To spray or not to spray?

Earlier this afternoon I was interviewed by the local television station news program on the occasion of today being Canada’s National Day of the Honey Bee.

As I noted in my previous post, our city is currently being inundated with forest tent caterpillars. They are everywhere, and it’s hard to take a walk in one of our city’s wonderful green spaces without literally bumping into them at every turn as they rappel out of the trees above. Yesterday evening I spent a bit of time in my yard and then spent most of the rest of the evening removing strands of caterpillar silk that had festooned me.

What does this have to do with Honey Bee Day? Well, as the planned news story is bound to point out, the temptation for caterpillar-plagued homeowners is going to be to spray the heck out of the little leaf-munching critters with whatever pesticide they can get their hands on. That urge, I would argue, is a mistake for a number of reasons:

  • At this point in the tent caterpillar infestation, they have done almost as much damage as they can do. I have been observing that they are growing quite well (unfortunately for us!) and are going to be entering their pupal (cocoon) stage shortly. In other words, spraying now won’t do much to reduce any remaining damage that they may still do. The damage is mainly done.
  • In any case, in the face of such a massive infestation, spraying a can of pesticide at a few of the caterpillars is analogous to facing up against the JTF2 with a BB gun. You may inflict some minor damage for a moment, but you’re going to be overrun anyhow.
  • For smaller trees and shrubs (many of which these caterpillars only eat reluctantly at best anyhow), physical removal is as effective as spraying, and definitely much better for the environment.
  • And, spraying WILL impact other arthropods that are beneficial, including enemies of the forest tent caterpillar… and pollinators such as honeybees and various native pollinators (bumblebees and others).

That final point, I believe, is going to be one of the messages of the news item later today. Specifically, don’t lose sight of the forest for the trees.

Or, in other words, don’t lose sight of…

  • the honeybees
  • the native pollinators
  • the spiders that eat garden pests
  • the parasitoid flies that dine on tent caterpillars
  • the ladybugs that eat your aphids
  • the seed-dispersing ants
  • the dragonflies that eat mosquitoes
  • that beautiful swallowtail butterfly that brightens your day
  • …you fill in the blank…

…for the caterpillars.

I realize that even after reading this, some folks are still going to want to buy a can or two of pesticide and use it in their yards. If that is you, then:

  • be sure to carefully follow the directions on the label because they are there for a reason.
  • remember that these are powerful chemicals and that more is not necessarily better.
  • do your best to limit your application to the area in which you deem that it’s needed.
  • protect yourself, your kids, and your pets during and after spraying.

I’ll close with a personal story. The other day I was in a garden store buying a few bedding plants and some soil for our gardens and containers. Near the checkout there was a display of pesticide that is labeled for use against forest tent caterpillar. A customer and a store employee were talking about how best to use the stuff. Being a nosy entomologist I joined the conversation and made my case. Following more discussion between the three of us the customer finally said, “well, I know that this won’t really help with the problem in my yard, but I’m just so grossed out by them that I want to do something.”

I’m not sure if she ended up buying the product or not. But I suspect that a lot of spraying goes on for that very reason – i.e. a general dislike of insects – particularly in vast quantities – combined with a desire to do something… anything.

So, one last plea – please carefully consider your need use a pesticide in this situation. This plague will be over for the year soon enough. If we are lucky, natural enemies and disease will knock the population down this year and we won’t be seeing these creatures in any substantial quantities for quite a few years to come. In the meantime pesticides will not alleviate the problem, but they might end up hurting some friends that you may not even know that you have.

If you would like more information on pollinator conservation, please see this page hosted by the Xerces Society.

—–

(And a small side note: I’ve been seeing a few “friendly flies” around lately. So hopefully their population levels will pick up and they’ll help to wipe out this infestation. Fingers crossed! Keep in mind that these creatures are called “friendly” for a reason. Specifically, they like to land on various surfaces, including people. But they are harmless to everything except for forest tent caterpillar cocoons. If they are going to be a factor in knocking down the tent caterpillar infestation, there are going to be a lot of them around very soon. Here is a picture of one so that you know what to look for. Click on the photograph to enlarge. Notice the stripes on the thorax, the pattern on the abdomen, and the nice, big reddish/burgundy eyes.)

What’s with all these caterpillars?

Prince George, British Columbia, where I live, is in the midst of a forest tent caterpillar outbreak. The number of these little caterpillars has been increasing each year for the past three or so years. And that means that people are noticing them and asking questions. This morning I received a phone call from an affiliated pair of local radio stations and gave them an interview. That has not been my first inquiry on the topic and so, because Twitter is not the best long-term repository for such answers, I’m hoping that this blog post will answer many of the questions that folks might have. I’ll update this post as I receive new questions. So fire away.

What are some of the basic facts about this insect? The forest tent caterpillar is a native species with a range that extends across much of Canada and the USA. They generally present wherever its host trees reside, and they numerous hosts depending upon the geographical locale. Here in western Canada they often feed on aspens and other poplars. They also eat the leaves on some other leafy-tree (angiosperm) species, although there are also some that they avoid. But they do not attack conifers.

Despite their name, forest tent caterpillars do not construct tents. They get their name because they are related to other species – notably eastern tent caterpillars – that do. Forest tent caterpillars do spin silk and often leave large patches of silk in areas where they congregate. Although they do not have tents, they do aggregate in groups and they also move around in little parades following each other from branch to branch and from tree to tree. In some major outbreaks the number of aggregating and parading caterpillars can be so high as to make roadways slippery and dangerous to drive on.

What is the life cycle like? How long will these caterpillars be around? Forest tent caterpillars spend the winter in the egg stage. They hatch out around the same time as bud burst, which means that they have leaves to eat as soon as they leave their eggs. The new caterpillars are quite small, but grow rapidly as they defoliate trees. They move in groups from one tree to the next when food is depleted. The caterpillar stage lasts for a few weeks – usually from about mid-May until the end of June or early-July depending on the local climate. At that point, once they have grown to a good size, they pupate in little cocoons in sheltered locations. The pupal stage lasts a few weeks and then adult moths emerge in July and early-August. The adult moths only live a few days, during which time they mate and the female lays a band of a few hundred eggs around the branch of a host tree. Then the next generation is ready to take on the winter and to emerge the following spring. If you see a lot of adult moths one year (as we did last year here in Prince George), there is a good chance that you’ll have more caterpillars the next year. So keep an eye on the number of adult moths in your area this summer.

Why are there so many of them this year? Forest tent caterpillar populations are cyclical. On occasion – perhaps every ten years or so in any particular location – there can be a population explosion for a few years. The explosions are always self-limiting, as are most biological phenomena. A variety of factors are likely involved in ending an outbreak: disease, predators and parasitoids, starvation, or even untimely inclement weather. Sometimes one of these is all that’s needed to knock the populations down to sub-outbreak levels; often several of these factors work in concert to have that effect.

Are they going to kill my trees? Probably not. Most healthy trees can survive a few years of defoliation. In fact, many trees put out a second set of leaves after losing their first set. Add to that the fact that even in a large infestation, caterpillar populations in any given area may focus on one stand of trees one year, and another the next. So not every tree is necessarily going to be fully defoliated in every year. Defoliation takes away the tree’s food source, because trees, like other plants, make their food by catching sunlight and carbon dioxide with their leaves. So forest tent caterpillars reduce yearly growth in trees. In fact, researchers can study tree rings, which are indicators of growth, to track past outbreaks of defoliators.

A few trees will undoubtedly die if they are already stressed or if an infestation continues on for a number of years before the caterpillar population collapses. But if you see any large tree in an area that harbors forest tent caterpillars, you can bet that it’s already survived a number of previous outbreaks.

What can I do about it? Not much. Once populations get to this level, pesticide spraying is mainly futile, particularly in small areas such as a few trees in your backyard. At most you will spend money and time on a treatment that really won’t have much of an effect. Killing a few caterpillars may make it seem like you’re doing something, but there are plenty more where they came from. At worst, you will kill beneficial organisms (including some that would otherwise be happily killing forest tent caterpillars); you will have deleterious effects on your local ecosystem; and you could be exposing your family and pets to pesticides.

As pointed out by another entomologist on Twitter, there are some cases where larger scale use of Btk, which is not toxic to most creatures other than tent caterpillars, is advisable:

But those are usually special, large-scale situations, often involving aerial applications.

In most cases you can take a non-pesticide approach in your yard. You may want to do this if you have young trees in your yard that may not be as resilient as older, larger trees. You can remove caterpillars by hand or with your garden nozzle. And you can use sticky bands on the trunk so that nomadic parades of caterpillars can’t get to the leaves by climbing up the tree (although they may descend from above on little silk lines). Besides that, though, it’s best to just let nature take its course. The population will collapse soon enough, and in the meantime it is an interesting biological phenomenon to observe.

Have you done any research on forest tent caterpillars? Yes. About a decade ago I was involved in work on tree responses to having their leaves fed on by this insect. In one study we surveyed all of the genes that were turned on and off in leaves while the tree was being fed on. In another study, we found that while the caterpillar was feeding on some leaves, undamaged leaves in other parts of the tree began to release chemical signals into the air. We think that those signals are used to attract in enemies of the caterpillars. In other words, it seems that the tree is calling for help when it detects that it is being fed upon. There is still more work to do on that, however.  For instance, we are not sure which of the chemicals that the attacked tree is releasing – if any – serve to attract enemies of the caterpillar.

Can you make these things into wine? Yes.

Where can I find more information? Along with some of the links above, you can look here, here, and here.

Bark beetles on ice

Over the next while I plan to blog about various papers that have come out of our research program. I won’t get to all of them, obviously. But I do plan to pick and choose a few recent ones, and/or ones that have been highlights to this point in my career.

I’m going to begin with a very recent paper from my lab on bark beetle larval overwintering physiology. The paper is entitled “Global and comparative proteomic profiling of overwintering and developing mountain pine beetle, Dendroctonus ponderosae (Coleoptera: Curculionidae), larvae” and is available in open access here.

Context: Mountain pine beetles usually spend their winters as small, young larvae under the bark of their host tree. In this location, they are exposed to extremely cold temperatures, sometimes ranging below –30°C and even pushing down towards -40°C. Mountain pine beetle larvae survive those temperatures by resisting freezing. Sometime in the autumn they begin to accumulate at least one antifreeze compound (glycerol) in their bodies, and then in the spring they presumably return that antifreeze compound (and perhaps others) to general metabolism for energy to complete their development

Cold temperatures have historically limited the range of the mountain pine beetle both in terms of longitude and latitude, and in terms of elevation. However, climate change has reduced the probability of cold winter temperatures – particularly the probability of extreme cold events fairly early in the autumn or fairly late in the spring. At those ‘shoulder seasons’ the larval insects have either not accumulated enough antifreeze compounds in their tissues (autumn, around Hallowe’en) or have metabolized most of it (spring, around Easter). Those are the vulnerable periods, and deep cold at those can cause populations to crash rapidly.

The lack of unseasonal cold events or of generally very deep cold in the heart of the winter over the past years has been one factor that has driven the dramatic outbreak that we’ve seen in British Columbia. In addition, historically colder areas such as the eastern slopes of the Rockies and central Alberta or high elevation areas in the Rockies have not been as cold either. This has allowed mountain pine beetles to survive winters and to move into hosts, such as jack pine and whitebark pine, that they have not historically used in the recorded past. In the case of jack pine outbreaks, the fear is that the beetle, freed from its main confine on west slope of the Rockies, is poised to move across Canada’s boreal forest. In the case of whitebark pine, the insect may further endanger already-threatened trees that are important to higher alpine ecosystems.

What we did: Up until now, the main known antifreeze compound in mountain pine beetle larva has been glycerol. We suspected that there was more to the insect’s overwintering physiology than just that, as most insects use several strategies to avoid freezing. So we conducted a proteomics experiment. That means that we surveyed the levels of all of the proteins in early-autumn larvae and compared them to levels of proteins in late-autumn larvae to look for changes. Similarly, we compared the levels of all detectable proteins between early-spring and late-spring larvae. Because we now have copious amounts of genomic data for the mountain pine beetle, we could identify which proteins did what in the insect and we could draw some conclusions as to which metabolic pathways and physiological processes were activated or deactivated in overwintering larvae at different times of the year.

What we found: In total we found 1507 proteins in all of our larval samples. Of these, 33 either increased or decreased in their levels between early- and late-autumn and 473 either increased or decreased in their levels between early- and late spring. Of the proteins that were present in either increased or decreased levels in one of the two seasons, 18 of them showed such changes in both seasons. This Venn diagram from the paper shows this general result:

 

 

These proteins can be classified into a number of general functional groups, as seen in this pie chart from the paper:

 

Of course, large groupings are not as informative as looking at individual proteins. So that is what we did, as I will write about in the next section.

What this means: In proteomics work like this, when we are dealing with hundreds of proteins, it is obvious that there is so much complexity that it would take untold pixels to explain everything. In fact, like may ‘-omics’ studies, the original authors (us, in this case) have to pick and choose things that seem interesting to them and then leave it to others wearing different research glasses to find other interesting trends. What follows are a few highlights that we noticed in the context of our research program. Our hope is that others will take our data and find other interesting things that we may have missed.

Glycerol: Our results confirm past work implicating glycerol as an important antifreeze compound in the mountain pine beetle. The data also confirm previous work in our lab (Fraser 2011, referenced in the paper) that shows certain glycerol biosynthetic genes being upregulated in the autumn and downregulated in the spring. Of particular note were the extreme variations in an enzyme called PEPCK (phosphoenolpyruvate carboxykinase) which likely indicates some level of nutritional stress in larvae heading into the cold of winter.

Trehalose: Trehalose is a major hemolymph (insect “blood”) sugar, and it has been found to be important in insect cold tolerance in other species. The levels of an enzyme involved in trehalose biosynthesis increased significantly in the autumn and decreased significantly in the spring, indicating that trehalose might function alongside glycerol as an antifreeze compound.

2-deoxyglucose: The largest autumn increases and spring decreases for any protein that we observed was for one enzyme that is involved in the biosynthesis of 2-deoxyglucose. By looking at what 2-deoxyglucose does in other organisms, we can make some guesses as to what it is doing in the mountain pine beetle. It is possible that 2-deoxyglucose regulates larval metabolism to direct energy flow appropriately toward overwintering in the autumn; that it acts in stress physiology as the insect enters a difficult period of its life; or that it is functional as an antifreeze compound. It’s also possible that it functions in more than of these roles. What is clear is that this metabolite, not previously detected in this species, is likely very important in mountain pine beetle overwintering physiology. So we have some work on our hands to figure out exactly what it’s doing.

Stress, in general: The levels of a number of proteins associated with stress physiology – for instance ferritin, superoxide dismutase and phospholipid hydroperoxide glutathione peroxidase – increased in the autumn and, in some cases, decreased again in the spring. The fact that winter is a stressful period in a mountain pine beetle’s life cycle is obvious from the basic ecology of the organism. We now have a number of stress physiology protein targets to investigate in further research.

Energy use during development: The increases and decreases of particular enzymes involved in basic metabolism indicate that mountain pine beetle larvae put most of their resources into overwintering preparation in the autumn, and only when they have survived to the spring do they begin to divert resources to ongoing developmental processes.

Detoxification of host defenses: A number of proteins commonly involved in detoxification of host chemical defenses were present in autumn larvae but, for the most part, showed reductions in the larvae as the spring progressed. Previous work in our lab has shown that larvae in the late-summer experience extremely high levels of host defense compounds. So autumn larvae are working hard to get prepared for overwintering while also dealing with a toxic environment. Once the winter is over, and the host tree is long dead, it is likely that residual host toxins have either been removed by the beetle’s symbiotic fungi or that they have naturally degraded or dissipated. In any case, the detoxification enzymes are seeming not needed to nearly the degree in the late spring that they were during the autumn. The larvae that survive living in a toxic wasteland in the autumn and that do not freeze to death in the winter are then free to use remaining stores of energy plus whatever they can glean from their host tree to complete their developmental cycle through the spring and early-summer.

Why this is important: This is the first comprehensive look at what is going on in an overwintering bark beetle. While there has been a bit of previous physiological work on mountain pine beetles and a few other bark beetle species, our work in the Tria Project has moved us into the post-genomic era for the mountain pine beetle. That means that we have an extensive genomic database and that we can conduct experiments like this that reveal the workings of a number of physiological systems all at once. We are doing other ‘-omics’ work as well on overwintering mountain pine beetle larvae, including transcriptomics (monitoring messenger RNA levels during different seasons) and directed metabolomics (monitoring specific metabolites related to overwintering) work. And we are doing experiments where we track the expression of specific genes and the activity of specific enzymes revealed to be important during this phase of the insect’s life cycle. Of course our lab, alone, can’t do all of the experimentation suggested by these results. In fact, the data are so extensive that we can’t even conceive of all of the potential experiments. That is what is cool about ‘-omics’ research – there’s no telling who will look at it and think “ah ha! I have a great idea!”

Ultimately we hope that this paper has blown the door open on bark beetle overwintering physiology. Further research is bound to uncover new and interesting results, and since winter cold and climate change play such a large role in the growth of mountain pine beetle populations, such results will help us to understand better where and how the beetles are spreading into new regions and new, susceptible hosts.

Where we are going with this: As I mentioned above, the amount of data from this one study is staggering. This is our lab’s first publication from the larger Tria Project and there are others in the works. Some of them will also produce similar copious data. Others have been designed to look at specific small portions of this study and of some of our other data. We are currently focusing in on some of the metabolic pathways and physiological processes that I mentioned above. And we hope that others are able to take our data and use it for different analyses. For instance, we have surveyed protein levels across much of the larval developmental period. Perhaps others interested in insect development will find and be able to use new information on development in the Coleoptera (beetles) generally, and in bark beetles and other weevils specifically.

This was a really fun study. We certainly hope that the data will be as useful to others as it has been for us already. This work has also moved our research program firmly into the realm of insect overwintering research, and it has been a great introduction for us into proteomics and the era of “big data” in the biological sciences.

ResearchBlogging.org

Bonnett TR, Robert JA, Pitt C, Fraser JD, Keeling CI, Bohlmann J, & Huber DP (2012). Global and comparative proteomic profiling of overwintering and developing mountain pine beetle, Dendroctonus ponderosae (Coleoptera: Curculionidae), larvae. Insect biochemistry and molecular biology, 42 (12), 890-901 PMID: 22982448

Good news x 3

Most days environmental news is bleak to say the least. Truthfully, much of what’s going on is bleak. Species are going extinct at record rates. Climate change seems to be accelerating. Environmental degradation is having real effects on real people.

But even though the bad news is usually what makes it onto the evening news, there are bits and pieces of good news as well. And those deserve to be highlighted. So, let’s take a look at three of those today.

—–

A clawed cave spider: I always get excited when I hear about new species discoveries. That’s partly because it reminds me that no matter how much we think that we’ve figured out, there are still zillions of cool things out there that we have no clue about. We just need to look – sometimes in difficult places. In this case, the cool new find is a new species of spider, Trogloraptor marchingtoni. And not just a new species, but seemingly an entirely new family. If a new species is a big deal, a new family is an even bigger deal. By way of analogy ostriches, pelicans, and hummingbirds are each in separate bird families. So you might say that this newly discovered spider is approximately as different from other groups of spiders as those three groups of birds are from each other.

Trogloraptor is about 4 cm in diameter and lives mainly in caves and some old growth forests. It has substantial claws on its legs, but it is not clear what they are used for. And, now that we know about this creature there are a ton of other new and interesting things to find out as well. What will those discoveries be? Only time, and more hard work, will tell.

An (un)extinct snail: The Mobile River Basin in the southeastern United States is home to an amazing diversity of freshwater mollusks. Or perhaps it should be said that it was home to an amazing diversity of freshwater mollusks. After years of human influences, several dozen species are now extinct. However, in a recent survey of the snail fauna of the Cahaba River, researchers found a small population of a snail that has been thought to be extinct for decades. The snails can be bred in captivity and the authors of the linked research article point out several locations that may be suitable for reintroductions.

Monarch butterflies finally find protection: I’ll probably devote an entire post to monarch butterflies in the near future because they are so amazing. Briefly, these insects migrate across a huge swath of North America to a few very small wintering areas in forest groves the mountains of Mexico. So, entire populations that cover large chunks of geography in the summer are dependent upon a the survival of a few hectares of trees. Because of this, they are highly susceptible to deforestation in that region. Illegal logging has been impinging on these winter redoubts for decades. Removal of trees, even trees not used by the butterflies for roosting, allows more rain below the canopy. Wet butterflies are highly susceptible to winter cold.

The whole situation has been extremely dire in recent years. But now comes news that cooperative work between government, NGOs, private individuals, and the people who live near to the butterflies’ overwintering groves has almost completely eliminated illegal logging. Residents are now replanting trees in the butterfly groves and are working on developing a more robust ecotourism-based economy.

—–

Yes, there are spots of good news out there as well. It pays to look for them because we need to take the time to highlight these events and accomplishments. They are due in large part to the dedication and efforts of researchers and, as exemplified in the case of the monarchs, to the people who are most likely to be affected by the negative consequences of doing nothing.