La stimulation des défenses de l’arbre par les champignons Ophiostomatoïdes peut expliquer le succès des attaques de Scolytes sur conifères
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Anderbrandt O., Schlyter F., and Lofqvist J., 1988. Dynamics of tree attack in the bark beetle Ips typographus under semi-epidemic conditions. In: T.L. Payne and H. Saarenmaa (Eds.), Integrated control of Scolytid bark beetle, Blacksburg: Virginia Polytech Institute State University, pp. 35–51.
Aukema B.H., Werner R.A., Haberkern K.E., Illman B.L., Clayton M.K., and Raffa K.F., 2005. Quantifying sources of variation in the frequency of fungi associated with spruce beetles: Implications for hypothesis testing and sampling methodology in bark beetle-symbiont relationships. For. Ecol. Manage., 10, 187–202.
Ayres M.P., Wilkens R.T., Ruel J.J., Lombardero M.J., and Vallery E., 2000. Nitrogen budgets of phloem-feeding bark beetles with and without symbiotic fungi (Coleoptera: Scolytidae). Ecology 81: 2198–2210.
Barras S.J., 1970. Antagonism between Dendroctonus frontalis and the fungus Ceratocystis minor. Ann. Entomol. Soc. Am. 63: 1187–1190.
Basham H.G., 1970. Wilt of loblolly pine inoculated with blue-stain fungi of the genus Ceratocystis. Phytopathology 60: 750–754.
Ben Jamaa M.L., Lieutier F., Yart A., Jerraya A., and Khouja M.L., 2007. Phytopathogenic fungi associated with the bark beetles Tomicus piniperda and Orthotomicus erosus in Tunisia; study of the virulence of some isolates. For. Pathol. 37: 51–63.
Berryman A.A., 1972. Resistance of conifers to invasion by bark beetlefungus associations. BioScience 22: 298–602.
Berryman A.A., 1976. Theoretical explanation of mountain pine betle dynamics in lodgepole pine forests. Environ. Entomol. 5: 1225–1233.
Berryman A.A., 1982. Population dynamics of bark beetles. In: J.B. Mitton and K.B. Sturgeon (Eds.), Bark beetles in North American conifers, Austin, Univ. Texas, pp. 264–314.
Bleiker K.P. and Six D.L., 2007. Dietary benefits of fungal associates to an eruptive herbivore: potential implications of multiple associates on host population dynamics. Environ. Entomol. 36: 1384–1396.
Bleiker K.P. and Six D.L., 2009. Competition and coexistence in a multipartner mutualism: interactions between two fungal symbionts of the mountain pine beetle in beetle-attacked trees. Microb. Ecol. 57: 191–202.
Bois E. and Lieutier F. 1997. Phenolic response of Scots pine clones to inoculation with Leptographium wingfieldii, a fungus associated with Tomicus piniperda. Plant Physiol.Biochem. 35: 819–825.
Bridges J.R., 1983. Mycangial fungi of Dendroctonus frontalis (Coleoptera: Scolytidae) and their relationship to beetle population trends. Environ. Entomol. 12: 858–861.
Bridges J.R., Nettleton W.A., and Conner M.D., 1985. Southern pine beetle (Coleoptera: Scolytidae) infestations without the blue-stain fungus, Ceratocystis minor. J. Econ. Entomol. 78: 325–27.
Brignolas F., Lieutier F., Sauvard D., Yart A., Drouet A., and Claudot A.-C., 1995. Changes in soluble phenol content of Norway spruce (Picea abies Karst.) phloem in response to wounding and inoculation with Ophiostoma polonicum. Eur. J. For. Pathol. 25: 253–65.
Brignolas F., Lieutier F., Sauvard D., Christiansen E., and Berryman A.A., 1998. Phenolic predictors for Norway spruce resistance to the bark beetle Ips typographus (Coleoptera: Scolytidae) and an associated fungus, Ceratocystis polonica. Can. J. For. Res., 28: 720–28.
Cardoza Y.J., Klepzig K.D., and Raffa K.F., 2006. Bacteria in oral secretions of an endophytic insect inhibit antagonistic fungi. Ecol. Entomol. 31: 636–645.
Cardoza Y.J., Moser J.C., Klepzig K.D., and Raffa K.F., 2008 Multipartite symbioses among fungi, mites, nematodes, and the spruce beetle, Dendroctonus rufipennis. Environ. Entomol. 37: 956–963.
Chararas C., 1962. Scolytides des conifères. Lechevalier Ed., Paris, 556p.
Christiansen E., 1985a. Ceratocystis polonica inoculated in Norway spruce: Blue-staining in relation to inoculum density, resinosis and tree growth. Eur. J. For. Pathol. 15: 160–167.
Christiansen E., 1985b. Ips/Ceratocystis infection of Norway spruce: what is a deadly dosage? Z. Angew. Entomol. 99: 6–11.
Christiansen E. and Glosli A.M., 1996. Mild drought enhances the resistance of Norway spruce to a bark beetle-transmitted blue-stain fungus. In: W.J. Mattson, P. Niemela, and M. Rousi (Eds.), Dynamics of forest herbivory: Quest for pattern and principle, USDA For. Serv. Gen. Tech. Rep. NC-183, pp. 192–99.
Christiansen E., Waring R.H., and Berryman A.A., 1987. Resistance of conifers to bark beetle attacks: searching for general relationships. For. Ecol. Manage. 22: 89–106.
Colineau B. and Lieutier F., 1994. Production of Ophiostoma-free adults of Ips sexdentatus Boern. (Coleoptera: Scolytidae) and comparison with naturally contaminated adults. Can. Entomol. 126: 103–10.
Cook S.P. and Hain F.P., 1987. Four parameters of the wound response of loblolly and shortleaf pines to inoculations with the blue-staining fungus associated with the southern pine beetle. Can. J. Bot. 65: 2403–2409.
Cook S.P., Hain F.P., and Nappen P.B., 1986. Seasonality of hypersensitive response by loblolly and shortleaf pine to inoculation with a fungal associate of the southern pine beetle (Coleoptera: Scolytidae). J. Entomol. Sci. 21: 283–285.
Croisé L. and Lieutier F., 1993, Effect of drought on the induced defence reaction of Scots pine to bark beetle associated fungi. Ann. Sci. for. 50: 91–97.
Croisé L., Lieutier F., and Dreyer E., 1998a. Scots pine responses to number and density of inoculation points with Leptographium wingfieldii Morelet, a bark beetle-associated fungus. Ann. Sci. For. 55: 497–506.
Croisé L., Dreyer E., and Lieutier F., 1998b, Effects of drought stress and severe prunning on the reaction zone induced by single inoculations with a bark beetle associated fungus (Ophiostoma ips) in the phloem of young Scots pines. Can. J. For. Res. 28: 1814–1824.
Delorme L. and 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.
Dymerski A.D., Anhold J.A., and Munson A.S., 2001. Spruce beetle (Dendroctonus rufipennis) outbreaks in Engelmann spruce (Picea engelmanni) in central Utah, 1986–1998. West. N. Am. Nat., 61: 19–24.
Eckhardt L.G., Goyer R.A., Klepzig K.D., and Jones J.P., 2004. Interactions of Hylastes species (Coleoptera: Scolytidae) with Leptographium species associated with loblolly pine decline. J. Econ. Entomol. 97: 468–474.
Filip G.M., Christiansen E., and Parks C., 1989. Secondary resin production increases with vigor of Abies grandis inoculated with Trichosporium symbioticum in Northeastern Oregon. USDA FS, PNW-RN 489, 1–10.
Franceschi V.R., Krokene P., Christiansen E., and Krekling T., 2005. Anatomical and chemical defenses of conifers against bark beetles and other pests. New Phytol. 167: 353–376.
Francke-Grosmann H., 1967. Ectosymbiosis in wood-inhabiting insects. In: S.M. Henry (Ed.), Symbiosis, Vol. 2, Academic Press, New York, London.
Furniss R.L. and Carolin V.M., 1977. Western Forest Insects. USDA For. Serv. Misc. Publ. N∘ 1339, 654 p.
Grégoire J.C. and Evans H.F., 2004. Damage and control of BAWBILT organisms, an overview. In: F. Lieutier, K.R. Day, A. Battisti, J.C. Grégoire, and H.J. Evans (Eds.), Bark and wood boring insects in living trees in Europe, a synthesis, Kluwer Acad. Publ., Dordrecht, pp. 19–37.
Guérard N., Dreyer E., and Lieutier F., 2000. Interactions between Scots pine, Ips acuminatus (Gyll.) and Ophiostoma brunneo-ciliatum (Math.): estimation of critical thresholds of attack and inoculation densities and effect on hydraulic properties of the stem. Ann. For. Sci. 57: 681–690.
Harding S., 1989. The influence of mutualistic blue-stain fungi on bark beetle population dynamics. Ph.D thesis, Royal Veterinary and Agricultural University Copenhagen.
Harrington T.C., 1993a. Diseases of conifers caused by species of Ophiostoma and Leptographium. In: M.J. Wingfield, K.A. Seifert, and J.F. Webber (Eds.), Ophiostoma and Ceratocystis: Taxonomy, Ecology and Pathogenicity, APS Press, St Paul, Minnesota, pp. 161–172.
Harrington T.C., 1993b. Biology and taxonomy of fungi associated with bark beetles. In: T.D. Schowalter and G.M. Filip (Eds.), BeetlePathogen Interactions in Conifer Forests, New York: Academic Press, pp. 37–58.
Harrington T.C., 2005. Ecology and evolution of mycetophagous bark beetles and their fungal partners. In: F.E. Vega and M. Blackwell (Eds.), Insect-fungal associations, ecology and evolution, Oxford University Press, pp. 257–289.
Harrington T.C. and Cobb F.W. Jr., 1983. Pathogenicity of Leptographium and Verticicladiella spp. Isolated from roots of western North American conifers. Phytopathology 73: 596–599.
Harrington T.C. and Wingfield M.J., 1998. The Ceratocystis species on conifers. Can. J. Bot. 76: 1446–57
Hetrick L.A., 1949. Some overlooked relationships of southern pine beetle. J. Econ. Entomol. 42: 466–469.
Highley L. and Tattar T.A., 1985. Leptographium terebrantis and black turpentine beetles associated with blue stain and mortality of black and Scots pine on Cape Cod, Massachussets. Plant Dis. 69: 528–530.
Hobson K.R., Parmeter J.R. Jr., and Wood D.L. 1994. The role of fungi vectored by Dendroctonus brevicomis Leconte (Coleoptera: Scolytidae) in occlusion of ponderosa pine xylem. Can. Entomol. 126: 277–282.
Hofstetter R.W., Cronin J.T., Klepzig K.D., Moser J.C., and Ayres M.P., 2006. Antagonisms, mutualisms and commensalisms affect outbreak dynamics of the southern pine beetle. Oecologia, 147: 679–691.
Hofstetter R.W., Dempsey T.D., Klepzig K.D., and Ayres M.P., 2007. Temperature-dependent effects on mutualistic, antagonistic, and commensalistic interactions among insects, fungi and mites. Community Ecol. 8: 47–56.
Horntvedt R., Christiansen E., Solheim H., and Wang, S., 1983. Artificial inoculation with Ips typographus-associated blue-stain fungi can kill healthy Norway spruce trees. Medd. fra Norsk. Skogforsk. 38: 1–20.
Jacobs K. and Wingfield M.J., 2001. Leptographium species, Insect associates and Agents of Blue Stain, APS Press, St Paul, Minnesota, 207 p.
Jankowiak R., 2005. Fungi associated with Ips typographus on Picea abies in southern Poland and their succession into the phloem and sapwood of beetle-infested trees and logs. For. Pathol. 35: 37–55.
Kelley S.T. and Farrell B.D., 1998. Is specialization a dead end? The phylogeny and host use in Dendroctonus bark beetles (Scolytidae). Evolution 52: 1731–1743.
Kim J-J., Plattner A., Lim Y.W., and Breuil C., 2008. Comparison of two methods to asses the virulence of the mountain pine beetle associate, Grosmannia clavigera, to Pinus contorta. Scand. J. For. Res. 23: 98–104.
Kirisits T., 1998. Pathogenicity of three blue-stain fungi associated with the bark beetle Ips typographus to Norway spruce in Austria. Österr. Z. Pilzk. 7: 191–201.
Kirisits T., 1999. Report on a strain of the pathogenic blue-stain fungus Ceratocystis polonica with low virulence. Osterr. Z. Piltz. 8: 157–167.
Kirisits T., 2001. Studies on the association of ophiostomatoid fungi with bark beetles in Austria with special emphasis on Ips typographus and Ips cembrae and their associated fungi Ceratocystis polonica and Ceratocystis laricicola. Dissertation thesis, Universität für Bodenkultur Wien.
Kirisits T., 2004. Fungal associates of European bark beetles with special emphasis on the Ophiostomatoid fungi. In: F. Lieutier, K.R. Day, A. Battisti, J.C. Grégoire, and H.F. Evans (Eds.), Bark and wood boring insects in living trees in Europe, a synthesis, Kluwer, Dordrecht, pp. 181–235.
Kirisits T., Grubelnik R., and Führer E., 2000. Die ökologische Bedeutung von Bläuepilzen für rindenbrütende Borkenkäfer. In: F. Müller (Ed.), Mariabrunner Waldbautage 1999 — Umbau sekundärer Nadelwälder, Vienna, Schriftenreihe der Forstlichen Bundesversuchsanstalt Wien, FBVA-Berichte, 111, pp. 117–137.
Klepzig K.D. and Six D.L., 2004. Bark beetle-fungal symbiosis: context dependency in complex associations. Symbiosis 37: 189–205.
Klepzig K.D., Raffa K.F., and Smalley E.B., 1991. Association of an insect-fungal complex with red pine decline in Wisconsin. For. Sci. 37: 1119–1139.
Klepzig K.D., Smalley E.B., and Raffa K.F., 1995. Dendroctonus valens and Hylastes porculus (Coleoptera: Scolytidae): vectors of pathogenic fungi (Ophiostomatales) associated with red pine decline disease. Great Lakes Entomol. 28: 81–87.
Klepzig K.D., Moser J.C., Lombardero M.J., Ayres M.P., Hofstetter R.W., and Walkinshaw C.J., 2001a. Mutualism and antagonism: ecological interactions among bark beetles, mites and fungi. In: M.J. Jeger and N.J. Spence (Eds.), Biotic interactions in plant-pathogen associations, CAB International, pp. 237–267.
Klepzig K.D., Moser J.C., Lombardero F.J., Hofstetter R.W., and Ayres M.P., 2001b. Symbiosis and competition: complex interactions among beetles, fungi and mites. Symbiosis 30: 83–96.
Knizek M. and Beaver R., 2004. Taxonomy and systematic of bark and ambrosia beetles. In: F. Lieutier, K.R. Day, A. Battisti, J.C. Grégoire, and H.J. Evans (Eds.), Bark and wood boring insects in living trees in Europe, a synthesis, Kluwer Acad. Publ., Dordrecht, pp. 41–54.
Krokene P. 1996. The role of blue-stain fungi in tree-killing by bark beetles. Thesis, University of Oslo.
Krokene P. and Solheim H., 1997. Growth of four bark-beetle-associated blue-stain fungi in relation to the induced wound response in Norway spruce. Can. J. Bot. 75: 618–625.
Krokene P. and Solheim H., 1998. Pathogenicity of four blue-stain fungi associated with aggressive and nonaggressive bark beetles. Phytopathology 88: 39–44
Krokene P. and Solheim H., 1999. What do low density inoculations with fungus tell us about fungal virulence and tree resistance? In: Lieutier F. Mattson W.J., and Wagner M.R. (Eds.), Physiology and genetics of tree-phytophage interactions, INRA Editions, Versailles, pp. 353–362.
Långström B. and Hellqvist C., 1988. Scots pine resistance against Tomicus piniperda as related to tree vitality and attack density. In: Payne T.L. and Saarenmaa H. (Eds.), Integrated control of scolytid bark beetles, Virginia Polytech. Inst. St. Univ., Blacksburg, pp. 121–133.
Långström B. and Hellqvist C., 1993. Scots pine susceptibility to attack by Tomicus piniperda (L) as related to pruning date and attack density. Ann. Sci. For. 50: 101–117.
Långström B., Hellqvist C., Ericsson A., and Gref D., 1992. Induced defense reaction in Scots pine following stem attacks by Tomicus piniperda L. Ecography 15: 318–327.
Långström B., Solheim H., Hellqvist C., and 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. Eur. J. For. Pathol. 23: 400–415.
Lee S., Kim J.-J., and Breuil C., 2006. Diversity of fungi associated with mountain pine beetle, Dendroctonus ponderosae, and infested lodgepole pines in British Columbia. Mountain Pine beetle Research Initiative Working Paper 2006–06, 20 p.
Lévieux J., Cassier P., Guillaumin D., and Roques A., 1991. Structures implicated in the transportation of pathogenic fungi by the European bark beetle, Ips sexdentatus Boerner: Ultrastructure of a mycangium. Can. Entomol. 123: 245–54.
Lieutier F., 1992. Les réactions de défense des conifères et stratégies d’attaque de quelques Scolytides européens. Mém. Soc. Roy. belge Entomol. 35: 529–539.
Lieutier F., 1995. Associated fungi, induced reaction and attack strategy of Tomicus piniperda (Coleoptera: Scolytidae) in Scots pine. In: F.P. Hain, S.M. Salom, W.F. Ravlin, T.L. Payne, and K.F. Raffa (Eds.), Behavior, Population Dynamics and Control of Forest Insects, Proceedings International Union Forestry Research Organizations Joint Conference, February 1994 Maui, Hawaï, pp. 139–153.
Lieutier F., 2002. Mechanisms of resistance in conifers and bark beetle attack strategies. In: M.R. Wagner, K.M. Clancy, F. Lieutier, and T.D. Paine (Eds.), Mechanisms and deployment of resistance in trees to insects, Kluwer, Dordrecht, pp. 31–75.
Lieutier F., 2004. Host resistance to bark beetles and its variations. In: F. Lieutier, K. Day, A. Battisti, J.C. Grégoire, and H. Evans (Eds.), Bark and wood boring insects in living trees in Europe, A synthesis, Kluwer, Dordrecht, pp. 135–180.
Lieutier F., Yart A., Garcia J., Poupinel B., and Lévieux J., 1988. Do fungi influence the establishment of bark beetles in Scots pine? In: W.J. Mattson, J. Lévieux, and C. Bernard-Dagan (Eds.), Mechanisms of woody plant defenses against insects: search for pattern, Springer, New York, pp. 321–334.
Lieutier F., Cheniclet C., and Garcia J., 1989a. Comparison of the defense reactions of Pinus pinaster and Pinus sylvestris to attacks by two bark beetles (Coleoptera: Scolytidae) and their associated fungi. Environ. Entomol. 18: 228–234.
Lieutier F., Yart A., Garcia J., Ham M.C., Morelet M., and Lévieux J., 1989b. Champignons phytopathogènes associés à deux Coléoptères Scolytidae du pin sylvestre (Pinus sylvestris L.) et étude préliminaire de leur agressivité envers l’hôte. Ann. Sci. For. 46: 201–216.
Lieutier F., Yart A., Garcia J., and Ham M-C., 1990. Cinétique de croissance des champignons associés à 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.
Lieutier F., Yart A., Jay-Allemand C., and Delorme L. 1991a. Preliminary investigations on phenolics as a response of Scots pine phloem to attacks by bark beetles and associated fungi. Eur. J. For. Pathol. 21: 354–354.
Lieutier F., Garcia J., Yart A., Vouland G., Pettinetti M., and Morelet M., 1991b. Ophiostomatales (Ascomycetes) associées à Ips acuminatus (Coleoptera: Scolytidae) sur le pin sylvestre (Pinus sylvestris) dans le Sud-Est de la France, et comparaison avec Ips sexdentatus Boern. Agronomie 11: 807–817.
Lieutier F., Vouland G., Pettinetti M., Garcia J., Romary P., and Yart A., 1992. Defence reactions of Norway spruce (Picea abies Karst.) to artificial insertion of Dendroctonus micans Kug. (Coleoptera: Scolytidae). J. Appl. Entomol. 114: 174–186.
Lieutier F., Garcia J., Yart A., and Romary P., 1995. Wound reaction of Scots pine (Pinus sylvestris L.) to attacks by Tomicus piniperda L. and Ips sexdentatus Boern. (Coleoptera: Scolytidae). J. Appl. Entomol. 119: 591–600.
Lieutier F., Sauvard D., Brignolas F., Picron V., Yart A., Bastien C., and Jay-Allemand C., 1996. Changes in phenolic metabolites of Scots pine phloem induced by Ophiostoma brunneo-ciliatum, a barkbeetle-associated fungus. Eur. J. For. Pathol., 26, 145–158.
Lieutier F., Yart A., Ye H., Sauvard D., and Gallois V., 2004. Betweenisolate variations in the performances of Leptographium wingfieldii Morelet, a fungus associated with the bark beetle Tomicus piniperda L.Ann. For. Sci. 61: 45–53.
Lieutier F., Ghaioule D., and Yart A., 2005. Virulence and possible role of fungi associated with the bark beetles Tomicus piniperda L., and Orthotomicus erosus Woll. in Morocco. In: F. Lieutier and D. Ghaioule (Eds.), Entomological research in Mediterranean ecosystems, INRA Ed., Versailles, pp. 195–208.
Mathiesen A., 1950. Über einige mit Borkenkäfern assoziierte Bläuepilze in Schweden. Oikos 2: 275–308.
Mathiesen-Käärik A., 1953. Eine Übersicht über die gewöhnlichsten mit Borkenkäfern assoziierten Bläuepilze in Schweden und einige für Schweden neue Bläuepilze. Meddel. Frå. Stat. Skogforsk. Inst. 43: 1–74.
Mathre D.E., 1964a. Survey of Ceratocystis spp. associated with bark beetles in California. Contrib. Boyce Thomp. Inst. 22: 353–361.
Mathre D.E., 1964b. Pathogenicity of Ceratocystis ips and Ceratocystis minor to Pinus ponderosa. Contrib. Boyce Thomp. Inst. 22: 363–388.
Neal T.A. and Ross D.W., 1999. Pathogenicity to western larch (Larix occidentalis) of two fungi, Ophiostoma pseudotsugae and Leptographium abietinum, associated with the Douglas fir beetle (Coleoptera: Scolytidae). Agric. For. Entomol. 1: 203–207.
Nebeker T.E., Hodges J.D., and Blanche C.A. 1993. Host Response to Bark Beetle and Pathogen Colonization. In. T.D. Schowalter and G.M. Filip (Eds.), Beetle Pathogen Interactions in Conifer Forests, Academic Press, San Diego, pp. 157–173.
Owen D.R., Lindahl K.Q., Wood D.L., and Parmeter J.R.Jr., 1987. Pathogenicity of fungi isolated from Dendroctonus valens, D. brevicomis and D. ponderosae to ponderosa pine seedlings. Phytopathology 77: 631–636.
Paine T.D. and Birch M.C., 1983. Acquisition and maintenance of mycangial fungi by Dendroctonus brevicomis LeConte (Coleoptera: Scolytidae). Environ. Entomol. 12: 1384–1386.
Paine T.D. and Stephen F.M., 1987. Fungi associated with the southern pine beetle: avoidance of induced defense response in loblolly pine. Oecologia 74: 377–379.
Paine T.D., Raffa K.F., and Harrington T.C., 1997. Interactions among Scolytid bark beetles, their associated fungi, and live host conifers. Annu. Rev. Entomol. 42: 179–206.
Parmeter J.R., Slaughter G.W., Chen M.M., and Wood D.L., 1992. Rate and depth of sapwood occlusion following inoculation of ponderosa pine with bluestain fungi. For. Sci. 38: 34–44.
Payne T.L., 1980. Life History & Habits. In: R.C. Thatcher, J.L. Searcy, J.E. Coster, and G.D. Hertel (Eds.), The southern pine beetle, USDA For. Serv. Sci. Educ. Admin. Tech. Bull. N∘ 1631, pp. 7–28.
Plattner A., Kim J-J., DiGiustini S., and Breuil C., 2008. Variation in pathogenicity of a mountain pine beetle-associated fungus, Grosmannia clavigera, on young lodgepole pine in British Columbia. Can J. Plant Pathol. 30: 1–10.
Raffa K.F., 1991. Induced defensive reactions in conifer-bark beetle systems. In: D.W. Tallamy and M.J. Raupp (Eds.), Phytochemical induction by herbivore, Wiley and Sons, pp. 245–276.
Raffa K.F., 2001. Mixed messages across multiple trophic levels: the ecology of bark beetle chemical communication systems. Chemoecology 11: 49–65.
Raffa K.F. and Berryman A.A., 1982a. Accumulation of monoterpenes and associated volatiles following fungal inoculation of grant fir with a fungus transmitted by the fir engraver Scolytus ventralis (Coleoptera: Scolytidae). Can. Entomol. 114: 797–810.
Raffa K.F. and Berryman A.A., 1982b. Gustatory cues in the orientation of Dendroctonus ponderosae (Coleoptera: Scolytidae) to host trees. Can. Entomol. 114: 97–104.
Raffa K.F. and Berryman A.A., 1983a. The role of host plant resistance in the colonization behavior and ecology of bark beetles (Coleoptera: Scolytidae). Ecol. Monog. 53: 27–49.
Raffa K.F. and Berryman A.A., 1983b. Physiological aspects of lodgepole pine wound responses to a fungal symbiont of the mountain pine beetle, Dendroctonus ponderosae (Coleoptera: Scolytidae). Can. Entomol. 115: 723–34.
Raffa K.F. and Klepzig K.D., 1992. Tree defense mechanisms against fungi associated with insects. In: R.A. Blanchette and A.R. Biggs (Eds.), Defense Mechanisms of Woody Plants Against Fungi, Springer, New York, pp. 354–389.
Raffa K.F. and Smalley E.B., 1988. Response of red and Jack pines to inoculation with microbial associates of the pine engraver, Ips pini (Coleoptera: Scolytidae). Can. J. For. Res. 18: 581–586.
Raffa K.F., Phillips T.W., and Salom S.M., 1993. Strategies and mechanisms of host colonization by bark beetles. In: Schowalter T.D. and Filip G.M. (Eds.), Beetle-pathogen interactions in conifer forests, Academic Press, San Diego, pp. 103–128.
Rane K.K. and Tattar T.A., 1987. Pathogenicity of blue stain fungi associated with Dendroctonus terebrans. Plant Dis. 71: 879–883.
Redfern D.B., Stoakley J.T., Steele H., and Minter D.W., 1987. Dieback and death of larch caused by Ceratocystis laricicola sp. nov. following attack by Ips cembrae. Plant Pathol. 36: 467–80.
Reid R.W., Whitney H.S., and Watson J.A., 1967. Reactions of lodgepole pine to attack by Dendroctonus ponderosae Hopkins and blue stain fungi. Can. J. Bot. 45: 115–126.
Rennerfelt E., 1950. Über den Zusammenhang zwischen dem Verblauen des Holzes und den Insekten. Oikos 2: 120–37
Reynolds K.M., 1992. Relations between activity of Dendroctonus rufipennis Kirby on Lutz spruce and blue stain associate with Leptographium abietinum (Peck) Wingfield. For. Ecol. Manage. 47: 71–86.
Rice A.V., Thormann M.N., and Langor D.W., 2007a. Mountain pine beetle associated blue-stain fungi cause lesions on jack pine, lodgepole pine, and lodgepole x jack pine hybrids in Alberta. Can. J. Bot. 85: 307–315.
Rice A.V., Thormann M.N., and Langor D.W., 2007b. Virulence of, and interactions among, mountain pine beetle associated blue-stain fungi on two pine species and their hybrids in Alberta. Can. J. Bot. 85: 316–323.
Rice A.V., Thormann M.N., and Langor D.W., 2008. Mountain pine beetle-associated blue-stain fungi are differentially adapted to boreal temperatures. For. Pathol. 38: 113–123.
Ross D.W. and Solheim H., 1997. Pathogenicity to Douglas fir of Ophiostoma pseudotsugae and Leptographium abietinum, fungi associated with the Douglas fir beetle. Can. J. For. Res. 27: 39–43.
Ross D.W., Fenn P., and Stephen F.M., 1992. Growth of southern pine beetle associated fungi in relation to the induced wound response in loblolly pine. Can. J. for. Res. 22: 1851–1859.
Russel C.E. and Berryman A.A., 1976. Host resistance to the fir engraver. 1. Monoterpene composition of Abies grandis pitch blisters and fungus-infested wounds. Can. J. Bot. 54: 14–18.
Safranyik L., Shrimpton D.M., and 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: D. Baumgartner (Ed.), Management of Lodgepole Pine Ecosystems, Pullman: Wash. State Univ. Coop. Ext. Serv., pp. 406–428.
Sallé A., Monclus R., Yart A., Garcia J., Romary P., and Lieutier F., 2005. Fungal flora associated with Ips typographus: Frequency, virulence and ability to stimulate the host defence reaction in relation to insect population levels. Can. J. For. Res. 35: 365–373.
Sallé A., Ye H., Yart A., and Lieutier F., 2008. Pinus yunnanensis resistance to a bark beetle associated fungus is increased during a natural water stress. Tree Physiol. 28: 679–687.
Siemaszko W., 1939. Zepoly grzybów towarzyszacych kornikom polskim [Fungi associated with bark-beetles in Poland]. Planta Polonica 7: 1–54 + plates.
Six D.L., 2003. Bark beetle-fungus symbiosis. In: T. Miller and K. Kourtzis (Eds.), Insect symbiosis, CRC Press, pp. 97–114.
Six D.L. and Bentz B.J., 2003. Fungi associated with the North American spruce beetle, Dendroctonus rufipennis. Can. J. For. Res. 33: 1815–1820.
Six D.L. and Bentz B.J., 2007. Temperature determines symbiont abundance in a multipartite bark beetle-fungus ectosymbiosis. Microb. Ecol. 54: 112–118.
Six D.L. and Klepzig K.D., 2004. Dendroctonus bark beetles as model systems for studies on symbiosis. Symbiosis 37: 207–232.
Six D.L. and Paine T.D., 1997. Ophiostoma clavigerum is the mycangial fungus of the Jeffrey pine beetle, Dendroctonus jeffreyi. Mycologia 89: 858–866.
Six D.L. and Paine T.D., 1998. Effects of mycangial fungi and host tree species on progeny survival and emergence of Dendroctonus ponderosae (Coleoptera: Scolytidae). Environ. Entomol. 27: 1393–1401.
Six D.L. and Paine T.D., 1999. Phylogenetic comparison of ascomycete mycangial fungi and Dendroctonus bark beetles (Coleoptera: Scolytidae). Ann. Entomol. Soc. Am. 91: 159–166.
Solheim H., 1986. Species of Ophiostomataceae isolated from Picea abies infested by the bark beetle Ips typographus. Nord. J. Bot. 6: 199–207
Solheim H., 1988. Pathogenicity of some Ips typographus associated blue-stain fungi to Norway spruce. Medd. fra Norsk. Inst. Skogforsk. 40: 1–11.
Solheim H., 1991. Oxygen deficiency and spruce resin inhibition of growth of fungi associated with Ips typographus. Mycol. Res. 95: 1387–1392.
Solheim H., 1992a. The early stages of fungal invasion in Norway spruce infested by the bark beetle Ips typographus. Can. J. Bot. 70: 1–5.
Solheim H., 1992b. Fungal succession in sapwood of Norway spruce infested by the bark beetle Ips typographus. Eur. J. For. Pathol. 22: 136–48.
Solheim H., 1993a. Ecological aspects of fungi associated with the spruce bark beetle Ips typographus in Norway. In: Wingfield M.J., Seifert K.A., and Webber J.F. (Eds.), Ceratocystis and Ophiostoma: taxonomy, ecology and pathogenicity, APS Press, St Paul, Minnesota, pp. 235–242.
Solheim H., 1993b. Fungi associated with the spruce bark beetle Ips typographus in an endemic area in Norway. Scand. J. For. Res. 8: 118–122.
Solheim H. and Krokene P., 1998a. Growth and virulence of mountain pine beetle associated blue-stain fungi, Ophiostoma clavigerum and Ophiostoma montium. Can. J. Bot. 76: 561–566.
Solheim H. and Krokene P., 1998b. Growth and virulence of Ceratocystis rufipenni and three blue-stain fungi isolated from the Douglas-fir beetle. Can. J. Bot. 76: 1763–1769.
Solheim H. and Långström B., 1991. Blue stain fungi associated with Tomicus piniperda in Sweden and preliminary observation on their pathogenicity. Ann. Sci. For. 48: 149–156.
Solheim H. and Safranyik L., 1997. Pathogenicity to Sitka spruce of Ceratocystis rufipenni and Leptographium abietinum, blue-stain fungi associated with the spruce bark beetle. Can. J. For. Res. 27: 1336–1341.
Solheim H., Långström B., and Hellqvist C., 1993. Pathogenicity of the blue stain fungi Leptographium wingfieldii and Ophiostoma minus to Scots pine: effect of tree pruning and inoculum density. Can J. For. Res. 23: 1438–1443.
Solheim H., Krokene P., and Långström B., 2001. Effects of growth and virulence of associated blue-stain fungi on host colonization behaviour of the pine shoot beetles Tomicus minor and T. piniperda. Plant Pathol. 50: 111–16.
Stephen F.M., Berisford C.W., Dahlsten D.L., Fenn P., and Moser J.C., 1993. Invertebrate and microbial associates. In: Schowalter T. and Filip G. (Eds.), Beetle-pathogen interactions in conifer forests, Academic, San Diego, pp. 129–153.
Uzunovic A. and Webber J.F., 1998. Comparison of blue stain fungi grown in vitro and in freshly cut pine billets. Eur. J. For. Pathol. 28: 323–334.
Viiri H., 1997. Fungal associates of the spruce bark beetle Ips typographus L. (Col., Scolytidae) in relation to different trapping methods. J. Appl. Entomol. 121: 529–33.
Viiri H. and Lieutier F., 2004. Ophiostomatoid fungi associated with the spruce bark beetle, Ips typographus, in post-epidemic areas in France. Ann. For. Sci. 61: 215–219.
Wallin K.F. and Raffa K.H., 2001. Effects of folivory on subcortical plant defenses: can defense theories predict interguild processes? Ecology 82: 1387–1400.
Waring R.H. and Pitman G.B., 1983. Physiological stress in lodgepole pine as a precursor for mountain pine beetle attack. Z. Angew. Entomol. 96: 265–270.
Whitney H.S., 1982. Relationships between bark beetles and symbiotic organisms. In: Mitton J.B. and Sturgeon K.B. (Eds.), Bark beetles in North American conifers, Austin, Univ. Texas Press, pp. 183–211.
Whitney H.S. and Cobb F.W., 1972. Non-staining fungi associated with the bark beetle Dendroctonus brevicomis (Coleoptera: Scolytidae) on Pinus ponderosa. Can. J. Bot. 50: 1943–1945.
Whitney H.S. and Farris S.H., 1970. Maxillary mycangium in the mountain pine beetle. Science 167: 54–55.
Wingfield M.J., 1983. Association of Verticicladiella procera and Leptographium terebrantis with insects in the lake states. Can. J. For. Res. 13: 1238–1245.
Wingfield M.J., Seifert K.A., and Webber J.F., 1993. Ceratocystis and Ophiostoma: taxonomy, ecology, and pathogenicity, APS Press, 293 p.
Wong B.E. and Berryman A.A., 1977. Host resistance to the fir engraver beetle. 3. Lesion development and containment of infection by resistant Abies grandis inoculated with Trichosporium symbioticum. Can. J. Bot. 55: 2358–2365.
Wood D.L., 1982. The role of pheromones, kairomones, and allomones in the host selection and behavior of bark beetles. Annu. Rev. Entomol. 27: 411–446.
Wullschleger S.D., McLaughlin S.B., and Ayres M.P., 2004. High resolution analysis of stem increment and sap flow for loblolly pine trees attacked by southern pine beetle. Can. J. For. Res. 34: 2387–2393.