September/October 2019 Non-Botrytis Fruit Rots of Strawberry: Under-Estimated and Under-Researched? Assessing the Impact of Irrigation Water Quality on Strawberry Cultivars California's Prune Orchard of the Future Colletotrichum Dieback in California Citrus Evaluating Biostimulant and Nutrient Inputs to Improve Tomato Yields and Crop Health
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Volume 4 : Issue 5 Photo courtesy of Luke Milliron.
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IN THIS ISSUE
4 10 18 26 32 38 44
Non-Botrytis Fruit Rots of Strawberry: Under-Estimated and Under-Researched?
CONTRIBUTING WRITERS & INDUSTRY SUPPORT Andre Biscaro Ed Lewis Irrigation and Water Resources Advisor, UCCE, Ventura County
Grape Trunk Diseases and Management
Assessing the Impact of Irrigation Water Quality on Strawberry Cultivars
Mark Bolda
4
Michael Cahn Irrigation and Water Resources Advisor, UCCE, Monterey County
California’s Prune Orchard of the Future
Joey S. Mayorquin
Entomology and Biologicals Advisor, UCCE
Themis Michailides
Greg W. Douhan
Professor and Plant Pathologist, UC Davis
Department of Plant Pathology, UC Davis
Katherine Jarvis-Shean UCCE Orchards Systems Advisor for Sacramento, Solano and Yolo Counties
Luke Milliron UCCE Farm Advisor for Butte, Glenn and Tehama Counties
Franz Niederholzer UCCE Farm Advisor for Colusa, Sutter and Yuba Counties
Gabriel Torres UCCE Farm Advisor, Tulare County
Steven Koike Director, TriCal Diagnostics
UC COOPERATIVE EXTENSION ADVISORY BOARD
Mechanistic Insight into the Salt Tolerance of Almonds
Kevin Day
Emily J. Symmes
County Director and UCCE IPM Advisor, UCCE Pomology Farm Sacramento Valley Advisor, Tulare/Kings County
Steven T. Koike,
50
UCCE Orchards Systems Advisor for Glenn, Butte and Tehama Counties
Surendra K. Dara
Akif Eskalen
18
Dani Lightle
Department of Microbiology and Plant Pathology, UC Riverside
UCCE Area Citrus Advisor for Tulare, Fresno and Madera Counties
Colletotrichum Dieback in California Citrus
Evaluating Biostimulant and Nutrient Inputs to Improve Tomato Yields and Crop Health
Farm Advisor and County Director, UCCE
Former Associate Dean, College of Agricultural and Environmental Sciences, University of California, Davis
Kris Tollerup
Director, TriCal Diagnostics
The Crop Consultant Conference Full Menu of Workshops and Seminars
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UCCE Integrated Pest Management Advisor, Parlier, CA
The articles, research, industry updates, company profiles, and advertisements in this publication are the professional opinions of writers and advertisers. Progressive Crop Consultant does not assume any responsibility for the opinions given in the publication.
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Non-Botrytis Fruit Rots of Strawberry: Under-estimated and Under-Researched?
BY MARK BOLDA | Farm Advisor and County Director, UCCE AND STEVEN KOIKE | Director, TriCal Diagnostics
G
rowers face a multitude of obstacles when trying to produce large volumes of high-quality strawberry fruit for a market that runs for many months. Up-front, pre-plant ground preparation and transplant costs are significant financial commitments that are expensed before even a single strawberry plant is put in the ground. Untimely rains and insect infestations can result in loss of fruit quality and numbers. A series of soilborne pathogens can later cause plant collapse and loss of profit. Of course, the intractable labor shortage dilemma may even result in perfectly marketable fruit not reaching the consumer. When it comes to diseases of the strawberry fruit, the number one concern is gray mold (also called Botrytis fruit rot), which justifiably attracts the rapt attention of field professionals and captures the interest of researchers. However, in coastal California another fungal issue can also take its toll on strawberry yields and quality and in many ways is overlooked and underestimated by the industry. Rhizopus fruit rot and Mucor fruit rot are collectively known as “leak” disease; this disease concern also deserves to be recognized and studied. Symptoms, Signs, Diagnosis In the field, leak symptoms and signs only develop on mature or near-mature
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September /October 2019
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Photo 1. Two pathogens, Rhizopus and Mucor, can turn strawberry fruit into black lumps.
fruit and are very distinctive. Infected red fruit first take on a darkened, water-soaked appearance; in short order the fruit will begin to wrinkle and collapse. Almost overnight the rapidly growing Rhizopus or Mucor pathogen will be visible as white fungal growth peppered and interspersed with tiny black spheres. Fungal growth will be extensive and can entirely envelop the fruit, turning it into a white and black lump (Photo 1). Rhizopus and Mucor produce pectolytic (endopolygalacturonase) and cellulase enzymes as they colonize the strawberry, disintegrating the fruit tissues and causing red juices (Photo 2, see page 6) to ooze and flow onto the plastic that covers the bed. It is because of these messy red juice flows that the designation “leak” is used for this disease.
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This ugly scene in the field, however, is only part of the problem that these fungi cause. During harvest infected but symptomless fruit, as well as healthy fruit exposed to spores of the two pathogens, will be packed into containers. The pathogens can continue to grow during postharvest handling, storage, and market display of fruit, causing postharvest fruit losses, shortening of shelf life of the product, and creating a mess in crates and clamshells (Photo 3, see page 6). In fact, if fruit are not properly refrigerated, the fungus on a single infected fruit can rapidly spread throughout an entire container, resulting in what is known as “nesting” or
Continued on Page 6
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Mycelial Growth
Spore Producing Bodies
Overall Colony Color
Fungus ID
Table. Description of various fungi found on post-harvest strawberry.
Continued from Page 5 clumping of oozing, rotted fruit. Harvested strawberry fruit are subject to a number of rotting molds; the leak fungi are generally identifiable due to the color and nature of the fungal growth (see Table). The Pathogens Much is already known about the two fungi causing strawberry leak disease. Rhizopus and Mucor are both in the group of fungi
called Zygomycetes. Both fungi are commonly found in agricultural environments and cause similar ripe fruit rots on crops such as apricot, cherry, peach, pear, and tomato. While closely related to each other and difficult to differentiate in the field, the two pathogens differ slightly. On California strawberry, Rhizopus tends to be the more commonly encountered pathogen. Rhizopus grows very rapidly and haphazardly in orientation, creating a web-like mess of mycelium (Photo 4, see page 7). Rhizopus forms a brown orange, root-like structure (called rhizoids) that allows it to quickly spread between adjacent fruit (Photo 5, see page 7). The black, spherical spore bearing structures produce
Photo 2. The leak pathogens produce enzymes that cause strawberry fruit to ooze juice. 6
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September /October 2019
huge numbers of dry spores that are readily spread by winds (Photo 6, see page 8). Mucor grows more slowly with an upright, erect mycelial habit (Photo 7, see page 8) and also produces spores on a black spherical structure (Photo 8, see page 8). However, Mucor spores collect in a wet droplet surrounding the head; such spores are therefore less prone to dispersal by winds. Both fungi survive and increase in the field by colonizing dead organic matter and debris; Rhizopus and Mucor also readily colonize discarded and overripe strawberry fruit left on the plant or thrown into the furrow. These fungi produce a resilient structure (zygospore) that resists drying and weathering
Photo 3. Enzymes released by Rhizopus and Mucor can cause significant fruit breakdown during storage and transport.
Photo 4. Rhizopus growth is rapid and results in a messy, weblike mycelial growth.
and provides another means of survival. Both Rhizopus and Mucor can be readily isolated from soil, thereby demonstrating that these fungi can persist in fields even if strawberry is not present. Once strawberry fruit begin to develop and ripen, spores come in contact with the fruit and usually gain entry via wounds and injuries. Strawberry leak pathogens tend to be more active if temperatures are relatively warmer, generally 65° F or higher. This temperature factor may be one reason that leak disease is more damaging in coastal California in late summer through early fall. The pectolytic enzyme that causes fresh market fruit to melt into juices can also be a concern in some processed fruit products. The enzyme is heat-stable and withstands canning temperatures; for example, apricot halves and brined cherries that are contaminated with Rhizopus and then canned may end up being apricot or cherry mush because of the continued activity of the stable enzyme even though the original fungus is cooked and dead. Management Options and Research Needs Growers already know to refrigerate strawberries as soon as possible after field packing the fruit. Refrigeration is a primary management tool for reducing losses due to leak disease. While refrigeration generally limits the development of Rhizopus, it is notable that some species of Mucor can grow quite well at storage temperatures of 32° F (0°
Continued on Page 8
Photo 5. Brown-orange root-like structures allow Rhizopus to rapidly spread between adjacent fruit.
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Continued from Page 7 C). Therefore, one research need is the precise identification of Rhizopus and Mucor species present in strawberry fields. Different species will have different temperature optima regarding growth and ability to infect fruit in the field, and the different species may respond differently to postharvest conditions. Photo 6. The black, spherical spore-producing head of Rhizopus releases thousands of wind-borne spores.
Photo 7. On strawberry fruit, the Mucor pathogen grows with an upright, erect mycelial habit.
Sanitation, both in field and during harvest, is another means of limiting leak development. Reducing the amount of over-ripe and rotted fruit in the field may help limit the Rhizopus and Mucor inoculum present in the planting; the influence of field sanitation on inoculum is another area of needed research. Field sanitation may be an increasingly difficult goal to attain given labor shortages and costs. Sanitation during the harvest process mainly involves the training and education of harvesters. Harvesters who touch and handle leak fruit will easily transmit the fungus to healthy fruit that are packed. Therefore, pickers should be reminded not to touch leak fruit and to be sure not to pack fruit showing any hint of leak infection. Fungicides can effectively limit Rhizopus development for some crops. However, such information is lacking for strawberry. Research is needed to determine the efficacy and feasibility of using fungicides for leak management in strawberry. Other interactions involving fungicides should also be investigated. There are indications that fungicides used to manage Botrytis could exacerbate growth by Rhizopus and Mucor. Among the many challenging factors facing strawberry growers, leak disease is not the number one concern. However, during certain times of the year in coastal California, leak disease can affect a significant amount of the harvest. A better understanding of strawberry leak disease, achieved through collaborative research, may help this industry manage this problem and improve on an already excellent commodity.
Photo 8. Mucor also produces a black, spherical head, though the spores are captured in a droplet and are not readily spread by wind. 8
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September /October 2019
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All photos courtesy of Gabriel Torres.
Grape Trunk Diseases and Management
BY GABRIEL TORRES | UCCE Farm Advisor, Tulare County "
T
runk disease” is a catch-all term that includes several different fungal diseases of grapevines trunks worldwide. The term was coined in the late 1990s by Dr Luigi Chiarappa¹, and can include foliar and vascular symptoms caused by Petri disease, Black foot, Eutypa, Botryosphaeria dieback, Phomopsis dieback and Esca. Most of the fungi (more than 50 species) causing trunk disease are
related, belonging to the order Botryosphareales, but fungi that belongs to the families that forms mushrooms can be also recovered from the cankers. In most of the cases, the cankers interfere with the movement of water from the roots to the leaves, shots and clusters. Petri disease and Esca are caused by the closely related species of fungi in the genus Phaeomoniella and Paheoacremoni-
um. In both diseases, longitudinal black stripes are visible under the bark. Different from Petri disease which occurs in vines younger than three years, Esca is observed in more mature plants. The foliar symptom can include the wellknown “Tiger Stripe” pattern (Photo 1). This symptom is visible normally by the end of June, when high temperatures stress the vines. Reddish-brown patches on the leaves are observed in Continued on Page 12
Appearance
Leaf Symptoms
Petri disease
Poor growth <3 years
Chloro�c leaves
Dieback
Dark longitudinal streaks on trunk (longitudinal cut)
Black foot
Black lesions on roots < 3 years
Scorched leaves
Dieback
Brown-reddish discolora�on
Eutypa
5 – 8 year
Stunted shoots chloro�c leaves
Cordon dieback
Pie Shape lesion
Botryosphaeria dieback
3-5 years
No foliar Symptoms (diff. with Eutypa)
Dieback
Pie shape with pycnidia on dead �ssue
Phomopsis dieback
Lack of budbreak of infected spurs
Brown leaf spots with yellow halos
Black elongated lesions
Canker
Leaf strip, fruit black measles 3-5 years
Tiger strip, sudden wil�ng
Shot �p dieback
Disease
Esca
Table 1. Summary of Trunk diseases.
10
Photo 1. Esca tiger strip symptom on Autumn King.
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September /October 2019
Shoot Symptom
Trunk Symptom
Brown and black longitudinal streaks. Irregular canker in cross sec�on
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Continued from Page 10 red cultivars, while yellow patches are more common on white grapes. Esca is also known as “black measles” because the dark spots that develop on berries (Photo 2). Measles is particularly damaging to table grapes because berry appearance is paramount. Black foot is caused by two species of the fungal genus Cylindrocarpon, and it most commonly observed on young vines (three-year-old vines or younger). Stunted vines and scorched leaves (Photo 3, see page 13) are a typical sign of black foot. Affected roots present black lesions and look like they are dead. The disease was reported by late 1990’s in California and has been frequently found in fields with poor planting practices, especially those that were J-rooted at planting. The disease if not prevented, can require costly replanting. Photo 2. Measles s.
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Botryosphaeria is caused by more than 20 species of fungi. However, fungi in
September /October 2019
the species Lasiodiplodia and Neofusicocum are the most damaging. Spurs from infected vines won’t develop new shoots (Photo 4, see page 14) . In cross-section, a pie shape necrotic lesion can be observed in infected trunks (Photo 5, see page 14), however this symptom can be also observed in vines infected with Eutypa. Eutypa is a common disease in California, and it is caused by the fungus Eutypa lata. In addition to the pie shaped internal lesion, proliferation of stunted shoots is common (Photo 6, see page 14). This symptom is absent in Botryosphaeria disease, where no growth or no leaf symptoms are observed. Phomopsis is normally associated with damage on green tissue, especially canes and leaves. However, when conditions favor the pathogen, damage caused by Phomopsis can result in death of spurs, canes and buds. Severely affected canes develop cracks and have a bleached ap-
Photo 3. Vines affected by black foot disease. Left: scorch symptoms.
pearance during winter. In early spring reproductive structures of the pathogen are visible as black speckles.
Impact All the described trunk diseases can be seen at any time of the vineyard life, but normally they start to appear between the third and the fifth year after planting. They can appear alone, or in combination, which can exacerbate the plant stress. In general, by year 10 to 12, 20 percent of the plants show symptoms when no preventive actions have been implemented. At this point, trunk diseases enter in an exponential phase, reaching 75 percent of infection by year 15, and 100 percent by year 20. Significant losses are associated with
trunk disease development. ReducManagement tion in number of clusters, decrease Trunk diseases are considered chronic in quality and cosmetic damages are diseases, and unfortunately there is the most visible impacts in the field. no fungicide that can provide curative However, cost of replanting, and/or action. Preventive management or the retraining if grower elects to use vine surgery, especially in young vineyards, Continued on Page 14 it also a major cost associated with trunk diseases. Siebert² in Beat the Heat & Care 2000, estimated the for Your Crops with: annual loss caused by Botryosphaeria and Eutypa in the California wine ® grape industry was $260 million. Similar Frost & Freeze negative effects have Additional Environmental Stress Conditions that the product is useful for: been reported in • High Temperatures & Extreme Heat • Drought Conditions other grape grow• Transplanting • Drying Winds ing areas and trunk A foliar spray that creates a What is diseases. semi-permeable membrane
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Photo 4. Lack of new shoots growth.
Continued from Page 13 removal of infected tissue from the vine (surgery) and destruction by mulching or soil incorporation of infected shoots and canes are the only viable alternatives. More than 95 percent of trunk disease infections are associated with pruning, or other cultural practices that leave
Photo 5. Typical symptom of botryosphaeria.
pruning wounds exposed at a time when the wounds may be infected. Dispersal of the pathogens responsible for causing trunk disease occurs during rain events. Under California conditions pruning and rain overlap during the winter months (November-January). Dr. Gubler and his team found that delaying pruning closer to bud break significantly reduces disease³. The logic behind this is that in a typical California year, rain is gone by the end of February and the days are warmer, letting the plants recover sooner than during the colder days of December and January. In addition, some sap movement (bleeding) starts to be present in February, helping the plant to remove the infective spores from susceptible tissue.
Photo 6. Stunted shoots proliferation on vine infected with Eutypa. 14
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September /October 2019
However, and knowing that the labor and logistics doesn’t permit all growers to postpone
pruning until the last part of the winter, the use of fungicides to protect the exposed tissues is important to reduce the rate of the infection. The best practice is to protect the plant any time there are pruning wounds. This is especially important if rain is expected following pruning. If pruning is done in November or December, it is advised at least two sprays with protectant fungicides be applied. If the pruning is postponed until January and warmer days are forecasted, one protectant spray after pruning is ideal. Another strategy for pruning is to do a double pruning (pre-pruning + pruning). It consists of pre-pruning the vines between November and January. Then, by the end of February or March, the pruning process is completed. The objective of this method is to remove any potential infection occurred during the winter months. A complementary fungicide spray after the last pruning can increase the control of trunk diseases. In order to improve the efficacy of
Continued on Page 16
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January 21, 2020 (Orland, CA)
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Total Attendees
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June 19-21, 2019 (Monterey, CA)
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15
30
Last Profitable Year
25 20 15 10 5 0 25%
25%
25%
50%
50%
50%
75%
75%
75%
No
3
5
10
3
5
10
3
5
10
Pract.
Percentage of control/year practice established Figure 2. Calculated lifespan of profitable vineyard based on the efficacy of the implemented practice and the year when they are implemented.
Continued from Page 14
can be found at:
04-17-0512-FE
protective fungicide, a closer identification of the disease is recommended as any particular fungicide cannot control all possible pathogens. A recent report done by Baumgartner and Brown⁴ on their research in 2017, demonstrates that Pristine, Topsin + Rally (in mixture), and Luna had better preventive control of Botryosphaeria and Phomopsis dieback. Eutypa was controlled more effectively with Pristine. The highest control of Esca was obtained with Serifel, but it only reached 64 percent. Results in 2018 in the same study presented different results and were mainly associated with a different weather condition.
1) http://ipm.ucanr.edu/PMG/selectnewpest.grapes.html
2. Siebert JB. Economic Impact of Eutypa on the California Wine Grape Industry. Davis; 2000.
Different studies, including the one recently done by Dr. Baumgartner and collaborators⁵, demonstrates that preventive practices works better if they are established during the first years of the crop (Figure 2). Dr. Baumgartner estimated that when more effective practices are adopted early in the crop life, it is expected to prolong the vineyard rentability by at least 25 years. Further information on trunk diseases 16
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2) Bettiga LJ, ed. Grape Pest Management, Third Edition. University of California, Agriculture and Natural Resources; 2013. https://books.google. com/books?id=4A9ZAgAAQBAJ.
3. Gubler WD, Rolshausen P e., Trouillase FP, et al. Grapevine trunk Diseases in Califronia. Pract Winer Vineyard. January 2005:1-9.
3) Wilcox WF, Gubler WD, Uyemoto JK, eds. Compendium of Grape Diseases, Disorders, and Pests. Second. St Paul, Minnesota, USA.: The American Phytopathological Society; 2017.
4. Baumgartner K, Brown AA. Protectants for Trunk-disease management in California table grapes. In: California Table Grape Seminar. Visalia: California Table Grape Commission; 2019:19-21.
4) Disease P, Gramaje D. Grapevine Trunk Diseases: Symptoms and Fungi Involved. 2018;102(1):12-39. https:// apsjournals.apsnet.org/doi/10.1094/ PDIS-04-17-0512-FE
5. Baumgartner K, Hillis V, Lubell M, Norton M, Kaplan J. Managing Grapevine Trunk Diseases in California ’ s Southern San Joaquin Valley. 2019;3:267-276. doi:10.5344/ ajev.2019.18075
Cited literature: 1. Gramaje D, Úrbez-Torres JR, Sosnowski MR. Managing Grapevine Trunk Diseases With Respect to Etiology and Epidemiology: Current Strategies and Future Prospects. Plant Dis. 2018;102(1):12-39. doi:10.1094/PDIS-
September /October 2019
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Assessing the Impact of Irrigation Water Quality on
Strawberry Cultivars BY ANDRE BISCARO | Irrigation and Water Resources Advisor, UCCE Ventura County AND MICHAEL CAHN | Irrigation and Water Resources Advisor, UCCE Monterey County
S
Introduction
trawberries are the third most valued crop in California ($2.3 billion) and one of the most sensitive to salinity. Limited information on the tolerance of new varieties to salt and chloride toxicity has led to significant yield losses in recent years. Even a modest yield loss of 5 percent due to soil and water salinity may cost the strawberry industry and California $260 million per year. Despite the importance, commonly used salinity tolerance thresholds for strawberry (Ayers and Westcot, 1985) are based on studies almost a half-century old and may not be applicable to the soils, water quality, climate, and modern cultivars grown in California. California production, which accounts for approximately 85 percent of the strawberries produced in the US, are mostly grown on coastal soils with electrical conductivity (ECe, saturated paste extract method) ranging from 2 to 4 dS/m. Some of these soils have moderate to high concentrations of calcium, bicarbonate and sulfate. Although most of these salts may be precipitated in the form of calcium sulfate (gypsum) and calcium carbonate (lime) and have limited impact on plant growth, the ECe can be considerably 18
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increased when a soil sample is saturated with distilled water (used in the saturated paste extract method) due to the dissolution of these salts. That is a common scenario found in arid regions such as in the Southwestern US (e.g. Ventura County), where limited rainfall contributes to the accumulation of certain salts in the topsoil. In the Watsonville area, however, there is much less carbonate and sulfate in the groundwater and therefore in agricultural fields, where sodium and chloride are of major concern. Excessive sodium most often leads to high sodium adsorption ration (SAR), which causes infiltration problems on some soil types. In irrigated agriculture, the irrigation water quality and leaching fraction are usually the main factors driving soil salinity. When appropriate leaching amounts are applied, the salinity of the soil and of the irrigation water reach a steadystate (equilibrium). However, when irrigation amounts do not exceed crop evapotranspiration (ETc), soil salinity can increase considerably due to the accumulation of salts in the rootzone. Infiltration rate and rainfall also affect soil salinity. In an attempt to account for the precipitation effect of certain salts, Rhoades et al. (1992) suggest that plants can tolerate ECe about 2 dS/m higher
September /October 2019
than published thresholds when grown on gypsiferous soils (soils that contain significant quantities of gypsum, or calcium sulfate). Although this publication provides basic management guidance, strawberry growers and farm managers need more detailed information to determine leaching fractions and to select irrigation water sources and cultivars. Identifying the specific types of anions and cations that make up the salts in soil and irrigation water is important for predicting how different strawberry cultivars will tolerate salinity. For example, a field with soil ECe of 2.5 dS/m, where chloride is approximately 10 meq/L can have significantly greater impacts on strawberry yields than a soil with the same soil ECe where chloride is 2 meq/L and calcium and sulfates are the predominate salts.
Material and Methods In order to assess how susceptible strawberry cultivars are to irrigation water of different quality, a two-year study was conducted in California between 2016 and 2018. The first year of the study consisted of a survey conducted in 40 strawberry fields located in the Oxnard and Watsonville districts,
Continued on Page 20
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DISTRICT OXNARD WATSONVILLE
dS/m
meq/L
EC SAR
Ca
Mg Na
CI SO₄
Average Standard Deviation
1.4 0.3
2.0 0.2
7.2 1.9
3.6 4.5 1.8 10.3 1.0 0.4 1.3 2.5
Average Standard Deviation
1.1 0.5
2.5 3.2 1.5 1.5
2.3 3.9 4.2 1.9 1.0 2.4 2.8 1.1
Table 1. Irrigation water chemical analysis average and standard deviation of 40 fields in the Oxnard and in the Watsonville production districts, year 1 (2016/2017 season).
Continued from Page 18 where irrigation water and soil samples were analyzed for salinity composition. Overall, the irrigation water of the fields located in the Oxnard district had greater electrical conductivity and significantly greater sulfate levels, while chloride levels in the Watsonville fields were twice as great as the Oxnard fields (Table 1). These results were used as the benchmark for determining the treatments of the salinity tolerance experiment conducted the following year. The second year of the study consisted of an experiment conducted in a commercial field located in Oxnard, California during the 2017/2018 production season. Strawberry yield, soil salinity and salts content in leaf blades of the
two most popular public cultivars in Oxnard (cv. Fronteras) and in Watsonville (cv. Monterey) were assessed under eight salinity treatments following a randomized complete block design. Each plot was 30 feet long and 1 bed wide (64 inches), with four plant rows, approximately 90 plants/plot, and two high flow drip tapes (0.67 gpm/100ft) placed about 1.5 inch deep between the 1st and 2nd, and between 3rd and 4th plant rows. The experiment was planted on October 2017, and the treatments started approximately a month post-planting in order to promote a good establishment of the crop; during that period, overhead micro-sprin-
klers was the predominant irrigation method. Drip irrigation amounts and timing were decided based on ETc estimations from the California Irrigation Management Information System (CIMIS station # 152) weather station, and matric potential readings from tensiometers, respectively. Water-powered injection pumps (Figure 1) blended the well water with concentrated salt solutions formulated for each treatment at a 1:100 ratio during every drip irrigation event from November 2017 to June
Continued on Page 22
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Treatments
Continued from Page 20 2018 (total of 60 drip irrigations). The treatments consisted of irrigation water with two levels of elevated sodium adsorption ratio (SAR, 4.6 and 6.6), three levels of elevated chloride (4.2, 7.7 and 11.7 meq/L), and two levels of elevated sulfate (18.3 and 26 meq/L of SO4). Table 2 displays a complete description of the salts’ composition of each treatment. Composite soil and leaf blade samples were collected from each plot at early, mid and late production stages and analyzed for pH, ECe, Ca, Mg, Na, Cl, B, HCO3, CO3 and SO4 (soil samples), and N, P, K, S, B, Ca, Mg, Zn, Mn, Fe, Cu, Na and Cl (leaf blade samples). Marketable and unmarketable yield, and berry weight were measured in average twice a week from December 2017 through June 2018, totaling 54 harvesting events. There was a total of 5.8 inches of rainfall throughout the entire growing season, of which 4.8 inches happened in March, between the first and second sampling events.
meq/L
EC SAR
Ca
Mg Na
CI SO₄
Number
Description
1 2
Elevated SAR, I Elevated SAR, II
1.7 2.1
4.6 5.6 6.6 5.5
2.9 9.6 1.2 16.4 2.8 13.6 3.1 18.5
3 4 5
Elevated CI, I Elevated CI, II Elevated CI, III
1.6 1.9 2.3
2.4 7.2 2.4 8.7 2.4 10.3
3.6 5.5 4.2 11.7 4.8 6.3 7.7 11.7 6.2 6.9 11.7 11.8
6 7
Elevated SO4, I Elevated SO4, II
1.8 2.3
2.7 5.5 7.9 7.0 2.1 18.3 3.1 5.4 12.9 9.3 2.3 26.0
8
Control
1.3
2.5
5.5
2.8
5.1 1.2 11.9
*Control water was provided by local water agency (United Water Conservation District).
Table 2. Chemical analysis of irrigation water treatments of year 2 (2017/2018 season). Values represent average of three samples collected from the drip tape throughout the season. Treatments Number
Description
lbs/acre
Yield loss*
P-Value
1 2
Elevated SAR, I Elevated SAR, II
70,626 68,795
4% 6%
0.953 0.618
3 4 5
Elevated CI, I Elevated CI, II Elevated CI, III
68,850 64,075 61,160
6% 13% 17%
0.632 0.022 0.001
6 7
Elevated SO4, I Elevated SO4, II
69,689 65,756
5% 10%
0.820 0.094
8
Control
73,393
*Compared to Control
Results and Discussion Total marketable yield of Fronteras was significantly (P<0.05) reduced by 13 and 17 percent with increasing chloride levels of 7.7 and 11.7 meq/L, respectively (Table 3). Although yields of all other treatments were lower than the control treatment (Figure 2), those differences were not statistically significant (P>0.05). The high sulfate treatment reduced Fronteras cv. marketable yield by 10 percent, although the differences were not statistically significant (P=0.094). Yield losses due to the elevated salts started before plant symptoms were noticeable in Fronteras. Total marketable yield of the Monterey cultivar was not significantly affected by any salinity treatment (Figure 3 and Table 4, see page 24). Cull rates of both cultivars were not affected by the salinity treatments. Fronteras berry weight was significantly reduced by 6.3 percent with the highest chloride treatment (11.7 meq/L). Salt concentrations in soil and leaf blade samples consistent-
Continued on Page 24 22 Progressive Crop Consultant
dS/m
Table 3. Total yield response to treatments, Fronteras cultivar.
Figure 2. Total marketable yield of Fronteras cultivar displayed in boxplot graph; in this graph, the box represents the limits between the 25th and the 75th percentiles, and the whiskers represent the upper and lower endpoints. The horizontal line inside the box represents the median.
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Treatments Number
Description
lbs/acre
Yield loss*
P-Value
1 2
Elevated SAR, I Elevated SAR, II
51,040 50,763
4% 5%
0.960 0.928
3 4 5
Elevated CI, I Elevated CI, II Elevated CI, III
51,725 53,296 50,812
3% 0% 5%
0.995 1.000 0.934
6 7
Elevated SO4, I Elevated SO4, II
52,797 51,700
1% 3%
1.000 0.995
8
Control
53,243
*Compared to Control
Table 4. Total yield response to treatments, Monterey cultivar.
Continued from Page 22 ly increased with the higher salinity treatments for both cultivars (data not shown).
with the appropriate leaching requirement to the water quality. The fact that the Monterey cultivar did not respond to the salinity treatments included in this study may be related to significantly greater chloride levels found in the irrigation water of the Watsonville area, where the cultivar was selected and tested before being released to commercial production.
challenging and most likely far from being achieved.
References
Ayers, R.S. and D.W. Westcot, 1985. The rainfall events that occurred beFAO Irrigation and Drainage Paper 29: tween the first and second samplings Water quality for agriculture. In Crop contributed to significant leaching of tolerance to salinity. http://www.fao. salts from the root zone (0-12 inch org/3/T0234E/T0234E03.htm#ch2.4.3 depth), which made overall ECe values from the second sampling date very In summary, the findings of this study Rhoades, J.D., A. Kandiah and A.M. similar to the values measured during conclude that the strawberry cultivar Mashali. 1992. FAO Irrigation and the first date. Hence, yield losses Fronteras is highly susceptible to eleDrainage Paper 48: The use of saline waobserved in this experiment may have vated chloride levels, and that salinity ters for crop production: http://www. been greater, and occurred sooner if effects on strawberry yield is cultivar fao.org/3/t0667e/t0667e00.htm the rainfall during that period had dependent. Although this study probeen less. Additionally, plant sympvides conclusive information of salinity toms of the salinity treatments, which effects on Fronteras and some informawere not observed until mid-May, may tion about Monterey cultivar, the quest Comments about this article? We want have been observable sooner with less to understanding the impact of salts on to hear from you. Feel free to email us at intense precipitation. Overall, the most the main strawberry cultivars is very article@jcsmarketinginc.com surprising finding of this study is the marked differences in yield response to the salinity treatments between the two cultivars. While Fronteras proved to be highly susceptible to increased irrigation water salinity, especially in regards with chloride, Monterey cv. presented limited and statistically not significant yield declines. Accordingly, other major public and proprietary strawberry cultivars may also exhibit a range of susceptibility to salinity. It is also reasonable to expect greater yield losses of the cultivar Fronteras grown on fields that have been farmed with irrigation water quality equivalent to the treatments of this study for years. In that case, plant establishment can be compromised by the increased water and soil salinity, especially if the irrigation wasn’t managed Figure 3. Total marketable yield of Monterey cultivar displayed in boxplot graph. 24 Progressive Crop Consultant
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California’s Prune Orchard OF THE Future BY LUKE MILLIRON | UCCE Farm Advisor for Butte, Glenn and Tehama Counties AND FRANZ NIEDERHOLZER | UCCE Farm Advisor for Colusa, Sutter and Yuba Counties AND DANI LIGHTLE | UCCE Orchards Systems Advisor for Glenn, Butte and Tehama Counties AND KATHERINE JARVIS-SHEAN | UCCE Orchards Systems Advisor for Sacramento, Solano and Yolo Counties
Figure 1. An unheaded 2nd leaf prune tree in March 2017 in Glenn County with traditionally headed trees in the background. This Glenn County grower is experimenting on their own with various tree training regimes.
C
alifornia will likely have a large prune crop in 2019 following favorable bloom conditions and lower yields in 2018. Unfortunately, in prune production with larger crops typically comes smaller fruit, of which there is currently an over-supply in the world market. High production of small fruit world-wide has come at a time when demand for small fruit from consuming nations like China, Brazil, and Russia has been in decline. California handlers have been strongly urging their growers to use shaker thinning to reduce the fruit number during spring and help deliver large, high-quality fruit at harvest. To be successful, the prune orchard of the future is going to have to thread the needle of achieving earlier production in its life cycle and maintaining high and consistent yields in maturity, all while attaining large average fruit size each year. Prunes come into production later than many other orchard crops. One way to increase early production is to reduce or eliminate severe heading 26 Progressive Crop Consultant
cuts during tree training. Subsequently, yield potential at orchard maturity may be increased over historical production levels in some situations by striking a new balance between spacing and rootstock vigor for increased canopy volume and higher light interception. Finally, the key mechanism for achieving more consistent yields and larger fruit size in prune production has been to thin the crop with mechanical shaking following good bloom conditions like we had this year. Shaker thinning will likely continue to be the foundation of consistent yields for future orchards. Pruning Prunes: Greater Early Production by Avoiding Heading Cuts During Establishment University of California (UC) research has shown that earlier and greater production can be achieved in both almonds and walnuts by reducing the severity of pruning during tree establishment. This has been done by reducing or eliminating the use of severe heading cuts (Figure 1) during tree
September /October 2019
establishment. In pruning, “heading cuts” reduce the length of a limb, while “thinning cuts” completely remove the limb. Although historical orchard tree training often calls for severe heading cuts (e.g. cutting back ½ or more of the 1st year growth during the first dormant period), leaving limbs unheaded can lead to earlier fruit production. Bill Krueger, now a UC Cooperative farm advisor emeritus, tested several pruning regimes for newly planted prune trees from 1996 through 2000. The most successful of these pruning regimes all minimized the severity of pruning. Yield and profitability were greatest in the treatment that selected three to five scaffolds at the first dormant and bent back competing limbs (nearly to, or to the point of breaking to reduce competitiveness). Competing limbs were again bent at second and third dormant, and finally limbs were left unheaded at fourth dormant. In all four years of this treatment, pruning cuts were made for selective thinning (complete limb removal) to help shape the tree into a vase-shape and elimi-
SOURCES:
Figure 2. Measuring both almond yield (kernel lbs/ac) and midday photosynthetically active radiation (PAR) percentage have shown a direct relationship of 40 kernel lb/ac per 1 percent PAR. Photo courtesy of Lampinen Lab, UC Davis.
nate competing or crossing branches. Other treatments that both yielded well and had the highest total income selected either 3 or 3-5 scaffolds and either left those scaffolds unheaded or lightly tipped in the first dormant. In the 2nd, 3rd and 4th dormant these other successful treatments had various sequences of either being unheaded (but still making thinning cuts) or leaving the trees completely unpruned. By contrast, the severe pruning treatment that had the lowest cumulative dry yield and income selected three scaffolds at the first dormant and then headed new limb growth back to 30 inches in the 1st through 4th dormant. You can read the full report from 2000, which is the second listed report at:
ucanr.edu/sites/driedplum/show_categories/General_Pruning/ Joe Turkovich, Winters area grower and Chairman of the California Prune Board developed his own minimal pruning training method, which he describes as a modified version of the "long pruning" method described by Krueger and others in the UC Prune Production Manual. First used in the early 1990’s, the goal of his approach is to create an upright canopy framework with a strong interior architecture capable of bearing large crops without the need for wiring, rope, or propping. It allows for early bearing and isolates breakage to flatter, bearing side limbs.
Continued on Page 28 September /October 2019
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27
Continued from Page 27 It involves the almost exclusive use of thinning cuts as opposed to heading cuts. Turkovich heads the dormant bareroot trees at 40 inches at planting to allow space for vertical separation between the future primary scaffolds. Scaffolds are selected during October of the first year of growth and left unheaded. In May of the 2nd year, the three scaffolds are lightly tipped back (approximate height nine feet) to keep them from bending out of position, and approximately a third of new growth is thinned out (in particular, removing crossing-limbs, while allowing flat fruiting wood to develop). In the dormant period between year two and three (or during the summer of year three) the only pruning that occurs is to select or promote the growth of secondary leaders (two per scaffold). Again, no heading cuts are done, and no attempt is made to "open up the tree". Between year three and four, again, no heading cuts. Excessive side limbs are removed or tipped to prevent over-bearing and breakage and tertiary leaders are selected or promoted, two per secondary leader. In subsequent years he continues to avoid heading cuts, never topping the trees. If tree height needs to be reduced, leaders are thinned back to strong side upright limbs three to five feet below the top of the tree. On 18' by 16' spacing, Turkovich reports this orchard training approach has yielded approximately 0.6 tons in the 3rd leaf, 1.2 in the 4th, 3.0 in the 5th and an average of 4.5-5.5 tons/ac of high-quality fruit in the 6th year and beyond. Whether utilizing one of the minimal pruning regimes tested by Bill Krueger or the approach utilized by Joe Turkovich, minimizing severe heading cuts during tree establishment can lead to improved early yields. Tighter Spacing and Greater Light Interception in the Prune Orchard of the Future: Increased Canopy Volume → Increased Light Interception → Increased Yield Potential At maturity, higher yields could be 28 Progressive Crop Consultant
Figure 3. Two clusters of prune yield (dry tons/acre) versus midday light interception (%), grouped by row spacing. Photo courtesy of E. Fichtner and F. Niederholzer.
achieved in many California prune orchards by capturing more light with the choice of a more vigorous rootstock, and/or planting at a closer spacing. We all know that fruit and leaves grow on branches, and that fruit need the sugar production from neighboring leaves to grow and sweeten. Thus, one way to think about the yield potential of an orchard is how many fruit-leaf groupings (also called bearing units) are spread out over the orchard. In other words, increasing the amount of space in the orchard taken up by the orchard canopy (instead of open, unused space) will increase your yield potential per acre. One measure of canopy size is how much light that canopy intercepts. Light that is intercepted by the leafy canopy and doesn’t reach the orchard floor is measured as midday photosynthetically active radiation (percent PAR). Work by the laboratory of Bruce Lampinen, University of California Cooperative Extension (UCCE) orchard specialist at UC Davis, has found that for every 1 percent of light that an almond orchard captures there is an average of 40 lbs/ac increased yield in all measured orchards (Figure 2, see page 27). Lampinen has found this relationship between greater light capture and greater yield potential in both almond and walnut production. Light interception isn’t the only determinant of yield of course, therefore these are “potential” yields and depend on proper irrigation, fertilization, pest and disease management.
September /October 2019
Light Interception and Yield Potential in Prune Production Although the relationship between canopy light interception and yield has not been as well studied in prune production, there does appear to be a clear relationship from the limited data available (see Figure 3). Although there is substantial variation, the denser 14 feet x 17 feet planting in this example is achieving between 60-80 percent light interception and is clearly out yielding the wider spaced plantings that are only capturing 30-45 percent of midday light, common in many California prune orchards. The 16 foot in-row spacings of the wider plantings appear as discrete trees (they do not touch), while the spacing 14 feet by 17 feet have created continuous hedgerows (Figure 4, see page 30). This tighter (183 trees/acre) spacing illustrates the 14 feet by 17 feet 6-8 dry tons/ac yield potential of prune orchards in excellent cropping years. Prune orchard spacing has historically been determined by the constraints of harvest equipment. However, some growers are instead shifting this paradigm and beginning to modify their equipment to get through tighter spacings. Many questions and potential challenges arise due to this shift in paradigm and will be addressed through experimentation by innovative growers and UC researchers. For more considerations impacting Continued on Page 30
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Figure 4. Two orchards with contrasting spacing, light interception and yield potential. Left photo courtesy of E. Fichtner. Right photo courtesy of F. Niederholzer.
Continued from Page 28 spacing and light interception, including rootstock vigor and soil type, per tree costs and mechanical hedging, see: cebutte.ucanr.edu/newsletters/Prune_ Notes79781.pdf Consistent Large Fruit Size The final component to remaining competitive with the increased production levels in Chile and Argentina, is achieving large, high-quality fruit each and every-year. The key approach to achieving consistent large fruit size is shaker thinning in years like 2019 when a high percentage of flowers set fruit (far too many for the tree to achieve a large average fruit size). Fruit thinning occurs roughly at “reference date” or when 80-90 percent of fruit have a visible “endosperm”. Endosperm is a clear gel-like glob that can be excised with a knife point from the blossom end of the seed (Figure 5). Reference date is roughly one week after the pit tip begins to harden and timing is typically late April or early May. Although the earlier thinning is done, the greater the effect will be on final fruit size at harvest, if you thin too early you can damage the tree without effectively removing fruit. UC Cooperative Extension orchard farm advisor Dani Lightle developed a great guide to shaker thinning that computes the required calculations for you: 30 Progressive Crop Consultant
sacvalleyorchards.com/prunes/horticulture-prunes/prune-thinning-calculator/ Thinning is a critical practice for several reasons. When production of small fruit is up worldwide at the same time demand for small fruit is in decline, achieving large average fruit size is an absolute imperative. Not only do small fruit have substantially less value (or even no value in some cases), they are costlier to harvest and dry. Setting a large crop of small fruit can also be a great stressor on an orchard creating a large sink for potassium demand and causing limb breakage. Finally, since not every year’s bloom creates favorable conditions for fruit set, over-cropping can set up a vicious cycle of having fewer flowers that will be blooming during an uncertain bloom period in the subsequent year. In other words, thinning enables a high flower density each year. Even if bloom conditions are poor and set is low, a low percentage of fruit set from a high number of flowers is much better than low set from only a few flowers. Mechanical thinning enables the production of higher-value fruit, avoids the drain of costly small fruit and sets up the orchard for more sustainable year-to-year production. Three key practices for maximizing orchard productivity are utilizing reduced severity of pruning during canopy training, achieving higher yield potential by maximizing canopy light interception and consistently attaining large average fruit size through thinning. These
September /October 2019
practices may be part of what gives the California prune orchard of the future a competitive edge in the global market. This work is made possible by the funding support of the California Prune Board. Special thanks to Mark Gilles (Sunsweet) for his input on prune orchard spacing both historically and currently. Special thanks also to Joe Turkovich who kindly provided the details of his modified version of the "long pruning" method. Comments about this article? We want to hear from you. Feel free to email us at article@jcsmarketinginc.com
Figure 5. Extraction of the endosperm on a developing prune. Photo courtesy of M.L. Poe.
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Colletotrichum
Dieback in California Citrus BY GREG W. DOUHAN | UCCE Area Citrus Advisor for Tulare, Fresno, and Madera Counties AND AKIF ESKALEN | Department of Plant Pathology, UC Davis AND JOEY S. MAYORQUIN| Department of Microbiology and Plant Pathology, UC Riverside
November 20th, 2019 7:00 AM - 1:00 PM Tulare Fairgrounds
215 Martin Luther King Jr Ave, Tulare, CA 93274
For More Information, See Page 37
32 Progressive Crop Consultant
September /October 2019
T
he 2017-2018 United States (U.S.) citrus crop was valued at 3.28 billion dollars with California’s citrus production accounting for 59 percent of the overall U.S. production. Much of California’s bearing acreage is devoted to orange production, however other citrus varieties of tangerine, mandarin, lemon and grapefruit are grown throughout the state. As the California citrus industry contributes to over half of the total U.S. citrus production, the identification and management of new disease threats is crucial. Colletotrichum, a Globally Distributed Fungus Colletotrichum constitutes a large genus of fungi which are known for having diverse ecological roles ranging from endophytes, fungi living within plant tissues and causing no known problems, to plant pathogens that can kill entire plants or portions of the plant. Colletotrichum includes some
important fungal pathogens of numerous plant hosts including native and agricultural plant species occurring in tropical and subtropical regions in the world. Colletotrichum is well-known for causing various anthracnose diseases on many plants, with general anthracnose symptoms including necrotic lesions on various plant parts including stems, leaves, flowers and fruits. Although Colletotrichum is primarily described as causing anthracnose diseases, other diseases such as rots caused by Colletotrichum spp. have been documented. Currently, over 100 species of Colletotrichum have been described and recent phylogenetic studies (which show the relationship among organisms) based on the analysis of DNA has found that at least 71 unique phylogenetic species exist within three well known ‘species’ of Colletotrichum based on traditional morphology; C. gloeosporioides, C. acutatum, and C. boninense. The large species diversity within the Colletotrichum genus highlights the
importance of DNA phylogenies to accurately identify species. With respect to citrus, two species of Colletotrichum, C. gloeosporioides (Penz.) Penz. & Sacc. and C. acutatum J.H. Simmonds, have been associated with anthracnose diseases of citrus. These anthracnose diseases, which include post-harvest anthracnose, postbloom fruit drop (PFD), and key lime anthracnose (KLA) are of great economic importance as postharvest diseases. However, recent evidence is suggesting that additional species of Colletotrichum previously unknown from citrus are causing diseases of citrus globally, particularly from the C. boninense species complex. Colletotrichum karstii You L. Yang, Zuo Y. Liu, K.D. Hyde & L. Cai (C. boninense species complex) has been increasingly reported from anthracnose symptoms of citrus worldwide and is often found to occur in association with other Colletotrichum spp., particularly C. gloeospo-
Continued on Page 34
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one species may be present. Historically, C. gloeosporioides sensu stricto has been the only species associated with anthracnose diseases of citrus in California. C. karstii, a ‘New’ Species Associated With Citrus in California
A
B
C
D
Figure 1. Symptoms of Colletotrichum Dieback. A) Shoot dieback symptoms on Clementine, B) Gumming symptoms on an infested shoot. C) Branch dieback symptoms on Clementine. D) Wood discoloration and canker on the wood.
Continued from Page 33
Colletotrichum Symptomology
rioides which generally predominates within citrus hosts. C. karstii has been increasingly reported from anthracnose diseases of other crops including avocado, mango, and persimmon and is considered the most common and widely distributed species of the C. boninense species complex. Although C. karstii has been reported from citrus in China, Italy, and Portugal, in the United States C. karstii has only been reported from other host species. 34 Progressive Crop Consultant
Recently, unusual disease symptoms associated with Colletotrichum spp. have been observed frequently in various citrus orchards in the San Joaquin Valley of California (Eskalen, per ob). Symptoms include leaf chlorosis, twig and shoot dieback, crown thinning, wood cankers in branches and in some cases death of young plants (Figure 1). Isolations from diseased tissues yielded typical Colletotrichum species based on colony morphology but slight differences also suggested that more than
September /October 2019
Recent work by researchers at the University of California have now identified C. karstii as a new pathogen of citrus causing twig and shoot dieback with or without gumming and occasionally branch dieback and wood canker in the Central Valley of California. Pathogenicity tests on clementine mandarin also confirmed that C. karstii is a more aggressive pathogen of citrus in California compared to C. gloeosporioides based on in planta experiments (Figure 2, see page 35). Based on a survey of samples collected throughout the Central Valley, this same research also found that both species are commonly isolated from symptomatic tissues and were often found co-infecting the symptomatic samples. However, the researchers also never found other known wood canker pathogen species of citrus within the Botryosphaeriaceae and Diatrypaceae from samples in which both Colletotrichum species were isolated. Unlike anthracnose which can cause twig dieback and is associated with C. gloeosporioides, this disease is associated with two species of Colletotrichum and is not limited to twig dieback alone but is also associated with shoot dieback and in some cases, woody cankers. Taken together, this confirms C. karstii as a new pathogen of citrus in California causing a disease distinct from anthracnose which is caused by C. gloeosporioides. The association of C. karstii with citrus twig and shoot dieback in California represents a significant finding since C. karstii appears now to be a new pathogen of citrus in the United States. Anthracnose disease of citrus has mainly been attributed to C. gloeosporioides and C. acutatum which
Mean Lesion Length (cm)
C. karstii
C. gloeosporioides
Control
Fungal Isolates Figure 2. Pathogenicity of Colletotrichum spp. on ‘4B’ clementine after 15 months. Vertical lines represent standard error of the mean.
results were found with other spore trap studies in California. Wounding is also known to predispose plants to infection by Colletotrichum and typical agricultural practices and the environment in California citrus groves (pruning, shearing, wind/sand damage) give both of these species the opportunity to colonize citrus trees. Based on recent research, symptoms were observed during the late spring and summer months, with no new symptoms being observed into fall, winter and early spring. This suggests that young, tender tissues developing in the late spring are likely necessary for initial pathogen colonization.
Continued on Page 36
are considered mainly as foliar and fruit pathogens. Although symptoms of anthracnose caused by C. gloeosporioides in citrus include twig dieback, leaf drop and necrosis on fruits as a postharvest disease, a progression to shoot dieback and association with branch dieback and wood cankers has not been observed. Although little is known regarding the epidemiology of C. karstii on citrus, several environmental factors are likely important for the dissemination and progression of this disease. Relative humidity and precipitation in citrus orchards in California play an important role in the epidemiology of Colletotrichum infection whereby conidia dispersed by rain and humidity are conducive to pathogen spread. Our spore trap study showed that spore trapping of Colletotrichum species occurred most frequently during the months with the highest precipitation (Figure 3), however Colletotrichum spp. were not always correlated with rainfall. Similar September /October 2019
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Month
Tulare Co.
Financial support for this project was provided by the Citrus Research Board (Project # 5400-152). Plants used for pathogenicity tests were kindly donated by Wonderful Citrus. We thank D. Trannam, R. Yuan, K. Sugino, Q. Douhan, and our cooperating citrus growers for assistance in the lab and field.
Comments about this article? We want to hear from you. Feel free to email us at article@jcsmarketinginc.com
Average Temperature (°C)/CFU
Acknowledgements
Total Precipitation (in)/Average Relative Humidity (%)
Currently no strategies exist for the management of this emerging disease in citrus. Adherence to cultural practices recommended for the management of other canker and dieback pathogens should be followed. These practices include maintaining trees in good condition through appropriate irrigation regimens and proper fertilization, removal of infested branches and pruning debris during dry periods followed by immediate disposal of infested material, and sanitizing pruning equipment. Chemical management using fungicides is being investigated and these methods may become part of an integrated pest management strategy for Colletotrichum diseases of citrus in California.
Average Temperature (°C)/CFU
Management Practices for Colletotrichum Dieback
Total Precipitation (in)/Average Relative Humidity (%)
Kern Co.
Continued from Page 35
Month Figure 3. Monthly spore trap counts with temperature (°C), precipitation (mm), and relative humidity (%) for (a) Kern and (b) Tulare counties. Vertical bars represent total colony forming units (CFU) counted from each citrus orchard by month. Lines represent average monthly temperature (°C) and relative humidity (%) and total monthly precipitation (mm).
36 Progressive Crop Consultant
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Evaluating Biostimulant and Nutrient Inputs to Improve Tomato Yields and Crop Health BY SURENDRA K. DARA | Entomology and Biologicals Advisor, UCCE AND ED LEWIS | Head, Department of Entomology, Plant Pathology, and Nematolody, University of Idaho
C
alifornia is the leading producer of tomatoes, especially for the processing market (California Department of Food and Agriculture (CDFA), 2019). Tomato is the 8th most important commodity in California valued at $1.05 billion. Processed tomatoes are ranked 6th among the exported commodities with a value of $813 million. While good nutrient management is necessary for optimal growth, health, and yields of any crop, certain products that contain minerals,
beneficial microbes, biostimulants, and other such products are gaining popularity as they are expected to improve crop health and yield, impart soil or drought resistance, induce systemic resistance, or improve plant's immune responses to pests, diseases, and other stress factors (Berg, 2009; Bakhat et al., 2018; Chandra et al., 2018; Shameer and Prasad, 2018). Maintaining optimal plant health through nutrient management is not only important for yield improvement, but also an
important part of integrated pest management strategy since healthy plants can withstand pest and disease pressure more than weaker plants and thus reduce the need for pesticide treatments.
Methodology A study was initiated in the summer 2017 to evaluate the impact of various treatment programs on tomato plant health and yield. Processing tomato
Continued on Page 40
Experimental plots, transplanting, and treatment details. All photos courtesy of Surendra K. Dara. 38 Progressive Crop Consultant
September /October 2019
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Continued from Page 38 cultivar Rutgers was seeded on June 7th and transplanted on July 18th, 2017 using a mechanical transplanter. Monoammonium phosphate (11-52-0) was applied at 250 lb/ac as a side-dress on August 7th as a standard for all treatments. Since planting was done later in the season, crop duration and harvesting period were delayed due to the onset of fall weather. Plots were sprinkler irrigated daily or every other day for three to four hours for about two weeks after transplanting. Drip irrigation was initiated from the beginning of August for 12-14 hours each week and for a shorter period from mid October onwards.
1
Standard
2
AgSil® 21 at 8.75 fl oz/ac in 100 gal of water through drip (for 30 minutes) every three weeks from July 31st to November 13th (6 times). AgSil 21 contains potassium (12.7 percent K2O) and silicon (26.5 percent SiO2) and is expected to help plants with mineral and climate stress, improve strength, and increase growth and yields.
3
Yeti BloomTM at 1 ml/gallon of water. Applied to the roots of the transplants one day before transplanting followed by weekly field application through the drip system from August 7th to November 13th (15 times). Yeti is marketed as a biostimulant and has a consortium of beneficial bacteria—Pseudomonas putida, Comamonas testosterone, Citrobacter freundii, and Enterobacter cloacae. Yeti Bloom is expected to enhance the soil microbial activity and helps with improved nutrient absorption.
4
There were five treatments in the study including the standard. Each treatment had a 38 inch wide and 300 foot long bed with a single row of tomato plants. Treatments were replicated four times and arranged in a randomized complete block design. Different materials were applied through drip using a Dosatron injector system, sprayed at the base of the plants with a handheld sprayer, or as a foliar spray using a tractor-mounted sprayer based on the following regimens. A 50 foot long area was marked in the center of each plot for observations. Plant health was monitored on August 1st, 8th, and 22nd by examining each plant and rating them on a scale of 5 where 0 represented a dead plant and 5 represented a very healthy plant. Yield data were collected from October 11th to December 5th on eight harvest dates by harvesting red tomatoes from each plot. On the last harvest date, mature green tomatoes were also harvested and included in the yield evaluation. Data were analyzed using analysis of variance and Tukey's HSD test was used for means separation.
Results and Discussion There was no statistically significant difference (P > 0.05) in the health of
Continued on Page 41 40 Progressive Crop Consultant
Tech-Flo®/Tech-Spray® program contained five products that supplied a variety of macro and micro nutrients. Products were applied through drip (for 30 min) at the following rates and frequencies in 300gal of water. 1. Tech-Flo All Season Blend #1 1 qrt/ac in transplant water and again at first bloom on August 28th. 2. Tech-Flo Cal-Bor+Moly at 2 qrt/ac at first bloom on August 28th. 3. Tech-Flo Omega at 2 qrt/ac in transplant water and again on September 11th (two weeks after the first bloom). 4. Tech-Flo Sigma at 2 qrt/ac on September 11th (two weeks after the first bloom). 5. Tech-Spray Hi-K at 2 qrt starting at early color break on September 25th with three follow up applications every two weeks.
5
Innovak Global program contained four products. 1. ATP Transfer UP at 2 ml/liter of water sprayed over the transplants to the point of runoff just before transplanting. Three more applications were made through drip (for 30 min) on August 7th and 21st and September 4th. This product contains ECCA Carboxy® acids that promote plant metabolism and expected to impart resistance to stress factors. 2. Nutrisorb-L at 40 fl oz/ac applied through drip (for 30 min) on 31 July, 14 August (vegetative growth stage), 4 and 18 September, and 2 October (bloom through fruiting). Nutrisorb-L contains poly hydroxyl carboxylic acids, which are expected to promote root growth and improve nutrient and water absorption. 3. Biofit®N at 2 lb/ac through drip (for 30 min) on July 31st, August 21st (three weeks after the first), and September 4th (at first bloom). Biofit contains a blend of beneficial microbes—Azotobacter chroococcum, Bacillus subtilis, B. megaterium, B. mycoides, and Trichoderma harzianum. This product is expected to improve the beneficial microbial activity in the soil and thus contribute to improved soil structure, root development, plant health, and ability to withstand stress factors. 4. Packhard at 50 fl oz/ac in 50 gal of water as a foliar spray twice during early fruit development (on September 11th and 18th) and every two weeks during the harvest period (four times from October 2nd to November13th). Contains calcium and boron that improve fruit quality and reduce postharvest issues.
September /October 2019
Continued from Page 40 the plants in August (Figure 1) or in the overall seasonal yield (Figure 2) among treatments. The average health rating from three observations was 3.94 for the standard, 4.03 for AgSil 21, 4.45 for Yeti Bloom, 4.38 for Tech-Flo/Spray program, and 4.35 Innovak Global program. When the seasonal total yield per plot was compared, Yeti Bloom had 194.1 lb followed by, Innovak program (191.5 lb), AgSil 21 (187.3 lb), the standard (147.4 lb) and Tech-Flo/Spray program (136.5 lb). Due to the lack of significant differences, it is difficult to comment on the efficacy of treatments, but the yield from AgSil 21 was 27 percent more than the standard while yields from Innovak program and Yeti Bloom were about 30 percent and 32 percent higher, respectively. Studies indicate that plants can benefit from the application of certain minerals such as silicon compounds and beneficial microorganisms, in addition to optimal nutrient inputs. Silicon is considered as a beneficial nutrient, which triggers the production of plant defense mechanisms against pests and diseases (Bakhat et al., 2018). Although pest and disease conditions were not monitored in this study, silverleaf whitefly (Bamisia tabaci) infestations and mild yellowing of foliage in some plants due to unknown biotic or abiotic stress were noticed. AgSil 21 contains 26.5 percent of silica as silicon dioxide and could have helped tomato plants to withstand biotic or abiotic stress factors. Similarly, beneficial microbes also promote plant growth and health through improved nutrient and water absorption and imparting the ability to withstand stresses (Berg, 2009; Shameer and Prasad, 2018). Beneficial microbes in Yeti Bloom and Biofit®N might have helped the tomato plants in withstanding stress factors and improved nutrient absorption. Other materials applied in the Innovak program might have also provided additional nutrition and sustained microbial activity. The scope of the study, with available resources, was to measure the impact of various treatments on tomato crop health
Continued on Page 42
Figure 1. Plant health on a 0 (dead) to 5 (very healthy) rating on
three observation dates.
Figure 2. Seasonal total yield/plot from different treatments.
Figure 3. Percent difference in tomato yield between the standard
and other treatment programs.
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Continued from Page 41
For Immediate Release:
and yield. Additional studies with soil and plant tissue analyses, monitoring pests and diseases, and their impact on yield would be useful.
Dr. Surendra Dara, entomology and biologicals advisor with the University of California Cooperative Extension, has been selected for the Distinguished Achievement Award in Extension from the Entomological Society of America that has more than 7000 members worldwide. This prestigious national level award recognizes outstanding contributions to extension entomology. His research and extension program creates innovative solutions for sustainable crop production and protection, and he reaches out to the agricultural community locally, regionally, and internationally. Details of this award and Dr. Dara’s credentials, achievements, and current research efforts can be found on the internet at https://www. entsoc.org/esa-names-winners-2019-professional-and-student-awards. Dr. Dara’s faculty profile can be seen at https://ucanr.edu/index.cfm?facultyid=4458
Acknowledgements: Thanks to Veronica Sanchez, Neal Hudson, Sean White, and Sumanth Dara for their technical assistance and the collaborating companies for product samples or providing financial assistance.
References Bakhat, H. F., B. Najma, Z. Zia, S. Abbas, H. M. Hammad, S. Fahad, M. R. Ashraf, G. M. Shah, F. Rabbani, S. Saeed. 2018. Silicon mitigates biotic stresses in crop plants: a review. Crop Protection 104: 21-34. DOI: 10.1016/j. cropro.2017.10.008. Berg, G. 2009. Plant-microbe interactions promoting plant growth and health: perspectives for controlled use of microorganisms in agriculture. Appl. Microbiol. Biotechnol. 84: 11-18. DOI: 10.1007/s00253-009-2092-7.
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CDFA (California Department of Food and Agriculture). 2019. California agricultural statistics review 2017-2018. (https://www.cdfa.ca.gov/statistics/ PDFs/2017-18AgReport.pdf) Chandra, D., A. Barh, and I. P. Sharma. 2018. Plant growth promoting bacteria: a gateway to sustainable agriculture. In: Microbial biotechnology in environmental monitoring and cleanup. Editors: A. Sharma and P. Bhatt, IGI Global, pp. 318-338. Shameer, S. and T.N.V.K.V. Prasad. 2018. Plant growth promoting rhizobacteria for sustainable agricultural practices with special reference to biotic and abiotic stresses. Plant Growth Regulation, pp.1-13. DOI: 10.1007/s10725017-0365-1.
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Mechanistic INSIGHT into the Salt Tolerance of Almonds BY DEVINDER SANDHU USDA-ARS, US Salinity Lab, Riverside California AND BISWA R. ACHARYA University of California Riverside
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ood quality water is extremely important for agriculture throughout the world. However, due to reduced availability of water and increasing food demands, future use of degraded waters is evident. One of the major concerns of utilizing degraded waters for irrigation is their high salt concentration. Salinity is one of the main abiotic stresses faced by the agriculture industry. Modest increase of soil salinity level impacts both plant growth and yield by causing several physiological and biochemical changes. Based on salt tolerance level plants are classified broadly in two groups: halophytes and glycophytes. The halophytes have special mechanisms to tolerate high concentrations of salts and therefore can grow in saline environments. The majority of plants (including almonds) are glycophytes and cannot tolerate high salt concentrations and so grow in soil containing low salts. However, among glycophytes, salt tolerance level varies tremendously not only at the species level but also at the variety level within a species. This variation is directly dependent on the functional status of various molecular components that play critical roles to protect the plant during salt stress. In the initial stages of salinity exposure, a plant faces osmotic stress, resulting in ion imbalance in cells, membrane disintegration and reduced photosynthesis. In addition, osmotic stress in the root sends a signal throughout the plant causing reprograming of physiological and molecular activities to initiate defense response against salinity stress. Slowly ionic stress develops, leading to accumulation of Na+
Continued on Page 46 44 Progressive Crop Consultant
September /October 2019
Figure 1. Evaluation of salinity tolerance of 16 almond rootstocks irrigated with waters of different ion compositions. Photo courtesy of Devinder Sandhu.
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Continued from Page 44
to a continuous increase in “Duecultivated area under almonds,
(sodium ions) and Cl- (chloride ions) in plant tissues. High ion concentrations are not only toxic but also interfere with absorption of essential nutrients by a plant. High Na+ and Cl- levels interfere in many molecular, biochemical, metabolic and physiological processes which could also lead to unnatural senescence and cell death. For plant species that are moderately tolerant to salinity, osmotic stress may play an important role. However, for species sensitive to salinity such as almonds, low salt concentration is able to impose ionic stress that may reach to an intolerable level, whereas it may not generate osmotic stress critical for plant growth. Hence, when studying salinity stress in almonds, it is important to focus on responses related to ionic stress and the exposure to salinity should be gradual to avoid any osmotic shock. This also mimics field conditions in an almond orchard, as during spring salt moves to subsurface layers due to the rain and slowly moves to upper layers during summer, which leads to gradual increase in root zone salinity. Due to a continuous increase in cultivated area under almonds, farmers are forced to utilize marginal lands with low quality saline water for irrigation. In almonds, rootstock plays an important role in regulating plant growth in salinity stressed environment. Hence, the development of new almond rootstocks tolerant to salinity is
farmers are forced to utilize marginal lands with low quality saline water for irrigation. highly desirable. In the last two decades, several studies focusing on screening almond rootstocks for salinity tolerance have been conducted and some tolerant rootstocks have been identified. However, a comprehensive approach to screen and develop new rootstocks with enhanced salinity is missing in almonds.
Impact of Salinity on Water Relations and Photosynthesis Water uptake by a plant is drastically affected under salinity, which leads to reduced water potential, relative water content, stomatal conductance and transpiration. As plants take nutrients with water, reduced water uptake also decreases tissue concentration of essential nutrients affecting plant growth. In addition, high salt concentrations also affect homeostasis, osmoregulation and net photosynthesis. Photosynthesis is the most critical metabolic process for almonds. In response to salinity, osmotic stress-mediated stomatal closure prevents water loss through transpiration in plants that also restricts the amount of CO2 taken in for photosynthesis. Consequently, stomatal conductance, net photosynthetic rate and amount of chlorophyll are used as physiological parameters to study salinity tolerance in different almond varieties. In a recent study where we compared several rootstocks for salinity tolerance, photosynthetic rate was found to be the most reliable parameter to assess salinity tolerance.
Continued on Page 48 46 Progressive Crop Consultant
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September /October 2019
Continued on Page 46
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Your Edge – And Ours – Is Knowledge. www.progressivecrop.com 47
Continued from Page 46
Tissue Ion Composition and Salinity Tolerance Tissue Na concentration is commonly used as a guide for the salinity tolerance of a variety. However, for some plant species, tissue Na concentration is not a true indicator of salt tolerance of a variety. Never-the-less, for almonds the negative correlation between tissue Na concentration and salt tolerance holds well. Similar to Na accumulation, salt tolerant genotypes stored least amount of Cl in leaf tissue.
Genetic Control of Salinity Tolerance In model plants, hundreds of genes have been discovered that play critical roles in salinity tolerance. Salt-stress induced signaling pathways have also been well-dissected. Molecular mechanisms of salt tolerance or salt sensitivity is largely unknown in almonds. Expression analysis of genes involved in ion transport in almond tissue showed induction of multiple genes involved in Na+ and Cl- transport under salinity treatment, suggesting importance of both Na and Cl during salinity stress. The genes involved in Na+ transport were differentially expressed during salinity stress, compared to the control. For instance, NHX1 (a vacuolar sodium/proton antiporter) and SOS3 (SALT OVERLY SENSITIVE 3 that encodes a calcium sensor) were upregulated in leaves and on the other hand HKT1 (encodes a Na transporter) was induced in roots under salinity treatment. SOS3 is involved in Na+ exclusion from roots, NHX1 plays a role in sequestering Na+ in vacuole and HKT1 is critical for retrieving Na+ from xylem back into root to protect leaves from salt toxicity. Additionally, CLC-C (chloride channel C) and SLAH3 (encodes a slow-type anion channel) that are important for Cl- transport, were highly upregulated in salinity treatments in almond roots. These observations confirmed the role of multiple component traits in salt tolerance mechanism in almonds. As seen in other plants, multiple signaling path48 Progressive Crop Consultant
ways and various genes are expected to be involved in establishing ionic homeostasis during salt stress. Nevertheless, there are not many studies focusing on understanding the roles of organic solutes and enzymatic or non-enzymatic antioxidants in mitigating effects of salinity in almonds. Although some genes involved in ion exclusion, and ion sequestration in vacuoles have been identified in almonds, future studies are warranted to identify additional genes. In addition, different scions should also be compared for the genetic variation involved in ion homeostasis and scavenging reactive oxygen species (ROS) produced during salinity stress, which may provide some insights into sensitivity of almonds to salinity. Contrary to studying the importance of a few genes in salinity stress at a time, an RNA-seq based approach compares global changes in gene expression between the control and the salinity treatments. In addition to targeting genes already characterized in model plants this strategy can link different pathways involved in salinity tolerance and identify specific almond genes contributing toward salt tolerance.
Can Alternate Approaches Mitigate Harmful Effects of Salinity? Many additional strategies have been reported in plants that have been implicated to improve salt tolerance level in response to salt stress. For instance, application of certain microbes could improve salt tolerance level of plants. Arbuscular mycorrhizal fungi (AMF) are known to form symbiotic associations with many land plants that are considered to be valuable to plant growth. AMF helps host plants not only by providing essential minerals but also by impeding the translocation of toxic ions like sodium. The use of AMF in multiple plant species has shown enhanced growth, development and productivity under
September /October 2019
salt stress. Although, different Prunus rootstocks have been screened for mycorrhizal colonization, direct effect of AMF in mitigating salinity still need to be established. Application of plant growth promoting rhizobacteria (PGPR) is also known to improve salt tolerance in different plant species. However, there are no published reports describing the effect of PGPR in improving salt tolerance in almonds. Although, AMF and PGRP show a lot of promise, the potential of their application on almond rootstocks to mitigate salinity stress needs to be explored further, along with the economic feasibility of these approaches at the commercial level.
Future Perspectives One of the main consequences of the climate change is the length and frequency of drought periods experienced in certain parts of the world. California, the main almond producing region of the world, experienced a long drought period in the recent past. Drought leads to excessive groundwater pumping and use of alternative water resources with high salinity for irrigation. Based on the current trends, salinity problem is expected to intensify in next couple of decades. Currently, salinity screening is taking a backseat in almond rootstock breeding, which is expected to change in the near future. One of the approaches for the future almond breeding programs will require screening of wild genetic material for salinity tolerance. In addition to the other important root-
stock traits such as high vigor, nematode resistance, disease resistance, insect resistance, drought tolerance, salinity tolerance should also take central stage during rootstock breeding. Identification and isolation of the key almond genes involved in salinity tolerance will be critical. Functional validation of selected almond genes by complementation assay in a model plant like Arabidopsis may provide an initial proof of functional conservation of genes between these species. Characterization of genes will facilitate identification of specific mutations that are critical for salinity tolerance. The CRISPR/Cas9 system has a great potential in fixing the both type of genes that play positive or negative roles in salt tolerance in almonds. The CRISPR/ Cas9 is a precise, suitable, and efficient technology that has been used for genome editing in various crops such as rice, wheat, maize and sorghum. It is important to note that CRISPR/Cas9 modified crops are not considered as genetically modified organisms (GMO).
main consequences of the “Oneclimateof thechange is the length and fre-
quency of drought periods experienced in certain parts of the world.
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Acknowledgements:
Tim Peltzer Peltzer Farm Management
The study was funded by Almond Board of California.
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49
The Crop Consultant Conference
Full Menu of Workshops and Seminars BY CECILIA PARSONS | ASSOCIATE EDITOR
T
he inaugural Crop Consultant Conference (CCC) will be a gathering place for all who are dedicated to caring for California specialty crops. Pest Control Advisors (PCA), Certified Crop Advisors (CCA), applicators and agriculture retailers are all invited to participate in this two-day conference, September 26-27 in Visalia. This event at the Visalia Convention Center packs a full menu of educational workshops and seminars, professional networking opportunities plus multiple hours of PCA and CCA credits into 24 hours. The program begins at 1 p.m. on Thursday and concludes after lunch and a final speaker, at 1 p.m. on Friday. The workshop and seminar topics at the CCC have been chosen to help all crop advisors keep informed about new regulations, pest and disease control and
50 Progressive Crop Consultant
management updates, label information and new technologies. In addition to the educational component, this conference will feature an early evening mixer and networking opportunities to be followed by a full gala dinner and entertainment.
Why Attend? “Where else can a PCA or CCA get that many hours of credit, receive useful information plus meals and entertainment and not have to drive long distances?” says Jason Scott, publisher of West Coast Nut, Progressive Crop Consultant and Organic Farmer magazines and host of this conference. “This event is right in their back yard, where specialty crops addressed in this conference, are grown. It is designed to present the ‘big picture’ of specialty crop production, innovative technology, regulations,
September /October 2019
and challenges here in California,” Scott added.
Citrus Greg Douhan University of California Cooperative Extension (UCCE) area citrus advisor for Tulare, Fresno and Madera counties, said the conference will be a valuable forum to communicate important research and information regarding many aspects of various
crops grown in California. Agriculture industry personnel, PCAs, CCAs, and so on and so forth, benefit from these meetings tremendously to keep abreast of the latest challenges that face California Agricultural producers.
“
Douhan, whose territory includes a major portion of California’s citrus belt, will be one of the featured conference speakers and will present current information on HLB and Asian Citrus Psyllid management.
Aerial Drone Technology A presentation on aerial drone technology is also expected to drive attendance. Chris Lawson, Business Development Manager for Aerobotics, will speak on optimizing integrated pest management (IPM) and nutrient management using drones. Agronomist Nick Canata with Ingleby USA/Eriksson LLC of Visalia reports that the CCC agenda looks interesting, especially the drone technology presen-
This event is right in their back yard, where specialty crops addressed in this conference are grown. It is designed to present the ‘big picture’ of specialty crop production, the new technology, regulations and challenges here in California
”
Continued on Page 52
September 26th-27th Visalia Convention Center See pages 54-55 for more details or visit progressivecrop.com/conference/PCC919 September /October 2019
www.progressivecrop.com
51
Botrysphaeria on walnut. Photo courtesy of Cecilia Parsons.
Continued from Page 51 tation. His company, he added, is presently using aerial flyovers to obtain irrigation information.
Mating Disruption Crop advisors who are evaluating their mating disruption choices will hear a panel of experts that includes United States Department of Agriculture (USDA) researcher Chuck Burks, Dani Casado, chemical ecologist with Suterra and Peter McGhee, research entomologist with Pacific BioControl Corp. This panel will evaluate mating disruption as part of an IPM program.
Checking for NOW Larvae. Photo courtesy of Cecilia Parsons.
dal, West Coast regional manager with Helm AGRO US.
Trade Show and Mixer The conference mixer and trade show begin at 5 p.m. Thursday, and dinner will be served at 6 p.m. The keynote speech will be Trécé on NOW Monitoring and Management–Current and Future Trends. At 7, Las Vegas entertainer and illusionist Jason Bird will perform. One of the most innovative and prolific minds in the magic industry, Bird continuously advances the boundaries of his craft while making connections with his audiences. Bird will also perform small group illusions during the trade show/mixer.
Soils
Friday
Thursday’s program starts on the ground with sustainability specialist Richard Kreps who will explain how to get the most out or your soils. Kreps, with Ultagro, said making soils work at an optimal level requires a quite a bit of dedication. Attacking it from all sides: amending, nutrition applications, increasing organic matter, biology and proper irrigation require a lot of coordination. The upside is orchard longevity, higher returns with less disease and pest pressure.
Paraquat Guidelines Thursday’s education agenda ends with new EPA guidelines for 2020 for Paraquat closed transfer system. Speaker will be Charlene Be-
52 Progressive Crop Consultant
Friday morning’s agenda kicks off at 7 a.m. with breakfast and a presentation by Patty Cardoso of Gar Tootelian on keeping growers compliant with local and state regulations. The trade show opens at 7:30. Friday’s topics include A New Approach to IPM by Surendra Dara, UCCE entomologist; a panel discussion major crop pests affecting specialty crops; and an update on labels. To register for this event and see a complete agenda, go to progressivecrop.com/conference/PCC919
Comments about this article? We want to hear from you. Feel free to email us at article@jcsmarketinginc.com
September /October 2019
September 26th-27th Visalia Convention Center Pre-Register at progressivecrop.com/conference/PCC919
Find the full agenda on page 55 or online at
progressivecrop.com/agenda September /October 2019
www.progressivecrop.com
53
f PCA Credit Bringing
f CCA Credit
Crop Consultants
7.5
Together
CCA Hours:
8:00AM
8.5
ONLY $100
Label Update
per person
CE Credits: 50 Minutes; L & R
Workshops and Seminars Mixer & Networking Meals Included
powered by: 8:50AM
Evaluation of Mating Disruption as Part of an IPM Program
CE Credits: 40 Minutes; Other
Powered by:
mpliance for
(Breakfast, Lunch and Snacks)
10:30AM
Chuck Burks USDA Dani Casado, Ph.D. in Applied Chemical Ecology, Suterra Peter McGhee, Ph.D., Research Entomologist
ove and wer – pliant
Other
PCA Hours:
Full Gala Dinner Live Entertainment
Trade Show
CE Credits: 30 Minutes; Other
(Jason Bird, Magician and Illusionist)
Over 60 Exhibits
11:00AM
Prizes
Panel—Top Insects Plaguing California Crops— co-hOSTEDSpecialty By: BMSB, Mealy Bugs/NOW Spotted Wing Drosophila
September 26th 1:00PM - 9:00PM September 27th 7:00AM - 1:15PM
David Haviland (Mealy Bugs/NOW) UC Cooperative Extension, Kern County, Kent Daane (SWD) Cooperative Extension Specialist, UC Berkeley, Jhalendra Rijal (BMSB) UCCE IPM Advisor for northern San Joaquin Valley
CE Credits: 60 Minutes; Other PRE-REGISTER TO BE ENTERED TO WIN A TRAEGER PRO 12:00PM SERIES 780 PELLET GRILL
9:30AM
Regulatory Impacts on September 26th-27th California Crop Protection
Visalia Convention Center Industry
Lunch
12:15PM
303 E. Acequia Ave. Visalia, CA 93291 A New Approach to IPM Western Growers
FOR MORE DETAILS OR TO PRE-REGISTER ONLINE VISIT Surendra Dara, Entomology and Biologicals Advi-
CE Credits: 30 Minutes; L & R sor, University of California Cooperative Extension progressivecrop.com/conference/PCC919
CE Credits: 30 Minutes; Other OVER $1,000 VALUE
10:00AM
1:00PM
Break
Dinner Sponsor Mixer Co-Sponsor
Adjourn
Agenda Sponsor
Indoor Sponsor
Registration Sponsor
Coffee Sponsor Traeger Grill Sponsor
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54 Progressive Crop Consultant
Indoor Sponsor
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September /October 2019
Indoor Sponsor
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Mixer/Trade Show
CE Credits: 30 Minutes; Other
1:00PM
6:00PM
Registration
2:00PM
Getting the Most out of Your Soil Richard Kreps, CCA
Dinner
6:30PM
8:50AM NOW Monitoring and Evaluation of Mating Management – Current and Future Trends Disruption as Part of an IPM Program Brent Short, Regional Technical Representative, Trécé, Inc.
2:30PM
How to Optimize IPM and Nutrient Management using Aerial Drone Technology
AGENDA
5:00PM
Thursday September 26
CE Credits: 30 Minutes; Other
Chuck Burks USDA Dani Casado, Ph.D. in Applied Chemical Ecology, Suterra Peter McGhee, Ph.D., Research Entomologist
CE Credits: 30 Minutes; Other
9:30AM
Chris Lawson, Business Development Manager, Aerobotics
CE Credits: 30 Minutes; Other
Update on the Sterile Insect Program for NOW
3:00PM
Managing Botrytis in a Challenging Year
Houston Wilson, Asst. Coop. Extension Specialist, Kearney Ag. Center, Dept. Entomology, UC Riverside
CE Credits: 30 Minutes; Other
Gabriel Torres, UCCE Farm Advisor, Tulare County
CE Credits: 30 Minutes; Other
3:30PM
The Latest in HLB and Asian Citrus Psyllid Management Greg Douhan, UCCE Area Citrus Advisor for Tulare, Fresno, and Madera Counties
CE Credits: 30 Minutes; Other
4:00PM
Navigating Fungal Diseases Themis Michailides , Professor and Plant Pathologist UC Davis
CE Credits: 30 Minutes; Other
4:30PM
Paraquat Closed Transfer System (New EPA Guidelines for 2020) Charlene Bedal, West Coast Regional Manager, HELM AGRO US
CE Credits: 30 Minutes; L & R
10:00AM
7:00PM Jason Bird
Trade Show Break CE Credits: 30 Minutes; Other
Magician and Illusionist Jason Bird will perform small group illusions during the trade show / mixer from 5-6PM
Friday September 27
7:00AM
Breakfast / Going Above and Beyond for Your Grower – Keeping them Compliant
11:00AM
Panel—Top Insects Plaguing California Specialty Crops— BMSB, Mealy Bugs, NOW, Spotted Wing Drosophila David Haviland (Mealy Bugs/NOW) UC Cooperative Extension, Kern County, Kent Daane (SWD) Cooperative Extension Specialist, UC Berkeley, Jhalendra Rijal (BMSB) UCCE IPM Advisor for northern San Joaquin Valley
CE Credits: 60 Minutes; Other
12:00PM
Patty Cardoso, Director of Grower Compliance for Gar Tootelian, Inc.
Lunch
12:20PM
7:30AM
Label Update
Trade Show
Earth-Sol
12:30PM
8:00AM
A New Approach to IPM
Label Update Plant Food Systems, Inc., Trécé, Inc., Helm, Suterra, & Sym-Agro, Inc.
CE Credits: 60 Minutes; L & R
Surendra Dara, Entomology and Biologicals Advisor, University of California Cooperative Extension
CE Credits: 30 Minutes; Other
1:15PM Adjourn
September /October 2019
www.progressivecrop.com
55
PUT YOUR ALMONDS TO BED WITH THE RIGHT NUTRITION.
HIGH PHOS™
Apply High Phos as Part of Your Post Harvest Fertilizer Program. A balanced formulation of essential nutrients containing organic and amino acids to stabilize the nutrients and facilitate their chelation, uptake, translocation and use.
56 Progressive Crop Consultant
September /October 2019
For more information visit wrtag.com, or contact Joseph Witzke at (209) 720-8040