Type 1 plasminogen activator inhibitor (PAI-1), the primary inhibitor of tissue-type plasminogen activator (t-PA), is found in plasma and platelets. PAI-1 circulates in complex with vitronectin (Vn), an interaction that stabilizes PAI-1 in its active conform. In this study, we examined the binding of platelet-derived Vn and PAI-1 to the surface of isolated platelets. Flow cytometry indicate that, like P-selectin, PAI-1, and Vn are found on the surface of thrombin-or calcium ionophore-activated platelets and platelet microparticles. The binding of PAI-1 to the activated platelet surface is Vn-dependent. Vn mediates the binding of PAI-1 to platelet surfaces through a high affinity (K d of 80 nM) binding interaction with the NH 2 terminus of vimentin, and this Vn-binding domain is expressed on the surface of activated platelets and platelet microparticles. Immunological and functional assays indicate that only ؊5% of the total PAI-1 in platelet releasates is functionally active, and it co-precipitates with Vn, and the vimentin-enriched cytoskeleton fraction of activated platelet debris. The remaining platelet PAI-1 is inactive, and does not associate with the cytoskeletal debris of activated platelets. Confocal microscopic analysis of platelet-rich plasma clots confirm the co-localization of PAI-1 with Vn and vimentin on the surface of activated platelets, and platelet microparticles. These findings suggest that platelet vimentin may regulate fibrinolysis in plasma and thrombi by binding platelet-derived Vn⅐PAI-1 complexes.
Enolpyruvylshikimate 3-phosphate synthase (EPSP synthase, AroA) catalyzes the sixth step in aromatic amino acid biosynthesis. It forms EPSP from shikimate 3-phosphate (S3P) and phosphoenolpyruvate (PEP) in an addition/elimination reaction that proceeds through a tetrahedral intermediate. In spite of numerous mechanistic studies, the catalytic roles of specific amino acid residues remain an open question. Recent experimental evidence for cationic intermediates or cationic transition states, and a consideration of the catalytic imperative, have guided this study on the catalytic roles of Lys22 (K22), Asp313 (D313), and Glu341 (E341). Steady-state and pre-steady-state kinetics and protein stability studies showed that mutations of D313 and E341 caused k(cat) to decrease up to 30,000-fold and 76,000-fold, respectively, while the effects on K(M) were modest, never more than 40-fold. Thus, both are identified as catalytic residues. In an active site that is overwhelmingly positively charged, the D313 and E341 side chains are positioned to form an "electrostatic sandwich" around the positive charge at C2 in cationic intermediates/transition states, stabilizing them and thereby promoting catalysis. Mutation of K22 showed large effects on K(M,S3P) (100-fold), K(M,PEP) (>760-fold), and up to 120-fold on k(cat). Thus, K22 had roles in both substrate-binding and transition-state stabilization. These results support the identification of E341 and K22 as general acid/base catalytic residues.
MurA (enolpyruvyl UDP-GlcNAc synthase) catalyzes the first committed step in peptidoglycan biosynthesis. In this study, MurA-catalyzed breakdown of its tetrahedral intermediate (THI), with a k(cat)/K(M) of 520 M(-1) s(-1), was far slower than the normal reaction, and 3 x 10(5)-fold slower than the homologous enzyme, AroA, reacting with its THI. This provided kinetic evidence of slow binding and a conformationally constrained active site. The MurA cocrystal structure with UDP-N-acetylmuramic acid (UDP-MurNAc), a potent inhibitor, and phosphite revealed a new "staged" MurA conformation in which the Arg397 side chain tracked phosphite out of the catalytic site. The closed-to-staged transition involved breaking eight MurA.ligand ion pairs, and three intraprotein hydrogen bonds helping hold the active site loop closed. These were replaced with only two MurA.UDP-MurNAc ion pairs, two with phosphite, and seven new intraprotein ion pairs or hydrogen bonds. Cys115 appears to have an important role in forming the staged conformation. The staged conformation appears to be one step in a complex choreography of release of the product from MurA.
Intravenous injection of bovine or human lactoferrin (6.25 x 10(-2) mumol/100 g body wt) in rats resulted in marked reduction of hepatic iron uptake from transferrin and asialotransferrin. The effect was dose dependent, saturable at approximately 5 mg/100 g body wt, and independent of lactoferrin's iron content. At this dose level, iron uptake from transferrin was reduced by 28% and from asialotransferrin by 43% in experiments lasting 90 min. Bovine lactoperoxidase, another basic protein, was similarly effective. The clearance of asialofetuin and pinocytosis of polyvinylpyrrolidone remained unaffected. Perfusion of isolated rat livers at 4 degrees C showed a strong reduction in asialotransferrin binding in the presence of lactoferrin. Chromatography of hepatic heparan sulfate proteoglycan on immobilized lactoferrin, lactoperoxidase, asialotransferrin, and transferrin showed that it possessed affinity for each of these proteins, more for the first two than the latter two. Heparan sulfate proteoglycan binding and efficacy in reducing hepatic iron uptake were also studied after selective modifications of positively charged amino acids in these proteins. The data obtained are compatible with the hypothesis that lactoferrin and other proteins with similarly high affinity for hepatic heparan sulfate exert their negative effect on iron uptake by preventing transferrin binding to the proteoglycan. The possibility is thus raised that the large number of low-affinity transferrin binding sites reported by earlier investigators for the liver may be heparan sulfate molecules.
After the injection of a small dose (1 jtg/100 g of body weight) of _151-labeled human asialotransferrin type 3 in rats, the radioactivity became rapidly associated with the liver. However, during the ensuing 12 hr a significant fraction of the dose returned to the circulation as protein-bound S5I. The protein released by the liver was indistinguishable by gel filtration from the original preparation and was precipitable by an antiserum to human transferrin. Nevertheless, it no longer bound to the immobilized Gal/GalN-specific lectin from rabbit liver. However, binding could be restored to a large extent by treatment with neuraminidase, indicating that the loss of binding was due to resialylation. Changes in the electrophoretic mobility of asialotransferrin released by the liver showed that resialylation was partial-i.e., it involved the attachment oftwo or three sialyl residues. From analysis by deconvolution of the plasma curve of partially resialylated asialotransferrin it was calculated that the liver "repaired" this way approximately one asialotransferrin molecule out of four. Plasma clearance of partially resialylated asialotransferrin was similar to that of nondesialylated transferrin.A minor portion (15-17%) of human transferrin phenotype C consists of molecules which, after desialylation, bind avidly (1) to the Gal/GalN-specific lectin (2) of the rat liver. We designated this fraction human asialotransferrin type 3 (HAsTf-3; ref.3). Suspended rat hepatocytes internalize HAsTf-3 via the above lectin (4). However, only a small fraction of the intracellular HAsTf-3 undergoes catabolism, whereas the rest is released showing no signs of proteolytic digestion. Cell-associated radioactivity decreases considerably more slowly in the suspension than is the time required for "2I-labeled HAsTf-3 ('"IHAsTf-3) to emerge from the hepatocytes, implying that the ligand is being repeatedly endo-and exocytosed. We termed this movement of HAsTf-3 the diacytic pathway (4) in contradistinction to the well-known lysosomal pathway for other asialoglycoproteins (5). During diacytosis, HAsTf-3 is entrapped in a subcellular particle that is ofa lesser equilibrium density than the vesicle that transports internalized asialoorosomucoid (6).The unusual handling of HAsTf-3 by the hepatocyte raises the question of how the liver ofthe intact rat ultimately disposes of this asialoglycoprotein. Because our earlier experiments in vivo were too short to provide an answer (3), we have now conducted studies lasting up to 12 hr. These showed that rat liver processed small doses of HAsTf-3 slowly in (at least) two ways-namely, catabolism and partial resialylation. Here we report our findings relating to resialylation. MATERIALS AND METHODSMaterials. Na125I, Na1311, 59FeC13, and N-acetyl-D-[6-3H(N)]mannosamine (19 Ci/mmol; 1 Ci = 3.7 X 1010 becquerels) were obtained from New England Nuclear. Neuraminidase from Vibrio cholerae was from GIBCO and neuraminidase from Diplococcus pneumoniae was a gift from M. Lowe and G. Ashwell (National ...
19788 -19794). The current studies were undertaken to further examine the interactions between vitronectin and fibrin(ogen). Comparison of vitronectin levels in plasma with those in serum indicates that ϳ20% of plasma vitronectin is incorporated into the clot. When the time course of biotinylated-vitronectin incorporation into clots formed from 125 I-fibrinogen is monitored, vitronectin incorporation into the clot parallels that of fibrinogen in the absence or presence of activated factor XIII. Vitronectin binds specifically to fibrin matrices with an estimated K d of ϳ0.6 M. Additional vitronectin subunits are assembled on fibrin-bound vitronectin multimers through self-association. Confocal microscopy of fibrin clots reveals the globular vitronectin aggregates anchored at intervals along the fibrin fibrils. This periodicity raised the possibility that vitronectin interacts with the ␥A/␥ variant of fibrin(ogen) that represents about 10% of total fibrinogen. In support of this concept, the vitronectin which contaminates fibrinogen preparations co-purifies with the ␥A/␥ fibrinogen fraction, and clots formed from ␥A/␥ fibrinogen preferentially bind vitronectin. These studies reveal that vitronectin associates with fibrin during coagulation, and may thereby modulate hemostasis and inflammation.Vitronectin is a multifunctional plasma glycoprotein that participates in the regulation of coagulation, fibrinolysis, and the complement cascade (reviewed in Refs. 1 and 2). Vitronectin also regulates cell adhesion and pericellular proteolysis on surfaces of cells and extracellular matrices (1-5). Like fibrinogen, vitronectin is found in plasma at micromolar concentrations (6), and is stored in megakaryocyte and platelet ␣-granules (7-9). In plasma, vitronectin circulates as a native, monomeric form that is a mixture of 72-kDa single-chain and two-chain disulfide-linked species (10 -12). Under normal conditions, less than 3% of plasma vitronectin is comprised of more reactive oligomeric forms that display enhanced affinity for heparin or heparin-like molecules, and for the conformationsensitive monoclonal antibody 8E6 (10 -12).During acute phase response, plasma vitronectin levels increase (6), with a relative increase in the percentage of oligomeric vitronectin (13). Levels of the oligomeric forms of vitronectin in serum relative to plasma also increase; indicating the process of coagulation alters vitronectin structure and function (10 -12, 14). The altered, oligomeric form of vitronectin is generated, at least in part, by interactions with other plasma proteins such as thrombin-antithrombin complexes (11, 12, 14, 15, and complement C5b-9 complexes (11, 12, 16).A portion of vitronectin in plasma (17,18), and in platelets is complexed with type 1 plasminogen activator inhibitor (PAI-1) 1 (8,9,19), an interaction that induces the formation of higher order complexes (4,5,20,21) and influences the structure and function of both PAI-1 and vitronectin. Thus, when bound to vitronectin, PAI-1 is stabilized in its active conforma...
The hepatic uptake and degradation of human diferric 125I-lactoferrin by the liver of the intact rat were studied. After intravenous injection, the tracer was rapidly cleared by the liver, probably by adsorptive pinocytosis, as inferred from observations with a 3,470-fold dose range. Endocytosed lactoferrin was transferred, with a delay, from a light-density subcellular particle to an organelle that had a density similar to lysosomes. The loss of protein bound 125I from the liver was very slow (half-life 2.7 h), and its rate matched closely that of human asialotransferrin type 3. Lactoferrin was found to be a poor substrate for lysosomal hydrolases in vitro. Fucoidin effected the release of a portion of lactoferrin from the liver back into the plasma. By using this agent, indirect evidence was obtained suggesting that a fraction of lactoferrin is being repeatedly endo- and exocytosed (diacytosed) by the liver over prolonged periods of time. Fucosylation failed to impart lactoferrinlike properties on human asialotransferrin type 1, although the derivatized protein exhibited a less than or equal to 10-fold increase in affinity for the liver relative to the parent molecule.
Hepatic iron uptake from and degradation of rat asialotransferrin prepared from the least anionic (major) component of rat transferrin were studied in intact rats. In experiments lasting 60-90 min, rat asialotransferrin delivered a three to four times larger fraction of the Fe dose to the liver than rat transferrin. Variations in the concentration of endogenous circulating rat 2Fe-transferrin by up to 300% failed to affect the enhanced hepatic delivery of Fe from rat asialotransferrin. However, pretreating the animals with a large dose of asialomucin, or fully sialylated human transferrin, or a combination of both did affect the delivery. In all cases, rat asialotransferrin delivered Fe to the liver at rates comparable with those seen with rat transferrin. The reason for the efficacy of human transferrin was clarified in competitive binding studies on rat hepatocytes and reticulocytes, which showed that human transferrin possessed an approximately sevenfold higher affinity for rat transferrin receptors than the homologous protein. These findings suggest that the enhanced hepatic uptake of Fe from rat asialotransferrin is mediated by simultaneous binding of the ligand both through its glycan and transferrin receptor affinity site. Pretreatment with asialomucin and human transferrin had no suppressing effect on basal hepatic delivery of iron from rat 2Fe-transferrin. The data suggest that deposition of a significant fraction of Fe in rat liver from rat transferrin is likely to take place by a mechanism not involving transferrin receptors. Desialylation shortened the metabolic half-life of rat transferrin from 33 to 24 h.(ABSTRACT TRUNCATED AT 250 WORDS)
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