Why Insects Matter

 

Insects are terrific pollinators!

As the growing human population transforms our planet, the global insect population is declining at an unprecedented rate of 2% a year. The world has lost 5% to 10% of all insect species just in the last 150 years, so in 40 more years we could lose one third of all insect species. In a study just published in the journal Science, a working group called the ‘Status of Butterflies in the U.S.’ found that the total abundance of butterflies in the U.S. declined by 22% from 2000 to 2020.  Said another way, one in five butterflies have vanished.

Many butterfly species, including the Monarch, are declining in abundance.

What is driving this precipitous drop in insect populations and why does it matter? Insect populations are struggling due to several factors, including deforestation/habitat loss (due to development), non-native invasive species, pesticide use, artificial light pollution, and climate change.  As a result, the populations of other animals, crops, and flowers that rely on insects to survive also struggle.

Non-native, invasive plants, like Ligustrum species, often overtake native habitats.

Scientists say that it is impossible to have an insect-free life on this planet. They perform many essential services that are vital for humans’ quality of life. Pollinators such as bees, butterflies, moths, and many other types of insects are necessary to produce diversity and abundance in our food supply, including crops such as coffee, chocolate, blueberries, apples, almonds, avocados, and pumpkins, just to name a few. In fact, pollinators help ensure that about 75% of the world’s flowering plants and 35% of the world’s food crops are produced.  Other scientists estimate that one out of every three bites of human food are directly related to the work of pollinators such as bees, butterflies, moths, beetles, and other insects.

Moths and beetles are pollinators, too!

Plant and animal waste would pile up if it weren’t for the services of dung beetles and other insect recyclers. Insects like dragonflies, ladybugs, green lacewings, ground beetles, and parasitic wasps keep what we call the ‘pest’ species at bay – the mosquitos, ticks, fleas, lice, and flies that can carry disease as well as crop pests such as armyworms, cutworms, and wireworms.  

Dung Beetles hard at work.

Roseate Skimmer dragonfly eating a mosquito.

Most humans like birds, but most are also unaware of the fact that 96% of birds would not be here without insects. It takes 6,000 to 9,000 caterpillars and other insects to feed a clutch of four to six Carolina Chickadee offspring. Multiply that by the fact that most all avian nestlings and fledglings eat some form of insects, and you very quickly realize how important they are to the food web. Insects are also the main food for all of the fish, so they are the glue that binds together every terrestrial and freshwater ecosystem on the planet.

Many bird species, like the endangered Golden-cheeked Warbler,
feed insects to their young.

What can be done to reduce this downward trend?  The good news is that the things we do in our own backyards can actually make a difference when it comes to insect conservation. First and foremost, reduce or (better yet) replace your non-native lawn with native plants.  Lawns make up about 50% of Austin’s green space, so turning them back into native plantings would provide significant benefit to insects. 

Replace your lawn with native plants -
extra bonus for providing water!

Eliminate all pesticide use, including mosquito spraying. The spray contains pyrethroids which are advertised as “safe as chrysanthemum flowers”, but they are a much stronger synthetic version that is chemically designed to be more toxic with longer breakdown times.  This increased potency compromises the human body’s ability to detoxify the pesticide in addition to killing all insects, not just mosquitos.

Mosquito spraying kills all insects,
not just mosquitos.

Light pollution contributes to insect decline.

And last, but not least, turn your exterior lights off at night so as not to affect the behavior of night-flying insects (this also benefits birds during spring and fall migration). Artificial lighting can disorient moths and confuse their sense of direction, causing one third of those that swirl around a light at night to die from exhaustion or predation. Excess light also disrupts the mating flashes of fireflies and confuses insects like mayflies by bouncing light off of asphalt and causing them to lay their eggs in the street instead of in a lake or stream.

Migration Isn't Just For The Birds

 

Wandering Glider dragonflies do more than wander...

Most people who are interested in nature know that each spring many species of birds migrate north, and each fall they migrate south.  But birds aren’t the only animals that participate in this amazing natural phenomenon, as even some insects (other than the well-known Monarch butterfly) participate in long-distance migrations as well.  While insects are the most species-rich and abundant group of macroscopic organisms on the planet, understanding many aspects of their annual cycles and behavior drastically trails behind the ability to identify and classify them. 

Migration is defined as the cyclical travel of an animal as it returns to its place of departure.  It can be accomplished in one or multiple generations.  Some animals don’t migrate at all, and others move only short distances south or north.  While the guiding factors for navigation are still being discovered, migration is typically triggered by local climate, food availability, seasonality, or reproduction.

Adult Common Green Darner

Interestingly, about nine dragonfly species are known to migrate, including the Common Green Darner (Anax junius), Wandering Glider (Pantala flavescens), as well as some species in the Skimmer family such as meadowhawks and saddlebags. These dragonflies are known to travel up to 1500 miles over the full cycle of their migration, taking three generations.

Adult Wandering Glider

The secrets of dragonfly migration were discovered and confirmed by biologists measuring the chemical makeup of their wings.  In their immature or nymph stage, dragonflies grow their wings while still developing in local water.  Because the stable hydrogen isotope concentration varies in concentration by latitude, biologists can estimate the geographic region where adult dragonflies developed as nymphs.  

The female Common Green Darner (bottom) is held by
the male (top) after mating, when ovipositing in water.

From February to August the first generation emerges in the south and migrates north.  From June to October the second generation emerges in the north and migrates south.  Both of these generations have the ability to undergo rapid development from egg to adult.  But from November to March the third generation emerges in the south and is non-migratory, focusing mainly on producing another first generation for the cycle to start again.  It is this generation that employs a different strategy, developing slowly in late fall, entering diapause or actively induced dormancy over the winter, and emerging in early spring.

Dragonfly migration was not well understood until very recently.  Research published in 2018 detailed the journeys of Common Green Darners by analyzing 852 wing samples from eight different countries and utilizing 21 years of citizen scientist observations to link each specimen to its place of origin and establish its migration history. However, it is important to note that the timing of migration and the development of nymphs are both highly temperature dependent, so continued climate change could lead to fundamental changes in the migration cycles for dragonflies and other migrating insect species. So as you can see, migration isn’t just for the birds!

Cooling Conduct

Eastern Ringtail dragonflies obelisking

The unrelenting heat this summer has affected all living creatures, and while humans can escape into air-conditioned spaces, wildlife needs to rely on other ways to regulate their body temperature.  Often this is accomplished through different types of behavioral strategies acquired through adaptation, and some may seem quite odd until you understand the dynamics at work.

One of the most obvious behaviors (for humans at least), is sweating.  But many creatures don’t have sweat glands, or only sweat from their feet (like some canines), so they rely on panting instead.  In panting, animals breathe rapidly and shallowly with their mouths open, thereby increasing evaporation from the surfaces of their mouths.  This evaporation removes heat and acts as a cooling mechanism.  Panting is used by most mammals (like dogs) and many species of birds. While panting is effective at removing heat, dehydration is a risk so a nearby water source is important.  Birds may also spread their wings and body feathers to allow heat to dispel, and they have an elaborate breathing system that includes air sacs (in addition to lungs) to help them get rid of excess heat through panting.

A molting Northern Cardinal, panting and spreading its wings to cool down

Some birds, such as some species of vultures and storks, will voluntarily defecate on their legs to cool down.  Since bird poop is mostly liquid, it works by having an evaporative cooling effect, much like sweating.  As the poop dries on the bird’s legs, the heat is carried away and it brings down their body temperature.  Pelicans, herons, doves, owls, quail, and nighthawks, can employ gular fluttering, vibrating the muscles and bones in the throat and exposing moist throat membranes to the air, which helps regulate temperature by increasing evaporation.

Insects, like most all creatures, can also maintain a stable body temperature in at least a portion of their bodies through some interesting behavioral means.  While many insects need some heat to warm up their flying muscles, many will adjust/reduce their activity levels or seek out shady spots to handle extreme heat.  Dragonflies, for example, will often obelisk while perched in the midday hot sun, or point the tip of their abdomen directly up at the sun.  It is believed that this behavior reduces the heating effect by reducing the amount of surface area exposed directly to the sun’s rays.

Checkered Setwing exhibiting obelisking as a cooling behavior

When temperatures soar, four-legged animals such as squirrels, marmots, rabbits, bears, and even dogs and cats will lie flat on their stomachs on a cooler surface with their arms and legs stretched out from their bodies.  This behavior is called splooting, and it is thought that since their bellies have less fur and lots of blood vessels, they can dissipate the heat and absorb some of the coolness from the surface.  Also known as frogging or pancaking, splooting can take on various forms: the full sploot (all four legs out), the classic sploot (one leg tucked underneath the body while the other is kicked back), the side sploot (one leg tucked under the body and the other kicked out to the side), and the reverse sploot or toolps (when the animal lays on its back with its legs in the air)!

Fox Squirrel in a full sploot on our back porch

Regardless of the method, we all have to find some form of cooling conduct that allows us to survive until temperatures fall and (hopefully) the rains begin once again.

 

Late Summer Skimmers

The quiet waters of a pond like this make great dragonfly habitat

Dragonflies are conspicuous visitors to various bodies of water, especially in the warmer months of the year.    These visitors include members of the largest family of dragonflies, the Libellulidae, otherwise known as the skimmers. Skimmers can be large and colorful, some with distinctive wing patterns, and are often seen perching on twigs and branches.  In late summer, especially after summer rains, some locally common but not often observed species can be found around newly refilled ponds, including the Gray-waisted Skimmer (Cannaphila insularis), Needham’s Skimmer (Libellula needhami), and Slaty Skimmer (Libellula incesta).  

Found in shady or marshy ponds, typically with tall reeds or cattails, the male Gray-waisted Skimmer has greenish-blue eyes, a white face in front and metallic blue on top, and a dark brown or black thorax divided by several pale stripes.  Its abdomen is pruinose gray on the front half and black on the back half, and its wings are clear with extreme dark only at the tips.  Females and juveniles have a yellow-orange abdomen marked with dark brown or black.  Gray-waisted Skimmers are often found perching in the shade at the tips of vegetation, with their abdomen held nearly parallel to the perch.

Gray-waisted Skimmer, male

The male Needham’s Skimmer has reddish-orange eyes and face, and a thorax than is orange in front and paler or more tannish on the sides. Its abdomen is reddish-orange with a dark dorsal stripe down the length, and its orange wings are somewhat darker along the leading edge.  Females and juveniles have brown eyes and faces, a yellowish-brown thorax, and their abdomens are yellow with a dark stripe running down the middle.  Needham’s Skimmers are typically found perching low on vegetation or overhanging the water’s edge.

Needham's Skimmer, male

Most often seen around marshy forest ponds, the male Slaty Skimmer has dark eyes and a metallic blue or violet face, and both the thorax and abdomen have an overall slaty-blue pruinescence.  The wings are typically clear, but can have a pale bluish stripe along the leading edge.  Females and juveniles have red-over-gray eyes and a pale face, a cream-colored thorax with broad dark shoulder stripes, and a black abdomen with yellowish-orange markings. Females also have more prominent dark wing tips and develop a pale pruinosity at maturity.  Males perch on top of tall grasses and sticks most often in sunlit areas.

Slaty Skimmer, male

Check out your local pond or body of water before the end of September, and you just might be rewarded with a sighting of these less common, late summer skimmers!

Outmaneuvering Mosquitos

Mosquitos can be a nuisance in the hot summer months.

As the temperatures start to increase so do the ads for mosquito-control companies that offer to blanket spray residential landscapes.  While many of these businesses claim that their treatments only kill mosquitos and other pests, in reality the broad-spectrum insecticides they use kill many other species.

Broad-spectrum insecticides are indiscriminate, and along with killing mosquitos, they also kill pollinators and other beneficial insects such as bees, butterflies, moths, caterpillars, dragonflies, damselflies, and lady beetles.  The damage continues further up the food chain, when birds die as their insect food disappears and aquatic animals such as fish die when these chemicals wash off our landscapes and flow into nearby creeks, ponds, rivers, and lakes. Even spraying with essential oils such as peppermint, rosemary, and lemongrass is discouraged, as these can also kill beneficial insects.

Keeping mosquitos at bay can be vital, with many mosquito-borne tropical diseases such as West Nile, Zika, and Dengue fever spreading in range.  However, there are other natural, safer alternatives to using broad-spectrum insecticides.  It starts with understanding that mosquitoes can breed in less than one inch of water, and that the most effective way to reduce their numbers is to target the larvae, not spray adults.  

Moving water discourages female mosquitoes from laying eggs.

Begin by removing any standing water in gutters, bird baths, flower pot saucers, children’s pools, pet bowls, watering cans, and anything else that can hold water. Female mosquitoes avoid laying eggs in moving water, so consider adding a small pump or fountain to a water feature. For standing water that cannot be drained, use a mosquito dunk that contains the natural bacterium Bti (Bacillus thuringiensis israelensis) that kills mosquito larvae as they hatch, and consider adding native mosquitofish (Gambusia species) if the water feature is permanent.  Mosquitos are weak flyers, so even setting up fans reduces their ability to find an individual.

Black-chinned Hummingbirds get protein from eating insects like mosquitoes.

.

Neon Skimmer dragonflies love to prey on mosquitoes.

Most surprising to many, those who garden for wildlife using native plants have fewer mosquito problems than those with non-native turf lawns.  Native plants attract natural mosquito predators such as birds (warblers, wrens, woodpeckers, hummingbirds), dragonflies, damselflies, frogs, turtles, and bats.  Hummingbirds consume hundreds of insects daily in addition to drinking nectar, dragonflies and turtles eat mosquito larvae before they can hatch, frogs specialized sticky tongues nab all kinds of insects, and bats consume millions of insects on the wing.

The sticky tongues of frogs like this Leopard Frog can catch adult mosquitoes.

Red-eared Slider turtles eat mosquito larvae before they hatch.

It is important to note that even if you have a native landscape and don’t spray for mosquitos but your neighbors do, you will still lose pollinators and other beneficial insects.  Recent studies have shown that nearly 3 billion birds have disappeared from North America since 1970 due to loss of their insect prey, and many insect species are rapidly declining or vanishing altogether. 

Make your voice heard by spreading the message that insecticides are significant contributor to wildlife decline, and how we outmaneuver mosquitos in our landscapes truly matters to us all.

Bodacious Borers

Cottonwood Borer

As spring turns into summer in Central Texas, the heat brings out some of our most interesting creatures, most notably the native wood-boring beetles.  This group encompasses many species and families of beetles, all of whom eat wood either in their larval or adult form.  Most often they are found in or around dead or dying trees, as they are vital players in enabling the turnover of weak trees with strong ones, and acting as primary decomposers of wood which allows for the recycling of nutrients back into the soil.

One large family of beetles in the wood-boring group is the longhorn beetles, or Cerambycidae, typically characterized by their extremely long antennae which are often as long or longer than the beetle’s body.  Their family scientific name comes from the mythological Greek shepherd Cerambus, who was turned into a large beetle with horns after an argument with nymphs.  Three of the more noticeable wood-boring longhorn beetles in our area include the Banded Hickory Borer (Knulliana cincta), Cottonwood Borer (Plectrodera scalator), and Texas Bumelia Borer (Plinthocoelium suaveolens plicatum).

Banded Hickory Borer

With a body length of up to 1.4 inches, the Banded Hickory Borer is a fairly slender, typically gray to reddish-brown beetle with a pair of pale marks near the base of the elytra or wing covers that are sometimes absent, and tiny spines at the ends of the elytra.  Eggs are laid by the adults in bark crevices or directly into hardwoods such as oak, pecan, walnut, willow, and hackberry, upon which their larva feed.  In their first season, the larva feed just beneath the bark, then head deeper into the wood as they develop, a cycle which takes two to three years to complete.

Cottonwood Borer

The Cottonwood Borer is an elongate, unmistakably robust beetle with black and white markings that are formed by contrasting areas of white pubescence or fine short hairs on black body parts.  At a body length of up to 1.6 inches, the summer-active adults lay eggs in August and September on cottonwood and willow, where larva bore into the base and overwinter.  After two or three years to reach maturity, they pupate in chambers beneath the bark and emerge as adults in late spring, and are often found feeding on new shoots, leaf petioles (stems), and the bark of their host trees.

Texas Bumelia Borer

One can hardly miss the bright iridescence of the metallic green Texas Bumelia Borer, with its contrasting reddish-orange and black legs. The larva of this species feed on gum bumelia and mulberry, developing in the roots and trunks of these host plants.  With a body length of 1.5 inches, the adults are diurnal and often found on the trunks of their host plants, although they typically feed on flower nectar and are attracted to lights.

Despite their large size, most native wood-boring beetles are not pests.  Instead, they take advantage of dead and dying trees and aid in the natural decomposition process. As you venture out and about this summer, see if you can find some of these bodacious borers!

A Different Kind of Longhorn

Cottonwood Borer

The Cerambycidae are a family of longhorn beetles, typically characterized by extremely long antennae, often as long as or longer than the beetle’s body.  Also called longicorns, over 400 species have been described in Texas alone.  The scientific name of this beetle family is named after the shepherd Cerambus, a mythical Greek figure who was transformed into a large beetle with horns after an argument with nymphs.  Most of these beetles can fly well and are found on tree trunks, logs, flowers, or come to lights at night.  Some even squeak as a defense mechanism when held, making a rocking motion with their head which rubs tiny ridges against the inside surface of their thorax.

Cottonwood Borer

Two of our more common longhorn beetles are the Cottonwood Borer (Plectrodera scalator) and the Long-jawed or Horse-bean Longhorn Beetle (Trachyderes mandibularis).  The Cottonwood Borer is one of the largest insects in North America, reaching 1.6 inches in length and 0.5 inches in width.  It has a bold black and white pattern on its body with long black antennae.  The white portions of the pattern are actually microscopic masses of hair.  Adults are active by day, feeding on leaf stems and shoots of cottonwood trees.  The female bores small holes in the base of the tree to lay her eggs.  The larvae take up to 2 years to mature, then they pupate for about 3 weeks in a root below ground, and once metamorphosis is completed they chew their way out of the root and dig their way to the surface.

Long-jawed Longhorn Beetle

Long-jawed Longhorn Beetle has a glossy black or dark brown body with 4 generally large but sometimes reduced yellow to yellow-orange markings, and segments of its antennae and legs alternating between black and yellow-orange.  It can grow to a length of 1.3 inches, and is generally common from March to November.  Its species name comes from the fact that the males have much expanded jaws or mandibles. Active during the day, adults are mostly found near wounded trees as they feed on oozing sap, and its larvae feed on native hackberries as well as non-native ficus and tamarisk species.

Goes fisheri

One of the subfamilies of the Long-horned Beetles is the Lamiinae, or Flat-faced Longhorns.  This includes the 9 New World species in the Goes genus, one of which is rare and endemic to Central Texas.  This species, Goes fisheri, was first described in 1941, but does not have a common name.  Beetles in this genus are typically twig girdlers or stem borers, although the food plant of G. fisheri is currently unknown.  It is distinguished from a more common species, G. pulcher, or the Hickory Borer, by the grayish pubescence of its elytra or wing covers.  G. fisheri is just over 1 inch long, not including its antenna, appears to be nocturnal in its habits, and is attracted to artificial light. 

This large family of longhorns includes beetles called sawyers, pruners, and girdlers in addition to borers.  Most are found in dead or dying wood, and some mine live plants.  While many of these beetles are considered to be occasional pests, it should be noted that they literally help shape the forest canopy and assist in recycling dead wood into precious soil.  All the more reason to appreciate this different kind of longhorn!

Mariposa de la Muerte

Commonly known as owlet moths, cutworms, or armyworms, moths in the Noctuidae family make up one of the largest families of Lepidoptera.  The word Noctuidae is derived from the Latin word noctua meaning ‘little owl’ and the largest moth in this family in the continental United States is the Black Witch (Ascalapha odorata).

The Black Witch moth has been known as mariposa de la muerte or ‘butterfly of death’ since the time of the Aztecs, when it was believed that they were harbingers of death.  With a wingspan of up to 6 inches, its upperside is mottled dark brown to grayish-brown with hints of iridescent purple and pink, and females, which are slightly larger and lighter in color than males, have a pale almost lavender-pink median band through both fore and hind wings.  

A Black Witch (male) attracted to our mercury vapor light

Common to abundant in the New World topics as far south as Brazil, the Black Witch flies year-round in south Florida and the Rio Grande Valley of Texas.  In June and July, summer monsoons in Mexico trigger this fabulous creature to migrate north through Texas, where it is often found roosting in garages, under eaves, or under bridges.  It has the ability to migrate great distances over bodies of open water, such as the Gulf of Mexico, and one specimen was recorded in 1903 in Leadville, Colorado, caught in a snowstorm on the Fourth of July!

Primarily nocturnal, the adult Black Witch is attracted to light and fermenting fruit.  Its larvae feed at night on a variety of cassias, acacias, ebony, mesquite, and other woody legumes, and rest during the day hidden under bark and branches.  Up to 3 inches long, its caterpillar is dark gray tinged with brown, with a pale stripe down the back and dark stripes down the sides, and it relies on this natural camouflage to make it difficult to spot.  Pupation occurs on the ground in scattered leaf litter within a fragile cocoon.  Black Witches breed year round in overlapping generations, and their adult stage is thought to last only three or four weeks.

A Black Witch (female) perched above our front door!

At first glance, this very large moth is often mistaken for a small bat hovering around a porch light, but it will eventually land and linger for several hours if undisturbed.  If this happens to you, you can only hope that the South Texas legend of the Black Witch is true, as it states, “If a Black Witch lands above your door and stays there for a while, you could win the lottery!”

Discovering Blacklighting

A large Polyphemus Silkmoth, Antheraea polyphemus, is always a 

welcome visitor.

Lepidoptera is the order of insects that includes both butterflies and moths.  While over 180,000 species of these insects have been identified worldwide, recent estimates suggest that this order may have more species than previously thought, and is among the four most speciose orders, along with Hymenoptera (sawflies, wasps, bees, & ants), Diptera (true flies, mosquitoes, gnats, & midges), and Coleoptera (beetles).  Of the approximately 180,000 known Lepidoptera species, some 160,000 are moths, with nearly 11,000 of them found in the United States, and many are yet to be described.

The Imperial Moth, Eacles imperialis, is another silkmoth that may 

come to a blacklight in Central Texas.

Carolina Sphinx, 

Manduca sexta

Small Heterocampa Moth, 

Heterocampa subrotata

With such huge numbers and such a diversity of species, how does one go about studying moths? A good place to start is while knowing that most moths are creatures of the night, they are also attracted to light.  The reason for this behavior is unknown, although one theory is that moths use a form of celestial navigation called transverse orientation.  They attempt to maintain a constant angular relationship to a bright celestial light, like the moon.  But since the moon is so far away, and the angle change is negligible, the moth appears to travel in a straight line.  This theory is tested when moths fly near much closer sources of light, such as a porch light or a campfire.  The angle to the light source changes constantly as the moth flies by, so the moth instinctively attempts to correct it by turning toward the light, thereby producing its erratic flight.

Cellar Melipotis, 

Melipotis cellaris

Giant Leopard Moth, 
Hypercompe scribonia

White Palpita Moth, 

Stemorrhages costata

Cisthene unifasc

Melonworm Moth, 

Diaphania hyalinat

Paler Diacme Moth, 

Diacme elealis

Eggplant Leafroller Moth, 

Lineodes integra

Ragweed Plume Moth, 

Adaina ambrosiae

Swag-lined Wave, 
Scopula umbilicata

Southern Emerald Moth, 
Synchlora frondaria

One way for the moth to keep a constant angle to a stationary light source is by becoming stationary itself, effectively being ‘trapped’ by the light rather than ‘attracted’ to it.  Those interested in studying moths have taken advantage of this fact, and have developed a method called blacklighting to attract and photograph moths.  The first step is to set up a light source, and either an ultraviolet light (also known as a blacklight) or a mercury vapor  light can be used. Mercury vapor is now the preferred source, as it provides a different spectrum of light than a blacklight, although a blacklight emits a greater spectrum of light.  Moths can see waves of light that humans cannot, so providing them with different spectrums will generally produce the greatest response. The light is carefully hung or positioned in front a vertical white sheet, which the light bounces off to produce a big, concentrated, glowing mass, while also providing a safe surface for the moths to land.

The blacklighting setup is positioned out of the wind and typically near a boundary between wooded and open areas.  The light is turned on at dusk and left on all night, as different species of moths are most active at different times.  After taking the desired photographs with a digital SLR with a macro lens and flash, the light is turned off and the sheet is given a vigorous shake to scatter the remaining moths.  After all that was done to ‘capture’ them with light for observation and photography, it would be a shame for them to become easy  quarry for insect-eating birds or other predators!   

Another opportunistic predator at a blacklight is this Mediterranean Gecko, which 
has captured an Underwing moth.