N A Swords scite author profile

The secondary structure of bacteriorhodopsin is known from electron-diffraction studies, making bacteriorhodopsin a useful test system for analysing environmental influences on membrane proteins using c.d. spectroscopy. The conformational effects of detergent solubilization and incorporation into vesicles of various types were determined by comparison of the calculated secondary structures derived from c.d. spectra with the structure determined from diffraction studies. In addition, two modified forms of the native purple membrane, a shrunken form of the hexagonal lattice and an orthorhombic lattice form, were used to determine the effects of varying membrane fragment size and protein concentration within the membranes. The two different vesicle incorporation procedures yielded bacteriorhodopsin spectra which were nearly identical with each other and very close to the structure calculated from electron-diffraction studies. Solubilization of the native protein in the non-ionic detergent n-octyl glucoside, without subsequent vesicle incorporation, resulted in a significantly altered protein conformation. Organizing the protein in different membrane lattices produced even more apparent deviations from the secondary structure determined by diffraction studies, as a consequence of optical effects caused by the high protein concentrations in the lattices. These studies show the importance of maintaining a 'native' environment, and the influence of particle geometry in interpreting c.d. studies of membrane proteins.

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Bone marrow accessory cells regulate human bone precursor cell development

Eipers

Kale

Taichman

et al. 2000

Experimental Hematology

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Intact platelet membranes, not platelet-released microvesicles, support the procoagulant activity of adherent platelets.

Swords

Tracy

Mann

1993

Arterioscler Thromb

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The possibility that platelets release microvesicles on adherence to either von Willebrand factor (vWf) or collagen was examined by flow cytometry analysis of the supernatant above layers of adherent platelets. No microvesicle release was detected as a result of adherence to vWf or to collagen, a known platelet agonist. Approximately 8% of the total platelet mass was released as microvesicles after thrombin stimulation of the vWf-or collagen-adherent platelets. A larger portion of the vWf-adherent platelet membranes (approximately 21%) was released as microvesicles subsequent to platelet stimulation with the nonphysiological agonist calcium ionophore A23187. Calpeptin, a calpain inhibitor, had no effect on microvesicle release, suggesting that calpain proteolysis of platelet cytoskeletal proteins was not responsible for microvesicle shedding under the conditions studied. Examination of the vWf-adherent platelets by scanning electron microscopy showed that virtually no microvesicles bound to exposed vWf multimers. No microvesicle binding to the adherent platelets was observed, indicating that the majority of the microvesicles were shed from the platelet and vWf surface on platelet activation. The ability of the microvesicle population to support procoagulant activity was measured with a prothrombinase activity assay and was compared with the activity supported by the adherent platelet membranes. More than 85% of the total prothrombinase activity remained associated with the adherent platelet membranes, both for unstimulated platelets and platelets stimulated with physiological agonists. Furthermore, the residual activity found in the buffer fraction containing detached platelets and any released microvesicles could be attributed to the detached platelets. No activity could be attributed to the microvesicles, as thrombin stimulation of either vWf-or collagen-adherent platelets did not promote increased procoagulant activity relative to the unstimulated adherent platelets, even though microvesicle release was detected as a result of agonist addition. Neither full platelet activation nor microvesicle shedding played an essential role in generating procoagulant activity in the adherent platelet system. (Arterioscler Thromb. 1993;13:1613 -1622.) KEY WORDS • microvesicles • platelets • procoagulant activity • prothrombinase complex

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The assembly of the prothrombinase complex on adherent platelets.

Swords

Mann

1993

Arterioscler Thromb

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Prothrombinase complex assembly, in real time, on platelets adherent to immobilized von Willebrand Factor (vWf) was examined by total internal reflection fluorescence spectroscopy (TIRFS). Electron microscopy showed that the platelets adhered to vWf in a largely unactivated state and could be activated by thrombin. Antibody binding to glycoprotein (GP) Ib and functional GPIIb-IIIa receptor molecules on adherent platelet membranes monitored by TIRFS also indicated that platelets adhered in a largely unactivated state. Maximal expression of the receptor form of GPIIb-IIIa detected by antibody binding was seen only after thrombin stimulation of the adherent platelets. Antibody binding to GPIb was detected on adherent platelets. A reduction in antibody binding was observed after thrombin stimulation of the platelets, indicating a change in GPIb as a consequence of thrombin stimulation of the platelets. The binding of the protein components of the prothrombinase complex to adherent and thrombin-stimulated adherent platelets was then studied individually. Factor Va bound to adherent and thrombin-stimulated adherent platelets with an estimated K a of 58 nmoI/L. Minimal factor Xa binding was observed on adherent platelets before thrombin stimulation. Factor Xa binding was, however, readily observed on thrombin-stimulated adherent platelets. This factor Xa binding was not saturable, and no K d value could be estimated. Direct measurement of prothrombinase complex assembly was demonstrated by using an energy transfer phenomenon between fluorescein-labeled factor Va and rhodamine-labeled factor Xa. Prothrombinase complex assembly was observed on both adherent and thrombin-stimulated adherent platelets. The estimated K A for the factor Va/factor Xa interaction was 4 nmol/L. TIRFS demonstrated that adherent platelets have the ability to support prothrombinase complex assembly, as shown by a direct energy transfer reaction between fluorescently labeled factors Va and Xa. (Arterioscler Thromb.

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N A Swords

Membrane-dependent reactions in blood coagulation: role of the vitamin K-dependent enzyme complexes

Circular-dichroism analyses of membrane proteins: examination of environmental effects on bacteriorhodopsin spectra

Bone marrow accessory cells regulate human bone precursor cell development

Intact platelet membranes, not platelet-released microvesicles, support the procoagulant activity of adherent platelets.

The assembly of the prothrombinase complex on adherent platelets.

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