Ayres MP and Lombardero MJ (2000) Assessing the consequences of global change for forest disturbance from herbivores and pathogens. Sci Total Environ 262:263-286
Bentz B, Régnière J, Fettig C, Hansen E, Hayes J, Hicke J, Kelsey R, Negrón J, Seybold S (2010) Climate Change and Bark Beetles of the Western United States and Canada: Direct and Indirect Effects. BioScience 60:602-613
Cale JA, Ding R, Wang F, Rajabzadeh R, Erbilgin N (2019a) Ophiostomatoid fungi can emit the bark beetle pheromone verbenone and other semiochemicals in media amended with various pine chemicals and beetle-released compounds. Fungal Ecol 39:285-295
Cale JA, Klutsch JG, Dykstra CB, Peters B, Erbilgin N (2019b) Pathophysiological responses of pine defensive metabolites largely lack differences between pine species but vary with eliciting ophiostomatoid fungal species. Tree Physiol 39:1121-1135
Cudmore T, Björklund N, Carroll A, Lindgren BS (2010) Climate change and range expansion of an aggressive bark beetle: Evidence of higher beetle reproduction in naïve host tree populations. J Appl Ecol 47:1036-1043
Erbilgin N, Cale JA, Hussain A, Ishangulyyeva G, Klutsch JG, Najar A, Zhao S (2017) Weathering the storm: how lodgepole pine trees survive mountain pine beetle outbreaks. Oecologia 184:469-478
Erbilgin N (2019) Phytochemicals as mediators for host range expansion of a native invasive forest insect herbivore. New Phytol 221:1268-1278
Franceschi B, Krokene P, Christiansen E, Krekling T (2005) Anatomical and chemical defenses of conifer bark against bark beetles and other pests. New Phytol 167:353-376
Hahn P, Maron J (2016) A Framework for Predicting Intraspecific Variation in Plant Defense. Trends Ecol Evol 31:646-656
Kane JM, Kolb TE (2010) Importance of resin ducts in reducing ponderosa pine mortality from bark beetle attack. Oecologia 164:601-609
Hahn P, Maron J (2016) A Framework for Predicting Intraspecific Variation in Plant Defense. Trends Ecol Evol 31:646-656
Kane JM, Kolb TE (2010) Importance of resin ducts in reducing ponderosa pine mortality from bark beetle attack. Oecologia 164:601-609
Kersten PJ, Kopper BJ, Raffa KF, Illman BL (2006) Rapid analysis of abietanes in conifers. J Chem Ecol 32:2679-2685
Kurz W, Dymond C, Stinson G, Rampley G, Neilson E, Carroll A, Ebata T, Safranyik L (2008) Mountain pine beetle and forest carbon feedback to climate change. Nature 452:987-990
Lotan JE, Critchfield WB (1990) Pinus contorta Dougl. ex. Loud. Lodgepole Pine. In Burns RM, Honkala BH (ed) Silvics of North America. Volume 1: Conifers. United States Department of Agriculture, Forest Service, pp 298-315
McKey D (1974) Adaptive patterns in alkaloid physiology. Am Nat 108:305-320
Raffa K, Powell E, Townsend P (2013) Temperature-driven range expansion of an irruptive insect heightened by weakly coevolved plant defenses. Proc Natl Acad Sci USA 110:2193-2198
Roth M, Hussain A, Cale JA, Erbilgin N (2018) Successful Colonization of Lodgepole Pine Trees by Mountain Pine Beetle Increased Monoterpene Production and Exhausted Carbohydrate Reserves. J Chem Ecol 44:209-214
Safranyik L, Shrimpton DM, Whitney HS (1974) Management of Lodgepole Pine to Reduce Losses from the Mountain Pine Beetle. Forestry Technical Report 1. Natural Resources Canada, Canadian Forest Service, Pacific Forestry Centre, Victoria, British Columbia.
Safranyik L, Wilson B (2006) Chapter 1. The biology and epidemiology of the mountain pine beetle in lodgepole pine forests. In Safranyik L, Wilson B (eds) The Mountain Pine Beetle: A Synthesis of Biology, Management, and Impacts on Lodgepole Pine. Natural Resources Canada, Canadian Forest Service, Pacific Forestry Centre, Victoria, BC, Canada, pp 3-66
Safranyik L, Carroll A, Régnière J, Langor D, Riel W, Shore T, Peter B, Cooke B, Nealis V, Taylor S (2010) Potential for range expansion of mountain pine beetle into the boreal forest of North America. Can Entomol 142:415-442
Schneider CA, Rasband WS, Eliceiri KW (2012) NIH Image to ImageJ: 25 years of image analysis. Nat Methods 9:671-675
Smithers LA (1962) Lodgepole Pine in Alberta. Bulletin 127. Canada Department of Forestry, Ottawa, Canada
McKey D (1974) Adaptive patterns in alkaloid physiology. Am Nat 108:305-320
Wiley E, Rogers B, Hodgkinson R, Landhäusser S (2016) Nonstructural carbohydrate dynamics of lodgepole pine dying from mountain pine beetle attack. New Phytol 209:550-562
Vazquez-Gonzalez C, Zas R, Erbilgin N, Ferrenberg S, Rozas V, Sampedro L (2020) Resin ducts as resistance traits in conifers: linking dendrochronology and resin-based defences. Tree Physl 40:1313-1326
Zhao S, Erbilgin N (2019) Larger Resin Ducts Are Linked to the Survival of Lodgepole Pine Trees During Mountain Pine Beetle Outbreak. Front Plant Sci 10:1-14
Zhao S, Klutsch JG, Cale JA, Erbilgin N (2019) Mountain pine beetle outbreak enhanced resin duct-defenses of lodgepole pine trees. For Ecol Manag 441:271-279
Bentz B, Régnière J, Fettig C, Hansen E, Hayes J, Hicke J, Kelsey R, Negrón J, Seybold S (2010) Climate Change and Bark Beetles of the Western United States and Canada: Direct and Indirect Effects. BioScience 60:602-613
Cale JA, Ding R, Wang F, Rajabzadeh R, Erbilgin N (2019a) Ophiostomatoid fungi can emit the bark beetle pheromone verbenone and other semiochemicals in media amended with various pine chemicals and beetle-released compounds. Fungal Ecol 39:285-295
Cale JA, Klutsch JG, Dykstra CB, Peters B, Erbilgin N (2019b) Pathophysiological responses of pine defensive metabolites largely lack differences between pine species but vary with eliciting ophiostomatoid fungal species. Tree Physiol 39:1121-1135
Cudmore T, Björklund N, Carroll A, Lindgren BS (2010) Climate change and range expansion of an aggressive bark beetle: Evidence of higher beetle reproduction in naïve host tree populations. J Appl Ecol 47:1036-1043
Erbilgin N, Cale JA, Hussain A, Ishangulyyeva G, Klutsch JG, Najar A, Zhao S (2017) Weathering the storm: how lodgepole pine trees survive mountain pine beetle outbreaks. Oecologia 184:469-478
Erbilgin N (2019) Phytochemicals as mediators for host range expansion of a native invasive forest insect herbivore. New Phytol 221:1268-1278
Franceschi B, Krokene P, Christiansen E, Krekling T (2005) Anatomical and chemical defenses of conifer bark against bark beetles and other pests. New Phytol 167:353-376
Hahn P, Maron J (2016) A Framework for Predicting Intraspecific Variation in Plant Defense. Trends Ecol Evol 31:646-656
Kane JM, Kolb TE (2010) Importance of resin ducts in reducing ponderosa pine mortality from bark beetle attack. Oecologia 164:601-609
Hahn P, Maron J (2016) A Framework for Predicting Intraspecific Variation in Plant Defense. Trends Ecol Evol 31:646-656
Kane JM, Kolb TE (2010) Importance of resin ducts in reducing ponderosa pine mortality from bark beetle attack. Oecologia 164:601-609
Kersten PJ, Kopper BJ, Raffa KF, Illman BL (2006) Rapid analysis of abietanes in conifers. J Chem Ecol 32:2679-2685
Kurz W, Dymond C, Stinson G, Rampley G, Neilson E, Carroll A, Ebata T, Safranyik L (2008) Mountain pine beetle and forest carbon feedback to climate change. Nature 452:987-990
Lotan JE, Critchfield WB (1990) Pinus contorta Dougl. ex. Loud. Lodgepole Pine. In Burns RM, Honkala BH (ed) Silvics of North America. Volume 1: Conifers. United States Department of Agriculture, Forest Service, pp 298-315
McKey D (1974) Adaptive patterns in alkaloid physiology. Am Nat 108:305-320
Raffa K, Powell E, Townsend P (2013) Temperature-driven range expansion of an irruptive insect heightened by weakly coevolved plant defenses. Proc Natl Acad Sci USA 110:2193-2198
Roth M, Hussain A, Cale JA, Erbilgin N (2018) Successful Colonization of Lodgepole Pine Trees by Mountain Pine Beetle Increased Monoterpene Production and Exhausted Carbohydrate Reserves. J Chem Ecol 44:209-214
Safranyik L, Shrimpton DM, Whitney HS (1974) Management of Lodgepole Pine to Reduce Losses from the Mountain Pine Beetle. Forestry Technical Report 1. Natural Resources Canada, Canadian Forest Service, Pacific Forestry Centre, Victoria, British Columbia.
Safranyik L, Wilson B (2006) Chapter 1. The biology and epidemiology of the mountain pine beetle in lodgepole pine forests. In Safranyik L, Wilson B (eds) The Mountain Pine Beetle: A Synthesis of Biology, Management, and Impacts on Lodgepole Pine. Natural Resources Canada, Canadian Forest Service, Pacific Forestry Centre, Victoria, BC, Canada, pp 3-66
Safranyik L, Carroll A, Régnière J, Langor D, Riel W, Shore T, Peter B, Cooke B, Nealis V, Taylor S (2010) Potential for range expansion of mountain pine beetle into the boreal forest of North America. Can Entomol 142:415-442
Schneider CA, Rasband WS, Eliceiri KW (2012) NIH Image to ImageJ: 25 years of image analysis. Nat Methods 9:671-675
Smithers LA (1962) Lodgepole Pine in Alberta. Bulletin 127. Canada Department of Forestry, Ottawa, Canada
McKey D (1974) Adaptive patterns in alkaloid physiology. Am Nat 108:305-320
Wiley E, Rogers B, Hodgkinson R, Landhäusser S (2016) Nonstructural carbohydrate dynamics of lodgepole pine dying from mountain pine beetle attack. New Phytol 209:550-562
Vazquez-Gonzalez C, Zas R, Erbilgin N, Ferrenberg S, Rozas V, Sampedro L (2020) Resin ducts as resistance traits in conifers: linking dendrochronology and resin-based defences. Tree Physl 40:1313-1326
Zhao S, Erbilgin N (2019) Larger Resin Ducts Are Linked to the Survival of Lodgepole Pine Trees During Mountain Pine Beetle Outbreak. Front Plant Sci 10:1-14
Zhao S, Klutsch JG, Cale JA, Erbilgin N (2019) Mountain pine beetle outbreak enhanced resin duct-defenses of lodgepole pine trees. For Ecol Manag 441:271-279