Engineering the thermostability of<Emphasis Type="Italic"> Trichoderma reesei</Emphasis> endo-1,4-β-xylanase II by combination of disulphide bridges

Disulphide bridges were introduced in different combinations into the N-terminal region and the single -helix of mesophilic Trichoderma reesei xylanase II (TRX II). We used earlier disulphide-bridge data and designed new disulphide bridges for the combination mutants. The most stable mutant contained two disulphide bridges (between positions 2 and 28 and between positions 110 and 154, respectively) and the mutations N11D, N38E, and Q162H. With a half-life of ~56 h at 65°C, the thermostability of this sevenfold mutant was ~5,000 times higher than that of TRX II, and the half-life was 25 min even at 75°C. The thermostability of this mutant was ~30 times higher than that of the corresponding mutant missing the bridge between positions 2 and 28. The extensive stabilization at two protein regions did not alter the kinetic properties of the sevenfold mutant from that of the wild-type TRX II. The combination of disulphide bridges enhanced significantly the pH-dependent stability in a wide pH range.     

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.     

Stabilization of Escherichia coli ribonuclease H by introduction of an artificial disulfide bond.

To examine the effect of the introduction of a disulfide bond on the stability of Escherichia coli ribonuclease H, a disulfide bond was engineered between Cys13, which is present in the wild-type enzyme, and Cys44, which is substituted for Asn44 by site-directed mutagenesis. The disulfide bond was only formed between these residues upon oxidation in vitro with redox buffer. The conformational and thermal stabilities were estimated from the guanidine hydrochloride and thermal denaturation curves, respectively. The oxidized (cross-linked) mutant enzyme showed a Tm of 62.3 degrees C, which was 11.8 degrees C higher than that observed for the wild-type enzyme. The free energy change of unfolding in the absence of denaturant, delta G[H2O], and the mid-point of the denaturation curve, [D]1/2, of the oxidized mutant enzyme were also increased by 2.1-2.8 kcal/mol and 0.36-0.48 M, respectively. Introduction of a disulfide bond thus greatly enhanced both the thermal and conformational stabilities of the enzyme. In addition, kinetic analyses for the enzymatic activities of mutant enzymes suggest that Thr43 and Asn44 are involved in the substrate-binding site of the enzyme.     

Native-like beta-hairpin retained in the cold-denatured state of bovine beta-lactoglobulin.

Bovine beta-lactoglobulin is denatured by increased temperature (heat denaturation) and by decreased temperature (cold-denaturation) in the presence of 4 M urea at pH 2.5. We characterized the structure of the cold-denatured state of beta-lactoglobulin using circular dichroism (CD), small-angle X-ray scattering (SAXS) and heteronuclear nuclear magnetic resonance (NMR). CD and SAXS indicated that the cold-denatured state, in comparison with the highly denatured state induced by urea, is rather compact, retaining some secondary structure, but no tertiary structure. The location of the residual structures in the cold-denatured state and their stability were characterized by 1H/2H exchange combined with heteronuclear NMR. The results indicated that the residues adjacent to the disulfide bond (C106-C119) connecting beta-strands G and H had markedly high protection factors, suggesting the presence of a native-like beta-hairpin stabilized by the disulfide bond. Since this beta-hairpin is conserved between different conformational states, including the kinetic refolding intermediate, it should be of paramount importance for the folding and stability of beta-lactoglobulin. On the other hand, the non-native alpha-helix suggested for the folding intermediate was not detected in the cold-denatured state. The 1H/2H exchange experiments showed that the protection factors of a mixture of the native and cold-denatured states is strongly biased by that of the labile cold-denatured state, consistent with a two-process model of the exchange.     

Conformational landscape and pathway of disulfide bond reduction of human alpha defensin

Human alpha defensins are a class of antimicrobial peptides with additional antiviral activity. Such antimicrobial peptides constitute a major part of mammalian innate immunity. Alpha defensins contain six cysteines, which form three well defined disulfide bridges under oxidizing conditions. Residues C3-C31, C5-C20, and C10-C30 form disulfide pairs in the native structure of the peptide. The major tissue in which HD5 is expressed is the crypt of the small intestine, an anaerobic niche that should allow for substantial pools of both oxidized and (partly) reduced HD5. We used ion mobility coupled to mass spectrometry to track the structural changes in HD5 upon disulfide bond reduction. We found evidence of stepwise unfolding of HD5 with sequential reduction of the three disulfide bonds. Alkylation of free cysteines followed by tandem mass spectrometry of the corresponding partially reduced states revealed a dominant pathway of reductive unfolding. The majority of HD5 unfolds by initial reduction of C5-C20, followed by C10-C30 and C3-C31. We find additional evidence for a minor pathway that starts with reduction of C3-C31, followed by C5-C20 and C10-C30. Our results provide insight into the pathway and conformational landscape of disulfide bond reduction in HD5.     

Mechanism of stabilization of Bacillus circulans xylanase upon the introduction of disulfide bonds

The introduction of disulfide bonds has been used as a strategy to enhance the stability of Bacillus circulans xylanase. The transition temperature of the S100C/N148C (DS1), V98C/A152C (DS2), and A1GC/G187,C188 (cXl) in comparison to the wild type was increased by 5.0, 4.1 and 3.8 degrees C, respectively. Interestingly, a combination of two disulfide bonds of DS1 and cXl (cDS1, circular disulfide 1) led to a 12 degrees C increase in the transition temperature. Importantly, an increase in the melting point and DeltaDeltaG values of the cDS1 mutant was cooperative. These results suggest that the mechanism of stabilization by disulfide bonds under irreversible denaturation condition is achieved through: (1) a change in the rate-limiting step on the denaturation pathway; (2) destabilizing the unfolded state without affecting the relative rate constants on the denaturation pathway (like cXl mutant); and (3) or combination of the two (cDS1 mutant).     

Disulfide bonds of phospholipase A2 from bee venom yield discrete contributions to its conformational stability

Disulfide bonds are known to be crucial for protein stability. To probe the contribution of each of the five disulfide bonds (C9-C31, C30-C70, C37-C63, C61-C95, and C105-C113) in bee venom phospholipase A₂ to stability, variants with deleted disulfide bonds were produced by substituting two serine residues for each pair of cysteine residues. The mutations started from the pseudo-wild-type variant (pWT) with the mutation I1A (Markert et al., Biotechnol. Bioeng. 98 (2007) 48-59). All variants were expressed in Escherichia coli, refolded from inclusion bodies and purified as pWT. The activity of the variants ranged from 12 to 82% of pWT. From the transition curves of guanidine hydrochloride-induced unfolding, the contributions of the individual disulfide bonds to conformational stability were estimated. They increased in the sequence C9-C31 < C105-C113 < C30-C70 ≈ C37-C63 < C61-C95. For two disulfide bonds (C9-C31, C105-C113) the effects were confirmed on additionally produced variants with the substitution of cysteine by alanine. Despite distinct differences in stability, all variants showed similar cooperativity in unfolding. Selected variants were also probed for proteolytic stability toward thermolysin. The removal of disulfide bonds increased the proteolytic susceptibility of the native proteins in the same way as the stability decreased. From the comparison of the results with literature data on phospholipase A₂ from bovine pancreas possessing seven disulfide bonds, it was concluded that conserved disulfide bonds in homologous proteins fulfill related functions in conformational stability.     

Evidence for an essential role of intradimer interaction in catalytic function of carnosine dipeptidase II using electrospray‐ionization mass spectrometry

Carnosine dipeptidase II (CN2/CNDP2) is an M20 family metallopeptidase that hydrolyses various dipeptides including β‐alanyl‐l ‐histidine (carnosine). Crystallographic analysis showed that CN2 monomer is composed of one catalytic and one dimerization domains, and likely to form homodimer. In this crystal, H228 residue of the dimerization domain interacts with the substrate analogue bestatin on the active site of the dimer counterpart, indicating that H228 is involved in enzymatic reaction. In the present study, the role of intradimer interaction of CN2 in its catalytic activity was investigated using electrospray‐ionization time‐of‐flight mass spectrometry (ESI‐TOF MS). First, a dimer interface mutant I319K was prepared and shown to be present as a folded monomer in solution as examined by using ESI‐TOF MS. Since the mutant was inactive, it was suggested that dimer formation is essential to its enzymatic activity. Next, we prepared H228A and D132A mutant proteins with different N‐terminal extended sequences, which enabled us to monitor dimer exchange reaction by ESI‐TOF MS. The D132A mutant is a metal ligand mutant and also inactive. But the activity was partially recovered time‐dependently when H228A and D132A mutant proteins were incubated together. In parallel, H228A/D132A heterodimer was formed as detected by ESI‐TOF MS, indicating that interaction of a catalytic center with H228 residue of the other subunit is essential to the enzymatic reaction. These results provide evidence showing that intradimer interaction of H228 with the reaction center of the dimer counterpart is essential to the enzymatic activity of CN2.     

Correlations between changes in conformational dynamics and physical stability in a mutant IgG1 mAb engineered for extended serum half-life

This study compares the local conformational dynamics and physical stability of an IgG1 mAb (mAb-A) with its corresponding YTE (M255Y/S257T/T259E) mutant (mAb-E), which was engineered for extended half-life in vivo. Structural dynamics was measured using hydrogen/deuterium (H/D) exchange mass spectrometry while protein stability was measured with differential scanning calorimetry (DSC) and size exclusion chromatography (SEC). The YTE mutation induced differences in H/D exchange kinetics at both pH 6.0 and 7.4. Segments covering the YTE mutation sites and the FcRn binding epitopes showed either subtle or no observable differences in local flexibility. Surprisingly, several adjacent segments in the C_H2 and distant segments in the V_H, C_H1, and V_L domains had significantly increased flexibility in the YTE mutant. Most notable among the observed differences is increased flexibility of the 244–254 segment of the C_H2 domain, where increased flexibility has been shown previously to correlate with decreased conformational stability and increased aggregation propensity in other IgG1 mAbs (e.g., presence of destabilizing additives as well as upon de-glycosylation or methionine oxidation). DSC analysis showed decreases in both thermal onset (T_onset) and unfolding (T_m1) temperatures of 7°C and 6.7°C, respectively, for the C_H2 domain of the YTE mutant. In addition, mAb-E aggregated faster than mAb-A under accelerated stability conditions as measured by SEC analysis. Hence, the relatively lower physical stability of the YTE mutant correlates with increased local flexibility of the 244–254 segment, providing a site-directed mutant example that this segment of the C_H2 domain is an aggregation hot spot in IgG1 mAbs.     

Correlations between changes in conformational dynamics and physical stability in a mutant IgG1 mAb engineered for extended serum half-life

This study compares the local conformational dynamics and physical stability of an IgG1 mAb (mAb-A) with its corresponding YTE (M255Y/S257T/T259E) mutant (mAb-E), which was engineered for extended half-life in vivo. Structural dynamics was measured using hydrogen/deuterium (H/D) exchange mass spectrometry while protein stability was measured with differential scanning calorimetry (DSC) and size exclusion chromatography (SEC). The YTE mutation induced differences in H/D exchange kinetics at both pH 6.0 and 7.4. Segments covering the YTE mutation sites and the FcRn binding epitopes showed either subtle or no observable differences in local flexibility. Surprisingly, several adjacent segments in the C_H2 and distant segments in the V_H, C_H1, and V_L domains had significantly increased flexibility in the YTE mutant. Most notable among the observed differences is increased flexibility of the 244–254 segment of the C_H2 domain, where increased flexibility has been shown previously to correlate with decreased conformational stability and increased aggregation propensity in other IgG1 mAbs (e.g., presence of destabilizing additives as well as upon de-glycosylation or methionine oxidation). DSC analysis showed decreases in both thermal onset (T_onset) and unfolding (T_m1) temperatures of 7°C and 6.7°C, respectively, for the C_H2 domain of the YTE mutant. In addition, mAb-E aggregated faster than mAb-A under accelerated stability conditions as measured by SEC analysis. Hence, the relatively lower physical stability of the YTE mutant correlates with increased local flexibility of the 244–254 segment, providing a site-directed mutant example that this segment of the C_H2 domain is an aggregation hot spot in IgG1 mAbs.     

Contribution of individual disulfide bonds to the oxidative folding of ribonuclease A

The eight cysteine residues of ribonuclease A form four disulfide bonds in the native protein. We have analyzed the folding of three double RNase A mutants (C65A/C72A, C58A/C110A, and C26A/C84A, lacking the C65-C72, C58-C110, and C26-C84 disulfide bonds, respectively) and two single mutants (C110A and C26A), in which a single cysteine is replaced with an alanine and the paired cysteine is present in the reduced form. The folding of these mutants was carried out in the presence of oxidized and reduced glutathione, which constitute the main redox agents present within the ER. The use of mass spectrometry in the analysis of the folding processes allowed us (i) to follow the formation of intermediates and thus the pathway of folding of the RNase A mutants, (ii) to quantitate the intermediates that formed, and (iii) to compare the rates of formation of intermediates. By comparison of the folding kinetics of the mutants with that of wild-type RNase A, the contribution of each disulfide bond to the folding process has been evaluated. In particular, we have found that the folding of the C65A/C72A mutant occurs on the same time scale as that of the wild-type protein, thus suggesting that the removal of the C65-C72 disulfide bond has no effect on the kinetics of RNase A folding. Conversely, the C58A/C110A and C26A/C84A mutants fold much more slowly than the wild-type protein. The removal of the C58-C110 and C26-C84 disulfide bonds has a dramatic effect on the kinetics of RNase A folding. Results described in this paper provide specific information about conformational folding events in the regions involving the mutated cysteine residues, thus contributing to a better understanding of the complex mechanism of oxidative folding.     

Conformational changes in chemically modified Escherichia coli thioredoxin monitored by H/D exchange and electrospray ionization mass spectrometry

Hydrogen/deuterium (H/D) exchange in combination with electrospray ionization mass spectrometry and near-ultraviolet (UV) circular dichroism (CD) was used to study the conformational properties and thermal unfolding of Escherichia coli thioredoxin and its Cys32-alkylated derivatives in 1% acetic acid (pH 2.7). Thermal unfolding of oxidized (Oxi) and reduced (Red) -thioredoxin (TRX) and Cys-32-ethylglutathionyl (GS-ethyl-TRX) and Cys-32-ethylcysteinyl (Cys-ethyl-TRX), which are derivatives of Red-TRX, follow apparent EX1 kinetics as charge-state envelopes, H/D mass spectral exchange profiles, and near-UV CD appear to support a two-state folding/unfolding model. Minor mass peaks in the H/D exchange profiles and nonsuperimposable MS- and CD-derived melting curves, however, suggest the participation of unfolding intermediates leading to the conclusion that the two-state model is an oversimplification of the process. The relative stabilities as measured by melting temperatures by both CD and mass spectral charge states are, Oxi-TRX, GS-ethyl-TRX, Cys-ethyl-TRX, and Red-TRX. The introduction of the Cys-32-ethylglutathionyl group provides extra stabilization that results from additional hydrogen bonding interactions between the ethylglutathionyl group and the protein. Near-UV CD data show that the local environment near the active site is perturbed to almost an identical degree regardless of whether alkylation at Cys-32 is by the ethylglutathionyl group, or the smaller, nonhydrogen-bonding ethylcysteinyl group. Mass spectral data, however, indicate a tighter structure for GS-ethyl-TRX.     

A new approach for weed control in a cucurbit field employing an attenuated potyvirus-vector for herbicide resistance

Thermal stability and other functional properties of Trichoderma reesei endo-1,4-beta-xylanase II (XYNII; family 11) were studied by designed mutations. Mutations at three positions were introduced to the XYNII mutant containing a disulfide bridge (S110C-N154C) in the alpha-helix. The disulfide bridge increased the half-life of XYNII from less than 1 min to 14 min at 65 degrees C. An additional mutation at the C-terminus of the alpha-helix (Q162H or Q162Y) increased the half-life to 63 min. Mutations Q162H and Q162Y alone had a stabilizing effect at 55 degrees C but not at 65 degrees C. The mutations N11D and N38E increased the half-life to about 100 min. Due to the stabilizing mutations the pH stability increased in a wide pH range, but at the same time the activity decreased both in acidic and neutral-alkaline pH, the pH optimum being at pH region 5-6. There was no essential difference between the specific activities of the mutants and the wild-type XYNII.     

Disulfide bond configuration of human cytomegalovirus glycoprotein B

Glycoprotein B (gB) is the most highly conserved of the envelope glycoproteins of human herpesviruses. The gB protein of human cytomegalovirus (CMV) serves multiple roles in the life cycle of the virus. To investigate structural properties of gB that give rise to its function, we sought to determine the disulfide bond arrangement of gB. To this end, a recombinant form of gB (gB-S) comprising the entire ectodomain of the glycoprotein (amino acids 1 to 750) was constructed and expressed in insect cells. Proteolytic fragmentation and mass spectrometry were performed using purified gB-S, and the five disulfide bonds that link 10 of the 11 highly conserved cysteine residues of gB were mapped. These bonds are C94-C550, C111-C506, C246-C250, C344-C391, and C573-C610. This configuration closely parallels the disulfide bond configuration of herpes simplex type 2 (HSV-2) gB (N. Norais, D. Tang, S. Kaur, S. H. Chamberlain, F. R. Masiarz, R. L. Burke, and F. Markus, J. Virol. 70:7379-7387, 1996). However, despite the high degree of conservation of cysteine residues between CMV gB and HSV-2 gB, the disulfide bond arrangements of the two homologs are not identical. We detected a disulfide bond between the conserved cysteine residue 246 and the nonconserved cysteine residue 250 of CMV gB. We hypothesize that this disulfide bond stabilizes a tight loop in the amino-terminal fragment of CMV gB that does not exist in HSV-2 gB. We predicted that the cysteine residue not found in a disulfide bond of CMV gB, cysteine residue 185, would play a role in dimerization, but a cysteine substitution mutant in cysteine residue 185 showed no apparent defect in the ability to form dimers. These results indicate that gB oligomerization involves additional interactions other than a single disulfide bond. This work represents the second reported disulfide bond structure for a herpesvirus gB homolog, and the discovery that the two structures are not identical underscores the importance of empirically determining structures even for highly conserved proteins.     

Biophysical and Structural Characterization of the Thioredoxin-binding Domain of Protein Kinase ASK1 and Its Interaction with Reduced Thioredoxin

Apoptosis signal-regulating kinase 1 (ASK1), a mitogen-activated protein kinase kinase kinase, plays a key role in the pathogenesis of multiple diseases. Its activity is regulated by thioredoxin (TRX1) but the precise mechanism of this regulation is unclear due to the lack of structural data. Here, we performed biophysical and structural characterization of the TRX1-binding domain of ASK1 (ASK1-TBD) and its complex with reduced TRX1. ASK1-TBD is a monomeric and rigid domain that forms a stable complex with reduced TRX1 with 1:1 molar stoichiometry. The binding interaction does not involve the formation of intermolecular disulfide bonds. Residues from the catalytic WCGPC motif of TRX1 are essential for complex stability with Trp³¹ being directly involved in the binding interaction as suggested by time-resolved fluorescence. Small-angle x-ray scattering data reveal a compact and slightly asymmetric shape of ASK1-TBD and suggest reduced TRX1 interacts with this domain through the large binding interface without inducing any dramatic conformational change.     

NMR characterization of three-disulfide variants of lysozyme, C64A/C80A, C76A/C94A, and C30A/C115A--a marginally stable state in folded proteins

Our earlier NMR study showed that a two-disulfide variant of hen lysozyme containing intra-alpha-domain disulfide bridges, C6-C127 and C30-C115, is partially folded, with the alpha domain tightly folded to the nativelike conformation and the beta domain flexible or unfolded. With a view that the formation of a third disulfide bridge is a key for the accomplishment of the overall chain fold, three-dimensional structures of three-disulfide variants of hen lysozyme lacking one disulfide bridge (C64A/C80A, C76A/C94A, and C30A/C115A) were studied in detail using NMR spectroscopy. Amide hydrogen exchange rates were measured to estimate the degree of conformational fluctuation in a residue-specific manner. The structure of C76A/C94A was found to be quite similar to that of the wild type, except for the peptide segment of residues 74-78. The structure of C64A/C80A was considerably disordered in the entire region of the loop (residues 62-79). Further, it was found that a network of hydrogen bonds within the beta sheet and the 3(10) helix in the beta domain were disrupted and fluctuating. In C30A/C115A, the D helix was unstructured and the interface of the B helix with the D helix was significantly perturbed. However, the structural disorder generated in the hydrophobic core of the alpha domain was prevented by the C helix from propagating toward the beta domain. A marginally stable state in folded proteins is discussed based on the structures remaining in each three-disulfide variant.     

Amide hydrogen/deuterium exchange & MALDI-TOF mass spectrometry analysis of Pak2 activation

Amide hydrogen/deuterium exchange (H/D exchange) coupled with mass spectrometry has been widely used to analyze the interface of protein-protein interactions, protein conformational changes, protein dynamics and protein-ligand interactions. H/D exchange on the backbone amide positions has been utilized to measure the deuteration rates of the micro-regions in a protein by mass spectrometry(1,2,3). The resolution of this method depends on pepsin digestion of the deuterated protein of interest into peptides that normally range from 3-20 residues. Although the resolution of H/D exchange measured by mass spectrometry is lower than the single residue resolution measured by the Heteronuclear Single Quantum Coherence (HSQC) method of NMR, the mass spectrometry measurement in H/D exchange is not restricted by the size of the protein(4). H/D exchange is carried out in an aqueous solution which maintains protein conformation. We provide a method that utilizes the MALDI-TOF for detection(2), instead of a HPLC/ESI (electrospray ionization)-MS system(5,6). The MALDI-TOF provides accurate mass intensity data for the peptides of the digested protein, in this case protein kinase Pak2 (also called γ-Pak). Proteolysis of Pak 2 is carried out in an offline pepsin digestion. This alternative method, when the user does not have access to a HPLC and pepsin column connected to mass spectrometry, or when the pepsin column on HPLC does not result in an optimal digestion map, for example, the heavily disulfide-bonded secreted Phospholipase A(2;) (sPLA(2;)). Utilizing this method, we successfully monitored changes in the deuteration level during activation of Pak2 by caspase 3 cleavage and autophosphorylation(7,8,9).     

Effect of the central disulfide bond on the unfolding behavior of elongation factor Ts homodimer from Thermus thermophilus

Functionally active elongation factor Ts (EF-Ts) from Thermus thermophilus forms a homodimer. The dimerization interface of EF-Ts is composed of two antiparallel beta-sheets that can be connected by an intermolecular disulfide bond. The stability of EF-Ts from T. thermophilus in the presence and absence of the intermolecular disulfide bond was studied by differential scanning calorimetry and circular dichroism. The ratio of the van't Hoff and calorimetric enthalpies, delta H(vH)/delta H(cal), indicates that EF-Ts undergoes thermal unfolding as a dimer independently of the presence or absence of the disulfide bond. This can be concluded from (1) the presence of residual secondary structure above the thermal transition temperature, (2) the absence of concentration dependence, which would be expected for dissociation of the dimer prior to unfolding of the monomers, and (3) a relatively low heat capacity change (delta Cp) upon unfolding. The retained dimeric structure of the thermally denatured state allowed for the determination of the effect of the intermolecular disulfide bond on the conformational stability of EF-Ts, which is deltadelta G(S-S,SH HS) = 10.5 kJ/mol per monomer at 72.5 degrees C. The possible physiological implications of the dimeric EF-Ts structure and of the intersubunit disulfide bond for the extreme conformational stability of proteins in thermophiles are discussed.     

Role of helices and loops in the ability of apolipophorin-III to interact with native lipoproteins and form discoidal lipoprotein complexes

The structure of Locusta migratoria apolipophorin-III consists of a five-helix bundle connected by four short loops. The role of the conformational flexibility of helices and loops on the lipid-binding activity of this apolipoprotein was investigated by disulfide mediated tethering experiments. One disulfide mutant tethering the second and fourth loops (L2-L4), and two disulfide mutants restricting the flexibility of the neighboring alpha-helices 3 and 4 (H3-H4) and 1 and 5 (H1-H5), were studied. The ability of the disulfide mutants to interact with phospholipid vesicles, mixed micelles of phosphatidylcholine and cholate, and in vivo with native spherical lipoprotein particles was studied. The L2-L4 mutant was active with native lipoproteins as well as being able to form discoidal lipoproteins upon incubation with either liposomes or discoidal micelles. The H3-H4 mutant was not able to interact with liposomes or native lipoproteins but interacted with discoidal micelles. The H1-H5 mutant was unable to interact with lipid in any of the three systems. Three conclusions were reached: (1) opening of the helix bundle does not require the separation of loops 2 and 4 as recently proposed by others and (2) alpha-helices 3 and/or 4 are involved in the insertion of apoLp-III in both phospholipid bilayers and monolayers. The conformational flexibility of helices 3 and 4 is required for the lipid-binding activity of apoLp-III. (3) Interaction of helices 1 and/or 5 with the lipid surface is required to the formation of stable lipoprotein complexes of any kind.