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Membrane Targeting (membrane + targeting)

Distribution by Scientific Domains
Life Sciences60%
Chemistry40%

Selected Abstracts

A role of the C-terminus of aquaporin 4 in its membrane expression in cultured astrocytes

GENES TO CELLS, Issue 7 2002
Ken-ichi Nakahama
Background: Aquaporin 4 (AQP4) is a predominant water channel protein in mammalian brains, which is localized in the astrocyte plasma membrane. Membrane targeting of AQP4 is essential to perform its function. The mechanism(s) of membrane targeting is not clear in astrocytes. Results: We investigated the role of the C-terminus of AQP4 (short isoform) in its membrane targeting by an expression study of C-terminal mutants of AQP4 in cultured astrocytes. The deletion of 26 C-terminal residues of AQP4 (AQP4,276,301aa) results in the intracellular localization of the protein. However, smaller deletions than 21 C-terminal residues did not alter its plasma membrane localization. These results suggest that C-terminal residues between Val276 and Ile280 play an important role in the expression of AQP4 in the plasma membrane. However, the plasma membrane localization of the AQP4(A276AAAA280) mutant (alanine substitution of Val276 -Ile280 of AQP4) suggests that another signal for membrane targeting exists in the C-terminus of AQP4. The deletion or point mutations of the PDZ binding motif of the AQP4(A276AAAA280) mutant resulted in the intracellular localization of the proteins. These results suggest that the PDZ binding motif may also be involved in the membrane targeting of AQP4. Conclusions: We found that the C-terminal sequence of AQP4 contains two important signals for membrane expression of AQP4 in cultured astrocytes. One is a hydrophobic domain and the other is a PDZ binding motif that exists in the C-terminus. [source]

Disruption of transport activity in a D93H mutant thiamine transporter 1, from a Rogers Syndrome family

FEBS JOURNAL, Issue 22 2003
Dana Baron
Rogers syndrome is an autosomal recessive disorder resulting in megaloblastic anemia, diabetes mellitus, and sensorineural deafness. The gene associated with this disease encodes for thiamine transporter 1 (THTR1), a member of the SLC19 solute carrier family including THTR2 and the reduced folate carrier (RFC). Using transient transfections into NIH3T3 cells of a D93H mutant THTR1derived from a Rogers syndrome family, we determined the expression, post-translational modification, plasma membrane targeting and thiamine transport activity. We also explored the impact on methotrexate (MTX) transport activity of a homologous missense D88H mutation in the human RFC, a close homologue of THTR1. Western blot analysis revealed that the D93H mutant THTR1 was normally expressed and underwent a complete N -glycosylation. However, while this mutant THTR1 was targeted to the plasma membrane, it was completely devoid of thiamine transport activity. Consistently, introduction into MTX transport null cells of a homologous D88H mutation in the hRFC did not result in restoration of MTX transport activity, thereby suggesting that D88 is an essential residue for MTX transport activity. These results suggest that the D93H mutation does not interfere with transporter expression, glycosylation and plasma membrane targeting. However, the substitution of this negatively charged amino acid (Asp93) by a positively charged residue (His) in an extremely conserved region (the border of transmembrane domain 2/intracellular loop 2) in the SLC19 family, presumably inflicts deleterious structural alterations that abolish thiamine binding and/or translocation. Hence, this functional characterization of the D93H mutation provides a molecular basis for Rogers syndrome. [source]

A role of the C-terminus of aquaporin 4 in its membrane expression in cultured astrocytes

GENES TO CELLS, Issue 7 2002
Ken-ichi Nakahama
Background: Aquaporin 4 (AQP4) is a predominant water channel protein in mammalian brains, which is localized in the astrocyte plasma membrane. Membrane targeting of AQP4 is essential to perform its function. The mechanism(s) of membrane targeting is not clear in astrocytes. Results: We investigated the role of the C-terminus of AQP4 (short isoform) in its membrane targeting by an expression study of C-terminal mutants of AQP4 in cultured astrocytes. The deletion of 26 C-terminal residues of AQP4 (AQP4,276,301aa) results in the intracellular localization of the protein. However, smaller deletions than 21 C-terminal residues did not alter its plasma membrane localization. These results suggest that C-terminal residues between Val276 and Ile280 play an important role in the expression of AQP4 in the plasma membrane. However, the plasma membrane localization of the AQP4(A276AAAA280) mutant (alanine substitution of Val276 -Ile280 of AQP4) suggests that another signal for membrane targeting exists in the C-terminus of AQP4. The deletion or point mutations of the PDZ binding motif of the AQP4(A276AAAA280) mutant resulted in the intracellular localization of the proteins. These results suggest that the PDZ binding motif may also be involved in the membrane targeting of AQP4. Conclusions: We found that the C-terminal sequence of AQP4 contains two important signals for membrane expression of AQP4 in cultured astrocytes. One is a hydrophobic domain and the other is a PDZ binding motif that exists in the C-terminus. [source]

Localization and targeting of the VP14 epoxy-carotenoid dioxygenase to chloroplast membranes

THE PLANT JOURNAL, Issue 5 2001
Bao-Cai Tan
Summary Abscisic acid (ABA) is a key regulator of seed dormancy and plant responses to environmental challenges. ABA is synthesized via an oxidative cleavage of 9- cis epoxy-carotenoids, the first committed and key regulatory step in the ABA biosynthetic pathway. Vp14 of maize encodes an epoxy-carotenoid dioxygenase that is soluble when expressed in E. coli. An important goal has been to determine how the soluble VP14 protein is targeted to epoxy-carotenoid substrates that are located in the thylakoid and envelope membranes of chloroplasts and other plastids. Using an in vitro chloroplast import assay, we have shown that VP14 is imported into chloroplasts with cleavage of a short stroma-targeting domain. The mature VP14 exists in two forms, one which is soluble in stroma and the other bound to thylakoid membranes. Analysis of a series of truncated VP14 mutants mapped the membrane targeting signal to the 160 amino acid N-terminal sequence. A putative amphipathic ,-helix within this region is essential, but not sufficient, for the membrane targeting. Either deletion of or insertion of helix breaking residues into this region abolished the membrane binding, whereas a chimeric protein carrying just the amphipathic region fused with bacterial glutathione S -transferase failed to associate with the thylakoid membrane. The membrane-bound VP14 was partially resistant to chaotropic washes such as 0.1 m Na2CO3 (pH 11.5) and 6 m urea. Unlabelled recombinant VP14 inhibited the tight binding of imported VP14, suggesting that VP14 is associated with specific components of the thylakoid membrane. [source]

Purification, crystallization and preliminary X-ray analysis of the GTP-binding protein Rab9 implicated in endosome-to-TGN vesicle trafficking

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 3 2004
Julia G. Wittmann
Rab GTP-binding proteins are involved in the regulation of distinct vesicular-transport events involving membrane targeting and fusion. They differ from other small GTPases by the presence of specific loop regions that serve as effector-binding sites in addition to the classical switch I and switch II regions. While the structures of many small GTP-binding proteins of the Ras superfamily are available in both GDP- and GTP-bound forms, Rab proteins are less well characterized than Ras proteins at the structural level. The crystallization of Rab9, a key regulatory component in the recycling of mannose-6-­phosphate receptors from endosomes to the trans-Golgi network, is described here. [source]