The following is a guest post by Memorial University student Andrew Chaulk. Andrew is looking into mosquito ecology an biodiversity . He recently attended a short course offered by the University of Florida’s FMEL in Vero Beach.
Just off a main road running through a small town in Florida, a small group of enthusiastic folks, both local and foreign, sit focused. Eyes trained on minute hairs, scales, and a plethora of other physical traits, we worked diligently; all of us training to identify the 174 species of mosquitoes which call North America home. What brought us all together? The advanced mosquito identification and certification course offered by the Florida Medical Entomology Lab in Vero Beach, Florida.
Toxorhynchites, one of the “good guys”. These mosquitoes won’t bite you, and their larvae are predators on other container-inhabiting mosquito larvae. Photo by Andrew Chaulk.
First offered in 2000 as a training course for mosquito control personnel in Florida, the course has since opened its doors, inviting students from across the United States and internationally. This year’s class comprised of 21 students, four of which were Canadian (including myself, Kate Bassett – a fellow Master’s student, and our supervisor, Dr. Tom Chapman), and one student had travelled all the way from Nigeria to receive this internationally recognized accreditation. Led primarily by Dr. Roxanne Connelly, a Louisiana born entomologist who specializes in mosquito biology and mosquito borne diseases, the course is the only one of its kind and covers the principles and skills needed to identify all known mosquito species in North America north of Mexico in a fast-paced and in-depth manner. The taxonomically based course is divided into two sections, with the first week covering adult mosquito keys, and the second, taught by retired entomologist George O’Meara, covers the larval keys.
George O’ Meara leading the class. Photo by Tom Chapman.
Having come all the way from St. John’s Newfoundland, we arrived in Vero Beach to a wonderful break from our typical early spring weather. The course, which ran from March 3rd to 14th, began with some brief introductions and a tour of the FMEL property before getting down to business. Each section of the course comprised of four days of instruction and practice with the keys followed by one morning of exams – one written and practical exam per section. The in class material was often broken up by opportunities to use a wide variety of mosquito collection methods. Demonstrations were also provided concerning methods of specimen preparation and during one such demonstration I was even given the opportunity to show the class how minuten pins are used since this method is not commonly used at the FMEL. Overall, while the learning curve for the course was rather steep and the instruction fast paced, there was an interesting combination of anxiety and comfort brought about by the very friendly and supportive atmosphere which I think created an excellent learning experience.
Greg Ross demonstrates some of the trapping and surveillance equipment, including lard can traps and CDC light traps. Photo by Andrew Chaulk.
Reflecting on my experience after returning to the snowy St. John’s, one unexpected yet valuable aspect of the course I took home with me was learning about the variety of backgrounds my peers had come from and how these all culminated in our taking the course together. From graduate students to naval officers, and mosquito control employees to research and medical scientists, our class was quite an interesting mix. While the foundation for my own interest in mosquitoes stems from my work for a graduate degree in biology at Memorial University of Newfoundland, I now have a much broader perspective on the amount of effort and resources that are invested in mosquito research and control.
Students work with FMEL’s teaching collection, which is extensive. Photo by Tom Chapman.
Taking everything into account, I see this course as being one of the most valuable experiences of my graduate experience to date. Still in the first year of a Master’s degree I am working on a project centered on the mosquitoes of our province. I am concerned with questions surrounding the biodiversity of these insects in our province, their ecology and behaviour, as well as identifying possible introduction pathways of novel species. Being able to see firsthand what the results of research in this area can develop into has provided perspective for my own project and also has given me ideas of where my research can take me in the future. My expectations for this course were well exceeded and I would recommend this course to anyone who is working with these insects in any aspect.
If you would like some more information concerning course content and registration for next year’s class please visit here.
Portrait of a house-killer: The eastern subterranean termite, Reticulitermes flavipes is commonly found in homes. Photo courtesy of USGS Bee Inventory and Monitoring Program/ by Sam Droege.
The following post is by Ben Friedson, an student of Biology at George Washington University
Termites are often thought to infest only tropical or temperate areas. In fact, they thrive in most parts of southern Canada, especially along the coasts. They are commonly found in large cities like Toronto or Ottawa. The most common type of termite to infest Canadian homes is the subterranean termite (in the East, Reticulitermes flavipes, in the West, Reticulitermes hesperus).
A mobile problem: Subterranean termites about to swarm. Photo by Ben Friedson.
Subterranean termites spend most of their lives underground, in colonies with up to 2 million members (depending on the species). In the spring, subterranean termites swarm when groups of reproductive termites go off to start new colonies. They feed on the wood of a home or building, targeting wooden floors, furnishings, window frames, doors, wall paneling and much more. As termites rarely show themselves in the open, infestations can be difficult to detect until damage becomes severe.
When inspecting your home for termite damage, look to identify at least one of the following:
Mud Tubes
If subterranean termites spend too much time above the ground, their bodies begin to dry out and they die. To avoid this, termite workers make mud tubes along the surfaces of walls, fences, tree trunks or steps so they can work and eat in the comfort of moist ground.
Termite mud tubes look as if someone has painted long thin lines on your home with dirt. Dry tubes are old tubes. Old tubes may indicate that the termites are still residing in your home. If you scrape open a moist mud tube, you may see the termites at work.
The most common places to find subterranean termites in a home are basements, garages or any other room on the ground floor.
Hollow Sounding Wood
All termites make tunnels through many types of substances like wood, mulch and drywall. Eventually, the internal structure of the material becomes so riddled with tunnels that it collapses. This is why it is so important to spot termites early, before severe damage occurs.
Unfortunately, you need X-ray vision in order to see the tunnels. However, you can determine the presence of tunnels by knocking on walls, steps or anywhere you suspect termites might be. If you tap a surface and it sounds hollow, this may be an indication of termite tunnels.
Another sign of termite damage is when you see strange spots or stripes on the surface of wooden items throughout the home such as steps, walls, window frames, doorways and furniture. Inspect your home in search of wood surface that appear discolored, warped or bubbling.
If you notice hollow spots on wood surfaces, the termites have eaten just about everything under a thin surface layer. Flakes of paint, wallpaper or plaster on the floor is a big indicator that hollow spots exist. Beware; termites can actually fall out of these spots, at times.
As home owners, you can prevent termite infestations by stopping any sources of moisture that would attract termites. In addition, you must ensure that landscapes are kept clean and neatly trimmed. Be sure that no trees are coming in contact with building walls. Firewood must be stored away from a building and kept dry.
Termite damage is a frustrating problem as it harms valuable property that must be repaired if it is neglected for too long. Contact an experience pest control company, immediately, if you suspect a termite infestation in your home.
Author Bio: Ben Friedson is a junior at George Washington University in Washington, DC, pursuing a BSc in Biology with a concentration in Entomology. He recently spent a semester studying at the University of Alberta, where courses in ecology heightened his interest in pest management and conservation issues.
Subterranean termites ready to swarm. Photo courtesy of Tom Murray.
This wasp has a problem! Three relatively enormous parasitic strepsipterans are occupying her abdomen…Photo by Sean McCann.
Who wouldn’t want to get to know the Strepsiptera? These animals are extremely odd, being obligate endoparasites of other insects, with a free-flying male and an eyeless, wingless female that never leaves the abdomen of her host. Different families of these parasites infect different hosts, ranging from silverfish and cockroaches to solitary and social wasps, leafhoppers, and froghoppers.
Allow me to introduce Xenos peckii, a strepsipteran parasite of Polistes fuscatus, the Northern Paper Wasp. As an entomologist, I have long been interested in these little-studied insects, so I was thrilled to get to help my colleague Mike Hrabar in his investigation their life history and reproduction.
Mike collected a several colonies of infected wasps from Maine and brought them back to the lab to observe their emergence, flight and mating behaviour in a systematic way. We used high speed videography and careful record keeping to document their life history in closer detail than had ever previously been recorded.
Not really bling. This wasp sports a heavy infestation of four developing Xenos, costing vast amounts of resources. Photo by Sean McCann.
From my perspective, one of the coolest things we learned is that the free-flying male opens his puparium by means of blade-like mandibles, which are used to cut along a zone of weakness in the pupal cap, functioning like a tiny can opener!
Head of male Xenos peckii. Note the scissor-like mandibles and the large and unusual compound eyes. Photo by Mike Hrabar. Figure 3G from Hrabar et al. 2014.
Check out the video below to see the male’s little mandibles working the cap open.
These little troopers fly immediately upon emergence, in stark contrast with most other insects, which need time to inflate and harden their wings. In fact, once the males begin beating their wings, they remain in flight continuously except for a brief period during mating.
Before our study, biologists had assumed that female Strepsiptera were completely immobile and passively waited for males to find them, but we observed that they move to adopt a distinct calling posture, elevating their cephalothorax up from the wasp’s abdomen, likely emitting a pheromone plume.
Female Xenos peckii in the abdomen of a Polistes fuscatus. This female is in the calling posture, elevating her cephalothorax. Photo by Mike Hrabar. Figure 4D from Hrabar et al. 2014.
The males smell this pheromone plume and fly toward it rapidly, in a zig-zag fashion reminiscent of pheromone-questing moths. As soon as a male reaches the female-infected host, he lands on her abdomen and walks down to where the female protrudes, using backwards steps with his heavily-modified tarsi.
Mid leg of Xenos peckii male. The tarsi are highly modified for gaining a strong grip on a wasp abdomen while searching for and mating with a female. Figure 8 from Hrabar et al. 2014.
Mating occurs rapidly, with typical copulation time being 3-5 seconds. As soon as mating is finished, the male is once again in flight, presumably in search of another female. After copulation, the female immediately withdraws from the calling posture and ceases calling other males. The following video was taken at 1000 frames/second with a high-speed video camera and shows the sequence from just after landing by the male through the majority of copulation.
This male Polistes fuscatus was weakening, and died while we were watching. Mike pinned the host, and we forgot about it for a while, until glancing at it we realized that one of the males was emerging! This shot was snatched quickly while the male had just popped off his cephalotheca. Photo by Sean McCann, Figure 2E from Hrabar et al. 2014.
We have shown that female Xenos are not just a passive receptacle or bag of eggs, but rather play a physically active role in soliciting mates. The male emergence is facilitated by using sharp mandibles to cut around an ecdysial suture line, and navigating the surface of his prospective mates host is aided by his extremely modified tarsi.
The short-lived males face a great challenge to locate and fly to a host with a calling female in the short amount of time they live (on average 2-2.5 hours). They are in constant flight from emergence until death with only a very short pause for mating. The female, by contrast, remains alive in her host, maturing a brood of eggs which she retains in her body until they hatch and crawl from her brood canal as motile planidial larvae.
These larvae will exit the brood canal at some point, but it is unclear exactly where they manage to find new hosts. It is possible they “deplane” at flowers and wait for a ride on a Polistes to a new nest of victims. Much more research will need to happen to fully understand these fascinating insects, but we have made a start at uncovering some of the mysteries of their emergence, communication and reproduction. Many more questions remain unanswered and provide opportunities for any natural historian to explore.
If you would like to read the whole paper, you can find it on the Canadian Entomologist site here, or if you are not a subscriber, I am hosting a corrected proof here.
The full citation for this paper is:
HRABAR, M., DANCI, A., MCCANN, S., SCHAEFER, P. W., and GRIES, G. 2014. New findings on life history traits of Xenos peckii (Strepsiptera: Xenidae). The Canadian Entomologist doi: http://dx.doi.org/10.4039/tce.2013.85 pp.1–14.
https://esc-sec.ca/wp-content/uploads/2016/12/lieutier_4_gonopteryx_rhamni.jpg6641000Sean McCannhttp://esc-sec.ca/wp/wp-content/uploads/2017/01/ESC_logo-300x352.pngSean McCann2014-03-11 06:00:152019-11-14 21:29:46The brief lives and loves of male strepsipterans
It was written by Philip Careless, Steve Marshall and Bruce Gill.
This link will be active and freely available for the next month, so do not worry about a paywall.
This research focuses on using natural history information to assess creative ways to monitor one of eastern North America’s most important invasive, exotic tree-feeding pests, the emerald ash borer (EAB). The Crabronidae species Cerceris fumipennis is a wasp that is known to provision its nests with metallic wood-boring beetles in the family Buprestidae. Therefore, there is potentially to find out where EAB is located based on whether nests of the wasps contain that particular beetle. It’s a clever approach, and although the basic biology of the system was already known, Philip and colleagues worked to quantify and fully assess this potential biosurveillance tool for the EAB. We need to know where this pest is, and an indicator such as C. fumipennis holds much potential.
I caught up with Philip and he kindly answered a few questions about this work:
What inspired this work?
Almost all graduate work begins as a spark in the advisor’s mind. Certainly this project came from the creative thinking of Dr. Stephen Marshall so he deserves credit for that. I was simply fortunate enough to be the one chosen to run with the idea. Though, more importantly, he and the rest of the advisory committee gave me enormous freedom to transform the question into a journey through the strange world of solitary wasps. As for fueling the fire, I would say it was the writing of entomologists like Howard Evans, a healthy dose of nature documentaries, and correspondence with enthusiastic forest managers like Troy Kimoto who are struggling to address pressing conservation challenges.
What do you hope will be the lasting impact of this paper?
I hope that it will help people think of other novel ways to utilize the often overlooked services that insects all around them provide and in turn care for and conserve biodiversity. In our case an insect that the public instinctively hates, fears, and kills has been transformed into an amazing, useful, and valued colleague.
Where will your next line of research on this topic take you?
We have over 370 nest-provisioning solitary wasps in Canada. Each species is eloquently designed to collect their specific preferred taxa – eg. Stictiella takes adult Lepidoptera, Isodontia takes Orthoptera, Crossocerustakes Psocoptera, etc. The next steps will be to look at our native wasps, identify what they provision with and then determine if they are well-suited to life as a biosurveillance tool – assisting with life science inventories or monitoring pests. As the prey choice of most solitary wasps is unknown, professionals and amateurs alike can assist by photographing provisioning wasps and uploading the images to bugguide.net or the like.
Do you have any interesting anecdotes about this research?
Sitting in the middle of a ball diamond under a beach umbrella with a butterfly net (watching wasps provision their nests) tends to draw a lot of curious looks and questions from passers by. On one such occasion in Windsor, Ontario – while showing a dog walker my prized wasp bringing back a beetle – I observed a novel form of predation. As the prey-laden female wasp diligently droned past us to the nest, the dog – previous quite bored – snapped it out of the air and ate it, prey and all! We humans were both surprised but the dog seemed quite pleased.
Brenna Wells hard at work, waiting to steal beetles from wasps.
For more information on this initiative, or even to get involved yourself, please visit the project website.
https://esc-sec.ca/wp-content/uploads/2017/03/ESC.034.jpg13562048Bloghttp://esc-sec.ca/wp/wp-content/uploads/2017/01/ESC_logo-300x352.pngBlog2014-02-24 10:37:172019-11-14 21:29:45Basing biosurveillance on good natural history: a case study of Crabronidae wasps and the emerald ash borer. TCE Editor’s Pick for 146(1)
It was an early morning after a long drive from Guelph to a small fruit farm in Chatham-Kent where my undergraduate student, Caitlyn, and I were conducting a small-plot spray trial to test the effect s of repellents against Drosophila suzukii (Spotted Wing Drosophila), a recent invasive and serious fruit pest. I knew the raspberry patch was heavily infested with D. suzukii so before getting to work, to amuse ourselves at the start of the day, I started gently shaking canes, and we watched the swarms of fruit flies disperse and hover over the fresh fruit. However, as I went to grab a branch low to the ground, I noticed something different about one of the fruit flies sitting on a leaf. It had characteristic white “racing stripes” along its thorax, unlike any other fruit fly I had seen. This was it! This was very likely Zaprionus indianus or African fig fly, another invasive and potential fruit pest that we knew was moving northwards from the southeastern USA. Caitlyn grabbed a vial and we successfully had, on 10 September 2013, what we thought was the first capture of this fly in Ontario and Canada.
Indeed the fly was Z. indianus, as determined by Meredith Miller, a M.Sc. student at the University of Guelph working on taxonomy of Drosophila spp. in Ontario. Through contact with Hannah Fraser at Ontario Ministry of Agriculture Food and Rural Affairs, we learned that their Ontario-wide monitoring program for D. suzukii had also picked up some African fig flies in apple-cider vinegar traps, and a few at an earlier date than our find in Chatham-Kent. Colleagues in Quebec (Jean-Phillipe Légaré and others at MAPAQ) had also found what they believed were Z. indianus. Once all the material was collected and examined by Meredith, we submitted a scientific note documenting our Z. indianus discovery in Canada that was published by the Journal of the Entomological Society of Ontario.
Zaprionus indianus is native to the Afrotropical region. It was found in Brazil in 1998 where it was given its common name because it became a significant pest of figs. In 2005, Z. indianus was discovered in Florida and has since been found successively further north and west in the USA (see a map of its distribution here). It is likely that the North American infestation did not come from the Brazilian population. Zaprionus indianus is the only member of Zaprionus present in Canada, and therefore the reddish-brown head and thorax and particularly the silvery stripes that extend from the antennae to the tip of scutellum can be used as distinguishing features.
Unlike D. suzukii (thankfully!), female Z. indianus do not possess heavily sclerotized and serrated ovipositors and are not currently seen as a serious threat to temperate fruit crops. They have been reared from a number of tropical, tree-ripened fruits in Florida and there is concern in vineyards in the eastern USA, where sometimes they outnumber D. suzukii in traps. It is possible that Z. indianus can use fruit that has been oviposited in by D. suzukii, thus increasing damage and possibly complicating control measures. In Canada, particularly Ontario and Quebec, winter temperatures may preclude establishment of African fig fly, and yearly re-infestation from the south would be necessary for it to show up in future years. At all but one site, we found just 1-4 flies during late summer and early fall per site, so it will be interesting to see what happens to numbers this coming growing season. In tropical and sub-tropical locations much larger populations have been detected the year following first detection.
For the past 1.5 years I have been working as a post-doctoral fellow at the University of Guelph with Rebecca Hallett on D. suzukii. We are developing a push-pull management strategy using volatile plant compounds to repel and attract this pest. With the occurrence of Z. indianus and possible reoccurrence in larger numbers in the future, we may have a unique opportunity to study how two recent invaders using similar resources interact, and also, perhaps, a more significant challenge ahead of us in developing management strategies. If you are interested in this topic or have current or future experiences with Z. indianus, I and co-authors on the scientific note would appreciate hearing from you. You can contact me at renkemaj@uoguelph.ca.
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Renkema J.M., Miller M., Fraser H., Légaré J.P. & Hallett R.H. (2013). First records of Zaprionus indianus Gupta (Diptera: Drosophilidae) from commercial fruit fields in Ontario and Quebec, Canada, Journal of the Entomological Society of Ontario, 144 125-130. OPEN ACCESS [PDF]
https://esc-sec.ca/wp-content/uploads/2017/03/ESC.016.jpg16662071Bloghttp://esc-sec.ca/wp/wp-content/uploads/2017/01/ESC_logo-300x352.pngBlog2014-02-03 06:00:122019-11-14 21:29:43African fig fly shows up in Canada: first occurrences of another fruit-infesting fly and potential pest.
A unique experience for the mosquito enthusiast – FMEL’s mosquito identification course 2014
Just off a main road running through a small town in Florida, a small group of enthusiastic folks, both local and foreign, sit focused. Eyes trained on minute hairs, scales, and a plethora of other physical traits, we worked diligently; all of us training to identify the 174 species of mosquitoes which call North America home. What brought us all together? The advanced mosquito identification and certification course offered by the Florida Medical Entomology Lab in Vero Beach, Florida.
Toxorhynchites, one of the “good guys”. These mosquitoes won’t bite you, and their larvae are predators on other container-inhabiting mosquito larvae. Photo by Andrew Chaulk.
First offered in 2000 as a training course for mosquito control personnel in Florida, the course has since opened its doors, inviting students from across the United States and internationally. This year’s class comprised of 21 students, four of which were Canadian (including myself, Kate Bassett – a fellow Master’s student, and our supervisor, Dr. Tom Chapman), and one student had travelled all the way from Nigeria to receive this internationally recognized accreditation. Led primarily by Dr. Roxanne Connelly, a Louisiana born entomologist who specializes in mosquito biology and mosquito borne diseases, the course is the only one of its kind and covers the principles and skills needed to identify all known mosquito species in North America north of Mexico in a fast-paced and in-depth manner. The taxonomically based course is divided into two sections, with the first week covering adult mosquito keys, and the second, taught by retired entomologist George O’Meara, covers the larval keys.
George O’ Meara leading the class. Photo by Tom Chapman.
Having come all the way from St. John’s Newfoundland, we arrived in Vero Beach to a wonderful break from our typical early spring weather. The course, which ran from March 3rd to 14th, began with some brief introductions and a tour of the FMEL property before getting down to business. Each section of the course comprised of four days of instruction and practice with the keys followed by one morning of exams – one written and practical exam per section. The in class material was often broken up by opportunities to use a wide variety of mosquito collection methods. Demonstrations were also provided concerning methods of specimen preparation and during one such demonstration I was even given the opportunity to show the class how minuten pins are used since this method is not commonly used at the FMEL. Overall, while the learning curve for the course was rather steep and the instruction fast paced, there was an interesting combination of anxiety and comfort brought about by the very friendly and supportive atmosphere which I think created an excellent learning experience.
Greg Ross demonstrates some of the trapping and surveillance equipment, including lard can traps and CDC light traps. Photo by Andrew Chaulk.
Reflecting on my experience after returning to the snowy St. John’s, one unexpected yet valuable aspect of the course I took home with me was learning about the variety of backgrounds my peers had come from and how these all culminated in our taking the course together. From graduate students to naval officers, and mosquito control employees to research and medical scientists, our class was quite an interesting mix. While the foundation for my own interest in mosquitoes stems from my work for a graduate degree in biology at Memorial University of Newfoundland, I now have a much broader perspective on the amount of effort and resources that are invested in mosquito research and control.
Students work with FMEL’s teaching collection, which is extensive. Photo by Tom Chapman.
Taking everything into account, I see this course as being one of the most valuable experiences of my graduate experience to date. Still in the first year of a Master’s degree I am working on a project centered on the mosquitoes of our province. I am concerned with questions surrounding the biodiversity of these insects in our province, their ecology and behaviour, as well as identifying possible introduction pathways of novel species. Being able to see firsthand what the results of research in this area can develop into has provided perspective for my own project and also has given me ideas of where my research can take me in the future. My expectations for this course were well exceeded and I would recommend this course to anyone who is working with these insects in any aspect.
If you would like some more information concerning course content and registration for next year’s class please visit here.
Identifying Termite Damage in Canada
Portrait of a house-killer: The eastern subterranean termite, Reticulitermes flavipes is commonly found in homes. Photo courtesy of USGS Bee Inventory and Monitoring Program/ by Sam Droege.
The following post is by Ben Friedson, an student of Biology at George Washington University
Termites are often thought to infest only tropical or temperate areas. In fact, they thrive in most parts of southern Canada, especially along the coasts. They are commonly found in large cities like Toronto or Ottawa. The most common type of termite to infest Canadian homes is the subterranean termite (in the East, Reticulitermes flavipes, in the West, Reticulitermes hesperus).
A mobile problem: Subterranean termites about to swarm. Photo by Ben Friedson.
Subterranean termites spend most of their lives underground, in colonies with up to 2 million members (depending on the species). In the spring, subterranean termites swarm when groups of reproductive termites go off to start new colonies. They feed on the wood of a home or building, targeting wooden floors, furnishings, window frames, doors, wall paneling and much more. As termites rarely show themselves in the open, infestations can be difficult to detect until damage becomes severe.
When inspecting your home for termite damage, look to identify at least one of the following:
Mud Tubes
If subterranean termites spend too much time above the ground, their bodies begin to dry out and they die. To avoid this, termite workers make mud tubes along the surfaces of walls, fences, tree trunks or steps so they can work and eat in the comfort of moist ground.
Termite mud tubes look as if someone has painted long thin lines on your home with dirt. Dry tubes are old tubes. Old tubes may indicate that the termites are still residing in your home. If you scrape open a moist mud tube, you may see the termites at work.
The most common places to find subterranean termites in a home are basements, garages or any other room on the ground floor.
Hollow Sounding Wood
All termites make tunnels through many types of substances like wood, mulch and drywall. Eventually, the internal structure of the material becomes so riddled with tunnels that it collapses. This is why it is so important to spot termites early, before severe damage occurs.
Unfortunately, you need X-ray vision in order to see the tunnels. However, you can determine the presence of tunnels by knocking on walls, steps or anywhere you suspect termites might be. If you tap a surface and it sounds hollow, this may be an indication of termite tunnels.
How bad it can get: Subterranean Termite damage in a structure. Photo courtesy of the Armed Forces Pest Management Board.
Spots of Damage
Another sign of termite damage is when you see strange spots or stripes on the surface of wooden items throughout the home such as steps, walls, window frames, doorways and furniture. Inspect your home in search of wood surface that appear discolored, warped or bubbling.
If you notice hollow spots on wood surfaces, the termites have eaten just about everything under a thin surface layer. Flakes of paint, wallpaper or plaster on the floor is a big indicator that hollow spots exist. Beware; termites can actually fall out of these spots, at times.
As home owners, you can prevent termite infestations by stopping any sources of moisture that would attract termites. In addition, you must ensure that landscapes are kept clean and neatly trimmed. Be sure that no trees are coming in contact with building walls. Firewood must be stored away from a building and kept dry.
Termite damage is a frustrating problem as it harms valuable property that must be repaired if it is neglected for too long. Contact an experience pest control company, immediately, if you suspect a termite infestation in your home.
Author Bio: Ben Friedson is a junior at George Washington University in Washington, DC, pursuing a BSc in Biology with a concentration in Entomology. He recently spent a semester studying at the University of Alberta, where courses in ecology heightened his interest in pest management and conservation issues.
Subterranean termites ready to swarm. Photo courtesy of Tom Murray.
The brief lives and loves of male strepsipterans
This wasp has a problem! Three relatively enormous parasitic strepsipterans are occupying her abdomen…Photo by Sean McCann.
Who wouldn’t want to get to know the Strepsiptera? These animals are extremely odd, being obligate endoparasites of other insects, with a free-flying male and an eyeless, wingless female that never leaves the abdomen of her host. Different families of these parasites infect different hosts, ranging from silverfish and cockroaches to solitary and social wasps, leafhoppers, and froghoppers.
Allow me to introduce Xenos peckii, a strepsipteran parasite of Polistes fuscatus, the Northern Paper Wasp. As an entomologist, I have long been interested in these little-studied insects, so I was thrilled to get to help my colleague Mike Hrabar in his investigation their life history and reproduction.
Mike collected a several colonies of infected wasps from Maine and brought them back to the lab to observe their emergence, flight and mating behaviour in a systematic way. We used high speed videography and careful record keeping to document their life history in closer detail than had ever previously been recorded.
Not really bling. This wasp sports a heavy infestation of four developing Xenos, costing vast amounts of resources. Photo by Sean McCann.
From my perspective, one of the coolest things we learned is that the free-flying male opens his puparium by means of blade-like mandibles, which are used to cut along a zone of weakness in the pupal cap, functioning like a tiny can opener!
Head of male Xenos peckii. Note the scissor-like mandibles and the large and unusual compound eyes. Photo by Mike Hrabar. Figure 3G from Hrabar et al. 2014.
Check out the video below to see the male’s little mandibles working the cap open.
[youtube http://www.youtube.com/watch?v=aCeEsXVNiOY?rel=0&w=560&h=315]
These little troopers fly immediately upon emergence, in stark contrast with most other insects, which need time to inflate and harden their wings. In fact, once the males begin beating their wings, they remain in flight continuously except for a brief period during mating.
Before our study, biologists had assumed that female Strepsiptera were completely immobile and passively waited for males to find them, but we observed that they move to adopt a distinct calling posture, elevating their cephalothorax up from the wasp’s abdomen, likely emitting a pheromone plume.
Female Xenos peckii in the abdomen of a Polistes fuscatus. This female is in the calling posture, elevating her cephalothorax. Photo by Mike Hrabar. Figure 4D from Hrabar et al. 2014.
The males smell this pheromone plume and fly toward it rapidly, in a zig-zag fashion reminiscent of pheromone-questing moths. As soon as a male reaches the female-infected host, he lands on her abdomen and walks down to where the female protrudes, using backwards steps with his heavily-modified tarsi.
Mid leg of Xenos peckii male. The tarsi are highly modified for gaining a strong grip on a wasp abdomen while searching for and mating with a female. Figure 8 from Hrabar et al. 2014.
Mating occurs rapidly, with typical copulation time being 3-5 seconds. As soon as mating is finished, the male is once again in flight, presumably in search of another female. After copulation, the female immediately withdraws from the calling posture and ceases calling other males. The following video was taken at 1000 frames/second with a high-speed video camera and shows the sequence from just after landing by the male through the majority of copulation.
[youtube http://www.youtube.com/watch?v=QPiG8AV0XWY?rel=0&w=560&h=420]
This male Polistes fuscatus was weakening, and died while we were watching. Mike pinned the host, and we forgot about it for a while, until glancing at it we realized that one of the males was emerging! This shot was snatched quickly while the male had just popped off his cephalotheca. Photo by Sean McCann, Figure 2E from Hrabar et al. 2014.
We have shown that female Xenos are not just a passive receptacle or bag of eggs, but rather play a physically active role in soliciting mates. The male emergence is facilitated by using sharp mandibles to cut around an ecdysial suture line, and navigating the surface of his prospective mates host is aided by his extremely modified tarsi.
The short-lived males face a great challenge to locate and fly to a host with a calling female in the short amount of time they live (on average 2-2.5 hours). They are in constant flight from emergence until death with only a very short pause for mating. The female, by contrast, remains alive in her host, maturing a brood of eggs which she retains in her body until they hatch and crawl from her brood canal as motile planidial larvae.
These larvae will exit the brood canal at some point, but it is unclear exactly where they manage to find new hosts. It is possible they “deplane” at flowers and wait for a ride on a Polistes to a new nest of victims. Much more research will need to happen to fully understand these fascinating insects, but we have made a start at uncovering some of the mysteries of their emergence, communication and reproduction. Many more questions remain unanswered and provide opportunities for any natural historian to explore.
If you would like to read the whole paper, you can find it on the Canadian Entomologist site here, or if you are not a subscriber, I am hosting a corrected proof here.
The full citation for this paper is:
HRABAR, M., DANCI, A., MCCANN, S., SCHAEFER, P. W., and GRIES, G. 2014. New findings on life history traits of Xenos peckii (Strepsiptera: Xenidae). The Canadian Entomologist doi: http://dx.doi.org/10.4039/tce.2013.85 pp.1–14.
Basing biosurveillance on good natural history: a case study of Crabronidae wasps and the emerald ash borer. TCE Editor’s Pick for 146(1)
New “field assistant”, getting its unique identifying paint job.
I’m pleased to announce the following Canadian Entomologist paper as this issue’s Editor’s Pick: The use of Cerceris fumipennis (Hymenoptera: Crabronidae) for surveying and monitoring emerald ash borer (Coleoptera: Buprestidae) infestations in eastern North America.
It was written by Philip Careless, Steve Marshall and Bruce Gill.
This link will be active and freely available for the next month, so do not worry about a paywall.
This research focuses on using natural history information to assess creative ways to monitor one of eastern North America’s most important invasive, exotic tree-feeding pests, the emerald ash borer (EAB). The Crabronidae species Cerceris fumipennis is a wasp that is known to provision its nests with metallic wood-boring beetles in the family Buprestidae. Therefore, there is potentially to find out where EAB is located based on whether nests of the wasps contain that particular beetle. It’s a clever approach, and although the basic biology of the system was already known, Philip and colleagues worked to quantify and fully assess this potential biosurveillance tool for the EAB. We need to know where this pest is, and an indicator such as C. fumipennis holds much potential.
I caught up with Philip and he kindly answered a few questions about this work:
What inspired this work?
What do you hope will be the lasting impact of this paper?
Where will your next line of research on this topic take you?
Do you have any interesting anecdotes about this research?
For more information on this initiative, or even to get involved yourself, please visit the project website.
Dr. Christopher Buddle
Editor, the Canadian Entomologist
@CMBuddle
African fig fly shows up in Canada: first occurrences of another fruit-infesting fly and potential pest.
By Justin Renkema, Post-Doc, University of Guelph
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It was an early morning after a long drive from Guelph to a small fruit farm in Chatham-Kent where my undergraduate student, Caitlyn, and I were conducting a small-plot spray trial to test the effect s of repellents against Drosophila suzukii (Spotted Wing Drosophila), a recent invasive and serious fruit pest. I knew the raspberry patch was heavily infested with D. suzukii so before getting to work, to amuse ourselves at the start of the day, I started gently shaking canes, and we watched the swarms of fruit flies disperse and hover over the fresh fruit. However, as I went to grab a branch low to the ground, I noticed something different about one of the fruit flies sitting on a leaf. It had characteristic white “racing stripes” along its thorax, unlike any other fruit fly I had seen. This was it! This was very likely Zaprionus indianus or African fig fly, another invasive and potential fruit pest that we knew was moving northwards from the southeastern USA. Caitlyn grabbed a vial and we successfully had, on 10 September 2013, what we thought was the first capture of this fly in Ontario and Canada.
Zaprionis indianus photographed by Dr. Stephen Marshall in Africa. (Photo © Stephen A. Marshall, used with permission)
Indeed the fly was Z. indianus, as determined by Meredith Miller, a M.Sc. student at the University of Guelph working on taxonomy of Drosophila spp. in Ontario. Through contact with Hannah Fraser at Ontario Ministry of Agriculture Food and Rural Affairs, we learned that their Ontario-wide monitoring program for D. suzukii had also picked up some African fig flies in apple-cider vinegar traps, and a few at an earlier date than our find in Chatham-Kent. Colleagues in Quebec (Jean-Phillipe Légaré and others at MAPAQ) had also found what they believed were Z. indianus. Once all the material was collected and examined by Meredith, we submitted a scientific note documenting our Z. indianus discovery in Canada that was published by the Journal of the Entomological Society of Ontario.
Zaprionus indianus is native to the Afrotropical region. It was found in Brazil in 1998 where it was given its common name because it became a significant pest of figs. In 2005, Z. indianus was discovered in Florida and has since been found successively further north and west in the USA (see a map of its distribution here). It is likely that the North American infestation did not come from the Brazilian population. Zaprionus indianus is the only member of Zaprionus present in Canada, and therefore the reddish-brown head and thorax and particularly the silvery stripes that extend from the antennae to the tip of scutellum can be used as distinguishing features.
Unlike D. suzukii (thankfully!), female Z. indianus do not possess heavily sclerotized and serrated ovipositors and are not currently seen as a serious threat to temperate fruit crops. They have been reared from a number of tropical, tree-ripened fruits in Florida and there is concern in vineyards in the eastern USA, where sometimes they outnumber D. suzukii in traps. It is possible that Z. indianus can use fruit that has been oviposited in by D. suzukii, thus increasing damage and possibly complicating control measures. In Canada, particularly Ontario and Quebec, winter temperatures may preclude establishment of African fig fly, and yearly re-infestation from the south would be necessary for it to show up in future years. At all but one site, we found just 1-4 flies during late summer and early fall per site, so it will be interesting to see what happens to numbers this coming growing season. In tropical and sub-tropical locations much larger populations have been detected the year following first detection.
For the past 1.5 years I have been working as a post-doctoral fellow at the University of Guelph with Rebecca Hallett on D. suzukii. We are developing a push-pull management strategy using volatile plant compounds to repel and attract this pest. With the occurrence of Z. indianus and possible reoccurrence in larger numbers in the future, we may have a unique opportunity to study how two recent invaders using similar resources interact, and also, perhaps, a more significant challenge ahead of us in developing management strategies. If you are interested in this topic or have current or future experiences with Z. indianus, I and co-authors on the scientific note would appreciate hearing from you. You can contact me at renkemaj@uoguelph.ca.
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Renkema J.M., Miller M., Fraser H., Légaré J.P. & Hallett R.H. (2013). First records of Zaprionus indianus Gupta (Diptera: Drosophilidae) from commercial fruit fields in Ontario and Quebec, Canada, Journal of the Entomological Society of Ontario, 144 125-130. OPEN ACCESS [PDF]