Fábio Casallanovo

Properties of St I and St II, two isotoxins isolated from Stichodactyla helianthus: a comparison.

Sticholysins I and II are two highly hemolytic polypeptides purified from the Caribbean Sea anemone Stichodactyla helianthus. Their high sequence homology (93%) indicates that they correspond to isoforms of the same hemolysin. The spectroscopic measurements show a close similarity in the secondary structure content, conformation and stability of both toxins. Exposure of the toxins to high pHs (>11), a free radical source (AAPH), urea or temperature produce permanent changes in the toxin that lead to a significant loss of HA. It is significant to note that this loss of hemolytic activity occurs when other indicators, probably with the only exception of near-UV CD spectra, barely detect changes in the protein structure. This emphasizes the sensitivity of the protein function to changes in the macromolecule conformation. The most noticeable difference between both toxins is the considerably higher activity of St II, both measured in terms of erythrocyte internal K(+) exit or hemolysis; which is related to enthalpic factors. This difference is not due to an incomplete association of St I to the membrane. We consider then that the different pore forming capacity of both toxins in erythrocytes can be explained in terms of the difference in charge of the N-terminal fragment, than can considerably reduce the St I insertion rate in the membrane probably due to the negatively charged outer leaflet of the red blood cell, without a significant reduction of its capacity to bind to the cell membrane. This electrostatic effect, together with a slightly more relaxed structure in St II, could explain the higher pore forming capacity of St II in the red blood cell membrane.

Binding of sea anemone pore-forming toxins sticholysins I and II to interfaces--modulation of conformation and activity, and lipid-protein interaction.

Sticholysins I and II (St I and St II) are water-soluble toxins produced by the sea anemone Stichodactyla helianthus. St I and St II bind to biological and model membranes containing sphingomyelin (SM), forming oligomeric pores that lead to leakage of internal contents. Here we describe functional and structural studies of the toxins aiming at the understanding at a molecular level of their mechanism of binding, as well as their effects on membrane permeabilization. St I and St II caused potassium leakage from red blood cells and temperature-dependent hemolysis, the activation energy of the process being lower for the latter toxin. Protein intrinsic fluorescence measurements provided evidence for toxin binding to model membranes composed of 1:1 (mol:mol) egg phosphatidyl choline (ePC):SM. The fluorescence intensity increased and the maximum emission wavelength decreased as a result of binding. The changes were quantitatively different for both toxins. Circular dichroism spectra showed that both St I and St II exhibit a high content of beta-sheet structure and that binding to model membranes did not alter the toxins conformation to a large extent. Changing the lipid composition by adding 5 mol% of negatively charged phosphatidic acid (PA) or phosphatidyl glycerol (PG) had small, but detectable, effects on protein conformation. The influence of lipid composition on toxin-induced membrane permeabilization was assessed by means of fluorescence measurements of calcein leakage. The effect was larger for ePC:SM bilayers containing 5 mol% of negative curvature-inducing lipids. Electron paramagnetic resonance (EPR) spectra of intercalated fatty acid spin probes carrying the nitroxide moiety at different carbons (5, 7, 12, and 16) evidenced the occurrence of lipid-protein interaction. Upon addition of the toxins, two-component spectra were observed for the probe labeled at C-12. The broader component, corresponding to a population of strongly immobilized spin probes, was ascribed to boundary lipid. The contribution of this component to the total spectrum was larger for St II than for St I. Moreover, it was clearly detectable for the C-12-labeled probe, but it was absent when the label was at C-16, indicating a lack of lipid-protein interaction close to the lipid terminal methyl group. This effect could be either due to the fact that the toxins do not span the whole bilayer thickness or to the formation of a toroidal pore leading to the preferential interaction with acyl chain carbons closer to the phospholipids head groups.

Effect of pH on the conformation, interaction with membranes and hemolytic activity of sticholysin II, a pore forming cytolysin from the sea anemone Stichodactyla helianthus

Sticholysin II (St II) is a pore forming cytolysin obtained from the sea anemone Stichodactyla helianthus. Incubation of diluted St II solutions at different pHs (ranging from 2.0 to 12) slightly changes the secondary structure of the protein. These changes are particularly manifested at high pH. Similarly, the intrinsic fluorescence of the protein indicates a progressive opening of the protein structure when the pH increases from acidic (2.0) to basic (12). These modifications are only partially reversible and do not produce any significant increase in the small capacity of the protein to bind hydrophobic dyes (ANS or Prodan). Experiments carried out with model membranes show a reduced capacity of binding to egg phosphatidyl choline:sphingomyelin (1:1) liposomes both at low (2.3) and high (11.5) pH. Preincubation of the protein in the 2. 5-9.0 pH range does not modify its hemolytic activity, measured in human red blood cells at pH 7.4. On the other hand, preincubation at pH 11.5 drastically reduces the hemolytic activity of the toxin. This strong reduction takes place without measurable modification of the toxin ability to be adsorbed to the red blood cell surface. This indicates that preincubation at high pH irreversibly reduces the capacity of the toxin to form pores without a significant decrease in its binding capacity. The present results suggest that at pH > or = 10 St II experiences irreversible conformational changes that notably reduce its biological activity. This reduced biological activity is associated with a partial defolding of the protein, which seems to contradict what is expected in terms of a molten globule formalism.

Effects of sodium dodecyl sulfate on the conformation and hemolytic activity of St I and St II, two isotoxins purified from Stichodactyla helianthus.

The effect of sodium dodecyl sulfate (SDS) upon the conformation and hemolytic activity of St I and St II strongly depends on its concentration. At relatively low surfactant concentrations (ca. 0.5-5mM range) the surfactant leads to the formation of aggregates, as suggested by the turbidity observed even at relatively low (micromolar range) protein concentrations. In this surfactant range, the proteins show an increase in intrinsic fluorescence intensity and reduced quenching by acrylamide, with an almost total loss of its hemolytic activity. At higher surfactant concentrations the protein adducts disaggregates. This produces a decrease in fluorescence intensity, increase in quenching efficiency by acrylamide, loss of the native tertiary conformation (as reported by the near UV-CD spectra), and increase in alpha-helix content (as evidenced by the far UV-CD spectra). However, and in spite of these substantial changes, the toxins partially recover their hemolytic activity. The reasons for this recovering of the activity at high surfactant concentrations is discussed.

Local anesthetic-induced microscopic and mesoscopic effects in micelles. A fluorescence, spin label and SAXS study

The interaction of the local anesthetic tetracaine (TTC) with anionic sodium lauryl sulfate (SLS) and zwitterionic 3-(N-hexadecyl-N,N-dimethylammonio)propanesulfonate (HPS) micelles was investigated by fluorescence, spin labeling EPR and small angle X-ray scattering (SAXS). Fluorescence pH titrations allowed the choice of adequate pHs for the EPR and SAXS experiments, where either charged or uncharged TTC would be present. The data also indicated that the anesthetic is located in a less polar environment than its charged counterpart in both micellar systems. EPR spectra evidenced that both anesthetic forms increased molecular organization within the SLS micelle, the cationic form exerting a more pronounced effect. The SAXS data showed that protonated TTC causes an increase in the SLS polar shell thickness, hydration number, and aggregation number, whereas the micellar features are not altered upon incorporation of the uncharged drug. The combined results suggest that the electrostatic interaction between charged TTC and SLS, and the intercalation of the drug in the micellar polar region induce a change in molecular packing with a decrease in the mean cross-sectional area, not observed when the neutral drug sinks more deeply into the micellar hydrophobic domain. In the case of HPS micelles, the EPR spectral changes were small for the charged anesthetic and the SAXS data did not evidence any change in micellar structure, suggesting that this species protrudes more into the aqueous phase due to the lack of electrostatic attractive forces in this system.

Conformational properties of angiotensin II and its active and inactive TOAC‐labeled analogs in the presence of micelles. Electron paramagnetic resonance, fluorescence, and circular dichroism studies

The interaction between angiotensin II (AII, DRVYIHPF) and its analogs carrying 2,2,6,6‐tetramethylpiperidine‐1‐oxyl‐4‐amino‐4‐carboxylic acid (TOAC) and detergents —negatively charged sodium dodecyl sulfate (SDS) and zwitterionic N‐hexadecyl‐N,N‐dimethyl‐3‐ammonio‐1‐propanesulfonate (HPS)—was examined by means of EPR, CD, and fluorescence. EPR spectra of partially active TOAC1‐AII and inactive TOAC3‐AII in aqueous solution indicated fast tumbling, the freedom of motion being greater at the N‐terminus. Line broadening occurred upon interaction with micelles. Below SDS critical micelle concentration, broader lines indicated complex formation with tighter molecular packing than in micelles. Small changes in hyperfine splittings evinced TOAC location at the micelle‐water interface. The interaction with anionic micelles was more effective than with zwitterionic micelles. Peptide‐micelle interaction caused fluorescence increase. The TOAC‐promoted intramolecular fluorescence quenching was more pronounced for TOAC3‐AII because of the proximity between the nitroxide and Tyr4. CD spectra showed that although both AII and TOAC1‐AII presented flexible conformations in water, TOAC3‐AII displayed conformational restriction because of the TOAC‐imposed bend (Schreier et al., Biopolymers 2004, 74, 389). In HPS, conformational changes were observed for the labeled peptides at neutral and basic pH. In SDS, all peptides underwent pH‐dependent conformational changes. Although the spectra suggested similar folds for AII and TOAC1‐AII, different conformations were acquired by TOAC3‐AII. The membrane environment has been hypothesized to shift conformational equilibria so as to stabilize the receptor‐bound conformation of ligands. The fact that TOAC3‐AII is unable to acquire conformations similar to those of native AII and partially active TOAC1‐AII is probably the explanation for its lack of biological activity.

Conformational studies of TOAC-labeled bradykinin analogues in model membranes

Spin-labeled analogues of bradykinin (BK) were synthesized containing the amino acid TOAC (2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid) either before Arg1 (TOAC0-BK) or replacing Pro3 (TOAC3-BK). Whereas the latter is inactive, the former retains about 70% of BKs activity in isolated rat uterus. A combined electron paramagnetic resonance (EPR)-circular dichroism (CD) approach was used to examine the conformational properties of the peptides in the presence of membrane-mimetic systems (negatively charged sodium dodecyl sulfate, SDS, and zwitterionic N-hexadecyl-N,N-dimethyl-3-ammonio-1-propanesulfonate, HPS). While the peptides bind to both monomeric and micellar SDS, no interaction occurs with HPS, evincing the contribution of electrostatic interactions. TOAC3-BKs EPR spectral lineshapes are broader than those of TOAC0-BK, indicating a more restricted degree of motion at position 3. Moreover, the motional freedom of both peptides decreased upon binding to SDS. BK and TOAC0-BK solution CD spectra indicate highly flexible conformations (possibly an equilibrium between rapidly interconverting forms), while TOAC3-BKs spectra correspond to a more ordered structure. SDS binding induces drastic changes in BK and TOAC0-BK spectra, indicating stabilization of similar folds. The micelle interface promotes a higher degree of secondary structure by favoring intramolecular hydrogen bonds. In contrast. TOAC3-BK spectra remain essentially unchanged. These results are interpreted as due to TOACs ring imposing a more constrained conformation. This rigidity is very likely responsible for the inability of TOAC3-BK to acquire the correct receptor-bound conformation leading to loss of biological activity, On the other hand, the greater flexibility of TOAC0-BK and the similarity between its conformational behavior and that of the native hormone are probably related to their similar biological activity.

Effect of a zwitterionic surfactant (HPS) on the conformation and hemolytic activity of St I and St II, two isotoxins purified from Stichodactyla helianthus.

N-hexadecyl-N-N′-dimethyl-3-ammonio-1-propane-sulfonate (HPS) is a zwitterionic surfactant that readily binds to sticholysins I and II, two sea toxins isolated from Stichodactyla helianthus. The binding constants, evaluated from changes in fluorescence intensities elicited by the surfactant, are ∼0.5–0.7 μM−1. The binding of the surfactant changes the conformation of the tertiary protein, without significant changes in its secondary structure, as reported from far-ultraviolet circular dichroism spectra. The changes elicited by HPS lead to loss of the native conformation (as reported from near-ultraviolet circular dichroism spectra) and to a shift of the intrinsic protein fluorescence toward longer wavelengths, an increase in fluorescence intensities and lifetimes, and a faster quenching by acrylamide. All these changes are indicative of a more expanded tertiary conformation. Despite this, the toxins fully retain their hemolytic activities, indicating that spectroscopic changes can be poor predictors of toxin activity.

Conformational Studies of Angiotensin II Cyclic Analogues

Angiotensin II (AII) is an octapeptide, produced in the blood as a result of two different enzymatic hydrolyses, which occur in the renal hypertensor system. Among many others pharmacological properties, angiotensin II exerts its effects in the smooth and visceral muscles, peripheral and central nervous system and in the induction of aldosterone releasing from the cortex adrenal gland. As a potent pressor agent it plays an important role in the blood pressure regulation. Many efforts have been done in order to establish the AII receptor-bound conformation. As the molecule is very flexible in solution, one of the most successful strategies is the use of conformationally constrained AII analogues by disulfide [1,2] or lactam bridges [3,4].