Project description:The definition of the structural basis of the conformational preferences of the genetically encoded amino acid residues is an important yet unresolved issue of structural biology. In order to gain insights into this intricate topic, we here determined and compared the amino acid propensity scales for different (φ, ψ) regions of the Ramachandran plot and for different secondary structure elements. These propensities were calculated using the Chou-Fasman approach on a database of non-redundant protein chains retrieved from the Protein Data Bank. Similarities between propensity scales were evaluated by linear regression analyses. One of the most striking and unexpected findings is that distant regions of the Ramachandran plot may exhibit significantly similar propensity scales. On the other hand, contiguous regions of the Ramachandran plot may present anticorrelated propensities. In order to provide an interpretative background to these results, we evaluated the role that the local variability of protein backbone geometry plays in this context. Our analysis indicates that (dis)similarities of propensity scales between different regions of the Ramachandran plot are coupled with (dis)similarities in the local geometry. The concept that similarities of the propensity scales are dictated by the similarity of the NCαC angle and not necessarily by the similarity of the (φ, ψ) conformation may have far-reaching implications in the field.

Project description:Brain derived neurotrophic factor (BDNF) is a member of the neurotrophin family of proteins which plays a central role in neuronal survival, growth, plasticity and memory. A single Val66Met variant has been identified in the prodomain of human BDNF that is associated with anxiety, depression and memory disorders. The structural differences within the full-length prodomain Val66 and Met66 isoforms could shed light on the mechanism of action of the Met66 and its impact on the development of neuropsychiatric-associated disorders. In the present study, we report the backbone 1H, 13C, and 15N NMR assignments of both full-length Val66 and Met66 prodomains in the presence of 2 M urea. These conditions were utilized to suppress residual structure and aid subsequent native state structural investigations aimed at mapping and identifying variant-dependent conformational differences under native-state conditions.

Project description:We have investigated by multidimensional NMR the structural and dynamic characteristics of the urea-denatured state of activated SUMO-1, a 97-residue protein belonging to the growing family of ubiquitin-like proteins involved in post-translational modifications. Complete backbone amide and 15N resonance assignments were obtained in the denatured state by using HNN and HN(C)N experiments. These enabled other proton assignments from TOCSY-HSQC spectra. Secondary Halpha chemical shifts and 1H-1H NOE indicate that the protein chain in the denatured state has structural preferences in the broad beta-domain for many residues. Several of these are seen to populate the (phi,psi) space belonging to polyproline II structure. Although there is no evidence for any persistent structures, many contiguous stretches of three or more residues exhibit structural propensities suggesting possibilities of short-range transient structure formation. The hetero-nuclear 1H-15N NOEs are extremely weak for most residues, except for a few at the C-terminal, and the 15N relaxation rates show sequence-wise variation. Some of the regions of slow motions coincide with those of structural preferences and these are interspersed by highly flexible residues. The implications of these observations for the early folding events starting from the urea-denatured state of activated SUMO-1 have been discussed.

Project description:The plasma protein von Willebrand factor (VWF) is essential for hemostasis initiation at sites of vascular injury. The platelet-binding A1 domain of VWF is connected to the VWF N-terminally located D'D3 domain through a relatively unstructured amino acid sequence, called here the N-terminal linker. This region has previously been shown to inhibit the binding of VWF to the platelet surface receptor glycoprotein Ib? (GpIb?). However, the molecular mechanism underlying the inhibitory function of the N-terminal linker has not been elucidated. Here, we show that an aspartate at position 1261 is the most critical residue of the N-terminal linker for inhibiting binding of the VWF A1 domain to GpIb? on platelets in blood flow. Through a combination of molecular dynamics simulations, mutagenesis, and A1-GpIb? binding experiments, we identified a network of salt bridges between Asp1261 and the rest of A1 that lock the N-terminal linker in place such that it reduces binding to GpIb?. Mutations aimed at disrupting any of these salt bridges activated binding unless the mutated residue also formed a salt bridge with GpIb?, in which case the mutations inhibited the binding. These results show that interactions between charged amino acid residues are important both to directly stabilize the A1-GpIb? complex and to indirectly destabilize the complex through the N-terminal linker.

Project description:Understanding the key factors that influence the interaction preferences of amino acids in the folding of proteins have remained a challenge. Here we present a knowledge-based approach for determining the effective interactions between amino acids based on amino acid type, their secondary structure, and the contact based environment that they find themselves in the native state structure as measured by their number of neighbors. We find that the optimal information is approximately encoded in a 60 x 60 matrix describing the 20 types of amino acids in three distinct secondary structures (helix, beta strand, and loop). We carry out a clustering scheme to understand the similarity between these interactions and to elucidate a nonredundant set. We demonstrate that the inferred energy parameters can be used for assessing the fit of a given sequence into a putative native state structure.

Project description:We sequenced the mRNA from a stably transduced Human T-cell line expressing the HIV-1 Tat protein. The inducible Tat expression has been used to understand and compare the cellular molecules and pathways being modulated by the wild type subtype-C Tat versus its single signature amino acid residue variant. Additionaly, the HIV-1 subtype B and C Tat comparitive analysis has also been included in the study to evaluate the gene expression profile as a reponse to subtype specific Tat proteins.

Project description:We used microarrays to detail the global gene expression in stably transfected HEK 293T cells of the over-expression of truncated FMRP containing 295 amino acid residues, which were compared with control (stably transfected HEK 293T cells of empty lentiviral vector (pLEX-MCS). Stably transfected HEK 293T cells of empty lentiviral vector (pLEX-MCS) and the over-expression of truncated FMRP were for RNA extraction and hybridization on Affymetrix microarrays.

Project description:The ruthenium-catalyzed ring-opening polymerization (ROMP) of 1-cyclobutenecarbonyl glycine methyl ester provides translationally invariant, head-to-tail ordered polymers. This polybutadiene backbone contains (within the limits of detection) only E-trisubstituted olefins, and it has no stereocenters that would serve as a source of structural ambiguities. Characterization of the polymer products indicates that they have polydispersities ranging from 1.2 to 1.6 and suggests that they are the products of a "living" polymerization. 1-Cyclobutenecarboxamide-derived ROMP polymers are excellent prospects for applications that require stereoregular chains functionalized with polar ligands.

Project description:The stability and folding of proteins are modulated by energetically significant interactions in the denatured state that is in equilibrium with the native state. These interactions remain largely invisible to current experimental techniques, however, due to the sparse population and conformational heterogeneity of the denatured-state ensemble under folding conditions. Molecular dynamics simulations using physics-based force fields can in principle offer atomistic details of the denatured state. However, practical applications are plagued with the lack of rigorous means to validate microscopic information and deficiencies in force fields and solvent models. This study presents a method based on coupled titration and molecular dynamics sampling of the denatured state starting from the extended sequence under native conditions. The resulting denatured-state pK(a)s allow for the prediction of experimental observables such as pH- and mutation-induced stability changes. I show the capability and use of the method by investigating the electrostatic interactions in the denatured states of wild-type and K12M mutant of NTL9 protein. This study shows that the major errors in electrostatics can be identified by validating the titration properties of the fragment peptides derived from the sequence of the intact protein. Consistent with experimental evidence, our simulations show a significantly depressed pK(a) for Asp(8) in the denatured state of wild-type, which is due to a nonnative interaction between Asp(8) and Lys(12). Interestingly, the simulation also shows a nonnative interaction between Asp(8) and Glu(48) in the denatured state of the mutant. I believe the presented method is general and can be applied to extract and validate microscopic electrostatics of the entire folding energy landscape.

Project description:The refolding of urea-denatured adenylate kinase (EC 2.7.4.3) has been followed by formation of the secondary structure, change of surface hydrophobicity and recovery of catalytic activity. During refolding of adenylate kinase with a 20-80-fold dilution of 4 M urea-denatured enzyme at 10 degrees C, the formation of the secondary structure is a fast process with a rate constant of >0.16 s-1. Transient enhancement of the 8-anilino-1-naphthalenesulphonate (ANS) fluorescence intensity is followed by a fluorescence decrease to the level equal to the value characteristic of native enzyme. The desorption of ANS binding fluorescence is relatively slow and can be fitted to a first order reaction with a rate constant of 0.004 s-1 when the ANS is present in the dilution buffer. The desorption of ANS-binding fluorescence is accelerated in the presence of nucleotide substrates. The rate constants are increased to 0.049, 0. 029, 0.028 and 0.029 s-1 in the presence of 1 mM AMP, MgATP, ATP and ADP respectively. The refolding rate constant calculated from the initial fluorescence intensity after mixing ANS with protein at different refolding intervals is 0.016 s-1, which is faster than those obtained when ANS is present throughout the refolding process, indicating that the binding of ANS with a partially folded intermediate retards its further refolding to its native structure. The reactivation rate is even faster than the rates of refolding monitored in the absence of substrates, showing that the refolding is accelerated in the presence of the substrates. A possible refolding pathway and the accelerating effect of substrates are discussed.