Molecular imprinting of protein by coordinate interaction

In this article,a novel strong interaction by forming complex between bovine serum albumin(BSA) and copper ion was utilized for the preparation of molecular imprinted hydrogel in aqueous solution.Results show that the inclusion of copper ion in preparation can bridge the template BSA and functional monomers together and improve the imprinting effect compared to the polymer made without copper ion added.High selectivity factor and large adsorption capacity are also observed for the obtained BSA-imprinted ...     

The N-terminal domain of apolipoprotein B-100: structural characterization by homology modeling

Background  

Apolipoprotein B-100 (apo B-100) stands as one of the largest proteins in humans. Its large size of 4536 amino acids hampers the production of X-ray diffraction quality crystals and hinders in-solution NMR analysis, and thus necessitates a domain-based approach for the structural characterization of the multi-domain full-length apo B.     

Binding free energy of several sterols to the N-terminal domain of Niemann-Pick C1-like 1 protein due to mutation: Molecular dynamics study

The membrane protein Niemann-Pick type C1-like 1 (NPC1L1) plays a central role in the absorption of cholesterol in the small intestine. Other sterols, notably vitamin E and vitamin K1 also utilize NPC1L1 as a membrane transporter even though other absorption paths exist. Many NPC1L1 mutations causing the disease due to poor transport of cholesterol are known. It is not clear at this moment if the same mutation can lead to reduced transport behavior with these vitamins. In this study, we have obtained the binding free energies of these two sterols using molecular dynamics simulation and compared these values with the cholesterol-binding free energy. The N-terminal domain (NTD) of the wild as well as the disease-causing two mutations, T61M and L110F, are used for this purpose. The result indicates that the mutations show reduced binding affinity compared to the wild except for the vitamin K1 in the T61M mutant, which has increased binding free energy. Also, we found the similarity of the key amino acids responsible for the change of free energy by mutation between T61M and L110F. At the same time, non-negligible differences exist also.     

AP/MALDI-MS complete characterization of the proteolytic fragments produced by the interaction of insulin degrading enzyme with bovine insulin

The prominent role that insulin degrading enzyme (IDE) has in the clearance of insulin as well as of other molecules such as amyloid-beta has recently drawn much interest in the scientific community toward this protease. In order to give an insight into the manner of interaction of IDE with its substrates, several papers have focused on the structure of the IDE/insulin complex. In this scenario, although the cleavage sites involved in the interaction of insulin with IDE are known, a convenient experimental method that is able to identify in a complete and unambiguous way, all the peptide fragments generated by such interaction has yet to be found. MS-based experiments have often represented to be invaluable tools for the assessment of the cleavage sites, but the reported MS-spectra always show a partial coverage of all the peptide fragments generated by the enzyme interaction, lacking a complete characterization. In this work, we report a new experimental procedure by which an unambiguous as well as complete assignment of all the peptide fragments generated by the interaction of insulin with IDE is described. Atmospheric pressure/matrix-assisted laser desorption ionization (AP/MALDI) mass spectra are reported and the data recorded, together with the introduction of a reduction/alkylation step, allows us to fully characterize the cleavage sites of the bovine insulin interacting with IDE. Different experimental conditions are screened and some insights into the IDE/insulin system regarding preference of the cleavage and its dependence on particular experimental conditions used are also given. Investigation on the tendency that different insulin fragments have toward aggregation is also carried out. Good reproducibility, global and unambiguous assignment, low time-consuming experimental procedure, and requirements of enzyme in small amounts are some of the advantages of the proposed AP/MALDI based approach.     

Inherent flexibility and protein function: The open/closed conformational transition in the N-terminal domain of calmodulin

The key to understand a protein's function often lies in its conformational dynamics. We develop a coarse-grained variational model to investigate the interplay between structural transitions, conformational flexibility, and function of the N-terminal calmodulin domain (nCaM). In this model, two energy basins corresponding to the "closed" apo conformation and "open" holo conformation of nCaM are coupled by a uniform interpolation parameter. The resulting detailed transition route from our model is largely consistent with the recently proposed EFbeta-scaffold mechanism in EF-hand family proteins. We find that the N-terminal parts of the calcium binding loops shows higher flexibility than the C-terminal parts which form this EFbeta-scaffold structure. The structural transition of binding loops I and II are compared in detail. Our model predicts that binding loop II, with higher flexibility and earlier structural change than binding loop I, dominates the open/closed conformational transition in nCaM.     

Ab initio modelling of the N-terminal domain of the secretin receptors

G protein coupled receptors of the secretin family are activated by peptide hormones of about 30 residues in length. There is considerable sequence homology within both the hormone and receptor families. The receptors possess in addition to the integral membrane domain a characteristic extracellular domain of about 120 residues in length, having conserved cysteine residues, which are involved in disulphide bridge formation, and tryptophanes, which have been shown to be critical for hormone binding. This extracellular domain does not have detectable homology to any known protein fold. In order to be able to propose a structure for this domain we have used ab initio prediction methods combined with constraints based on experimental results for the disulphide connectivity. The results of computational tools for predicting secondary structure and accessibility, together with ligand binding and mutational data and other structural considerations were used in the ab initio protein folding programs DRAGON and GADGET and also the simpler program RAMBLE, which was able to explore different permutations of disulphide bond connectivity, tryptophan side chain orientation and chain topology. The methods generated a limited number of plausible models but no single unique solution was found under the constraints. One of these was refined into a full atomic model that contained a possible peptide binding site comprising the most conserved residues.     

The use of the flory-huggins interaction parameter for the characterization of vacuum distillation residue fractions of mineral oils

Summary The Flory-Huggins interaction parameter,κ _1,2, ^∞ , was determined for a number of fractions separated from vacuum distillation residues of natural oils. Examined fractions were used as liquid stationary phases in inverse gas chromatography. The chemical character of the fractions was discussed in terms of the interaction parameter.     

The use of the Flory-Huggins interaction parameter for the characterization of vacuum distillation residue fractions of mineral oils

Summary The Flory-Huggins interaction parameter, κ _1,2 ^∞ , was determined for a number of fractions separated from vacuum distillation residues of natural oils. Examined fractions were used as liquid stationary phases in inverse gas chromatography. The chemical character of the fractions was discussed in terms of the interaction parameter.     

Molecular recognition of protein surfaces: high affinity ligands for the CBP KIX domain

Potent and specific inhibitors of protein.protein interactions have potential both as therapeutic compounds and biological tools, yet discovery of such molecules remains a challenge. Our laboratory has recently described a strategy, called protein grafting, for the identification of miniature proteins that bind protein surfaces with high affinity and specificity and inhibit the formation of protein.protein complexes. In protein grafting, those residues that comprise a functional alpha-helical binding epitope are stabilized on the solvent-exposed alpha-helical face of the small yet stable protein avian pancreatic polypeptide (aPP). Here we use protein grafting in combination with molecular evolution by phage display to identify phosphorylated peptide ligands that recognize the shallow surface of CBP KIX with high nanomolar to low micromolar affinity. Furthermore, we show that grafting of the CBP KIX-binding epitope of CREB KID onto the aPP scaffold yields molecules capable of high affinity recognition of CBP KIX even in the absence of phosphorylation. Importantly, both classes of designed ligands exhibit high specificity for the target CBP KIX domain over carbonic anhydrase and calmodulin, two unrelated proteins that bind hydrophobic or alpha-helical molecules that might be encountered in vivo.     

Molecular dynamics simulations of a hyperthermophilic and a mesophilic protein L30e

Molecular dynamics (MD) simulations were used to study the hyperthermophilic ribosomal protein L30e from archaeon Thermococcus celer at 300 and 350 K, and its mesophilic homologue, yeast L30e, at 300 K in explicit solvent for a period of 5.0 ns. Three trajectories obtained from the MD simulations were stable throughout the simulation period, such as total potential energy, radius of gyration, root-mean-square deviation, and secondary structures assignment. At 300 K, T. celer L30e is less flexible than its mesophilic homologue, and this difference becomes more pronounced at 350 K. Salt bridge networks, one triad and one hexad, are present at the surface of T. celer L30e. The ion pairs forming these salt bridges maintain close contact at a higher temperature, suggesting that these networks contribute to the protein’s hyperthermal stability. By contrast, we found no such networks to be present in yeast L30e. For charged residue I in T. celer L30e, the ΔΔGsolvI value and its corresponding ΔECoulI value possess opposite signs. This indicates that for T. celer L30e, a change in the solvation free energy of a charged residue due to increasing temperature is compensated by a change in the residude’s Coulombic interaction energy with the rest of the protein.     

Delineation of RAID1, the RACK1 interaction domain located within the unique N-terminal region of the cAMP-specific phosphodiesterase, PDE4D5

Background  

The cyclic AMP specific phosphodiesterase, PDE4D5 interacts with the β-propeller protein RACK1 to form a signaling scaffold complex in cells. Two-hybrid analysis of truncation and mutant constructs of the unique N-terminal region of the cAMP-specific phosphodiesterase, PDE4D5 were used to define a domain conferring interaction with the signaling scaffold protein, RACK1.     

Molecular dynamics simulation of S100B protein to explore ligand blockage of the interaction with p53 protein

As a tumor suppressor, p53 plays an important role in cancer suppression. The biological function of p53 as a tumor suppressor is disabled when it binds to S100B. Developing the ligands to block the S100B-p53 interaction has been proposed as one of the most important approaches to the development of anti-cancer agents. We screened a small compound library against the binding interface of S100B and p53 to identify potential compounds to interfere with the interaction. The ligand-binding effect on the S100B-p53 interaction was explored by molecular dynamics at the atomic level. The results show that the ligand bound between S100B and p53 propels the two proteins apart by about 2 Å compared to the unligated S100B-p53 complex. The binding affinity of S100B and p53 decreases by ~8.5–14.6 kcal/mol after a ligand binds to the interface from the original unligated state of the S100B-p53 complex. Ligand-binding interferes with the interaction of S100B and p53. Such interference could impact the association of S100B and p53, which would free more p53 protein from the pairing with S100B and restore the biological function of p53 as a tumor suppressor. The analysis of the binding mode and ligand structural features would facilitate our effort to identify and design ligands to block S100B-p53 interaction effectively. The results from the work suggest that developing ligands targeting the interface of S100B and p53 could be a promising approach to recover the normal function of p53 as a tumor suppressor.     

Biochemical characterization of peptidyl carrier protein (PCP), the thiolation domain of multifunctional peptide synthetases

Background: A structurally diverse group of bioactive peptides is synthesized by peptide synthetases which act as templates for a growing peptide chain, attached to the enzyme via a thloester bond. The protein templates are composed of distinctive substrate-activating modules, whose order dictates the primary structure of the corresponding peptide product. Each module contains defined domains that catalyze adenylation, thioester and peptide bond formation, as well as substrate modifications. To show that a putative thiolation domain (PCP) is involved in covalent binding and transfer of amino aryl residues during non-ribosomal peptide synthesis, we have cloned and biochemically characterized that region of tyrocidine synthetase 1, TycA.Results: The 327-bp gene fragment encoding PCP was cloned using its homology to the genes for the acyl carrier proteins of fatty acid and polyketide biosynthesis. The protein was expressed as a His₆, fusion protein, and purified in a single step by affinity chromatography. Incorporation of β-[³H]alanine, a precursor of coenzyme A, demonstrated the modification of PCP with the cofactor 4′-phosphopantetheine. When an adenylation domain is present to supply the amino adenylate moiety, PCP can be acylated in vitro.Conclusions: PCP can bind covalently to the cofactor phosphopantetheine and can subsequently be acylated, strongly supporting the multiple carrier model of non-ribosomal peptide synthesis. The adenylation and thiolation domains can each act as independent multifunctional enzymes, further confirming the modular structure of peptide synthees, and can also perform sequential steps in trans, as do multienzyme complexes.     

Synthesis and spectroscopic characterization of photo-affinity peptide ligands to study rhodopsin-G protein interaction

G protein-coupled receptors (GPCRs) are involved in the control of virtually all aspects of our behavior and physiology. Activated receptors catalyze nucleotide exchange in heterotrimeric G proteins (composed of alpha.GDP, beta and gamma subunits) on the inner surface of the cell membrane. The GPCR rhodopsin and the G protein transducin (G(t)) are key proteins in the early steps of the visual cascade. The main receptor interaction sites on G(t) are the C-terminal tail of the G(t)alpha-subunit and the farnesylated C-terminal tail of the G(t)gamma-subunit. Synthetic peptides derived from these C-termini specifically bind and stabilize the active rhodopsin conformation (R*). Here we report the synthesis of R*-interacting peptides containing photo-reactive groups with a specific isotope pattern, which can facilitate detection of cross-linked products by mass spectrometry. In a preliminary set of experiments, we characterized such peptides derived from the farnesylated G(t)gamma C-terminus (G(t)gamma(60-71)far) in terms of their capability to bind R*. Here, we describe novel peptides with photo-affinity labels that bind R* with affinities similar to that of the native G(t)gamma(60-71)far peptide. Such peptides will enable an improved experimental strategy to probe rhodopsin-G(t) interaction and to map so far unknown interaction sites between both proteins.     

Copper-ion interaction with the 106-113 domain of the prion protein: a solution-equilibria study on model peptides

Prion diseases are characterized by a structural modification of the regular prion protein (PrP(C)) to its isoform, termed PrP(Sc)(scrapie). Such a modification involves the secondary and tertiary structure of the protein; the amino acidic sequence remains unchanged. PrP(Sc) is almost insoluble in non-denaturing solvents, resistant to proteases and it loses its redox activity. PrP(C) is able to bind copper and other metal ions: these complexes have been suggested to play an important role in the protein refolding leading to PrP(Sc). It is well-known that at least one relatively strong copper-binding site is located in the PrP(92--126) domain, where two His residues (96 and 111) are present. However, in the same domain, other amino acidic residues bear potentially donating atoms, i.e. Met, Asn and Lys residues. In order to shed light on the role of the side chains of such potentially tridentate amino acids on copper complexation, the polypeptide Ac-KTNMKHMA-NH(2), corresponding to the PrP(106--113) fragment, and some synthetic analogues have been investigated as ligands for the copper ion, by means of both thermodynamic and spectroscopic techniques. The pivotal role of imidazolic side chain of His in "anchoring" the metal ion has been confirmed. On the other hand, no clue was found on the participation of sulfur atom of Met or side amino-group of Lys residues to copper complex-formation.     

Molecular cloning of clathrin assembly protein gene (rCALM) and its differential expression to AP180 in rat brain

Binding of clathrin assembly protein to clathrin triskelia induces their assembly into clathrin-coated vesicle (CCV) in neurons. The clathrin assembly protein gene (rCALM) was cloned from rat brain cDNA library. rCALM deduced 69 kD molecule has overall 73% amino acid homology compared with that of AP180 protein. The N-terminal domain, where amino acid sequences are very similar with AP180, harbours binding sites for clathrin and inositides, as well as possible phosphorylation sites, but the proline rich C-terminal domain is different from that of AP180. The mRNA expression of rCALM and AP180 by in situ hybridization histochemistry revealed that the rCALM mRNA was more intensely expressed than that of AP180, and the distribution patterns were different from each other. These results suggest that the rCALM mediates the assembly of clathrin in neural and supporting cells of brain, and regulates the clathrin coated-vesicle formation through phosphorylation and inositide metabolism.     

Online coupling of reverse-phase and hydrophilic interaction liquid chromatography for protein and glycoprotein characterization

We have developed a novel system for coupling reverse-phase (RP) and hydrophilic interaction liquid chromatography (HILIC) online in a micro-flow scheme. In this approach, the inherent solvent incompatibility between RP and HILIC is overcome through the use of constant-pressure online solvent mixing, which allows our system to perform efficient separations of both hydrophilic and hydrophobic compounds for mass spectrometry-based proteomics applications. When analyzing the tryptic digests of bovine serum albumin, ribonuclease B, and horseradish peroxidase, we observed near-identical coverage of peptides and glycopeptides when using online RP-HILIC—with only a single sample injection event—as we did from two separate RP and HILIC analyses. The coupled system was also capable of concurrently characterizing the peptide and glycan portions of deglycosylated glycoproteins from one injection event, as confirmed, for example, through our detection of 23 novel glycans from turkey ovalbumin. Finally, we validated the applicability of using RP-HILIC for the analysis of highly complex biological samples (mouse chondrocyte lysate, deglycosylated human serum). The enhanced coverage and efficiency of online RP-HILIC makes it a viable technique for the comprehensive separation of components displaying dramatically different hydrophobicities, such as peptides, glycopeptides, and glycans.     

Taxol biosynthesis: Molecular cloning and characterization of a cytochrome P450 taxoid 7 beta-hydroxylase

Biosynthesis of the anticancer drug Taxol in yew species involves eight cytochrome P450-mediated oxygenations and four coenzyme A-dependent acylations of the diterpenoid core. A family of cytochrome P450 genes, obtained from a yew cell cDNA library, were functionally expressed and screened with taxusin (taxa-4(20),11(12)-dien-5 alpha,9 alpha,10 beta,13 alpha-tetraol tetraacetate) as a surrogate substrate. One clone converted this substrate to an oxygenated derivative that was identified as 7 beta-hydroxytaxusin. The structure and properties of this 7 beta-hydroxylase are similar to those of other taxoid hydroxylases. Kinetic and binding assays indicated selectivity of the 7 beta-hydroxylase for polyoxygenated and acylated taxoid substrates, an observation consistent with the operation of this enzyme in the central portion of the Taxol biosynthetic pathway. Although the 7 beta-hydroxyl of Taxol is not essential for antimitotic activity, this functional group provides a convenient means for preparing taxoid derivatives.