Access the full text.
Sign up today, get DeepDyve free for 14 days.
(2014)
Forestry statistics 2014. [WWW document
E. Hansen, B. Bentz, James Powell, D. Gray, J. Vandygriff (2011)
Prepupal diapause and instar IV developmental rates of the spruce beetle, Dendroctonus rufipennis (Coleoptera: Curculionidae, Scolytinae).Journal of insect physiology, 57 10
P. Carle (1975)
Dendroctonus micans Kug. (Col. Scolytidae), l'hylésine géant ou dendroctone de l'épicéa, 27
M. Furniss (1996)
Taxonomic Status of Dendroctonus punctatus and D. micans (Coleoptera: Scolytidae)Annals of The Entomological Society of America, 89
M. Furniss (1995)
Biology of Dendroctonus punctatus (Coleoptera: Scolytidae)Annals of The Entomological Society of America, 88
D. Wainhouse, P. Beech-Garwood (1994)
Growth and survival of Dendroctonus micans larvae on six species of coniferJournal of Applied Entomology, 117
Xingfu Jiang, S. Huang, L. Luo, Yueqiu Liu, Lei Zhang (2010)
Diapause termination, post-diapause development and reproduction in the beet webworm, Loxostege sticticalis (Lepidoptera: Pyralidae).Journal of insect physiology, 56 9
D. Parker, T. Legg, C. Folland (1992)
A new daily central England temperature series, 1772–1991International Journal of Climatology, 12
C. King, N. Fielding (1989)
Dendroctonus micans in Britain - its biology and control
J. Grégoire, L. Safranyik (1985)
Host colonization strategies in Dendroctonus: larval gregariousness vs. mass-attack by adults ?
E. Elton (1950)
Dendroctonus micans Kugel., a pest of Sitka Spruce in the Netherlands.
B. Bentz, J. Logan, G. Amman (1991)
TEMPERATURE-DEPENDENT DEVELOPMENT OF THE MOUNTAIN PINE BEETLE (COLEOPTERA: SCOLYTIDAE) AND SIMULATION OF ITS PHENOLOGYThe Canadian Entomologist, 123
K. Voolma (1993)
The occurrence of the great European spruce bark beetle, Dendroctonus micans Kug. (Coleoptera, Scolytidae), as a pest of Scots pine, Pinus sylvestris L.Metsanduslikud Uurimused, 26
T. Wyatt, A. Phillips, J. Grégoire (1993)
Turbulence, trees and semiochemicals: wind‐tunnel orientation of the predator, Rhizophagus grandis, to its barkbeetle prey, Dendroctonus micansPhysiological Entomology, 18
M. Baisier, J.‐C. Grégoire, K. Delinte, O. Bonnard (1988)
Mechanisms of Woody Plant Defenses Against Insects
H. Danks (1987)
Insect dormancy: an ecological perspective.
J. Grégoire (1984)
Dendroctonus micans in Belgium: the situation today
J. Grégoire, M. Baisier, A. Drumont, D. Dahlsten, H. Meyer, W. Francke (1991)
Volatile compounds in the larval frass ofDendroctonus valens andDendroctonus micans (Coleoptera: Scolytidae) in relation to oviposition by the predator,Rhizophagus grandis (Coleoptera: Rhizophagidae)Journal of Chemical Ecology, 17
M. Baisier, J. Grégoire, K. Delinte, O. Bonnard (1988)
The Role of Spruce Monoterpene Derivatives as Oviposition Stimuli for Rhizophagus grandis, a Predator of the Bark Beetle, Dendroctonus micans
B. Wermelinger, MarC. Seifert (1998)
Analysis of the temperature dependent development of the spruce bark beetle Ips typographus (L) (Col., Scolytidae)Journal of Applied Entomology, 122
J. Powell, Janette Jenkins, J. Logan, B. Bentz (2000)
Seasonal temperature alone can synchronize life cyclesBulletin of Mathematical Biology, 62
N. Meurisse, D. Couillien, J. Grégoire (2008)
Kairomone traps: a tool for monitoring the invasive spruce bark beetle Dendroctonus micans (Coleoptera: Scolytinae) and its specific predator, Rhizophagus grandis (Coleoptera: Monotomidae)Journal of Applied Ecology, 45
A. Storer, D. Wainhouse, M. Speight (1997)
The effect of larval aggregation behaviour on larval growth of the spruce bark beetle Dendroctonus micansEcological Entomology, 22
M. Gilbert, G. Vouland, J. Grégoire (2001)
Past attacks influence host selection by the solitary bark beetle Dendroctonus micansEcological Entomology, 26
N. Fielding, H. Evans (1997)
Biological control of Dendroctonus micans (Scolytidae) in Great Britain., 18
Michael Crawley (2022)
The R book
V. Jarošı́k, A. Honěk, A. Dixon (2002)
Developmental Rate Isomorphy in Insects and MitesThe American Naturalist, 160
(1988)
Infestation des peuplements de Picea par Dendroctonus micans Kug. (Coleoptera: Scolytidae) en Limousin (France) et essais de lutte biologique avec le prédateur Rhizophagus grandis Gyll
J. Durant, D. Hjermann, Geir Ottersen, N. Stenseth (2007)
Climate and the match or mismatch between predator requirements and resource availabilityClimate Research, 33
P. Carle (1975)
Dendroctonus micans kug. (Col. Scolytidae), l'Hylésine géant ou Dendroctone de l'Epicéa (note bibliographique)
(2014)
Too Hot, Too Cold, Too Wet, Too Dry: Drivers and Impacts of the Seasonal Weather in the UK. Synopsis report CS01. Met Office
Janette Jenkins, J. Powell, J. Logan, B. Bentz (2001)
Low seasonal temperatures promote life cycle synchronizationBulletin of Mathematical Biology, 63
(1977)
Handbook for the Identification of British Insects (ed. by A. Watson)
Jack Lester, J. Irwin (2012)
Metabolism and cold tolerance of overwintering adult mountain pine beetles (Dendroctonus ponderosae): evidence of facultative diapause?Journal of insect physiology, 58 6
D. Wainhouse, P. Beech-Garwood, R. Howell, D. Kelly, M. Orozco (1992)
Field response of predatorRhizophagus grandis to prey frass and synthetic attractantsJournal of Chemical Ecology, 18
I. Hodek (2013)
Diapause development, diapause termination and the end of diapauseEuropean Journal of Entomology, 93
P. Carle (1975)
Dendroctonus micans Kug. (Col. Scolytidae), the giant bark-beetle or European spruce beetle (bibliographical note)., 27
D. Wainhouse, D. Cross, R. Howell (1990)
The role of lignin as a defence against the spruce bark beetle Dendroctonus micans: effect on larvae and adultsOecologia, 85
D. Wainhouse, T. Wyatt, A. Phillips, D. Kelly, M. Barghian, P. Beech-Garwood, D. Cross, R. Howell (1991)
Response of the predatorRhizophagus grandis to host plant derived chemicals inDendroctonus micans larval frass in wind tunnel experiments (Coleoptera: Rhizophagidae, Scolytidae)CHEMOECOLOGY, 2
Y. Hui (1994)
Influence of temperature on the experimental population of the pine shoot beetle, Tomicus piniperda (L.) (Col., Scolytidae)Journal of Applied Entomology, 117
J. Grégoire (1988)
The Greater European Spruce Beetle
J. Deneubourg, J. Grégoire, E. Fort (1990)
Kinetics of larval gregarious behavior in the bark beetleDendroctonus micans (Coleoptera: Scolytidae)Journal of Insect Behavior, 3
(1984)
Some new data on the biology of Rhizophagus grandis ( Col : Rhizophagidae )
N. Fielding, H. Evans, J. Williams, B. Evans (1991)
Distribution and Spread of the Great European Spruce Bark Beetle, Dendroctonus micans, in Britain—1982 to 1989Forestry, 64
Daily HadCET mean data
E. Dyer, P. Hall (1977)
FACTORS AFFECTING LARVAL DIAPAUSE IN DENDROCTONUS RUFIPENNIS (COLEOPTERA: SCOLYTIDAE)The Canadian Entomologist, 109
M. Furniss, S. Kegley (2008)
Biology of Dendroctonus murrayanae (Coleoptera: Curculionidae: Scolytinae) in Idaho and Montana and Comparative Taxonomic Notes, 101
D. Bevan, C. King (1983)
Dendroctonus micans Kug, -- a new pest of spruce in U.K.Commonwealth forestry review, 62
M. Kenis, B. Wermelinger, J. Grégoire (2007)
Research on Parasitoids and Predators of Scolytidae – A Review
(1984)
Dendroctonus micans in the United Kingdom: the result of two years experience in survey and © 2017 Crown copyright
J. Reeve, F. Anderson, S. Kelley (2012)
Ancestral State Reconstruction for Dendroctonus Bark Beetles: Evolution of a Tree Killer, 41
S. Kelley, Brian Farrell (1998)
IS SPECIALIZATION A DEAD END? THE PHYLOGENY OF HOST USE IN DENDROCTONUS BARK BEETLES (SCOLYTIDAE)Evolution, 52
C. King, N. Fielding, T. O'Keefe (1991)
Observations on the life cycle and behaviour of the predatory beetle, Rhizophagus grandis Gyll. (Col., Rhizophagidae) in BritainJournal of Applied Entomology, 111
A. Luik, K. Voolma (1990)
HIBERNATION PECULIARITIES AND COLD-HARDINESS OF THE GREAT SPRUCE BARK BEETLE, DENDROCTONUS MICANS KUG.Proceedings of the Estonian Academy of Sciences. Biology
(1982)
tonus micans, in Britain
R. Team (2014)
R: A language and environment for statistical computing.MSOR connections, 1
G. Vouland, D. Schvester (1994)
Bionomie et développement de Dendroctonus micans Kug (Col Scolytidae) dans le Massif centralAnnals of Forest Science, 51
D. Inward, D. Wainhouse, A. Peace (2012)
The effect of temperature on the development and life cycle regulation of the pine weevil Hylobius abietis and the potential impacts of climate changeAgricultural and Forest Entomology, 14
Hazan Akıncı, G. Özcan, M. Eroglu (2009)
Impacts of site effects on losses of oriental spruce during Dendroctonus micans (Kug.) outbreaks in TurkeyAfrican Journal of Biotechnology, 8
L. Safranyik, C. Simmons, H. Barclay (1990)
A conceptual model of spruce beetle population dynamics.
F. Lieutier, K. Day, A. Battisti, J. Grégoire, H. Evans (2004)
Bark and Wood Boring Insects in Living Trees in Europe, a Synthesis
I. Hodek (2002)
Controversial aspects of diapause developmentEuropean Journal of Endocrinology, 99
Dendroctonus micans is an invasive species that has spread throughout Britain, which prompts the question: how is the voltinism of this pest and its biocontrol agent Rhizophagus grandis affected by climate? Dendroctonus micans and R. grandis were reared at a range of constant temperatures. Lower developmental threshold temperature (LDT) and day degree (DD) requirements for the egg, larval and pupal stage of D. micans were estimated to be 7.4 °C 153 DD, 6.6 °C 527 DD and 7.2 °C 126 DD, respectively. At 12.5, 15 and 17.5 °C, prior to prepupal cell formation, fifth‐instar larvae underwent a diapause, which has not been observed previously in this species. Prepupal development rate also did not increase linearly with temperature. For R. grandis, the LDT and DD requirements for the egg, larval, prepupal and pupal stages were 5.7 °C 84 DD, 6.2 °C 263 DD, 8.1 °C 90 DD and 6.8 °C 178 DD, respectively. At 12.5 and 15 °C, most prepupae failed to pupate, which is indicative of a facultative diapause. The key developmental parameters reported in the present study may be used to model the phenology of the beetles throughout their range, providing better‐timed control strategies or to predict outbreak risk under climate change as a result of reduced biocontrol effectiveness.
Agricultural and Forest Entomology – Wiley
Published: Aug 1, 2017
Keywords: ; ; ; ; ; ; ; ; ; ;
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.