Host Resistance to Bark Beetles and Its Variations (original) (raw)
References
Amezaga, I. 1997. Forest characteristics affecting the rate of shoot pruning by the pine shoot beetle (Tomicus piniperda L.) in Pinus radiata D. Don and P. sylvestris L. plantations. Forestry 70, 129-37. Google Scholar
Amman G.D., McGregor, M.D., Schmitz, R.F. & Oakes, R.D. 1988. Susceptibility of lodgepole pine to infestation by mountain pine beetles following partial cutting of stands. Canadian Journal of Forest Research 18, 688-95. Google Scholar
Annila, E., Långström, B., Varama, M., Hiukka, R. & Niemela, P. 1999. Susceptibility of defoliated Scots pine to spontaneous and induced attack by _Tomicus piniperda_and Tomicus minor. Silva Fennica 33, 93-106. Google Scholar
Baier P., Führer, E., Kirisits, T. & Rosner, S. 2002. Defence reactions of Norway spruce against bark beetles and the associated fungus Ceratocystis polonica in secondary pure and mixed species stands. Forest Ecology and Management 159, 73-86. Google Scholar
Bakke, A., 1983. Host tree and bark beetle interaction during mass outbreak of Ips typographus in Norway. Zeitschrift für angwandte Entomologie, 96, 118-25. Google Scholar
Baradat, P., Bernard-Dagan, C., Pauly, G. & Zimmermann-Fillon, C. 1975. Les terpènes du Pin maritime : aspects biologiques et génétiques. III. Hérédité de la teneur en myrcène. Annales des Sciences Forestières, 32, 29-54. Google Scholar
Baradat, P., Marpeau, A. & Bernard-Dagan, C. 1978. Variation of terpenes within and between populations of maritime pine. In. Biochemical genetics of forest trees, D. Rudin (Ed.), Umea, Sweden. Google Scholar
Barrett, J.P. & Bengston, G.W. 1964. Oleoresin yields for slash pines from seven seed sources. Forest Science, 10, 159-64. Google Scholar
Bartos, D.L. & Amman, G.D. 1989. Microclimate: an alternative to tree vigor as a basis for mountain pine beetle infestations. USDA Forest Service Research Paper INT-400. Google Scholar
Bartos, D.L. & Booth, G.D. 1994. Effects of thinning on temperature dynamics and mountain pine beetle activity in a lodgepole pine stand. USDA Forest Service Research Paper INT-RP-479. Google Scholar
Belanger, R.P., Osgood, E.A. & Hatchell, G.E., 1979. Stand, soil, and site characteristics associated with southern pine beetle infestations in the southern Appalachians. USDA Forest Service Research Paper SE-198. Google Scholar
Bernard-Dagan, C., Fillon, C., Pauly, G., Baradat, P. & Illy, G. 1971. Les terpènes du Pin maritime. I. Variabilité de la composition monoterpénique dans un individu, entre individus et entre provenances. Annales des Sciences Forestières, 28, 223-58. Google Scholar
Berryman, A.A. 1972. Resistance of conifers to invasion by bark beetle fungus associations. BioScience 22,598-602. Google Scholar
Berryman, A.A. 1976. Theoretical explanation of mountain pine beetle dynamics in lodgepole pine forests. Environmental Entomology, 5,1225-33. Google Scholar
Berryman, A.A. 1982. Population Dynamics of Bark Beetles. In. Bark Beetles in North American Conifers, J.B. Mitton, K.B. Sturgeon (Eds.). Austin: University of Texas. Google Scholar
Berryman, A.A. & Ashraf, M. 1970. Effects of _Abies grandis_resin on the attack behavior and brood survival of Scolytus ventralis (Coleoptera: Scolytidae). The Canadian Entomologist, 102,1229-36. Google Scholar
Blanche, C.A., Hodges, J.D. & Nebeker, T.E. 1985. Changes in bark beetle susceptibility indicators in a lightning-struck loblolly pine. Canadian Journal of Forest Research, 15, 397-99. Google Scholar
Blanche, C.A., Lorio, P.L., Jr., Sommers, R.A., Hodges, J.D. & Nebeker, T.E. 1992. Seasonal cambial growth and development of loblolly pine: xylem formation, inner bark chemistry, resin ducts, and resin flow. Forest Ecology and Management, 49, 151-65. Google Scholar
Bois, E. & Lieutier, F. 1997. Phenolic response of Scots pine clones to inoculation with Leptographium wingfieldii, a fungus associated with Tomicus piniperda. Plant Physiology and Biochemistry, 35, 819-25. CAS Google Scholar
Bois E., Lieutier F. & Yart, A. 1999. Bioassays on Leptographium wingfieldii, a bark beetle associated fungus, with phenolic compounds of Scots pine phloem. European Journal of Plant Pathology, 105, 51-60. CAS Google Scholar
Bordasch, R.P. & Berryman, A.A. 1977. Host resistance to the fir engraver beetle Scolytus ventralis(Coleoptera: Scolytidae). 2. Repellency of Abies grandis resins and some monoterpenes. The Canadian Entomologist, 109, 95-100. CAS Google Scholar
Bridges, J.R. 1987. Effects of terpenoïd compounds on growth of symbiotic fungi associated with the southern pine beetle. Phytopathology, 77,83-85. CAS Google Scholar
Brignolas, F. 1995. Rôle des composés phénoliques dans l’efficacité de la réaction induite du liber de l’épicea (Picea abies) à enrayer la progression d’Ophiostoma polonicum, champignon associé au Scolytide Ips typographus. Thèse Université d’Orléans: Physiologie et biologie des organismes, populations, interactions. Google Scholar
Brignolas, F., Lacroix, B., Lieutier, F., Sauvard, D., Drouet, A., Claudot, A.-C., Yart, A., Berryman, A.A. & Christiansen, E. 1995b. Induced responses in phenolic metabolism in two Norway spruce clones after wounding and inoculations with Ophiostoma polonicum, a bark beetle-associated fungus. Plant Physiology, 109,821-27. CAS Google Scholar
Brignolas, F. Lieutier, F., Sauvard, D., Christiansen, E. & Berryman, A.A. 1998. Phenolic predictors for Norway spruce resistance to the bark beetle Ips typographus (Coleoptera: Scolytidae) and an associated fungus, Ceratocystis polonica. Canadian Journal of Forest Research, 28,720-28. CAS Google Scholar
Brignolas, F., Lieutier, F., Sauvard, D., Yart, A., Drouet, A. & Claudot, A.-C. 1995a. Changes in soluble phenol content of Norway spruce (Picea abies Karst.) phloem in response to wounding and inoculation with Ophiostoma polonicum. European Journal of Forest Patholology, 25,253-65. Google Scholar
Brown, M.W., Nebeker, T.E. & Honea, C.R. 1987. Thinning increases loblolly pine vigor and resistance to bark beetles. Southern Journal of applied Forestry 11, 28-31. Google Scholar
Bryant, J.P., Chapin, F.S., III & Klein, D.R. 1983. Carbon nutrient balance of boreal plants in relation to vertebrate herbivory. Oikos, 40, 357-68. CAS Google Scholar
Buijtenen, J.P. & Van Santamour, F. 1972. Resin crystallization related to weevil resistance in white pine (Pinus strobus). The Canadian Entomologist, 104, 215-18. Google Scholar
Cates, R.G. & Alexander, H. 1982. Host Resistance and Susceptibility. In. Bark Beetles in North American Conifers, J.B. Mitton, K.B. Sturgeon (Eds.). Austin: Univ. Texas. Google Scholar
Cedervind, J., Pettersson, M. & Långström, B. 2003. Attack dynamics of the pine shoot beetle, Tomicus piniperda(Co,. Scolytinae) in Scots pine stands defoliated by Bupalus piniaria(Lep. Geometridae). Agricultural and Forest Entomology 5, 253-61. Google Scholar
Chararas C. 1962. Scolytides des Conifères. Paris, Lechevalier. Google Scholar
Cheniclet, C., Bernard-Dagan, C. & Pauly, G. 1988. Terpene Biosynthesis Under Pathological Conditions. In. Mechanisms of Woody Plant Defences Against Insects: Search for Pattern, W.J. Mattson, J. Lévieux, C. Bernard-Dagan (Eds.). New York: Springer. Google Scholar
Chiron, H., Drouet, A. Lieutier, F., Payer, H-D., Ernst, D. & Sandermann, H. Jr. 2000. Gene induction of stilbene biosynthesis in Scots pine in response to ozone treatment, wounding, and fungal infection. Plant Physiology, 124,865-72. PubMedCAS Google Scholar
Christiansen, E. 1985a. _Ceratocystis polonica_inoculated in Norway spruce: Blue-staining in relation to inoculum density, resinosis and tree growth. European Journal of Forest Pathology, 15,160-67. Google Scholar
Christiansen, E. 1989. Bark beetles and air pollution. Meddelelser fra det Norske Skogforsoksvesen, 42, 101-07. Google Scholar
Christiansen, E. 1992. After-effects of drought did not predispose young _Picea abies_to infection by the bark beetle-transmitted blue-stain fungus Ophiostoma polonicum. Scandinavian Journal of Forest Research, 7, 557-69. Google Scholar
Christiansen, E. & Ericsson, A. 1986. Starch reserves in Picea abies in relation to defence reaction against a bark beetle transmitted blue-stain fungus, Ceratocystis polonica Canadian Journal of Forest Research, 16, 78-83. Google Scholar
Christiansen, E. & Fjorne, G. 1993. Pruning enhances the susceptibility of _Picea abies_to infection by the bark beetle-transmitted blue-stain fungus, Ophiostoma polonicum. Scandinavian Journal of Forest Research 8, 235-45. Google Scholar
Christiansen, E., Franceschi, V.R., Nagy, N.E., Krekling, T., Berryman, A.A., Krokene, P. & Solheim, H. 1999b. Traumatic resin ducts formation in Norway spruce (Picea abies(L.) Karst.) after wounding or infection with a bark beetle-associated blue stain fungus, _Ceratocystis polonica_Siem. In. Physiology and Genetics of Tree Phytophage Interactions, F. Lieutier, W.J. Mattson, M.R. Wagner (Eds.). Versailles: INRA Editions. Google Scholar
Christiansen, E. & Glosli, A.M. 1996. Mild drought enhances the resistance of Norway spruce to a bark beetle-transmitted blue-stain fungus. In: Dynamics of Forest Herbivory: Quest for Pattern and Principle, W.J. Mattson, P. Niemela, M. Rousi (Eds). USDA Forest Service General Technical Report NC-183, pp. 192-99. Google Scholar
Christiansen, E. & Horntvedt, R. 1983. Combined Ips/Ceratocystis attack on Norway spruce and defensive mechanisms of the trees. Zeitschrift für angewandte Entomologie, 96, 110-18. Google Scholar
Christiansen, E. & Huse, K. 1980. Infestation ability of Ips typographus in Norway spruce trees, in relation to butt rot, tree vitality and increment. Meddelelser fra det Norske Skogforsoksvesen, 35, 469-82. Google Scholar
Christiansen, E., Krokene P., Berryman, A.A., Franceschi, V.R., Krekling, T., Lieutier, F., Lönneborg, A. & Solheim, H. 1999a. Mechanical injury and fungal infection induce acquired resistance in Norway spruce. Tree Physiology, 19, 399-403. Google Scholar
Christiansen, E., Waring, R.H. & Berryman A.A. 1987. Resistance of conifers to bark beetle attack: searching for general relationships. Forest Ecology and Management, 22, 89-106. Google Scholar
Cobb, F.W. Jr., Kirstie, M., Zavarin, E. & Barber, H.W., Jr. 1968a. Inhibitory effects of volatile oleoresin components on Fomes annosus and four _Ceratocystis_species. Phytopathology, 58, 1327-35. CAS Google Scholar
Cobb, F.W., Jr., Wood, D.L., Stark, R.W. & Parmeter, J.R., Jr. 1968b. Photochemical oxidant injury and bark beetles (Coleoptera: Scolytidae) infestation of ponderosa pine. IV. Theory on the relationship between oxidant injury and bark beetle infestation. Hilgardia, 39, 141-52. Google Scholar
Cook, S. P., Hain, F.P. & Nappen, 1986. Seasonality of the hypersensitive response by loblolly and shortleaf pine to inoculation with a fungal associate of the southern pine beetle (Coleoptera: Scolytidae). Journal of Entomological Science, 21, 283-85. Google Scholar
Coulson, R.N. 1979. Population dynamics of bark beetles. Annual Review of Entomology, 24, 417-47. Google Scholar
Coulson, R.N., Flamm, R.O., Pulley, P.E., Payne, T.L., Rykiel, E.J. & Wagner, T.L. 1986. Response of the southern pine bark beetle guild (Coleoptera: Scolytidae) to host disturbance. Environmental Entomology, 15, 850-58. Google Scholar
Croisé, L., Dreyer, E. & Lieutier, F. 1998a. Effects of drought stress and severe pruning on the reaction zone induced by single inoculations with a bark beetle associated fungus (Ophiostoma ips) in the phloem of young Scots pines. Canadian Journal of Forest Research 28, 1814-24. Google Scholar
Croisé, L. & Lieutier, F. 1993. Effect of drought on the induced defence reaction of Scots pine to bark beetle-associated fungi. Annales des Sciences Forestières, 50, 91-97. Google Scholar
Croisé, L., Lieutier, F., Cochard, H. & Dreyer, E. 2001. Effects of drought stress and high density stem inoculations with _Leptographium wingfieldii_on hydraulic properties of young Scots pine trees. Tree Physiology, 21, 427-36. PubMed Google Scholar
Croisé, L., Lieutier, F. & Dreyer, E. 1998b. Scots pine responses to number and density of inoculation points with Leptographium wingfieldii Morelet, a bark beetle-associated fungus. Annales des Sciences Forestières, 55, 497-506. Google Scholar
Dahlsten, D.L. & Rowney, D.L. 1980. Influence of air pollution on population dynamics of forest insects and on tree mortality. Symposium on effects of air pollutants on Mediterranean and temperate forest ecosystems, Riverside, California, USA, June 22-27. Google Scholar
DeAngelis, J.D., Nebeker, T.E., & Hodges J.D., 1986. Influence of tree age and growth rate on the radial resin duct system in loblolly pine (Pinus taeda). Canadian Journal of Botany, 64, 1046-49. Google Scholar
Debazac, E.F. 1977. Manuel des conifères, ENGREF, Nancy. Google Scholar
Delorme, L., & Lieutier, F. (1990). Monoterpene composition of the preformed and induced resins of Scots pine, and their effect on bark beetles and associated fungi. Eur. J. For. Pathol., 20, 304-16. Google Scholar
Dreyer, E., Guérard, N. Lieutier, F., Pasquier-Barré, F., Lung, B. & Piou, D. 2002. Interactions between nutrient and water supply to potted Pinus sylvestris trees and their susceptibility to several pests and pathogens. In. Effects of water and nutrient stress on pine susceptibility to various pest and disease guilds, Lieutier, F. (Ed), Final scientific report of the EU project FAIR 3 CT96-1854. Google Scholar
Dunn, J.P. & Lorio, P.L., Jr. 1992. Effect of bark girdling on carbohydrate supply and resistance of loblolly pine to southern pine beetle (Dendroctonus frontalis Zimm.) attack. Forest Ecology and Management, 50, 317-30. Google Scholar
Dunn, J.P. & Lorio, P.L., Jr. 1993. Modified water regimes affect photosynthesis, xylem water potential, cambial growth, and resistance of juvenile Pinus taeda L. to Dendroctonus frontalis (Coleoptera: Scolytidae). Physiological and Chemical Ecology, 22, 948-57. Google Scholar
Ehnström, B., Långström, B. & Hellqvist, C. 1995. Insects in burned forests – forest protection and faunal conservation (preliminary results). Entomologica Fennica, 6, 109-17. Google Scholar
Evensen, P.C., Solheim, H., Hoiland, K. & Stenersen, J. 2000. Induced resistance of Norway spruce, variation of phenolic compounds and their effects on fungal pathogens. Forest Pathology, 30, 97-108. Google Scholar
Everaerts, C., Grégoire, J.-C. & Merlin, J. 1988. Toxicity of Spruce Monoterpenes Against Bark Beetles and Their Associates . In. _Mechanisms of Woody Plant Defences Against Insects: Search for Pattern_W.J. Mattson, J. Lévieux, C. Bernard-Dagan (Eds.). New York: Springer. Google Scholar
Fäldt, J., Martin, D., Miller, B., Rawat, S. & Bohlmann, J. 2003. Traumatic resin defence in Norway spruce (Picea abies): Methyl jasmonate-induced terpene synthase gene expression, and cDNA cloning and functional characterization of (+)-3-carene synthase. Plant Molecular Biology, 51, 119-33. PubMed Google Scholar
Ferrell, G.T. 1974. Moisture stress and fir engraver (Coleoptera: Scolytidae) attack in white fir infected by true mistletoe. Canadian Entomologist 106, 315-18. Google Scholar
Ferrell, G.T. 1978. Moisture stress threshold of susceptibility to fir engraver beetles in pole-size white firs. Forest Science, 24, 85-92. Google Scholar
Ferrell, G.T. 1983. Host resistance to the fir engraver, Scolytus ventralis (Coleoptera: Scolytidae): frequencies of attacks containing resin blisters and canals of Abies concolor. The Canadian Entomologist, 115, 1421-28. Google Scholar
Ferrell G.T. & Otrosina W.J., 1996. Differential susceptibility of white fir provenances to the fir engraver and its fungal symbiont in Northern California. In. Dynamics of forest herbivory; quest for pattern and principle, W.J. Mattson, P. Niemela, M. Rousi (Eds), USDA Forest Service General Technical Report NC-183. Google Scholar
Ferrell, G.T., Otrosina, W.J. & Demars, Jr, C.R. 1994. Predicting susceptibility of white fir during a drought-associated outbreak of the fir engraver, Scolytus ventralis, in California. Canadian Journal of Forest Research 24, 302-05. Google Scholar
Filip, G.M., Christiansen, E., & Parks, C.A., 1989. Secondary resin production increases with vigor of _Abies grandis_inoculated with _Trichosporium symbioticum_in Northeastern Oregon. USDA Forest Service Research Note PNW-RN-489, 12 p. Google Scholar
Filip, G.M., Ganio, L.M., Oester, P.T., Mason, R.R. & Wickman, B.E. 2002. Ten-year effect of fertilization on tree growth and mortality associated with Armillaria root disease, fir engravers, dwarf mistletoe, and western spruce budworm in Northeastern Oregon. Western Journal of Applied Forestry, 17, 122-128. Google Scholar
Flamm, R.O., Pulley, P.E. & Coulson, R.N. 1993. Colonization of disturbed trees by the southern pine bark beetle guild (Coleoptera: Scolytidae). Environmental Entomology, 22, 62-70. Google Scholar
Franceschi, V.R., Krekling, T., Berryman, A.A. & Christiansen, E. 1998. Specialized phloem parenchyma cells in Norway spruce (Pinaceae) bark are an important site of defence reactions. American Journal of Botany 85, 601-15. Google Scholar
Franceschi, V.R., Krekling, T. & Christiansen, E. 2002. Application of methyl jasmonate on Picea abies(Pinaceae) stems induces defence-related responses in phloem and xylem. American Journal of Botany, 89, 578-86. CAS Google Scholar
Franceschi, V.R., Krokene, P., Krekling, T., Berryman, A.A. & Christiansen, E. 2000. Phloem parenchyma cells are invoved in local and distant defence responses to fungal inoculation or bark beetle attack in Norway spruce (Pinaceae). American Journal of Botany, 87, 314-26. PubMed Google Scholar
Fredericksen, T.S., Hedden, R.L. & Williams, S.A. 1995. Susceptibility of loblolly pine to bark beetle attack following simulated wind stress. Forest Ecology and Management, 76, 96-107. Google Scholar
Gilbert, M., Vouland, G. & Grégoire J.C. 2001. Past attacks influence host selection by the solitary bark beetle Dendroctonus micans. Ecological Entomology, 26, 133-42. Google Scholar
Gilmore, A.R. 1977. Effects of soil moisture stress OrgName monoterpenes in loblolly pine. Journal of Chemical Ecology, 3, 667-76. CAS Google Scholar
Grégoire, J.C. 1988. The Greater European Spruce Beetle. In. Dynamics of Forest Insect Populations: Patterns, Causes, Implications, A.A. Berryman (Ed). New York: Plenum Press. Google Scholar
Grégoire J.C., Braekman J.C. & Tondeur A., 1982. Chemical communication between larvae of Dendroctonus micans Kug. (Coleoptera: Scolytidae). Les colloques de l’INRA. 7. Les médiateurs chimiques: 16-20. Google Scholar
Grodski, W. 1997. Changes in the occurrence of bark beetles on Norway spruce in a forest decline area in the Sudety mountains in Poland. In. Integrated cultural tactics into the management of bark beetles and reforestation pests, J.C. Grégoire, A.M. Liebhold, F.R. Stephen, K.R. Day, S.M. Salom (Eds). USDA Forest Service General Technical Report NE-236. Google Scholar
Guérard, N. 2001. Résistance du Pin sylvestre aux attaques de Scolytes et de leur champignons associés : interactions avec l’alimentation hydrique et minérale. Thèse Université de Tours, Biologie des populations, génétique et éco-éthologie. Google Scholar
Guérard, N., Dreyer, E. & Lieutier, F. 2000a. Interactions between Scots pine, Ips acuminatus(Gyll.) and Ophiostoma brunneo-ciliatum(Math.): estimation of the critical thresholds of attack and inoculation densities and effects on hydraulic properties of the stem. Annals of Forest Sciences, 57, 681-90. Google Scholar
Guérard, N., Dreyer, E. & Lieutier, F. 2000b. Influence of water and mineral nutrition on Scots pine resistance to bark-beetles and an associated blue-stain fungus. XXI IUFRO World Congress, 7.01.02 Working Party, ‘‘_Mechanisms of tree resistance to phytophagous insects_», 7-12 August, Kuala Lumpur (Malaysia). Google Scholar
Hanover, J.A., 1975. Physiology of tree resistance to insects. Annual Review of Entomology, 20, 75-95. CAS Google Scholar
Hanover, J.W., 1966, Genetics of terpenes. 1. Gene control of monoterpenes levels in Pinus monticola Dougl. Heredity, 21, 73-84. CAS Google Scholar
Harrington, T.C. 1993. Diseases of Conifers Caused by Species of Ophiostoma and Leptographium . In. Ceratocystis and Ophiostoma. Taxonomy, Ecology, and Pathogenicity, M.J. Wingfield, K.A. Seifert, J.F. Webber (Eds.). Saint Paul: APS Press. Google Scholar
Hart, J.H. 1981. Role of phytostilbenes in decay and disease resistance. Annual Review of Phytopathology, 19, 437-58. CAS Google Scholar
Hart, J.H. & Shrimpton, D.M. 1979. Role of stilbenes in resistance of wood to decay. Phytopathology, 69, 1138-43. CAS Google Scholar
Heidger, C.M. & Lieutier, F. 2002. Possibilities to utilize tree resistance to insects in forest pest management in central and western Europe. In. Mechanisms and Deployment of Resistance in Trees to Insects, M.R. Wagner, K.M. Clancy, F. Lieutier, T.D. Paine (Eds), Dordrecht, Kluwer. Google Scholar
Herms, D.A. & Mattson, W.J. 1992. The dilemma of plants: to grow or defend. Quaterly Review of Biology, 67, 283-335. Google Scholar
Hodges, J.D. & Lorio, P.L., Jr. 1975. Moisture stress and composition of xylem oleoresin in loblolly pine. Forest Science, 21, 283-90. CAS Google Scholar
Hodges, J.D. & Picard, L.S. 1971. Lightning in the ecology of the southern pine beetle, Dendroctonus frontalis(Coleoptera: Scolytidae). The Canadian Entomologist, 103, 44-51. Google Scholar
Horntvedt, R. 1988. Resistance of _Picea abies_to Ips typographus: tree response to monthly inoculations with Ophiostoma polonicum, a beetle transmitted blue-stain fungus. Scand. J. For. Res., 3, 107-114. Google Scholar
Horntvedt, R., Christiansen, E., Solheim, H. & Wang, S. 1983. Artificial inoculation with _Ips typographus_-associated blue-stain fungi can kill healthy Norway spruce trees. Meddelelser fra det Norske Skogforsoksvesen, 38, 1-20. Google Scholar
Hudgins, J.W., Christiansen, E. & Franceschi V. 2003a. Methyl jasmonate induces changes mimicking anatomical defences in diverse members of the Pinaceae. Tree Physiology, 23, 361-71. CAS Google Scholar
Hudgins, J.W., Krekling, T. & Franceschi V. 2003b. Distribution of calcium oxalate crystals in the secondary phloem of conifers: constitutive defence mechanism? New Phytologist, 159, 677-690. CAS Google Scholar
Johnson, M.A. & Croteau, R. 1987. Biochemistry of Conifer Resistance to Bark Beetles and their Fungal Symbionts. In. Ecology and Metabolism of Plant Lipids, G. Fuller, W.D. Nes (Eds.). ACS Symposium Series N° 325. Washington DC: American Chemical Society. Google Scholar
Karban, R. & Baldwin, I.T. 1997. Induced Responses to Herbivory. Chicago: The University of Chicago Press. Google Scholar
Katoh, S. & Croteau, R. 1998. Individual variation in constitutive and induced monoterpene biosynthesis in grand fir (Abies grandis). Phytochemistry, 47, 577-82. CAS Google Scholar
Keen, F.P. 1938. Insects enemies of western forests. USDA Miscellanous Publication 273. Google Scholar
King, E.W. 1972. Rainfall and epidemics of the southern pine beetle. Environmental Entomology, 1, 279-85. Google Scholar
Klepzig, K.D., Kruger, E.L., Smalley, E.B. & Raffa K.F. 1995. Effects of biotic and abiotic stress on induced accumulation of terpenes and phenolics in red pines inoculated with bark beetle-vectored fungus. Journal of Chemical Ecology 21, 601-626. CAS Google Scholar
Koricheva, J., Larsson, S. & Haukioja, E. 1998. Insect performance on experimentally stressed woody plants: a meta-analysis. Annual Review of Entomology, 43, 195-216. PubMedCAS Google Scholar
Krekling, T., Franceschi, V.R., Berryman, A.A. & Christiansen, E. 2000. The structure and development of polyphenolic parenchyma cells in Norway spruce (Picea abies) bark. Flora, 195, 354-69. Google Scholar
Krokene, P., Christiansen, E. & Solheim, H. 2000. Induced disease resistance in Norway spruce and its implications for bark beetle population dynamics. Abstracts of the XXI Intenational Congress of Entomology, August 20-26, Foz do Iguassu, Brazil. Google Scholar
Krokene, P., Christiansen, E., Solheim, H., Franceschi, V.R. & Berryman, A.A. 1999. Induced resistance to pathogenic fungi in Norway spruce. Plant Physiology, 121, 565-69 PubMedCAS Google Scholar
Krokene, P. & Solheim, H. 1999. What do low-density inoculations with fungus tell us about fungal virulence and tree resistance? In. Physiology and Genetics of Tree-Phytophage Interactions, F. Lieutier, W.J. Mattson, M.R. Wagner (Eds.). Versailles: INRA Editions. Google Scholar
Krokene, P., Solheim, H. & Christiansen, E. 2001. Induction of disease resistance in Norway spruce (Picea abies) by necrotizing fungi. Plant Pathology, 50, 230-33. Google Scholar
Krokene, P., Solheim, H., Krekling, T. & Christiansen, E. 2003. Inducible anatomical defence responses in Norway spruce stems and their possible role in induced resistance. Tree Physiology, 23, 191-97. PubMed Google Scholar
Kytö, M., Niemela, P. & Annila, E. 1996. Vitality and bark-beetle resistance of fertilized Norway spruce. Forest Ecology and Management, 84, 149-57. Google Scholar
Kytö, M., Niemela, P. & Annila, E. 1998. Effects of vitality fertilization on the resin flow and vigour of Scots pine in Finland. Forest Ecology and Management, 102, 121-30. Google Scholar
Kytö, M., Niemela, P., Annila, E. & Varama, M. 1999. Effects of forest fertilization on radial growth and resin exudation of insect defoliated Scots pines. Journal of Applied Ecology, 36, 763-69. Google Scholar
Långström, B., Annila, E., Hellqvist C., Varama, M. & Niemela, P. 2001a. Tree mortality, needle biomass recovery and growth losses in Scots pine following defoliation by Diprion pini(L.) and subsequent attack by Tomicus piniperda(L.). Scandinavian Journal of Forest Research 16, 342-53. Google Scholar
Långström, B. & Hellqvist, C. 1988. Scots pine resistance against _Tomicus piniperda_as related to tree vitality and attack density. In: Integrated control of scolytid bark beetles, Payne, T.L., Saarenmaa, H. (eds), Procedings of the IUFRO working party and XVII International congress of entomology symposium, Vancouver, B.C., Canada, July 4 1988. Google Scholar
Långström, B. & Hellqvist, C. 1993a. Induced and spontaneous attacks by pine shoot beetles on young Scots pine trees: tree mortality and beetle performances. Journal of Applied Entomology, 115, 25-36. Google Scholar
Långström, B. & Hellqvist, C. 1993b. Scots pine susceptibility to attack by Tomicus piniperda(L) as related to pruning date and attack density. Annales des Sciences Forestières 50, 101-17. Google Scholar
Långström, B., Hellqvist C. & Ehnström B., 1999. Susceptibility of fire-damaged Scots pine (_Pinus sylvestris_L.) to attack by Tomicus piniperda L. In. Physiology and Genetics of Tree-Phytophage Interactions, F. Lieutier, W.J. Mattson, M.R. Wagner (Eds). Versailles: INRA Editions. Google Scholar
Långström, B., Hellqvist, C., Ericsson, A. & Gref, D. 1992. Induced defence reaction in Scots pine following stem attacks by Tomicus piniperda L. Ecography, 15, 318-27. Google Scholar
Långström B., Solheim, H., Hellqvist, C. & Gref, R. 1993. Effects of pruning young Scots pines on host vigour and susceptibility to Leptographium wingfieldii and Ophiostoma minus, two blue-stain fungi associated with Tomicus piniperda. European Journal of Forest Pathology 23, 400-15. Google Scholar
Långström, B., Solheim, H., Hellqvist, C. & Krokene, P. 2001b. Host resistance in defoliated Scots pine: effects of single and mass inoculations using bark beetle-associated blue-stain fungi. Agricultural and Forest Entomology 3, 211-16. Google Scholar
Lanz, W., Skwara, P. & Grodski, W. 1993. Bark beetle attack on immission-damaged Norway spruce stands in Silesia. Allgemeine Forst Zeitschrift, 48, 670-73. Google Scholar
Larsson, S., Oren, R., Waring, R.H. & Barrett, J.W., 1983. Attacks of mountain pine beetle as related to tree vigor of ponderosa pine. Forest Science, 29, 395-402. Google Scholar
Lévieux, J. Jactel, H. & Lieutier, F. 1988. Preliminary study of variability in sap pressure of Scots pine clones in central France. Annales des Sciences Forestières, 45, 341-55. Google Scholar
Lieutier, F. 1992. Les réactions de défense des conifères et stratégies d’attaques de quelques Scolytides européens. Mémoires de la Société Royale Belge d’Entomolologie, 35, 529-39. Google Scholar
Lieutier, F. 1993. Induced defence reaction of conifers to bark beetles and their associated _Ophiostoma_species. In. Ceratocystis and Ophiostoma. Taxonomy, Ecology, and Pathogenicity, M.J. Wingfield, K.A. Seifert, J.F. Webber (Eds.). Saint Paul: APS Press. Google Scholar
Lieutier, F. 1995. Associated fungi, induced reaction and attack strategy of Tomicus piniperda(Coleoptera: Scolytidae) in Scots pine. In. Behavior, Population Dynamics and Control of Forest Insects , F.P. Hain, S.M. Salom, W.F. Ravlin, T.L. Payne, K.F. Raffa (Eds.). Proceedings International Union Forestry Research Organizations Joint Conference, 1994 February 6-11, Maui, Hawaï. Google Scholar
Lieutier, F. 2002. Mechanisms of resistance in conifers and bark beetle attack strategies. In. Mechanisms and Deployment of Resistance in Trees to Insects, M.R. Wagner, K.M. Clancy, F. Lieutier, T.D. Paine (Eds), Dordrecht, Kluwer. Google Scholar
Lieutier, F. & Berryman, A.A. 1988. Preliminary histological investigations on the defence reactions of three pines to _Ceratocystis clavigera_and two chemical elicitors. Canadian Journal of Forest Research, 18, 1243-47. Google Scholar
Lieutier, F., Berryman, A.A. & Millstein, J.A. 1991a. Preliminary study of the monoterpene response of three pines to Ophiostoma clavigerum (Ascomycetes: Ophiostomatales) and two chemivcal elicitors. Annales des Sciences Forestières, 48, 377-88. Google Scholar
Lieutier, F., Brignolas, F., Picron, V., Yart A. & Bastien, C. 1996a. Can Phloem Phenols Be Used as Markers of Scots Pine Resistance to Bark Beetles ? In. _Dynamics of Forest Herbivory: Quest for Pattern and Principl_e, W.J. Mattson, P. Niemela, M. Rousi (Eds.). USDA Forest Service General Techical Report NC-183. Google Scholar
Lieutier F., Brignolas F., Sauvard D., Yart A., Galet C., Brunet M. & Van de Sype H., 2003a. Intra- and inter-provenance variability in phloem polyphenols of Picea abies (L.) KARST. and relation with resistance to a bark-beetle-associated fungus. Tree physiology, 23, 247-56. CAS Google Scholar
Lieutier, F., Brignolas, F., Yart, A., Grodski, W., Jakus, R. & Sauvard, D. 2003b. Field validation of phenolics as predictors of Norway spruce resistance to Ips typographus attacks during a finishing outbreak. IUFRO Working Party meeting “_Forest Insect Population Dynamics and Host Influences_”, September 14-19, Kanazawa, Japan. Google Scholar
Lieutier, F., Cheniclet, C. & Garcia, J. 1989a. Comparison of the defence reactions of Pinus pinaster and Pinus sylvestris to attacks by two bark beetles (Coleoptera: Scolytidae) and their associated fungi. Environmental Entomology, 18, 228-34. Google Scholar
Lieutier, F., Faure, T. & Garcia, J. 1988a. Les attaques de Scolytes et le dépérissement du pin sylvestre en Provence - Côte d’Azur. Revue forestière française, 40, 224-32. Google Scholar
Lieutier, F. & Ferrell, G.Y. 1988. Relationships between indexes of tree vigour and the induced defence reaction of Scots pine to a fungus associated with Ips sexdentatus Boern. (Coleoptera: Scolytidae). In:.b Integrated control of scolytid bark beetles, Payne, T.L., Saarenmaa, H. (eds), Procedings of the IUFRO working party and XVII International congress of entomology symposium, Vancouver, B.C., Canada, July 4 1988. Google Scholar
Lieutier, F., Garcia, J., Romary, P. & Yart, A. 1995. Wound reactions of Scots pine (Pinus sylvestris L.) to attacks by Tomicus piniperda L. and Ips sexdentatus Boern. (Coleoptera: Scolytidae). Journal of Applied Entomology, 119, 591-600. Google Scholar
Lieutier, F., Garcia, J., Romary, P., Yart, A., Jactel, H. & Sauvard, D. 1993. Inter-tree variability in the induced defence reaction of Scots pine to single inoculations by Ophiostoma brunneo-ciliatum a bark beetle-associated fungus. Forest Ecology and Management, 59, 257-70. Google Scholar
Lieutier, F., Långström, B., Solheim, H., Hellqvist, C. & Yart, A. 1996b. Genetic and Phenotypic Variation in the Induced Reaction of Scots Pine, _Pinus Sylvestris_L., to _Leptographium Wingfieldii_Reaction Zone Length and Fungal Growth . . In. Dynamics of Forest Herbivory: Quest for Pattern and Principle, W.J. Mattson, P. Niemela, M. Rousi (Eds.). USDA Forest Service General Technical Report NC-183. Google Scholar
Lieutier, F., Sauvard, D., Brignolas, F., Picron, V., Yart, A., Bastien, C. & Jay-Allemand, C. 1996c. Changes in phenolic metabolites of Scots-pine phloem induced by Ophiostoma brunneo-ciliatum, a bark-beetle-associated fungus. European Journal of Forest Pathology, 26, 145-58. Google Scholar
Lieutier, F., Vouland, G., Pettinetti, M., Garcia, J., Romary, P. & Yart, A. 1992. Defence reactions of Norway spruce (_Picea abies_Karst.) to artificial insertion of Dendroctonus micans Kug. (Col. Scolytidae). Journal applied Entomology, 114, 174-86. Google Scholar
Lieutier, F., Yart, A., Garcia, J. & Ham, M-C. 1990. Cinétique de croissance des champignons associés á _Ips sexdentatus_Boern. et à Tomicus piniperda L. (Coleoptera: Scolytidae) et des réactions de défense des pins sylvestres (Pinus sylvestris L.) inoculés. Agronomie, 10, 243-56. Google Scholar
Lieutier, F., Yart, A., Garcia, J., Ham, M-C., Morelet, M. & Lévieux, J. 1989b. Champignons phytopathogènes associés á deux coléoptères scolytidae du pin sylvestre (Pinus sylvestris L.) et étude préliminaire de leur agressivité envers l’hôte. Annales des Sciences Foresiéres, 46, 201-16. Google Scholar
Lieutier, F., Yart, A., Garcia, J., Poupinel, B. & Lévieux, J. 1988b. Do Fungi Influence the Establishment of Bark Beetles in Scots Pine ? In. Mechanisms of Woody Plant Defences Against Insects: Search for Pattern, W.J. Mattson, J. Lévieux, C. Bernard-Dagan (Eds.). New York: Springer. Google Scholar
Lieutier, F., Yart, A., Jay-Allemand, C. & Delorme, L. 1991b. Preliminary investigations on phenolics as a response of Scots pine phloem to attacks by bark beetles and associated fungi. European Journal of Forest Pathology, 21, 354-54. Google Scholar
Lieutier, F., Yart A., Ye H., Sauvard D. & Gallois V. 2004. Between-isolate variations in the performances of Leptographium wingfieldii Morelet, a fungus associated with the bark beetle Tomicus piniperda L. Annals of Forest Sciences, in press. Google Scholar
Lieutier, F., Ye, H. & Yart, A. 2003c. Shoot damage by Tomicus sp. (Coleoptera: Scolytidae) and effect Pinus yunnanensis resistance to subsequent reproductive attacks on the stem. Agricultural and Forest Entomology 5, 227-33. Google Scholar
Lombardero, M.J., Ayres, M.P., Lorio, P.L., Jr. & Ruel, J.J. 2000. Environmental effects on constitutive and inducible resin defences of P. taeda. Ecology Letters, 3, 329-339. Google Scholar
Loomis, W.E. 1932. Growth-differentiation balance vs carbohydrate-nitrogen ration. Proceedings of the American Society of Horticultural Science, 29, 240-45. CAS Google Scholar
Lorio, P.L., Jr. 1986. Growth-differentiation balance: a basis for understanding southern pine beetle-tree interactions. Forest Ecology and Management, 14, 259-73. Google Scholar
Lorio, P.L., Jr. & Hodges, J.D. 1968a. Oleoresin exudation pressure and relative water content of inner bark as indicators of moisture stress in loblolly pines. Forest Science, 14, 392-98. Google Scholar
Lorio, P.L., Jr. & Hodges, J.D. 1968b. Microsite effect on oleoresin exudation pressure of large loblolly pines. Ecology, 49, p1207-10. Google Scholar
Lorio, P.L., Jr. & Hodges, J.D. 1977. Tree water status affects induced southern pine beetle attacks and brood production. USDA Forest Service Research Paper SO-135. Google Scholar
Lorio, P.L., Jr. & Sommers, R.A. 1986. Evidence for competition for photosynthates between growth processes and oleoresin synthesis in Pinus taeda L. Tree physiology, 2, 301-06. CAS Google Scholar
Lorio, P.L., Stephen, F.M. & Paine, T.D. 1995. Environment and ontogeny modify loblolly pine response to induced acute water deficits and bark beetle attacks. Forest Ecology and Management, 73, 97-110. Google Scholar
Löyttyniemi, K. 1978. (In Finnish) Effect of forest fertilization on pine shoot beetles (Tomicus spp., Col., Scolytidae). Folia Forestalia, 348, 1-19. Google Scholar
Martin, D., Tholl, D., Gershenzon, J. & Bohlmann, J. 2002. Methyl jasmonate induces traumatic resin ducts, terpenoid resin biosynthesis and terpenoid accumulation in developing xylem of Norway spruce (Picea abies) stems. Plant Physiology, 129, 1003-18. PubMedCAS Google Scholar
Mason R.R. 1971. Soil moisture and stand density affect oleoresin exudation flow in a loblolly pine plantation. Forest Science, 17, 170-77. Google Scholar
Matson, P.A., Hain, F.P. & Mawby, W. 1987. Indices of tree susceptibility to bark beetles vary with silvicultural treatment in a loblolly pine plantation. Forest Ecology and Management 22, 107-18. Mattson, W.J. & Haack, R.A. 1987. The role of drought in outbreaks of plant-eating insects. Bioscience, 37, 110-118. Google Scholar
McMullen, L.H., Fiddick, R.L. & Wood, R.O. 1981. Bark beetles, Pseudohylesinus spp.(Coleoptera: Scolytidae), associated with amabilis fir defoliated by _Neodiprion_sp. (Hymenoptera: Diprionidae). Journal of the Entomological Society of British Columbia 78, 43-45. Google Scholar
Mergen, F., Hoekstra, P.E. & Echols, R.M. 1955. Genetic control of oleoresin yield and viscosity in slash pine. Forest Science, 1, 19-30. Google Scholar
Miller, P.R., Cobb, F.W., Jr. & Zavarin, E. 1968. Photochemical oxidant injury and bark beetles (Coleoptera: Scolytidae) infestation of ponderosa pine. III. Effect of injury upon oleoresin composition, phloem carbohydrates, and phloem pH. Hilgardia, 39, 135-40. CAS Google Scholar
Miller, R.H. & Berryman, A.A. 1986. Nutrient allocation and mountain pine beetle attack in girdled lodgepole pines. Canadian Journal of Forest Research, 16, 1036-40. CAS Google Scholar
Miller, R.H., Whitney, H.S. & Berryman, A.A. 1986. Effects of induced translocation stress and bark beetle attack (Dendroctonus ponderosae) on heat pulse velocity and the dynamic wound response of lodgepole pine (Pinus contorta var. latifolia). Canadian Journal of Botany, 64, 2669-74. Google Scholar
Mitchell, R.G., Waring, R.H. & Pitman, G.B. 1983. Thinning lodgepole pine increases tree vigor and resistance to mountain pine beetle. Forest Science, 29, 204-11. Google Scholar
Moore, G.E. & Layman, H.F. 1978. Attempts to increase resistance of loblolly pines to bark beetles by fertilization. USDA Forest Service Research Note SE-260. Google Scholar
Müllick, D.B. 1977. The non-specific nature of defence in bark and wood during wounding, insect, and pathogen attack. Recent advances in phytochemistry, 11, 359-441. Google Scholar
Mulock, P. & Christiansen, E. 1986. The threshold of successful attack by Ips typographus on Picea abies: a field experiment. Forest Ecology and Management, 14, 125-132. Google Scholar
Nageleisen, L.M. 2002. Le point sur les attaques des Scolytes des résineux en fin d’année 2001 suite aux tempêtes de décembre 1999 et les mesures de lutte mises en œuvre. Les Cahiers du DSF, 1-2002 [La Santé des Forêts (France) 2000, 2001], Ministère de l’Agriculture, de l’Alimentation, de la Pêche et des Affaires Rurales (DERF), Paris. Google Scholar
Nageleisen, L.M. 2003. Le point sur les attaques des Scolytes des résineux en fin d’année 2002 suite aux tempêtes de décembre 1999 et les mesures de lutte mises en œuvre. Les Cahiers du DSF,sous presse ,Ministère de l’Agriculture, de l’Alimentation, de la Pêche et des Affaires Rurales (DERF), Paris Google Scholar
Nagy, N.E., Franceschi, V.R., Solheim, H., Krekling, T. & Christiansen, E. 2000. Wound-induced traumatic resin duct development in stems of Norway spruce (Pinaceae): anatomy, and cytological traits. American Journal of Botany, 87,302-13. PubMed Google Scholar
Nebeker, T.E., Hodges, J.D., Honea, C.R. & Blanche, C.A. 1988. Preformed Defensive System in Loblolly Pine: Variability and Impact on Management Practices . In. Integrated Control of Scolytid Bark Beetles, T.L. Payne, H. Saarenmaa (Eds.). Blacksburg, VA: Virginia Polytechnic Institute Press. Google Scholar
Nebeker, T.E., Hodges, J.D., Blanche, C.A., Honea, C.R. & Tisdale, R.A., 1992. Variation in the constitutive defensive system of Loblolly pine in relation to bark beetle attack. Forest Science, 38, 457-66. Google Scholar
Nihoul, D., Nef. & Waterkeyn, L. 1989. Variability between and within individuals in some anatomical characteristics of the bark of Norway spruce (Picea abies) in the Belgian Ardennes. Annales des Sciences Forestières, 46, 85-95. Google Scholar
Paine T.D., 1984. Seasonal response of ponderosa pine to inoculation of the mycangial from the western pine beetle. Canadian Journal of Botany, 62, 551-55. Google Scholar
Paine T.D. & Hanlon, C.C. 1994. Influence of oleoresin constituents from _Pinus ponderosa_and Pinus jeffreyi on the growth of the mycangial fungi from _Dendroctonus ponderosae_and Dendroctonus brevicomis. Journal of Chemical Ecology, 20, 2551-63. CAS Google Scholar
Paine, T.D., Raffa, K.F. & Harrington, T.C. 1997. Interactions among scolytids bark beetles, their associated fungi, and live host conifers. Annual Review of Entomology, 42, 179-206. PubMedCAS Google Scholar
Paine T.D., Stephen F.M. & Cates R.G., 1993. Within and among tree variation in the response of loblolly pine to a fungus associated with Dendroctonus frontalis (Coleoptera: Scolytidae) and sterile wounding. The Canadian Entomologist, 125, 65-71. Google Scholar
Pesson, P. & Chararas, C. 1969. Les Scolytides, insectes ravageurs mondiaux des forêts de conifères. L’année biologique, 8, 683-733. Google Scholar
Raffa, K.F. 1991. Induced defensive reactions in conifer-bark beetle systems. In. Phytochemical induction by herbivores, D.W. Tallamy, M.J. Raupp (Eds), Wiley & Sons, New York. Google Scholar
Raffa, K.F. & Berryman, A.A. 1982a. Physiological differences between lodgepole pines resistant and susceptible to the mountain pine beetle and associated microorganisms. Environmental Entomology, 11, 486-92. CAS Google Scholar
Raffa, K.F. & Berryman, A.A., 1982b. Accumulation of monoterpenes and associated volatiles following fungal inoculation of grand fir with a fungus transmitted by the fir engraver Scolytus ventralis(Coleoptera: Scolytidae). The Canadian Entomologist, 114, 797-810. CAS Google Scholar
Raffa, K.F. & Berryman, A.A. 1983a. The role of host plant resistance in the colonization behavior and ecology of bark beetles (Coleoptera: Scolytidae). Ecological Monographs, 53, 27-49. Google Scholar
Raffa, K.F. & Berryman, A.A. 1983b. Physiological aspects of lodgepole pine wound responses to a fungal symbiont of the mountain pine beetle, Dendroctonus ponderosae (Coleoptera: Scolytidae). The Canadian Entomologist, 115, 723-34. Google Scholar
Raffa, K.F., Berryman, A.A., Simasko J., Teal W. & Wong B.L. 1985. Effects of grant fir monoterpenes on the fire engraver, Scolytus ventralis (Coleoptera: Scolytidae), and its symbiotic fungus. Environmental Entomology, 14, 552-56. CAS Google Scholar
Raffa, K.F. & Klepzig, K.D. 1996. Effects of root inhabiting insect-fungal complexes on aspects of tree resistance to bark beetles. In: Dynamics of forest herbivory: quest for pattern and principle, W.J. Mattson, P. Niemela, M. Rousi (Eds), USDA Forest Service General Technical Report NC-183. Google Scholar
Raffa, K.F., Krause, S.C. & Reich, P.B. 1998. Long term effects of defoliation on red pine suitability to insects feeding on diverse plant tissues. Ecology 79, 2352-64. Google Scholar
Raffa, K.F. & Smalley, E.B. n1995. Interaction of pre-attack and induced monoterpene concentrations in host conifer defence against bark beetle-fungal complexes. Oecologia, 102, 285-95. Google Scholar
Rasmussen, L.A. 1987. Mountain pine beetle selection of dwarf mistletoe and Comandra blister rust infected lodgepole pine. USDA Forest Service Research Note INT-367. Google Scholar
Rasmussen, L.A., Amman, G.D., Vandygriff, J.C., Oakes, R.D., Munson, A.S. & Gibson, K.E. 1996. Bark beetle and wood borer infestation in the greater Yellowstone area during four postfire years. USDA Forest Service Research Paper INT-RP-487. Google Scholar
Reid, R.W. & Gates H. 1970. Effect of temperature and resin on hatch of eggs of the mountain pine beetle (Dendroctonus ponderosae). The Canadian Entomologist, 102, 617-22. Google Scholar
Reid, R.W. & Shrimpton, D.M., 1971. Resistant response of lodgepole pine to inoculation with _Europhium clavigerum_in different months and at different heights on stem. Canadian Journal of Botany, 49, 349-51. Google Scholar
Reid, R.W., Whitney, H.S. & Watson, J.A. 1967. Reactions of lodgepole pine to attack by Dendroctonus ponderosae Hopkins and blue stain fungi. Canadian Journal of Botany, 45, 115-26. Rudinsky, J.A. 1962. Ecology of Scolytidae. Annual Review Entomology, 7, 327-48. Google Scholar
Rudinsky, J.A., 1966. Host selection and invasion by the Douglas fir beetle, _Dendroctonus pseudotsugae_Hopkins, in coastal Douglas-fir forests. The Canadian Entomologist, 98, 98-111. CAS Google Scholar
Ruel, J.J., Ayres, M.P. & Lorio, P.L., Jr. 1998. Loblolly pine responds to mechanical wounding with increased resin flow. Canadian Journal of Forest Research, 28, 596-602. Google Scholar
Safranyik, L., Shrimpton, D.M. & Whitney, H.S. 1975. An interpretation of the interaction between lodgepole pine, the mounain pine beetle and its associated blue stain fungi in western Canada. In. Management of Lodgepole Pine Ecosystems, D. Baumgartner (Ed.), Pullman: Washington State University Cooperative Extension Service. Google Scholar
Sandness, A. & Solheim, H., 2002. Variation in tree size and resistance to Ceratocystis polonicain a monoclonal stand of Picea abies. Scandinavian Journal of Forest Research, 17, 522-28. Google Scholar
Santoro, A.E., Lombardero, M.J., Ayres, M.P. & Ruel, J.J. 2001. Interactions between fire and bark beetles in an old growth pine forest. Forest Ecology and Management, 144, 245-54. Google Scholar
Schroeder, M. 1990. Duct resin flow in Scots pine to the attack of the bark beetle _Tomicus piniperda_L. (Col., Scolytidae). Journal of applied Entomology, 109, 105-12. Google Scholar
Schwertfeger, F. 1944. _Die Waldkrankheiten. Ein Lehrbuch der Forstpathologie und des Forstschutzes_XVI, 479 p. Google Scholar
Shrimpton, D.M. 1973a. Extractives associated with wound response of lodgepole pine attacked by the mountain pine beetle and associated microorganisms. Canadian Journal of Botany, 51, 527-34 CAS Google Scholar
Shrimpton, D.M., 1973b. Age- and size-related response of lodgepole pine to inoculation with Europhium clavigerum. Canadian Journal of Botany, 51, 1155-60. Google Scholar
Shrimpton, D.M. & Whitney H.S. 1968. Inhibition of growth of blue stain fungi by wood extractives. Canadian Journal of Botany, 46, 757-61. CAS Google Scholar
Showalter, T.D. & Turchin, P. 1993. Southern pine beetle infestation development: interaction between pine and hardwood basal area. Forest Science, 39, 201-10. Google Scholar
Smith, R.H. 1963. Toxicity of pine resin vapors to 3 species of Dendroctonus bark beetles. Journal of Economic Entomology, 56, 827-31. CAS Google Scholar
Solheim, H. & Långström B. 1991. Blue stain fungi associated with Tomicus piniperda in Sweden and preliminary observation on their pathogenicity. Annales des Sciences Forestières, 48, 149-56. Google Scholar
Solheim, H., Långström, B. & Hellqvist, C. 1993. Pathogenicity of the blue-stain fungi Leptographium wingfieldii and Ophiostoma minus to Scots pine: effect of the tree pruning and inoculum density. Canadian Journal of Forest Research, 23, 1438-43. Google Scholar
Stark, R.W., Miller, P.R., Cobb, F.W., Jr., Wood, D.L. & Parmeter, J.R., Jr. 1968. Photochemical oxidant injury and bark beetles (Coleoptera: Scolytidae) infestation of ponderosa pine. I. Incidence of bark beetle infestation in injured trees. Hilgardia, 39, 121-26. Google Scholar
Steele, C.L., Lewinsohn, E. & Croteau, R. 1995. Induced oleoresin biosynthesis in grand fir as a defence against bark beetles. Proceedings National Academy of Sciences USA, 92, 4164-68. CAS Google Scholar
Stephen F.M., Paine T.D., 1985. Seasonal patterns of host resistance to fungal associates of the southern pine beetle. Zeitschrift für Angewandte Entomologie, 99, 113-22. Google Scholar
Storer, A.J. & Speight, M.R. 1996. Relationships between Dendroctonus micans Kug. (Coleoptera: Scolytidae) survival and development and biochemical changes in Norway spruce, Picea abies (L.) Karst., phloem caused by mechanical wounding. Journal of Chemical Ecology, 22, 559-73. CAS Google Scholar
Thalenhorst W., 1958. Grundzüge der populationsdynamik des grössen Fichten-borkenkäfer Ips typographus L. Shriftenreihe der Forstlichen Fakültat der Universität Göttingen, 21. Google Scholar
Tisdale, R.A. & Nebeker, T.E. 1992. Resin flow as a function of height along the bole of loblolly pine. Canadian Journal of Botany, 70, 2509-11. Google Scholar
Tkacz, B.M. & Schmitz, R.F. 1986. Association of an endemic mountain pine beetle population with lodgepole pine infected by Armillaria root disease in Utah. USDA Forest Service Research Note INT-353. Google Scholar
Tobolski, J.J. & Hanover, J.W., 1971. Genetic variations in the monoterpenes of Scotch pine. Forest Science, 17, 293-99. CAS Google Scholar
Tuomi, J., Fagerstrom, T. & Niemela, P. 1991. Carbon allocation, phenotypic plasticity, and induced defences. In. Phytochemical induction by herbivores, D.W. Tallamy, M.J. Raupp (Eds), Wiley & Sons, New York. Google Scholar
Vetrova, V.P., Stasova, V.V. & Pashenova, N.V. 1999. Effect of defoliation on resistance response of _Abies sibirica_Ledeb. to inoculation with blue-stain fungi. In: Physiology and genetics of tree phytophage interactions, F. Lieutier, W.J. Mattson, M.R. Wagner (Eds), INRA, Versailles. Google Scholar
Viiri, H., Annila, E., Kitunen, V. & Niemela, P. 2001. Induced responses in stilbenes and terpenes in fertilized Norway spruce after inoculation with blue-stain fungus, Ceratocystis polonica. Trees, 15, 112-22. CAS Google Scholar
Viiri, H., Kytö & Niemela, P. 1999. Resistance of fertilized Norway spruce (Picea abies(L.) Karst.) and Scots pine (Pinus sylvestris L.). In. Physiology and Genetics of Tree-Phytophage Interactions, F. Lieutier, W.J. Mattson, M.R. Wagner (Eds). Versailles: INRA Editions. Google Scholar
Vité, J.P., 1961. The influence of water supply on oleoresin exudation pressure and resistance to bark beetle attack in Pinus ponderosa. Contribution Boyce Thompson Institute, 21, 37-66. Google Scholar
Vité, J.P. & Wood, D.L. 1961. A study of the applicability of the measurement of oleoresin exudation pressure in determining susceptibility of second-growth ponderosa pine to bark beetle infestation. Contribution Boyce Thompson Institute, 21, 67-78. Google Scholar
Vouland, G. 1991. Le Dendroctone de l’Epicea: Dendroctonus micans Kug. (Col.: Scolytidae) dans le Massif Central. Thèse Université Aix-Marseille III. Google Scholar
Wainhouse, D., Cross, D.J. & Howell, R.S. 1990. The role of lignin as a defence against the spruce bark beetle Dendroctonus micans: effects on larvae and adults. Oecologia 85, 257-65. Google Scholar
Wainhouse, D., Ashburner, R., Ward, E. & Boswell, R. 1997. The effect of lignin and bark wounding on susceptibility of spruce trees to Dendroctonus micans. Journal of Chemical Ecology 24, 1551-61. Google Scholar
Wainhouse, D., Rose, D.R. & Pearce, A.J. 1998a. The influence of preformed defences on the dynamic wound response in Spruce bark. Functional Ecology 11, 564-72. Google Scholar
Wainhouse, D., Ashburner, E., Ward, E. & Rose, J. 1998b. The effect of variation of light and nitrogen on growth and defence in young Sitka spruce. Functional Ecology, 12, 561-72. Google Scholar
Wallin, K.F., Kolb, T.E., Skov, K.R. & Wagner, M.R. 2003. Effects of scorch on ponderosa pine resistance to bark beetles in northern Arizona. Environmental Entomology, 32, 652-61. Google Scholar
Wallin, K.F. & Raffa, K.F. 1999. Altered constitutive and inducible phloem monoterpenes following natural defoliation of Jack pine: implications to host mediated interguild interactions and plant defence theories. Journal of Chemical ecology 25, 861-80. CAS Google Scholar
Wallin, K.F. & Raffa, K.F. 2001. Effects of folivory on subcortical plant defences: can defence theories predict interguild processes? Ecology, 82, 1387-1400. Google Scholar
Waring, R.H. & Pitman, G.B. 1983. Physiological stress in lodgepole pine as a precursor for mountain pine beetle attack. Zeitschrift für angwandte Entomologie, 96, 265-70. Google Scholar
Waring, R.H. & Pitman, G.B. 1985. Modifying lodgepole pine stands to change susceptibility to mountain pine beetle attack. Ecology 66, 889-97. Google Scholar
Warren, J.M., Allen, H.L. & Booker, F.L. 1999. Mineral nutrition, resin flow and phloem phytochemistry in loblolly pine. Tree Physiology, 19, 655-63. PubMedCAS Google Scholar
Wong, B.L. & Berryman, A.A. 1977. Host resistance to the fir engraver beetle. 3. Lesion development and containment of infection in resistant Abies grandis inoculated with _Trichosporium symboticum_Canadian Journal of Botany, 55, 1358-65. Google Scholar
White, T.C.R. 1984. The abundance of invertebrate herbivores in relation to the availability of nitrogen in stressed foods. Oecologia, 63, 90-105. Google Scholar
Wilkinson, R.C. 1979. Tunnelling in slash pine by Ips calligraphus (Germ). Florida Entomologist, 62, 72-73. Google Scholar
Witanachchi, J.P. & Morgan, F.D. 1981. Behavior of the bark beetle, Ips grandicollis, during host selection. Physiological Entomology, 6, 219-23. Google Scholar
Wright, L.C., Berryman, A.A. & Gurusiddaiah, S. 1979. Host resistance to the fir engraver beetle, Scolytus ventralis (Coleoptera: Scolytidae) 4. Effect of defoliation on wound monoterpene and inner bark carbohydrate concentrations. Canadian Entomologist 111, 1255-62. CAS Google Scholar
Wright, L.C., Berryman, A.A. &, Wickman, B.E. 1984. Abundance of the fir engraver, Scolytus ventralis and the Douglas-fir beetle, Dendroctonus pseudotsugae, following tree defoliation by the Douglas-fir tussock moth, Orgyia pseudotsugata. Canadian Entomologist 116, 293-305. Google Scholar
Ye, H. & Lieutier, F. 1997. Shoot aggregation by Tomicus piniperda(Col; Scolytidae) in Yunnan, southwestern China. Annales des Sciences Forestières, 54, 635-41. Google Scholar
Ye H. & Lieutier F. 2001. Seasonal variations in Pinus yunnanensis natural resistance to artificial fungus inoculation, in relation with water stress. Final plenary workshop of the EU project ERBIC 18CT96 0057 ‘‘_Definition of methods to protect conifers from insects compromising forest survival and regeneration in the mountain areas of Southwestern China_’’. 27-31 May. Lijiang, China. Google Scholar