubulin gene. In the field trials, fungicides effectively reduced white mold incidence on plants by 75% (2015) and 93% (2016) and on pods by 81% (2015) and 87% (2016), both relative to the nontreated plots. However, fungicide applications led to significant increases in pod yield, relative to the nontreated plots, only in 2015 when the incidence of white mold on plants and pods were higher (85 and 49.2%) than in 2016 (31.3 and 10.3%). Although fungicide resistance was not detected, and thus control failures reported by New York snap bean growers may be due to other factors, further monitoring of sensitivity within the S. sclerotiorum population is encouraged as well as the use of rational systems to base their judicious and economic use.

Five Reasons to Consider Phytophthora infestans a Reemerging Pathogen.

Phytophthora infestans has been a named pathogen for well over 150 years and yet it continues to "emerge", with thousands of articles published each year on it and the late blight disease that it causes. This review explores five attributes of this oomycete pathogen that maintain this constant attention. First, the historical tragedy associated with this disease (Irish potato famine) causes many people to be fascinated with the pathogen. Current technology now enables investigators to answer some questions of historical significance. Second, the devastation caused by the pathogen continues to appear in surprising new locations or with surprising new intensity. Third, populations of P. infestans worldwide are in flux, with changes that have major implications to disease management. Fourth, the genomics revolution has enabled investigators to make tremendous progress in terms of understanding the molecular biology (especially the pathogenicity) of P. infestans. Fifth, there remain many compelling unanswered questions.

The 2009 Late Blight Pandemic in the Eastern United States - Causes and Results.

The tomato late blight pandemic of 2009 made late blight into a household term in much of the eastern United States. Many home gardeners and many organic producers lost most if not all of their tomato crop, and their experiences were reported in the mainstream press. Some CSAs (Community Supported Agriculture) could not provide tomatoes to their members. In response, many questions emerged: How did it happen? What was unusual about this event compared to previous late blight epidemics? What is the current situation in 2012 and what can be done? It's easiest to answer these questions, and to understand the recent epidemics of late blight, if one knows a bit of the history of the disease and the biology of the causal agent, Phytophthora infestans.

Extension plant pathology: strengthening resources to continue serving the public interest.

Extension plant pathologists deliver science-based information that protects the economic value of agricultural and horticultural crops in the United States by educating growers and the general public about plant diseases. Extension plant pathologists diagnose plant diseases and disorders, provide advice, and conduct applied research on local and regional plant disease problems. During the last century, extension plant pathology programs have adjusted to demographic shifts in the U.S. population and to changes in program funding. Extension programs are now more collaborative and more specialized in response to a highly educated clientele. Changes in federal and state budgets and policies have also reduced funding and shifted the source of funding of extension plant pathologists from formula funds towards specialized competitive grants. These competitive grants often favor national over local and regional plant disease issues and typically require a long lead time to secure funding. These changes coupled with a reduction in personnel pose a threat to extension plant pathology programs. Increasing demand for high-quality, unbiased information and the continued reduction in local, state, and federal funds is unsustainable and, if not abated, will lead to a delay in response to emerging diseases, reduce crop yields, increase economic losses, and place U.S. agriculture at a global competitive disadvantage. In this letter, we outline four recommendations to strengthen the role and resources of extension plant pathologists as they guide our nation's food, feed, fuel, fiber, and ornamental producers into an era of increasing technological complexity and global competitiveness.

First Report of Leaf Curl on Celery Caused by Colletotrichum acutatum in the United States.

In June 2010 and July 2011, celery (Apium graveolens) samples cv. Tango were submitted to the Penn State Plant Disease Clinic from Franklin and Dauphin Counties, PA, respectively. Plants exhibited curling and twisting of leaves and petioles and dark, brownish-black necrotic lesions at the base of the plant, extending up the petioles. A fungal organism with morphology consistent to Colletotrichum acutatum J.H. Simmonds was isolated from plant lesion tissue excised from the Dauphin Co. sample. Grown on half strength potato dextrose agar (PDA), the colony had gray aerial mycelium and a pink reverse. Conidia were 5.1 to 14.5 × 2.6 to 5.1 µm, aseptate, hyaline, elliptical, with one or both ends slightly pointed, and formed from the mycelium or in dense orange masses of acervuli on the aerial surface of the culture. Setae were not present. To test pathogenicity, five 23-week-old plants of the cv. Sonora and five 11-week-old plants each of the cvs. Tango and Tall Utah were sprayed until runoff with a conidial suspension (1.3 × 106 conidia/ml and 1.4 × 106 conidia/ml, respectively) and 0.025% Tween. One plant of each cv. was sprayed with milliQ water and 0.025% Tween as a control. Plastic bags were sprayed with the conidial suspension (milliQ water for the control), and secured over the individual plants for 24 h to create a humidity chamber. Plants were incubated in a growth chamber with a 16-h photoperiod, 25°C day/18°C night temperatures, and 70% humidity. Post-inoculation, all of the cv. Tango plants exhibited leaf cupping and curling after 7 days and most plants had dark stem lesions after 3 weeks, consistent with celery leaf curl symptoms. Plants of cvs. Tall Utah and Sonora developed malformed leaves and leaf curl symptoms 16 days and 10 days post-inoculation, respectively. None of the control plants developed symptoms. Infected tissue was excised from diseased plants, surface disinfested in 0.5% sodium hypochlorite for 45 s and plated on half strength PDA. Fungal colonies consistent with C. acutatum were recovered from all inoculated celery tissues (except two of the five inoculated cv. Tall Utah plants and the negative controls). To verify morphological identification, the internal transcribed spacer (ITS) rDNA region was amplified and sequenced for our original isolate and those recovered from the inoculated plants using ITS1 and ITS4 primers (2) (GenBank Accession No. JQ794875). Sequence homology revealed 99 to 100% similarity to accessioned isolates of C. acutatum, which included the holotype and a paratype of C. acutatum (Accession Nos. AF411700 and AF411701, respectively). Celery leaf curl has been reported to have caused devastating crop losses on celery in Australia (1, 3) and to our knowledge, C. acutatum causing leaf curl of celery has not been officially reported in the United States. Infected celery plants are unmarketable because of the leaf malformation and eventual plant necrosis caused by C. acutatum. As such, this disease could have serious negative implications for celery growers in the United States. References: (1) J. B. Heaton and S. R. Dullahide. Australas. Plant Pathol. 22:152, 1993. (2) T. J. White et al. Page 315 in: PCR Protocols: A Guide to Methods and Applications. Academic Press, San Diego, CA, 1990. (3) D. G Wright and J. B. Heaton. Australas. Plant Pathol. 20:155, 1991.

An IPM Program for Managing Fungal Leaf Blight Diseases of Carrot in New York.

Fungal leaf blight diseases caused by Cercospora carotae and Alternaria dauci occur annually on processing carrot in New York, with growers applying up to eight fungicide sprays to manage these diseases. An integrated pest management (IPM) program involving the use of a 25% disease incidence threshold to prompt the first fungicide application and timing subsequent sprays by monitoring for increases in disease severity and weather forecasts in conjunction with a 10- to 14-day spray interval was evaluated in grower fields in 1997 and 1998. The IPM plots, compared with the grower plots, required two to six fewer fungicide applications but showed no yield reduction. From 1999 to 2004, the IPM program was validated and the effect of crop rotation and carrot cultivar susceptibility also were assessed. Carrot plants growing in fields with 2-year or longer crop rotation intervals reached the 25% disease incidence threshold later in the season and required fewer fungicide applications. The less-susceptible carrot cultivars also reached the 25% disease incidence threshold later, required fewer fungicide applications, and were less severely diseased than more susceptible cultivars. Validation of the IPM program in New York showed that both fungal leaf blights can be managed effectively using a 25% incidence threshold to prompt the first fungicide spray and making the subsequent fungicide applications based on increases in disease severity, weather forecasts, and a 10- to 14-day spray interval.

Damage and Management of Meloidogyne hapla Using Oxamyl on Carrot in New York.

The northern root-knot nematode (Meloidogyne hapla) is a major pathogen of processing carrot in New York, significantly reducing marketable yield and profitability. Severely infected carrots are stubby, galled and forked and therefore unmarketable. In field microplot trials in 1996 and 1998, the incidence and severity of root-galling increased and the marketable yield of carrot decreased as the initial inoculum density of M. hapla was increased from 0 to 8 eggs/cm(3) soil, in mineral or organic soils. The application of oxamyl at planting was effective against M. hapla and its damage to carrots grown in mineral and organic soils. Oxamyl application reduced root-galling severity and increased marketable yield. In commercial fields, the cost-effectiveness of oxamyl application was related to the level of soil infestation with M. hapla.