Wednesday, December 17, 2014

Pest Alert: Boxwood Blight on Holiday Greenery

Note to the reader: This blog was originally published in December 2014. The first paragraph was updated in 2016 to reflect changes in the intervening years.

Boxwood blight has been a problem in North Carolina since it was first found here in the fall of 2011.  At first it was primarily a problem for the nursery industry, but it has been found in an increasing number of landscapes across the state. Now, according to NCDA&CS plant pathologist Leah Roberts, there are widespread reports this month [November 2016] of boxwood blight on holiday greenery being sold at retail outlets. For this reason we are re-publicizing this 2014 blog post.

Leaves darkened and drying, falling from twigs. Dark streaks on green stems.
Boxwood blight on tips from a holiday wreath. Photo (2014) by Matt Bertone, NCSU PDIC.
The situation took a new turn this month [December 2014] with the discovery by the North Carolina Department of Agriculture and Consumer Services of boxwood blight in boxwood holiday greenery sold at retail stores in a few North Carolina locations. We do not know how widespread this disease is on boxwood tips sold for holiday greenery, but this alert is being distributed to avoid potentially irreversible damage to established boxwood plantings. It is written for purchasers of boxwood wreaths or other holiday greenery made from boxwood. Tip growers and nursery operations should consult with their local County Cooperative Extension Service or the NCDA&CS Plant Protection Section.

dark leaf spots and dark stem streaks, as well as leaf loss, are typical symptoms of boxwood blight
Dark leaf spots (left) and dark stem streaks and defolation (right) are typical boxwood blight symptoms.

Affected boxwood show three main symptoms:
  • dark leaf spots
  • dark streaks on green twigs
  • leaf drop. 
In some cases leaves will lose their luster and dry up without the typical spots, but this can happen for reasons other than boxwood blight. American and English boxwoods are particularly susceptible and are rendered unsightly by the disease, although they do not die.  Sarcoccoca (sweet box) is also affected. The fungus can infect Pachysandra, too, causing leaf spots that could go unnoticed.

Boxwood blight is caused by a fungus known scientifically as Calonectria pseudonaviculata. It also goes by the names Cylindrocladium pseudonaviculata and Cylindrocladium buxicola. The fungus is harmless to other kinds of plants, to animals, and to people.

lower leaves brown and fallen on boxwood-blight-stricken shrub
Defoliation typically begins near the base of the boxwood plant and moves upward. Photo by Kelly Ivors.
Calonectria pseudonaviculata can be spread long distances on infected plant material and could be moved on contaminated clothing, bags, footwear, tools, vehicles, etc. used by workers moving from field to field. Short-distance spread is by splashing water and potentially by animal activity. The sticky spores do not easily become airborne except by water splash. Infected wreaths and roping that are exposed to rains could be a source of the fungus for nearby boxwood, sweet box, or Pachysandra.  Greenery that is hanging in a sheltered area will pose little immediate risk, but leaves falling from them could be a source of contamination later on.

What should you do if you have boxwood greenery for the holidays? As a precaution, we are recommending the following:
(1) Inspect boxwood greenery for blight, and immediately discard suspicious material, including fallen leaves.
(2) If there are boxwood shrubs in your landscape and if any boxwood greenery has been placed in an area where it is exposed to rainfall, relocate the greenery or bag and discard it. Do not handle the material when wet, because you could easily spread the spores.
(3) At the end of the holiday season, bag up all boxwood greenery and dispose of it in a landfill. Do not place it in the compost.
(4) Monitor nearby boxwood plantings for symptoms of the disease.

More information about this disease, including more photographs, can be found on NCSU’s Plant Pathology Portal. The Virginia Boxwood Blight Task Force web page is also a good reference and includes lists of best management practices for different situations.

Friday, September 19, 2014

Almost-plague-level Liriope Munchers!!!

The red bricks of NCSU's campus are a nice resting pad for some grasshoppers with full bellies. 

As I walked back from lunch the other day, I stopped by the library to take a peak at a single, large grasshopper on a rail. It was a differential grasshopper (Acrididae: Melanoplus differentialis), and although I don't usually look at these common insects it was too conspicuous not to stop and admire. The next day our good friend Dave Stephan came to me to ask if I had good pics of the species. I said no, but figured "Why not?" So Dave, being the great person he is, collected some for me. The odd thing though was what they were feeding on:

A differential grasshopper sitting among the destruction it and its friends caused.

That's right, liriope or monkey grass (Liriope sp.)! This widely planted, grass-like ground cover is rarely ever attacked by pests. The most frequently encountered insect feeding on this ornamental is the fern scale, Pinnaspis aspidistrae. Otherwise I could only find reference to snails and slugs as animals that feed on this host. These grasshoppers must not know that they are not supposed to feed on it, because there were hundreds in the large patch on campus! But why? We really don't know. I am also unsure if they will feed on the related lilyturf or mondo grass (Ophiopogon sp.).

Male Melanoplus differentialis, the differential grasshopper.

Female differential grasshopper.

Differential grasshoppers are typically pests of field crops like soybean, corn and cole crops, but also feed on many grasses and other plants. They can become serious pests in some areas during certain years. Their large size (about 2" long) also makes them conspicuous and also very hungry! Keep an eye out and let us know if you notice them feeding on liriope (or mondo grass) - perhaps this is an isolated event, but we don't know for sure.

Saturday, August 30, 2014

Attack of the Armyworms

The edge of the battlefield.

Spodoptera frugiperda (its species name meaning "fruit ruiner") was always a fun name to say when learning insect trivia for Linnaean games. The common name, fall armyworm, was also visually interesting, evoking marching hordes of munching, wriggling larvae. Apparently those descriptions aren't too far off. This year looks to have been a good year for them and a bad year for homeowners with lawns and crop producers. As evidence, there are now many reports about these pests from across the country (TX, OK, ALPA, and more).

Fall armyworms feed on a variety of plants - at least 80 species. Hosts like apples, strawberries, flowers and many weeds may be eaten by these caterpillars. They are even common in many field crops like alfalfa and soybeans. However, fall armyworms prefer to feed on various grasses (Poaceae), including some of our favorite foods (corn, wheat) and turf grasses (fescue, Bermudagrass, etc.). The larvae grow rapidly by chewing holes in leaves, or completely devouring entire grass blades. At first, larvae are less than a centimeter long and may be a bright green:

Young fall armyworms are more green than brown, but even older ones can vary in color. Specific traits other than color are best used to identify this species.

As they age through six instars (larval "stages"), they normally change to a darker green-brown color:

Mature fall armyworms can be close to 1.5" long and olive green-brown, giving them a military appearance further adding to the "army" moniker.

It takes about 16-30 days for the caterpillars to mature (depending on temperature) at which time they burrow into the ground where they pupate. Pupae are reddish brown and may be found in high densities in the soil of infested areas:

Pupae of fall armyworms are typical of many moths - reddish-brown, wiggly and buried in the soil.

After a little more than a week in warm weather, adult moths emerge from the pupae, take flight, and mate to make more armyworms. Eggs are laid on vegetation around grassy areas. Adults are readily sexed due to their strong color dimorphism. Females are a drab brown with subtle markings, while males have much more bold patterns and are actually pretty attractive:

An adult female fall armyworm, exemplifying the typical brown moth appearance (length ~2 cm).
Male fall armyworms are pretty nice looking for a pest (length ~2 cm).

The best way to tell larvae of fall armyworms from other armyworms in the genus Spodoptera (as well as other owlet caterpillars in the family Noctuidae) is through a combination of traits. The most often cited characteristic is the inverted yellow "Y" on the head (extending up the pronotum) as seen here:

Mature caterpillar's head and thorax, showing the inverted "Y" found on this species.

However, some other members of the genus have a similar "Y" and some fall armyworm instars lack it (later ones show it best). Thus Wagner et al. in Owlet Caterpillars of Eastern North America have a key that includes a character that is more reliable and separates out S. frugiperda from its relatives in the first couplet: the dorsal pinnacula (top-most black spots with an associated seta) are as big or bigger than the spiracles:

The black dots (pinnacula) on the tail end reveal the fall armyworm's identity: the dorsal ones (square of four shown by orange arrow) are each larger than the spiracles (blue arrow).

Fall armyworms can be found during warm parts of the year throughout the eastern United States (east of the Rocky Mountains). However, they can only survive winters in places like Texas and Florida (as well as Mexico and the Caribbean). Adults are strong fliers and migrate up through the states, sometimes with help from storms that blow them part of the way. Here in NC they may be present for several generations from spring through fall, while there is usually only one generation up north. The generations around late summer and early fall are usually the largest, thus the "fall" in the armyworm's name.

From Sparks (1979)

So what can be done and why is this year worse? Fortunately, most years do not see mass amounts of these caterpillars. Parasitoids and pathogens kill many of the armyworms in the overwintering areas, reducing the size of the resulting northern migrants. However, as Sparks (1979) describes below, some weather conditions in their year-round range can cause mass outbreaks:

From Sparks (1979)

If you fear you may have armyworms in your lawn or corn crop, monitoring early can help detect the caterpillars. For homeowners, the presence of birds in a lawn can indicate an abundance of larvae. However, by the time large, mature larvae are seen, control may not be helpful as they will soon pupate. Thresholds for crops and potential control methods can be found through the links below.

Helpful Resources:

Monday, August 18, 2014

Box Blight Confirmed in Wake County

Box blight has been confirmed in boxwood plants originating in a nursery in the NC mountains and offered for sale at the North Carolina State Farmers Market in Raleigh. The disease also has been confirmed at the Raleigh home of the vendor. A small number of customers may have purchased infected plants between the beginning of July and mid-August 2014.

Box blight is a destructive fungal disease of boxwood leaves and twigs. Symptoms include brown leaf spots, dark streaks on twigs, and extensive leaf drop. Sarcococca (sweetbox) and Pachysandra can also become infected. A fact sheet is available with additional information about identification and management of this disease. Note that sanitizer information is currently being updated. For most bleach formulations the correct ratio of bleach to water is now 1:14.

Personnel from the North Carolina Department of Agriculture and Consumer Services are attempting to trace the sales of these plants from the Farmers Market. Careful removal and destruction of all infected shrubs may help keep losses to a minimum and prevent further local spread.  If believe you may have purchased one of the plants in question, please contact the office of Phil Wilson, Plant Pest Administrator for the NCDA&CS at 919-707-3753. Other parties with questions about box blight should direct them to their local County Cooperative Extension Service office.

Friday, August 15, 2014

Soybean Disease Update from Steve Koenning

Physiological Scorch – Is it SDS, Stem Canker, Black Root Rot (CBR), Brown Stem Rot, or something else? 
We are receiving soybean samples in the Plant Disease and Insect Clinic (PDIC) that have symptoms of Physiological Scorch (Figure 1).  Most of the scorch in these samples is due to SDS or Sudden Death Syndrome, but numerous diseases can cause similar symptoms.  Regardless of the cause, this symptom is indicative of a problem with the vascular system once soybean has shifted to the reproductive phase.  Usually “Scorch” is the result of a root-rot such as SDS, CBR, dectes stem borer, or Phytophthora root rot.  Fungicide sprays will not impact these problems at all and should be avoided. Below are links to disease notes that will explain how to differentiate these diseases and what action to take in the future. 

Physiological scorch symptoms

Frogeye leaf spot, Target spot, and Stem Canker

Target spot of soybean and frogeye leaf spot have both been identified in North Carolina this year. Many cultivars are resistant to these diseases so there is no cause for alarm at this time.  If the disease is detected, a fungicide should be applied.  If target spot is identified, it warrants an application of a strobilurin fungicide.  If frogeye is identified, then a combination fungicide (StrategoYLD, Fortix, Quadris Top, or Affiance) may be warranted since resistance to strobilurin fungicides was identified last year in Beaufort County. See the North Carolina Agricultural Chemicals Manual for more information.  

Soybean Stem Canker has been found in the Piedmont and in Martin County.  Soybean stem canker must be controlled with varietal resistance. Fungicides rarely impact this disease, especially at this point in the season.

Friday, July 18, 2014

TSWV in Chrysanthemum

A greenhouse-grown chrysanthemum was received in the Plant Disease and Insect Clinic on July 10th and diagnosed with Tomato spotted wilt virus (TSWV) by Emma Lookabaugh. Symptoms consisted of dark leaf spots, lateral curling of the leaves at some of the spots, and at least one stem lesion.
TSWV symptoms on Chrysanthemum

Although TSWV is the most commonly diagnosed viral disease here in the PDIC, it has been a long time since we've detected it on chrysanthemum from North Carolina. We have no records of it during the current millennium, but if memory serves there was at least one case back in the late 1990s. The current case does not constitute an outbreak, but should serve as a reminder to growers to take measures to prevent this disease.

A different sort of TSWV symptom on mum, from a different sample.
Tomato spotted wilt occurs on hundreds of field and crops, including peanut, tobacco, tomato, pepper, and potato, as well as on a wide range of ornamentals. In the last 6-1/2 years we have diagnosed it on the following ornamentals from commercial sources: African marigold, angel-wing begonia, calla lily, Cyclamen, Gaillardia, Gerbera, Senecio confusus, Lisianthus, Lobelia, Madagascar periwinkle, Sedum, and Stoke's aster. Its sister virus, INSV, is a frequent problem on many ornamentals.

Mottling and ringspot symptoms on TSWV-infected Senecio (left) and Stokesia (right)
Both TSWV and INSV can cause a wide range of symptoms, including mottling, ringspots, stunting, and necrotic leaf and stem lesions. Both are members of the genus Tospovirus and are transmitted by minute insects called thrips*. One curious fact about this transmission is that the virus is acquired by the insect during its larval development, but then the insect itself becomes permanently infected. Of course the virus can be brought into a greenhouse with infected plants, and could be perpetuated through vegetative propagation.

A thrips compared to the tip of a pin.
These strategies against TSWV (and INSV) are recommended for greenhouse flower production:
  • Avoid growing vegetable transplants and flowers in the same greenhouse, and avoid growing plants of different ages together.
  • Screen greenhouse vents and air intakes to exclude thrips from entering the greenhouse.
  • Control weeds in and around the greenhouse. Many weeds are susceptible to tospoviruses and can serve as reservoirs of virus and thrips.
  • Monitor greenhouses for thrips activity using blue or yellow sticky cards, with the top 2/3 of the card placed above the plant tops.  Use two cards per 5000 sq. ft. of greenhouse area.
  • Use insecticides to manage thrips populations when necessary. Remove flowers from plants before treatment since the interior of flowers rarely get adequate coverage. It is important to note that some thrips populations have developed insensitivity to commonly used insecticides. In addition, no insecticide can completely eliminate thrips. Utilize the most effective chemistries wisely by rotating insecticides by mode of action (IRAC class) with each application, or at least with every generation of thrips. Always follow label directions and check that products are labeled for the intended crop. Details on insecticides for thrips management can be found in the NCSU Information Note on Western flower thrips and the University of Florida's thrips management information.
TSWV symptoms on Lobelia
If you suspect you have infected plants, we recommend having the diagnosis confirmed by a laboratory. Large growers with recurring problems may want to keep a supply of the simple lateral-flow ELISA tests on hand. Suppliers** include AC Diagnostics and Agdia. There is no cure, so all infected plants must be removed and destroyed. The potting mix of these plants should also be discarded, as this is where the thrips vectors pupate. Eliminate old stock plants as these are often sources of thrips and viruses.

More information about TSWV in the following crops is also available:
- peanut 
- tobacco
- tomato

Mike Munster and Steve Frank

*Grammatical footnote: The word thrips is both singular and plural.
**Mention of trade names and companies does not imply endorsement by North Carolina State University or the Plant Disease and Insect Clinic.

Tuesday, June 17, 2014

Bark & Ambrosia Beetle Academy

An Ambriosiodmus beetle excavated from its tunnel in a dead maple tree. The beetle is very small, only a few millimeters long.

Beetles are hard to avoid. They are the most diverse group of organisms, making up a whopping 25% of all multicellular species described to date. With a grab bag of over 350,000 species you're bound to have many that are interesting biologically or important to human endeavors. Scolytinae and Platypodinae (or Scolytidae and Platypodidae for the old schoolers) are two groups of highly specialized weevils (Curculionidae) that fit both of those profiles. Thus, if any insect groups merit their own week-long course it's these amazing beetles.

Luckily, a group of experts had that in mind when they developed the Bark & Ambrosia Beetle Academy, hosted and organized by Jiri Hulcr and his team at the University of Florida. I was fortunate enough to attend the first ever (and surely not the last) class in early May, and although I could tell many stories I am going to just mention some of the informative tidbits I learned through fun facts and photographs I took.

  • "Bark beetles" and "ambrosia beetles" are not taxonomic groups. They are not even completely black and white definitions. Some of these beetles feed only on bark and phloem (former), others grow fungi on which they feed (latter), and still others use different strategies like finding fungi or supplementing their wood diet with fungi. There are even "bark beetles" that bore into cacti or herbaceous plants - truly a diverse group.

Galleries under the bark of a loblolly pine (Pinus taeda) made by the southern pine beetle (Dendroctonus frontalis). Dark streaks of Ophiostoma blue stain fungus can be seen which compete with bark beetles and can cause mortality. Life under bark is a diverse ecosystem.
Bore holes lined with fungus grown by beetles. These ambrosia beetles can gnaw away the wood, but need to feed on the fungus to survive.

  • Fungus farming has evolved independently at least 11 times in these two groups (once in Platypodinae and several times in the Scolytinae). The beetles have special pockets (mycangia or mycetangia) on various body parts to carry the spores of their fungi. What was even more surprising to learn was that some ambrosia beetles actually "steal" fungus (called mycocleptae) from other beetles by tunneling close to the true farmers and letting the fungus grow into their tunnel!

A composite image of two different ambrosia beetles tunneling in a dead maple. The one on the left is a female Ambrosiophilus while the one on the right is a male Ambrosiodmus (see female in title image). The two upper right tunnels are in such close proximity that the fungus grows between them, a phenomenon that lead some beetles to evolve a fungus stealing strategy (including some species of the genus Ambrosiophilus).

  • Like wasps and some other animals, many of theses beetles have unusual sex systems (namely haplodiploidy) whereby males are produced from unfertilized eggs, while females come from fertilized eggs. What's more, in many of these beetles a foundress mother beetle will create a tunnel and lay many female eggs and one male that will end up mating with his sisters. The males in many cases are much smaller, cannot fly and are mainly used for one task - reproduction. In one extreme case, the species Ozopemon uniseriatus, the male is larviform (paedomorphic) and very different from a typical adult beetle. This sexual system along with living in a domicile with other members of the family is likely the reason one species, Austroplatypus incompertus, has become the only known eusocial (i.e. truly social) beetle, with a reproductive "queen" that has many offspring that do not reproduce and instead take care of their brothers and sisters. Colonies can last as long as 37 years (as does the queen) in a single eucalyptus tree!

The black twig borer (Xylosandrus compactus) is a species that exhibits haplodiploidy. Here a tiny, pale male (center) can be seen with his more massive sisters. He will fertilize them before they go colonize other twigs.

  • In the South, pines (Pinus sp.) are a prevalent tree that have their own groups of bark beetles, mostly members of the genus Ips and Dendroctonus. Several species inhabit trees just under the bark and are usually located at specific heights depending on the species. Ips are likely to invade unhealthy/dead trees, stumps and logs but can cause damage to healthy ones in certain situations. They are easily identified by the scooped-out rear (elytral declivity) with several spines surrounding the concavity (see below). Dendroctonus have a head that's visible from above and a gradual, even declivity. Though the black turpentine beetle (Dendroctonus terebrans) is large and infests healthy trees, it is rarely ever of concern. The southern pine beetle (Dendroctonus frontalis), on the other hand, aggressively attacks healthy trees en masse until tree death occurs. There are other Dendroctonus species that attack pines out West, with similar consequences (the mountain pine beetle Dendroctonus ponderosae, for example, is extremely damaging). The main difference between identifying D. frontalis and D. terebrans entrance holes and pitch tubes on pine is that the former's pitch flows are larger and nearer the base of the tree, while the latter's are smaller, more numerous and about breast height (see below).

Resin flows from a loblolly pine (Pinus taeda) under attack by southern pine beetles (Dendroctonus frontalis). Note that the "popcorn" (i.e. resin flows) is found in the crack between the bark, unlike Ips which will often bore right through the bark plates.
Close up of the small, hardened resin flow created by a southern pine beetle (Dendroctonus frontalis). These are made when the beetle enters the tree, which uses the resin to push the beetles out. When they exit, the beetles leave tiny dry holes because the tree is dead and does not produce the protective resin.
An adult southern pine beetle  (Dendroctonus frontalis). The total length of the beetle is ~3 mm. Note the head is visible from above as in all Dendroctonus
The resin flow of a black turpentine beetle (Dendroctonus terebrans) is much larger, as is the beetle itself  (about 5-8 mm).
Ips, like this Ips grandicollis, are frequently found under pine bark, but rarely cause problems for healthy trees. Their presence may mean that a tree is under stress or unhealthy in some way. This beetle is about 4 mm long and has a head hidden below the pronotum and spines circling the tip of the elytra. 

  • As most people know, some species of these beetles are extremely economically important. The classic example is the European elm bark beetle (Scolytus multistriatus), which along with a few other species transmits the causative agent of Dutch elm disease (Ophiostoma sp.). I learned that it's actually the maturation feeding of adult beetles (i.e. when they feed externally on new trees to gain nutrition) that partly helps to spread the disease. Other beetles are as or more destructive. Closer to home, the redbay ambrosia beetle (Xyleborus glabratus) is an exotic species from Asia that attacks healthy members of the family Lauraceae. It brings with it a fungal pathogen (Raffaelea lauricola) that causes laurel wilt, a disease that leads to mortality in these plants, many of which are important for forests and commercial use (e.g. avocado and cinnamon). Lastly, a commodity close to many people's heart is also under attack around the world: coffee. The coffee berry borer (Hypothenemus hampei) threatens the supply of the world's favorite caffeinated drink by boring into the seeds (the very beans we love) and living out their existence inside. Their small colonies significantly reduce the quality of the product and are difficult to control. All of these beetles are being studied to understand the best ways to manage and prevent their destructive, however unintended, nature.

The redbay ambrosia beetle (Xyleborus glabratus) is a tiny beetle that prefers infesting healthy trees in the family Lauraceae. Though not a pest in its native Asia, outside of its home range it transmits Raffaelea lauricola to trees, causing a wilting disease by interfering with the plant's vascular system.
The effects of laurel wilt (Raffaelea lauricola) can at first be seen in the dying leaves atop redbay trees. Upon further investigation, dark streaks can be seen under the bark of trees with the disease.

  • It's an uphill battle: every year we get more species of insect pests. Bark beetles, due to their cryptic nature and small size, are among the most commonly imported species. Over 60 species of bark beetles have been introduced and established in the US and the number will surely climb. Many are not important pests, relying largely on dead trees for their homes and food. Those that attack healthy trees, and especially those that bring with them pathogenic fungi, are the ones we should and do worry about. It should be noted, though, that these beetles in general are important decomposers of dead trees in natural systems and play a key role in forest health.

Xylosandrus amputatus was recently (2010) found in Florida and has now been collected in Georgia; its home range is East Asia. Luckily this species attacks dead or dying trees, so it will likely not become a pest.

  • Even though it may seem futile, we are developing new methods for controlling them. One researcher is even using the sounds these beetles produce to communicate with each other as a potential source of control, by confusing or repelling them. We are also not in this alone: many species of insects and other animals are predators or parasites of bark and ambrosia beetles. Knowing the good from the bad is important, as is implementing control strategies that reduce pest beetle populations while encouraging the livelihood of these beneficial insects.
Darkling beetles (Tenebrionidae) in the genus Corticeus (like this C. thoracicus) are often found among bark beetle galleries where they feed on many things, including the larvae of bark and ambrosia beetles. They can contribute to the control of some pest beetles.

A cylindrical bark beetle (Zopheridae: Colydiinae: Colydium lineola) is the perfect shape to fit into bark and ambrosia beetle tunnels. They are predators of the wood boring beetles.

Checkered beetles (Cleridae) are predators as larvae and adults. Here the larva of one is found under pine bark, likely feeding on the many Dendroctonus larvae located underneath.
A clown beetle (Histeridae) is yet another predator of bark and ambrosia beetles. Though this one was a moderate size (~4 mm), I have seen tiny Plegaderus (~1.5 mm) that were mistaken for bark beetles because they were found inside  tunnels.

It's not just beetles that feed on bark and ambrosia beetle. These maggots of the long-legged fly Medetera (Dolichopodidae) inhabit wood-boring beetle galleries and feed on their young. 

The course was excellent and I advise anyone interested in the subject to attend the next time it is held. I enjoyed meeting all of the participants, and the presenters were very helpful and had a wealth of knowledge. It's great to see so many people are interested in not just controlling these beetles, but understanding their lifestyles and evolution.

Participants signed a copy of one of Stephen Wood's tome on bark and ambrosia beetles.

For more photos, please visit my Flickr album from the trip (including photos of some other insects and nature I encountered).