Crop Protection Research Institute The Benefits of Insecticide Use: Sunflowers Lygus Bug Lygus Bug Damage, Kernel Brown Spot Spraying Sunflowers Banded Sunflower Moth Damage March 2009 Leonard Gianessi CropLife Foundation 1156 15th Street, NW #400 Washington, DC 20005 Phone 202-296-1585 www.croplifefoundation.org Fax 202-463-0474
Key Points Growers of sunflower seeds who do not spray insecticides have insect damage over 10% which renders the crop unfit for human consumption. Lygus bugs were not a problem in sunflowers until 1998. Lygus bugs damage sunflowers with digestive enzymes resulting in a spot (kernel brown spot) on the seed. Banded sunflower moth can damage up to 40% of the sunflower seeds in a field. Technical Summary North Dakota, South Dakota and Minnesota account for two-thirds of U.S. acreage of commercial sunflowers. 1.8 million acres of sunflowers produce an annual crop valued at $319 million. 20% of the crop goes into the non-oil (confection) market for use in foods while 80% goes into processing for cooking oils. Approximately 209,000 acres are grown for confection food uses, producing a volume of 273 million pounds valued at $46 million. The sunflower is the only row crop in North America that coexists with its native ancestors [4]. Although sunflowers are native to North America, commercial sunflower production is relatively new in the U.S. Archeological evidence documents sunflower use by native Americans with the first cultivation around 3000 B.C. Native Americans used sunflower seed as a food before the cultivation of corn. Spanish explorers collected sunflower in North America and by 1580 it was a common garden flower in Spain [1]. It spread along trade routes to Europe, Egypt, India, China and Russia. Peter the Great is credited with the introduction of the sunflower into Russia in the 18 th century as an ornamental crop [2]. By 1769 it was being cultivated for oil. The Russian Orthodox Church, through strict Lenten fast regulations, may have inadvertently been responsible for encouraging the rapid adoption of sunflower oil as an edible oil. Lenten regulations were formulated before the introduction of sunflowers and thus parishioners rapidly adopted sunflower oil as the oil without sin for Lenten cooking [2]. Cultivated sunflowers returned to the Americas from Russia during the late 1800s and the seeds were primarily produced as scratch food for poultry. Acreage remained small below 80,000 acres through the mid 1960s. The great expansion in sunflower acres in the Northern Great Plains took place in the 1970s fueled by the rapid expansion in world oilseed demand and the introduction of a high-oil content sunflower variety from the USSR. Oilseed sunflower seeds are usually smaller and are black in color with a thin hull that adheres to the kernel [3]. Non-oil seed or confectionery sunflowers have striped hulls, are larger, and have thick hulls which are loosely attached, allowing for a more complete dehulling. The confectionery sunflowers sell for about 60% more than the oil varieties. When extensive commercial planting of sunflower began in the 1970s, many of the insects which evolved on native perennial sunflower species transferred to the cultivated
crop. The density of cultivated sunflowers is normally 37,000-60,000 plants per hectare as opposed to the scattered spacing of the native sunflower plants. The high density monocultures have become excellent hosts for some native insect pests which have adapted to cultivated sunflower and have become economic pests [4]. The high density of hosts in cultivated sunflower fields has resulted in increased populations of these insect pests by reducing the time required to identify suitable hosts [2]. The sunflower, because it is derived from a native ancestor, has parasitoids, predators and pathogens that moved along with the pest insects into cultivated plantings. However, the monocultural production methods, the increases in hectarage, and the expansion of the crop into new areas have led to insect population explosions that natural enemies have been unable to maintain below economic thresholds [2]. A set of trade standards have been developed for nonoil sunflower kernels which stipulate that there should be no more than 2% insect damage [20]. Pesticide use surveys for sunflower acreages in the northern Great Plains indicate that 33% of the acres are treated with insecticides [5]. It is believed that all of the confectionery acres and 50% of the oilseed acres are treated. The NDSU budget for confectionery sunflowers includes a spray targeted at head feeding insects: red seed weevil, lygus bug and banded sunflower moth [6]. The NDSU Extension Service recommends that sunflowers grown for the confectionery market be treated a minimum of two times for these three insect pests [7]. Growers who do not spray at all invariably have insect damage above 10% which renders the entire crop unfit for human consumption and may render it unusable even for bird feed due to the insect holes in the seed [21]. For oilseed sunflowers, NDSU recommends a spray for the banded sunflower moth when two moths are found for every 100 plants inspected. For the red sunflower seed weevil, NDSU recommends that oilseed growers determine the threshold for spraying based on the prices of sunflowers and insecticides and the number of sunflower plants per acre. Based on recent prices, spray thresholds for red sunflower seed weevil have been 3-8 weevils per head for oilseed [7]. There is a small acreage of organic sunflowers in North Dakota, South Dakota, and Minnesota. Most of these organic acres are for oil production. The world market for organic sunflower seeds for confectionary foods is dominated by China [22]. Two applications of insecticides for red seed weevil, lygus bug, and banded moth cost approximately $22/A including application costs, which represents about 12% of the cost of growing confection sunflowers [6]. Without insecticides sprays, it is assumed that the sunflower seeds could not be sold in the confection market but would instead be sold for oil with a loss of 60% in value.
Red Sunflower Seed Weevil The red sunflower seed weevils deposit eggs in sunflower seeds and larvae feed in the developing sunflower kernels destroying a portion of the kernel and reducing oil content. Red sunflower weevils are unable to lay eggs prior to pollen development because they require a pollen meal before the eggs can mature. The need for pollen indicates the close association between plant and insect. Eggs are deposited through the hull and are appressed to the developing kernel. A single egg is laid per seed. The larvae make an exit hole and exit the seeds in late summer and overwinter in the soil, emerging as adults the following summer. There is one generation per year. While some seeds may be totally consumed, research reveals that most seeds are only partially fed upon. This results in difficulty in separating undamaged from weevil-damaged seed. A single female red sunflower seed weevil lays enough eggs to damage an average of 20 seeds. The mean weight loss of damaged vs. undamaged seeds was 31% with a 25% reduction in oil content [19]. Population levels of natural enemies are insufficient to control the red sunflower seed weevil. Parasites attack about 5% of the larvae in the seeds and there is a 3% predation rate of larvae and pupae in the soil [13]. Insecticide treatments reduced seed weevil damage by 93-96% [18]. The number of larvae per head was reduced from 108 to less than 1[19]. Research has been conducted with trap crops where early maturing sunflowers were planted in the margins around commercial fields. The margins flowered earlier than the field interior and acted as an attractant for the red sunflower seed weevil which were killed with an insecticide in the trap crop before the interior field began to bloom. This reduced the need to spray the entire field with insecticides [23]. Banded Sunflower Moth During the development of the sunflower crop in the northern plains in the 1970s, the banded sunflower moth was reported to be a noneconomic problem requiring no management practices. However, since the early 1980s, cultivated sunflower fields in North Dakota, South Dakota, and Minnesota have frequently had economic damage from the insect [17]. In 1983 some North Dakota research fields experienced about 40% seed damage by the banded sunflower moth resulting in yield losses exceeding 534 lbs/a of seed [12]. Adults begin to emerge from the soil about mid-july and are present in the field until mid-august. The leaves of sunflower contain a combination of chemicals, volatiles, and moisture that stimulates egglaying by the banded sunflower moth [16]. Larvae penetrate and consume the contents of seeds. After feeding to maturity, larvae make an exit hole and drop to the ground and spin cocoons in the soil to overwinter. Yield loss due to larval feeding can be attributed to a reduction in seed number, seed weight, and oil content. Research determined that each larva consumes 6-7 seeds with an average of 25-40 larvae per sunflower head [14]. Research with insecticides to control
the banded sunflower moth resulted in significantly greater total number of seeds per head (+200) and total yield (+445 lbs/a) compared with untreated sunflower [15]. Lygus Bug Kernel brown spot was observed for the first time in 1998 on dehulled confection sunflowers grown in north central states. The spot is superficial with little or no tissue degradation. There is usually no sign on the exterior of the hull that the kernel has brown spot. Processors are allowed only 0.5% brown spot damage in their finished product [8]. Farmers who produce sunflower seeds for the confection market end up selling the seeds for birdseed at low prices if more than 0.5% have kernel brown spot [9]. Feeding by the lygus bug was identified as the source of kernel brown spot. Though lygus bugs don t eat much (probably not enough to reduce sunflower crop yields), they inject plant tissues, such as the developing seeds, with digestive enzymes and extract nutrients with their pointed mouthparts [9]. Lygus insert their mouthparts into the host, start a pre-digestion pump to inject saliva and start digestion, then suck the fluids into the stomach. The saliva is toxic to plant tissue, helping reduce the plant fluid into a digestible source. The result is a spot (Kernel Brown Spot) resulting from tissue death at the feeding site. The brown spot can also result in a bitter taste to the seeds [10]. Research indicated 8 to 20 seeds were damaged by each adult lygus bug. Based on these figures, confection sunflower heads of approximately 800 seeds per head would sustain 1 to 2.5% damage from each lygus bug, a figure that exceeds the 0.5% level of damage allowed before dockage [10]. The sharp increase in broadleaf crops in the past few years may be a key reason why the lygus population is increasing. Sunflower is not a preferred crop for lygus. Since lygus are mobile with a wide crop preference, when a field infested with lygus is harvested, the bugs will move into the next closest food source [11]. Since sunflower blooms late in the summer relative to other crops, lygus may move from canola, alfalfa, and other crops harvested in late July to sunflower fields starting to bloom in August [11]. Research has shown that lygus are controlled by the same insecticide sprays that control banded sunflower moth and seed weevils. In four spray trials, kernel brown spot was reduced from 1.8% to 0.17% with insecticide sprays [8]. References 1. McCormick, Ian, Cecil W. Davison, and Roger L. Hoskin, The U.S. Sunflower Industry, Commodity Economics Division, Economic Research Service, USDA, Agricultural Economic Report No. 663, October 1992. 2. Charlet, Laurence D., Dennis D. Kopp, and Christian Y. Oseto, Sunflowers: Their History and Associated Insect Community in the Northern Great Plains, Bulletin of the ESA, Summer 1987. 3. Crop Profile for Sunflower in North Dakota, North Dakota State University Extension Service, September 1999.
4. Charlet, Larry D. and Gary J. Brewer, Sunflower Insect Pest Management in North America, University of Minnesota Radcliffe s IPM World Textbook, Available at http://ipmworld.umn.edu.chapters/charlet2.htm. 5. USDA, Agricultural Chemical Usage Field Crops: 1999, National Agricultural Statistics Service, May 2000. 6. Swenson, Andrew and Ron Haugen, Projected 2006 Crop Budgets South Central North Dakota, Farm Management Planning Guide, North Dakota State University Extension Service, December 2005. 7. Field Crop Insect Management Guide, NDSU Extension Service Report E-1143. 8. Confections Seeing Spots, The Sunflower, January 2001. 9. Charlet, Laurence D. and Thomas J. Gulya, Zeroing in on a Confectionary Sunflower Blemish, Agricultural Research, February 2002. 10. Charlet, Larry D., Lygus Bug and Kernel Brown Spot in Confectionary Sunflower: Determination of Economic Injury Levels and Susceptible Growth Stages, and Control Potential With Insecticides, in Proceedings Sunflower Research Workshop, 2002. 11. Charlet, Larry, Tom Gulya, and Cheryl Biller, Kernel Brown Spot on Confection Sunflowers: Disease or Insect Induced Problem?, in Proceedings Sunflower Research Workshop, 2001. 12. Rogers, C.E., Insect Pests and Strategies for Their Management in Cultivated Sunflower, Field Crops Research, 30: 301-332, 1992. 13. Charlet, Laurence D., Gary J. Brewer, and Bernard A Franzmann, Sunflower Insects, in A.A. Schneiter [ed.], Sunflower Technology and Production, Agron. Ser. 35. Am. Soc. Agron. Madison, WI. 14. Charlet, Laurence D. and Theresa A. Gross, Bionomics and Seasonal Abundance of the Banded Sunflower Moth (Lepidoptera: Cochylidae) on Cultivated Sunflower in the Northern Great Plains, Journal of Economic Entomology, 83(1): 135-141, 1990. 15. Charlet, Laurence D. and John D. Busacca, Insecticidal Control of Banded Sunflower Moth, Cochylis hospes (Lepidoptera: Cochylidae), Larvae at Different Sunflower Growth Stages and Dates of Planting in North Dakota, Journal of Economic Entomology, 79: 648-650 (1986). 16. Barker, John F., Oviposition by the Banded Sunflower Moth (Lepidoptera: Cochylidae) in Response to Constituents of the Bracts and Leaves of Helianthus annuus, Journal of Economic Entomology, 90(1):160-164, 1997. 17. Charlet, Laurence D., Biology and Seasonal Abundance of Parasitoids of the Banded Sunflower Moth (Lepidoptera: Tortricidae) in Sunflower, Biological Control, 20:113-121, 2001.
18. Gednalske, J.V. and D.D. Walgenbach, Influence of Insecticide Application Timing on Damage by Smicronyx fulvus and S. sordidus (Coleoptera: Curculionidae), Journal of Economic Entomology, 77:1545-1548, 1984. 19. Oseto, Christian Y. and Gary A. Braness, Chemical Control and Bioeconomics of Smicronyx fulvus on Cultivated Sunflower in North Dakota, Journal of Economic Entomology, 73:218-220, 1980. 20. Optimizing the Quality of Your Confection Crop, The Sunflower, April/May 1998. 21. Keep the Banded Moth in Your Cross Hairs, The Sunflower, March/April 2002. 22. Western Food Makers Source Chinese Organic Ingredients, available at: http://www.ap-foodtechnology.com/news/printnewsbis.asp?id=59043. 23. Brewer, G., Trap Cropping, The Sunflower, March 1993.