A helical twist-induced conformational switch activates cleavage in the hammerhead ribozyme

We have captured the structure of a pre-catalytic conformational intermediate of the hammerhead ribozyme using a phosphodiester tether formed between I and Stem II. This phosphodiester tether appears to mimic interactions in the wild-type hammerhead RNA that enable switching between nuclease and ligase activities, both of which are required in the replicative cycles of the satellite RNA viruses from which the hammerhead ribozyme is derived. The structure of this conformational intermediate reveals how the attacking nucleophile is positioned prior to cleavage, and demonstrates how restricting the ability of Stem I to rotate about its helical axis, via interactions with Stem II, can inhibit cleavage. Analogous covalent crosslinking experiments have demonstrated that imposing such restrictions on interhelical movement can change the hammerhead ribozyme from a nuclease to a ligase. Taken together, these results permit us to suggest that switching between ligase and nuclease activity is determined by the helical orientation of Stem I relative to Stem II.     

Structural basis for innate immune sensing by M-ficolin and its control by a pH-dependent conformational switch

Ficolins are soluble oligomeric proteins with lectin-like activity, assembled from collagen fibers prolonged by fibrinogen-like recognition domains. They act as innate immune sensors by recognizing conserved molecular markers exposed on microbial surfaces and thereby triggering effector mechanisms such as enhanced phagocytosis and inflammation. In humans, L- and H-ficolins have been characterized in plasma, whereas a third species, M-ficolin, is secreted by monocytes and macrophages. To decipher the molecular mechanisms underlying their recognition properties, we previously solved the structures of the recognition domains of L- and H-ficolins, in complex with various model ligands (Garlatti, V., Belloy, N., Martin, L., Lacroix, M., Matsushita, M., Endo, Y., Fujita, T., Fontecilla-Camps, J. C., Arlaud, G. J., Thielens, N. M., and Gaboriaud, C. (2007) EMBO J. 24, 623-633). We now report the ligand-bound crystal structures of the recognition domain of M-ficolin, determined at high resolution (1.75-1.8 A), which provides the first structural insights into its binding properties. Interaction with acetylated carbohydrates differs from the one previously described for L-ficolin. This study also reveals the structural determinants for binding to sialylated compounds, a property restricted to human M-ficolin and its mouse counterpart, ficolin B. Finally, comparison between the ligand-bound structures obtained at neutral pH and nonbinding conformations observed at pH 5.6 reveals how the ligand binding site is dislocated at acidic pH. This means that the binding function of M-ficolin is subject to a pH-sensitive conformational switch. Considering that the homologous ficolin B is found in the lysosomes of activated macrophages (Runza, V. L., Hehlgans, T., Echtenacher, B., Zahringer, U., Schwaeble, W. J., and Mannel, D. N. (2006) J. Endotoxin Res. 12, 120-126), we propose that this switch could play a physiological role in such acidic compartments.     

pH-dependent conformational changes in thrombocyte proteins

A study was made of the medium pH influence on structural states of platelets by optical methods. Within the pH range (6-8), two pH induced reversible changes of platelet state were observed. A conclusion is made that the structural rearrangements in platelets induced in the medium by changes in hydrogen ion concentration may involve some rearrangements in platelet proteins, and thus acting as a factor regulating platelet function.     

pH-dependent conformational changes of wheat germ calmodulin

Fluorescence energy transfer measurements were carried out between landmarks on wheat germ calmodulin to measure the interdomain distance. Tb3+ ions bound at the four Ca2+-binding sites were used as energy donors, and an organic chromophore, [4-(dimethylamino)-phenyl-4'-azophenyl]maleimide, attached to the single cysteine residue at position 27, was used as the acceptor. At pH's near neutrality all bound Tb3+ ions emit luminescence with shortened lifetimes as a result of energy transfer to the acceptor; at pH 5, however, part of the metal emission becomes unquenched. When the protein is subjected to limited digestion with trypsin in the presence of Ca2+, resulting in the formation of two fragments, each corresponding to half of the molecule, the decay of Tb3+ emission is no longer pH sensitive. These results suggest that, like rabbit skeletal troponin C [Wang, C.-L. A., Zhan, Q., Tao, T., & Gergely, J. (1987) J. Biol. Chem. 257, 8372-8375], wheat germ calmodulin exists in a relatively compact conformation at neutral pH's, but becomes more elongated at pH 5.     

The pH-dependent conformational change of diphtheria toxin

Labeling by a hydrophobic photoactivatable reagent and limited proteolysis have been used to study conformational changes of diphtheria toxin related to its pH-dependent membrane insertion and translocation. TID (3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine) labels diphtheria toxin at pH 5 much more efficiently than at pH 7, both in the presence and absence of lipid vesicles. In the absence of membranes, the extent of labeling is greater and the pH dependence is stronger. As analyzed on sodium dodecyl sulfate-polyacrylamide gels and by high pressure liquid chromatography, both the A- and B-subunits and most of the cyanogen bromide fragments of the toxin are labeled by TID at acid pH. The products of trypsin cleavage of diphtheria toxin at pH 5 are different from those seen at neutral pH. Trypsin-susceptible sites were identified by gel electrophoresis of the trypsin fragments, combined with electrophoresis and high pressure liquid chromatography of CNBr digests of trypsin-treated toxin. At neutral pH, the main sites of digestion are at the junction between the A- and B-fragments and near the NH2 terminus of the A-fragment. At pH 5.2, these sites are less efficiently cut, and new sites appear near the NH2 terminus of the B-fragment, in an amphipathic portion of the sequence. Thus, even in the absence of membranes, acid pH induces a significant conformational change in diphtheria toxin. This change involves burial of some previously accessible sites, exposure of previously inaccessible sites, and the formation of hydrophobic regions over an extensive portion of the polypeptide chain.     

pH-dependent conformational flexibility within the ribosomal peptidyl transferase center.

A universally conserved adenosine, A2451, within the ribosomal peptidyl transferase center has been proposed to act as a general acid-base catalyst during peptide bond formation. Evidence in support of this proposal came from pH-dependent dimethylsulfate (DMS) modification within Escherichia coli ribosomes. A2451 displayed reactivity consistent with an apparent acidity constant (pKa) near neutrality, though pH-dependent structural flexibility could not be rigorously excluded as an explanation for the enhanced reactivity at high pH. Here we present three independent lines of evidence in support of the alternative interpretation. First, A2451 in ribosomes from the archaebacteria Haloarcula marismortui displays an inverted pH profile that is inconsistent with proton-mediated base protection. Second, in ribosomes from the yeast Saccharomyces cerevisiae, C2452 rather than A2451 is modified in a pH-dependent manner. Third, within E. coli ribosomes, the position of A2451 modification (N1 or N3 imino group) was analyzed by testing for a Dimroth rearrangement of the N1-methylated base. The data are more consistent with DMS modification of the A2451 N1, a functional group that, according to the 50S ribosomal crystal structure, is solvent inaccessible without structural rearrangement. It therefore appears that pH-dependent DMS modification of A2451 does not provide evidence either for or against a general acid-base mechanism of protein synthesis. Instead the data suggest that there is pH-dependent conformational flexibility within the peptidyl transferase center, the exact nature and physiological relevance of which is not known.     

pH-dependent conformational states of horse liver alcohol dehydrogenase.

The quenching of liver alcohol dehydrogenase protein fluorescence at alkaline pH indicates two conformational states of the enzyme with a pKa of 9.8+/-0.2, shifted to 10.6+/-0.2 in D2O. NAD+ and 2-p-toluidinonaphthalene-6-sulfonate, a fluorescent probe competitive with coenzyme, bind to the acid conformation of the enzyme. The pKa of the protein-fluorescence quenching curve is shifted toward 7.6 in the presence of NAD+, and the ternary complex formation with NAD+ and trifluoroethanol results in a pH-independent maximal quench. At pH (pD) 10.5, the rate constant for NAD+ binding was 2.6 times faster in D2O2 than in H2O due to the shift of the pKa. Based on these results, a scheme has been proposed in which the state of protonation of an enzyme functional group with a pKa of 9.8 controls the conformational state of the enzyme. NAD+ binds to the acid conformation and subsequently causes another conformational change resulting in the perturbation of the pKa to 7.6. Alcohol then binds to the unprotonated form of the functional group with a pKa of 7.6 in the binary enzyme-NAD+ complex and converts the enzyme to the alkaline conformation. Thus, at neutral pH liver alcohol dehydrogenase undergoes two conformational changes en route to the ternary complex in which hydride transfer occurs.     

Ionic-strength- and pH-dependent conformational states of human plasma fibronectin

In order to provide a more detailed understanding of human plasma fibronectin (PFn) solution structure, we examined the effects of pH and ionic strength (mu) variation on the sedimentation velocities (s20,w), fluorescence polarization-derived mean harmonic rotational relaxation times (rho H), far-ultraviolet (UV) circular dichroism (CD), and intrinsic tryptophan fluorescence of dimeric PFn and the monomeric 190/170-kDa PFn fragment. By comparing the biophysical properties of PFn with those of the 190/170-kDa PFn fragment, we could assess the relative importance of intrasubunit and intersubunit electrostatic forces in the stabilization of PFn structure. The rho H derived from isothermal polarization measurements on 1-pyrenebutyrate conjugated PFn decreased markedly (4.5----1.05-1.23 microseconds) when mu was increased from 0.2 to 1.2 or when the pH was adjusted from 7.4 to 2.0 or 11.0. We also noted a significant decrease in the PFn s20,w (13----8.5-9.6S) under these same solvent conditions. In contrast, the rho H and s20,w of the monomeric 190/170-kDa PFn fragment were relatively insensitive to changes in mu or pH. Computer simulations of the observed pH-dependent changes in the far-UV CD of PFn and the 190/170-kDa PFn fragment revealed only minor differences in protein secondary structure. We also observed only small bathochromic shifts (1-3 nm) in the emission maxima of PFn and 190/170-kDa PFn fragment tryptophan fluorescence under acidic or high mu conditions. These results suggest that minimal changes in PFn tertiary (i.e., intrasubunit) structure occur at pH 2, 11, or at mu = 1.2.(ABSTRACT TRUNCATED AT 250 WORDS)     

The pH-dependent conformational transition of beta-lactoglobulin modulates the binding of protoporphyrin IX

We have investigated the interaction between PPIX and beta-lactoglobulin (beta-lg) as a function of the pH of the solution. beta-lg is a small globular protein (MW approximately 18 kDa) with a very well characterized structure that reveals several possible binding sites for ligands. The interaction with beta-lg affects the photophysical properties of PPIX. The shift of PPIX emission maximum, excitation maximum and the increase of the fluorescence intensity is an indicator that binding between the porphyrin and beta-lg occurs. The binding constant appears to be modulated by the pH of the solution. Spectroscopic measurements do not reveal any significant energy transfer between the Trp residues of beta-lg and PPIX, however, fluorescence anisotropy decay measurements confirm the binding and the modulation introduced by the pH of the solution. Since beta-lg has been shown to be stable within the range of pH adopted in our experiments (5.0-9.0), the results suggest that PPIX binds a site affected by the pH of the solution. Because of the crystallographic evidence an obvious site is near the aperture of the interior beta-barrel however an alternative (or concurrent) binding site may still be present.