Interactions between mastoparan B and the membrane studied by 1H NMR spectroscopy

Mastoparan B (MP-B) is an antimicrobial cationic tetradecapeptide amide isolated from the venom of the hornet Vespa basalis. NMR spectroscopy was used to study the membrane associated structures of MP-B in various model membrane systems such as 120 mM DPC micelles, 200 mM SDS micelles, and 3%(w/v) DMPC/DHPC (1:2) bicelles. In all systems, MP-B has an amphiphilic alpha-helical structure from Lys2 to Leu14. NOESY experiments performed on MP-B in nondeuterated SDS micelles show that protons in the indole ring of Trp9 are in close contact with methylene protons of SDS micelles. T1 relaxation data and NOE data revealed that the bound form of MP-B may be dominant in SDS micelles. The interactions between MP-B and zwitterionic DPC micelles were much weaker than those between MP-B and anionic SDS micelles. By substitution of Trp9 with Ala9, the pore-forming activity of MP-B was decreased dramatically. All of these results imply that strong electrostatic interactions between the positively charged Lys residues in MP-B and the anionic phospholipid head groups must be the primary factor for MP-B binding to the cell membrane. Then, insertion of the indole ring of Trp9 into the membrane, as well as the amphiphilic alpha-helical structures of MP-B may allow MP-B to span the lipid bilayer through the C-terminal portion. These structural features are crucial for the potent antibiotic activities of MP-B.     

Determining the effect of the incorporation of unnatural amino acids into antimicrobial peptides on the interactions with zwitterionic and anionic membrane model systems

Circular Dichroism (CD), isothermal calorimetry (ITC) and calcein fluorescence leakage experiments were conducted to provide insight into the mechanisms of binding of a series of antimicrobial peptides containing unnatural amino acids (Ac-XF-Tic-Oic-XK-Tic-Oic-XF-Tic-Oic-XK-Tic-KKKK-CONH₂) to zwitterionic and anionic micelles, SUVs and LUVs; where X (Spacer# 1) is either Gly, β-Ala, Gaba or 6-aminohexanoic acid. It is the intent of this investigation to correlate these interactions with the observed potency and selectivity against several different strains of bacteria. The CD spectra of these compounds in the presence of zwitterionic DPC micelles and anionic SDS micelles are very different indicating that these compounds adopt different conformations on binding to the surface of anionic and zwitterionic membrane models. These compounds also exhibited very different CD spectra in the presence of zwitterionic POPC and anionic mixed 4:1 POPC/POPG SUVs and LUVs, indicating the formation of different conformations on interaction with the two membrane types. This observation is also supported by ITC and calcein leakage data. ITC data suggested these peptides interact primarily with the surface of zwitterionic LUVs and was further supported by fluorescence experiments where the interactions do not appear to be concentration dependent. In the presence of anionic membranes, the interactions appear more complex and the calorimetric and fluorescence data both imply pore formation is dependent on peptide concentration. Furthermore, evidence suggests that as the length of Spacer# 1 increases the mechanism of pore formation also changes. Based on the observed differences in the mechanisms of interactions with zwitterionic and anionic LUVs these AMPs are potential candidates for further drug development.     

Structure‐activity relationship of Trp‐containing analogs of the antimicrobial peptide gomesin

Gomesin (Gm) has a broad antimicrobial activity making it of great interest for development of drugs. In this study, we analyzed three Gm analogs, [Trp¹]‐Gm, [Trp⁷]‐Gm, and [Trp⁹]‐Gm, in an attempt to gain insight into the contributions of different regions of the peptide sequence to its activity. The incorporation of the tryptophan residue in different positions has no effect on the antimicrobial and hemolytic activities of the Gm analogs in relation to Gm. Spectroscopic studies (circular dichroism, fluorescence and absorbance) of Gm and its analogs were performed in the presence of SDS, below and above its critical micelle concentration (CMC) (~8 mM), in order to monitor structural changes induced by the interaction with this anionic surfactant (0–15 mM). Interestingly, we found that the analogs interact more strongly with SDS at low concentrations (0.3‐6.0 mM) than close to or above its CMC. This suggests that SDS monomers are able to cover the whole peptide, forming large detergent‐peptide aggregates. On the other hand, the peptides interact differently with SDS micelles, inserting partially into the micelle core. Among the peptides, Trp in position 1 becomes more motionally‐restricted in the presence of SDS, probably because this residue is located at the N‐terminal region, which presents higher conformational freedom to interact stronger with SDS molecules. Trp residues in positions 7 and 9, close to and in the region of the turn of the molecule, respectively, induced a more constrained structure and the compounds cannot insert deeper into the micelle core or be completely buried by SDS monomers. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Conformation and interactions of bombolitin I analogues with SDS micelles and phospholipid vesicles: CD,fluorescence, two-dimensional NMR and computer simulations

Bombolitins are five structurally related heptadecapeptides acting at the membrane level able to lyse erythrocytes and liposomes and to enhance the activity of phospholipase A ₂(PLA₂). In the presence of SDS or phospholipid vesicles bombolitins are able to form amphiphilic α-helical structures and this property seems to be the major determinant of bioactivity. In order to test the model of interaction between bombolitin I and membranes, an analogue was synthesized in which all the lysines were replaced by arginines: ([Arg^2,9,12, Ile¹⁰] bornbolitin I). The design ofthis sequence allowed the synthesis of a second analogue through a specijic postsynthetic dansylation at the ?-amino group qf a lysine residue replacing the original leucine residue at position 7. The, first analogue was, fiilly characterized by CD and two-dimensional nmr in the presence of SDS or phospholipid vesicles. The peptide, folds into an amphiphilic α-helical confbrrnation with the helical segment spanning the central part of the sequencefrom Ile³ to His¹⁶. This behavior is identical to that observed for the native sequence. The replacement of Iysine residues by arginine hus no detectable effect on the conformational prderence of the peptide chain. By CD and fluorescence spectroscopy measurements, the fluorophore-containing analogue [Arg^2,9,12, Lys⁷(?-dansyl)] bombolitin I also folded into the α-helical conformation in the presence of SDS micelles or phospholipid vesicles. In particular, the dansyl fluorophore, which is located approximately in the middle of the apolar surface ojthe amphiphilic helix, is clearly buried in a hydrophobic environment when the peptide is bound to phospholipid vesicles. These findings support the hypothesis that the peptide helices are oriented parallel to the vesicle surface. © 1995 John Wiley & Sons, Inc.     

Micelle bound structure and DNA interaction of brevinin‐2‐related peptide,an antimicrobial peptide derived from frog skin

Brevinin‐2‐related peptide (BR‐II), a novel antimicrobial peptide isolated from the skin of frog, Rana septentrionalis, shows a broad spectrum of antimicrobial activity with low haemolytic activity. It has also been shown to have antiviral activity, specifically to protect cells from infection by HIV‐1. To understand the active conformation of the BR‐II peptide in membranes, we have investigated the interaction of BR‐II with the prokaryotic and eukaryotic membrane‐mimetic micelles such as sodium dodecylsulfate (SDS) and dodecylphosphocholine (DPC), respectively. The interactions were studied using fluorescence and circular dichroism (CD) spectroscopy. Fluorescence experiments revealed that the N‐terminus tryptophan residue of BR‐II interacts with the hydrophobic core of the membrane mimicking micelles. The CD results suggest that interactions with membrane‐mimetic micelles induce an α‐helix conformation in BR‐II. We have also determined the solution structures of BR‐II in DPC and SDS micelles using NMR spectroscopy. The structural comparison of BR‐II in the presence of SDS and DPC micelles showed significant conformational changes in the residues connecting the N‐terminus and C‐terminus helices. The ability of BR‐II to bind DNA was elucidated by agarose gel retardation and fluorescence experiments. The structural differences of BR‐II in zwitterionic versus anionic membrane mimics and the DNA binding ability of BR‐II collectively contribute to the general understanding of the pharmacological specificity of this peptide towards prokaryotic and eukaryotic membranes and provide insights into its overall antimicrobial mechanism. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

The application of DOSY NMR and molecular dynamics simulations to explore the mechanism(s) of micelle binding of antimicrobial peptides containing unnatural amino acids

Anionic and zwitterionic micelles are often used as simple models for the lipids found in bacterial and mammalian cell membranes to investigate antimicrobial peptide‐lipid interactions. In our laboratory we have employed a variety of 1D, 2D, and diffusion ordered (DOSY) NMR experiments to investigate the interactions of antimicrobial peptides containing unnatural amino acids with SDS and DPC micelles. Complete assignment of the proton spectra of these peptides is prohibited by the incorporation of a high percentage of unnatural amino acids which don't contain amide protons into the backbone. However preliminary assignment of the TOCSY spectra of compound 23 in the presence of both micelles indicated multiple conformers are present as a result of binding to these micelles. Chemical Shift Indexing agreed with previously collected CD spectra that indicated on binding to SDS micelles compound 23 adopts a mixture of α‐helical structures and on binding to DPC micelles this peptide adopts a mixture of helical and β‐turn/sheet like structures. DOSY NMR experiments also indicated that the total positive charge and the relative placement of that charge at the N‐terminus or C‐terminus are important in determining the mole fraction of the peptide that will bind to the different micelles. DOSY and ¹H‐NMR experiments indicated that the length of Spacer #1 plays a major role in defining the binding conformation of these analogs with SDS micelles. Results obtained from molecular simulations studies of the binding of compounds 23 and 36 with SDS micelles were consistent with the observed NMR results. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 548–561, 2013.     

Solution structures and model membrane interactions of Ctriporin,an anti‐methicillin‐resistant Staphylococcus aureus Peptide from Scorpion Venom

Ctriporin peptide (Ctr), a novel antimicrobial peptide isolated from the venom of the scorpion Chaerilus tricostatus, shows a broad‐spectrum of antimicrobial activity and is able to inhibit antibiotic resistant pathogens, including Methicillin resistant Staphylococcus aureus, Methicillin Resistant Coagulase‐negative Staphylococcus, and Penicillin Resistant Staphylococcus epidermidis strains. To understand the active conformation of the Ctr peptide in membranes, we have investigated the interaction of Ctr with the negatively charged and zwitterionic membrane‐mimetic micelles such as sodium dodecyl sulphate (SDS) and n‐dodecylphosphocholine (DPC), respectively. The interactions were studied using fluorescence and circular dichroism (CD) spectroscopy. Fluorescence experiments revealed that the N‐terminus tryptophan residue of Ctr interacted with the hydrophobic core of the membrane mimicking micelles. The CD results suggest that interactions with membrane‐mimetic micelles induce an α‐helix conformation in Ctr. Moreover, we have determined the solution structures of Ctr in SDS and DPC micelles using nuclear magnetic resonance (NMR) spectroscopy. The structural comparison of Ctr in the presence of SDS and DPC micelles showed significant conformational changes. The observed structural differences of Ctr in anionic versus zwitterionic membrane‐mimetic micelles suggest that the mode of interaction of this peptide may be different in two environments which may account for its ability to differentiate bacterial and eukaryotic cell membrane. © 2014 Wiley Periodicals, Inc. Biopolymers 101: 1143–1153, 2014.     

Conformational and functional studies of gomesin analogues by CD, EPR and fluorescence spectroscopies

The aim of this work was to examine the bioactivity and the conformational behavior of some gomesin (Gm) analogues in different environments that mimic the biological membrane/water interface. Thus, manual peptide synthesis was performed by the solid-phase method, antimicrobial activity was evaluated by a liquid growth inhibition assay, and conformational studies were performed making use of several spectroscopic techniques: CD, fluorescence and EPR. [TOAC¹]-Gm; [TOAC¹, Ser^2,6,11,15]-Gm; [Trp⁷]-Gm; [Ser^2,6,11,15, Trp⁷]-Gm; [Trp⁹]-Gm; and [Ser^2,6,11,15, Trp⁹]-Gm were synthesized and tested. The results indicated that incorporation of TOAC or Trp caused no significant reduction of antimicrobial activity; the cyclic analogues presented a β-hairpin conformation similar to that of Gm. All analogues interacted with negatively charged SDS both above and below the detergent's critical micellar concentration (cmc). In contrast, while Gm and [TOAC¹]-Gm required higher LPC concentrations to bind to micelles of this zwitterionic detergent, the cyclic Trp derivatives and the linear derivatives did not seem to interact with this membrane-mimetic system. These data corroborate previous results that suggest that electrostatic interactions with the lipid bilayer of microorganisms play an important role in the mechanism of action of gomesin. Moreover, the results show that hydrophobic interactions also contribute to membrane binding of this antimicrobial peptide.     

Structure analysis of the fourth transmembrane domain of Nramp1 in model membranes

Nramp1 (natural resistance-associated macrophage protein 1) is an integral membrane protein with 12 putative transmembrane domains. As a proton-coupled divalent metal cation transporter, it is involved in defense against intracellular pathogens. Disease-causing mutation in Nramp1 occurring at glycine 169 located within the fourth transmembrane domain (TM4) suggests functional importance of this domain. In this paper, we study the three-dimensional structures of a peptide, corresponding to the TM4 of the wild-type Nramp1, in SDS micelles and 2, 2, 2-trifluoroethanol solvent using CD and NMR spectroscopies. We have found that an α-helix is predominantly induced in membrane-mimetic environments and the folding of the C-terminal residues is regulated by pH in SDS micelles. The peptide is embedded in SDS micelles and self-associated by coiled-coil interactions. The helix of the peptide in TFE is lengthened towards the N-terminus compared with those in SDS micelles at acidic pH and the self-association of the peptide is also observed in TFE. The fact that Mn²⁺ ions are accessible to Asp-14 located in the interior of SDS micelles is found and the binding affinity is increased with increasing pH. The self-association of the peptide may provide a path by which Mn²⁺ ions pass through the membrane.     

The conformation of substance P in lipid environments.

NMR and CD studies have been used to analyze the model membrane-bound structure of the neuropeptide substance P (RPKPQQFFGLM-NH2, SP), which has previously been proposed as the NK1 receptor active form. Conformations were determined for the SP in the presence of aqueous solutions of zwitterionic dodecylphosphocholine (DPC) and anionic sodium dodecylsulfate (SDS) micelles. The two structures are similar, although fast exchange between free and bound forms was observed for SP with DPC micelles, and predominantly bound characteristics were found for SP in SDS. The addition of 150-200 mM NaCl had no observable effect on the bound conformation in either case. Thus, the structure of SP at a micelle surface is determined largely by hydrophobic forces, and the electrostatic interactions determine the amount of SP that is bound.     

Cys-labeling kinetics of membrane protein GlpG: a role for specific SDS binding and micelle changes?

Empirically, α-helical membrane protein folding stability in surfactant micelles can be tuned by varying the mole fraction MF^SDS of anionic (sodium dodecyl sulfate (SDS)) relative to nonionic (e.g., dodecyl maltoside (DDM)) surfactant, but we lack a satisfying physical explanation of this phenomenon. Cysteine labeling (CL) has thus far only been used to study the topology of membrane proteins, not their stability or folding behavior. Here, we use CL to investigate membrane protein folding in mixed DDM-SDS micelles. Labeling kinetics of the intramembrane protease GlpG are consistent with simple two-state unfolding-and-exchange rates for seven single-Cys GlpG variants over most of the explored MF^SDS range, along with exchange from the native state at low MF^SDS (which inconveniently precludes measurement of unfolding kinetics under native conditions). However, for two mutants, labeling rates decline with MF^SDS at 0–0.2 MF^SDS (i.e., native conditions). Thus, an increase in MF^SDS seems to be a protective factor for these two positions, but not for the five others. We propose different scenarios to explain this and find the most plausible ones to involve preferential binding of SDS monomers to the site of CL (based on computational simulations) along with changes in size and shape of the mixed micelle with changing MF^SDS (based on SAXS studies). These nonlinear impacts on protein stability highlights a multifaceted role for SDS in membrane protein denaturation, involving both direct interactions of monomeric SDS and changes in micelle size and shape along with the general effects on protein stability of changes in micelle composition.     

Solution structure of neuromedin B by (1)H nuclear magnetic resonance spectroscopy.

The solution structure of neuromedin B (NMB) was investigated using two-dimensional nuclear magnetic resonance (NMR) spectroscopy in membrane-mimicking environments. NMB adopts a relaxed helical conformation from Trp(4) to Met(10) in 50% aqueous 2,2, 2-trifluoroethanol (TFE) solution and in 150 mM SDS micelles. Sidechain atoms of the three residues, Trp(4), His(8) and Phe(9) orient toward the same direction and these residues might play a key role on interacting with hydrophobic acyl chains of the phospholipids in the membrane. NOESY experiments performed on NMB in non-deuterated SDS micelle show that aromatic ring protons of Trp(4) and Phe(9) residues are in close contact with methylene protons of SDS micelles. In addition, proton longitudinal relaxation data proved that the interactions between NMB with SDS micelle are characterized as extrinsic interaction. Trp(4) and Phe(9) seem to be important in interaction with receptor and this agrees with the previous studies of structure-activity relationship (Howell, D.C. et al. (1996) Int. J. Pept. Protein Res. 48, 522-531). These conformational features might be helpful in understanding the molecular mechanism of the function of NMB and developing the efficient drugs.     

Denaturation of α-lactalbumin and myoglobin by the anionic biosurfactant rhamnolipid

Glycolipid biosurfactants (GBS) are promising environmentally friendly alternatives to chemical surfactants. Surfactants interact with proteins in many applications, often leading to significant changes in protein properties. Given GBS' marked difference in structure compared to traditional chemical surfactants, it is of interest to investigate their impact on protein structure and stability. Here we combine spectroscopic and calorimetric studies to analyze the interactions between the anionic GBS rhamnolipid (RL) and two model proteins α-lactalbumin in the Ca^2 +-free apo-form (αLA) and myoglobin (Mb), whose interactions with traditional surfactants are well known. RL denatures αLA at sub-cmc concentrations (0.1–1 mM) while Mb is only denatured above the cmc, i.e. in the presence of RL micelles. Denaturation leads to increased α-helicity, similar to the effect of SDS. The proteins bind approximately the same amount of RL by weight as SDS. However, RL employs a denaturation mechanism which combines features from non-ionic surfactants (very slow unfolding kinetics and few unfolding steps) with those of SDS (unfolding below the cmc in the case of αLA and the ability to unfold stable proteins in the case of Mb). We ascribe these features to RL's weakly acidic carboxylic head group and complex hydrophobic tail, which lead to a low cmc and low protein affinity. These features restrict the concentration range where RL monomers can bind and denature proteins while still allowing micelles to bind and denature to a significant extent.     

NMR structures and molecular dynamics simulation of hylin‐a1 peptide analogs interacting with micelles

Antimicrobial peptides are recognized candidates with pharmaceutical potential against epidemic emerging multi‐drug resistant bacteria. In this study, we use nuclear magnetic resonance spectroscopy and molecular dynamics simulations to determine the unknown structure and evaluate the interaction with dodecylphosphatidylcholine (DPC) and sodium dodecylsulphate (SDS) micelles with three W⁶‐Hylin‐a1 analogs antimicrobial peptides (HyAc, HyK, and HyD). The HyAc, HyK, and HyD bound to DPC micelles are all formed by a unique α‐helix structure. Moreover, all peptides reach the DPC micelles' core, which thus suggests that the N‐terminal modifications do not influence the interaction with zwiterionic surfaces. On the other hand, only HyAc and HyK peptides are able to penetrate the SDS micelle core while HyD remains always at its surface. The stability of the α‐helical structure, after peptide‐membrane interaction, can also be important to the second step of peptide insertion into the membrane hydrophobic core during permeabilization. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

Interactions of an anionic antimicrobial peptide with Staphylococcus aureus membranes

The antimicrobial activity of the anionic peptide, AP1 (GEQGALAQFGEWL), was investigated. AP1 was found to kill Staphylococcus aureus with an MLC of 3 mM and to induce maximal surface pressure changes of 3.8 mN m⁻¹ over 1200 s in monolayers formed from lipid extract of S. aureus membranes. FTIR spectroscopy showed the peptide to be α-helical (100%) in the presence of vesicles formed from this lipid extract and to induce increases in their fluidity (Δν circa 0.5 cm⁻¹). These combined data show that AP1 is able to function as an α-helical antimicrobial peptide against Gram-positive bacteria and suggest that the killing mechanism used by the peptide involves interactions with the membrane lipid headgroup region. Moreover, this killing mechanism differs strongly from that previously reported for AP1 against Gram-negative bacteria, indicating the importance of considering the effects of membrane lipid composition when investigating the structure/function relationships of antimicrobial peptides.     

Identification of an “α-helix-extended segment-α-helix” conformation of the sixth transmembrane domain in DMT1

DMT1 (divalent metal ion transporter 1) is one member of a family of proton-coupled transporters that facilitate the cellular absorption of divalent metal ions. A pair of mutation-sensitive and highly conserved histidines in the sixth transmembrane domain (TM6) of DMT1 was found to be important for proton-metal ion cotransport. In the present work, we investigate the structures and locations of the peptides from TM6 of DMT1 and its H267A and H272A mutants in SDS micelles by CD and NMR methods. The circular dichroism studies show that the α-helix is a predominant conformation for the wildtype peptide and H267A mutant in SDS micelles, whereas the helicity is evidently decreased for H272A mutant. The pH value has little effect on the α-helical contents of the three peptides. The NMR studies indicate that the wildtype peptide in SDS micelles forms an “α-helix-extended segment-α-helix” structure in which the His267 locates near the central part of the extended segment, while the His272 is involved in the α-helical folding. Both histidines are buried in SDS micelles as evidenced by their pK_a values. The structure of the wildtype peptide is evidently changed by the mutations of H267A and H272A. The H267A mutant forms an ordered structure consisting of an α-helix from the C-terminus to the central part and continuous turns in the residual part. The extended structure in the central part of the wildtype peptide is abolished by H267A mutation. The H272A mutation mainly induces unfolding of the short helix in the N-terminal side, while the short helix in the C-terminal side and unordered conformation in the central part remain. All the three peptides are embedded in SDS micelles, and the H267A mutant is inserted more deeply due to increasing hydrophobicity in the central part of the peptide. The specific “α-helix-extended segment-α-helix” structure of TM6 may have an important implication for the binding of the transporter to H⁺ and metal ions and the conformation change induced by the mutations of two highly conserved histidines may be correlated to the deficiency of the transport activity of DMT1.     

Structure and localization of an essential transmembrane segment of the proton translocation channel of yeast H-V-ATPase

Vacuolar (H⁺)-ATPase (V-ATPase) is a proton pump present in several compartments of eukaryotic cells to regulate physiological processes. From biochemical studies it is known that the interaction between arginine 735 present in the seventh transmembrane (TM7) segment from subunit a and specific glutamic acid residues in the subunit c assembly plays an essential role in proton translocation. To provide more detailed structural information about this protein domain, a peptide resembling TM7 (denoted peptide MTM7) from Saccharomyces cerevisiae (yeast) V-ATPase was synthesized and dissolved in two membrane-mimicking solvents: DMSO and SDS. For the first time the secondary structure of the putative TM7 segment from subunit a is obtained by the combined use of CD and NMR spectroscopy. SDS micelles reveal an α-helical conformation for peptide MTM7 and in DMSO three α-helical regions are identified by 2D ¹H-NMR. Based on these conformational findings a new structural model is proposed for the putative TM7 in its natural environment. It is composed of 32 amino acid residues that span the membrane in an α-helical conformation. It starts at the cytoplasmic side at residue T719 and ends at the luminal side at residue W751. Both the luminal and cytoplasmatic regions of TM7 are stabilized by the neighboring hydrophobic transmembrane segments of subunit a and the subunit c assembly from V-ATPase.     

Unfolding a transmembrane helix dimer: A FRET study in mixed micelles

The exact nature of membrane protein folding and assembly is not understood in detail yet. Addition of SDS to a membrane protein dissolved in mild, non-polar detergent results in formation of mixed micelles and in subsequent denaturation of higher ordered membrane protein structures. The exact nature of this denaturation event is, however, enigmatic, and separation of an individual helix pair in mixed micelles has also not been reported yet. Here we followed unfolding of the human glycophorin A transmembrane helix dimer in mixed micelles by fluorescence spectroscopy. Energy transfer between differently labelled glycophorin A transmembrane helices decreased with increasing SDS mole fractions albeit without modifying the helicity of the peptides. The energetics and kinetics of the dimer dissociation in mixed micelles is analyzed and discussed, and the experimental data demonstrate that mixed micelles can be used as a general method to investigate unfolding of α-helical membrane proteins.     

The structure of α-amanitin in dimethylsulfoxide solution

The backbone and side-chain conformations of the bicyclic octapeptide α-amanitin indimethylsulfoxide (DMSO) solution have ben deduced from analysis of the nmr spectrl parameters and conformational energy calculations. Several ambiguities in the nmr spectral assignments were resolved following a comparison with the recently published conformation of β-amanitin in the crystalline state. The peptide proton exchange and temperature coefficient data demonstrate strong intramolecular hyfrogen bonds for the GLY⁵ and Cys⁸ peptide protons. The vicinal proton coupling constants are consistent with the cyclic octapeptide udergoing chain reversl at the Ile⁶-Gly⁷ abd the Hyp²-Hyi³ dipeptide segments. The upfield shifts of the glycine and isoleucine protons demonstrate the folding of the indole ring of the Trp⁴-Cys⁸ brifge towards the Gly⁵-Ile⁶-Gly⁷ half of the Ile-amanitin molecule. The structure af α-amanitin in DMSO is defined by the (?ψ) backbone rotation angles Trp⁴(?90, ?60), Gly⁵ (+120, ?120), Ile⁶(?6, +120), Gly⁷ (+45, +60), Cys⁸(?120, ?60), Asn¹ (+175, ?175), Hyp² (?160, ?45), and Hyi³ (?90, ?60). The study demonstrates that the structure of α-amanitin in solution is similar to the structure f β-amanitin in the crystalline state.     

The conformation of the cytoplasmic helix 8 of the CB1 cannabinoid receptor using NMR and circular dichroism

The cytoplasmic helix domain (fourth cytoplasmic loop, helix 8) of numerous GPCRs such as rhodopsin and the β-adrenergic receptor exhibits unique structural and functional characteristics. Computational models also predict the existence of such a structural motif within the CB1 cannabinoid receptor, another member of the G-protein coupled receptor superfamily. To gain insights into the conformational properties of this GPCR component, a peptide corresponding to helix 8 of the CB1 receptor with a small contiguous segment from transmembrane helix 7 (TM7) was chemically synthesized and its secondary structure determined by circular dichroism (CD) and solution NMR spectroscopy. Our studies in DPC and SDS micelles revealed significant α-helical structure while in an aqueous medium, the peptide exhibited a random coil configuration. The relative orientation of helix 8 within the CB1 receptor was obtained from intermolecular ³¹P-¹H and ¹H-¹H NOE measurements. Our results suggest that in the presence of an amphipathic membrane environment, helix 8 assumes an alpha helical structure with an orientation parallel to the phospholipid membrane surface and perpendicular to TM7. In this model, positively charged side chains interact with the lipid headgroups while the other polar side chains face the aqueous region. The above observations may be relevant to the activation/deactivation of the CB1 receptor.