Analysis of activation-induced conformational changes in p47phox using tryptophan fluorescence spectroscopy.

Activation of the neutrophil NADPH oxidase requires translocation of cytosolic proteins p47(phox), p67(phox), and Rac to the plasma membrane or phagosomal membrane, where they assemble with membrane-bound flavocytochrome b. During this process, it appears that p47(phox) undergoes conformational changes, resulting in the exposure of binding sites involved in assembly and activation of the oxidase. In the present study, we have directly evaluated activation-induced conformational changes in p47(phox) using tryptophan fluorescence and circular dichroism spectroscopy. Treatment of p47(phox) with amphiphilic agents known to activate the NADPH oxidase (SDS and arachidonic acid) caused a dose-dependent quenching in the intrinsic tryptophan fluorescence of p47(phox), whereas treatment with a number of other amphiphilic agents that failed to activate the oxidase had no effect on p47(phox) fluorescence. In addition, the concentration range of activating agents required to induce changes in fluorescence correlated with the concentration range of these agents that induced maximal NADPH oxidase activity in a cell-free assay system. We next determined if activation by phosphorylation caused the same type of conformational changes in p47(phox). Protein kinase C phosphorylation of p47(phox) in vitro resulted in comparable quenching of fluorescence, which also correlated directly with NADPH oxidase activity. Finally, the circular dichroism (CD) spectrum of p47(phox) was significantly changed by the addition of SDS, whereas treatment with a non-activating detergent had no effect on the CD spectrum. These results support the conclusion that activation by amphiphilic agents results in changes in the secondary structure of p47(phox). Thus, our studies provide direct evidence linking conformational changes in p47(phox) to the NADPH oxidase activation/assembly process and also further support the hypothesis that amphiphile-mediated activation of the NADPH oxidase induces changes in p47(phox) that are similar to those mediated by phosphorylation in vivo.

Inhibition of human factor VIIIa by anti-A2 subunit antibodies.

Human inhibitory alloantibodies and autoantibodies to Factor VIII (FVIII) are usually directed toward the A2 and/or C2 domains of the FVIII molecule. Anti-C2 antibodies block the binding of FVIII to phospholipid, but the mechanism of action of anti-A2 antibodies is not known. We investigated the properties of a patient autoantibody, RC, and a monoclonal antibody, 413, that bind to the region which contains the epitopes of all anti-A2 alloantibodies or autoantibodies studied to date. mAb 413 and RC were noncompetitive inhibitors of a model intrinsic Factor X activation complex (intrinsic FXase) consisting of Factor IXa, activated FVIII (FVIIIa), and synthetic phospholipid vesicles, since they decreased the Vmax of intrinsic FXase by > 95% at saturating concentrations without altering the Km. This indicates that RC and mAb 413 either block the binding of FVIIIa to FIXa or phospholipid or interfere with the catalytic function of fully assembled intrinsic FXase, but they do not inhibit the binding of the substrate Factor X. mAb 413 did not inhibit the increase in fluorescence anisotropy that results from the binding of Factor VIIIa to fluorescein-5-maleimidyl-D-phenylalanyl-prolyl-arginyl-FIXa (Fl-M-FPR-FIXa) on phospholipid vesicles in the absence of Factor X, indicating it does not inhibit assembly of intrinsic FXase. Addition of Factor X to Fl-M-FPR-FIXa, FVIIIa, and phospholipid vesicles produced a further increase in fluorescence anisotropy and a decrease in fluorescence intensity. This effect was blocked completely by mAb 413. We conclude that anti-A2 antibodies inhibit FVIIIa function by blocking the conversion of intrinsic FXase/FX complex to the transition state, rather than by interfering with formation of the ground state Michaelis complex.

Isolation and characterization of thrombin-activated human factor VIII.

Recombinant human factor VIII (fVIII) was activated by thrombin at pH 7.4, followed by CM-Sepharose chromatography at pH values ranging from 3.5 to 7.4. Optimal coagulant activity was recovered at pH 5.5 and was associated with the isolation of an A1/A2/A3-C1-C2 heterotrimer. The activity was stable at -80 degrees C, but decayed slowly (t1/2 approximately 1 week) and nonproteolytically at room temperature or 4 degrees C. The coagulant activity of the pH 5.5 fVIIIa preparation assayed in human hemophilia A plasma was only 20% that of porcine factor VIIIa. However, its activity was approximately 75% that of porcine fVIIIa in a plasma-free assay, indicating that human fVIIIa is unstable relative to porcine fVIIIa during the coagulation assay. The first-order rate constant for spontaneous, nonproteolytic loss of activity of human fVIIIa at pH 7.4 was decreased 8-fold by fIXa and phospholipid, indicating that human fVIIIa is stabilized when incorporated into the intrinsic pathway factor X activation complex.

NMR constrained solution structures for laminin peptide 11. Analogs define structural requirements for inhibition of tumor cell invasion of basement membrane matrix.

Peptide 11, CDPGYIGSR-NH2, is a segment of laminin which blocks tumor cell invasion. A high affinity laminin receptor in tumor cells is thought to be blocked by the carboxyl-terminal YIGSR, and conformational energy calculations suggest that the glycine in YIGSR allows an important conformational bend. We replaced the YIGSR glycine residue in peptide 11 with either D-alanine or L-alanine to allow or disfavor the proposed glycine bend. We found the Gly7-->D-Ala7 analog to be equal to peptide 11 in inhibiting tumor cell invasion of basement membrane matrix. The Gly7-->L-Ala7 analog was much less capable of invasion inhibition. Two-dimensional 1H-1H NMR was used to study the solution conformations of the peptide 11 analogs. NOESY experiments revealed close NH-NH contacts in peptide 11 and the D-Ala7 analog, but not in the L-Ala7 analog. Molecular dynamics generated low energy structures with excellent NOE agreement for peptide 11 and its analogs. Both peptide 11 and the D-Ala7 analog, but not the less active L-Ala7 analog, were predicted to have similar bends around Gly7 or D-Ala7. These results suggest that a bend in the YIGSR region of peptide 11 may be important for the binding of laminin to its metastasis-associated receptor.

The transverse location of the retinal chromophore in the purple membrane by diffusion-enhanced energy transfer.

We have used fluorescence energy transfer in the rapid-diffusion limit (RDL) to estimate the trans-membrane depth of retinal in the purple membrane (PM). Chelates of Tb(III) are excellent energy donors for the retinal chromophore of PM, having a maximum Ro value for Förster energy transfer of approximately 62 A (assuming a donor quantum yield of 1). Energy transfer rates were measured from the time-resolved emission kinetics of the donor. The distance of closest approach between chelates and the chromophore was estimated by simulating RDL energy-transfer rate constants according to geometric models of either PM sheets or membrane vesicles. The apparent rate constant for RDL energy transfer between Tb(III)HED3A and retinal in PM sheets is 1.5(+/- 0.1) x 10(6) M-1 s-1, corresponding to a depth of approximately 10 +/- 2 A for the retinal chromophore. Cell envelope vesicles (CEVs) from Halobacterium halobium were studied by using RDL energy transfer to assess the proximity of retinal to either the extracellular or intracellular face of the PM. The estimated depth of retinal from the extravesicular face of the PM is 10 +/- 3 A, based on the RDL energy-transfer rate constant. Energy-transfer levels to retinal in the PM were estimated by an indirect method with energy donors trapped in the inner-aqueous space of CEVs. The rate constants derived for this arrangement are too low to be consistent with the shortest depth of retinal deduced for PM sheets. Thus, the intravesticular face of CEVs, corresponding to the cytoplasmic face of cells, is the more distant surface from the chromophore of bacteriorhodopsin.

Isoelectric focusing studies of bacteriorhodopsin.

Purified bacteriorhodopsin (BR) samples show a minimum of four isoelectric forms in immobilized pH gradient isoelectric focusing gels. The bands occur as doublets with isoelectric points (pI) centered at 5.20 (principal species) and 5.60. In typical preparations additional bands may be observed at 4.90, 5.07 and 5.50. Purple membrane (PM) was proteolyzed with papain to calibrate the pI shift produced by changing the number of charges on the protein. Asp-242 is removed during the first cleavage between residues 239 and 240 resulting in the loss of a single negative charge and a shift of the principal doublet by +0.35 pH units to pI 5.55. The second papain cleavage occurs between residues 231 and 232 which removes Glu-232, -234 and -237 and shifts the pI by +0.60 pH units to pI 6.10. The +0.60 pH shift upon the second papain cleavage is consistent with the loss of two negative charges and is supported by prior evidence that at least one of the three glutamate residues lost during the second proteolysis step is protonated and neutral in the intact protein. The native and proteolyzed products of BR retain the characteristic 550 nm absorption maxima for solubilized BR. A model for the structural origin of the pI heterogeneity of BR species in proteolyzed PM is presented.

Synthetic peptides derived from fibrinogen and fibronectin change the conformation of purified platelet glycoprotein IIb-IIIa.

The glycoprotein IIb-IIIa complex (GP IIb-IIIa) is a platelet cell-surface receptor for fibrinogen and fibronectin. A carboxyl-terminal decapeptide of the fibrinogen gamma-chain (Leu-Gly-Gly-Ala-Lys-Gln-Ala-Gly-Asp-Val LGGAKQAGDV] and a tetrapeptide (Arg-Gly-Asp-Ser (RGDS] from the fibrinogen alpha-chain and the fibronectin cell-binding domain appear to mediate the binding of these ligands to GP IIb-IIIa. The present study was designed to examine the effects of these and related peptides on the structure of purified platelet GP IIb-IIIa. Treatment of GP IIb-IIIa with various synthetic peptides affected the glycoprotein so that GP IIb alpha became a substrate for hydrolysis by thrombin. The order of potency of these peptides was as follows: RGDS greater than LGGAKQAGDV greater than KGDS greater than RGES. This is the same order of potency in which these peptides inhibit fibrinogen binding to platelets. This effect was time-, temperature-, and concentration-dependent; RGDS induced a half-maximal effect at approximately 60 microM. In addition, RGDS, but not RGES, decreased the intensity of the intrinsic protein fluorescence of GP IIb-IIIa. Finally, the decapeptide or RGDS decreased the sedimentation coefficient of GP IIb-IIIa from 8.5 to 7.7 or 7.4 S, respectively, whereas RGES had a minimal effect. This decrease was accompanied by an increase in the Stoke's radius from 74 to 82 A with RGDS or 85 A with the decapeptide, indicating a peptide-induced unfolding of the GP IIb-IIIa complex. This change in conformation may be related to changes in the distribution and function of GP IIb-IIIa on the platelet surface that occur when adhesive proteins or peptides from the GP IIb-IIIa binding domains of these proteins bind to GP IIb-IIIa.

Coupling between the bacteriorhodopsin photocycle and the protonmotive force in Halobacterium halobium cell envelope vesicles. III. Time-resolved increase in the transmembrane electric potential and modeling of the associated ion fluxes.

Bacteriorhodopsin functions as an electrogenic, light-driven proton pump in Halobacterium halobium. In cell envelope vesicles, its photocycle kinetics can be correlated with membrane potential. The initial decay rate of the M photocycle intermediate(s) decreases with increasing membrane potential, allowing the construction of a calibration curve. The laser (592.5 nm) was flashed at various time delays following the start of background illumination (592 +/- 25 nm) and transient absorbance changes at 418 nm monitored in cell envelope vesicles. The vesicles were loaded with and suspended in either 3 M NaCl or 3 M KCl buffered with 50 mM HEPES at pH 7.5 and the membrane permeability to protons modified by pretreatment with N,N'-dicyclohexylcarbodiimide. In each case the membrane potential rose with a halftime of approximately 75 ms. The steady-state potential achieved depends on the cation present and the proton permeability of the membrane, i.e., higher potentials are developed in dicyclohexylcarbodiimide treated vesicles or in NaCl media as compared with KCl media. The results are modeled using an irreversible thermodynamics formulation, which assumes a constant driving reaction affinity (Ach) and a variable reaction rate (Jr) for the proton-pumping cycle of bacteriorhodopsin. Additionally, the model includes a voltage-gated, electrogenic Na+/H+ antiporter that is active when vesicles are suspended in NaCl. Estimates for the linear phenomenological coefficients describing the overall proton-pumping cycle (Lr = 3.5 X 10(-11)/mol2/J X g X s), passive cation permeabilities (LHu = 2 X 10(-10), LKu = 2.2 X 10(-10), LNau = 1 X 10(-11)), and the Na+/H+ exchange via the antiporter (Lex = 5 X 10(-11)) have been obtained.

Transient proton inflows during illumination of anaerobic Halobacterium halobium cells.

In Halobacterium halobium strain R1 containing both bacteriorhodopsin (bR) and halorhodopsin (hR), the light-driven proton uptake has been experimentally resolved into three transient inflows which are superimposed on the larger proton outflow. Under anaerobic conditions the early proton uptake consists of two components: (i) an inflow which can be blocked using the ATPase inhibitor, Dio-9, and (ii) an inflow which can be abolished by low concentrations (less than 125 nM) of triphenyltin chloride (TPT) with no inhibition of ATP synthesis. At pH 6 these two inflows are approximately equal in magnitude and duration. Measurements of buffering capacity and internal pH indicate that Dio-9 does not alter the passive proton-hydroxyl permeability of the cell membrane and that TPT at these low concentrations slightly decreases it. At later times of illumination (iii) another transient light-driven proton inflow occurs. This inflow is most evident during the first illumination after cells have been stored for extended times in the dark. The internal potassium concentration is not changed by storage, but apparently sodium is taken up, and we attribute the third inflow to sodium extrusion in exchange for protons. These results demonstrate the existence of three distinct triggered secondary proton inflows through the cell membrane. The proton inflow, which can be inhibited by Dio-9, correlates with proton-dependent ATP synthesis. The second inflow, which disappears in the presence of low TPT concentrations, is a passive proton uptake through an otherwise unidentified channel in response to electrogenic chloride pumping by bacteriorhodopsin and/or halorhodopsin. The third system correlates with the Na+/H+ antiporter function that has been demonstrated in H. halobium cell envelope vesicles. In contrast to observations on hR-containing vesicles, which can develop substantial Cl- gradients, the electroneutral OH-/Cl- exchange function can be demonstrated in intact cells only at TPT concentrations greater than 500 nM.

Coupling between the bacteriorhodopsin photocycle and the protonmotive force in Halobacterium halobium cell envelope vesicles. II. Quantitation and preliminary modeling of the M----bR reactions.

The cell membrane of Halobacterium halobium (H. halobium) contains the proton-pump bacteriorhodopsin, which generates a light-driven transmembrane protonmotive force. The interaction of the bacteriorhodopsin photocycle with the electric potential component of the protonmotive force has been investigated. H. halobium cell envelope vesicles have been prepared by sonication and further purified by ultracentrifugation on Ficoll/NaCl/CsCl density gradients. Under continuous illumination (550 +/- 50 nm) varied from 0 to 40 mW cm-2, the vesicles maintain a membrane potential of 0 to -100 mV. The membrane potential was measured by flow dialysis of 3H-TPMP+ uptake and could be abolished by the uncoupler carbonylcyanide-m-chlorophenylhydrazone. Time-resolved absorption spectroscopy was used to measure the decay kinetics of the M photocycle intermediate, which was initiated by a weak laser flash (588 nm), while the vesicles were continuously illuminated as above. The M decay kinetics were fitted with two exponential decays by a computer deconvolution program. The faster decaying form decreases in amplitude (70 to 10% of the total) and the slower decaying form increases in amplitude and lifetime (23 to 42 ms) as the background light intensity increases. Although any correlation between the membrane potential and the bacteriorhodopsin photocycle M-forms is complex, the present data will allow specific tests of the physical mechanism for this interaction to be designed and conducted.

The present state of the chemiosmotic coupling theory.

Although the general principles of the chemiosmotic coupling theory have become widely accepted, the (degree of) loc(aliz)ation of electrochemical proton potential difference cannot yet be deduced from the existing experimental data. Many results are not in ready accordance with the idea that one protonic electrochemical potential difference, i.e. the one between a homogeneous inner and a homogeneous outer aqueous phase, would be the high-free-energy intermediate of membrane-linked free-energy transduction. Rather, free-energy transduction in an organelle like a mitochondrion or a chloroplast might take place in large number (about 1 per H+-ATPase) of miniature chemiosmotic systems. The energized protons produced in such a miniature system might be largely (but not totally) confined to a proton-domain belonging to it. Hence, there might be many (rather than one) different relevant proton gradients.

An evaluation of N-phenyl-1-naphthylamine as a probe of membrane energy state in Escherichia coli.

Colicin El and the uncoupler of oxidative phosphorylation, trifluoromethoxy-carbonylcyanidephenylhydrazone (FCCP), cause an increase in the fluorescence intensity of N-phenyl-1-naphthylamine bound to whole cells of Escherichia coli. It has been shown elsewhere that this fluorescence increase correlates well with de-energization. Addition of glucose causes a large cyanide-sensitive decrease of intensity, tentatively associated with energization, with the emission spectrum almost returning to the original trace with a peak at 417 nm. These data suggest that there may be a measurable competition between de-energization and energization of the cell membrane, and that the probe fluorescence intensity may be a general indicator of membrane energy level. The conclusions reached about cellular energy level from measurements of the probe fluorescence intensity correlate partly (a, b below, not c) with the energy level assayed physiologically through rates of active transport; (a) FCCP is found to be a poor inhibitor of proline transport if cells are first incubated with glucose, showing eutger cinpetition between the processes of energization and de-energization or an increase in the envelope permeability barrier to FCCP caused by glucose addition. (b) Cyanide blocks the fluorescence decrease caused by glucose and inhibits proline and serine transport, consistent with the decrease in probe fluorescence intensity indicating an increase in membrane energization. However, (c) it appears that the amplitude of the fluorescence intensity decrease caused by glucose addition in the presence of FCCP and colicin E1 greatly exaggerates the extent of real membrane energization. Glucose added after uncoupler can cause only a small increase, and after colicin, a negligible increase in the proline transport rate, indicating that the magnitude of the fluorescence intensity decrease after glucose addition is not a true measure of membrane energization, but rather seems to amplify this energization greatly. Glucose addition does not cause a decrease in fluorescence intensity in cells treated with EDTA to remove lipopolysaccharide and an apparent barrier to the probe. The rotational relaxation time of the probe in intact cells appears to correlate somewhat better with the cellular energy level than does intensity.

Changes in rotational motion of a cell-bound fluorophore caused by colicin E1: a study by fluorescence polarization and differential polarized phase fluorometry.

The stationary fluorescence polarization and the differential phase delay of the polarized components of the fluorescence of 1-phenylnaphthylamine in Escherichia coli suspensions were measured before and after addition of colicin E1. Both sets of measurements register an increase in the rotational relaxation time of the fluorescent probe when colicin is present. These increases are absent in an E. coli mutant tolerant to colicin E1. The physical interpretation of the changes demands separate estimation of the fraction f2 of the emitting fluorophores that change their properties upon colicin addition and of the rotational relaxation time p2 of this fraction, following the colicin-induced changes. By themselves, the steady state polarizaiton observations permit only the conclusion that f2 must be in the range of 1-0.06 and the change in p2/pi between 1.5 and a value larger than 10. Combination of the data of stationary polarization with those of differential phase fluorometry results in an important reduction in the uncertainty:f2 must be in the range 1-0.33 and the change in p2/pi in the range 1.5-2.5.

Evidence for an increase in microviscosity of plasma membranes from soybean hypocotyls induced by the plant hormone, indole-3-acetic Acid.

The plant hormone indole-3-acetic acid (IAA or auxin) added at a concentration for half-maximal promotion of cell elongation (1 mum) caused an increase of 25% in the fluorescence polarization of the membrane-bound probe N-phenyl-1-naphthylamine, when added to fractions enriched in plasma membranes from soybean hypocotyls (Glycine max L. var. Wayne), with no measurable change in fluorescence lifetime. The amplitude of the polarization increase was maximal in the temperature range 12 to 22 C. The findings provide evidence for a cell-free response of isolated plasma membranes to the hormone and imply that the response involves an increase in the microviscosity of hydrocarbon regions of the membrane.

Changes in E. coli cell envelope structure caused by uncouplers of active transport and colicin E1.

It is of interest to inquire whether agents that uncouple or deenergize membranes cause concomitant structural changes. The agents considered here are the uncoupler carbonyl cyanide-p-trifluoromethoxyphenylhydrazone and the bacteriocidal protein colicin E1, agents for which there is some precedent for believing that they interact with membranes. In intact E. coli ML 308-225 cells the inhibition of [14C]-PROLINE ACtive transport by FCCP increases with uncoupler concentration from approximately 20% at 2 muM to approximately 100% at 5 muM. The increase in the rotational relaxation time (rho) of the cell-bound fluorescent probe N-phenyl-1-naphthylamine (PhNap)1 and 8-anilino-1-naphthalene-sulfonate (ANS) under these conditions shows the same dependence on FCCP concentration. For cells treated with EDTA to remove part of the outer lipopolysaccharide layer, inhibition of proline transport and the increase in rho value of ANS show the same dependence on FCCP concentration with saturation at 0.3 muM. EDTA treatment causes a large increase in the binding and rotational relaxation time of PhNap, the latter quantity approaching a value obtained with purified inner membrane. Similar effects are produced in untreated cells by 5muM FCCP...