Behçet's syndrome as a tool to dissect the mechanisms of thrombo-inflammation: clinical and pathogenetic aspects.

Behçet's syndrome (BS) is a complex disease with different organ involvement. The vascular one is the most intriguing, considering the existence of a specific group of patients suffering from recurrent vascular events involving the venous and, more rarely, the arterial vessels. Several clinical clues suggest the inflammatory nature of thrombosis in BS, especially of the venous involvement, thus BS is considered a model of inflammation-induced thrombosis. Unique among other inflammatory conditions, venous involvement (together with the arterial one) is currently treated with immunosuppressants, rather than with anti-coagulants. Although many in-vitro studies have suggested the different roles of the multiple players involved in clot formation, in-vivo models are crucial to study this process in a physiological context. At present, no clear mechanisms describing the pathophysiology of thrombo-inflammation in BS exist. Recently, we focused our attention on BS patients as a human in-vivo model of inflammation-induced thrombosis to investigate a new mechanism of clot formation. Indeed, fibrinogen displays a critical role not only in inflammatory processes, but also in clot formation, both in the fibrin network and in platelet aggregation. Reactive oxygen species (ROS)-derived modifications represent the main post-translational fibrinogen alterations responsible for structural and functional changes. Recent data have revealed that neutrophils (pivotal in the pathogenetic mechanisms leading to BS damage) promote fibrinogen oxidation and thrombus formation in BS. Altogether, these new findings may help understand the pathogenetic bases of inflammation-induced thrombosis and, more importantly, may suggest potential targets for innovative therapeutic approaches.

Rapid communication: a vegetable oil extract restores redox status in fibroblasts from psoriatic patients.

Psoriasis is an inflammatory skin disease that affects 2-5% of the worldwide population. It is a chronic immune-mediated hyperproliferative inflammatory skin disease of unknown etiology, characterized by the appearance of sore patches of thick, red skin with silvery scales.

Crystal structure of common type acylphosphatase from bovine testis.

BACKGROUND: Acylphosphatase (ACP) is a low molecular weight phosphomonohydrolase catalyzing with high specificity the hydrolysis of the carboxyl-phosphate bond present in acylphosphates. The enzyme is thought to regulate metabolic processes in which acylphosphates are involved, such as glycolysis and the production of ribonucleotides. Furthermore the enzyme is capable of hydrolyzing the phospho-aspartyl intermediate formed during the action of membrane pumps such as (Ca2++Mg2+) ATPase. Although the tertiary structure of a muscle ACP has been determined by NMR spectroscopy, little is known about the catalytic mechanism of ACP and further structures might provide an increased understanding. RESULTS: The structure of 'common type' ACP from bovine testis has been determined by X-ray crystallography to a resolution of 1.8 A. The structure has been refined to an R factor of 17.0 % using all data between 15 and 1.8 A. The binding of a sulphate and a chloride ion in the active centre allows a detailed description of this site. The overall protein folds of common type and muscle ACP are similar but their loops have very different conformations. These differences, in part, are probably caused by the binding of the ions in the active site of the common type form. The phosphate-binding loop of ACP shows some remarkable similarities to that of low molecular weight protein tyrosine phosphatase. CONCLUSIONS: The active site of ACP has been located, enabling a reaction mechanism to be suggested in which the phosphate moiety bound to Arg23 acts as a base, abstracting a proton from a nucleophilic water molecule liganded to Asn41. The transition-state intermediate is stabilized by the phosphate-binding loop. We suggest the catalysis to be substrate assisted, which probably explains why this enzyme can only hydrolyze acylphosphates.

Erythrocyte oxidative stress is associated with cell deformability in patients with retinal vein occlusion.

Essentials Retinal vein occlusion (RVO), characterized by blood hyperviscosity, has an unclear pathogenesis. We aimed to find out if hemorheological profile is altered by oxidative stress in RVO patients. Red blood cell (RBC) oxidative stress is associated to whole blood viscosity and RBC deformability. Reactive oxygen species alter RBC membrane rigidity, playing a key role in RVO pathogenesis. SUMMARY: Background Retinal vein occlusion (RVO) is characterized by vision loss resulting from hypoperfusion and hypoxia of the retina. RVO pathogenesis is not yet fully understood, although blood hyperviscosity has been observed. Erythrocyte deformability plays a key role in determining blood viscosity, and it is critical to microvascular perfusion and oxygen delivery. It has been shown that oxidative stress-induced erythrocyte membrane fluidity alterations are linked to the progression of cardiovascular diseases. Objectives To determine whether erythrocytes from RVO patients show signs of oxidative stress, and whether this condition can modify the hemorheologic profile in these patients. Patients and Methods We analyzed the entire hemorheologic profile and erythrocyte oxidative stress - reactive oxygen species (ROS) production and membrane lipid peroxidation - in 128 RVO patients and 128 healthy subjects, matched for age and sex. Fluorescence anisotropy was used to evaluate the fluidity of erythrocyte membranes. Results In RVO patients, erythrocyte oxidative stress was present and positively correlated with whole blood viscosity and erythrocyte deformability. Multivariate linear regression analysis after adjustment for age, cardiovascular risk factors, medications, leukocyte number and mean corpuscular volume indicated that erythrocyte-derived ROS and erythrocyte lipid peroxidation were significantly and positively correlated with erythrocyte membrane viscosity and deformability. Moreover, in vitro experiments demonstrated that ROS have a key role in erythrocyte membrane fluidity. Conclusions Our findings indicate that erythrocyte oxidative stress plays a key role in the pathogenesis of RVO, and pave the way to new therapeutic interventions.

Chemical synthesis and expression of a gene coding for human muscle acylphosphatase.

A DNA sequence coding for human muscle acylphosphatase has been constructed using 16 chemically synthesized oligonucleotides. The 300-bases long DNA sequence has been cloned in the pT7.7 Escherichia coli expression vector and in the pYEpsec1 Saccharomyces cerevisiae expression vector. In both cases a high level of expression of acylphosphatase has been observed. The recombinant proteins have been purified to homogeneity and assayed in comparison with the natural protein, using benzoylphosphate as a substrate and phosphate as a competitive inhibitor. The recombinant enzymes expressed in the two microorganisms maintain the kinetic properties of the natural protein. In addition, NMR analysis shows that the gross fold of the two recombinant enzymes is correct.

Arginine-23 is involved in the catalytic site of muscle acylphosphatase.

Three mutants of human muscle acylphosphatase in which arginine-23 was replaced by glutamine, histidine and lysine, respectively, were prepared by oligonucleotide-directed mutagenesis of a synthetic gene coding for the enzyme. All mutants, purified by affinity chromatography, were almost completely unable to catalyze the hydrolysis of the substrate. 1H-NMR spectroscopy experiments showed the absence of any major conformational changes of the three mutants with respect to the wild-type recombinant enzyme. Equilibrium dialysis experiments demonstrated that the mutated proteins lost the ability of binding inorganic phosphate, a competitive inhibitor of the enzyme. These results strongly support an involvement of arginine-23 at the phosphate binding-site of acylphosphatase, confirming the hypothesis of the existence of a phosphate binding structural motif recently proposed by other authors.

Detection of two partially structured species in the folding process of the amyloidogenic protein beta 2-microglobulin.

beta 2-Microglobulin is a small, major histocompatibility complex class I-associated protein that undergoes aggregation and accumulates as amyloid deposits in human tissues as a consequence of long-term haemodialysis. The folding process of this amyloidogenic protein has been studied in vitro by diluting the guanidine hydrochloride-denatured protein in refolding buffer at pH 7.4 and monitoring the folding process by means of a number of spectroscopic probes that allow the native structure of the protein to be detected as it develops. These techniques include fluorescence spectroscopy, far and near-UV circular dichroism, 8-anilino-1-naphthalenesulfonic acid binding and double jump assays. All spectroscopic probes indicate that a significant amount of structure forms within the dead-time of stopped-flow measurements (<5 ms). The folding reaction goes to completion through a fast phase followed by a slow phase, whose rate constants are ca 5.1 and 0.0030 s(-1) in water, respectively. Unfolding-folding double jump experiments, together with the use of peptidyl prolyl isomerase, reveal that the slow phase of folding of beta 2-microglobulin is not fundamentally determined by cis/trans isomerisation of X-Pro peptide bonds. Other folding-unfolding double jump experiments also suggest that the fast and slow phases of folding are not related to independent folding of different populations of protein molecules. Rather, we provide evidence for a sequential mechanism of folding where denatured beta 2-microglobulin collapses to an ensemble of partially folded conformations (I(1)) which fold subsequently to a more highly structured species (I(2)) and, finally, attain the native state. The partially folded species I(2) appears to be closely similar to previously studied amyloidogenic forms of beta 2-microglobulin, such as those adopted by the protein at mildly acid pH values and by a variant with six residues deleted at the N terminus. Since amyloid formation in vivo originates from partial denaturation of beta 2-microglobulin under conditions favouring the folding process, the long-lived, partially structured species detected here might be significantly populated under some physiological conditions and hence might play an important role in the process of amyloid formation.

Slow folding of muscle acylphosphatase in the absence of intermediates.

The folding of a 98 residue protein, muscle acylphosphatase (AcP), has been studied using a variety of techniques including circular dichroism, fluorescence and NMR spectroscopy following transfer of chemically denatured protein into refolding conditions. A low-amplitude phase, detected in concurrence with the main kinetic phase, corresponds to the folding of a minor population (13%) of molecules with one or both proline residues in a cis conformation, as shown from the sensitivity of its rate to peptidyl prolyl isomerase. The major phase of folding has the same kinetic characteristics regardless of the technique employed to monitor it. The plots of the natural logarithms of folding and unfolding rate constants versus urea concentration are linear over a broad range of urea concentrations. Moreover, the initial state formed rapidly after the initiation of refolding is highly unstructured, having a similar circular dichroism, intrinsic fluorescence and NMR spectrum as the protein denatured at high concentrations of urea. All these results indicate that AcP folds in a two-state manner without the accumulation of intermediates. Despite this, the folding of the protein is extremely slow. The rate constant of the major phase of folding in water, kfH2O, is 0.23 s-1 at 28 degreesC and, at urea concentrations above 1 M, the folding process is slower than the cis-trans proline isomerisation step. The slow refolding of this protein is therefore not the consequence of populated intermediates that can act as kinetic traps, but arises from a large intrinsic barrier in the folding reaction.

Structural characterization of the transition state for folding of muscle acylphosphatase.

The transition state for folding of a small protein, muscle acylphosphatase, has been studied by measuring the rates of folding and unfolding under a variety of solvent conditions. A strong dependence of the folding rate on the concentration of urea suggests the occurrence in the transition state of a large shielding of those groups that are exposed to interaction with the denaturant in the unfolded state (mainly hydrophobic moieties and groups located on the polypeptide backbone). The heat capacity change upon moving from the unfolded state to the transition state is small and is indicative of a substantial solvent exposure of hydrophobic groups. The solvent-accessibility of such groups in the transition state has also been found to be significant by measuring the rates of folding and unfolding in the presence of sugars. These rates have also been found to be accelerated by the addition of small quantities of alcohols. Trifluoroethanol and hexafluoroisopropanol were particularly effective, suggesting that stabilisation of local hydrogen bonds lowers the energy of the transition state relative to the folded and unfolded states. Finally, a study with a competitive inhibitor of acylphosphatase has provided evidence for the complete loss of ligand binding affinity in the transition state, indicating that specific long-range interactions at the level of the active site are not yet formed at this stage of the folding reaction. A model of the transition state for acylphosphatase folding, in which beta-turns and one or both alpha-helices are formed to a significant extent but in which the persistent long-range interactions characteristic of the folded state are largely absent, accounts for all our data. These results are broadly consistent with models of the transition states for folding of other small proteins derived from mutagenesis studies, and suggest that solvent perturbation methods can provide complementary information about the transition region of the energy surfaces for protein folding.

Stabilisation of alpha-helices by site-directed mutagenesis reveals the importance of secondary structure in the transition state for acylphosphatase folding.

The effects of stabilising mutations on the folding process of common-type acylphosphatase have been investigated. The mutations were designed to increase the helical propensity of the regions of the polypeptide chain corresponding to the two alpha-helices of the native protein. Various synthetic peptides incorporating the designed mutations were produced and their helical content estimated by circular dichroism. The most substantial increase in helical content is found for the peptide carrying five mutations in the second alpha-helix. Acylphosphatase variants containing the corresponding mutations display, to different extents, enhanced conformational stabilities as indicated by equilibrium urea denaturation experiments monitored by changes of intrinsic fluorescence. All the protein variants studied here refold with apparent two-state kinetics. Mutations in the first alpha-helix are responsible for a small increase in the refolding rate, accompanied by a marked decrease in the unfolding rate. On the other hand, multiple mutations in the second helix result in a considerable increase in the refolding rate without any significant effect on the unfolding rate. Addition of trifluoroethanol was found to accelerate the folding of the acylphosphatase variants, the extent of the acceleration being inversely proportional to the intrinsic rate of folding of the corresponding mutant. The trifluoroethanol-induced acceleration is far less marked for those variants whose alpha-helical structure is efficiently stabilised by amino acid replacements. This observation suggests that trifluoroethanol acts in a similar manner to the stabilising mutations in promoting native-like secondary structure. Analysis of the kinetic data indicates that the second helix is fully consolidated in the transition state for folding of acylphosphatase, whereas the first helix is only partially formed. These data suggest that the second helix is an important element in the folding process of the protein.

Reduction of the amyloidogenicity of a protein by specific binding of ligands to the native conformation.

It is known that human muscle acylphosphatase (AcP) is able, under appropriate conditions in vitro, to aggregate and form amyloid fibrils of the type associated with human diseases. A number of compounds were tested for their ability to bind specifically to the native conformation of AcP under conditions favoring denaturation and subsequent aggregation and fibril formation. Compounds displaying different binding affinities for AcP were selected and their ability to inhibit protein fibrillization in vitro was evaluated. We found that compounds displaying a relatively high affinity for AcP are able to significantly delay protein fibrillization, mimicking the effect of stabilizing mutations; in addition, the effectiveness of such outcome correlates positively to both ligand concentration and affinity to the native state of AcP. By contrast, the inhibitory effect of ligands on AcP aggregation disappears in a mutant protein in which such binding affinity is lost. These results indicate that the stabilization of the native conformation of amyloidogenic proteins by specific ligand binding can be a strategy of general interest to inhibit amyloid formation in vivo.

Solution conditions can promote formation of either amyloid protofilaments or mature fibrils from the HypF N-terminal domain.

The HypF N-terminal domain has been found to convert readily from its native globular conformation into protein aggregates with the characteristics of amyloid fibrils associated with a variety of human diseases. This conversion was achieved by incubation at acidic pH or in the presence of moderate concentrations of trifluoroethanol. Electron microscopy showed that the fibrils grown in the presence of trifluoroethanol were predominantly 3-5 nm and 7-9 nm in width, whereas fibrils of 7-9 nm and 12-20 nm in width prevailed in samples incubated at acidic pH. These results indicate that the assembly of protofilaments or narrow fibrils into mature amyloid fibrils is guided by interactions between hydrophobic residues that may remain exposed on the surface of individual protofilaments. Therefore, formation and isolation of individual protofilaments appears facilitated under conditions that favor the destabilization of hydrophobic interactions, such as in the presence of trifluoroethanol.

Initial denaturing conditions influence the slow folding phase of acylphosphatase associated with proline isomerization.

The folding kinetics of human common-type acylphosphatase (cAcP) from its urea- and TFE-denatured states have been determined by stopped-flow fluorescence techniques. The refolding reaction from the highly unfolded state formed in urea is characterized by double exponential behavior that includes a slow phase associated with isomerism of the Gly53-Pro54 peptide bond. However, this slow phase is absent when refolding is initiated by dilution of the highly a-helical denatured state formed in the presence of 40% trifluoroethanol (TFE). NMR studies of a peptide fragment corresponding to residues Gly53-Gly69 of cAcP indicate that only the native-like trans isomer of the Gly-Pro peptide bond is significantly populated in the presence of TFE, whereas both the cis and trans isomers are found in an approximately 1:9 ratio for the peptide bond in aqueous solution. Molecular modeling studies in conjunction with NMR experiments suggest that the trans isomer of the Gly53-Pro54 peptide bond is stabilized in TFE by the formation of a nonnative-like hydrogen bond between the CO group of Gly53 and the NH group of Lys57. These results therefore reveal that a specific nonnative interaction in the denatured state can increase significantly the overall efficiency of refolding.

Aspartic-129 is an essential residue in the catalytic mechanism of the low M(r) phosphotyrosine protein phosphatase.

The crystal structure of the bovine liver low M(r) phosphotyrosine protein phosphatase suggests the involvement of aspartic acid-129 in enzyme catalysis. The Asp-129 to alanine mutant has been prepared by oligonucleotide-directed mutagenesis of a synthetic gene coding for the enzyme. The purified mutant elicited an highly reduced specific activity (about 0.04% of the activity of the wild-type) and a native-like fold, as judged by 1H NMR spectroscopy. The kinetic analysis revealed that the mutant is able to bind the substrate and a competitive inhibitor, such as inorganic phosphate. Moreover, trapping experiments demonstrated it maintains the ability to form the E-P covalent complex. The Asp-129 to alanine mutant shows extremely reduced enzyme phosphorylation (k2) and dephosphorylation (k3) kinetic constant values as compared to the wild-type enzyme. The data reported indicate that aspartic acid-129 is likely to be involved both in the first step and in the rate-limiting step of the catalytic mechanism, i.e. the nucleophilic attack of the phosphorylated intermediate.

Crystallisation of a low molecular weight phosphotyrosine protein phosphatase from bovine liver.

Single crystals of a low molecular weight phosphotyrosine protein phosphatase from bovine liver have been grown. The crystals belong to space group P2(1)2(1)2(1), have cell dimensions a = 46.3 A, b = 62.2 A, c = 62.7 A and diffract to better than 2.0 A resolution. The crystals are well suited for high resolution X-ray studies.

Properties of N-terminus truncated and C-terminus mutated muscle acylphosphatases.

Enzymatic activity and structure of N-terminus truncated and C-terminus substituted muscle acylphosphatase mutants were investigated by kinetic studies under different conditions and 1H NMR spectroscopy, respectively. The N-terminus truncated mutant lacked the first six residues (delta 6), whereas arginine 97 and tyrosine 98 were replaced by glutamine giving two C-terminus substituted mutants (R97Q and Y98Q, respectively). All acylphosphatase forms were obtained by modifications of a synthetic gene coding for the human muscle enzyme which was expressed in E. coli. The delta 6 deletion mutant elicited a reduced specific activity and a native-like structure. The kinetic and structural properties of R97Q and Y98Q mutants indicate a possible role of Arg-97 in the stabilisation of the active site correct conformation, most likely via back-bone and side chain interactions with Arg-23, the residue involved in phosphate binding by the enzyme. This study also suggests a possible involvement of Tyr-98 in the stabilisation of the acylphosphatase overall structure.

C-terminal region contributes to muscle acylphosphatase three-dimensional structure stabilisation.

Ser-Ala and Ser-Ala-Ser-Ala C-terminus elongated (delta+2 and delta+4, respectively) and two C-terminus deleted (delta-2 and delta-3) muscle acylphosphatase mutants were investigated to assess the catalytic and structural roles of the C-terminal region. The kinetic analysis of these mutants shows that the removal of two or three C-terminal residues reduces the catalytic activity to 7% and 4% of the value measured for the wild-type enzyme, respectively; instead, the elongation of the C-terminus does not significantly change the enzyme behaviour. 1H Nuclear magnetic resonance spectroscopy indicates that all mutants display a native-like fold though they appear less stable, particularly delta-2 and delta-3 mutants, as compared to the wild-type enzyme. Such destabilisation of the C-terminal modified mutants is further confirmed by urea inactivation experiments. The results here presented account for an involvement of the C-terminal region in the stabilisation of the three-dimensional structure of acylphosphatase, particularly at the active-site level. Moreover, a participation of the C-terminal carboxyl group to the catalytic mechanism can be excluded.

Sequence-specific recognition of peptide substrates by the low Mr phosphotyrosine protein phosphatase isoforms.

A number of phosphotyrosine-containing peptides derived from the PDGF receptor phosphorylation sites have been synthesised. The peptides were assayed as substrates of the two isoforms (IF1 and IF2) of the low Mr PTPase. The calculated k(cat), Km, and k(cat)/Km values indicate that only one peptide is best hydrolysed by IF2 (but not IF1), whose catalytic efficiency averages those previously reported for most PTPases (except the Yersinia enzyme). This peptide is the only one containing a couple of no bulky hydrophobic residues at the phosphotyrosine N-side. The determination of the same catalytic parameters in the presence of analogues of the best hydrolysed peptide in which one or both hydrophobic residues were replaced by Asp or Lys residues confirmed the importance of the hydrophobic cluster at the phosphotyrosine N-side for optimal enzymatic hydrolysis. These findings are discussed in the light of the known IF2 X-ray structure.

Expression, purification and preliminary crystal analysis of the human low Mr phosphotyrosine protein phosphatase isoform 1.

The genes of the human low Mr phosphotyrosine protein phosphatase (PTPase) isoforms 1 (IF1) and 2 (IF2) were isolated by screening a human placenta cDNA library, cloned in pGEX and expressed in E. coli as fusion proteins with glutathione S-transferase. The recombinant proteins were purified by a rapid one-step procedure allowing each enzyme to purify with high final yield and specific activity. This result is important for IF1, whose purification from natural sources is difficult, due to precipitation propensity, thus hindering structural studies. The enzymes obtained showed kinetic parameters very similar to those previously determined for the enzymes purified by classical procedures from both human erythrocytes and rat liver. These recombinant enzymes can therefore be used in place of those purified from natural sources for every purpose. IF1 and IF2 crystals were also grown. IF1 crystals were X-ray-grade, diffracted to better than 2.4 A and were suitable for high resolution X-ray structure determination.

Crystallisation and preliminary X-ray analysis of the 'common-type' acylphosphatase.

Single crystals of a 'common-type' acylphosphatase from bovine testis have been grown. Crystals belong to space group C2 and have cell dimensions a = 64.6 A, b = 36.5 A, c = 45.2 A and beta = 104.8 and contain one monomer per asymmetric unit. The crystals diffract better than 2.0 A resolution and are well suited for an X-ray structure determination.