Access the full text.
Sign up today, get DeepDyve free for 14 days.
F. Messina (2004)
How labile are the egg‐laying preferences of seed beetles?Ecological Entomology, 29
G. Lushai, O. Markovitch, H. Loxdale (2002)
Host-based genotype variation in insects revisitedBulletin of Entomological Research, 92
J. Dalling, K. Harms (1999)
Damage tolerance and cotyledonary resource use in the tropical tree Gustavia superbaOikos, 85
F. Messina (2004)
PREDICTABLE MODIFICATION OF BODY SIZE AND COMPETITIVE ABILITY FOLLOWING A HOST SHIFT BY A SEED BEETLE, 58
A. Diamantidis, N. Papadopoulos, Chris Nakas, Shuang Wu, H. Müller, J. Carey (2009)
Life history evolution in a globally invading tephritid: patterns of survival and reproduction in medflies from six world regionsBiological Journal of The Linnean Society, 97
F. Messina, Margaret Karren (2003)
Adaptation to a novel host modifies host discrimination by the seed beetle Callosobruchus maculatusAnimal Behaviour, 65
R. Guedes, Robert Smith, N. Guedes (2003)
Host suitability, respiration rate and the outcome of larval competition in strains of the cowpea weevil, Callosobruchus maculatusPhysiological Entomology, 28
(1992)
Investigations of the damage of broad bean weevil Bruchus rufimanus Bohem (Coleoptera: Bruchidae) on broad bean
R. Mitchell (1990)
Behavioral Ecology of Callosobruchus Maculatus
H. Mano, Y. Toquenaga (2008)
Wall-making behavior as a proximate mechanism to generate variation in larval competition in Callosobruchus maculatus (Coleoptera: Bruchidae)Evolutionary Ecology, 22
C. Tomaz, D. Kestring, M. Rossi (2007)
Effects of the seed predator Acanthoscelides schrankiae on viability of its host plant Mimosa bimucronata.Biological research, 40 3
Anzeiger Fur Schadlingskunde Pflanzenschutz Umweltschutz
M. Harris, J. Stuart, M. Mohan, S. Nair, R. Lamb, O. Rohfritsch (2003)
Grasses and gall midges: plant defense and insect adaptation.Annual review of entomology, 48
P. Credland, K. Dick, A. Wright (1986)
Relationships between larval density, adult size and egg production in the cowpea seed beetle, Callosobruchus maculatusEcological Entomology, 11
Accepted 23
M. Cipollini, E. Stiles (1991)
Seed predation by the bean weevil Acanthoscelides obtectus on Phaseolus species: consequences for seed size, early growth and reproductionOikos, 60
K. Takakura (2002)
The specialist seed predator Bruchidius dorsalis (Coleoptera: Bruchidae) plays a crucial role in the seed germination of its host plant, Gleditsia japonica (Leguminosae)Functional Ecology, 16
B. Southgate (1979)
Biology of the BruchidaeAnnual Review of Entomology, 24
P. Mucunguzi (1995)
Effects of bruchid beetles on germination and establishment of Acacia speciesAfrican Journal of Ecology, 33
R. Stillwell, W. Wallin, Lisa Hitchcock, Charles Fox (2007)
Phenotypic plasticity in a complex world: interactive effects of food and temperature on fitness components of a seed beetleOecologia, 153
Sara Via (1990)
Ecological genetics and host adaptation in herbivorous insects: the experimental study of evolution in natural and agricultural systems.Annual review of entomology, 35
Epperlein Epperlein (1992)
Investigations of the damage of broad bean weevil Bruchus rufimanus Bohem (Coleoptera: Bruchidae) on broad bean seed ( Vicia faba L)Anzeiger Fur Schadlingskunde Pflanzenschutz Umweltschutz, 65
F. Messina (1993)
Heritability and ‘evolvability’ of fitness components in Callosobruchus maculatusHeredity, 71
A. Baier, B. Webster (1992)
Control of Acanthoscelides obtectus Say (Coleoptera: Bruchidae) in Phaseolus vulgaris L. Seed stored on small farms—II. Germination and cooking timeJournal of Stored Products Research, 28
P. Credland (1990)
Biotype Variation and Host Change in Bruchids: Causes and Effects in the Evolution of Bruchid Pests
Richard Smith, R. Baker, C. Malumphy, S. Hockland, R. Hammon, J. Ostojá-Starzewski, D. Collins (2007)
Recent non‐native invertebrate plant pest establishments in Great Britain: origins, pathways, and trendsAgricultural and Forest Entomology, 9
A. Hegazy, N. Eesa (1991)
On the Ecology, Insect Seed‐Predation, and Conservation of a Rare and Endemic Plant Species: Ebenus amnitagei (Leguminosae)Conservation Biology, 5
R. Smith (1990)
Adaptations of Callosobruchus Species to Competition
Y. Toquenaga (1993)
Contest and scramble competitions inCallosobruchus maculatus (Coleoptera: Bruchidae) II. Larval competition and interference mechanismsResearches on Population Ecology, 35
(1990)
Behavioural ecology of Callosobruchus maculatus . Bruchids and Legumes : Economics , Ecology , and Coevolution ( ed . by
R. Mitchell (1991)
The traits of a biotype of Callosobruchus maculatus (F.) (Coleoptera: Bruchidae) from South IndiaJournal of Stored Products Research, 27
F. Messina (1991)
Competitive Interactions Between Larvae from Divergent Strains of the Cowpea Weevil (Coleoptera: Bruchidae)Environmental Entomology, 20
A. Malacrida, L. Gomulski, M. Bonizzoni, S. Bertin, G. Gasperi, C. Guglielmino (2007)
Globalization and fruitfly invasion and expansion: the medfly paradigmGenetica, 131
H. Mano, Y. Toquenaga (2008)
Wall-Making Behavior in Callosobruchus maculatus (Coleoptera: Bruchidae), 101
C. Phillips, D. Baird, I. Iline, M. McNeill, J. Proffitt, S. Goldson, J. Kean (2007)
East meets west: adaptive evolution of an insect introduced for biological control.Journal of Applied Ecology, 45
F. Messina (2004)
Life-history variation in a seed beetle: adult egg-laying vs. larval competitive abilityOecologia, 85
M. Tuda, Y. Iwasa (2004)
Evolution of contest competition and its effect on host–parasitoid dynamicsEvolutionary Ecology, 12
M. Kenis, M. Auger-Rozenberg, A. Roques, L. Timms, C. Péré, M. Cock, J. Settele, S. Augustin, C. Lopez‐Vaamonde (2008)
Ecological effects of invasive alien insectsBiological Invasions, 11
M. Tuda (2007)
Evolutionary character changes and population responses in an insect host-parasitoid experimental systemResearches on Population Ecology, 40
By Smartt, J. Smartt (1985)
Evolution of Grain Legumes. III. Pulses in the Genus VignaExperimental Agriculture, 21
P. Credland, J. Dendy (1992)
Comparison of seed consumption and the practical use of insect weight in determining effects of host seed on the Mexican bean weevil, Zabrotes subfasciatus (Boh.)Journal of Stored Products Research, 28
M. Miller (1994)
Large African herbivores, bruchid beetles and their interactions with Acacia seedsOecologia, 97
R. Ahern, D. Hawthorne, M. Raupp (2009)
Founder effects and phenotypic variation in Adelges cooleyi, an insect pest introduced to the eastern United StatesBiological Invasions, 11
U. Savalli, M. Czesak, C. Fox (2000)
Paternal Investment in the Seed Beetle Callosobruchus maculatus (Coleoptera: Bruchidae): Variation Among Populations, 93
(1994)
Contest and scramble competitions in an artificial world: genetic analysis with genetic algorithms
M. Takano, Y. Toquenaga, K. Fujii (2001)
Polymorphism of competition type and its genetics in Callosobruchus maculatus (Coleoptera: Bruchidae)Population Ecology, 43
Ki-Seung Kim, C. Hill, G. Hartman, M. Mian, B. Diers (2008)
Discovery of Soybean Aphid BiotypesCrop Science, 48
R. Shade, L. Murdock, L. Kitch (1999)
Interactions Between Cowpea Weevil (Coleoptera: Bruchidae) Populations and Vigna (Leguminosae) SpeciesJournal of Economic Entomology, 92
K. Epperlein (1992)
Untersuchungen zur Schadwirkung des BohnensamenkäfersBruchus rufimanus Bohem. (Col., Bruchidae) an Ackerbohnensaatgut (Vicia faba L.)Anzeiger für Schädlingskunde, Pflanzenschutz, Umweltschutz, 65
Clement Thanthianga, R. Mitchell (1987)
Vibrations mediate prudent resource exploitation by competing larvae of the bruchid bean weevil Callosobruchus maculatusEntomologia Experimentalis et Applicata, 44
Y. Toquenaga, K. Fujii (1991)
Contest and scramble competitions inCallosobruchus maculatus (Coleoptera: Bruchidae)Researches on Population Ecology, 33
A. Mack (1998)
An Advantage of Large Seed Size: Tolerating Rather than Succumbing to Seed Predators 1Biotropica, 30
F. Messina, R. Mitchell (1989)
Intraspecific variation in the egg-spacing behavior of the seed beetleCallosobruchus maculatusJournal of Insect Behavior, 2
M. Tuda, J. Rönn, S. Buranapanichpan, N. Wasano, G. Arnqvist (2006)
Evolutionary diversification of the bean beetle genus Callosobruchus (Coleoptera: Bruchidae): traits associated with stored‐product pest statusMolecular Ecology, 15
Charles Fox, R. Stillwell, A. Amarillo-S, M. Czesak, F. Messina (2004)
Genetic architecture of population differences in oviposition behaviour of the seed beetle Callosobruchus maculatusJournal of Evolutionary Biology, 17
D. Garant, S. Forde, A. Hendry (2007)
The multifarious effects of dispersal and gene flow on contemporary adaptationFunctional Ecology, 21
S. Wulff (2007)
SAS for Mixed ModelsThe American Statistician, 61
H. Delatte, P. Duyck, Aurélie Triboire, P. David, N. Becker, O. Bonato, B. Reynaud (2009)
Differential invasion success among biotypes: case of Bemisia tabaciBiological Invasions, 11
P. Credland, K. Dick (1987)
Food consumption by larvae of three strains of Callosobruchus maculatus (Coleoptera: Bruchidae)Journal of Stored Products Research, 23
B. Tran, P. Credland (1995)
Consequences of inbreeding for the cowpea seed beetle, Callosobruchus maculatus (F.)(Coleoptera: Bruchidae)Biological Journal of The Linnean Society, 56
M. Taper (1990)
Experimental Character Displacement in the Adzuki Bean Weevil, Callosobruchus Chinensis
1 Populations of the seed beetle Callosobruchus maculatus (F.) exhibit considerable differences in body size and larval behaviour. We examined whether such variation modifies the relationship between beetle infestation and host plant performance. 2 Larvae from African and Asian biotypes were reared in seeds of four hosts that represented an almost four‐fold variation in seed mass. We estimated mass lost to larval consumption, and compared germination rates and seedling growth between infested and control seeds. 3 In seeds bearing a single larva, the larger‐bodied, contest‐competing larvae of the Asian biotype caused a 38–47% greater reduction in seed mass compared with the smaller‐bodied, scramble‐competing larvae of the African biotype. The amount of seed mass lost per larva remained similar in seeds with one or two scramble‐competing larvae but decreased significantly in seeds bearing two contest‐competing Asian larvae. 4 Differences in larval consumption and behaviour produced striking differences in the frequency of germination. Germination of singly‐infested mung bean (i.e. the smallest host) was 71% for African‐infested seeds versus 11% for Asian‐infested seeds. In cowpea (i.e. the largest host), 76% of Asian‐infested seeds germinated, whereas the germination rate of African‐infested cowpeas (92%) was similar to that of uninfested seeds. 5 Effects of beetle origin persisted after germination. Seedlings derived from Asian‐infested seeds had greater cotyledon damage 7 days after germination, and displayed lower height and less biomass 15 days after germination. Cotyledon damage was a good predictor of seedling performance (i.e. better than seed mass consumed) 15 days after germination. 6 Previous studies have suggested that population differences in larval size and burrowing behaviour (‘centripetal tendency’) reflect adaptation to different‐sized seeds. The present study demonstrates that these differences in turn influence the impact of larval feeding on host viability. Strong biotypic variation makes it difficult to generalize about pest impacts at the level of pest species.
Agricultural and Forest Entomology – Wiley
Published: Nov 1, 2010
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.