about
Multiple functions of microsomal triglyceride transfer proteinTriacylglycerol-rich lipophorins are found in the dipteran infraorder Culicomorpha, not just in mosquitoesFrom fat fruit fly to human obesityDrosophila Lipophorin Receptors Recruit the Lipoprotein LTP to the Plasma Membrane to Mediate Lipid UptakeFatty acid synthase cooperates with glyoxalase 1 to protect against sugar toxicityFatty-acid preference changes during development in Drosophila melanogasterLipoproteins in Drosophila melanogaster--assembly, function, and influence on tissue lipid compositionSialome of a generalist lepidopteran herbivore: identification of transcripts and proteins from Helicoverpa armigera labial salivary glandsSeasonal Dynamics in the Chemistry and Structure of the Fat Bodies of Bumblebee QueensObp56h Modulates Mating Behavior in Drosophila melanogasterTesting the Effects of DL-Alpha-Tocopherol Supplementation on Oxidative Damage, Total Antioxidant Protection and the Sex-Specific Responses of Reproductive Effort and Lifespan to Dietary Manipulation in Australian Field Crickets (Teleogryllus commodIsolation, characterization, and cDNA sequence of a carotenoid binding protein from the silk gland of Bombyx mori larvae.Temperature-dependent lipid metabolism in the blow fly Lucilia sericata.Analysis of fat body transcriptome from the adult tsetse fly, Glossina morsitans morsitans.Apolipocrustacein, formerly vitellogenin, is the major egg yolk precursor protein in decapod crustaceans and is homologous to insect apolipophorin II/I and vertebrate apolipoprotein B.An RGS-containing sorting nexin controls Drosophila lifespan.Metabolite localization by atmospheric pressure high-resolution scanning microprobe matrix-assisted laser desorption/ionization mass spectrometry imaging in whole-body sections and individual organs of the rove beetle Paederus riparius.Roles of specific membrane lipid domains in EGF receptor activation and cell adhesion molecule stabilization in a developing olfactory system.Regulation of energy stores and feeding by neuronal and peripheral CREB activity in Drosophila.Dung beetles eat acorns to increase their ovarian development and thermal tolerance.Conserved family of glycerol kinase loci in Drosophila melanogasterThe major yolk protein vitellogenin interferes with the anti-plasmodium response in the malaria mosquito Anopheles gambiaeMobilization of lipid stores in Manduca sexta: cDNA cloning and developmental expression of fat body triglyceride lipase, TGLAlternative exon usage in the single CPT1 gene of Drosophila generates functional diversity in the kinetic properties of the enzyme: differential expression of alternatively spliced variants in Drosophila tissues.Radiation-induced metabolomic changes in sterile male Μοnochamus alternatus (Coleoptera: Cerambycidae).Gbb/BMP signaling is required to maintain energy homeostasis in Drosophila.Apolipophorin-III mediates antiplasmodial epithelial responses in Anopheles gambiae (G3) mosquitoes.Drosophila lipophorin receptors mediate the uptake of neutral lipids in oocytes and imaginal disc cells by an endocytosis-independent mechanismMetabolic profiling of somatic tissues from Monochamus alternatus (Coleoptera: Cerambycidae) reveals effects of irradiation on metabolism.Targeting gene expression to the female larval fat body of transgenic Aedes aegypti mosquitoes.Insect endosymbiont proliferation is limited by lipid availability.Glycerol hypersensitivity in a Drosophila model for glycerol kinase deficiency is affected by mutations in eye pigmentation genes.Role of high-fat diet in stress response of Drosophila.Prolonged postdiapause: influence on some indicators of carbohydrate and lipid metabolism of the red mason bee, Osmia rufa.Insect fat body: energy, metabolism, and regulationBiochemical crypsis in the avoidance of natural enemies by an insect herbivoreCharacterization of the oxysterol-binding protein gene family in the yellow fever mosquito, Aedes aegyptiResponse to cold acclimation in diapause pupae of Hyles euphorbiae (Lepidoptera: Sphingidae): candidate biomarker identification using proteomics.Chikungunya virus adaptation to Aedes albopictus mosquitoes does not correlate with acquisition of cholesterol dependence or decreased pH threshold for fusion reaction.Genetic dissection of sleep-metabolism interactions in the fruit fly.
P2860
Q21245057-6493BDE9-6BBD-4AFB-A948-F8385CEBE4CDQ24798653-1577DB3C-14D6-46FE-B9E4-852F1CD798D5Q26822877-FFDF22D6-E1F3-4D43-9753-9CB77991BA72Q27310760-F65788B3-354A-4A83-BD10-7AEE0DB0ABAEQ27311488-5955BD62-277C-40C3-B622-53929850FB53Q27314825-D2319ACA-D218-43A2-A700-6C477B6E035DQ27332377-FBD5D354-F99D-4A6E-ADF1-BC5582B7E038Q28477666-10994A66-78C2-42AA-BBFA-8D4B4B246BDAQ28550873-625162BA-3BA4-4512-A783-326AB8C69FA7Q28821763-A75D4ABF-C2EB-410A-A2C0-A672A855B4ACQ30393898-CA76C4A9-BDDE-431F-AF66-ABA7A6C7D303Q30735535-418429BA-437D-4D66-B0A4-BC52289CE039Q30907598-F1AF3177-D9CB-482D-9A0B-7509C06E84BCQ33253849-F4F222C4-2044-4F14-AD2A-2F27A72C0EB6Q33269947-CBDC00C0-C39B-4C8F-A9BE-F5B42646D768Q33334331-C1B93BDC-3FBE-411E-81FB-3BC4428D481AQ33463455-D9E5DF10-5C6C-4936-8075-98EF9C424190Q33507260-5F68619C-5408-41F9-B0F0-68A55C981151Q33521215-635E7188-E884-424D-8329-B79F5C35334FQ33559764-C2F56900-186B-4B27-B264-84922D7DE0B4Q33595210-33D6DDC5-92F3-441A-B293-ED395BA5C8E0Q33638401-EEF51624-F24C-4297-AF70-67EA0BF2E5EBQ33691501-4A25A0DC-42BA-4D06-AACA-84E6587EEFA7Q33706918-AF9FC57C-2CCE-4E6E-AE8E-FCD85E928C20Q33725237-79B24B33-72F0-4EAE-ADDD-310C4F1FB353Q33727928-4B3443C5-600F-4FBA-A878-21A07AA6B06BQ33745175-DA68108A-2357-4656-BF99-F6852DE0DBBEQ33828417-5E8A23D6-FD26-49A9-9D4E-240577FDC697Q33907892-4AF5B9C2-BCE8-4AF7-A066-8536E1E69492Q33911879-A5FDE44D-5D63-43BC-8D66-F56918D401CDQ34010215-50A7140F-85CD-4382-8A44-9E90D3395F55Q34199649-8CE234F8-3EAF-45E4-AAA4-366A5E9F883EQ34369569-8BA34B39-F4F3-4CC9-8600-A637252EA16EQ34384414-9AB1C814-74C1-4E55-B88A-CBDB02FDFCFCQ34786707-1B44769A-E964-472E-AE49-AF49DF13525CQ34832201-BE0CF690-E312-484E-B1F3-9F8A68A479C3Q35113303-E75EFED1-AF78-4D20-8EB9-551B6D4C4EB8Q35120677-94FD17BC-37D4-4F31-A2AE-1CF7A114D1F8Q35183277-6A831E43-74F4-4047-B968-B318C858FEA9Q35243737-46A828FE-2A81-4392-A190-1AA6C72470AB
P2860
description
2001 nî lūn-bûn
@nan
2001 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2001年の論文
@ja
2001年論文
@yue
2001年論文
@zh-hant
2001年論文
@zh-hk
2001年論文
@zh-mo
2001年論文
@zh-tw
2001年论文
@wuu
name
Fat metabolism in insects.
@ast
Fat metabolism in insects.
@en
Fat metabolism in insects.
@nl
type
label
Fat metabolism in insects.
@ast
Fat metabolism in insects.
@en
Fat metabolism in insects.
@nl
prefLabel
Fat metabolism in insects.
@ast
Fat metabolism in insects.
@en
Fat metabolism in insects.
@nl
P2093
P1476
Fat metabolism in insects.
@en
P2093
Canavoso LE
Pennington JE
P356
10.1146/ANNUREV.NUTR.21.1.23
P407
P577
2001-01-01T00:00:00Z