Structural determinants of protein translocation in bacteria: conformational flexibility of SecA IRA1 loop region.

Bacteria employ the SecA motor protein to push unfolded proteins across the cytoplasmic membrane through the SecY protein-conducting channel complex. The crystal structure of the SecA-SecY complex shows that the intramolecular regulator of ATPase1 (IRA1) SecA domain, made up of two helices and the loop between them, is partly inserted into the SecY conducting channel, with the loop between the helices as the main functional region. A computational analysis suggested that the entire IRA1 domain is structurally autonomous, and was the basis to synthesize peptide analogs of the SecA IRA1 loop region, to the aim of investigating its conformational preferences. Our study indicates that the loop region populates a predominantly flexible state, even in the presence of structuring agent. This provides indirect evidence that the SecA loop-SecY receptor docking involves loop-mediated opening of the SecY channel.

Cold denaturation and aggregation: a comparative NMR study of titin I28 in bulk and in a confined environment.

An NMR study of the thermal stability of titin I28 in the temperature range from -16 to 65 degrees C showed that this protein can undergo cold denaturation at physiological conditions. This is the second case of a protein undergoing unbiased cold denaturation. Comparison of the stability curves in buffer and in crowded conditions shows that it is possible to measure thermodynamics parameters for unfolding even when proteins aggregate at high temperature. The use of confinement in polyacrylamide gels, with the addition of polyethylene glycol, allows easy access to subzero temperatures that might enable studies of cold denaturation of many proteins.

The importance of electrostatic potential in the interaction of sweet proteins with the sweet taste receptor.

In addition to many small molecular mass sweeteners there are in nature a few sweet proteins. The molecular volume of sweet proteins is so different from that of common sweeteners that it was difficult to understand how molecules as large as proteins can activate a receptor designed to host small molecules. We have recently shown that sweet proteins can activate the sweet receptor by a mechanism of interaction, called ''wedge model", in which proteins fit a large cavity of the receptor with wedge-shaped surfaces of their structures. In order to substantiate this model we have designed, expressed and characterized seven mutants of MNEI, a single chain monellin. Three uncharged residues of the interaction surface, Met42, Tyr63 and Tyr65, were changed either into acidic or basic residues whereas Asp68, a key acidic residue, was changed into a basic one. As a general trend, we observe that an increase of the negative charge is much more detrimental for sweetness than an increase of positive charge. In addition we show that by a careful choice of a residue at the center of the interface between MNEI and receptor, it is possible even to increase the sweetness of MNEI. These results are fully consistent with the wedge model.

Conformation-activity relationship of neuropeptide S and some structural mutants: helicity affects their interaction with the receptor.

Neuropeptide S (NPS) is the endogenous ligand of the previously orphan G-protein coupled receptor now named NPSR. The NPS-NPSR receptor system regulates important biological functions such as sleep/waking, locomotion, anxiety and food intake. Recently, exhaustive Ala scan and d-amino acid scan studies, together with systematic N- and C-terminal truncation, led to the identification of key residues for biological activity. Because conformational preferences might also play an important role, we undertook a detailed conformational analysis of NPS and several analogues in solution. We show that helicity induced by substitution of three flexible residues in the 5-13 regulatory region abolishes biological activity. A parallel pharmacological and conformational study of single and multiple substitutions of glycines 5, 7, and 9 showed that helicity can be tolerated in the C-terminal part of the peptide but not around Gly7. The identification of hNPSR partial agonists heralds the possibility of designing pure NPS receptor antagonists.

Structural determinants of unexpected agonist activity in a retro-peptide analogue of the SDF-1alpha N-terminus.

We have synthesised two retro-peptide analogues of the stromal cell derived growth factor 1 (SDF-1alpha) segment known to be critical for CXCR4 receptor binding, corresponding to the sequences HSEFFRCPCRFFESH and HSEFFRGGGRFFESH. We have assayed the ability of these peptides to activate extracellular signal-regulated kinase 1/2 phosphorylation in cells over expressing the SDF-1alpha receptor, finding that the first variant was able to serve as an agonist of CXCR4, whereas the second one was inactive. Finally, by comparing representative solution structures of the two peptides, we have found that the biological response of HSEFFRCPCRFFESH may be ascribed to a beta-beta-type turn motif centred on Phe(4)-Phe(5).

The mechanism of interaction of sweet proteins with the T1R2-T1R3 receptor: evidence from the solution structure of G16A-MNEI.

The mechanism by which sweet proteins elicit a response on the T1R2-T1R3 sweet taste receptor is still mostly unknown but has been so far related to the presence of "sweet fingers" on the protein surface able to interact with the same mechanism as that of low molecular mass sweeteners. In the search for the identification of sweet fingers, we have solved the solution structure of G16A MNEI, a structural mutant that shows a reduction of one order of magnitude in sweetness with respect to its parent protein, MNEI, a single-chain monellin. Comparison of the structures of wild-type monellin and its G16A mutant shows that the mutation does not affect the structure of potential glucophores but produces a distortion of the surface owing to the partial relative displacement of elements of secondary structure. These results show conclusively that sweet proteins do not possess a sweet finger and strongly support the hypothesis that the mechanism of interaction of sweet-tasting proteins with the recently identified T1R2-T1R3 GPC receptor is different from that of low molecular mass sweeteners.

NMR studies of flexible peptides in cavities mimicking the synaptic cleft.

The interaction of neuropeptides with post-synaptic receptors is characterised by a high entropic barrier originating from the combination of nanomolar concentration with low conformer population. The influence of high viscosity environments on conformer distribution can help overcome this difficulty. In an attempt to simulate the physicochemical conditions of the synaptic cleft, (15)N-labelled enkephalin has been studied in polyacrylamide gels swollen by different aqueous solutions in the temperature range 273-293 K. Nuclear Overhauser enhancement spectra in the gel pores are consistent with a conformational selection or a slowing down of internal motions that can favour the interaction of the peptide with the receptor.

Structural characterization of a neurotoxic threonine-rich peptide corresponding to the human prion protein alpha 2-helical 180-195 segment, and comparison with full-length alpha 2-helix-derived peptides.

The 173-195 segment corresponding to the helix 2 of the globular PrP domain is a good candidate to be one of the several 'spots' of intrinsic structural flexibility, which might induce local destabilization and concur to protein transformation, leading to aggregation-prone conformations. Here, we report CD and NMR studies on the alpha2-helix-derived peptide of maximal length (hPrP[180-195]) that is able to exhibit a regular structure different from the prevalently random arrangement of other alpha2-helix-derived peptides. This peptide, which has previously been shown to be affected by buffer composition via the ion charge density dependence typical of Hofmeister effects, corresponds to the C-terminal sequence of the PrP(C) full-length alpha2-helix and includes the highly conserved threonine-rich 188-195 segment. At neutral pH, its conformation is dominated by beta-type contributions, which only very strong environmental modifications are able to modify. On TFE addition, an increase of alpha-helical content can be observed, but a fully helical conformation is only obtained in neat TFE. However, linking of the 173-179 segment, as occurring in wild-type and mutant peptides corresponding to the full-length alpha2-helix, perturbs these intrinsic structural propensities in a manner that depends on whether the environment is water or TFE. Overall, these results confirm that the 180-195 parental region in hPrP(C) makes a strong contribution to the chameleon conformational behavior of the segment corresponding to the full-length alpha2-helix, and could play a role in determining structural rearrangements of the entire globular domain.

Kissper, a kiwi fruit peptide with channel-like activity: structural and functional features.

Kissper is a 39-residue peptide isolated from kiwi fruit (Actinidia deliciosa). Its primary structure, elucidated by direct protein sequencing, is identical to the N-terminal region of kiwellin, a recently reported kiwi fruit allergenic protein, suggesting that kissper derives from the in vivo processing of kiwellin. The peptide does not show high sequence identity with any other polypeptide of known function. However, it displays a pattern of cysteines similar, but not identical, to those observed in some plant and animal proteins, including toxins involved in defence mechanisms. A number of these proteins are also active on mammalian cells. Functional characterization of kissper showed pH-dependent and voltage-gated pore-forming activity, together with anion selectivity and channeling in model synthetic PLMs, made up of POPC and of DOPS:DOPE:POPC. A 2DNMR analysis indicates that in aqueous solution kissper has only short regions of regular secondary structure, without any evident similarity with other bioactive peptides. Comparative analysis of the structural and functional features suggests that kissper is a member of a new class of pore-forming peptides with potential effects on human health.

A new mutant of bovine seminal ribonuclease with a reversed swapping propensity.

Bovine seminal ribonuclease (BS-RNase) is made up of two identical subunits bridged through two disulfide bonds. In solution, it exists as a 2:1 equilibrium mixture between two forms, with (MxM) and without swapping (M=M) of the N-terminal arms. The swapping endows BS-RNase with some special biological functions, including antitumor activity, since MxM retains a dimeric structure even under reducing conditions, thus evading the cytosolic ribonuclease inhibitor. To investigate the structural basis of domain swapping in BS-RNase, we have obtained several mutants by replacing selected residues with the corresponding ones of its monomeric counterpart, bovine pancreatic ribonuclease (RNase A). We have already shown that, in contrast with all other cases of swapped proteins, the swapping propensity of BS-RNase does not depend on the specific sequence of the 16-22 hinge loop, which connects the main body to the dislocating arm. In this paper we report the design, the expression, and the structural characterization of two mutants obtained by replacing Arg80 with Ser either in BS-RNase or in the mutant already containing the 16-22 hinge sequence of RNase A. NMR and circular dichroism data indicate that, in the monomeric form of the latter mutant, Ser80 acts as a switch for the conformation of the hinge region. Accordingly, in the dimeric form of the same mutant the MxM:M=M equilibrium ratio is inverted to 1:2. Overall, these data suggest that the presence of Arg80 triggers the swapping of N-terminal ends and plays a relevant role in the stability of the swapped form of BS-RNase.

NMR structure and CD titration with metal cations of human prion alpha2-helix-related peptides.

The 173-195 segment corresponding to the helix 2 of the C-globular prion protein domain could be one of several "spots" of intrinsic conformational flexibility. In fact, it possesses chameleon conformational behaviour and gathers several disease-associated point mutations. We have performed spectroscopic studies on the wild-type fragment 173-195 and on its D178N mutant dissolved in trifluoroethanol to mimic the in vivo system, both in the presence and in the absence of metal cations. NMR data showed that the structure of the D178N mutant is characterized by two short helices separated by a kink, whereas the wild-type peptide is fully helical. Both peptides retained these structural organizations, as monitored by CD, in the presence of metal cations. NMR spectra were however not in favour of the formation of definite ion-peptide complexes. This agrees with previous evidence that other regions of the prion protein are likely the natural target of metal cation binding.

The alpha-to-beta conformational transition of Alzheimer's Abeta-(1-42) peptide in aqueous media is reversible: a step by step conformational analysis suggests the location of beta conformation seeding.

Current views of the role of beta-amyloid (Abeta) peptide fibrils range from regarding them as the cause of Alzheimer's pathology to having a protective function. In the last few years, it has also been suggested that soluble oligomers might be the most important toxic species. In all cases, the study of the conformational properties of Abeta peptides in soluble form constitutes a basic approach to the design of molecules with "antiamyloid" activity. We have experimentally investigated the conformational path that can lead the Abeta-(1-42) peptide from the native state, which is represented by an alpha helix embedded in the membrane, to the final state in the amyloid fibrils, which is characterized by beta-sheet structures. The conformational steps were monitored by using CD and NMR spectroscopy in media of varying polarities. This was achieved by changing the composition of water and hexafluoroisopropanol (HFIP). In the presence of HFIP, beta conformations can be observed in solutions that have very high water content (up to 99 % water; v/v). These can be turned back to alpha helices simply by adding the appropriate amount of HFIP. The transition of Abeta-(1-42) from alpha to beta conformations occurs when the amount of water is higher than 80 % (v/v). The NMR structure solved in HFIP/H2O with high water content showed that, on going from very apolar to polar environments, the long N-terminal helix is essentially retained, whereas the shorter C-terminal helix is lost. The complete conformational path was investigated in detail with the aid of molecular-dynamics simulations in explicit solvent, which led to the localization of residues that might seed beta conformations. The structures obtained might help to find regions that are more affected by environmental conditions in vivo. This could in turn aid the design of molecules able to inhibit fibril deposition or revert oligomerization processes.

Solution structure of a chemosensory protein from the desert locust Schistocerca gregaria.

Chemical stimuli, generally constituted by small volatile organic molecules, are extremely important for the survival of different insect species. In the course of evolution, insects have developed very sophisticated biochemical systems for the binding and the delivery of specific semiochemicals to their cognate membrane-bound receptors. Chemosensory proteins (CSPs) are a class of small soluble proteins present at high concentration in insect chemosensory organs; they are supposed to be involved in carrying the chemical messages from the environment to the chemosensory receptors. In this paper, we report on the solution structure of CSPsg4, a chemosensory protein from the desert locust Schistocerca gregaria, which is expressed in the antennae and other chemosensory organs. The 3D NMR structure revealed an overall fold consisting of six alpha-helices, spanning residues 13-18, 20-31, 40-54, 62-78, 80-90, and 97-103, connected by loops which in some cases show dihedral angles typical of beta-turns. As in the only other chemosensory protein whose structure has been solved so far, namely, CSP from the moth Mamestra brassicae, four helices are arranged to form a V-shaped motif; another helix runs across the two V's, and the last one is packed against the external face. Analysis of the tertiary structure evidenced multiple hydrophobic cavities which could be involved in ligand binding. In fact, incubation of the protein with a natural ligand, namely, oleamide, produced substantial changes to the NMR spectra, suggesting extensive conformational transitions upon ligand binding.

The interaction of highly helical structural mutants with the NOP receptor discloses the role of the address domain of nociceptin/orphanin FQ.

Nociceptin is a heptadecapeptide whose sequence is similar to that of Dynorphin A, sharing a message domain characterized by two glycines and two aromatic residues, and a highly basic C-terminal address domain but, in spite of these similarities, displays no opioid activity. Establishing the relative importance of the message and address domains of nociceptin has so far been hampered by its extreme conformational flexibility. Here we show that mutants of this peptide, designed to increase the helical content in the address domain, can be employed to explain the mode of interaction with the NOP receptor. Nociceptin analogues in which Ala residues are substituted with aminoisobutyric acid (Aib) show a substantial increment of activity in their interaction with the NOP receptor. The increment of biological activity was attributed to the well-documented ability of Aib to induce helicity. Here we have verified this working hypothesis by a conformational investigation extended to new analogues in which the role of Aib is taken up by Leu. The NMR conformational analysis confirms that all Ala/Aib peptides as well as [Leu(7,11)]-N/OFQ-amide and [Leu(11,15)]-N/OFQ-amide mutants (N/OFQ=nociceptin/orphanin FQ) have comparable helix content in helix-promoting media. We show that the helical address domain of nociceptin can place key basic residues at an optimal distance from complementary acidic groups of the EL(2) loop of the receptor. Our structural data are used to rationalize pharmacological data which show that although [Leu(11,15)]-N/OFQ-amide has an activity comparable to those of Ala/Aib peptides, [Leu(7,11)]-N/OFQ-amide is less active than N/OFQ-amide. We hypothesize that bulky residues cannot be hosted in or near the hinge region (Thr(5)-Gly(6)-Ala(7)) without severe steric clash with the receptor. This hypothesis is also consistent with previous data on this hinge region obtained by systematic substitution of Thr, Gly, and Ala with Pro.

Role of the hinge peptide and the intersubunit interface in the swapping of N-termini in dimeric bovine seminal RNase.

Bovine seminal ribonuclease (BS-RNase) is the only known dimeric enzyme characterized by an equilibrium between two different 3D structures: MxM, with exchange (or swapping) of the N-terminal 1-20 residues, and M=M, without exchange. As a consequence, the hinge region 16-22 has a different tertiary structure in the two forms. In the native protein, the equilibrium ratio between MxM and M=M is about 7 : 3. Kinetic analysis of the swapping process for a recombinant sample shows that it folds mainly in the M=M form, then undergoes interconversion into the MxM form, reaching the same 7 : 3 equilibrium ratio. To investigate the role of the regions that are most affected structurally by the swapping, we expressed variant proteins by replacing two crucial residues with the corresponding ones from RNase A: Pro19, within the hinge peptide, and Leu28, located at the interface between subunits. We compared the structural properties of the monomeric forms of P19A-BS-RNase, L28Q-BS-RNase and P19A/L28Q-BS-RNase variants with those of the parent protein, and investigated the exchange kinetics of the corresponding dimers. The P19A mutation slightly increases the thermal stability of the monomer, but it does not alter the swapping tendency of the dimer. In contrast, the L28Q mutation significantly affects both the dimerization and swapping processes but not the thermal stability of the monomer. Overall, these results suggest that the structural determinants that control the exchange of N-terminal arms in BS-RNase may not be located within the hinge peptide, and point to a crucial role of the interface residues.

Interaction of sweet proteins with their receptor. A conformational study of peptides corresponding to loops of brazzein, monellin and thaumatin.

The mechanism of interaction of sweet proteins with the T1R2-T1R3 sweet taste receptor has not yet been elucidated. Low molecular mass sweeteners and sweet proteins interact with the same receptor, the human T1R2-T1R3 receptor. The presence on the surface of the proteins of "sweet fingers", i.e. protruding features with chemical groups similar to those of low molecular mass sweeteners that can probe the active site of the receptor, would be consistent with a single mechanism for the two classes of compounds. We have synthesized three cyclic peptides corresponding to the best potential "sweet fingers" of brazzein, monellin and thaumatin, the sweet proteins whose structures are well characterized. NMR data show that all three peptides have a clear tendency, in aqueous solution, to assume hairpin conformations consistent with the conformation of the same sequences in the parent proteins. The peptide corresponding to the only possible loop of brazzein, c[CFYDEKRNLQC(37-47)], exists in solution in a well ordered hairpin conformation very similar to that of the same sequence in the parent protein. However, none of the peptides has a sweet taste. This finding strongly suggests that sweet proteins recognize a binding site different from the one that binds small molecular mass sweeteners. The data of the present work support an alternative mechanism of interaction, the "wedge model", recently proposed for sweet proteins [Temussi, P. A. (2002) FEBS Lett.526, 1-3.].

Solution structure of nociceptin peptides.

Peptides embedded in the sequence of pre-pro-nociceptin, i.e. nociceptin, nocistatin and orphanin FQ2, have shed light on the complexity of the mechanisms involving the peptide hormones related to pain and have opened up new perspectives for the clinical treatment of pain. The design of new ligands with high selectivity and bioavailability, in particular for ORL1, is important both for the elucidation and control of the physiological role of the receptor and for their therapeutic importance. The failure to obtain agonists and antagonists when using, for nociceptin, the same substitutions that are successful for opioids, and the conformational flexibility of them all, justify systematic efforts to study the solution conformation under conditions as close as possible to their natural environment. Structural studies of linear peptides in solution are hampered by their high flexibility. A direct structural study of the complex between a peptide and its receptor would overcome this difficulty, but such a study is not easy since opioid receptors are membrane proteins. Thus, conformational studies of lead peptides in solution are still important for drug design. This review deals with conformational studies of natural pre-nociceptin peptides in several solvents that mimic in part the different environments in which the peptides exert their action. None of the structural investigations yielded a completely reliable bioactive conformation, but the global conformation of the peptides in biomimetic environments can shed light on their interaction with receptors.

A synthetic peptide reproducing the mitochondrial targeting motif of AKAP121: a conformational study.

The conformational features of a peptide derived by the 10-30 sequence of the mitochondrial domain of AKAP121 [Ac-1XKKPLALPGMLALLGWWWFFSRKKX25-NH2 (X=beta-Ala)] in water and in a water/trifluoroethanol (TFE) mixture at 298 K have been determined by NMR and CD spectroscopy. Backbone clustering analysis of NMR-derived structures led to the identification of a single representative structure in water/TFE. The structure of the peptide consists mainly of an alpha-helix, whose core is the region 7-23, with a less ordered N-terminal part. These data are confirmed by CD analysis. It is noteworthy that the high hydrophobic Trp16-Phe20 segment, that might also mediate interaction with tubulin, is organized in an alpha-helical wheel. Our conformational data can be the starting point for the development of highly selective peptides that interfere with the biological function of the Protein Kinase A scaffold protein AKAP121.

New antitumour cyclic astin analogues: synthesis, conformation and bioactivity.

Astins, antitumour cyclic pentapeptides, were isolated from the Aster tataricus. Their chemical structures, consist of a 16-membered ring system containing a unique beta,gamma-dichlorinated proline [Pro(Cl)2], other non-coded amino acid residues and a cis conformation in one of the peptide bonds. The astin backbone conformation, along with the cis peptide bond in which the beta,gamma-dichlorinated proline residue is involved, was considered to play an important role in their antineoplastic activities on sarcoma 180A and P388 lymphocytic leukaemia in mice, but the scope and potential applications of this activity remain unclear. With the aim at improving our knowledge of the conformational properties influencing the bioactivity in this class of compounds, new astin-related cyclopeptides were synthesized differing from the natural products by the presence of some non-proteinogenic amino acid residues: Aib, Abu, -(S)beta3-hPhe and a peptide bond surrogate (-SO2-NH-). The analogues prepared c(-Pro-Thr-Aib-beta3-Phe-Abu-), c[Pro-Thr-Aib-(S)beta3-hPhe-Abu], c[Pro-Abu-Ser-(S)beta3-hPhe psi(CH2-SO2-NH)-Abu] and c[Pro-Thr-Aib-(S)beta3-hPhe psi(CH2-SO2-NH)-Abu] were synthesized by classical methods in solution and tested for their antitumour effect. These molecules were studied by crystal-state x-ray diffraction analysis and/or solution NMR and MD techniques.

Influence of conformational flexibility on biological activity in cyclic astin analogues.

The astins, a family of natural antitumor cyclopeptides, from the roots of Aster tataricus, consist of a 16-membered ring system containing uncoded amino acid residues. The backbone conformation, with a cis-3,4-dichlorinated proline residue, plays an important role in antineoplastic activity. The acyclic astins, on the other hand, do not show antitumor activity, suggesting that the cyclic nature of astins may be a key role in their biological properties. Although the antineoplastic activity of natural astins has been screened in vitro and in vivo, the mechanism of action has never been investigated. With the aim at elucidating the influence of conformational flexibility on biological activity, we have designed and synthesized several astin analogues containing either Aib and the nonproteinogenic Abu and (S)beta3-hPhe residues, able to modify the peptide backbone structure, or the peptide bond surrogate -SO2-NH-. Tested for their antitumor effect, our astin-related cyclopeptides are able to inhibit the growth of tumor cell lines, while the acyclic astins are inefficacious. The present work reports on the structure-activity study of a selected synthetic cyclotetrapeptide corresponding to the sequence c[Thr-Aib-(S)beta3-hPhePsi(CH2-SO2-NH)-Abu], synthesized by classical methods and characterized conformationally by two-dimensional NMR and molecular dynamics analyses.