5CINECA Supercomputing Centre. 6University of Modena and Reggio Emilia.7Christian-Albrechts-University Kiel.8Michigan State University. International course and report were conceived by Pietro Cozzini and Glen E. Kellogg. * To whom correspondence should be addressed. For G.E.K.: Department of Medicinal Chemistry, Virginia Commonwealth University, Box 980540, Richmond, VA 23298-0540; (phone) 804-828-6452; (fax) 804-827-3664; (e-mail) glen.kellogg@vcu.edu. For P.C.: Department of General and Inorganic Chemistry, University of Parma, Via G.P. Usberti 17/A 43100, Parma, Italy; (phone) +39-0521-905669; (fax) +39-0521-905556; (e-mail) pietro.cozzini@unipr.it. NIH Public Access IntroductionStructure-based drug discovery has played an important role in medicinal chemistry 1 beginning nearly when the first X-ray crystal structure of the myoglobin and hemoglobin proteins at nearatomic resolution were described by Perutz, Kendrew and colleagues. 2-5 Even though only static structures were (and still generally are) used for most Structure-Based Drug Design (SBDD), and indeed most molecular modeling, the importance of flexibility was recognized immediately: hemoglobin has two rather different structures, "tense" and "relaxed", depending on its oxygenation, although in recent years a family of relaxed hemoglobin structures with different tertiary structure conformations have been reported. 6 In fact, all proteins are inherently flexible systems. This flexibility is frequently essential for function (e.g., as in hemoglobin). Proteins have an intrinsic ability to undergo functionally relevant conformational transitions under native state conditions, 7,8 on a wide range of scales, both in time and space. 9 In adenylate kinase large conformational changes due to movements of the nucleotide 'lids'-rate-limiting for overall catalytic turnover 10,11 -are 'linked' with relatively small-amplitude atomic fluctuations on the ps timescale such that changes in the local backbone conformation are required for lid closure. 12 Nuclear receptors are modular proteins where a significant degree of conformational flexibility is essential to biological function. Most of the pharmacology of nuclear receptor ligands has been discussed on the basis of their ability to stabilize (or displace) a short α-helix segment (known as H12 or AF-2) localized at the carboxy terminus of the receptor in (or from) its conformation in the protein "active" form. 13-15 Available X-ray crystal structures show a surprisingly wide range of structural diversity in ligands binding to, and inhibiting, nuclear receptor proteins such as the farnesoid X-receptor (FXR). 16,17 Protein dynamics is also a key component of intramolecular and intermolecular communication/signaling mechanisms and an essential requirement for the function of Gprotein coupled receptors (GPCRs), which are the largest known superfamily of membrane proteins. GPCRs regulate cell activity by transmitting extracellular signals to the inside of cells and respond to these signals by catalyzing nucleotide e...
The substitution of alanines for the two cysteines which form thioether linkages to the haem group in cytochrome c 552 from Hydogenobacter thermophilus destabilises the native protein fold. The holo form of this variant slowly converts into a partially folded apo state that over prolonged periods of time aggregates into fibrillar structures. Characterisation of these structures by electron microscopy and thioflavin-T binding assays shows that they are amyloid fibrils. The data demonstrate that when the native state of this cytochrome is destabilised by loss of haem, even this highly K K-helical protein can form L L-sheet structures of the type most commonly associated with protein deposition diseases. ß
Heteronuclear NMR investigations of dynamic regions of intact Escherichia coli ribosomes
15 N-1 H NMR spectroscopy has been used to probe the dynamic properties of uniformly 15 N labeled Escherichia coli ribosomes. Despite the high molecular weight of the complex (Ϸ2.3 MDa), [ 1 H-15 N] heteronuclear single-quantum correlation spectra contain Ϸ100 well resolved resonances, the majority of which arise from two of the four C-terminal domains of the stalk proteins, L7͞L12. Heteronuclear pulse-field gradient NMR experiments show that the resonances arise from species with a translational diffusion constant consistent with that of the intact ribosome. Longitudinal relaxation time (T1) and T1 15 N-spin relaxation measurements show that the observable domains tumble anisotropically, with an apparent rotational correlation time significantly longer than that expected for a free L7͞L12 domain but much shorter than expected for a protein rigidly incorporated within the ribosomal particle. The relaxation data allow the ribosomally bound C-terminal domains to be oriented relative to the rotational diffusion tensor. Binding of elongation factor G to the ribosome results in the disappearance of the resonances of the L7͞L12 domains, indicating a dramatic reduction in their mobility. This result is in agreement with cryoelectron microscopy studies showing that the ribosomal stalk assumes a single rigid orientation upon elongation factor G binding. As well as providing information about the dynamical properties of L7͞L12, these results demonstrate the utility of heteronuclear NMR in the study of mobile regions of large biological complexes and form the basis for further NMR studies of functional ribosomal complexes in the context of protein synthesis. P rotein synthesis in living systems takes place on the ribosome, a complex macromolecular assembly whose structural and functional properties are rapidly emerging from a powerful combination of electron microscopy (EM) and x-ray crystallography (1, 2). In Escherichia coli, the ribosome is composed of 54 different proteins and three RNA molecules (23S, 16S, and 5S rRNA) This 2.3-MDa complex is termed the 70S ribosome and is made up of two components, the 30S and 50S subunits. The translation of genetic information into functional proteins involves a number of auxiliary factors, many of which are GTPases, including IF2, EF-Tu, elongation factor G (EF-G), and RF3 (2). These molecules bind to overlapping sites on the 50S subunit and regulate the transition of the ribosome through various states on the translational pathway. The binding sites are collectively known as the GTPase-associated region, due to the role of this region in stimulating the GTPase activity of the auxiliary factors.The GTPase-associated region (GAR) includes helices 42-44 and 95 (the ␣-sarcin loop) of 23S RNA, and the proteins L10, L11, and L7͞L12 (1). The latter (L7͞L12) is located on the ribosomal stalk and is unique among the ribosomal proteins, because it is the only protein present in multiple copies (four proteins per ribosomal particle). Although atomic details of much of the GAR have been reve...
Sodium dodecyl sulphate (SDS), a detergent that mimics some characteristics of biological membranes, has been found to a¡ect signi¢cantly ¢bril formation by a peptide from human complement receptor 1. In aqueous solution the peptide is unfolded but slowly aggregates to form ¢brils. In sub-micellar concentrations of SDS the peptide is initially K K-helical but converts rapidly to a L L-sheet structure and large quantities of ¢brils form. In SDS above the critical micellar concentration the peptide adopts a stable K K-helical structure and no ¢brils are observed. These ¢ndings demonstrate the sensitivity of ¢bril formation to solution conditions and suggest a possible role for membrane components in amyloid ¢bril formation in living systems.
Model peptides mimic the structure and function of the N‐terminus of the pore‐forming toxin sticholysin II
To investigate the role of the N-terminal region in the lytic mechanism of the pore-forming toxin sticholysin II (St II), we studied the conformational and functional properties of peptides encompassing the first 30 residues of the protein. Peptides containing residues 1-30 (P1-30) and 11-30 (P11-30) were synthesized and their conformational properties were examined in aqueous solution as a function of peptide concentration, pH, ionic strength, and addition of the secondary structure-inducing solvent trifluoroethanol (TFE). CD spectra showed that increasing concentration, pH, and ionic strength led to aggregation of P1-30; as a consequence, the peptide acquired beta-sheet conformation. In contrast, P11-30 exhibited practically no conformational changes under the same conditions, remaining essentially structureless. Moreover, this peptide did not undergo aggregation. These differences clearly point to the modulating effect of the first 10 hydrophobic residues on the peptides aggregation and conformational properties. In TFE both the first ten hydrophobic peptides acquired alpha-helical conformation, albeit to a different extent, P11-30 displayed lower alpha-helical content. P1-30 presented a larger fraction of residues in alpha-helical conformation in TFE than that found in St II's crystal structure for that portion of the protein. Since TFE mimics the membrane environment, such increase in helical content could also occur upon toxin binding to membranes and represent a step in the mechanism of pore formation. The peptides conformational properties correlated well with their functional behavior. Thus, P1-30 exhibited much higher hemolytic activity than P11-30. In addition, P11-30 was able to block the toxin's hemolytic activity. The size of pores formed in red blood cells by P1-30 was estimated by measuring the permeability to PEGs of different molecular mass. The pore radius (0.95 +/- 0.01 nm) was very similar to that of the pore formed by the toxin. The results demonstrate that the synthetic peptide P1-30 is a good model of St II conformation and function and emphasize the contribution of the toxin's N-terminal region, and, in particular, the hydrophobic residues 1-10 to pore formation.
Cerato-platanin (CP) is a secretion protein produced by the fungal pathogen Ceratocystis platani, the causal agent of the plane canker disease and the first member of the CP family. CP is considered a pathogen-associated molecular pattern because it induces various defense responses in the host, including production of phytoalexins and cell death. Although much is known about the properties of CP and related proteins as elicitors of plant defense mechanisms, its biochemical activity and host target(s) remain elusive. Here, we present the three-dimensional structure of CP. The protein, which exhibits a remarkable pH and thermal stability, has a double -barrel fold quite similar to those found in expansins, endoglucanases, and the plant defense protein barwin. Interestingly, although CP lacks lytic activity against a variety of carbohydrates, it binds oligosaccharides. We identified the CP region responsible for binding as a shallow surface located at one side of the -barrel. Chemical shift perturbation of the protein amide protons, induced by oligo-N-acetylglucosamines of various size, showed that all the residues involved in oligosaccharide binding are conserved among the members of the CP family. Overall, the results suggest that CP might be involved in polysaccharide recognition and that the double -barrel fold is widespread in distantly related organisms, where it is often involved in host-microbe interactions.
Rational Design, Synthesis, and Preliminary Structure–Activity Relationships of α-Substituted-2-Phenylcyclopropane Carboxylic Acids as Inhibitors of Salmonella typhimurium O-Acetylserine Sulfhydrylase
Cysteine is a building block for several biomolecules that are crucial for living organisms. The last step of cysteine biosynthesis is catalyzed by O-acetylserine sulfydrylase (OASS), a highly conserved pyridoxal 5'-phosphate (PLP)-dependent enzyme, present in different isoforms in bacteria, plants, and nematodes, but absent in mammals. Beside the biosynthesis of cysteine, OASS exerts a series of "moonlighting" activities in bacteria, such as transcriptional regulation, contact-dependent growth inhibition, swarming motility, and induction of antibiotic resistance. Therefore, the discovery of molecules capable of inhibiting OASS would be a valuable tool to unravel how this protein affects the physiology of unicellular organisms. As a continuation of our efforts toward the synthesis of OASS inhibitors, in this work we have used a combination of computational and spectroscopic approaches to rationally design, synthesize, and test a series of substituted 2-phenylcyclopropane carboxylic acids that bind to the two S. typhymurium OASS isoforms at nanomolar concentrations.
Synthetic peptides with sequences identical to fragments of the constant region of different classes (IgG, IgM, IgA) of antibodies (Fc-peptides) exerted a fungicidal activity in vitro against pathogenic yeasts, such as Candida albicans , Candida glabrata , Cryptococcus neoformans , and Malassezia furfur , including caspofungin and triazole resistant strains. Alanine-substituted derivatives of fungicidal Fc-peptides, tested to evaluate the critical role of each residue, displayed unaltered, increased or decreased candidacidal activity in vitro . An Fc-peptide, included in all human IgGs, displayed a therapeutic effect against experimental mucosal and systemic candidiasis in mouse models. It is intriguing to hypothesize that some Fc-peptides may influence the antifungal immune response and constitute the basis for devising new antifungal agents.
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