Simple polyglutamine (polyQ) peptides aggregate in vitro via a nucleated growth pathway directly yielding amyloid-like aggregates. We show here that the 17 amino acid flanking sequence (httNT) N-terminal to the polyQ in the toxic huntingtin exon1 fragment imparts onto this peptide a complex alternative aggregation mechanism. In isolation the httNT peptide is a compact coil that resists aggregation. When polyQ is fused to this sequence, it induces in httNT, in a repeat-length dependent fashion, a more extended conformation that greatly enhances its aggregation into globular oligomers with httNT cores and exposed polyQ. In a second step, a new, amyloid-like aggregate is formed with a core composed of both httNT and polyQ. The results indicate unprecedented complexity in how primary sequence controls aggregation within a substantially disordered peptide, and have implications for the molecular mechanism of Huntington's disease.
Octanol-to-water solvation free energies of acetyl amino amides (Ac-X-amides) [Fauchère, J.L., & Pliska, V. (1983) Eur. J. Med. Chem. --Chim. Ther. 18,369] form the basis for computational comparisons of protein stabilities by means of the atomic solvation parameter formalism of Eisenberg and McLachlan [(1986) Nature 319, 199]. In order to explore this approach for more complex systems, we have determined by octanol-to-water partitioning the solvation energies of (1) the guest (X) side chains in the host-guest pentapeptides AcWL-X-LL, (2) the carboxy terminus of the pentapeptides, and (3) the peptide bonds of the homologous series of peptides AcWLm (m = 1-6). Solvation parameters were derived from the solvation energies using estimates of the solvent-accessible surface areas (ASA) obtained from hard-sphere Monte Carlo simulations. The measurements lead to a side chain solvation-energy scale for the pentapeptides and suggest the need for modifying the Asp, Glu, and Cys values of the "Fauchère-Pliska" solvation-energy scale fro the Ac-X-amides. We find that the unfavorable solvation energy of nonpolar residues can be calculated accurately by a solvation parameter of 22.8 +/- 0.8 cal/mol/A2, which agrees satisfactorily with the AC-X-amide data and thereby validates the Monte Carlo ASA results. Unlike the Ac-X-amide data, the apparent solvation energies of the uncharged polar residues are also largely unfavorable. This unexpected finding probably results, primarily, from differences in conformation and hydrogen bonding in octanol and buffer but may also be due to the additional flaking peptide bonds of the pentapeptides. The atomic solvation parameter (ASP) for the peptide bond is comparable to the ASP of the charged carboxy terminus which is an order of magnitude larger than the ASP of the uncharged polar side chains of the Ac-X-amides. The very large peptide bond ASP, -96 +/- 6 cal/mol/A2, profoundly affects the results of computational comparisons of protein stability which use ASPs derived from octanol-water partitioning data.
The importance of the left-handed polyproline II (PPII) helical conformation has recently become apparent. This conformation generally is involved in two important functions: protein-protein interactions and structural integrity. PPII helices play vital roles in a variety of processes including signal transduction, transcription, and cell motility. Proline-rich regions of sequence are often assumed to adopt this structure. Remarkably, little is known about the physical determinants of this secondary structure type. In this study, we have explored the formation of PPII helices by a short poly(proline) peptide. In addition, the results from experiments used to determine the propensities for apolar residues, plus glycine, asparagine, and glutamine, to adopt this structure in a poly(proline)-based host peptide are reported here. Proline possesses the highest intrinsic propensity, with glutamine, alanine, and glycine having surprisingly high propensities.-Branched residues possess the lowest propensities of the residues examined. It is postulated that propensities possessed by apolar residues are due in part to peptide-solvent interactions, and that the remarkably high propensity possessed by glutamine may be due to a side chain to backbone hydrogen bond. These data are the first step toward a molecular understanding of the formation of this important, and yet little studied, secondary structure.In recent years, the left-handed polyproline II (PPII) 1 helical conformation has been elevated from the status of a relatively rare and seemingly uninteresting secondary structure to one that is surprisingly common and of the utmost importance. This structure plays a central role in numerous vital processes including signal transduction, transcription, cell motility, and the immune response. Proline-rich ligands of the cytoskeletal protein profilin (1), as well as those of the SH3, WW, and EVH1 protein interaction domains, are bound in this conformation (2). The peptide ligands of class II MHC molecules are also bound in the PPII conformation (3). PPII helices are major features of collagens (4) and plant cell wall proteins (5). The PPII helix is believed to be the dominant conformation for many proline-rich regions of sequence (PRRs) (6). Sequences not rich in proline also adopt this structure. For example, poly(lysine), poly(glutamate), and poly(aspartate) peptides form PPII helices (7). Around 2% of all residues in known protein structures are found in PPII helices at least four residues long (8, 9). As many as 10% of all residues are found in the PPII conformation, although not necessarily as part of PPII helices (10). PPII helices have also been hypothesized to be a major component of protein denatured states (11-14), giving them a role in a most fundamental process. Recently, Blanch et al. (15) have suggested that the PPII helix might be the precursor conformation in amyloid formation. Given the preceding, it is truly remarkable how little is known about the physical determinants of the PPII helical conformat...
Despite the clear importance of the left-handed polyproline II (PPII) helical conformation in many physiologically important processes as well as its potential significance in protein unfolded states, little is known about the physical determinants of this conformation. We present here a scale of relative PPII helix-forming propensities measured for all residues, except tyrosine and tryptophan, in a proline-based host peptide system. Proline has the highest measured propensity in this system, a result of strong steric interactions that occur between adjacent prolyl rings. The other measured propensities are consistent with backbone solvation being an important component in PPII helix formation. Side chain to backbone hydrogen bonding may also play a role in stabilizing this conformation. The PPII helix-forming propensity scale will prove useful in future studies of the conformational properties of proline-rich sequences as well as provide insights into the prevalence of PPII helices in protein unfolded states.
In recent host-guest studies, the helixforming tendencies of amino acid residues have been quantified by three groups, each obtaining similar results [Padmanabhan, S
The pathogenic spirochete Leptospira interrogans disseminates throughout its hosts via the bloodstream, then invades and colonizes a variety of host tissues. Infectious leptospires are resistant to killing by their hosts' alternative pathway of complement-mediated killing, and interact with various host extracellular matrix (ECM) components. The LenA outer surface protein (formerly called LfhA and Lsa24) was previously shown to bind the host ECM component laminin and the complement regulators factor H and factor H-related protein-1. We now demonstrate that infectious L. interrogans contain five additional paralogs of lenA, which we designated lenB, lenC, lenD, lenE and lenF. All six genes encode domains predicted to bear structural and functional similarities with mammalian endostatins. Sequence analyses of genes from seven infectious L. interrogans serovars indicated development of sequence diversity through recombination and intragenic duplication. LenB was found to bind human factor H, and all of the newly-described Len proteins bound laminin. In addition, LenB, LenC, LenD, LenE and LenF all exhibited affinities for fibronectin, a distinct host extracellular matrix protein. These characteristics suggest that Len proteins together facilitate invasion and colonization of host tissues, and protect against host immune responses during mammalian infection.
The highly conserved phosphatase calcineurin plays vital roles in numerous processes including T-cell activation, development and function of the central nervous system, and cardiac growth. It is activated by the calcium sensor calmodulin. Calmodulin binds to a regulatory domain within calcineurin, causing a conformational change that displaces an autoinhibitory domain from the active site, resulting in activation of the phosphatase. This is the same general mechanism by which calmodulin activates calmodulin-dependent protein kinases. Previously published data has hinted that the regulatory domain of calcineurin is intrinsically disordered. In this work we demonstrate that the regulatory domain is unstructured and that it folds upon binding calmodulin, ousting the autoinhibitory domain from the catalytic site. The regulatory domain is 95 residues long, with the autoinhibitory domain attached to its C-terminal end and the 24 residue calmodulin binding region towards the N-terminal end. This is unlike the calmodulin-dependent protein kinases which have calmodulin binding sites and autoinhibitory domains immediately adjacent in sequence. Our data demonstrate that not only does the calmodulin binding region fold, but that an ~25-30 residue region between it and the autoinhibitory domain also folds, resulting in over half of the regulatory domain adopting α-helical structure. This appears to be the first observation of calmodulin inducing folding of this scale outside of its binding site on a target protein.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.