Platelet membrane glycoprotein (GP) Ib contains receptors for von Willebrand factor and thrombin. Its proteolytic fragment, glycocalicin, circulates in normal plasma. In this study, storage of platelet concentrates for 5 d resulted in a 221% increase in plasma glycocalicin (1.3 times the total amount of glycocalicin present on the surface of all platelets), an 8% overall increase in platelet surface GPIb, and the appearance of a surface GPIb-negative subpopulation of platelets. Total platelet GPIb content of fresh washed platelets, determined by gel electrophoresis and immunoassay of Triton X-100 lysates, averaged 159,740 molecules per platelet. There were 36,360 surface GPIb molecules per platelet, determined by immunoassay of the supernatant of fresh washed platelets whose surface GPIb had been completely plasmin-cleaved. In sumnpary, these studies provide evidence for (a) a redistribution of GPIb molecules with platelet storage, and (b) a large intraplatelet pool of GPIb (approximately threefold larger than the platelet surface pool of GPIb).
A variety of evidence suggests that the cytoplasmic mRNA-associated proteins of eucaryotic cells are derived from the cytoplasm and function there, most likely in protein synthesis or some related process. Furthermore, the evidence suggests that protein-free mRNA added to a cell-free translation system should become associated with a set of proteins similar to those associated with mRNA in native polyribosomes. To test this hypothesis, we added deproteinized rabbit reticulocyte mRNA to a homologous cell-free translation system made dependent on exogenous mRNA by treatment with micrococcal nuclease. The resulting reconstituted complexes were irradiated with UV light to cross-link the proteins to mRNA, and the proteins were analyzed by gel electrophoresis. The proteins associated with polyribosomal mRNA in the reconstituted complexes were indistinguishable from those associated with polyribosomal mRNA in intact reticulocytes. Furthermore, reticulocyte mRNA-associated proteins were very similar to those of cultured mammalian cells. The composition of the complexes varied with the translational state of the mRNA; that is, certain proteins present in polyribosomal mRNA-protein complexes were absent or reduced in amount in 40S to 80S complexes and in complexes formed in the absence of translation. However, other proteins, including a 78-kilodalton protein associated with polyadenylate, were present irrespective of translational state, or else they were preferentially associated with untranslated mRNA. These findings are in agreement with previous data suggesting that proteins associated with cytoplasmic mRNA are derived from the cytoplasm and that they function in translation or some other cytoplasmic process, rather than transcription, RNA processing, or transport from the nucleus to the cytoplasm.It is becoming increasingly clear that the proteins associated with cytoplasmic mRNA in eucaryotic cells associate in the cytoplasm with already existing mRNA rather than coming out of the nucleus along with newly synthesized mRNA and that they function in translation or in some related cytoplasmic process such as determining mRNA stability. This laboratory and others showed that these proteins differ dramatically from those of nuclear RNA-protein complexes containing mRNA precursors (21,24,35). Even cytoplasmic polyadenylate [poly(A)]-protein complexes differ in structure and composition from their nuclear counterparts (1,35,39). The labeling kinetics of the cytoplasmic mRNA-associated proteins were consistent with cytoplasmic addition to mRNA (13). These findings make it unlikely that they are packaging or transport proteins.The mRNA-associated proteins are similar in size, charge, and amino acid composition to soluble RNA-binding proteins which can serve as initiation and elongation factors in translation (26,28,36,37,40). Furthermore, we showed that the proteins of polyribosomal mRNA-protein complexes (mRNP) continue to be synthesized and to become associated with mRNA in the absence of mRNA synthesis (13 lation system,...
A variety of evidence suggests that the cytoplasmic mRNA-associated proteins of eucaryotic cells are derived from the cytoplasm and function there, most likely in protein synthesis or some related process. Furthermore, the evidence suggests that protein-free mRNA added to a cell-free translation system should become associated with a set of proteins similar to those associated with mRNA in native polyribosomes. To test this hypothesis, we added deproteinized rabbit reticulocyte mRNA to a homologous cell-free translation system made dependent on exogenous mRNA by treatment with micrococcal nuclease. The resulting reconstituted complexes were irradiated with UV light to cross-link the proteins to mRNA, and the proteins were analyzed by gel electrophoresis. The proteins associated with polyribosomal mRNA in the reconstituted complexes were indistinguishable from those associated with polyribosomal mRNA in intact reticulocytes. Furthermore, reticulocyte mRNA-associated proteins were very similar to those of cultured mammalian cells. The composition of the complexes varied with the translational state of the mRNA; that is, certain proteins present in polyribosomal mRNA-protein complexes were absent or reduced in amount in 40S to 80S complexes and in complexes formed in the absence of translation. However, other proteins, including a 78-kilodalton protein associated with polyadenylate, were present irrespective of translational state, or else they were preferentially associated with untranslated mRNA. These findings are in agreement with previous data suggesting that proteins associated with cytoplasmic mRNA are derived from the cytoplasm and that they function in translation or some other cytoplasmic process, rather than transcription, RNA processing, or transport from the nucleus to the cytoplasm.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.