Genetic characterization of glucose transporter function in Leishmania mexicana
about
Leishmania carbon metabolism in the macrophage phagolysosome- feast or famine?Induction of a stringent metabolic response in intracellular stages of Leishmania mexicana leads to increased dependence on mitochondrial metabolismComparative Life Cycle Transcriptomics Revises Leishmania mexicana Genome Annotation and Links a Chromosome Duplication with Parasitism of VertebratesA dynamic programming approach for the alignment of signal peaks in multiple gas chromatography-mass spectrometry experiments.Transgenic, fluorescent Leishmania mexicana allow direct analysis of the proteome of intracellular amastigotes.Leishmania UDP-sugar pyrophosphorylase: the missing link in galactose salvage?Identification of Leishmania proteins preferentially released in infected cells using change mediated antigen technology (CMAT).Evidence that intracellular stages of Leishmania major utilize amino sugars as a major carbon source.Life cycle studies of the hexose transporter of Plasmodium species and genetic validation of their essentialityPathos: a web facility that uses metabolic maps to display experimental changes in metabolites identified by mass spectrometry.On the evolution of hexose transporters in kinetoplastid Protozoans [corrected].Remodeling of protein and mRNA expression in Leishmania mexicana induced by deletion of glucose transporter genes.Intracellular pathogen Leishmania donovani activates hypoxia inducible factor-1 by dual mechanism for survival advantage within macrophage.The effect of tunicamycin on the glucose uptake, growth, and cellular adhesion in the protozoan parasite Crithidia fasciculata.Virulence of Leishmania major in macrophages and mice requires the gluconeogenic enzyme fructose-1,6-bisphosphataseA constitutive pan-hexose permease for the Plasmodium life cycle and transgenic models for screening of antimalarial sugar analogsLeishmania beta-1,2-mannan is assembled on a mannose-cyclic phosphate primer.Regulation and biological function of a flagellar glucose transporter in Leishmania mexicana: a potential glucose sensorNutrient transport and pathogenesis in selected parasitic protozoa.Plasmodial sugar transporters as anti-malarial drug targets and comparisons with other protozoa.Niche metabolism in parasitic protozoa.Isotopomer profiling of Leishmania mexicana promastigotes reveals important roles for succinate fermentation and aspartate uptake in tricarboxylic acid cycle (TCA) anaplerosis, glutamate synthesis, and growth.Functional characterization of nucleoside transporter gene replacements in Leishmania donovaniA unique, highly conserved secretory invertase is differentially expressed by promastigote developmental forms of all species of the human pathogen, Leishmania.Kharon1 null mutants of Leishmania mexicana are avirulent in mice and exhibit a cytokinesis defect within macrophagesCentrin gene disruption impairs stage-specific basal body duplication and cell cycle progression in Leishmania.Intracellular Survival of Leishmania major Depends on Uptake and Degradation of Extracellular Matrix Glycosaminoglycans by Macrophages.TOR-induced resistance to toxic adenosine analogs in Leishmania brought about by the internalization and degradation of the adenosine permease.Transporters, channels and receptors in flagellaEpisomally driven antisense mRNA abrogates the hyperinducible expression and function of a unique cell surface class I nuclease in the primitive trypanosomatid parasite, Crithidia luciliae.Both sequence and context are important for flagellar targeting of a glucose transporter.Role of cytosolic glyceraldehyde-3-phosphate dehydrogenase in visceral organ infection by Leishmania donovani'Transient' genetic suppression facilitates generation of hexose transporter null mutants in Leishmania mexicanaLysosomal degradation of Leishmania hexose and inositol transporters is regulated in a stage-, nutrient- and ubiquitin-dependent manner.Leishmania adaptor protein-1 subunits are required for normal lysosome traffic, flagellum biogenesis, lipid homeostasis, and adaptation to temperatures encountered in the mammalian host.Transgenic Leishmania and the immune response to infectionTargeting the Cytochrome bc1 Complex of Leishmania Parasites for Discovery of Novel Drugs.Host-derived glucose and its transporter in the obligate intracellular pathogen Toxoplasma gondii are dispensable by glutaminolysis.Amplification of an alternate transporter gene suppresses the avirulent phenotype of glucose transporter null mutants in Leishmania mexicana.KHARON1 mediates flagellar targeting of a glucose transporter in Leishmania mexicana and is critical for viability of infectious intracellular amastigotes.
P2860
Q26776497-E52F54FB-E8A0-4F5E-A035-6BE5DAF0AB35Q28539098-4037CC57-C7A4-406A-BE40-3CC97278ED34Q28550169-A0808795-D1EF-4101-915A-C5D9AA6EEDDFQ33304061-0006C55A-F840-4B1D-B6D6-255A421D5986Q33334019-00071E9C-7289-4636-BC6E-4CB079ABB5B9Q33569844-A1DD13A5-97BF-467D-9084-7E8B789D2956Q33722105-9BFD6188-1329-415E-902A-EC02D87AF970Q33784561-84F26E8A-845E-482D-9E7C-D2499785D988Q33808831-9E001B0B-4FBF-4308-A5FC-91ACB42F0EDCQ34049038-ECB0E16B-A800-44EE-B84B-0B71FCAF02F2Q34261772-49EAF593-9112-4B79-8357-BB942A1B2203Q34279807-C7E3B746-C4B1-48FD-8494-B0E2F0EB454DQ34305465-E17ADC87-F8EA-4A8D-9161-216ED88CD117Q34422766-FEF3F97C-2093-4321-A2EE-77FC0DE8302EQ34600333-643A03A2-C49D-4C99-A699-CD802DCE9355Q34682340-FFDD804E-2C7F-448C-9303-31FB97ABA9CBQ34686971-77F84697-C606-4AC8-9AFA-ED055C04E445Q34847826-202E6C25-903D-4333-9D6D-1822928B21E7Q35080823-B0CEDDF7-405B-4A42-89D3-EF6BF3D60CECQ35102950-54EABA12-3E83-4B60-B377-D3CD0DAE17D9Q35113597-DAB5E8F9-4885-4E64-969A-76874E1C0664Q35145016-1EB18EE2-F76C-442D-9DB4-DD46C344690EQ35221187-438499EF-7329-425D-8972-6575614BC156Q35561793-A4B966D4-9705-4C97-AFCD-E32FE9401A83Q35743719-E30541F3-032C-4559-8B55-1B05E46D8FF4Q35745876-BCD8E454-2363-46AA-8FA3-3118BDEE5F27Q35762935-0D154405-1F6B-4344-B1CA-E2956048C8C6Q35972458-6B210165-AF71-40F3-8AF6-310A10E253C6Q36125076-24721F25-8F3A-42BE-AB10-681DA9C96A93Q36178696-5AE9C428-72D0-4433-8383-DCAC865D082BQ36450984-5CF666EF-A86B-4C79-AB3C-4A49431B4EF9Q36505121-1472CEBA-E465-44A0-B078-AAC6D9042FE9Q36532898-54283CC3-BB1E-4C21-A40F-497806846F33Q36670234-CA2FE4F6-7921-49F3-A987-80F1EA9F616DQ36846221-9877B497-A439-4199-9922-90944320F61EQ37081691-559255D9-39AD-4203-A0DC-5E5D4A510999Q37120118-D541BD7F-B562-4B05-9A90-21702E3F8E24Q37293288-082BFFB0-9B37-410D-9475-AFC6821B2763Q37310878-C5079831-87E0-4108-B2EB-FCE2827B9D20Q37311973-A67D96F6-7DAA-447B-92DF-0DB0A8606132
P2860
Genetic characterization of glucose transporter function in Leishmania mexicana
description
2003 nî lūn-bûn
@nan
2003 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի մարտին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Genetic characterization of glucose transporter function in Leishmania mexicana
@ast
Genetic characterization of glucose transporter function in Leishmania mexicana
@en
Genetic characterization of glucose transporter function in Leishmania mexicana
@nl
type
label
Genetic characterization of glucose transporter function in Leishmania mexicana
@ast
Genetic characterization of glucose transporter function in Leishmania mexicana
@en
Genetic characterization of glucose transporter function in Leishmania mexicana
@nl
prefLabel
Genetic characterization of glucose transporter function in Leishmania mexicana
@ast
Genetic characterization of glucose transporter function in Leishmania mexicana
@en
Genetic characterization of glucose transporter function in Leishmania mexicana
@nl
P2093
P2860
P921
P356
P1476
Genetic characterization of glucose transporter function in Leishmania mexicana
@en
P2093
David Sacks
Dayana Rodriguez-Contreras
Govind Modi
Kathleen McBride
Michael P Barrett
Patrick Merkel
Richard J S Burchmore
P2860
P304
P356
10.1073/PNAS.0630165100
P407
P50
P577
2003-03-21T00:00:00Z