Jump to content

Mountain pine beetle

From Wikipedia, the free encyclopedia
(Redirected from Mountain Pine Beetle)

Mountain pine beetle
Adult
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Family: Curculionidae
Genus: Dendroctonus
Species:
D. ponderosae
Binomial name
Dendroctonus ponderosae
(Hopkins, 1902)

The mountain pine beetle (Dendroctonus ponderosae) is a species of bark beetle native to the forests of western North America from Mexico to central British Columbia. It has a hard black exoskeleton, and measures approximately 5 millimetres (14 in), about the size of a grain of rice.

In western North America, an outbreak of the beetle and its microbial associates affected wide areas of lodgepole pine forest, including more than 160,000 km2 (40 million acres) of forest in British Columbia.[1] The outbreak in the Rocky Mountain National Park in Colorado began in 1996 and has caused the destruction of millions of acres/hectares of ponderosa and lodgepole pine trees. At the peak of the outbreak in 2009, over 16,000 km2 (4.0 million acres) were affected.[2] The outbreak then declined due to better environmental conditions, but many vulnerable trees had already been destroyed.[2][3]

Mountain pine beetles inhabit ponderosa, whitebark, lodgepole, Scots, jack,[4] limber, Rocky Mountain bristlecone,[5] and Great Basin bristlecone[6] pine trees. Normally, these insects play an important role in the life of a forest, attacking old or weakened trees, and speeding development of a younger forest. However, unusually hot, dry summers and mild winters in 2004–2007 throughout the United States and Canada, along with forests filled with mature lodgepole pine, led to an unprecedented epidemic.[7]

The outbreak may have been the largest forest insect blight seen in North America since European colonization.[8] Monocultural replanting, and a century of forest fire suppression have contributed to the size and severity of the outbreak, and the outbreak itself may, with similar infestations, have significant effects on the capability of northern forests to remove greenhouse gases (such as CO2) from the atmosphere.[9]

Because of its impact on forestry, the transcriptome[10] and the genome[11] of the beetle have been sequenced. It was the second beetle genome to be sequenced.

Life cycle

[edit]
A lodgepole pine tree infested by the mountain pine beetle, with visible pitch tubes

Beetles develop through four stages: egg, larva, pupa and adult. Except for a few days during the summer when adults emerge from brood trees and fly to attack new host trees, all life stages are spent beneath the bark.[12]

In low elevation stands and in warm years, mountain pine beetles require one year to complete a generation. At high elevations, where summers are typically cooler, life cycles may vary from one to two years

Female beetles initiate attacks. As they chew into the inner bark and phloem, pheromones are released, attracting male and female beetles to the same tree. The attacking beetles produce more pheromones, resulting in a mass attack that overcomes the tree's defenses, and results in attacks on adjacent trees.

Natural predators of the mountain pine beetle include certain birds, particularly woodpeckers, and various insects.


Tree infestations

[edit]

Effects

[edit]
Mountain pine beetles can damage whole regions of forest.

Mountain pine beetles affect pine trees by laying eggs under the bark. The beetles introduce blue stain fungus into the sapwood that prevents the tree from repelling and killing the attacking beetles with tree pitch flow. The fungus also blocks water and nutrient transport within the tree. On the tree exterior, this results in popcorn-shaped masses of resin, called "pitch tubes", where the beetles have entered.[13] The joint action of larval feeding and fungal colonization kills the host tree within a few weeks of successful attack (the fungus and feeding by the larvae girdles the tree, cutting off the flow of water and nutrients). In recent years, drought conditions have further weakened trees, making them more vulnerable and unable to defend against attack. When the tree is first attacked, it remains green. Usually within a year of attack, the needles will have turned red. This means the tree is dying or dead, and the beetles have moved to another tree. Within three to four years after the attack, very little foliage is left, so the trees appear grey.[7]

As beetle populations increase or more trees become stressed because of drought or other causes, the population may quickly increase and spread. Healthy trees are then attacked, and huge areas of mature pine stands may be threatened or killed. Warm summers and mild winters play a role in both insect survival and the continuation and intensification of an outbreak. Adverse weather conditions (such as winter lows of -40°) can reduce the beetle populations and slow the spread, but the insects can recover quickly and resume their attack on otherwise healthy forests.

Increases due to climate change

[edit]

Climate change and the associated changing weather patterns occurring worldwide have a direct effect on biology, population ecology, and the population of eruptive insects, such as the mountain pine beetle. This is because temperature is a factor which determines insect development and population success.[14] Mountain pine beetles are a species native to Western North America.[15] Prior to climatic and temperature changes, the mountain pine beetle predominately lived and attacked lodgepole and ponderosa pine trees at lower elevations, as the higher elevation Rocky Mountains and Cascades were too cold for their survival.[16] Under normal seasonal freezing weather conditions in the lower elevations, the forest ecosystems that pine beetles inhabit are kept in a balance by factors such as tree defense mechanisms, beetle defense mechanisms, and freezing temperatures. It is a simple relationship between a host (the forest), an agent (the beetle) and the environment (the weather and temperature).[15] However, as climate change causes mountain areas to become warmer and drier, pine beetles have more power to infest and destroy the forest ecosystems, such as the whitebark pine forests of the Rocky Mountains.[15]

Increased temperatures also allow the pine beetle to increase their life cycle by 100%: it only takes a single year instead of two for the pine beetle to develop. As the Rockies have not adapted to deal with pine beetle infestations, they lack the defenses to fight the beetles.[15] Warmer weather patterns, drought, and beetle defense mechanisms together dries out sap in pine trees, which is the main mechanism of defense that trees have against the beetle, as it drowns the beetles and their eggs.[15] This makes it easier for the beetle to infest and release chemicals into the tree, luring other beetles in an attempt to overcome the weakened defense system of the pine tree. As a consequence, the host (forest) becomes more vulnerable to the disease-causing agent (the beetle).[15]

Pine forests in British Columbia have been devastated by a pine beetle infestation, which has expanded unhindered since 1998 at least in part due to the lack of severe winters since that time; a few days of extreme cold kill most mountain pine beetles and have kept outbreaks in the past naturally contained. The infestation, which (by November 2008) has killed about half of the province's lodgepole pines (33 million acres or 135,000 km2)[17][18] is an order of magnitude larger than any previously recorded outbreak.[19] One reason for unprecedented host tree mortality may be due to that the mountain pine beetles have higher reproductive success in lodgepole pine trees growing in areas where the trees have not experienced frequent beetle epidemics, which includes much of the current outbreak area.[20] In 2007 the outbreak spread, via unusually strong winds, over the continental divide to Alberta. An epidemic also started, be it at a lower rate, in 1999 in Colorado, Wyoming, and Montana. The United States forest service predicts that between 2011 and 2013 virtually all 5 million acres (20,000 km2) of Colorado's lodgepole pine trees over five inches (127 mm) in diameter will be lost.[18]

The whitebark forests of the Rockies are not the only forests that have been affected by the mountain pine beetle. Due to temperature changes and wind patterns, the pine beetle has now spread through the Continental Divide of the Rockies and has invaded the fragile boreal forests of Alberta.[15]

Management

[edit]

Management techniques include harvesting at the leading edges of "green attack", as well as other techniques that can be used to manage infestations on a smaller scale, including:[21]

  • Pheromone baiting – is luring beetles into trees 'baited' with a synthetic hormone that mimics the scent of a female beetle. Beetles can then be contained in a single area, where they can more easily be destroyed.
  • Sanitation harvesting – is removing single infested trees to control the spread of beetle populations to other areas.
  • Snip and skid – is removing groups of infested trees scattered over a large area.
  • Controlled, or mosaic, burning – is burning an area where infested trees are concentrated, to reduce high beetle infestations in the area or to help reduce the fire hazard in an area. Controlling wildfires has significantly increased since the 1980s and '90s due to firefighting technology.
  • Fall and burn – is cutting (felling) and burning beetle-infested trees to prevent the spread of beetle populations to other areas. This is usually done in winter, to reduce the risk of starting forest fires.
  • Pesticides – Biopesticides such as chitosan have been tested for protection against the mountain pine beetle, and pesticides such as carbaryl, permethrin, and bifenthrin are used for smaller area applications.

Around the turn of the millennium the US Forest Service tested chitosan,[22][23] a biopesticide, to pre-arm pine trees to defend themselves against MPB. The US Forest Service results show colloidal chitosan elicited a 40% increase in pine resin (P<0.05) in southern pine trees. One milliliter chitosan per 10 gallons water was applied to the ground area within the drip ring of loblolly pine trees. The application was repeated three times from May through September in 2008. The chitosan was responsible for eliciting natural defense responses of increased resin pitch-outs, with the ability to destroy 37% of the pine beetle eggs.[24] Dr. Jim Linden, Microbiologist, Colorado State University, stated the chitosan increased resin pitch-outs to push the mountain pine beetle out of the tree, preventing the MPB from entering the pine tree and spreading blue stain mold.[25]

Searching out, removing, and destroying the brood in infested trees is the best way to slow the spread of mountain pine beetles; however, it may not protect specific trees. Spraying trees to prevent attack is the most effective way to protect a small number of high-value trees from mountain pine beetles. Carbaryl, permethrin and bifenthrin are registered in the United States for use in the prevention of pine beetle infestations. Carbaryl is considered by the EPA to likely be carcinogenic to humans. It is moderately toxic to wild birds and partially to highly toxic to aquatic organisms. Permethrin is easily metabolized in mammalian livers, so is less dangerous to humans. Birds are also practically not affected by permethrin. Negative effects can be seen in aquatic ecosystems, as well as it being very toxic to beneficial insects. Bifenthrin is moderately dangerous to mammals, including humans; it is slightly more toxic to birds and aquatic ecosystems than permethrin, as well as extremely toxic to beneficial insects.[26]

In 2015 fall and burn was the technique being used in Alberta where there is hope of limiting the outbreak to western Canada, preventing its spread to northern Saskatchewan and further towards eastern Canada where jack pine may be vulnerable as far east as Nova Scotia.[27] By 2022 the beetle population in Alberta had dropped by 94 per cent when compared to its peak in 2019, according to the Alberta Forestry service.[28]

Effects

[edit]

Fire hazard

[edit]

While weather and drought are important drivers of wildfires in sub boreal forests, bottom-up drivers of elevation and vegetation, including the fuel legacies of bark beetle outbreaks, are crucial factors influencing high-severity burning.[29] The outbreak of mountain pine beetles in the early 2010s, ten times larger than previous outbreaks,[30] created dead pine stands representing a potential fire hazard, prompting the BC government to direct fuel management activities in beetle areas as recommended in the 2003 Firestorm Provincial Review.[31] Huge swaths of central British Columbia (BC) and parts of Alberta have been hit badly, with over 40 million acres (160,000 km2) of BC's forests affected.[32]

Previously, cold spells had killed off bark beetles, but with warmer weather they attacked the forests.[33][34] The longer breeding season is another factor encouraging beetle proliferation. The combination of warmer weather, attack by beetles, and mismanagement during past years has led to a substantial increase in the severity of forest fires in Montana.[34][35] According to a study done for the U.S. Environmental Protection Agency by the Harvard School of Engineering and Applied Science, portions of Montana will experience a 200% increase in area burned by wildland fires, and an 80% increase in air pollution from those fires.[36][37]

On the carbon cycle

[edit]

Researchers from the Canadian Forest Service have studied the relationship between the carbon cycle and forest fires, logging and tree deaths. They concluded by 2020, the pine beetle outbreak will have released 270 megatonnes of carbon dioxide into the atmosphere from Canadian forests. There is yet to be an accepted study of the carbon cycle effect over a future period of time for North American forests, but scientists believe we are at a "tipping point" of our Western Forests becoming a source of carbon off-put that is greater than that of a "carbon sink".[30] Other scientists say that this "tipping point" will reverse itself as new forest life is established. This new growth will remove more carbon dioxide than the mature trees they are replacing would have. According to a 2016 study from the Pacific Institute for Climate Solutions rising levels of carbon dioxide may cancel out the pine beetle impact in British Columbia by 2020.[38] The fertilization effect of the increased CO2 levels has returned BC forests to a carbon sink as of 2016 per Werner Kurz of the Canadian Forest Service.[39]

On water resources

[edit]

Hydrologists from the University of Colorado have investigated the impacts of beetle-infested forests on the water cycle, in particular, snow accumulation and melt. They concluded that dead forests will accumulate more snowpack as a result of thinner tree canopies and decreased snow sublimation. These thinned canopies also cause faster snowmelt by allowing more sunlight through to the forest floor and lowering the snowpack albedo, as a result of needle litter on the snow surface.[40] Augmented snowpack coupled with dead trees that no longer transpire will likely lead to more available water.

In human culture

[edit]

In Custer, South Dakota, a giant effigy of a mountain pine beetle is set on fire each January as a part of its annual Burning Beetle celebration. The celebration began as an artistic response to environmental change caused by mountain pine beetle infestations in the Black Hills. [41]

See also

[edit]

References

[edit]
  1. ^ Irvin, Doyle (2017-02-15). "Blisters, Beetles and British Columbia: Global ReLeaf in Canada". American Forests Magazine. Archived from the original on 2021-07-11. Retrieved 2021-09-09.
  2. ^ a b "Bob Ward: Colorado Wildfires Are Linked to Global Warming". Huffingtonpost.com. 2013-06-19. Retrieved 2014-02-14.
  3. ^ "Broad-level Reconstruction of Mountain Pine Beetle Outbreaks from 1999-2015 across the Northern Region" (PDF). Fs.usda.gov. December 2019. Retrieved 2022-03-23.
  4. ^ Erbilgin, Nadir; Ma, Cary; Whitehouse, Caroline; Shan, Bin; Najar, Ahmed; Evenden, Maya (30 October 2013). "Chemical similarity between historical and novel host plants promotes range and host expansion of the mountain pine beetle in a naïve host ecosystem". New Phytologist. 201 (3): 940–50. doi:10.1111/nph.12573. PMID 24400902.
  5. ^ Bentz, Barbara J.; Hansen, E. Matthew; Vandygriff, James C.; Stephens, S. Sky; Soderberg, David (2021). "Rocky Mountain bristlecone pine (Pinus aristata) is a confirmed host to mountain pine beetle (Dendroctonus ponderosae)". Western North American Naturalist. 81. doi:10.3398/064.081.0102. S2CID 235324443. Retrieved 9 September 2022.
  6. ^ Bentz, Barbara J.; Millar, Constance I.; Vandygriff, James C.; Hansen, Earl M. (1 April 2022). "Great Basin bristlecone pine mortality: Causal factors and management implications". Forest Ecology and Management. 509: 120099. Bibcode:2022ForEM.50920099B. doi:10.1016/j.foreco.2022.120099. S2CID 246982193.
  7. ^ a b "The mountain pine beetle, Dendroctonus ponderosae, is a small insect, less than a centimetre long, which lives most of its life under the bark of pine trees, including lodgepole, ponderosa and western white pine". Archived from the original on 11 August 2010. Retrieved 2022-03-23.
  8. ^ Petit, Charles (2007-01-30). "In the Rockies, Pines Die and Bears Feel It". The New York Times. Retrieved 2009-02-09.
  9. ^ Kurz, WA; Dymond, CC; Stinson, G; et al. (2008-04-24). "Mountain pine beetle and forest carbon feedback to climate change". Nature. 452 (7190): 987–990. Bibcode:2008Natur.452..987K. doi:10.1038/nature06777. PMID 18432244. S2CID 205212545.
  10. ^ Keeling, Christopher I.; Henderson, Hannah; Li, Maria; Yuen, Mack; Clark, Erin L.; Fraser, Jordie D.; Huber, Dezene P.W.; Liao, Nancy Y.; Roderick Docking, T.; Birol, Inanc; Chan, Simon K.; Taylor, Greg A.; Palmquist, Diana; Jones, Steven J.M.; Bohlmann, Joerg (2012-08-31). "Transcriptome and full-length cDNA resources for the mountain pine beetle, Dendroctonus ponderosae Hopkins, a major insect pest of pine forests". Insect Biochemistry and Molecular Biology. 42 (8): 525–36. Bibcode:2012IBMB...42..525K. doi:10.1016/j.ibmb.2012.03.010. PMID 22516182.
  11. ^ Keeling, Christopher I; Yuen, Macaire MS; Liao, Nancy Y; Roderick Docking, T; Chan, Simon K; et al. (2013). "Draft genome of the mountain pine beetle, Dendroctonus ponderosae Hopkins, a major forest pest". Genome Biology. 14 (3): R27. doi:10.1186/gb-2013-14-3-r27. PMC 4053930. PMID 23537049.
  12. ^ "US Forest Service Forest Insect and Disease Leaflet Mountain Pine Beetle" (PDF). Fs.fed.us. Retrieved 2014-02-14.
  13. ^ "Mountain Pine Beetle". Ext.colostate.edu. 2014-01-08. Archived from the original on 2001-03-10. Retrieved 2014-02-14.
  14. ^ Sambaraju, Kishan R.; Carroll, Allan L.; Zhu, Jun; et al. (2012). "Climate change could alter the distribution of mountain pine beetle outbreaks in western Canada". Ecography. 35 (3): 211–223. Bibcode:2012Ecogr..35..211S. doi:10.1111/j.1600-0587.2011.06847.x.
  15. ^ a b c d e f g Epstein, P.; Ferber, D. (2011). Changing Planet, changing health. Los Angeles, California: University of California Press. pp. 138–160. ISBN 978-0-520-26909-5.
  16. ^ Kurz, W. (April 2008). "Mountain pine beetle and forest carbon feedback to climate change". Nature. 452 (7190): 987–990. Bibcode:2008Natur.452..987K. doi:10.1038/nature06777. PMID 18432244. S2CID 205212545.
  17. ^ "Natural Resources Canada". Archived from the original on 2010-06-13. Retrieved 2010-03-11.
  18. ^ a b Robbins, Jim (17 November 2008). "Bark Beetles Kill Millions of Acres of Trees in West". The New York Times.
  19. ^ Kurz, W. A.; Dymond, C. C.; Stinson, G.; Rampley, G. J.; Neilson, E. T.; Carroll, A. L.; Ebata, T.; Safranyik, L. (April 2008). "Mountain pine beetle and forest carbon feedback to climate change". Nature. 452 (7190): 987–990. Bibcode:2008Natur.452..987K. doi:10.1038/nature06777. PMID 18432244. S2CID 205212545.
  20. ^ Cudmore TJ; Björklund N; Carrollbbb, AL; Lindgren BS. (2010). "Climate change and range expansion of an aggressive bark beetle: evidence of higher reproductive success in naïve host tree populations" (PDF). Journal of Applied Ecology. 47 (5): 1036–43. doi:10.1111/j.1365-2664.2010.01848.x.
  21. ^ "Mountain Pine Beetle - Ministry of Forests, Lands and Natural Resource Operations - Province of British Columbia". 30 December 2012. Archived from the original on 30 December 2012. Retrieved 23 March 2022.
  22. ^ Mason, M. (1997). "Defense Response in Slash Pine: Chitosan Treatment Alters the Abundance of Specific mRNAs". Res. Pap. SRS-30.asheville, Nc: U.S. Department of Agriculture, Forest Service, Southern Research Station. 9P. 030 (1): 135–7. doi:10.1094/MPMI.1997.10.1.135. PMID 9002276.
  23. ^ Klepzig, K. (2003). "Cellular response of loblolly pine to wound inoculation with bark beetle-associated fungi and chitosan". Res. Pap. SRS-30.asheville, Nc: U.S. Department of Agriculture, Forest Service, Southern Research Station. 9P. 030.
  24. ^ O'Toole, Erin (2009-09-10). "Solution for Pine Bark Beetles May Help Front Range Trees". NPR Morning Edition - KUNC 91.5 FM Greeley, CO. Archived from the original on 2009-09-24. Retrieved 2010-02-26.
  25. ^ Porter, Steve (2009-09-11). "Arming trees against pine beetle invasions". Northern Colorado Business Report.
  26. ^ "Colorado State University Spraying Trees to Protect Against Mountain Pine Beetle: Common Questions for Landowners to Consider" (PDF). Csfs.colostate.edu. Retrieved 2014-02-14.
  27. ^ Hillary Rosner (April 2015). "Pine Beetle Epidemic". National Geographic. Archived from the original on March 18, 2015. Retrieved March 23, 2015.
  28. ^ Short, Dylan (6 Dec 2022). "Invasive mountain pine beetle population dropping significantly: Alberta Forestry". Calgary Herald. Archived from the original on 9 Aug 2024. Retrieved 3 Nov 2024.
  29. ^ Talucci, Anna C.; Meigs, Garrett W.; Knudby, Anders; Krawchuk, Meg A. (2022). "Fire severity and the legacy of mountain pine beetle outbreak: high-severity fire peaks with mixed live and dead vegetation". Environmental Research Letters. 17 (12): 124010. Bibcode:2022ERL....17l4010T. doi:10.1088/1748-9326/aca2c1. S2CID 253878500.
  30. ^ a b "Beetles may doom Canada's carbon reduction target: study". Terradaily.com. 2008-04-23. Retrieved 2008-04-28.
  31. ^ "British Columbia 2003 Firestorm Provincial Review". Archived from the original on 8 August 2010. Retrieved 2022-03-23.
  32. ^ "Mountain Pine Beetle - Ministry of Forests and Range - Province of British Columbia". For.gov.bc.ca. Archived from the original on 2013-04-05. Retrieved 2014-02-14.
  33. ^ "Beetles shaping Montana's forest lands". The Missoulian. July 31, 2005. Archived from the original on August 8, 2009.
  34. ^ a b "Forest Service finds varied beetle activity". The Missoulan. February 14, 2010.
  35. ^ "UM climate expert says triple-digit Julys will be norm". Billings Gazette. August 27, 2007.
  36. ^ "Forecast: More air pollution, Study predicts global warming will increase fires in Northern Rockies". Billings Gazette. July 29, 2009.
  37. ^ Spracklen, D. V; Mickley, L. J; Logan, J. A; Hudman, R. C; Yevich, R; Flannigan, M. D; Westerling, A. L (2009). "Impacts of climate change from 2000 to 2050 on wildfire activity and carbonaceous aerosol concentrations in the western United States" (PDF). Journal of Geophysical Research. 114 (D20): D20301. Bibcode:2009JGRD..11420301S. doi:10.1029/2008jd010966. Archived from the original (PDF) on 2011-07-19. Retrieved 2012-08-02.
  38. ^ "Scientists: Thriving BC forests outpace pine-beetle CO2 losses by 2020" (PDF). Pics.uvic.ca. April 11, 2016. Retrieved 2022-03-23.
  39. ^ Shore, Randy (April 12, 2016). "Global warming induced 'fertilization effect' causing B.C.'s forests to grow back faster than expected". National Post.
  40. ^ "Mountain pine beetle activity may impact snow accumulation and melt". ScienceDaily. Retrieved 2014-02-14.
  41. ^ "'Burn, beetle, burn': giant wooden effigies of invasive pest set on fire in South Dakota". The Daily Telegraph. 22 January 2024. Retrieved 22 January 2024.
[edit]