Specific interactions of sticholysin I with model membranes: An NMR study

Sticholysin I (StnI) is an actinoporin produced by the sea anemone Stichodactyla helianthus that binds biological and model membranes forming oligomeric pores. Both a surface cluster of aromatic rings and the N‐terminal region are involved in pore formation. To characterize the membrane binding by StnI, we have studied by ¹H‐NMR the environment of these regions in water and in the presence of membrane‐mimicking micelles. Unlike other peptides from homologous actinoporins, the synthetic peptide corresponding to residues 1–30 tends to form helix in water and is more helical in either trifluoroethanol or dodecylphosphocholine (DPC) micelles. In these environments, it forms a helix‐turn‐helix motif with the last α‐helical segment matching the native helix‐α₁ (residues 14–24) present in the complete protein. The first helix (residues 4–9) is less populated and is not present in the water‐soluble protein structure. The characterization of wild‐type StnI structure in micelles shows that the helix‐α₁ is maintained in its native structure and that this micellar environment does not provoke its detachment from the protein core. Finally, the study of the aromatic resonances has shown that the motional flexibility of specific rings is perturbed in the presence of micelles. On these bases, the implication of the aromatic rings of Trp‐111, Tyr‐112, Trp‐115, Tyr‐132, Tyr‐136, and Tyr‐137, in the interaction between StnI and the micelle is discussed. Based on all the findings, a revised model for StnI interaction with membranes is proposed, which accounts for differences in its behavior as compared with other highly homologous sticholysins. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Salt-induced conformational change of random copolymers (Lys50Tyr50)n and (Lys50Phe50)n studied by 1H- and 13C-nuclear magnetic resonances. Aggregation behavior of helical segments

¹H- and ¹³C-nmr studies of conformational transitions of random amino acid copolymers containing aromatic residues (Lys⁵⁰Tyr⁵⁰)_n and (Lys⁵⁰Phe⁵⁰)_n in the presence of neutral salts were performed to serve as models of the aggregation behavior of polypeptides of biological significance. The ¹H and ¹³C signal intensities of Tyr and Phe residues decreased preferentially with increasing concentration of neutral salts such as NaCl and NaClO₄. This behavior contrasts with that of (Lys)_n in the presence of similar neutral salts, where the displacement of the ¹³C signal is clearly seen on transition from the random-coil to the helical conformation. On the basis of the previous conformational studies, the loss of the peak areas is ascribed to the presence of immobilized helical segments by hydrophobic interaction between aromatic side chains. The remaining resonances are due to the residual random-coil regions, since the values of nuclear Overhauser enhancements and chemical shifts are unchanged in the presence and absence of the neutral salts.     

Methanol-stabilized intermediates in the thermal unfolding of ribonuclease A: Characterization by 1H nuclear magnetic resonance

The thermal unfolding of ribonuclease A has been studied in solutions of 25, 35 and 50% methanol ($\text{v}\text{v}$), using 360 MHz proton magnetic resonance spectroscopy. Several observations indicate that the native structure of the protein in methanol cryosolvents is very similar to that in aqueous solution. A detailed analysis of the unfolding process has been made using the C-2 protons of the imidazole side-chains of the four histidine residues. As denaturation proceeds new resonances appear, whose chemical shifts correspond to neither native nor fully unfolded species. These have been assigned to particular His residues by selective deuteration studies. The thermal denaturation transitions reveal a multiphasic process in each of the solvents, and become less co-operative with increasing concentrations of methanol. The denaturation is fully reversible with no evidence of hysteresis.The new resonances that appear during the unfolding process are attributed to partially folded species, which are stabilized by the presence of the relatively hydrophobic methanol. Based on the temperature dependence of the chemical shifts and the relative areas of the various resonances, a detailed sequence of events has been proposed to describe the unfolding process. Key features include the initial general loosening of the two domains, the subsequent movement of the upper S-peptide region (residues 13 to 25) away from the main body of the protein, followed by partial separation of the sheet structure and full exposure of the N-terminal helix, leading to complete separation of the “winged domains”, and ultimately the loss of the residual sheet and helix structure.     

1H-Nuclear magnetic-resonance studies on glycophorin and its carbohydrate-containing tryptic peptides.

The proton nuclear magnetic resonance (1H-NMR) spectra of glycophorin and its tryptic sialoglycopeptides were investigated. From the intensities of the assigned resonances it was concluded that all of the residues in the sialoglycopeptides are sufficiently mobile in conformation to give sharp resonances, while in glycophorin this is true for only approximately 80% of the peptide backbone. The resonances of the central sequence of some 20 of the hydrophobic residues are strongly broadened. This region is probably that of alpha-helical structure which is known to aggregate. The linewidths and intensities of the resonances are not, or only slightly, affected by changing the ionic strength, temperature or by carboxymethylation of the Met-81 residue in glycophorin. Glycophorin was found to bind about 100 mol sodium dodecylsulphate/mol protein as derived from studies on linebroadening of the latter's C-3 to C-11 methylene resonances. The bound dodecyl-sulphate probably increases the mobilities of the hydrophobic residues in the protein as these resonance intensities are increased by the binding. The carbohydrate chains in glycophorin were conformationally mobile; no evidence was found for tight carbohydrate-protein interactions. The relevance of flexible carbohydrate chains in membrane glycoproteins is discussed in relation to cell surface chemistry.     

Residual interactions in unfolded bile acid-binding protein by 19F NMR

The folding initiation mechanism of human bile acid-binding protein (BABP) has been examined by (19) F NMR. Equilibrium unfolding studies of BABP labeled with fluorine at all eight of its phenylalanine residues showed that at least two sites experience changes in solvent exposure at high denaturant concentrations. Peak assignments were made by site-specific 4FPhe incorporation. The resonances for proteins specifically labeled at Phe17, Phe47, and Phe63 showed changes in chemical shift at denaturant concentrations at which the remaining five phenylalanine residues appear to be fully solvent-exposed. Phe17 is a helical residue that was not expected to participate in a folding initiation site. Phe47 and Phe63 form part of a hydrophobic core region that may be conserved as a site for folding initiation in the intracellular lipid-binding protein family.     

Omega amino acids in peptide design: incorporation into helices

Incorporation of easily available achiral ω-amino acid residues into an oligopeptide results in substitution of amide bonds by polymethylene units of an aliphatic chain, thereby providing a convenient strategy for constructing a peptidomimetic. The central Gly-Gly segment of the helical octapeptide Boc-Leu-Aib-Val-Gly-Gly-Leu-Aib-Val-Ome(1) has been replaced by δ-amino-valeric acid (δ-Ava) residue in the newly designed peptide Boc-Leu-Aib-Val-δ-Ava-Leu-Aib-Val-OMe(2). ¹H-nmr results clearly suggest that in the apolar solvent CDCl₃, the δ-Ava residue is accommodated into a folded helical conformation, stabilized by successive hydrogen bonds involving the NH groups of Val(3), δ-Ava(4), and Leu(5). The δ-Ava residue must adopt a gauche-gauche-trans-gauche-gauche conformation along the central polymethylene unit of the aliphatic segment, a feature seen in an energy-minimized model conformation based on nmr parameters. The absence of hydrogen bonding functionalities, however, limits the elongation of the helix. In fact, in CDCl₃, the folded conformation consists of an N-terminal helix spanning residues 1–4, followed by a Type II β-turn at residues 5 and 6, whereas in strongly solvating media like (CD₃)₂SO, the unfolding of the N-terminal helix results in β-turn conformations at Leu(1)-Aib(2). The Type II β-turn at the Leu(5)-Aib(6) segment remains intact even in (CD₃)₂SO. CD comparisons of peptides 1 and 2 reveal a “nonhelical” spectrum for 2 in 2,2,2-trifluoroethanol. © 1996 John Wiley & Sons, Inc.     

Synthesis and conformational study of peptides possessing helically arranged ΔZPhe side chains

Z-Dehydrophenylalanine (Δ^zPhe) possessing four oligopeptides, Boc-(L -Ala-Δ^zPhe-Aib)_n-OCH₃ (n = 1–4: Boc, t-butoxycarbonyl; Aib, α-aminoisobutyric acid), were synthesized, and their solution conformations were investigated by ¹H-nmr, ir, uv, and CD spectroscopy and theoretical CD calculation. ¹H-nmr (the solvent accessibility of NH groups) and ir studies indicated that all the NH groups except for those belonging to the N-terminal L -Ala-Δ^zPhe moiety participate in intramolecular hydrogen bonding in chloroform. This suggests that the peptides n = 2–4 have a 4 → 1 hydrogen-bonding pattern characteristic of 3₁₀-helical structures. The uv spectra of all these peptides recorded in chloroform and in trimethyl phosphate showed an intense maximum around 276 nm assigned to the Δ^zPhe chromophores. The corresponding CD spectra of the peptides n = 2–4 showed exciton couplets with a negative peak at longer wavelengths, whereas that of the peptide n = 1 showed only weak signals. Theoretical CD spectra were calculated for the peptides n = 2–4 of several helical conformations, on the basis of exciton chirality method. This calculation indicated that the three peptides form a helical conformation deviating from the perfect 3₁₀-helix that contains three residues per turn, and that their side chains of Δ^z Phe residues are arranged regularly along the helix. The center-to-center distance between the nearest phenyl pair(s) was estimated to be ～ 5.5 Å. The chemical shifts of the Δ^zPhe side-chain protons (H^β and aromatic H) for the peptides n = 2–4 indicated anisotropic shielding effect of neighboring phenyl group(s); the effect also supports a regular arrangement of the Δ^z Phe side chains along the helical axis. © 1993 John Wiley & Sons, Inc.     

Behavior of Solvent-Exposed Hydrophobic Groove in the Anti-Apoptotic Bcl-XL Protein: Clues for Its Ability to Bind Diverse BH3 Ligands from MD Simulations

Bcl-X_L is a member of Bcl-2 family of proteins involved in the regulation of intrinsic pathway of apoptosis. Its overexpression in many human cancers makes it an important target for anti-cancer drugs. Bcl-X_L interacts with the BH3 domain of several pro-apoptotic Bcl-2 partners. This helical bundle protein has a pronounced hydrophobic groove which acts as a binding region for the BH3 domains. Eight independent molecular dynamics simulations of the apo/holo forms of Bcl-X_L were carried out to investigate the behavior of solvent-exposed hydrophobic groove. The simulations used either a twin-range cut-off or particle mesh Ewald (PME) scheme to treat long-range interactions. Destabilization of the BH3 domain-containing helix H2 was observed in all four twin-range cut-off simulations. Most of the other major helices remained stable. The unwinding of H2 can be related to the ability of Bcl-X_L to bind diverse BH3 ligands. The loss of helical character can also be linked to the formation of homo- or hetero-dimers in Bcl-2 proteins. Several experimental studies have suggested that exposure of BH3 domain is a crucial event before they form dimers. Thus unwinding of H2 seems to be functionally very important. The four PME simulations, however, revealed a stable helix H2. It is possible that the H2 unfolding might occur in PME simulations at longer time scales. Hydrophobic residues in the hydrophobic groove are involved in stable interactions among themselves. The solvent accessible surface areas of bulky hydrophobic residues in the groove are significantly buried by the loop LB connecting the helix H2 and subsequent helix. These observations help to understand how the hydrophobic patch in Bcl-X_L remains stable in the solvent-exposed state. We suggest that both the destabilization of helix H2 and the conformational heterogeneity of loop LB are important factors for binding of diverse ligands in the hydrophobic groove of Bcl-X_L.     

Membrane interface composition drives the structure and the tilt of the single transmembrane helix protein PMP1: MD studies

PMP1, a regulatory subunit of the yeast plasma membrane H⁺-ATPase, is a single transmembrane helix protein. Its cytoplasmic C-terminus possesses several positively charged residues and interacts with phosphatidylserine lipids as shown through both ¹H- and ²H-NMR experiments. We used all-atom molecular dynamics simulations to obtain atomic-scale data on the effects of membrane interface lipid composition on PMP1 structure and tilt. PMP1 was embedded in two hydrated bilayers, differing in the composition of the interfacial region. The neutral bilayer is composed of POPC (1-palmitoyl-2-oleoyl-3-glycero-phosphatidylcholine) lipids and the negatively charged bilayer is composed of POPC and anionic POPS (1-palmitoyl-2-oleoyl-3-glycero-phosphatidylserine) lipids. Our results were consistent with NMR data obtained previously, such as a lipid sn-2 chain lying on the W28 aromatic ring and in the groove formed on one side of the PMP1 helix. In pure POPC, the transmembrane helix is two residues longer than the initial structure and the helix tilt remains constant at 6 ± 3°. By contrast, in mixed POPC-POPS, the initial helical structure of PMP1 is stable throughout the simulation time even though the C-terminal residues interact strongly with POPS headgroups, leading to a significant increase of the helix tilt within the membrane to 20 ± 5°.     

Role of the helix capping in the stability of the mouse prion (180-213) segment: investigation through molecular dynamics simulations.

Molecular dynamics simulation of the 180-213 segment, forming the B and C helices in the mouse prion protein, and of three mutants, where the capping box residues or the hydrophobic staple motif residues were selectively mutated, have been carried out. The results indicate that the wild type segment is stable over all the trajectory, whilst the mutants display different degrees of destabilization. In detail mutation of Asp202 brings to a rapid unfolding of helix C likely because of the concomitant loss of a hydrogen bond and of a negative charge able to stabilize the dipole in the first turn of the helix. A lower destabilizing effect is observed upon mutation Thr199. On the other hand mutation of Phe198 and Val203, the hydrophobic staple residues, brings to an incorrect orientation of the first helix relative to the second one due to a weakening of the hydrophobic interaction. The results confirm the importance of the presence of both motifs for the structural integrity of the isolated fragment and suggest that these residues may have a main role in the structural transition observed in the inherited human prion diseases.     

NMR structure and localization of a large fragment of the SARS-CoV fusion protein: Implications in viral cell fusion

The lethal Coronaviruses (CoVs), Severe Acute Respiratory Syndrome-associated Coronavirus (SARS-CoV) and most recently Middle East Respiratory Syndrome Coronavirus, (MERS-CoV) are serious human health hazard. A successful viral infection requires fusion between virus and host cells carried out by the surface spike glycoprotein or S protein of CoV. Current models propose that the S2 subunit of S protein assembled into a hexameric helical bundle exposing hydrophobic fusogenic peptides or fusion peptides (FPs) for membrane insertion. The N-terminus of S2 subunit of SARS-CoV reported to be active in cell fusion whereby FPs have been identified. Atomic-resolution structure of FPs derived either in model membranes or in membrane mimic environment would glean insights toward viral cell fusion mechanism. Here, we have solved 3D structure, dynamics and micelle localization of a 64-residue long fusion peptide or LFP in DPC detergent micelles by NMR methods. Micelle bound structure of LFP is elucidated by the presence of discretely folded helical and intervening loops. The C-terminus region, residues F42-Y62, displays a long hydrophobic helix, whereas the N-terminus is defined by a short amphipathic helix, residues R4-Q12. The intervening residues of LFP assume stretches of loops and helical turns. The N-terminal helix is sustained by close aromatic and aliphatic sidechain packing interactions at the non-polar face. ¹⁵N{¹H}NOE studies indicated dynamical motion, at ps-ns timescale, of the helices of LFP in DPC micelles. PRE NMR showed that insertion of several regions of LFP into DPC micelle core. Together, the current study provides insights toward fusion mechanism of SARS-CoV.     

Structure and potential C-terminal dimerization of a recombinant mutant of surfactant-associated protein C in chloroform/methanol.

The solution structure of a recombinant mutant [rSP-C (FFI)] of the human surfactant-associated protein C (hSP-C) in a mixture of chloroform and methanol was determined by high-resolution NMR spectroscopy. rSP-C (FFI) contains a helix from Phe5 to the C-terminal Leu34 and is thus longer by two residues than the helix of porcine SP-C (pSP-C), which is reported to start at Val7 in the same solvent. Two sets of resonances at the C-terminus of the peptide were observed, which are explained by low-order oligomerization, probably dimerization of rSP-C (FFI) in its alpha-helical form. The dimerization may be induced by hydrogen bonding of the C-terminal carboxylic groups or by the strictly conserved C-terminal heptapeptide segment with a motif similar to the GxxxG dimerization motif of glycophorin A. Dimerization at the heptapeptide segment would be consistent with findings based on electrospray ionization MS data, chemical cross-linking studies, and CNBr cleavage data.     

Terminal effect of chiral residue on helical screw sense in achiral peptides

To understand the terminal effect of chiral residue for determining a helical screw sense, we adopted five kinds of peptides I – V containing N‐ and/or C‐terminal chiral Leu residue(s): Boc–L ‐Leu–(Aib–ΔPhe)₂–Aib–OMe ( I ), Boc–(Aib–ΔPhe)₂–L ‐Leu–OMe ( II ), Boc–L ‐Leu–(Aib–ΔPhe)₂–L ‐Leu–OMe ( III ), Boc–D ‐Leu–(Aib–ΔPhe)₂–L ‐Leu–OMe ( IV ), and Boc–D ‐Leu–(Aib–ΔPhe)₂–Aib–OMe ( V ). The segment –(Aib–ΔPhe)₂– was used for a backbone composed of two “enantiomeric” (left‐/right‐handed) helices. Actually, this could be confirmed by ¹H‐nmr [nuclear Overhauser effect (NOE) and solvent accessibility of NH resonances] and CD spectroscopy on Boc–(Aib–ΔPhe)₂–Aib–OMe, which took a left‐/right‐handed 3₁₀‐helix. Peptides I – V were also found to take 3₁₀‐type helical conformations in CDCl₃, from difference NOE measurement and solvent accessibility of NH resonances. Chloroform, acetonitrile, methanol, and tetrahydrofuran were used for CD measurement. The CD spectra of peptides I – III in all solvents showed marked exciton couplets with a positive peak at longer wavelengths, indicating that their main chains prefer a left‐handed screw sense over a right‐handed one. Peptide V in all solvents showed exciton couplets with a negative peak at longer wavelengths, indicating it prefers a right‐handed screw sense. Peptide IV in chloroform showed a nonsplit type CD pattern having only a small negative signal around 280 nm, meaning that left‐ and right‐handed helices should exist with almost the same content. In the other solvents, peptide IV showed exciton couplets with a negative peak at longer wavelengths, corresponding to a right‐handed screw sense. From conformational energy calculation and the above ¹H‐nmr studies, an N‐ or C‐terminal L ‐Leu residue in the lowest energy left‐handed 3₁₀‐helical conformation was found to take an irregular conformation that deviates from a left‐handed helix. The positional effect of the L ‐residue on helical screw sense was discussed based on CD data of peptides I – V and of Boc–(L ‐Leu–ΔPhe)_n–L ‐Leu–OMe (n = 2 and 3). © 1999 John Wiley & Sons, Inc. Biopoly 49: 551–564, 1999     

Structures of membrane proteins

Summary The possible conformations of integral membrane proteins are restricted by the nature of their environment. In order to satisfy the requirement of maximum hydrogen bonding, those protions of the polypeptide chain which are in contact with lipid hydrocarbon must be organized into regions of regular secondary structure. As possible models of the intramembranous regions of integral membrane proteins, three types of regular structues are discussed. Two, the alpha helix and the beta-pleated sheet, are regularly occurring structural features of soluble proteins. The third is a newly proposed class of conformations called beta helices. These helices have unique features which make them particularly well-suited to the lipid bilayer environment. The central segment of the membrane-spanning protein glycophorin can be arranged into a beta helix with a hydrophobic exterior and a polar interior containing charged amino-acid side chains. Such structures could function as transmembrane ion channels. A model of the activation process based on a hypothetical equilibrium between alpha and beta helical forms of a transmembrane protein is presented. The model can accurately reproduce the kinetics and voltage dependence of the channels in nerve.     

Diffusing and colliding: the atomic level folding/unfolding pathway of a small helical protein

Proteins with ultra-fast folding/unfolding kinetics are excellent candidates for study by molecular dynamics. Here, we describe such simulations of a three helix bundle protein, the engrailed homeodomain (En-HD), which folds via the diffusion-collision model. The unfolding pathway of En-HD was characterized by seven simulations of the protein and 12 simulations of its helical fragments yielding over 1.1 micros of simulation time in water. Various conformational states along the unfolding pathway were identified. There is the compact native-like transition state, a U-shaped helical intermediate and an unfolded state with dynamic helical segments. Each of these states is in good agreement with experimental data. Examining these states as well as the transitions between them, we find the role of long-range tertiary contacts, specifically salt-bridges, important in the folding/unfolding pathway. In the folding direction, charged residues form long-range tertiary contacts before the hydrophobic core is formed. The formation of HII is assisted by a specific salt-bridge and by non-specific (fluctuating) tertiary contacts, which we call contact-assisted helix formation. Salt-bridges persist as the protein approaches the transition state, stabilizing HII until the hydrophobic core is formed. To complement this information, simulations of fragments of En-HD illustrate the helical propensities of the individual segments. By thermal denaturation, HII proved to be the least stable helix, unfolding in less than 450 ps at high temperature. We observed the low helical propensity of C-terminal residues from HIII in fragment simulations which, when compared to En-HD unfolding simulations, link the unraveling of HIII to the initial event that drives the unfolding of En-HD.     

Caveolin-1 hydrophobic segment peptides insertion into membrane mimetic systems: role of proline residue

Caveolin-1 has a segment of hydrophobic amino acids comprising approximately residues 103-122 that are anchored to the membrane with cholesterol-rich domains. Previously, we reported that changing the Pro(110) residue to Ala (the P110A mutant) prevents not only the localization of the protein into lipid rafts but also the formation and functioning of caveolae. The conformational state of caveolin-1 can be shifted toward the transmembrane arrangement by this single amino acid mutation. To model the conformation, and extent of membrane insertion of this segment into membrane-mimetic environments, we have prepared a peptide corresponding to this hydrophobic segment of caveolin-1 having the sequence KKKKLSTIFGIPMALIWGIYFAILKKKKK-amide and the mutated version, KKKKLSTIFGIAMALIWGIYFAILKKKKK-amide. These peptides contain flanking Lys residues to facilitate purification and handling of the peptide. Circular dichroism measurements demonstrated that the mutated peptide has increased helical content compared with the wild type both in the presence and absence of lipid. The fluorescence emission from the Trp residues in the peptide showed significant blue shifts in the presence of liposomes, however the presence of cholesterol in hydrated vesicle bilayers decreases its helical content. Our overall findings support our studies with the intact protein in cells and suggest that the peptide of WT caveolin-1 hydrophobic segment has an intrinsic preference not to maintain its conformation as a rigid transmembrane helix. Substituting the Pro residue with an Ala allows the peptide to exist in a more hydrophobic environment likely as a consequence of a change in its conformation to a straight hydrophobic helix that traverses the membrane.     

Control of Transmembrane Helix Dynamics by Interfacial Tryptophan Residues

Transmembrane protein domains often contain interfacial aromatic residues, which may play a role in the insertion and stability of membrane helices. Residues such as Trp or Tyr, therefore, are often found situated at the lipid-water interface. We have examined the extent to which the precise radial locations of interfacial Trp residues may influence peptide helix orientation and dynamics. To address these questions, we have modified the GW^5,19ALP23 (acetyl-GGALW⁵(LA)₆LW¹⁹LAGA-[ethanol]amide) model peptide framework to relocate the Trp residues. Peptide orientation and dynamics were analyzed by means of solid-state nuclear magnetic resonance (NMR) spectroscopy to monitor specific ²H- and ¹⁵N-labeled residues. GW^5,19ALP23 adopts a defined, tilted orientation within lipid bilayer membranes with minimal evidence of motional averaging of NMR observables, such as ²H quadrupolar or ¹⁵N-¹H dipolar splittings. Here, we examine how peptide dynamics are impacted by relocating the interfacial Trp (W) residues on both ends and opposing faces of the helix, for example by a 100° rotation on the helical wheel for positions 4 and 20. In contrast to GW^5,19ALP23, the modified GW^4,20ALP23 helix experiences more extensive motional averaging of the NMR observables in several lipid bilayers of different thickness. Individual and combined Gaussian analyses of the ²H and ¹⁵N NMR signals confirm that the extent of dynamic averaging, particularly rotational “slippage” about the helix axis, is strongly coupled to the radial distribution of the interfacial Trp residues as well as the bilayer thickness. Additional ²H labels on alanines A3 and A21 reveal partial fraying of the helix ends. Even within the context of partial unwinding, the locations of particular Trp residues around the helix axis are prominent factors for determining transmembrane helix orientation and dynamics within the lipid membrane environment.     

A conserved hydrophobic core at Bcl-xL mediates its structural stability and binding affinity with BH3-domain peptide of pro-apoptotic protein

Bcl-2 family proteins regulate apoptosis through their homo- and heterodimerization. By protein sequence analysis and structural comparison, we have identified a conserved hydrophobic core at the BH1 and BH2 domains of Bcl-2 family proteins. The hydrophobic core is stabilized by hydrophobic interactions among the residues of Trp137, Ile140, Trp181, Ile182, Trp188 and Phe191 in Bcl-x_L. Destabilization of the hydrophobic core can promote the protein unfolding and pore formation in synthetic lipid vesicles. Interestingly, though the hydrophobic core does not participate in binding with BH3 domain of pro-apoptotic proteins, disruption of the hydrophobic core can reduce the affinity of Bcl-x_L with BH3-domain peptide by changing the conformation of Bcl-x_L C-terminal residues that are involved in the peptide interaction. The BH3-domain peptide binding affinity and pore forming propensity of Bcl-x_L were correlated to its death-repressor activity, which provides new information to help study the regulatory mechanism of anti-apoptotic proteins. Meanwhile, as the tryptophans are conserved in the hydrophobic core, in vitro binding assay based on FRET of “Trp → AEDANS” can be devised to screen for new modulators targeting anti-apoptotic proteins as well as “multi-BH domains” pro-apoptotic proteins.     

Nuclear magnetic resonance studies of the unfolding of pancreatic ribonuclease. II. Unfolding by urea and guanidine hydrochloride.

The unfolding of ribonuclease by urea and guanidine hydrochloride has been studied by ¹H nuclear magnetic resonance spectroscopy, under conditions where the unfolding is fully reversible and concentration-independent. Both urea and guanidine produce marked changes in the chemical shift of the histidine C₍₂₎H resonances, together with small changes in other regions of the spectrum, at concentrations (0.1 to 1.0 m) far below those which are required for gross unfolding of the protein. The changes in area of the histidine C₍₂₎H resonances through the major unfolding transition produced by these denaturants give evidence for the existence of at least two intermediates in the unfolding process. The “order of unfolding” of the histidine residues is closely similar for both urea and guanidine hydrochloride unfolding, and also similar to that found for thermal unfolding at low pH (see Benz &; Roberts, 1975) accompanying paper.     

Unfolding pathway of the colicin E1 channel protein on a membrane surface

The channel-forming domain of colicin E1 is composed of a soluble helical bundle which, upon membrane binding, unfolds to form an extended, two-dimensional helical net in the membrane interfacial layer. To characterize the pathway of unfolding of the protein and the structure of the surface-bound intermediate, the time-course of intra-protein distance changes and unfolding on a millisecond time-scale were determined from the kinetics of changes in the efficiency of fluorescence resonance energy transfer, and of the donor-acceptor overlap integral, between each of six individual tryptophan residues and a Cys-conjugated energy transfer acceptor (C509-AEDANS). Comparison of the rate constants revealed the following order of events associated with unfolding of the protein at the membrane surface: (A) movement of the hydrophobic core helices VIII-IX, coincident with a small change in Trp-Cys509 distances of the outer helices; (B) unfolding of surface helices in the helical bundle in the order: helix I, helices III, IV, VI, VII, and helix V; (C) a slow (time-scale, seconds) condensation of the surface-bound helices. The rate of protein unfolding events increased with increasing anionic lipid content. Unfolding did not occur below the lipid thermal phase transition, indicating that unfolding requires mobility in the interfacial layer. The structure of the two-dimensional membrane-bound intermediate in the steady-state was inferred to consist of a quasi-circular arrangement of eight helices embedded in the membrane interfacial layer and anchored by the hydrophobic helical hairpin. The pathway of unfolding of the colicin channel at the membrane surface, catalyzed by electrostatic and hydrophobic forces, is the first described for a membrane-active protein. It is proposed that the pathway and principles described for the colicin protein are relevant to membrane protein import.