|
|
Registro Completo |
Biblioteca(s): |
Embrapa Pantanal. |
Data corrente: |
19/05/1998 |
Data da última atualização: |
14/09/2020 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Autoria: |
NOONAN, M. J.; FLEMING, C. H.; TUCKER, M. A.; KAYS, R.; HARRISON, AUTUMN-LYNN; CROFOOT, M. C.; ABRAHMS, B.; ALBERTS, S.; ALI, A. H.; ALTMANN, J.; ANTUNES, P. C.; ATTIAS, N.; BELANT, J. L.; BEYER JUNIOR, D. E.; BIDNER, L. R.; BLAUM, N.; BOONE, R. B.; CAILLAUD, D.; PAULA, R. C. de; DE LA TORRE, J. A.; DEKKER, J.; DEPERNO, C. S.; FARHADINIA, M.; FENNESSY, J.; FICHTEL, C.; FISCHER, C.; FORD, A.; GOHEEN, J. R.; HAVMØLLER, R. W.; HIRSCH, B. T.; HURTADO, C.; ISBELL, L. A.; JANSSEN, R.; JELTSCH, F.; KACZENSKY, P.; KANEKO, Y.; KAPPELER, P.; KATNA, A.; KAUFFMAN, M.; KOCH, F.; KULKARNI, A; LAPOINT, S.; LEIMGRUBER, P.; MACDONALD, D. W.; MARKHAM, A. C.; MCMAHON, L.; MERTES, K.; MOORMAN, C. E.; MORATO, R. G.; MOßBRUCKER, A. M.; MOURAO, G.; O'CONNOR, D.; OLIVEIRA-SANTOS, L. G. R.; PASTORINI, J.; PATTERSON, B. D.; RACHLOW, J.; RANGLACK, D. H.; REID, N.; SCANTLEBURY, D. M.; SCOTT, D. M.; SELVA, N.; SERGIEL, A.; SONGER, M.; SONGSASEN, N.; STABACH, J. A.; STACY-DAWES, J.; SWINGEN, M. B.; THOMPSON, J. J.; ULLMANN, W.; VANAK, A. T.; THAKER, M.; WILSON, J. W.; YAMAZAKI, K.; YARNELL, R. W.; ZIEBA, F.; ZWIJACZ-KOZICA, T.; FAGAN, W. F.; MUELLER, T.; CALABRESE, J. M. |
Afiliação: |
MICHAEL J. NOONAN, Smithsonian Conservation Biology Institute, National Zoological Park; CHRISTEN H. FLEMING, University of Maryland; MARLEE A. TUCKER, Senckenberg Biodiversity and Climate Research Centre; ROLAND KAYS, Museum of Natural Sciences, Biodiversity Lab, Raleigh; AUTUMN-LYNN HARRISON, Smithsonian Conservation Biology Institute, Washington, D.C; MARGARET C. CROFOOT, University of California, Davis; BRIANA ABRAHMS, NOAA Southwest Fisheries Science Center; SUSAN C. ALBERTS, Duke University, Durham; ABDULLAHI H. ALI, Hirola Conservation Programme, Garissa; JEANNE ALTMANN, Princeton University; PAMELA CASTRO ANTUNES, Federal University of Mato Grosso do Sul, Campo Grande, MS; NINA ATTIAS, Universidade Federal do Mato Grosso do Sul, Campo Grande; JERROLD L. BELANT, College of Environmental Science and Forestry, Syracuse; DEAN E. BEYER JUNIOR, Michigan Department of Natural Resources; LAURA R. BIDNER, Mpala Research Centre, Nanyuki; NIELS BLAUM, University of Potsdam, Plant Ecology and Nature Conservation; RANDALL B. BOONE, Colorado State University, Fort Collins; DAMIEN CAILLAUD, Colorado State University; ROGERIO CUNHA DE PAULA, Chico Mendes Institute for the Conservation of Biodiversity; J. ANTONIO DE LA TORRE, Universidad Nacional Autónoma de Mexico and CONACyT; JASJA DEKKER, Jasja Dekker Dierecologie; CHRISTOPHER S. DEPERNO, University of Oxford, Tubney House; MOHAMMAD FARHADINIA, Future4Leopards Foundation, Tehran; JULIAN FENNESSY, Giraffe Conservation Foundation, PO; CLAUDIA FICHTEL, German Primate Center, Behavioral Ecology & Sociobiology Unit; CHRISTINA FISCHER, Restoration Ecology, Department of Ecology and Ecosystem Management; ADAM FORD, The University of British Columbia; JACOB R. GOHEEN, University of Wyoming, Laramie; RASMUS W. HAVMØLLER, University of California, Davis; BEN T. HIRSCH, James Cook University, Townsville; CINDY HURTADO, Universidad Nacional Mayor de San Marcos, Lima; LYNNE A. ISBELL, Mpala Research Centre, Nanyuki; RENÉ JANSSEN, 6Bionet Natuuronderzoek, Valderstraat; FLORIAN JELTSCH, University of Potsdam, Plant Ecology and Nature Conservation; PETRA KACZENSKY, Norwegian Institute for Nature Research - NINA; YAYOI KANEKO, Tokyo University of Agriculture and Technology, Tokyo; PETER KAPPELER, Ashoka Trust for Research in Ecology and the Environment (ATREE); ANJAN KATNA, Ashoka Trust for Research in Ecology and the Environment (ATREE), Bangalore; MATTHEW KAUFFMAN, University of Wyoming, Laramie, WY; FLAVIA KOCH, German Primate Center, Behavioral Ecology & Sociobiology Unit; ABHIJEET KULKARNI, Ashoka Trust for Research in Ecology and the Environment (ATREE); SCOTT LAPOINT, Manipal Academy of Higher Education, Manipal; PETER LEIMGRUBER, University of Wyoming; DAVID W. MACDONALD, Max Planck Institute for Ornithology; A. CATHERINE MARKHAM, Black Rock Forest; LAURA MCMAHON, Office of Applied Science, Department of Natural Resources; KATHERINE MERTES, Institute for the Conservation of Neotropical Carnivores; CHRISTOPHER E. MOORMAN, Frankfurt Zoological Society, Bernhard-Grzimek-Allee; RONALDO G. MORATO, National Research Center for Carnivores Conservation; ALEXANDER M. MOßBRUCKER, Frankfurt Zoological Society, Bernhard-Grzimek-Allee; GUILHERME DE MIRANDA MOURAO, CPAP; DAVID O'CONNOR, San Diego Zoo Institute of Conservation Research; LUIZ GUSTAVO R. OLIVEIRA-SANTOS, National Geographic Partners; JENNIFER PASTORINI, Federal University of Mato Grosso do Sul; BRUCE D. PATTERSON, Centre for Conservation and Research, Sri Lanka; JANET RACHLOW, Anthropologisches Institut, Switzerland; DUSTIN H. RANGLACK, University of Nebraska at Kearney, Kearney; NEIL REID, Queen's University Belfast, Belfast; DAVID M. SCANTLEBURY, Queen's University Belfast; DAWN M. SCOTT, Keele University, Keele; NURIA SELVA, Institute of Nature Conservation, Polish Academy of Sciences; AGNIESZKA SERGIEL, Treaty Authority, Duluth; MELISSA SONGER, Asociación Guyra Paraguay-CONACYT; NUCHARIN SONGSASEN, Instituto Saite, Paraguay; JARED A. STABACH, Wellcome Trust/DBT India Alliance, Hyderabad, India; JENNA STACY-DAWES, University of KwaZulu-Natal, Westville, Durban; MORGAN B. SWINGEN, Indian Institute of Science, Bangalore, India; JEFFREY J. THOMPSON, University of Pretoria; WIEBKE ULLMANN, Ibaraki Nature Museum, Osaki; ABI TAMIM VANAK, University of Agriculture, Tokyo; MARIA THAKER, Nottingham Trent University, Brackenhurst Campus; JOHN W. WILSON, University of Pretoria, Pretoria; KOJI YAMAZAKI, Ibaraki Nature Museum, Osaki; RICHARD W. YARNELL, Nottingham Trent University, Brackenhurst Campus; FILIP ZIEBA, Tatra National Park, Zakopane; TOMASZ ZWIJACZ-KOZICA, Tatra National Park, Zakopane; WILLIAM F. FAGAN, University of Maryland, College Park; THOMAS MUELLER, Senckenberg Gesellschaft für Naturforschung, Frankfurt; JUSTIN M. CALABRESE, National Zoological Park, Front Royal. |
Título: |
Effects of body size on estimation of mammalian area requirements. |
Ano de publicação: |
2020 |
Fonte/Imprenta: |
Conservation Biology, v.34, n. 4, p. 1017-1028, 2020. |
DOI: |
10.1111/cobi.13495 |
Idioma: |
Inglês |
Conteúdo: |
Accurately quantifying species' area requirements is a prerequisite for effective area-based conservation. This typically involves collecting tracking data on species of interest and then conducting home range analyses. Problematically, autocorrelation in tracking data can result in space needs being severely underestimated. Based on the previous work, we hypothesized the magnitude of underestimation varies with body mass, a relationship that could have serious conservation implications. To evaluate this hypothesis for terrestrial mammals, we estimated home-range areas with global positioning system (GPS) locations from 757 individuals across 61 globally distributed mammalian species with body masses ranging from 0.4 to 4000 kg. We then applied blockcross validation to quantify bias in empirical home range estimates. Area requirements of mammals < 10 kg were underestimated by a mean approximately 15%, and species weighing approximately 100 kg were underestimatedby approximately 50% on average. Thus, we found area estimation was subject to autocorrelation induced bias that was worse for large species. Combined with the fact that extinction risk increases as body mass increases, theallometric scaling of bias we observed suggests the most threatened species are also likely to be those with theleast accurate home range estimates. As a correction, we tested whether data thinning or autocorrelation informedhome range estimation minimized the scaling effect of autocorrelation on area estimates. Data thinning requiredan approximately 93% data loss to achieve statistical independence with 95% confidence and was, therefore, nota viable solution. In contrast, autocorrelation informed home range estimation resulted in consistently accurateestimates irrespective of mass. When relating body mass to home range size, we detected that correcting forautocorrelation resulted in a scaling exponent significantly >1, meaning the scaling of the relationship changedsubstantially at the upper end of the mass spectrum. MenosAccurately quantifying species' area requirements is a prerequisite for effective area-based conservation. This typically involves collecting tracking data on species of interest and then conducting home range analyses. Problematically, autocorrelation in tracking data can result in space needs being severely underestimated. Based on the previous work, we hypothesized the magnitude of underestimation varies with body mass, a relationship that could have serious conservation implications. To evaluate this hypothesis for terrestrial mammals, we estimated home-range areas with global positioning system (GPS) locations from 757 individuals across 61 globally distributed mammalian species with body masses ranging from 0.4 to 4000 kg. We then applied blockcross validation to quantify bias in empirical home range estimates. Area requirements of mammals < 10 kg were underestimated by a mean approximately 15%, and species weighing approximately 100 kg were underestimatedby approximately 50% on average. Thus, we found area estimation was subject to autocorrelation induced bias that was worse for large species. Combined with the fact that extinction risk increases as body mass increases, theallometric scaling of bias we observed suggests the most threatened species are also likely to be those with theleast accurate home range estimates. As a correction, we tested whether data thinning or autocorrelation informedhome range estimation minimized the scaling effect of autocorrelation on ar... Mostrar Tudo |
Thesagro: |
Comportamento Animal; Conservação; Mamífero. |
Thesaurus Nal: |
Animal behavior; Conservation status; Home range; Mammals. |
Categoria do assunto: |
P Recursos Naturais, Ciências Ambientais e da Terra |
URL: |
https://ainfo.cnptia.embrapa.br/digital/bitstream/item/215878/1/BodySizeEstimation2020.pdf
|
Marc: |
LEADER 04945naa a2201153 a 4500 001 1792404 005 2020-09-14 008 2020 bl uuuu u00u1 u #d 024 7 $a10.1111/cobi.13495$2DOI 100 1 $aNOONAN, M. J. 245 $aEffects of body size on estimation of mammalian area requirements. 260 $c2020 520 $aAccurately quantifying species' area requirements is a prerequisite for effective area-based conservation. This typically involves collecting tracking data on species of interest and then conducting home range analyses. Problematically, autocorrelation in tracking data can result in space needs being severely underestimated. Based on the previous work, we hypothesized the magnitude of underestimation varies with body mass, a relationship that could have serious conservation implications. To evaluate this hypothesis for terrestrial mammals, we estimated home-range areas with global positioning system (GPS) locations from 757 individuals across 61 globally distributed mammalian species with body masses ranging from 0.4 to 4000 kg. We then applied blockcross validation to quantify bias in empirical home range estimates. Area requirements of mammals < 10 kg were underestimated by a mean approximately 15%, and species weighing approximately 100 kg were underestimatedby approximately 50% on average. Thus, we found area estimation was subject to autocorrelation induced bias that was worse for large species. Combined with the fact that extinction risk increases as body mass increases, theallometric scaling of bias we observed suggests the most threatened species are also likely to be those with theleast accurate home range estimates. As a correction, we tested whether data thinning or autocorrelation informedhome range estimation minimized the scaling effect of autocorrelation on area estimates. Data thinning requiredan approximately 93% data loss to achieve statistical independence with 95% confidence and was, therefore, nota viable solution. In contrast, autocorrelation informed home range estimation resulted in consistently accurateestimates irrespective of mass. When relating body mass to home range size, we detected that correcting forautocorrelation resulted in a scaling exponent significantly >1, meaning the scaling of the relationship changedsubstantially at the upper end of the mass spectrum. 650 $aAnimal behavior 650 $aConservation status 650 $aHome range 650 $aMammals 650 $aComportamento Animal 650 $aConservação 650 $aMamífero 700 1 $aFLEMING, C. H. 700 1 $aTUCKER, M. A. 700 1 $aKAYS, R. 700 1 $aHARRISON, AUTUMN-LYNN 700 1 $aCROFOOT, M. C. 700 1 $aABRAHMS, B. 700 1 $aALBERTS, S. 700 1 $aALI, A. H. 700 1 $aALTMANN, J. 700 1 $aANTUNES, P. C. 700 1 $aATTIAS, N. 700 1 $aBELANT, J. L. 700 1 $aBEYER JUNIOR, D. E. 700 1 $aBIDNER, L. R. 700 1 $aBLAUM, N. 700 1 $aBOONE, R. B. 700 1 $aCAILLAUD, D. 700 1 $aPAULA, R. C. de 700 1 $aDE LA TORRE, J. A. 700 1 $aDEKKER, J. 700 1 $aDEPERNO, C. S. 700 1 $aFARHADINIA, M. 700 1 $aFENNESSY, J. 700 1 $aFICHTEL, C. 700 1 $aFISCHER, C. 700 1 $aFORD, A. 700 1 $aGOHEEN, J. R. 700 1 $aHAVMØLLER, R. W. 700 1 $aHIRSCH, B. T. 700 1 $aHURTADO, C. 700 1 $aISBELL, L. A. 700 1 $aJANSSEN, R. 700 1 $aJELTSCH, F. 700 1 $aKACZENSKY, P. 700 1 $aKANEKO, Y. 700 1 $aKAPPELER, P. 700 1 $aKATNA, A. 700 1 $aKAUFFMAN, M. 700 1 $aKOCH, F. 700 1 $aKULKARNI, A 700 1 $aLAPOINT, S. 700 1 $aLEIMGRUBER, P. 700 1 $aMACDONALD, D. W. 700 1 $aMARKHAM, A. C. 700 1 $aMCMAHON, L. 700 1 $aMERTES, K. 700 1 $aMOORMAN, C. E. 700 1 $aMORATO, R. G. 700 1 $aMOßBRUCKER, A. M. 700 1 $aMOURAO, G. 700 1 $aO'CONNOR, D. 700 1 $aOLIVEIRA-SANTOS, L. G. R. 700 1 $aPASTORINI, J. 700 1 $aPATTERSON, B. D. 700 1 $aRACHLOW, J. 700 1 $aRANGLACK, D. H. 700 1 $aREID, N. 700 1 $aSCANTLEBURY, D. M. 700 1 $aSCOTT, D. M. 700 1 $aSELVA, N. 700 1 $aSERGIEL, A. 700 1 $aSONGER, M. 700 1 $aSONGSASEN, N. 700 1 $aSTABACH, J. A. 700 1 $aSTACY-DAWES, J. 700 1 $aSWINGEN, M. B. 700 1 $aTHOMPSON, J. J. 700 1 $aULLMANN, W. 700 1 $aVANAK, A. T. 700 1 $aTHAKER, M. 700 1 $aWILSON, J. W. 700 1 $aYAMAZAKI, K. 700 1 $aYARNELL, R. W. 700 1 $aZIEBA, F. 700 1 $aZWIJACZ-KOZICA, T. 700 1 $aFAGAN, W. F. 700 1 $aMUELLER, T. 700 1 $aCALABRESE, J. M. 773 $tConservation Biology$gv.34, n. 4, p. 1017-1028, 2020.
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Embrapa Pantanal (CPAP) |
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Biblioteca(s): |
Embrapa Recursos Genéticos e Biotecnologia. |
Data corrente: |
26/02/2013 |
Data da última atualização: |
07/03/2023 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Circulação/Nível: |
A - 1 |
Autoria: |
MAGALHÃES, D. M.; BORGES, M.; LAUMANN, R. A.; SUJII, E. R.; MAYON, P.; CAULFIELD, J. C; MIDEGA, C. A. O.; KHAN, Z. R.; PICKETT, P. J. A.; BIRKETT, M. A.; MORAES, M. C. B. |
Afiliação: |
D. M. MAGALHÃES; MIGUEL BORGES, CENARGEN; RAUL ALBERTO LAUMANN, CENARGEN; EDISON RYOITI SUJII, CENARGEN; P. MAYON, Biological Chemistry and Crop Protection Department; J. C. CAULFIELD, Biological Chemistry and Crop Protection Department; C. A. O. MIDEGA, International Centre of Insect Physiology and Ecology (icipe); Z. R. KHAN, International Centre of Insect Physiology and Ecology (icipe); P. J. A. PICKETT, Biological Chemistry and Crop Protection Department; M. A. BIRKETT, Biological Chemistry and Crop Protection Department; MARIA CAROLINA BLASSIOLI MORAES, CENARGEN. |
Título: |
Semiochemicals from herbivory induced cotton plants enhance the foraging behavior of the cotton boll weevil, Anthonomus grandis. |
Ano de publicação: |
2012 |
Fonte/Imprenta: |
Journal of Chemical Ecology, v. 38, p. 1528-1538, 2012. |
Idioma: |
Inglês |
Conteúdo: |
The boll weevil, Anthonomus grandis, has been monitored through deployment of traps baited with aggregation pheromone components. However, field studies have shown that the number of insects caught in these traps is significantly reduced during cotton squaring, suggesting that volatiles produced by plants at this phenological stage may be involved in attraction. Here, we evaluated the chemical profile of volatile organic compounds (VOCs) emitted by undamaged or damaged cotton plants at different phenological stages, under different infestation conditions, and determined the attractiveness of these VOCs to adults of A. grandis. In addition, we investigated whether or not VOCs released by cotton plants enhanced the attractiveness of the aggregation pheromone emitted by male boll weevils. Behavioral responses of A. grandis to VOCs from conspecific-damaged, heterospecificdamaged (Spodoptera frugiperda and Euschistus heros) and undamaged cotton plants, at different phenological stages, were assessed in Y-tube olfactometers. The results showed that volatiles emitted from reproductive cotton plants damaged by conspecifics were attractive to adults boll weevils, whereas volatiles induced by heterospecific herbivores were not as attractive. Additionally, addition of boll weevil-induced volatiles fromreproductive cotton plants to aggregation pheromone gave increased attraction, relative to the pheromone alone. The VOC profiles of undamaged and mechanically damaged cotton plants, in both phenological stages, were not different. Chemical analysis showed that cotton plants produced qualitatively similar volatile profiles regardless of damage type, but the quantities produced differed according to the plant?s phenological stage and the herbivore species. Notably, vegetative cotton plants released higher amounts of VOCs compared to reproductive plants. At both stages, the highest rate of VOC release was observed in A. grandis-damaged plants. Results show that A. grandis uses conspecific herbivore-induced volatiles in host location, and that homoterpene compounds, such as (E)-4,8-dimethylnona-1,3,7?triene and (E,E)-4,8,12-trime-thyltrideca-1,3,7,11-tetraene and the monoterpene (E)-ocimene, may be involved in preference for host plants at the reproductive stage. MenosThe boll weevil, Anthonomus grandis, has been monitored through deployment of traps baited with aggregation pheromone components. However, field studies have shown that the number of insects caught in these traps is significantly reduced during cotton squaring, suggesting that volatiles produced by plants at this phenological stage may be involved in attraction. Here, we evaluated the chemical profile of volatile organic compounds (VOCs) emitted by undamaged or damaged cotton plants at different phenological stages, under different infestation conditions, and determined the attractiveness of these VOCs to adults of A. grandis. In addition, we investigated whether or not VOCs released by cotton plants enhanced the attractiveness of the aggregation pheromone emitted by male boll weevils. Behavioral responses of A. grandis to VOCs from conspecific-damaged, heterospecificdamaged (Spodoptera frugiperda and Euschistus heros) and undamaged cotton plants, at different phenological stages, were assessed in Y-tube olfactometers. The results showed that volatiles emitted from reproductive cotton plants damaged by conspecifics were attractive to adults boll weevils, whereas volatiles induced by heterospecific herbivores were not as attractive. Additionally, addition of boll weevil-induced volatiles fromreproductive cotton plants to aggregation pheromone gave increased attraction, relative to the pheromone alone. The VOC profiles of undamaged and mechanically damaged cotton plants, in bo... Mostrar Tudo |
Palavras-Chave: |
Host plant; Phenological stages. |
Thesagro: |
Anthonomus Grandis; Planta hospedeira. |
Thesaurus NAL: |
Curculionidae; terpenoids. |
Categoria do assunto: |
-- |
URL: |
https://ainfo.cnptia.embrapa.br/digital/bitstream/item/179309/1/Magalhaes2012-Article-SemiochemicalsFromHerbivoryInd.pdf
|
Marc: |
LEADER 03212naa a2200313 a 4500 001 1951175 005 2023-03-07 008 2012 bl uuuu u00u1 u #d 100 1 $aMAGALHÃES, D. M. 245 $aSemiochemicals from herbivory induced cotton plants enhance the foraging behavior of the cotton boll weevil, Anthonomus grandis.$h[electronic resource] 260 $c2012 520 $aThe boll weevil, Anthonomus grandis, has been monitored through deployment of traps baited with aggregation pheromone components. However, field studies have shown that the number of insects caught in these traps is significantly reduced during cotton squaring, suggesting that volatiles produced by plants at this phenological stage may be involved in attraction. Here, we evaluated the chemical profile of volatile organic compounds (VOCs) emitted by undamaged or damaged cotton plants at different phenological stages, under different infestation conditions, and determined the attractiveness of these VOCs to adults of A. grandis. In addition, we investigated whether or not VOCs released by cotton plants enhanced the attractiveness of the aggregation pheromone emitted by male boll weevils. Behavioral responses of A. grandis to VOCs from conspecific-damaged, heterospecificdamaged (Spodoptera frugiperda and Euschistus heros) and undamaged cotton plants, at different phenological stages, were assessed in Y-tube olfactometers. The results showed that volatiles emitted from reproductive cotton plants damaged by conspecifics were attractive to adults boll weevils, whereas volatiles induced by heterospecific herbivores were not as attractive. Additionally, addition of boll weevil-induced volatiles fromreproductive cotton plants to aggregation pheromone gave increased attraction, relative to the pheromone alone. The VOC profiles of undamaged and mechanically damaged cotton plants, in both phenological stages, were not different. Chemical analysis showed that cotton plants produced qualitatively similar volatile profiles regardless of damage type, but the quantities produced differed according to the plant?s phenological stage and the herbivore species. Notably, vegetative cotton plants released higher amounts of VOCs compared to reproductive plants. At both stages, the highest rate of VOC release was observed in A. grandis-damaged plants. Results show that A. grandis uses conspecific herbivore-induced volatiles in host location, and that homoterpene compounds, such as (E)-4,8-dimethylnona-1,3,7?triene and (E,E)-4,8,12-trime-thyltrideca-1,3,7,11-tetraene and the monoterpene (E)-ocimene, may be involved in preference for host plants at the reproductive stage. 650 $aCurculionidae 650 $aterpenoids 650 $aAnthonomus Grandis 650 $aPlanta hospedeira 653 $aHost plant 653 $aPhenological stages 700 1 $aBORGES, M. 700 1 $aLAUMANN, R. A. 700 1 $aSUJII, E. R. 700 1 $aMAYON, P. 700 1 $aCAULFIELD, J. C 700 1 $aMIDEGA, C. A. O. 700 1 $aKHAN, Z. R. 700 1 $aPICKETT, P. J. A. 700 1 $aBIRKETT, M. A. 700 1 $aMORAES, M. C. B. 773 $tJournal of Chemical Ecology$gv. 38, p. 1528-1538, 2012.
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