- (Focus Area) Agriculture
- Author: Kathy Keatley Garvey
But agriculturists and scientists have.
The spotted-wing drosophila (SWD), Drosophila suzukii, is an agricultural pest that is super tiny.
It's approximately 2 to 4 millimeters in length with a wingspan of 5 to 6.5 millimeters. One millimeter is approximately 0.039 inches. There are 25.4 millimeters in 1 inch. So, the adult is about the size of a grain of sand, which can measure 0.5 to 2 mm in diameter.
SWD, native to southeast Asia and first discovered in California in 2008, lays its eggs in such soft-skinned, ripening fruits as strawberries, raspberries, cherries, blueberries, peaches, nectarines, apricot and grape.
In 2008, the first year of its discovery in California, the economic loss attributed to this pest amounted to $500 million. Latest statistics from 2015 indicate a $700 million national economic loss.
Lead author of the paper, “Transcriptome Analysis of Drosophila suzukii Reveals Molecular Mechanisms Conferring Pyrethroid and Spinosad Resistance,” is Christine Tabuloc, then a doctoral candidate and now a postdoctoral researcher working under the mentorship of Professors Chiu and Zalom.
"In this work, we leveraged high throughput sequencing to identify biomarkers of insecticide resistance in D. suzukii,” Tabuloc explained. “We found that different genes are responsible for resistance to different chemicals. Specifically, we found that genes involved in metabolism are highly expressed in flies resistant to pyrethroid insecticides. We also observed evidence of two different mechanisms of resistance in 2 lines generated from a single spinosad-resistant population. We found an increased expression of metabolic genes in one line and increased expression of cuticular genes in the other.”
Tabuloc added that “our work has enabled for the detection of resistance in California populations, and we are currently doing a nationwide screening to determine whether resistance is now present in other states. Currently, we are working with the Zalom lab to use the results of our assays to try and combat resistance. There are experiments in progress trying to increase the efficacy of insecticides by blocking some of the genes involved in resistance, such that the enzymes encoded by those genes have decreased function."
A giant in the entomological world, Zalom directed the UC Statewide Integrated Pest Management Program for 16 years. He is an Honorary Member of the Entomological Society of America (ESA), the highest ESA honor, and he served as its president in 2014.
“This work not only represents good science; it has very practical implications," Zalom said. He and Tabuloc presented results of the work at a special berry grower seminar on insecticide resistance organized by UC Agriculture and Natural Resources (UC ANR) Farm Advisor Mark Bolda, strawberry and caneberry farm advisor in Santa Cruz, Monterey and San Benito counties, Mark Bolda in Watsonville.
"The presentations were extremely well-received," Zalom noted. "The original program was targeted for about 1.5 hours, but the meeting extended to over three hours due to the extent of questions and great discussion that followed. Growers and their consultants are hungry for new information that they find interesting and potentially useful, and this work was clearly of interest to them.”
Said Bolda: “The research was top shelf and the need, of course, is very great. Some of the information that Frank and Christine presented has been put into immediate use in the industry.”
What most people don't know is that Bolda was the first to discover the pest in North America. That was in 2008.
"He asked me to come down to look at it and the problem...we weren't able to get an actual species identification until 2009!" Zalom said.
As the pest continues to spread throughout much of the country, anxious growers are worried about its increased resistance to pesticides. The UC Davis research team is alleviating that worry.
- Author: Ben A Faber
Avocado Irrigation Workshop
Avocado Irrigation Workshop
October 16 (Wednesday), 2024
2:00 – 5:00 P.M.
UC Cooperative Extension Ventura County (California Room)
669 County Square Dr, Ventura, CA 93003
Workshop registration link: Registration
2:00 - 5:00 p.m. |
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Break: 10 mins. |
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3:45 |
Using Soil Moisture Sensor to Optimize Irrigation – Andre Biscaro, UCCE Irrigation and Water Resources Advisor, Ventura County |
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4:15 |
Water Distribution Uniformity Management in Orchards – Jamie Whiteford, Ventura County Resource Conservation District |
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4:45 |
Mission Produce TM: Resources and Updates - Danny Klittich, Mission Produce |
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5:00 |
ADJOURN |
For more information about the workshop, please contact
Ali Montazar, amontazar@ucanr.edu, or Ben Faber, bafaber@ucanr.edu.
CEU CREDITS: CCA (2.5 hrs.)
VCAILG (2.5 hrs.)
- Author: Ben A Faber
Informational Videos Covering Fertilizer Application through Irrigation Water
Now Available in English and Spanish
Nicole Nunes FREP Grant Program
Through a grant from the Fertilizer Research and Education Program (FREP), Cal Poly's Irrigation Training and Research Center (ITRC) has developed a series of informational videos covering chemicals, application hardware, techniques, and timing of fertilizer application through irrigation water.
The videos are based on information provided in the Fertigation book developed by ITRC and updated in 2019. The Fertigation book is also available in English and Spanish and can be downloaded for free from the ITRC website: https://www.itrc.org/books/index.html
The 22 informational videos are available on YouTube or through the ITRC website and cover the following topics:
- Overview
- Basic Fertilizer Chemistry and Vocabulary
- Nitrogen and the Environment
- Basic Soil Principles
- Crop Fertilizer Requirements
- Testing of Plants Soil and Water
- Fertilizer Labels Characteristics and Usage
- Nitrogen Conversions
- Volatilization of Ammonia from Irrigation Water
- Irrigation System Uniformity and Efficiency
- Safety
- Purging Media Tanks of Chemicals
- Calibration, Titration, and Travel Time
- Varying Venturi Injection Rates
- Chemigation for Soil Infiltration Problems
- SO2 Generators (Sulfur Burners)
- Chemigation for Drip System Maintenance
- Incompatibility of Different Fertilizers
- Proportional Injection
- Fertilizer and Chemical Injection Devices
- Calibration of Fertilizer and Chemical Injectors
More Fertigation Resources Coming Soon
ITRC is developing the informational video series into a Fertigation Certificate Program available to the irrigation and fertilizer industry. The videos will be coupled with information and suggested readings from the Fertigation book to create a comprehensive online course. Course participation will be verified with an exam on the presented materials and successful participants will receive a certificate of completion.
Stay tuned for more information regarding the availability of the certification program.
To learn more about this project and other current and completed FREP projects please visit: https://www.cdfa.ca.gov/is/ffldrs/frep/Research.html
- Author: Michael D Cahn
Introduction
Traditional winter cereal cover crops planted in the Salinas valley have many potential benefits including, scavenging nitrate in the soil profile, increasing organic matter in the soil, and protecting the soil from erosion during storm events. However, when grown for 3 to 4 months during the late fall and winter, cereal rye, triticale, or barley can accumulate 5 to 6 tons of dry matter biomass that must be incorporated into the soil before planting a spring vegetable crop. Tilling in a high amount of cover crop biomass can be disruptive to spring planting schedules. Consequently, only a small fraction of the vegetable ground in the Salinas valley is cover cropped each year.
Previous studies demonstrated alternative strategies can limit the biomass growth of these cereal cover crop species so that they can more easily be tilled into the soil, and therefore less disruptive to spring planting schedules. After fall land preparation, the cereal cover crops are seeded into listed beds and/or in the furrow bottoms. After they become established they can reduce runoff and protect the soil from erosion during early winter storm events. Before the cover crops grow too big, they are terminated with an herbicide to limit the amount of above ground biomass that needs to be incorporated in the spring. For organic systems, planting a mustard cover crop on listed beds or furrows which can be terminated mechanically by mowing is another strategy to limit biomass. A good target for these low biomass cover crops is between 0.5 to 1 ton of dry matter per acre by the date of termination. Once terminated, the biomass begins to decompose. However, the residue on the surface continues to protect the soil from erosion and can significantly increase infiltration from rain events. This helps to leach accumulated salts in the soil as well as recharge groundwater aquifers. The remaining decomposed residue can easily be incorporated into the soil during bed preparation in the spring.
One risk of this low biomass approach is accessing fields during the winter to terminate the cover crop. If soil conditions are too wet or if there is not enough available labor, it may be difficult to fit in a spray application or to run a flail mower. This termination step also increases the cost of managing the cover crop. A possible solution is to use species that grow slowly during the winter when temperatures are cold. Sudangrass and sorghum-sudangrass hybrid are warm season adapted species that could be used in this low biomass approach to managing winter cover crops.
Field trial with warm season adapted cover crop species
A field trial was conducted with sudangrass and sorghum-sudangrass in the 2023-2024 winter to evaluate biomass growth, and the effect on storm water runoff and soil erosion compared to bare-fallow plots. The site was located on an Arroyo Seco gravelly loam soil with a slope of more than 5%. Plots measuring 1050 ft in length by four 40-inch wide peaked beds were planted with either sudangrass, sorghum sudangrass hybrid, or left bare fallow. Treatments were replicated 4 times. The cover crops were seeded at 60 to 80 lbs/acre on October 4th and were subsequently sprinkle-irrigated several times. Total water applied for establishment was 2.6 inches. One application of the herbicide Bromoxnil (Maestro) was applied about 45 days after planting to kill emerged broadleaf weeds.
Results
Above ground biomass, N uptake, and carbon accumulation
Both cover crops had limited biomass growth, accumulating only 0.35 to 0.5 tons/acre of dry matter by early January and less than 1 ton/acre by mid March (Table 1). Growth was set back by cold conditions that occurred from mid November through early January, occasionally reaching freezing temperatures which caused damage to leaves (Fig. 1). However, the freezing temperatures lasted only a few hours and were not severe enough to kill the cover crops (Fig. 2). By March 13th the cover crops had taken up 45 to 55 lbs N/acre and had a carbon to nitrogen ratio of 15. The C:N ratio of 15 would suggest that after soil incorporation the residue would decompose rather quickly and release N for the following vegetable crop.
Runoff, rainfall infiltration, and control of soil erosion
Total rainfall measured at the trial site was 10.2 inches for the winter season. The most intense period of rainfall occurred in late January and early February which resulted in several runoff events (Fig. 3). During this period about 50% of the rainfall in the bare fallow plots was lost as runoff compared to 15% lost as runoff in the cover crop plots (Fig.4). Over the entire winter season, runoff was reduced by an average of 70% under the cover cropped plots compared to the bare fallow plots, and significantly more rainfall was infiltrated into the ground in the cover cropped plots. In addition, suspended sediment concentration was 90% and 77% less in the sudangrass and sorghum-sudangrass cover crop plots, respectively, compared to the bare plots. Turbidity, total P, and total N concentration in the runoff were also reduced under the cover crop plots compared to the bare fallow plots (Table 2).
Seasonal soil erosion losses could be calculated based on the volume of the runoff and sediment concentration in the runoff. The total loss of sediment averaged more than 3500 lbs per acre in the bare fallow plots during the winter, while erosion losses were reduced by 96% to 98% in the sorghum-sudangrass and sudangrass plots (Fig. 5). Total N losses were reduced by 83% to 86% in the cover crop plots compared to the fallow plots, and total P losses were reduce by 81% to 85% in the cover cropped plots compared to the bare fallow plots.
Conclusions
The use of warm season species such as sudangrass and sorghum-sudangrass hybrids as winter cover crops provides several advantages compared to planting cereal cover crops. The biomass growth through the winter is self-limiting due to the cold conditions that typically occur in the Salinas Valley. Because the final biomass would likely be less than 1 ton per acre, these species can be planted on listed beds in the fall rather than on flat ground. This means that in the spring, the remaining cover crop can be lillistoned into the peaked beds a few weeks before final bedshaping and planting. Cover crops planted on flat ground and have high amounts of biomass usually require many tillage passes to prepare ground for planting. Despite, having less biomass than traditional winter cereal species, sudangrass and sorghum-sudangrass hybrid cover crops provided excellent erosion control compared to leaving the ground bare, and increased infiltration of rainfall during storm events. Also these species may be able to scavenge significant amounts of nitrogen from the soil which can limit nitrate leaching during the winter months.
On the east-side of the Salinas Valley groundwater levels have been in the decline for several decades. Infiltrating as much rainfall as possible during the winter using strategies such as low biomass cover crops could potentially help recharge the aquifer in this region. We plan to conduct a second year of field trials with these warm season species to continue evaluating this approach to managing winter cover crops in vegetable systems.
Acknowledgments
This project was funded by the California Leafy Greens Research Board.
- Author: Kathy Keatley Garvey
The seminars begin Monday afternoon, Sept. 30 and continue every Monday through Dec. 2.
Nematologist Amanda Hodson, assistant professor of soil ecology and pest management, is coordinating the seminars. All, except one, will be held in Briggs Hall. All, but one, will be on Zoom.
The Zoom link:
https://ucdavis.zoom.us/j/95882849672.
Michael Hoffmann, professor emeritus, Cornell University, will deliver the Thomas and Nina Leigh Distinguished Alumni Award Seminar in the Putah Creek Lodge at 4 p.m. on Oct. 14. (See below)
The list of seminars:
Monday, Sept. 30, 4:10 to 5 p.m., 122 Briggs
Kyle Wickings
Department of Entomology, Cornell University
Title: “Composition and Function of Soil Invertebrate Communities in Residential Greenspaces”
Monday, Oct. 7, 4:10 to 5 p.m., 122 Briggs
Juliana Rangel Posada
Professor of Apiculture, Department of Entomology, Texas A&M University
Title: “Don't Compromise: Food Lipid Content Shapes Protein-Lipid Regulation in Honey Bee (Apis mellifera) Nurses”
Monday, Oct. 14, 4 p.m. to 7 p.m. Thomas and Nina Leigh Distinguished Alumni Award Seminar
Michael Hoffmann
Professor Emeritus, Cornell University
Title: “Our Changing Menu: Using the Power of Food to Confront Climate Change”
This will take place beginning at 4 p.m. in the Putah Creek Lodge and will include a social, lecture and dinner. Reservations closed. (See more)
Monday, Oct. 21, 4:10 to 5 p.m.,122 Briggs
Andrew Corbett
Research Affiliate, UC Davis Department of Entomology and Nematology (formerly with the lab of UC Davis distinguished professor Jay Rosenheim, now emeritus)
Title: "In Silico Experiments with the Effect of Natural Habitats on Biological Control in Agricultural Landscapes."
Monday, Oct. 28, 4:10 to 5 p.m., 122 Briggs
Jolene Saldivar
UC Davis Chancellor's Postdoctoral Fellow, lab of Professor Louie Yang
Title: "Disturbance in Coastal Sage Scrub and the Implications for Migratory Butterflies”
Monday, Nov. 4, 4:10 to 5 p.m., 122 Briggs
Eliza Litsey (exit seminar)
Litsey, a former graduate student in the honey bee lab of Elina Niño, UC Davis Department of Entomology, received her master's degree in entomology in June 2024 and is now a laboratory technician at the lab of research entomologist Julia Fine, USDA/ARS, Davis. Litzey also holds a bachelor's degree from UC Davis.)
Monday, Nov. 18, 122 Briggs (in-person only; will not on Zoom)
Andre Custodio Franco
Assistant Professor, Indiana University Bloomington
Title: "Deciphering the Soil Macrobiome: Belowground Communities Driving Ecosystem Responses to Global Change”
Monday, Nov. 25, 4:10 to 5 p.m., 122 Briggs
Christine Sprunger
Associate Professor of Soil Health at Michigan State University
Title: "Nematodes as Bioindicators of Soil Health and Climate Resiliency”
Monday, Dec. 2, 4:10 to 5 p.m., 122 Briggs
Inga Zasada
Research Plant Pathologist, USDA-ARS
Title: "How an Applied Nematolgist Uses Genomic Tools to Address Plant-Parasitic Nematode Research”
For more information, contact Hodson at akhodson@ucdavis.edu