about
Synchrotron x-ray visualisation of ice formation in insects during lethal and non-lethal freezingCaterpillars benefit from thermal ecosystem engineering by wandering albatrosses on sub-Antarctic Marion IslandHemispheric asymmetries in biodiversity--a serious matter for ecologySuccess stories and emerging themes in conservation physiology.Coping with thermal challenges: physiological adaptations to environmental temperatures.Reestablishment of ion homeostasis during chill-coma recovery in the cricket Gryllus pennsylvanicus.Variation in thermal performance among insect populations.Cold truths: how winter drives responses of terrestrial organisms to climate change.Cold hardiness and deacclimation of overwintering Papilio zelicaon pupae.Insects in fluctuating thermal environments.Cold tolerance of the montane Sierra leaf beetle, Chrysomela aeneicollis.Deleterious effects of repeated cold exposure in a freeze-tolerant sub-Antarctic caterpillar.Paradoxical acclimation responses in the thermal performance of insect immunity.Worrying about weird wintersCan we predict the effects of multiple stressors on insects in a changing climate?The effects of acclimation on thermal tolerance, desiccation resistance and metabolic rate in Chirodica chalcoptera (Coleoptera: Chrysomelidae).Translocation experiments with butterflies reveal limits to enhancement of poleward populations under climate change.The sub-lethal effects of repeated freezing in the woolly bear caterpillar Pyrrharctia isabella.Thermal variability increases the impact of autumnal warming and drives metabolic depression in an overwintering butterflyCold tolerance of the eastern subterranean termite, Reticulitermes flavipes (Isoptera: Rhinotermitidae), in Ontario.Positive selection in glycolysis among Australasian stick insectsClimatic variability and the evolution of insect freeze tolerance.Parallel molecular routes to cold adaptation in eight genera of New Zealand stick insectsThe effects of carbon dioxide anesthesia and anoxia on rapid cold-hardening and chill coma recovery in Drosophila melanogasterShort-term hardening effects on survival of acute and chronic cold exposure by Drosophila melanogaster larvae.Slow and stepped re-warming after acute low temperature exposure do not improve survival of Drosophila melanogaster larvae.Cold acclimation wholly reorganizes the Drosophila melanogaster transcriptome and metabolomeIntracellular ice formation in insects: unresolved after 50 years?Mechanisms underlying insect chill-coma.An invitation to measure insect cold tolerance: Methods, approaches, and workflow.Linking energetics and overwintering in temperate insects.CRISPR-induced null alleles show that Frost protects Drosophila melanogaster reproduction after cold exposure.Insect Immunity Varies Idiosyncratically During Overwintering.The overwintering biology of the acorn weevil, Curculio glandium in southwestern Ontario.The impacts of repeated cold exposure on insects.Intra-individual variation allows an explicit test of the hygric hypothesis for discontinuous gas exchange in insects.Does cold activate the Drosophila melanogaster immune system?Elevational variation in adult body size and growth rate but not in metabolic rate in the tree weta Hemideina crassidens.Rapid desiccation hardening changes the cuticular hydrocarbon profile of Drosophila melanogaster.Thermal preference and performance in a sub-Antarctic caterpillar: A test of the coadaptation hypothesis and its alternatives.
P50
Q24288727-2B8F3C7C-7600-4EB6-A48E-3FCF2B3FC801Q24671077-EBA24010-0DEB-4237-8CA9-8731F66D4BA8Q24793762-AE211990-41C6-4BC1-96BA-554EF327357CQ28828770-082AE7E7-8944-4EF3-A66D-990E00D74083Q30431296-4FF4FA11-E8DA-44AD-BAF5-2780A52CDF4CQ30530457-CC6D082F-A054-46DC-B0CA-F783247E98F4Q30574752-F4B0EDF2-78DD-4EFD-80AC-9A3D09ED2462Q30797840-68A983EE-71AD-413C-8EB0-76AA79408FD1Q30843669-220728F0-2DC7-4F1A-8684-5A159F357F48Q30863808-405E8257-CAD7-4416-A2F0-0159C61D13B4Q30984361-95BC6797-97CF-4D7F-A3D4-AC249D8305C1Q30984426-6CE78F08-CCA3-4BDB-895B-AC9B4BDECD61Q31043114-1ACDBF00-4DF5-4B5F-AC6E-3FB8DC88314FQ31125911-A6A83EA5-F703-44CD-B5A0-37A3ECCD94A3Q31135688-EA5F1014-3BA6-4BB3-A925-6760BD3D17DAQ33217107-7666E779-053E-42AD-A8D9-52A487C3C527Q33473088-462AD3C6-3149-4948-AB9D-C03BF7667A43Q33841666-25E9FC5F-F5CE-4689-9A31-6049939913FAQ34222610-F66D5E94-AAD8-49D5-8263-5018A83AEFAFQ34887351-723A75FB-C4BF-4638-A901-D6972616B39DQ35002388-EF4CFE06-CFCE-4173-A919-78929CF2DB45Q35152906-2B89AA6C-8D95-4672-B6CC-FFBAA62F31A8Q35769007-FD7BEDA5-CB1C-4801-A357-2403583D48E6Q36102562-67DBC52C-AE36-4D55-BAA7-D4989B1D8186Q36657954-205B9FB6-252A-4600-AF5B-2653583655E4Q36859669-3B19814A-6023-4F1B-8406-357A38D8580DQ37054248-B78BCB82-9A86-49CB-8E3E-18455058C6D8Q37624966-16F41E60-FA2B-4DF8-B6F1-2B4CD011ADBFQ37802457-A3F98E97-4BD0-434B-B8AA-FA9EE7A4A391Q38641502-DBB15AE4-2DF9-405F-9BDC-9BB311AF384AQ38651912-C487ED38-4D46-4C2D-A531-2E6D8FA0C602Q38657989-A21F9A44-9706-455C-A6B9-CF736A4D42A5Q38895016-5A6FDA3A-A056-4D95-8203-93A197522749Q39128149-9A98B12B-DE4D-47A9-B015-CEE48C9FA3F3Q39624134-C96BC405-2FFC-4609-B2D9-BA32D0B3473DQ40381886-C41E8CB8-0ED3-461F-B5D6-A3923122B705Q40465932-8FF58925-A249-45FE-A5E8-EF4F1EEEA4F1Q41262827-6C36A77E-C8FB-4A1B-B4CF-28DD1B710831Q41742296-5611C1E2-76C7-46B3-90C0-D98F69D8D747Q41988451-9AA5A3AA-036E-48F5-8523-2C374DE30A35
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
ricercatore
@it
հետազոտող
@hy
name
Brent J Sinclair
@ast
Brent J Sinclair
@en
Brent J Sinclair
@es
Brent J Sinclair
@nl
Brent J Sinclair
@sl
type
label
Brent J Sinclair
@ast
Brent J Sinclair
@en
Brent J Sinclair
@es
Brent J Sinclair
@nl
Brent J Sinclair
@sl
altLabel
Brent J. Sinclair
@en
Sinclair BJ
@en
prefLabel
Brent J Sinclair
@ast
Brent J Sinclair
@en
Brent J Sinclair
@es
Brent J Sinclair
@nl
Brent J Sinclair
@sl
P106
P21
P214
66149066362465600778
P31
P496
0000-0002-8191-9910
P734
P735
P7859
viaf-66149066362465600778