Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P50583 (asymmetrical)
 12,197 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The transport function and orientation of the reconstituted human erythrocyte glucose transporter was studied with liposomes made with bovine brain lipid or Escherichia coli lipid. Reconstitution was achieved by a simple octyl glucoside dilution method. The reconstituted transporters with either lipid showed identical counterflow transport activity, the same response to various inhibitors, and characteristic cytochalasin B (CB) labeling. Functional location and purification of the glucose transporter was performed by using gel-permeation high-performance liquid chromatography with octyl glucoside-containing buffer. The reconstituted transport activity was associated only with band 4.5 protein (preactin) and not with band 3 protein. Both CB binding and transport function of the reconstituted transporters were resistant to trypsin but susceptible to chymotrypsin digestion. However, both trypsin and chymotrypsin treatment of unsealed ghosts completely eliminated the CB labeling and transport function of the glucose transporter. In our reconstitution system the glucose transporters maintained a normal asymmetrical (right-side-out) orientation and good transport function. A specific monoclonal antibody against the glucose transporter inhibited CB labeling of the transporters on unsealed ghosts. This was not found with the reconstituted system; however, after freeze-thawing there was a significant inhibition of CB binding by the antibody. These findings suggest that the CB-binding site of the reconstituted transporter is on the inner side of the proteoliposomes.
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PMID:Human erythrocyte glucose transporter: normal asymmetric orientation and function in liposomes. 351 73

The transmembrane 4 (TM4) superfamily contains many important leukocyte differentiation-related surface proteins including CD9, CD37, CD53, and CD81; tumor-associated antigens including CD63/ME491, CO-029, and SAS; and a newly identified metastasis suppressor gene R2. Relatively little is known, however, about the structure and aggregation state of these four transmembrane-domained proteins. The asymmetrical unit membrane (AUM), believed to play a major role in stabilizing the apical surface of mammalian urothelium thus preventing it from rupturing during bladder distention, contains two TM4 members, the uroplakins (UPs) Ia and Ib. In association with two other (single transmembrane-domained) membrane proteins, UPII and UPIII, UPIa and UPIb form 16-nm particles that naturally form two-dimensional crystalline arrays, thus providing unique opportunities for studying membrane structure and function. To better understand how these proteins interact to form the 16-nm particles, we analyzed their nearest neighbor relationship by chemical cross-linking. We show here that UPIa and UPIb, which share 39% of their amino acid sequence, are cross-linked to UPII and UPIII, respectively. We also show that UPIa has a propensity to oligomerize, forming complexes that are stable in SDS, and that UPII can be readily cross-linked to form homodimers. The formation of UPII homodimers is sensitive, however, to octyl glucoside that can solubilize the AUMs. These data suggest that there exist two types of 16-nm AUM particles that contain UPIa/UPII or UPIb/UPIII, and support a model in which the UPIa and UPII occupy the inner and outer domains, respectively, of the UPIa/UPII particle. This model can account for the apparent "redundancy" of the uroplakins, as the structurally related UPIa and UPIb, by interacting with different partners, may play different roles in AUM formation. The model also suggests that AUM plaques with different uroplakin compositions may differ in their assembly, and in their abilities to interact with an underlying cytoskeleton. Our data indicate that two closely related TM4 proteins, UPIa and UPIb, can be present in the same cell, interacting with distinct partners. AUM thus provides an excellent model system for studying the targeting, processing, and assembly of TM4 proteins.
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PMID:Selective interactions of UPIa and UPIb, two members of the transmembrane 4 superfamily, with distinct single transmembrane-domained proteins in differentiated urothelial cells. 853 Mar 66

Rat peritoneal macrophages were cultured with a specific and potent phospholipase A2 activator A 23187, with 1-stearoyl-2-[3H]arachidonoyl-sn-GPC as source of [3H] arachidonic acid, and with a dialkyl-GPC, at 2, 10 or 20 microM. Four dialkyl-GPCs were prepared by chemical synthesis. Position 2 of rac-glycerol was alkylated with an alkane chain of 8 carbons and position 1 was alkylated with various alkane chains (8, 10, 12, or 16 carbons). [3H] arachidonic acid was split, then recovered with cell nonesterified fatty acids and nonphosphorous glycerolipids after endocellular phospholipase A2 activity. It was also recovered with fatty acids and eicosanoids isolated from culture medium. Inhibition of fatty acid release and eicosanoid synthesis depended on mixed chain dialkyl-GPC structures. The highest inhibitory effect on arachidonic acid release was reached with 1-decyl-2octyl-GPC and was practically as high in culture medium (IC50 at 5 microM) as in cells (IC50 at 4 microM). 1,2-di-octyl-GPC and 1-dodecyl-2-octyl-GPC had weaker inhibitory effects (but higher in culture medium than in cells). The asymmetrical 1-hexadecyl-2-octyl-GPC poorly affected enzyme activity.
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PMID:Influence of alkyl chain lengths in dialkylglycerophosphocholines towards phospholipase A2 inhibition in macrophages. 858 51

The molecular architectures of enveloped viruses are one demonstrative example of perfectly arranged macromolecular complex that is achieved through the structural specificity of virus assembly. Virus morphogenesis is a multi-step process that depends on the concerted actions of many viral and cellular components as well as fitted organization of main viral constituents. Viral envelope was shown to be composed of the mixture of lipid raft and non-raft domains. The domains are recruited from the host-cell membrane as discrete well-ordered lipid-protein units in the process of virus assembly. Raft-like nature of influenza virus A envelope was visualized using a novel approach of cold solubilization of the detergent-resistant membranes from intact influenza virus A virions with the mixture of two non-ionic detergents drastically differing in their raft-solubilizing activities, NP40 and octyl-glucopyranoside. In the view of this methodological approach, the virus envelope is apparently an ensemble of platforms which are flexibly joint in the viral envelope, and composed of surface glycoproteins (hemagglutinin and neuraminidase), matrix M1 protein and lipids. The modern concept of transmembrane asymmetry of lateral domains in biological membranes was involved to explain the solubilization mechanism revealed. Using principles of this concept we suggest matrix M1 protein shell as a structure-forming base to support asymmetrical rafts in the virus envelope.
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PMID:[The concept of transmembrane asymmetry of lateral domains in biomemranes and influenza virus envelope fine structure]. 1980 18