A Molecular Dynamics Study of Human Defensins HBD-1 and HNP-3 in Water

Abstract

Mammalian defensins are crucial components of the innate immune system. They are characterized by three disulfide bridges and exhibit broad spectrum antibacterial activity. The spacing between the cysteines and disulfide connectivities in the two classes of defensins, the α- and β-forms, are different. The structural motif of 3 β-strands appears to be conserved in α and β-defensins despite differences in disulfide connectivities and spacing between cysteines. In this study, Molecular Dynamics Simulations (MDS) have been carried out to study the conformational behavior of α- and β-defensins with and without disulfide bridges. Our results indicate that β-strands in the C-terminal region of HBD-1 and HNP-3 do not unfold during the course of MDS. The segment adopting α-helix in HBD-1 unfolds early during the simulations. The backbone hydrogen bonds in HBD-1 and HNP-3 are broken during MDS. When the disulfide bonds are absent, the N-terminal β-strand unfolds by 20 ns but β-strands are observed in the C-terminal region of HNP-3. HBD-1, without disulfide bridges, unfolds to a greater extent during the course of the MDS. Examination of distances between sulfur atoms of cysteines without disulfide bridges during the simulations indicate that there is no specific preference for native disulfide bridges, which could be the reason for the experimental observation of non-native disulfide bridge formation during chemical synthesis of human α- and β-defensins. Since defensins with non-native disulfide bridges are biologically active, the exact three dimensional structures observed for native HBD-1 and HNP-3 does not appear to be essential for exhibiting antibacterial activity.     

Disulfiram irreversibly aggregates betaine aldehyde dehydrogenase--a potential target for antimicrobial agents against Pseudomonas aeruginosa

In the human pathogen Pseudomonas aeruginosa, betaine aldehyde dehydrogenase (PaBADH) may play the dual role of assimilating carbon and nitrogen from choline or choline precursors--abundant at infection sites--and producing glycine betaine, which protects the bacterium against the high-osmolality stress prevalent in the infected tissues. This tetrameric enzyme contains four cysteine residues per subunit and is a potential drug target. In our search for specific inhibitors, we mutated the catalytic Cys286 to alanine and chemically modified the recombinant wild-type and the four Cys-->Ala single mutants with thiol reagents. The small methyl-methanethiosulfonate inactivated the enzymes without affecting their stability while the bulkier dithionitrobenzoic acid (DTNB) and bis[diethylthiocarbamyl] disulfide (disulfiram) induced enzyme dissociation--at 23 degrees C--and irreversible aggregation--at 37 degrees C. Of the four Cys-->Ala mutants only C286A retained its tetrameric structure after DTNB or disulfiram treatments, suggesting that steric constraints arising upon the covalent attachment of a bulky group to C286 resulted in distortion of the backbone configuration in the active site region followed by a severe decrease in enzyme stability. Since neither NAD(P)H nor betaine aldehyde prevented disulfiram-induced PaBADH inactivation or aggregation, and reduced glutathione was unable to restore the activity of the modified enzyme, we propose that disulfiram could be a useful drug to combat infection by P. aeruginosa.     

Biochemical and structural characterization of mammalian-like purine nucleoside phosphorylase from the Archaeon Pyrococcus furiosus

We report here the characterization of the first mammalian-like purine nucleoside phosphorylase from the hyperthermophilic archaeon Pyrococcus furiosus (PfPNP). The gene PF0853 encoding PfPNP was cloned and expressed in Escherichia coli and the recombinant protein was purified to homogeneity. PfPNP is a homohexamer of 180 kDa which shows a much higher similarity with 5'-deoxy-5'-methylthioadenosine phosphorylase (MTAP) than with purine nucleoside phosphorylase (PNP) family members. Like human PNP, PfPNP shows an absolute specificity for inosine and guanosine. PfPNP shares 50% identity with MTAP from P. furiosus (PfMTAP). The alignment of the protein sequences of PfPNP and PfMTAP indicates that only four residue changes are able to switch the specificity of PfPNP from a 6-oxo to a 6-amino purine nucleoside phosphorylase still maintaining the same overall active site organization. PfPNP is highly thermophilic with an optimum temperature of 120 degrees C and is characterized by extreme thermodynamic stability (T(m), 110 degrees C that increases to 120 degrees C in the presence of 100 mm phosphate), kinetic stability (100% residual activity after 4 h incubation at 100 degrees C), and remarkable SDS-resistance. Limited proteolysis indicated that the only proteolytic cleavage site is localized in the C-terminal region and that the C-terminal peptide is not necessary for the integrity of the active site. By integrating biochemical methodologies with mass spectrometry we assigned three pairs of intrasubunit disulfide bridges that play a role in the stability of the enzyme against thermal inactivation. The characterization of the thermal properties of the C254S/C256S mutant suggests that the CXC motif in the C-terminal region may also account for the extreme enzyme thermostability.     

Engineered disulfide bonds increase active-site local stability and reduce catalytic activity of a cold-adapted alkaline phosphatase

Alkaline phosphatase is an extracellular enzyme that is membrane-bound in eukaryotes but resides in the periplasmic space of bacteria. It normally carries four cysteine residues that form two disulfide bonds, for instance in the APs of Escherichia coli and vertebrates. An AP variant from a Vibrio sp. has only one cysteine residue. This cysteine is second next to the nucleophilic serine in the active site. We have individually modified seven residues to cysteine that are on two loops predicted to be within a 5 A radius. Four of them formed a disulfide bond to the endogenous cysteine. Thermal stability was monitored by circular dichroism and activity measurements. Global stability was similar to the wild-type enzyme. However, a significant increase in heat-stability was observed for the disulfide-containing variants using activity as a measure, together with a large reduction in catalytic rates (k(cat)) and a general decrease in Km values. The results suggest that a high degree of mobility near the active site and in the helix carrying the endogenous cysteine is essential for full catalytic efficiency in the cold-adapted AP.     

Role of disulfide bonds in goose-type lysozyme

The role of the two disulfide bonds (Cys4-Cys60 and Cys18-Cys29) in the activity and stability of goose-type (G-type) lysozyme was investigated using ostrich egg-white lysozyme as a model. Each of the two disulfide bonds was deleted separately or simultaneously by substituting both Cys residues with either Ser or Ala. No remarkable differences in secondary structure or catalytic activity were observed between the wild-type and mutant proteins. However, thermal and guanidine hydrochloride unfolding experiments revealed that the stabilities of mutants lacking one or both of the disulfide bonds were significantly decreased relative to those of the wild-type. The destabilization energies of mutant proteins agreed well with those predicted from entropic effects in the denatured state. The effects of deleting each disulfide bond on protein stability were found to be approximately additive, indicating that the individual disulfide bonds contribute to the stability of G-type lysozyme in an independent manner. Under reducing conditions, the thermal stability of the wild-type was decreased to a level nearly equivalent to that of a Cys-free mutant (C4S/C18S/C29S/C60S) in which all Cys residues were replaced by Ser. Moreover, the optimum temperature of the catalytic activity for the Cys-free mutant was downshifted by about 20 degrees C as compared with that of the wild-type. These results indicate that the formation of the two disulfide bonds is not essential for the correct folding into the catalytically active conformation, but is crucial for the structural stability of G-type lysozyme.     

Overexpression, physicochemical characterization, and modeling of a hyperthermophilic pyrococcus furiosus type 2 IPP isomerase

In the first step of this study, type 2 isopentenyl diphosphate isomerase (IDI2) from Pyrococcus furiosus (pf-IDI2), a hyperthermophilic microorganism, was cloned and overexpressed in E. coli. After purification, hyperthermophilic behavior of this protein was approached by means of enzymatic assays and thermal denaturation studies. Compared with the mesophilic Streptococcus pneumoniae IDI2, which unfolds and looses activity above 50 degrees C, pf-IDI2 is still folded and active at 80 degrees C. Molecular modeling was applied, in a parallel step, to understand the molecular basis of thermal stability. Comparison of IDI2 from S. pneumoniae, T. thermophilus, and P. furiosus suggested that additional charged residues present in the hyperthermophilic enzyme might contribute to its higher thermal stability. This could increase the number of salt bridges between monomers of IDI2 in P. furiosus enzyme and, hence, decrease flexibility of loops or N-terminal segment, thereby enhancing its thermal stability.     

Soluble human core 2 beta6-N-acetylglucosaminyltransferase C2GnT1 requires its conserved cysteine residues for full activity

Human UDP-GlcNAc: Galbeta1-3GalNAc- (GlcNAc to GalNAc) beta1,6-GlcNAc-transferase (C2GnT1) is a member of a group of beta6-GlcNAc-transferases that belongs to CAZy family 14. One of the striking features of these beta6-GlcNAc-transferases is the occurrence of nine completely conserved cysteine residues that are located throughout the catalytic domain. We have expressed the soluble catalytic domain of human C2GnT1 in insect cells, and isolated active enzyme as a secreted protein. beta-Mercaptoethanol (beta-ME) and dithiothreitol (DTT) were found to stimulate the enzyme activity up to 20-fold, indicating a requirement for a reduced sulfhydryl for activity. When the enzyme was subjected to nonreducing PAGE, the migration of the protein was identical to the migration in reducing gels, demonstrating the absence of intermolecular disulfide bonds. This suggested that the monomer is the active form of the enzyme. Sulfhydryl reagents such as 5,5'-dithiobis-2-nitrobenzoic acid (DTNB) and N-ethylmaleimide (NEM) inactivated the enzyme, and the inactivation was partially prevented by prior addition of donor or acceptor substrate and by sulfhydryl reducing agents. We therefore investigated the role of all nine conserved cysteine residues in enzyme stability and activity by site-directed mutagenesis where individual cysteine residues were changed to serine. All of the mutants were expressed as soluble proteins. Seven of the Cys mutants were found to be inactive, while C100S and C217S mutants had 10% and 41% activity, respectively, when compared to the wild-type enzyme. Wild-type and C217S enzymes had similar K(M) and V(max) values for acceptor substrate Galbeta1-3GalNAcalpha-p-nitrophenyl (GGApnp), but the K(M) value for UDP-GlcNAc was higher for C217S than for the wild-type enzyme. In contrast to wild-type enzyme, C217S was not stimulated by reducing agents and was not inhibited by sulfhydryl specific reagents. These results suggest that Cys-217 is a free sulfhydryl in active wild-type enzyme and that Cys-217, although not required for activity, is in or near the active site of the protein. Since seven of the mutations were totally inactive, it is likely that these seven Cys residues play a role in maintaining an active conformation of soluble C2GnT1 by forming disulfide bonds. These bonds are only broken at high concentrations of disulfide reducing agents.     

The active site cysteine of the proapoptotic protein glyceraldehyde-3-phosphate dehydrogenase is essential in oxidative stress-induced aggregation and cell death

Recent studies have revealed that the redox-sensitive glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), is involved in neuronal cell death that is triggered by oxidative stress. GAPDH is locally deposited in disulfide-bonded aggregates at lesion sites in certain neurodegenerative diseases. In this study, we investigated the molecular mechanism that underlies oxidative stress-induced aggregation of GAPDH and the relationship between structural abnormalities in GAPDH and cell death. Under nonreducing in vitro conditions, oxidants induced oligomerization and insoluble aggregation of GAPDH via the formation of intermolecular disulfide bonds. Because GAPDH has four cysteine residues, including the active site Cys(149), we prepared the cysteine-substituted mutants C149S, C153S, C244A, C281S, and C149S/C281S to identify which is responsible for disulfide-bonded aggregation. Whereas the aggregation levels of C281S were reduced compared with the wild-type enzyme, neither C149S nor C149S/C281S aggregated, suggesting that the active site cysteine plays an essential role. Oxidants also caused conformational changes in GAPDH concomitant with an increase in beta-sheet content; these abnormal conformations specifically led to amyloid-like fibril formation via disulfide bonds, including Cys(149). Additionally, continuous exposure of GAPDH-overexpressing HeLa cells to oxidants produced disulfide bonds in GAPDH leading to both detergent-insoluble and thioflavin-S-positive aggregates, which were associated with oxidative stress-induced cell death. Thus, oxidative stresses induce amyloid-like aggregation of GAPDH via aberrant disulfide bonds of the active site cysteine, and the formation of such abnormal aggregates promotes cell death.     

Disulfide formation and stability of a cysteine-rich repeat protein from Helicobacter pylori

Helicobacter pylori cysteine-rich proteins (Hcps) are disulfide-containing repeat proteins. The repeating unit is a 36-residue, disulfide-bridged, helix-loop-helix motif. We use the protein HcpB, which has four repeats and four disulfide bridges arrayed in tandem, as a model to determine the thermodynamic stability of a disulfide-rich repeat protein and to study the formation and the contribution to stability of the disulfide bonds. When the disulfide bonds are intact, the chemical unfolding of HcpB at pH 5 is cooperative and can be described by a two-state reaction. Thermal unfolding is reversible between pH 2 and 5 and irreversible at higher pH 5. Differential scanning calorimetry shows noncooperative structural changes preceding the main thermal unfolding transition. Unfolding of the oxidized protein is not an all-or-none two-state process, and the disulfide bonds prevent complete unfolding of the polypeptide chain. The reduced protein is significantly less stable and does not unfold in a cooperative way. During oxidative refolding of the fully reduced protein, all the possible disulfide intermediates with a correct disulfide bond are formed. Formation of "wrong" (non-native) disulfide bonds could not be demonstrated, indicating that the reduced protein already has some partial repeating structure. There is a major folding intermediate with disulfides in the second, third, and fourth repeat and reduced cysteines in the first repeat. Disulfide formation in the first repeat limits the overall rate of oxidative refolding and contributes about half of the thermodynamic stability to native HcpB, estimated as 27 kJ mol(-1) at 25 degrees C and pH 7. The high contribution to stability of the first repeat may be explained by the repeat acting as a cap to protect the hydrophobic interior of the molecule.     

Contribution of disulfide bonds to the conformational stability and catalytic activity of ribonuclease A.

Disulfide bonds between the side chains of cysteine residues are the only common crosslinks in proteins. Bovine pancreatic ribonuclease A (RNase A) is a 124-residue enzyme that contains four interweaving disulfide bonds (Cys26-Cys84, Cys40-Cys95, Cys58-Cys110, and Cys65-Cys72) and catalyzes the cleavage of RNA. The contribution of each disulfide bond to the conformational stability and catalytic activity of RNase A has been determined by using variants in which each cystine is replaced independently with a pair of alanine residues. Thermal unfolding experiments monitored by ultraviolet spectroscopy and differential scanning calorimetry reveal that wild-type RNase A and each disulfide variant unfold in a two-state process and that each disulfide bond contributes substantially to conformational stability. The two terminal disulfide bonds in the amino-acid sequence (Cys26-Cys84 and Cys58-Cys110) enhance stability more than do the two embedded ones (Cys40-Cys95 and Cys65-Cys72). Removing either one of the terminal disulfide bonds liberates a similar number of residues and has a similar effect on conformational stability, decreasing the midpoint of the thermal transition by almost 40 degrees C. The disulfide variants catalyze the cleavage of poly(cytidylic acid) with values of kcat/Km that are 2- to 40-fold less than that of wild-type RNase A. The two embedded disulfide bonds, which are least important to conformational stability, are most important to catalytic activity. These embedded disulfide bonds likely contribute to the proper alignment of residues (such as Lys41 and Lys66) that are necessary for efficient catalysis of RNA cleavage.     

Role of disulfide bonds in conformational stability and folding of 5'-deoxy-5'-methylthioadenosine phosphorylase II from the hyperthermophilic archaeon Sulfolobus solfataricus

Sulfolobus solfataricus 5'-deoxy-5'-melthylthioadenosine phosphorylase II (SsMTAPII), is a hyperthermophilic hexameric protein with two intrasubunit disulfide bonds (C138-C205 and C200-C262) and a CXC motif (C259-C261). To get information on the role played by these covalent links in stability and folding, the conformational stability of SsMTAPII and C262S and C259S/C261S mutants was studied by thermal and guanidinium chloride (GdmCl)-induced unfolding and analyzed by fluorescence spectroscopy, circular dichroism, and SDS-PAGE. No thermal unfolding transition of SsMTAPII can be obtained under nonreducing conditions, while in the presence of the reducing agent Tris-(2-carboxyethyl) phosphine (TCEP), a Tm of 100°C can be measured demonstrating the involvement of disulfide bridges in enzyme thermostability. Different from the wild-type, C262S and C259S/C261S show complete thermal denaturation curves with sigmoidal transitions centered at 102°C and 99°C respectively. Under reducing conditions these values decrease by 4°C and 8°C respectively, highlighting the important role exerted by the CXC disulfide on enzyme thermostability. The contribution of disulfide bonds to the conformational stability of SsMTAPII was further assessed by GdmCl-induced unfolding experiments carried out under reducing and nonreducing conditions. Thermal unfolding was found to be reversible if the protein was heated in the presence of TCEP up to 90°C but irreversible above this temperature because of aggregation. In analogy, only chemical unfolding carried out in the presence of reducing agents resulted in a reversible process suggesting that disulfide bonds play a role in enzyme denaturation. Thermal and chemical unfolding of SsMTAPII occur with dissociation of the native hexameric state into denatured monomers, as indicated by SDS-PAGE.     

Positions of disulfide bonds and N-glycosylation site in juvenile hormone binding protein

The juvenile hormone binding protein (JHBP) from Galleria mellonella hemolymph is a glycoprotein composed of 225 amino acid residues. It contains four Cys residues forming two disulfide bridges. In this study, the topography of the disulfide bonds as well as the site of glycan attachment in the JHBP molecule from G. mellonella was determined, using electrospray mass spectrometry. The MS analysis was performed on tryptic digests of JHBP. Our results show that the disulfide bridges link Cys10 and Cys17, and Cys151 and Cys195. Of the two potential N-glycosylation sites in JHBP, Asn4, and Asn94, only Asn94 is glycosylated. This site of glycosylation is also found in the fully biologically active recombinant JHBP expressed in the yeast Pichia pastoris.     

The CXC motif: a functional mimic of protein disulfide isomerase

Protein disulfide isomerase (PDI) utilizes the active site sequence Cys-Gly-His-Cys (CGHC; E degrees ' = -180 mV) to effect thiol-disulfide interchange during oxidative protein folding. Here, the Cys-Gly-Cys-NH(2) (CGC) peptide is shown to have a disulfide reduction potential (E degrees ' = -167 mV) that is close to that of PDI. This peptide has a thiol acid dissociation constant (pK(a) = 8.7) that is lower than that of glutathione. These attributes endow the CGC peptide with substantial disulfide isomerization activity. Escherichia coli thioredoxin (Trx) utilizes the active site sequence Cys-Gly-Pro-Cys (CGPC; E degrees ' = -270 mV) to effect disulfide reduction. Removal of the proline residue from the Trx active site yields a CGC active site with a greatly destabilized disulfide bond (E degrees ' >or= -200 mV). The DeltaP34 variant retains high conformational stability and remains a substrate for thioredoxin reductase. In contrast to the reduced form of the wild-type enzyme, the reduced form of DeltaP34 Trx has disulfide isomerization activity, which is 25-fold greater than that of the CGC peptide. Thus, the rational deletion of an active site residue can bestow a new and desirable function upon an enzyme. Moreover, a CXC motif, in both a peptide and a protein, provides functional mimicry of PDI.     

Thermal stability of pyrrolidone carboxyl peptidases from the hyperthermophilic Archaeon, Pyrococcus furiosus.

The temperature adaptation of pyrrolidone carboxyl peptidase (PCP) from a hyperthermophile, Pyrococcus furiosus (Pf PCP), was characterized in the context of an assembly form of the protein which is a homotetramer at neutral pH. The Pf PCP exhibited maximal catalytic activity at 90-95 degrees C and its activity was higher in the temperature range 30-100 degrees C than its counterpart from the mesophilic Bacillus amyloliquefaciens (BaPCP). Thermal stability was monitored by differential scanning calorimetry (DSC). Two clearly separated peaks appeared on the DSC curves for Pf PCP at alkaline and acidic pH. Using the oxidized Pf PCP and two mutant proteins (Pf C188S and Pf C142/188S), it was found that the peaks on the high and low temperature sides of the DSC curve of Pf PCP were produced by the forms with an intersubunit disulfide bridge between the two subunits and without the bridge, respectively, indicating the stabilization effect of intersubunit disulfide bridges. The denaturation temperature (Td) of Pf PCP with intersubunit disulfide bridges was higher by 53 degrees C at pH 9.0 than that of BaPCP. An analysis of the equilibrium ultracentrifugation patterns showed that the tetrameric Pf C142/188S dissociated into dimers with decreasing pH in the acidic region and became monomer subunits at pH 2.5. The heat denaturation of Pf PCP and its two Cys mutants was highly reversible in the dimeric forms, but completely irreversible in the tetrameric form. The Td of Pf C142/188S decreased as the enzyme became dissociated, but the monomeric form of the protein was still folded at pH 2.5, although BaPCP was completely denatured at acidic pH. These results indicate that subunit interaction plays an important role in stabilizing PCP from P. furiosus in addition to the intrinsic enhanced stability of its monomer.     

Structural basis for the redox control of plant glutamate cysteine ligase

Glutathione (GSH) plays a crucial role in plant metabolism and stress response. The rate-limiting step in the biosynthesis of GSH is catalyzed by glutamate cysteine ligase (GCL) the activity of which is tightly regulated. The regulation of plant GCLs is poorly understood. The crystal structure of substrate-bound GCL from Brassica juncea at 2.1-A resolution reveals a plant-unique regulatory mechanism based on two intramolecular redox-sensitive disulfide bonds. Reduction of one disulfide bond allows a beta-hairpin motif to shield the active site of B. juncea GCL, thereby preventing the access of substrates. Reduction of the second disulfide bond reversibly controls dimer to monomer transition of B. juncea GCL that is associated with a significant inactivation of the enzyme. These regulatory events provide a molecular link between high GSH levels in the plant cell and associated down-regulation of its biosynthesis. Furthermore, known mutations in the Arabidopsis GCL gene affect residues in the close proximity of the active site and thus explain the decreased GSH levels in mutant plants. In particular, the mutation in rax1-1 plants causes impaired binding of cysteine.     

Conservation of cysteine residues in fungal histidine acid phytases

Amino acid sequence analysis of fungal histidine acid phosphatases displaying phytase activity has revealed a conserved eight-cysteine motif. These conserved amino acids are not directly associated with catalytic function; rather they appear to be essential in the formation of disulfide bridges. Their role is seen as being similar to another eight-cysteine motif recently reported in the amino acid sequence of nearly 500 plant polypeptides. An additional disulfide bridge formed by two cysteines at the N-terminus of all the filamentous ascomycete phytases was also observed. Disulfide bridges are known to increase both stability and heat tolerance in proteins. It is therefore plausible that this extra disulfide bridge contributes to the higher stability found in phytase from some Aspergillus species. To engineer an enhanced phytase for the feed industry, it is imperative that the role of disulfide bridges be taken into cognizance and possibly be increased in number to further elevate stability in this enzyme.     

Analysis of the thyrotropin-releasing hormone-degrading ectoenzyme by site-directed mutagenesis of cysteine residues. Cys68 is involved in disulfide-linked dimerization.

Thyrotropin-releasing hormone-degrading ectoenzyme is a member of the M1 family of Zn-dependent aminopeptidases and catalyzes the degradation of thyrotropin-releasing hormone (TRH; Glp-His-Pro-NH2). Cloning of the cDNA of this enzyme and biochemical studies revealed that the large extracellular domain of the enzyme with the catalytically active site contains nine cysteine residues that are highly conserved among species. To investigate the functional role of these cysteines in TRH-DE we used a site-directed mutagenesis approach and replaced individually each cysteine by a serine residue. The results revealed that the proteolytically truncated and enzymatically fully active enzyme consists of two identical subunits that are associated noncovalently by protein-protein interactions but not via interchain S-S bridges. The eight cysteines contained within this region are all important for the structure of the individual subunit and the enzymatic activity, which is dramatically reduced in all mutant enzymes. This is even true for the four cysteines that are clustered within the C-terminal domain remote from the Zn-binding consensus sequence HEICH. In contrast, Cys68, which resides within the stalk region seven residues from the end of the hydrophobic membrane-spanning domain, can be replaced by serine without a significant change in the enzymatic activity. Interestingly, this residue is involved in the formation of an interchain disulfide bridge. Covalent dimerization of the subunits, however, does not seem to be essential for efficient biosynthesis, enzymatic activity and trafficking to the cell surface.     

Lactoperoxidase folding and catalysis relies on the stabilization of the alpha-helix rich core domain: a thermal unfolding study

Lactoperoxidase (LPO) belongs to the mammalian peroxidase family and catalyzes the oxidation of halides, pseudo-halides and a number of aromatic substrates at the expense of hydrogen peroxide. Despite the complex physiological role of LPO and its potential involvement in carcinogenic mechanisms, cystic fibrosis and inflammatory processes, little is known on the folding and structural stability of this protein. We have undertaken an investigation of the conformational dynamics and catalytic properties of LPO during thermal unfolding, using complementary biophysical techniques (differential scanning calorimetry, electron spin resonance, optical absorption, fluorescence and circular dichroism spectroscopies) together with biological activity assays. LPO is a particularly stable protein, capable of maintaining catalysis and structural integrity up to a high temperature, undergoing irreversible unfolding at 70 degrees C. We have observed that the first stages of the thermal denaturation involve a minor conformational change occurring at 40 degrees C, possibly at the level of the protein beta-sheets, which nevertheless does not result in an unfolding transition. Only at higher temperature, the protein hydrophobic core, which is rich in alpha-helices, unfolds with concomitant disruption of the catalytic heme pocket and activity loss. Evidences concerning the stabilizing role of the disulfide bridges and the covalently bound heme cofactor are shown and discussed in the context of understanding the structural stability determinants in a relatively large protein.     

Disulfide bridges in interleukin-8 probed using non-natural disulfide analogues: dissociation of roles in structure from function.

The structural and functional roles of the two disulfide bridges in interleukin-8 (IL-8) were addressed using IL-8 analogues with covalently modified disulfide bridges. The analogues were prepared using chemical synthesis by replacement of a cysteine for either homocysteine, penicillamine, or selenocysteine and on folding resulted in a covalently modified disulfide. Deletion of either of the two disulfide bridges by replacement of either cysteine pair with alanine resulted in loss of both structure and function. In contrast, all of the analogues with modified disulfide bridges had native tertiary fold as determined by nuclear magnetic resonance spectroscopic methods. Their structural similarity provided a rational basis for assessing the functional effects of the changes to the disulfide. Modification to the disulfide bridge between cysteines 9 and 50 had only a modest effect on IL-8 function. In contrast, alterations to the 7-34 disulfide bridge resulted in a dramatic reduction in biological potency. Thus, although both disulfide bridges are required for maintenance of the native tertiary fold, their role in determining IL-8 activity is distinct. We propose that 7-34 disulfide has a direct role in determining receptor binding and activation, whereas the 9-50 was not directly involved. The synthesis of non-natural disulfide analogues is a novel general approach to structure-activity relationships of disulfide bridges. The demonstration that the participation of disulfide bridges in function can be dissociated from their effects on the stability of the tertiary structure suggests that this method will lead to increased understanding of the roles of disulfide bridges in proteins.     

Role of disulfide bonds in conformational stability and folding of 5′-deoxy-5′-methylthioadenosine phosphorylase II from the hyperthermophilic archaeon Sulfolobus solfataricus

Sulfolobus solfataricus 5′-deoxy-5′-melthylthioadenosine phosphorylase II (SsMTAPII), is a hyperthermophilic hexameric protein with two intrasubunit disulfide bonds (C138–C205 and C200–C262) and a CXC motif (C259–C261). To get information on the role played by these covalent links in stability and folding, the conformational stability of SsMTAPII and C262S and C259S/C261S mutants was studied by thermal and guanidinium chloride (GdmCl)-induced unfolding and analyzed by fluorescence spectroscopy, circular dichroism, and SDS-PAGE. No thermal unfolding transition of SsMTAPII can be obtained under nonreducing conditions, while in the presence of the reducing agent Tris-(2-carboxyethyl) phosphine (TCEP), a Tm of 100 °C can be measured demonstrating the involvement of disulfide bridges in enzyme thermostability. Different from the wild-type, C262S and C259S/C261S show complete thermal denaturation curves with sigmoidal transitions centered at 102 °C and 99 °C respectively. Under reducing conditions these values decrease by 4 °C and 8 °C respectively, highlighting the important role exerted by the CXC disulfide on enzyme thermostability. The contribution of disulfide bonds to the conformational stability of SsMTAPII was further assessed by GdmCl-induced unfolding experiments carried out under reducing and nonreducing conditions. Thermal unfolding was found to be reversible if the protein was heated in the presence of TCEP up to 90 °C but irreversible above this temperature because of aggregation. In analogy, only chemical unfolding carried out in the presence of reducing agents resulted in a reversible process suggesting that disulfide bonds play a role in enzyme denaturation. Thermal and chemical unfolding of SsMTAPII occur with dissociation of the native hexameric state into denatured monomers, as indicated by SDS-PAGE.