Isolation of an iC3b forming enzyme from peritoneal polymorphonuclear leukocytes of guinea pigs

We have investigated fluid phase cleavage of C3b by peritoneal polymorphonuclear leukocytes of guinea pigs and found that polymorphonuclear leukocytes expressed an iC3b forming enzyme as well as C3b receptor with maturation in peritoneal cavity. The iC3b forming enzyme was found to be distinct from C3bINA, a physiological iC3b forming enzyme in plasma, since the activity was inhibited by monoiodoacetic acid and did not require a cofactor plasma protein, beta 1H, for the cleavage of C3b into iC3b. The iC3b forming enzyme is gradually released upon incubation of PMN at 37 degrees C. The molecular weight of the iC3b forming enzyme was estimated to be 48,000 from gel filtration on Sephadex G-200.     

Interaction of antitumor drugs with human erythrocyte ghost membranes and mastocytoma P815: a spin label study.

The cytotoxic and mutagenic properties of antitumor drugs such as adriamycin, acridines, diacridine, actinomycin D and Pt compounds are related to their interaction with nucleic acids and inhibition of protein synthesis. We have examined their interaction with human erythrocyte ghost membranes and murine mastocytoma cells using spin labeling techniques. These drugs induce changes in electron spin resonance of the spin labeled ghost membranes and in the mastocytoma cells. These alterations suggest that these drugs induce changes in protein conformation of the membranes. The membrane binding properties of these drugs may be important in their mechanism of action.     

Isolated epsilon subunit of Bacillus subtilis F1-ATPase binds ATP

Previously, we demonstrated ATP binding to the isolated epsilon subunit of F1-ATPase from thermophilic Bacillus PS3 [Kato-Yamada Y., Yoshida M. (2003) J. Biol. Chem. 278, 36013]. However, whether it is a general feature of the epsilon subunit from other sources is yet unclear. Here, using a sensitive method to detect weak interactions between fluorescently labeled epsilon subunit and nucleotide, it was shown that the epsilon subunit of F1-ATPase from Bacillus subtilis also bound ATP. The dissociation constant for ATP binding at room temperature was calculated to be 2 mM, which may be suitable for sensing cellular ATP concentration in vivo.     

Interaction of calmodulin with L-selectin at the membrane interface: implication on the regulation of L-selectin shedding

The calmodulin (CaM) hypothesis of ectodomain shedding stipulates that CaM, an intracellular Ca²⁺-dependent regulatory protein, associates with the cytoplasmic domain of l-selectin to regulate ectodomain shedding of l-selectin on the other side of the plasma membrane. To understand the underlying molecular mechanism, we have characterized the interactions of CaM with two peptides derived from human l-selectin. The peptide ARR18 corresponds to the entire cytoplasmic domain of l-selectin (residues Ala317-Tyr334 in the mature protein), and CLS corresponds to residues Lys280-Tyr334, which contains the entire transmembrane and cytoplasmic domains of l-selectin. Monitoring the interaction by fluorescence spectroscopy and other biophysical techniques, we found that CaM can bind to ARR18 in aqueous solutions or the l-selectin cytoplasmic domain of CLS reconstituted in the phosphatidylcholine bilayer, both with an affinity of approximately 2 μM. The association is calcium independent and dynamic and involves both lobes of CaM. In a phospholipid bilayer, the positively charged l-selectin cytoplasmic domain of CLS is associated with anionic phosphatidylserine (PS) lipids at the membrane interface through electrostatic interactions. Under conditions where the PS content mimics that in the inner leaflet of the cell plasma membrane, the interaction between CaM and CLS becomes undetectable. These results suggest that the association of CaM with l-selectin in the cell can be influenced by the membrane bilayer and that anionic lipids may modulate ectodomain shedding of transmembrane receptors.     

Ca(2+)-induced movement of tropomyosin in skeletal muscle thin filaments observed by multi-site FRET

To obtain information on Ca(2+)-induced tropomyosin (Tm) movement in Ca(2+)-regulated muscle thin filaments, frequency-domain fluorescence energy transfer data were collected between 5-(2-iodoacetyl-amino-ethyl-amino)naphthalene-1-sulfonic acid at Cys-190 of Tm and phalloidin-tetramethylrhodamine B isothiocyanate bound to F-actin. Two models were used to fit the experimental data: an atomic coordinate (AC) model coupled with a search algorithm that varies the position and orientation of Tm on F-actin, and a double Gaussian distance distribution (DD) model. The AC model showed that little or no change in transfer efficiency is to be expected between different sites on F-actin and Tm if Ca(2+) causes azimuthal movement of Tm of the magnitude suggested by structural data (C. Xu, R. Craig, L. Tobacman, R. Horowitz, and W. Lehman. 1999. Biophys. J. 77:985-992). However, Ca(2+) produced a small but significant change in our phase/modulation versus frequency data, showing that changes in lifetime decay can be detected even when a change of the steady-state transfer efficiency is very small. A change in Tm azimuthal position of 17 on the actin filament obtained with the AC model indicates that solution data are in reasonable agreement with EM image reconstruction data. In addition, the data indicate that Tm also appears to rotate about its axis, resulting in a rolling motion over the F-actin surface. The DD model showed that the distance from one of the two chains of Tm to F-actin was mainly affected, further verifying that Ca(2+) causes Tm to roll over the F-actin surface. The width of the distance distributions indicated that the position of Tm in absence and in presence of Ca(2+) is well defined with appreciable local flexibility.     

Role of Cys-295 on subunit interactions and allosteric regulation of phosphofructokinase-2 from Escherichia coli

In a previous work, chemical modification of Cys-238 of Escherichia coli Pfk-2 raised concerns on the importance of the dimeric state of Pfk-2 for enzyme activity, whereas modification of Cys-295 impaired the enzymatic activity and the MgATP-induced tetramerization of the enzyme. The results presented here demonstrate that the dimeric state of Pfk-2 is critical for the stability and the activity of the enzyme. The replacement of Cys-238 by either Ala or Phe shows no effect on the kinetic parameters, allosteric inhibition, dimer stability and oligomeric structure of Pfk-2. However, the mutation of Cys-295 by either Ala or Phe provokes a decrease in the k(cat) value and an increment in the K(m) values for both substrates. We suggest that the Cys-295 residue participates in intersubunit interactions in the tetramer since the Cys-295-Phe mutant exhibits higher tetramer stability, which in turn results in an increase in the fructose-6-P concentration required for the reversal of the MgATP inhibition relative to the wild type enzyme.     

Distances between the b-subunits in the tether domain of F0F1-ATP synthase from E. coli

The arrangement of the b-subunits in the holo-enzyme F₀F₁-ATP synthase from E. coli is investigated by site-directed mutagenesis spin-label EPR. F₀F₁-ATP synthases couple proton translocation with the synthesis of ATP from ADP and phosphate. The hydrophilic F₁-part and the hydrophobic membrane-integrated F₀-part are connected by a central and a peripheral stalk. The peripheral stalk consists of two b-subunits. Cysteine mutations are introduced in the tether domain of the b-subunit at b-40, b-51, b-53, b-62 or b-64 and labeled with a nitroxide spin label. Conventional (9 GHz), high-field (95 GHz) and pulsed EPR spectroscopy reveal: All residues are in a relatively polar environment, with mobilities consistent with helix sites. The distance between the spin labels at each b-subunit is 2.9 nm in each mutant, revealing a parallel arrangement of the two helices. They can be in-register but separated by a large distance (1.9 nm), or at close contact and displaced along the helix axes by maximally 2.7 nm, which excludes an in-register coiled-coil model suggested previously for the b-subunit. Binding of the non-hydrolysable nucleotide AMPPNP to the spin-labeled enzyme had no significant influence on the distances compared to that in the absence of nucleotides.     

Rapid screening of membrane topology of secondary transport proteins

Limited experimental data may be very useful to discriminate between membrane topology models of membrane proteins derived from different methods. A membrane topology screening method is proposed by which the cellular disposition of three positions in a membrane protein are determined, the N- and the C-termini and a position in the middle of the protein. The method involves amplification of the encoding genes or gene fragments by PCR, rapid cloning in dedicated vectors by ligation independent cloning, and determination of the cellular disposition of the three sites using conventional techniques. The N-terminus was determined by labeling with a fluorescent probe, the central position and the C-terminus by the reporter fusion technique using alkaline phosphatase (PhoA) and green fluorescence protein (GFP) as reporters. The method was evaluated using 16 transporter proteins of known function from four different structural classes. For 13 proteins a complete set of three localizations was obtained. The experimental data was used to discriminate between membrane topology models predicted by TMHMM, a widely used predictor using the amino acid sequence as input and by MemGen that uses hydropathy profile alignment and known 3D structures or existing models. It follows that in those cases where the models from the two methods were similar, the models were consistent with the experimental data. In those cases where the models differed, the MemGen model agreed with the experimental data. Three more recent predictors, MEMSAT3, OCTOPUS and TOPCONS showed a significantly higher consistency with the experimental data than observed with TMHMM.     

F-Actin Structure Destabilization and DNase I Binding Loop Fluctuations: Mutational Cross-Linking and Electron Microscopy Analysis of Loop States and Effects on F-Actin

The conformational dynamics of filamentous actin (F-actin) is essential for the regulation and functions of cellular actin networks. The main contribution to F-actin dynamics and its multiple conformational states arises from the mobility and flexibility of the DNase I binding loop (D-loop; residues 40-50) on subdomain 2. Therefore, we explored the structural constraints on D-loop plasticity at the F-actin interprotomer space by probing its dynamic interactions with the hydrophobic loop (H-loop), the C-terminus, and the W-loop via mutational disulfide cross-linking. To this end, residues of the D-loop were mutated to cysteines on yeast actin with a C374A background. These mutants showed no major changes in their polymerization and nucleotide exchange properties compared to wild-type actin. Copper-catalyzed disulfide cross-linking was investigated in equimolar copolymers of cysteine mutants from the D-loop with either wild-type (C374) actin or mutant S265C/C374A (on the H-loop) or mutant F169C/C374A (on the W-loop). Remarkably, all tested residues of the D-loop could be cross-linked to residues 374, 265, and 169 by disulfide bonds, demonstrating the plasticity of the interprotomer region. However, each cross-link resulted in different effects on the filament structure, as detected by electron microscopy and light-scattering measurements. Disulfide cross-linking in the longitudinal orientation produced mostly no visible changes in filament morphology, whereas the cross-linking of D-loop residues > 45 to the H-loop, in the lateral direction, resulted in filament disruption and the presence of amorphous aggregates on electron microscopy images. A similar aggregation was also observed upon cross-linking the residues of the D-loop (> 41) to residue 169. The effects of disulfide cross-links on F-actin stability were only partially accounted for by the simulations of current F-actin models. Thus, our results present evidence for the high level of conformational plasticity in the interprotomer space and document the link between D-loop interactions and F-actin stability.     

The beta4-beta8 groove is an ATP-interactive site in the alpha crystallin core domain of the small heat shock protein, human alphaB crystallin

The site for ATP interactions in human alphaB crystallin, the archetype of small heat-shock proteins, was identified and characterized to resolve the controversial role of ATP in the function of small heat-shock proteins. Comparative sequence alignments identified the alphaB crystallin sequence, (82)KHFSPEELKVKVLGD(96) as a Walker-B ATP-binding motif that is found in several ATP-binding proteins, including five molecular chaperones. Fluorescence resonance energy transfer and mass spectrometry using a novel fluorescent ATP analog, 8-azido-ATP-[gamma]-1-naphthalenesulfonic acid-5(2-aminoethylamide) (azido-ATP-EDANS) and a cysteine mutant of human alphaB crystallin (S135C) conjugated with a fluorescent acceptor, eosin-5-maleimide (EMA) identified the beta4-beta8 groove as the ATP interactive site in alphaB crystallin. A 44% decrease in the emitted fluorescence of azido-ATP-EDANS at the absorption maximum of S135C-EMA and a corresponding 50% increase in the fluorescence emission of S135C-EMA indicated a close spatial relationship between azido-ATP-EDANS and the center of the beta8 strand ((131)LTITSSLS(138)). Liquid chromatography, electrospray ionization mass spectrometry identified two peptide fragments of the alphaB crystallin Walker-B motif photo-affinity-labeled with azido-ATP-EDANS confirming the beta4-beta8 groove as an ATP interactive site. The results presented here clearly establish the beta4-beta8 groove as the ATP interactive region in alphaB crystallin, and are in contrast to the existing paradigm that classifies small heat-shock proteins as ATP-independent chaperones.