Archive for Pests

TIPPING THE SCALES

Posted in Pests, Scale insects, Virginia with tags , , , , on September 19, 2010 by Dr. Art Evans

By Arthur V. Evans

Wax scales that is. Indian wax scales to be precise.

While trimming our nandina hedge this afternoon, I noticed a couple of small, white, barnacle-looking lumps on a stem. They were female Indian wax scales, Ceroplastes ceriferus (Fabricius). Sexing Indian wax scales is easy since males are not known in any wild population in Virginia. Adults are covered with a thick, white waxy layer that not only protects them from predators, parasitoids, and pesticides, but also helps them to survive freezing temperatures during the winter.

Reproduction is by parthenogenesis. One generation is produced annually in Virginia, but two or more appear in warmer climates. The first instars, or crawlers, hatch in spring and early summer and feed on leaves. They are not covered with a protective wax layer and are very susceptible to dehydration, parasites, and pesticides.

Adult Indian wax scales are conspicuous in late summer and early fall and suck sap from at least 122 plant species in 46 families. Prolific breeders, they quickly cover ornamental plants. Burgeoning wax scale populations not only ruin the plant’s appearance, but also cover them with sooty mold that develops on the prodigious amount of sticky waste (honeydew) that they produce.

Carefully tipping or lifting the scale to one side to detach the it from the plant stem reveals the orange and segmented body underneath. In the adjacent photo, the anterior of the body is on the lower right, while posterior is on the upper left. The mouthparts are visible and appear as a dark central spot at about the anterior third of the body.

Resource: Kosztarab, M. 1996. Scale Insects of Northeastern North America. Identification, Biology, and Distribution. Virginia Museum of Natural History, Special Publication No. 3. Martinsville, VA. 650 pp.

© 2010, A.V. Evans

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A BOUNTY OF BOXELDER BUGS

Posted in Insects, Pests, True bugs with tags , , , on March 24, 2010 by Dr. Art Evans

By Arthur V. Evans

A neighbor recently sought my advice about tiny, scarlet insects scurrying across his deck and up his walls, some of which were no larger than bits of coarsely ground pepper. Some had apparently found their way into his home and congregated in the well-lit windows on the south side of the house. A quick inspection of his home and property confirmed my suspicions; the tiny invaders were boxelder bugs.

For the past few weeks, I had noticed congregations of both adults and nymphs sunning themselves along back fences alleys and in trees growing along roadsides. I assured my neighbor that they posed no threat to property or pets, and that only in large numbers might they cause some damage to some plants.

The eastern boxelder bug, Boisea trivittata, is widespread throughout eastern United States. The wester boxelder bug, B. rubrolineata, is similar in appearance, but its found mainly west of the Rockies.

Adult boxelder bugs are flat, dark-gray insects with three red lines behind the head and may reach ½ inch in length. The thickened portions of their wings are bordered with red, while the membranous tips are blackish. They are strong fliers, flashing their bright red abdomens as they spread their wings and take to the air. Young nymphs are mostly red, but later stages appear darker as their wing pads grow larger. Both adults and nymphs have long, thin antennae.

Hibernating adults leave their winter hideaway with the advent of warm weather in late March or early April. Soon the females begin laying their dark reddish eggs in the crevices of bark on box elder trees and other nearby objects. The eggs hatch in two or three weeks, just as succulent new box elder leaves are beginning to appear. The nymphs eat and grow, shedding their external skeleton five times before becoming a fully winged adult. Up to two generations of boxelder bugs are produced annually.

Both adults and nymphs prefer to feed on the seed-bearing female box elder trees, sucking sap from the new leaves, tender twigs, and developing seeds. They will also attack ash, maple, plum, cherry, apple, and peach trees, as well as grapevines and strawberries. Damage from their feeding activities may cause blotchy yellow patches or brown spots on fruit and leaves. Severe infestations of boxelder bugs can result in misshapen leaves and fruit, but mature and healthy plants seldom suffer any serious harm.

In the late spring and early fall, flying or crawling boxelder bugs converge on stone piles, tree holes, and other protected places, sometimes by the hundreds. They may invade buildings, crowding into cracks and crevices in walls, door and window casings, and around foundations. They do not bite, nor do they damage buildings, furnishings, clothing, or food. However, they will soil curtains and walls with their waste and will definitely leave a stain if crushed.

The best way to keep unwanted boxelder bugs, as well as other insects and spiders, out of your home is by improving security. Replace screens and door sweeps. Repair thresholds and secure pet doors. Apply screens to vents and other openings. Caulk and seal all possible entry sites near doors, windows, crawl spaces, light fixtures, utility pipes or wires, weather boarding, and in areas along the foundation.

For boxelder bugs already in the house, vacuuming, sweeping, or picking them up are the most effective methods for dispatching them. They do not feed on household structures or reproduce indoors, so there is no need to use chemical controls inside the home. Aerosol sprays designed to kill ants and cockroaches are generally ineffective against boxelder bugs.

Removing leaf litter and other debris that serve as egg-laying sites near the base of female (seed-producing) box elder trees will reduce large populations of boxelder bugs outdoors. Eliminate other hiding places, such as piles of boards, rocks, leaves, grass, and other debris close to the house. Clear leaves and grass away from the house, especially on the south and west sides of the structure. Since boxelder bugs prefer to feed and lay their eggs on female box elder trees, plant male box elder trees instead. Male trees, propagated from cuttings taken from other male trees, are purchased from the nursery. These measures will significantly reduce the numbers of boxelder bugs looking to get inside your warm and cozy home.

As with many other insects labeled as “pests,” a little knowledge of their habits can help to reduce costly and sometimes unnecessary reliance upon pesticides, while at the same time raising our levels of tolerance and wonder. To me, this year’s appearance of boxelder bugs is just another marvelous pulse in the seasonal cycle of life. I am not the only one who feels this way. Just ask the folks in Minneota, Minnesota. They celebrate these little creatures each year with Boxelder Bug Days, a fall festival featuring bug races, bug poetry, plays, and other activities. If you can’t beat ‘em, join ‘em!

© 2010, A.V. Evans

HOUSE CENTIPEDES ON THE MOVE

Posted in Centipedes with tags , , on March 21, 2010 by Dr. Art Evans

By Arthur V. Evans

The house centipede, Scutigera coleoptrata, looks more spider and less centipede as it motors up a wall, along a sidewalk, or across the kitchen floor.

One of my favorite non insect arthropod species is a fleet-footed fellow no more that one and a half inches long and has racing stripes down its back. Surrounded by a blur of legs in full stride, the house centipede, Scutigera coleoptrata, looks more spider and less centipede as it motors up a wall, along a sidewalk, or across the kitchen floor.

House centipedes are probably native to the Mediterranean region and have been accidentally transported to many parts of the world. In Tasmania, they are known as the “domestic quickfoot.” These curious animals are well-established across much of the warmer regions of North America, but have managed to penetrate cooler, less hospitable regions in the north by adapting to life indoors.

Outside, house centipedes are at home in the cool, dark, moist recesses of rocks, trees, and leaf litter. They are equally well suited to living in the basements, bathrooms, and drains of our homes, offices, and laboratories. Individuals are sometimes encountered when they become trapped in tubs and sinks, or are attracted to flying insects drawn to porch lights at night.

House centipedes are equipped with a pair of large compound eyes, which allows them to quickly identify potential prey.

Hardwired with a “need for speed” to capture agile prey and escape equally nimble predators, house centipedes possess an array of unique morphological features. The distinct, capsule-shaped head is equipped with a pair of large compound eyes, an exceptional feature among centipedes. Acute vision is probably a major asset when a house centipede must quickly identify a potential prey item while on the run.

The structure of the house centipede’s eyes is similar to those of insects and crustaceans. As a result, they have been the objects of study for scientists seeking to better understand the evolutionary relationships of house centipedes with insects and other arthropods.

House centipedes sprint at speeds of 420mm/second; a 5’8” human would have to run the same distance, relative to their height, at a speed of about 42 miles/hour. But it takes more than the long, slender legs of a sprinter to get these centipedes up to speed; it also requires plenty of oxygen. Their lung-like tracheal system is unique among centipedes and allows oxygen into the body quickly and efficiently to help power the numerous muscles that drive the legs.

Most of their 30 long, slender, banded legs are used not only for getting around and escaping predators, but also to help capture and secure prey. When attacked, the house centipede’s legs easily break off and continue wiggling for a short period, like a lizard’s tail, to distract predators. Fortunately, lost legs are completely regenerated after just one molt. Under ideal conditions, adult house centipedes shed their exoskeletons every 30-60 days for the rest of their lives, which may last up to three years.

Centipedes are the only group of animals that have their front legs modified into fangs that inject venom to subdue and kill prey. Although they usually feed on invertebrates, some larger species will also attack small lizards, snakes, birds, and rodents.

The venom of house centipedes is not particularly toxic, at least not to humans. They seldom bite. Descriptions of the bites of house centipedes range from “minor nuisance” to “severe pain.” However, serious effects from the bite are more likely to be the result of secondary infection than the bite itself.

House centipedes prey on scores of unwanted house pests, especially small spiders, clothes moths, and cockroaches. This one is dining on a crane fly.

Still, house centipedes have become one of those “bread-and-butter” species of the pest control industry. Company literature and web sites would have you believe that these curious and largely beneficial creatures are major household pests. As with many “pests,” the greatest harm involving house centipedes is the “bite” to your wallet caused by the unnecessary purchase of pesticides to control these needlessly maligned animals. The truth is that they do more good than harm because they prey on scores of unwanted house pests, especially small spiders, clothes moths, and cockroaches. And they do all this without charging a dime for their services.

© 2010, A.V. Evans

WHAT’S IN YOUR ATTIC? BROWN MARMORATED STINK BUGS, PERHAPS

Posted in Environment, Insects, Pests, True bugs, Winter with tags , , , , , on March 15, 2010 by Dr. Art Evans

By Arthur V. Evans

Last month, while attending a meeting of the Bull Run Mountains Conservancy held in The Plains, Virginia, I was approached by several members who wanted to know about a stink bug that had invaded their homes by the dozens or hundreds in the fall. At first I thought they were referring to a species of bark stink bug, Brochymena, which sometimes enters homes by hiding under the bark of firewood hauled inside for the fireplace. Just as I was going into my spiel about sending me a photograph or a specimen for identification, someone said, “Look! There’s one!”

 

The brown marmorated stink bug, Halymorpha halys Stål, is steadily expanding its range across North America.

 

Sure enough, a robust gray stink bug was slowly making its way up the wall toward a window through which the day’s last rays of sunlight were shining. Judging from its distinctive markings, I knew that it was not a species of Brochymena and wondered if it might be the brown marmorated stink bug (BMSB), Halymorpha halys Stål. My suspicions were soon confirmed.

This uninvited insect from Asia has proven to be quite a nuisance to many homeowners in northeastern United States for the past several winters. They are much more likely to take up residence inside buildings than either of their native look-alikes, Brochymena and Euschistus.

BMSB was first reported from Allentown, Pennsylvania in 2001, but it turns out that the species has been in that area since at least 1996. The very first individuals probably arrived in America as stowaways, possibly as eggs, on packing crates most likely shipped from China or Japan. Since then, they have spread throughout Connecticut, Maryland, New Jersey, New York, Pennsylvania, Virginia, and West Virginia. As of 2004, an isolated population has become established in Oregon.

Like other stink bugs in the family Pentatomidae, BMSB are “shield-shaped” in outline. They are about 17 mm in length and are nearly as wide as they are long. Unlike similar species of native stink bugs, BMSB has white bands on the antennae and dark bands along the edges of the abdomen surrounding the wings. The head and pronotum (upper surface of the mid section, or first thoracic segment) have patches of small, round coppery or metallic bluish pits. The glands that put the stink in these and other pentatomids are located on the underside of the thorax and upper surface of the abdomen.

 

A nymph of the brown marmorated stink bug, Halyomorpha halys.

 

Brown marmorated stink bugs probably produce a single generation per year in America, but records from the sub-tropical regions of China indicate that there are 4-6 generations annually. Local populations of adults emerge from their winter hideaways in early June and begin mating and laying eggs almost immediately. The small black and red larvae (nymphs) soon hatch and molt five times during the months of July and August. Adults appear in mid August and begin seeking overwintering sites by mid September as the evenings start to become cooler.

To escape the cold, BMSB enter homes, out buildings, office buildings, and other structures by crawling under siding and shingles, around door and window frames, and into crawl spaces and attics. Once inside, they will settle in and become inactive for short periods. However, reinvigorated by the warmth of home heating systems, they are driven to crawl over walls and furniture, or fly clumsily to lights and windows.

As they bumble about, BMSB leave their odor on everything they land and crawl on. The accumulation of this odor at a good hibernation site serves as a powerful chemical beacon that attracts their brethren to the same location year after year.

The best way to keep BMSB out of homes and other structures requires preventative measures to be taken during the summer, after the bugs have already left, to prevent a re-infestation in the fall. Seal cracks and spaces around doors, windows, vents, utility access points, siding, trim, fascia boards, and chimneys. Caulk is handy for small cracks, but wire mesh and screens may be required when dealing with larger spaces associated with attics and foundation vents.

The good news is that once inside your home, BMSB will not bite you or your pets, spread disease, nor lay their eggs. Their piercing-sucking mouthparts are adapted for drawing sap from plants, not damaging furniture, clothing, or other household items.

Using insecticides on BMSB indoors is not particularly effective. Crushing them or sucking them up with a vacuum cleaner causes them to release their noxious odors that may persist in a room or on cleaning implements for sometime. Any disturbance perceived by the bugs as a threat will cause them to stink as a defensive measure. The best thing to do is to simply let them walk on a piece of paper and take them directly outside.

What is being done about BMSB nuisance in America? Since they have yet to become serious agricultural pests here in the States, there is little incentive for chemical companies to develop pesticides to combat them. Pesticides of any kind are incredibly expensive to bring to market and the number of homeowners plagued by home invasions of these bugs will never support the company’s efforts to recoup their investment, much less generate a profit.

But all is not lost. Researchers are learning everything they can about BMSB so that they can identify the weak links in their life cycle and exploit them to affect some level of control. Select BMSB genes and proteins are being sought for the possible development of genetically modified crops that will help suppress their numbers. There is also the possibility of using parasitic insects that will attack stink bugs during egg stage, not only to lessen their potentially harmful impact on crops such as soybeans, cotton, and corn, but also to reduce the numbers of individuals seeking shelter for the winter.

One of the more promising avenues of research involves the synthesis of attractant chemicals, or pheromones, to use in stink bug traps. Although BMSB attractant pheromone is currently unknown, scientists have discovered that they are attracted to the pheromones produced by the male of another species of stink bug native to Japan, Plautia stali Scott. Traps in America baited with this pheromone not only attract BMSB, but also some native species of stink bugs and a tachinid fly, Trichopodes pennipes,  that parasitizes native stink bugs.

Why would these stink bugs and one of their natural enemies be attracted to the pheromone of another species of stink bug? Research on other stink bugs species suggests that some use the pheromones of stink bug species other than their own in an effort to locate better feeding sites. Further, this chemically induced aggregation of different species of stink bugs may serve as a defensive strategy known as the “selfish-herd effect.” As the herd, or aggregation, grows individual stink bugs are increasingly less likely to be selected by a parasitic fly that, not so coincidentally, uses the very same pheromone to locate its victims. The discovery of the attractiveness of this pheromone offers up a potentially useful tool for monitoring and managing BMSB in America.

BMSB is steadily expanding its range across North America. Although clearly annoying to homeowners, the degree to which this species will become an agricultural pest in America remains unclear, especially as it moves south into warmer climates. Within their native range of China, Japan, Korea and Taiwan BMSB is most certainly an agricultural pest, attacking soybeans, apples, peaches, figs, mulberries, citrus, persimmons, and a variety of ornamental plants.

For now, all we can do is batten down the hatches and hope that science will come to the rescue.

© 2010, A.V. Evans

THE FOREST CATERPILLAR HUNTER, Calosoma sycophanta, IN VIRGINIA

Posted in Beetles, Environment, Insects with tags , , , , , , , on February 24, 2010 by Dr. Art Evans

By Arthur V. Evans

In July of 2008, while conducting a beetle survey of the Bull Run Mountains Natural Area Preserve in Fauquier and Prince William counties in Virginia, I found numerous metallic green elytra scattered along a foot trail winding through an oak woodland on a west-facing slope. The area had been heavily infested with larvae of the gypsy moth, Lymantria dispar, as evidenced by thousands of larval exuviae and pupal cases that festooned the trunks of oaks and other hardwood trees.

At first glance, I thought the beetle remains were those of the indigenous caterpillar hunter or fiery searcher, Calosoma scrutator, a common, brightly colored, and widespread carabid beetle found in the mountains and lowlands of Virginia. Closer inspection revealed that the elytra were much brighter and more yellow than those of C. scrutator and lacked the characteristic coppery red margins.

Further searching in the area produced a very fragile, yet nearly intact specimen ensnared in an abandoned spider web. The pronotum of this specimen was mostly black with metallic blue along the margins, rather than bluish with violet or coppery yellow green borders typical of C. scrutator. Of the five other species of Calosoma known in Virginia, only C. wilcoxi has entirely metallic green elytra, but it is smaller and much duller than either C. scrutator or the silk-wrapped remains in question. (Figure 1).

Figure 1. The Virginia species of Calosoma (from top to bottom, left to right): C. calidum (F.), C. externum (Say), C. frigidum Kirby, C. sayi Dejean, C. scrutator F., C. sycophanta (L.), and C. wilcoxi LeConte. The scale bar equals 5.0 mm. © 2009, Chris Wirth.

I soon realized that what I had in my possession were the remains of a European species, the forest caterpillar hunter, C. sycophanta. Long known as an important predator of gypsy moth larvae in France, 4,046 of these beetles were imported into the United States between 1905 and 1910, most of which were released in New England to combat outbreaks of two European species of lymantriids: the gypsy moth and the browntail moth, Euproctis chrysorroea.

In the United States, the forest caterpillar hunter is established in Connecticut, Maine, Maryland, Massachusetts, Michigan, New Hampshire, New Jersey, New York, Rhode Island, Vermont, and Washington. They have been released in Delaware, Michigan, Washington, and West Virginia, but they have yet to become established in these states. In spite of releases on Vancouver Island, British Columbia, Quebec, New Brunswick, and Nova Scotia, the forest caterpillar hunter does not appear to be a permanent resident in Canada either.

Both the adults and larvae climb trees to attack and eat caterpillars and pupae of gypsy moths and other species. Adult males are more likely to be found on tree trunks, while females tend to remain on the ground. Based on observations in the laboratory and in the field, both sexes are active day and night. Males tend to be more conspicuous as they spend most of their time actively searching for mates. The more secretive females spend much of their time buried in the soil and hidden among leaf litter to feed and lay eggs.

Adult activity coincides with the larval activity of the gypsy moth. Beetles emerge from their overwintering sites in June to search for prey and mates, although some beetles may remain dormant for up to two years. Although adults are strong and agile fliers capable of leaving their overwintering sites behind to search for high populations of caterpillars, their appearance at new outbreaks of gypsy moths is by no means certain. In fact, beetles released as part of biological control programs often remain near their release site.

Forest caterpillar hunters will attack a variety of other caterpillar species, but are most abundant where populations of gypsy moth caterpillars are high. They remain active for about a month, re-enter the soil, and remain there until the following spring.

Adult predation is not this species’ primary impact on gypsy moth populations. It’s greatest impact is through larval production and the voracious appetites of the beetle’s larvae for mature caterpillars and pupae. The ability of adult beetles to reproduce is directly dependent upon the availability of high densities of gypsy moth caterpillars, especially since females require sufficient protein to ensure successful development of their eggs.

Eggs are laid in the soil beginning in early July and hatch in 4-7 days. The larvae climb trees in search of caterpillars and pupae. The remains of pupae attacked by beetle larvae have characteristically large and jagged holes. Mature beetle larvae seek pupation sites in the soil. The entire life cycle, from egg to adult, takes about seven weeks. In Connecticut, adults are known to live three to four years.

Anecdotal evidence suggests that forest caterpillar hunters are potentially important predators of gypsy moth larvae and pupae, but there is still much to learn. Nearly all of the information on the ecology and behavior of C. sycophanta was gathered during the brief period of adult activity that coincides with gypsy moth outbreaks, but little is known about the ecology of this species between outbreaks.

Many thanks to Chris Wirth for the wonderful color plate. This essay is excerpted from Evans, A.V. 2010. The forest caterpillar hunter, Calosoma sycophanta, an Old World species confirmed as part of the Virginia beetle fauna (Coleoptera: Carabidae). Banisteria [2009] 34: 33-37. The full article is available at http://fwie.fw.vt.edu/VNHS/banisteria/banisteria.asp.

©2010, A.V. EVANS

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