Receptor-mediated endocytosis of transferrin and the uptake of fe in K562 cells: identification of a nonlysosomal acidic compartment.
about
Internalization and processing of transferrin and the transferrin receptor in human carcinoma A431 cellsNanobiopolymer for direct targeting and inhibition of EGFR expression in triple negative breast cancerTrafficking of the plasma membrane gamma-aminobutyric acid transporter GAT1. Size and rates of an acutely recycling poolMorphologic characterization of the pathway of transferrin endocytosis and recycling in human KB cellsReceptor-mediated endocytosis of transferrin and recycling of the transferrin receptor in rat reticulocytesStructure, function and clinical significance of transferrin receptors.A possible role for Na+,K+-ATPase in regulating ATP-dependent endosome acidification.Characterization of oligonucleotide transport into living cells.Regulation of transferrin receptor expression at the cell surface by insulin-like growth factors, epidermal growth factor and platelet-derived growth factorTheoretical considerations on the role of membrane potential in the regulation of endosomal pHEndocytosis of the membrane immunoglobulins of mouse spleen B-cells: a quantitative study of its rate, amount and sensitivity to physiological, physical and cross-linking agents.Co-assembly of Kv4 {alpha} subunits with K+ channel-interacting protein 2 stabilizes protein expression and promotes surface retention of channel complexesEndosome pH measured in single cells by dual fluorescence flow cytometry: rapid acidification of insulin to pH 6Membranous intermediates in endocytosis are labile, as shown in a temperature-sensitive mutant.Salvage of glucosylceramide by recycling after internalization along the pathway of receptor-mediated endocytosis.High-resolution kinetics of transferrin acidification in BALB/c 3T3 cells: exposure to pH 6 followed by temperature-sensitive alkalinization during recycling.Iron status in mice carrying a targeted disruption of lactoferrinEffects of different transferrin forms on transferrin receptor expression, iron uptake, and cellular proliferation of human leukemic HL60 cells. Mechanisms responsible for the specific cytotoxicity of transferrin-gallium.Efficient clearance of non-transferrin-bound iron by rat liver. Implications for hepatic iron loading in iron overload states.Desialation of transferrin by rat liver endothelium.Lactoferrin and host defense.Ferristatin II promotes degradation of transferrin receptor-1 in vitro and in vivo.Renal anemia: a nephrologist's view.Interaction of Cm(III) and Am(III) with human serum transferrin studied by time-resolved laser fluorescence and EXAFS spectroscopy.Iron, lipocalin, and kidney epithelia.Human serum transferrin fibrils: nanomineralisation in bacteria and destruction of red blood cells.Endocytosis of a functionally enhanced GFP-tagged transferrin receptor in CHO cells.Growth of Francisella tularensis LVS in macrophages: the acidic intracellular compartment provides essential iron required for growthThe transport of iron and copper across the cell membrane: different mechanisms for different metals?A fusion-loop antibody enhances the infectious properties of immature flavivirus particles.Avian Influenza Virus Infection of Immortalized Human Respiratory Epithelial Cells Depends upon a Delicate Balance between Hemagglutinin Acid Stability and Endosomal pH.Differentiation-associated switches in protein 4.1 expression. Synthesis of multiple structural isoforms during normal human erythropoiesis.Deletional analysis of the promoter region of the human transferrin receptor geneMavN is a Legionella pneumophila vacuole-associated protein required for efficient iron acquisition during intracellular growth.Monensin inhibits intracellular dissociation of asialoglycoproteins from their receptor.Co-migration and internalization of transferrin and its receptor on K562 cells.Acidification of endocytic vesicles by an ATP-dependent proton pumpRapid acidification of endocytic vesicles containing asialoglycoprotein in cells of a human hepatoma lineMembrane fusion mutants of Semliki Forest virusA lipophilic iron chelator can replace transferrin as a stimulator of cell proliferation and differentiation.
P2860
Q24681319-14CAAA8F-36E8-40EF-8E96-6D93B792F1DCQ28480835-F506AB1C-02F2-4232-8825-C465A204095CQ28581638-59D6D381-16C7-4975-87EE-409D187FFB72Q28609354-0CEDADD4-1041-478A-913E-B987F91CEDE3Q28609355-65E28043-EE82-4543-AB0C-242A5B8DF259Q33545639-01EEA097-C4DC-40AE-9A7B-D951F31C9AEDQ33831586-191B2274-48C6-4A71-B6B3-DA80F058C1FBQ33855658-D7DE09DE-FAA0-41E6-87A6-AC1224A48113Q33879706-56442123-AAC3-492E-B086-36A5E94EDB83Q33907147-3640144C-DC90-47AC-9BAE-C30DE3C60B61Q33939921-11AE97C3-1D28-4E4C-A994-37C4F2849724Q34236486-1B6B890E-BE05-43C1-8882-C54366494F7CQ34248163-6D54FDCF-E614-4A90-9CDD-37F55C429316Q34285996-1F0BF108-8E64-417B-B8A3-45035DEFFBABQ34325694-C2F166D2-E14C-4147-8B42-EF39E266E16BQ34353048-7FB16143-0C4B-4924-AF35-1FC8AFAB3B69Q34462620-07407B64-3DD2-4ABC-BCA8-57683B8E51D6Q34550382-98A493FE-D761-40AB-B824-8496B5AB53FCQ34559341-AA4FABA9-2CB9-4A1E-9174-F4EAF3918D7DQ34559405-7560FEE5-1715-4E94-8D55-66E977603F71Q34573857-4DB704FE-243B-44E3-AC69-B6057342C8ABQ34875712-C2D7B38F-CCF3-4991-8C6F-7AE1F41528D3Q35115561-36D5160E-0C6B-4A7D-B45D-58FB2EEA1B84Q35120280-9EBE5554-B346-4F7E-804F-1F7C79917716Q35146299-63A1D3C9-AC69-440A-9E0C-593DBD9AC4D2Q35211683-64C2243F-FC8D-4771-9B19-E4A47523E40FQ35214291-6E2D701B-8536-4578-8F0F-82E39ED0E1E7Q35403392-89C13D4D-39C0-4134-8EF5-74AB6FA61A3DQ35531211-582474AD-F443-4EA4-BA1F-43C83B1B0459Q35531326-2176A62E-19AE-4EFB-A794-C2AA6CC396ECQ35536208-753B4508-307B-4EA1-88DD-5422E869E236Q35824129-D6EEDFD2-CDFE-474C-9BAD-4215D262F942Q35941938-8FBB0DE1-7CC1-48A4-94EC-C63930A1C77CQ36078970-4FEA5990-99F5-49AD-AE95-31D380B6A6EFQ36207248-FFABC531-3461-4FA9-B291-685EF1979251Q36207619-0508AC44-47F1-419C-BDC1-60F58FAC00C5Q36207760-0F839FAE-BF9B-4734-B81B-F171BA8EC77BQ36208501-312B7BB7-9455-42BE-97B7-0AF6EE27F177Q36209563-59E00E00-6162-4C6A-90F6-BDDD54C5F880Q36210096-E3986B01-F1D6-4308-9012-3DE62E36C37F
P2860
Receptor-mediated endocytosis of transferrin and the uptake of fe in K562 cells: identification of a nonlysosomal acidic compartment.
description
1982 nî lūn-bûn
@nan
1982年の論文
@ja
1982年学术文章
@wuu
1982年学术文章
@zh-cn
1982年学术文章
@zh-hans
1982年学术文章
@zh-my
1982年学术文章
@zh-sg
1982年學術文章
@yue
1982年學術文章
@zh
1982年學術文章
@zh-hant
name
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@ast
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@en
type
label
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@ast
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@en
prefLabel
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@ast
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@en
P2093
P2860
P356
P1476
Receptor-mediated endocytosis ...... nlysosomal acidic compartment.
@en
P2093
Bridges KR
Harford JB
Klausner RD
van Renswoude J
P2860
P304
P356
10.1073/PNAS.79.20.6186
P407
P577
1982-10-01T00:00:00Z