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Home > Master Publication List > Dung Beetle Benefits in the Pasture Ecosystem

Dung Beetle Benefits in the Pasture Ecosystem


Michelle Thomas
NCAT Agriculture Intern
Published 2001
CT155


Abstract

Dung Beetle
Dung beetle.
www.clipart.com

Dung beetles feed on manure, use it to provide housing and food for their young, and improve nutrient cycling, soil structure, and forage growth in the meantime. This publication describes dung beetles and their benefits to pastures, and offers management information. It also offers information about building a dung beetle "farm."

Table of Contents

Introduction

Dung beetles play a small but remarkable role in the pasture ecosystem. They feed on manure, use it to provide housing and food for their young, and improve nutrient cycling, soil structure, and forage growth in the meantime. Dung beetles are important enough in manure and nutrient recycling that they well deserve the pasture manager"s attention.

Dung beetles belong to the zoological order Coleoptera and family Scarabaeidae. Of the more than 90 species in the U.S., less than a dozen are significant in dung burial. Three behavioral groups of the beetles are relevant to manure recycling. Probably the best-known group are the "tumble bugs" or "rollers" (e.g., the species Canthon pilularius). In the behavior characteristic of this group, a male-female pair roll a ball of dung (brood ball) away from a manure pile in order to bury it. Dung beetles generally work in pairs.

Another group are the "tunnelers." An example of this group is Onthophagus gazella, which typically bury the dung balls under the manure pat or close to the edge. Piles of soil next to the dung pat are indicators of tunneler-type dung beetle activity. Collectively, tunnelers and tumblers are classified as "nesters" because of their behavior in preparing a home for their young. The third group of beetles that use dung are the "dwellers". Most dwellers belong to the subfamily Aphodiidae. They live within the manure pat, engage in little to no digging, and generally do not form brood balls.

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Appearance and Behavior

Dung beetles range in size from 2mm (0.1 inch) to 60 mm (2.5 inches). The front legs usually have serrated edges, used for powerful digging. Colors range from black to brown to red, and can have a metallic appearance. Males often have one or two horns. Scarabs are distinguished from other beetles by the appearance of their antennae, which are segmented and end with a plate-like oval club of three to seven expansible leaves. These lobes create a large surface area for detecting odors. Look for these specialized antennae with a magnifying glass.

Adult dung beetles are drawn to manure by odor. Many are species-specific—they prefer a certain type of animal manure. They will fly up to 10 miles in search of just the right dung, and can attack dung pats within seconds after they drop. Some species will even hitch a ride near the tails of animals in anticipation of a deposit. Once drawn by the odor, the adults use the liquid contents of the manure for their nourishment. Dr. Patricia Richardson, Research Associate at the University of Texas, memorably refers to this as a "dung slurpie."

If they are a nesting species, the pair then goes to work on forming a brood ball out of the dung, which contains a large amount of roughage. The pair continue to work as a team to bury the ball.

The female, which typically has shorter, thicker legs, digs while the male helps haul the soil from the tunnel. The female lays one egg in each ball. She then seals the brood ball, seals the tunnel, and begins the process again if she is of a species that lays several eggs.

hatching process
Fincher, G.T. and P.B. Morgan. 1990. Flies affecting livestock and poultry. p. 152. In: Habeck, et al. (eds.) Classical Biological Control in the Southern United States. Southern Cooperative Series Bulletin No. 355. November 1990.

In about a week, the egg hatches within the brood ball. The larva feasts on the interior contents of the ball, eating about 40-50%, and sealing the interior with its own excrement along the way. This leads to a totally enclosed, protected environment. The larva does not have to compete with others for a food source, and is also protected from predators outside the brood ball. If the integrity of the brood ball is destroyed, the larva will die. Under ideal environmental conditions, the larva will pupate at an average of three weeks. A young adult beetle emerges, eats its way out of the brood ball, forms a new tunnel to crawl out through, and goes on its way in search of fresh manure. The newly emerged beetles will breed two weeks later, with a complete generation taking six weeks under ideal environmental conditions. (1)

Soil moisture level is crucial to many species, as breeding and dung burial are decreased in dry periods. During dry weather, the young adults emerge from the brood ball but remain within the soil, waiting for rain. As with most beetles, activity decreases during the coldest months. The larvae remain viable deep within the soil, waiting for environmental cues such as rainfall and temperature to prompt their emergence.

Other dung beetle species prefer an arid climate. Euoniticellus intermedius, imported from Australia, is found in south, central, and west Texas where it is especially important ecologically, being active during dry weather when other native beetles are not. (2)

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Importing New Species

Dr. Truman Fincher (retired) directed the dung beetle research program at the USDA-ARS Food Animal Protection Research Laboratory at College Station, Texas, until 1998. His research was directed at importing and introducing dung beetle species that would complement and not compete with native populations, in order help balance U.S. pasture ecosystems. According to Fincher, the beetles in the U.S. have not been able to keep up with our increased livestock production and manure waste. Increased fertilizer use and higher-producing forage varieties have boosted forage yields, increasing in turn the animal carrying capacity per unit of pasture. Also, widespread use of insecticides, herbicides, fungicides, and anthelmintics may be responsible for reducing dung beetle populations. (3)

If pastures throughout the variety of climates, soil types, and other physical conditions in the U.S. supported Dr. Fincher"s ideal complex of dung beetles, manure burial would be ongoing 24 hours a day. Though it may take up to 120 different species of dung beetles to accomplish this goal, the behavioral diversity among species makes it a feasible goal. Some are nighttime flyers, some fly during the day, and some prefer older manure to very fresh. If several species are working together, some may bury the brood ball close to the manure pat, some farther away, some shallow, and some deep. (4)

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Benefits to the Pasture System

Dung beetles" benefits to livestock and the pasture environment just might outweigh their somewhat disgusting choice of food. For example, manure is the breeding ground and incubator for horn flies (Haematobia irritans) and face flies (Musca autumnalis), two economically important pests of cattle. A single manure pat can generate 60-80 horn fly adults if protected from insect predators and competitors such as dung beetles. As dung beetles feed, they compete with the fly larvae for food and physically damage the flies" eggs. Fly populations have been shown to decrease significantly in areas with dung beetle activity. Dr. George Bornemissza found that 95% fewer horn flies emerged from cowpats attacked by Onthophagus gazella, than from pats where beetles were excluded. (2)

Dung Beetles
The Afro-Asian dung beetle, Onthophagus gazella, has been successfully established in the southern tier of states, from California to South Carolina. The male is shown at left, the female at right.
Anon. 1997. Heroes of the pasture. (Interview with G.T. Fincher.) Acres U.S.A. December. p. 26.

Dung beetles are also reported to be effective biological control agents for gastrointestinal parasites of livestock. The eggs of most gastrointestinal parasites pass out in the feces of the host. The eggs then hatch into free-living larvae and develop into the infective stage. They then migrate onto grass, where they can be ingested by grazing animals, and complete their life cycle within the animal. If the manure/egg incubator is removed by beetles, the eggs perish and the life cycle of the parasite is broken.

On a pasture-management level, dung pat removal is beneficial for forage availability. Most ruminants will not graze closely to their own species" manure pats. Research has shown that the forage is palatable, but avoided because of the dung pile. Consequently, cattle manure deposits can make from 5% to 10% per acre per year unavailable. By completely and quickly removing the manure, dung beetles can significantly enhance grazing efficiency.

The tunneling behavior of dung beetles increases the soil"s capacity to absorb and hold water, and their dung-handling activities enhance soil nutrient cycling. An adequate population and mix of species can remove a complete dung pile from the surface within 24 hours. As the adult dung beetles use the liquid component for nourishment and the roughage for the brood balls, the dung pat quickly disappears. If left on the surface, up to 80% of manure nitrogen is lost through volatilization; by quickly incorporating manure into the soil, dung beetles make more of this nitrogen available for plant use. The larvae use only 40-50% of the brood ball before pupating, leaving behind the remainder of this nutrient-rich organic matter for soil microbes, fungi, and bacteria to use in creating humus. (5)

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Management

Dung beetle larvae are susceptible to some insecticides used for fly and internal parasite control for cattle. Ivermectin (Ivomec and Doramectin) injectable, used at the recommended dose, reduced survival of the young of two species for 1 to 2 weeks in a study done by Dr. Fincher. Ivermectin pour-on reduced survival of the larvae for 1 to 3 weeks. Most detrimental was Ivermectin administered as a bolus, with effects lasting up to 20 weeks. Discontinuing the use of this type of insecticide will help increase your population of dung beetles.

Specific chemicals aside, one must consider that any product designed to harm, limit, or kill would have some impact on the ecosystem in general, and should be used judiciously. Backrubbers, ear tags, and the occasional use of insecticide dusts and sprays are alternatives that have little or no effect on dung beetles. (2) Another option is to treat cattle during the coolest months of the year, as the beetles and larvae are inactive at those times. Better yet, before treating your animals for internal parasites, take a fecal sample to your veterinarian. An egg count can help determine parasite load and whether the symptoms you may be seeing in the form of low gains, weight loss, unthriftiness, etc., are truly being caused by parasites.

Controlled grazing systems increase dung beetle populations and varieties by concentrating the manure in smaller areas, thus reducing the time beetles must spend in search of food. Grazing cycles that match the reproductive cycle of the beetles are favorable, as cattle return to grazing cells at the same time that new adults are emerging from the soil. For more information on controlled grazing systems, refer to the ATTRA publications Rotational Grazing and Pastures: Sustainable Management.

Watch the length of time it takes for the manure pats to disappear in your pasture. If they remain intact for more than a few days, chances are your dung beetle population is low to non-existent. Look for hole formation in the surface of the manure pats. Many types of beetle and other insects also help to desiccate the pats. Management is the key to increasing the number and variety of dung beetles and other beneficial insects.

Dung beetles are just one small part of the pasture ecosystem, but too important to ignore. To summarize the dung beetle benefits highlighted by Dr. Fincher:
  • Increased pasture yields resulting from the incorporation of organic matter into the soil with an increase in soil friability, aeration, and water holding capacity.
  • Reduction of other insect pest populations that breed in animal feces.
  • Prevention of pasture surface pollution.
  • Reduction of animal diseases by removing contaminated feces from pasture surfaces.
  • Return to the soil of nutrients that would otherwise be tied up in fecal deposits and unavailable to pasture grasses.
  • Increased effective grazing areas of pastures covered by feces.
  • Reduced nitrogen loss in livestock feces.

On a Personal Note... My interest in this research area was sparked by observations made during our local grazing group"s pasture walks, held monthly in the Northwest Arkansas area. While walking through the pastures, you have to carefully watch your step to avoid those proverbial "pats." As the warm spring days arrived, we noticed holes on top of the manure pats, and began to investigate further. Seeing various small beetles, spiders, flies, gnats, and other insects led to more investigation.

Some in the group were more investigative than others, using pocketknives and sticks to plow into the manure. We found dry, hard shells with holes on the outside, and tunnels with moisture underneath. Some of the shells were simply that—shells with hollow interiors. Many pats were spread out, with only a bit of roughage left behind. Several had piles of soil next to the edge of the pat. Having learned about dung beetles and their benefits from veterinarian and ATTRA Specialist Dr. Ann Wells, the group had some ideas about what we were looking at. And as usual, we also had more questions. My curiosity piqued, I began to research the subject during my summer internship. I have since had the opportunity of watching the seasonal changes on the dung scene from late spring, through summer, and into early fall.

Research in the scientific literature was also interesting, but I finally turned to a few experts for the benefit of their applied knowledge. Dr. Patricia Richardson has written several publications on this topic, with a humorous style I admire. When I came across mention of a dung beetle "farm" used at a workshop in Texas, I decided to try to replicate it for myself. Dr. Richardson very helpfully provided construction details.

Next, I needed the "workhorse" of all the tunneler dung beetles, the Onthophagus gazella. Again I called on Dr. Richardson for advice on how to locate them near my home in the Arkansas River Valley. She suggested watching at dusk and at dawn, as they are nighttime flyers. For several evenings and early mornings I followed her suggestions, to no avail. (I did see three beautiful "rainbow scarabs" around a pat by flashlight late one evening.) Frustrated, I went to Plan B: I scooped up an entire manure pat with the telltale sign of tunneler activity, a fresh soil mound, next to it—and bagged and froze it. I dissected the pat the next afternoon, sorting out beetles by size and appearance into separate containers, and made a trip to the University of Arkansas Entomology Museum, where Dr. Jeffrey Barnes identified my beetles for me. To my utter dismay (devastation may be a better word), there were no Scarabs, or "true dung beetles." Most of my specimens were of the Histeridae family, which is another very beneficial beetle, but not what I was looking for. Finally I turned to Oklahoma cattleman Walt Davis, who graciously sent several of the gazella beetles to me by mail.

I filled the "farm" with sandy soil from the river bottom, and put fresh cattle manure on top. The looming challenge now was to distinguish the males from the females, in order to place two or three pairs into the farm. With Dr. Richardson"s notes close at hand, I placed one beetle into a white coffee cup for close viewing. The front legs were serrated as she described, and the antennae had little lobes on the end. Males have two small horns that lie toward the back and are a little difficult to see at first. The females have shorter, thicker legs than the males, and no horns. (I must admit I have become quick at sex identification of these creatures, which is alarmingly rewarding.) I placed two pairs into the farm and waited.

Within three days, we began to see tunnels forming. I added another pair and the brood balls became visible within a few more days. I cannot adequately describe my excitement. After two weeks, at least 38 brood balls were present, indicating time to entice the parents out of the nest. Dr. Richardson suggested "starving" them out for a few days, then luring them into a new, fresh pile of manure. The process worked very well.

At this point, I am watching the brood balls for movement and hatching, approximately 4 weeks after their burial. I have seen two larvae moving and eating, and hope they will consider the sheet of Plexiglas an integral part of the brood ball for later pupation. The weather, however, will have an effect since it is cooling off below 55 degrees Fahrenheit at night. This will slow their activity, and, from my understanding, may even arrest their emergence until the warm spring evenings and rainfall begin. Even so, this dung beetle farm can be used for presentations and educational opportunities for several months and that is my intention.

One last note of excitement over this project: I located several dung beetles I believe to be gazellas while cleaning the poultry pens at our county fair in September, after a long, much-needed rain. Moisture is critical to their activity, and they showed up when and where I least expected! We have since found these tunnelers on our own farm as well, and they are most welcome to stay as long as they will.

Dung beetle life cycle viewing chamber
Dung beetle life cycle viewing chamber.

 

 

 

 

 

 

 

You can easily build your own dung beetle farm for observation of burrows, brood balls, larvae, etc. This would make a great school or 4-H project for the kids. The chamber consists of two plexiglass sides with a ½" space between them held in a wooden frame, with a viewing area (per side) of about 24" wide by 20" tall. Information provided by Dr. G. Truman Fincher via Dr. Patricia Richardson.

Lumber needed: (use treated lumber)

Bottom: (2" x 4") 31" long. Cut a "generous" 7/8"-wide, ½"-deep center groove down the entire length of the board.

Sides: make 2—(2" x 2") 21" long. Again, cut a "generous" 7/8"-wide, ½"-deep center groove the entire length of the board. At the bottom end of each side piece, cut the board to leave a ½"-deep, 7/8" wide tongue to fit into the groove in the bottom piece.

Braces: make 2—(2" x 4") On the outside of each side piece is a wedge-shaped brace about 4" tall, glued to the side and screwed to the bottom.

Top: (1" x 2") 20" long. Cut a "generous" 7/8"-wide, ¼"-deep center groove the entire length of the board. Make a 16"-long cut (the thickness of the saw blade) through the board, in the center of the groove and the middle of the board"s length—this is the air slit.

Plexiglass needed:

2 viewing sides: 3/16" thick, 25" wide by 21" tall
2 end strips: ½" thick, ½" wide by 20.5" tall
1 bottom strip: ½" thick, ½" wide by 25" long
3 support circles (or squares, or triangles): ½" thick, about the diameter of a quarter, to keep the viewing sides from bowing in or out.

Glue all strips and circles to one of the plexiglass viewing sides. Place one circle in the center, about 16" from the bottom. Place the other two about 6" in from either side and 8" up from the bottom.

When the chamber is assembled, drill a hole through each support circle (in through one plexiglass side and out the other). Secure with bolts and nuts. Glue and screw wood frame pieces into place.

Add sandy loam soil up to about 7" from the top, fresh cow manure (big blob piled in middle), and two or three male/female pairs of adult dung beetles. Keep at warm temperature (they like 85 degrees F). They should begin to burrow and make brood balls within a day or two. Add more fresh manure as needed. Remove the adult dung beetles in a week to ten days (withhold fresh manure for a while, then lure them into a bucket of fresh). Provide 14 hours of light, 10 of darkness.

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References

  1. Richardson, Patricia Q. and R.H. (DicKB] Richardson. 2000. Dung beetles improve the soil community (Texas/Oklahoma). Ecological Restoration. Summer. Vol. 18, No. 2. p. 116-117.

  2. Knutson, Allen. 2000. Dung beetles–Biological control agents of horn flies. Texas Biological Control News. Winter. Texas Agricultural Extension Service. The Texas A&M University System.

  3. Habeck, D.H., F.D. Bennett, and J.H. Frank (eds.) November 1990. Classical biological control in the southern United States. Southern Cooperative Series Bulletin No. 355.

  4. Fincher, G.T. 1981. The potential value of dung beetles in pasture ecosystems. J. Georgia Entomol. Soc. Vol. 16. 1st Supplement. p. 316-333.

  5. Richardson, Patricia Q. and R.H. (DicKB] Richardson. September 1999. Factsheet: Dung beetles (Work for free, love their worKB]. p. 1-3.

  6. Behrens, Patricia W. 1994. Dung beetles: Beetlemania in action. Acres U.S.A., October. Vol. 24, No. 10. p. 10-12

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Other Sources of Information

Floate, Kevin. 2001. Lethbridge Research Centre. Agriculture and Agri-Food Canada Research Branch. Accessed 6 June, 2001:
Biological Control of Insect Pests: Insects in Cattle Dung
http://res2.agr.ca/lethbridge/scitech/kdf/dungbugs-bousiere.htm

North Carolina State University
Dung Beetles of Central and Eastern North Carolina Cattle Pastures
www.ces.ncsu.edu/depts/ent/notes/forage/guidetoncdungbeetles.pdf [PDF/475KB]


Dung Beetle Benefits in the Pasture Ecosystem
By Michelle Thomas
NCAT Agriculture Intern
Tiffany Nitschke, HTML Production
CT 155
Slot 171

 

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This page was last updated on: August 28, 2014