Protein Surface Mimetics: Understanding How Ruthenium Tris(Bipyridines) Interact with Proteins

Protein surface mimetics achieve high‐affinity binding by exploiting a scaffold to project binding groups over a large area of solvent‐exposed protein surface to make multiple cooperative noncovalent interactions. Such recognition is a prerequisite for competitive/orthosteric inhibition of protein–protein interactions (PPIs). This paper describes biophysical and structural studies on ruthenium(II) tris(bipyridine) surface mimetics that recognize cytochrome (cyt) c and inhibit the cyt c/cyt c peroxidase (CCP) PPI. Binding is electrostatically driven, with enhanced affinity achieved through enthalpic contributions thought to arise from the ability of the surface mimetics to make a greater number of noncovalent interactions than CCP with surface‐exposed basic residues on cyt c. High‐field natural abundance ¹H,¹⁵N HSQC NMR experiments are consistent with surface mimetics binding to cyt c in similar manner to CCP. This provides a framework for understanding recognition of proteins by supramolecular receptors and informing the design of ligands superior to the protein partners upon which they are inspired.     

An ACP structural switch: conformational differences between the apo and holo forms of the actinorhodin polyketide synthase acyl carrier protein

The actinorhodin (act) synthase acyl carrier protein (ACP) from Streptomyces coelicolor plays a central role in polyketide biosynthesis. Polyketide intermediates are bound to the free sulfhydryl group of a phosphopantetheine arm that is covalently linked to a conserved serine residue in the holo form of the ACP. The solution NMR structures of both the apo and holo forms of the ACP are reported, which represents the first high resolution comparison of these two forms of an ACP. Ensembles of twenty apo and holo structures were calculated and yielded atomic root mean square deviations of well-ordered backbone atoms to the average coordinates of 0.37 and 0.42 A, respectively. Three restraints defining the protein to the phosphopantetheine interface were identified. Comparison of the apo and holo forms revealed previously undetected conformational changes. Helix III moved towards helix II (contraction of the ACP), and Leu43 on helix II subtly switched from being solvent exposed to forming intramolecular interactions with the newly added phosphopantetheine side chain. Tryptophan fluorescence and S. coelicolor fatty acid synthase (FAS) holo-synthase (ACPS) assays indicated that apo-ACP has a twofold higher affinity (K(d) of 1.1 muM) than holo-ACP (K(d) of 2.1 muM) for ACPS. Site-directed mutagenesis of Leu43 and Asp62 revealed that both mutations affect binding, but have differential affects on modification by ACPS. Leu43 mutations in particular strongly modulate binding affinity for ACPS. Comparison of apo- and holo-ACP structures with known models of the Bacillus subtilis FAS ACP-holo-acyl carrier protein synthase (ACPS) complex suggests that conformational modulation of helix II and III between apo- and holo-ACP could play a role in dissociation of the ACP-ACPS complex.     

Complementary Roles of Two DNA Protection Proteins from Deinococcus geothermalis

The roles of two interrelated DNA protection protein in starved cells (Dps)—putative Dps Dgeo_0257 and Dgeo_0281—as orthologous proteins to DrDps1 for DNA binding, protection, and metal ion sensing were characterised in a Deinococcus geothermalis strain. Dgeo_0257 exhibited high DNA-binding affinity and formed a multimeric structure but lacked the conserved amino acid sequence for ferroxidase activity. In contrast, the Dgeo_0281 (DgDps1) protein was abundant in the early exponential phase, had a lower DNA-binding activity than Dgeo_0257, and was mainly observed in its monomeric or dimeric forms. Electrophoretic mobility shift assays demonstrated that both purified proteins bound nonspecifically to DNA, and their binding ability was affected by certain metal ions. For example, in the presence of ferrous and ferric ions, neither Dgeo_0257 nor Dgeo_0281 could readily bind to DNA. In contrast, both proteins exhibited more stable DNA binding in the presence of zinc and manganese ions. Mutants in which the dps gene was disrupted exhibited higher sensitivity to oxidative stress than the wild-type strain. Furthermore, the expression levels of each gene showed an opposite correlation under H₂O₂ treatment conditions. Collectively, these findings indicate that the putative Dps Dgeo_0257 and DgDps1 from D. geothermalis are involved in DNA binding and protection in complementary interplay ways compared to known Dps.     

Structure and redox properties of the haem centre in the C357M mutant of cytochrome P450cam

The effects of site-specific mutation of the axial cysteine (C357M) to a methionine residue in cytochrome P450cam on the enzyme's coordination geometry and redox potential have been investigated. The absorption spectra of the haem centre in the C357M mutant of the enzyme showed close similarity to those of cytochrome c both in the oxidised and reduced forms. A well-defined absorption peak at 695 nm, similar to that seen in the case of cytochrome c and characteristic of methionine ligation to the ferric haem, was observed. The results indicated that the haem of C357M cytochrome P450cam is possibly axially coordinated to a methionine and a histidine, analogously to cytochrome c. The circular dichroism spectra in the visible and the far-UV regions suggested that the tertiary structure of the haem cavity in the C357M mutant cytochrome P450cam was distinctly different from that in the wild-type enzyme or in cytochrome c, although the secondary structure of the mutant remained identical to that of the wild-type cytochrome P450cam. Comparison of the natures of the CD spectra in the 400 nm and 695 nm regions of the C357M mutant of cytochrome P450cam with those of horse cytochrome c suggested (R) chirality at the sulfur atom of the iron-bound methionine residue in the mutant. The redox potential of the haem centre, estimated by redox titration of the C357M mutant, was found to be +260 mV, which is much higher than that in the wild-type enzyme and similar to the redox potential of cytochrome c. This supported the concept that axial ligation of the haem plays the major role in tuning the redox potential of the haem centre in haem proteins.     

Rieske iron-sulfur protein of the cytochrome bc(1) complex: a potential target for fungicide discovery

The cytochrome bc(1) complex (complex III, cyt bc(1)) is an essential component of cellular respiration. Cyt bc(1) has three core subunits that are required for its catalytic activity: cytochrome b, cytochrome c(1), and the Rieske iron-sulfur protein (ISP). Although most fungicides inhibit this enzyme by binding to the cytochrome b subunit, resistance to these fungicides has developed rapidly due to their widespread application. Resistance is mainly associated with mutations in cytochrome b, the only subunit encoded by mitochondrial DNA. Recently, the flexibility and motion of the ISP and its essential role in electron transfer have received intense attention; this leads us to propose a new classification of cyt bc(1) inhibitors (three types of Q(o) inhibitors) that mobilize, restrict, or fix the rotation of the ISP. Importantly, the strengths of the ISP-inhibitor interactions correlate with inhibitor activity and the development of resistance to Q(o) inhibitors, thereby offering clues for designing novel cyt bc(1) inhibitors with high potency and a low risk of resistance.     

The ternary complex of cytochrome f and cytochrome c: identification of a second binding site and competition for plastocyanin binding

The complex of yeast cytochrome c and cytochrome f from the cyanobacterium Phormidium laminosum was investigated by NMR spectroscopy. Chemical shift perturbation analysis reveals that residues around the haem edge of cytochrome c are involved in the complex interface. Binding curves derived from an NMR spectroscopy titration at 10 mM ionic strength indicate that there are two sites for cytochrome c with binding constants of approximately 2 x 10(4) M(-1) and 4 x 10(3) M(-1). A protein docking simulation with NMR-derived constraints identifies two sites, at the front (Site I) and back faces (Site II) of the haem region of cytochrome f. Site I is homologous to the binding site previously determined for the natural cytochrome f partner plastocyanin. Site II may represent the binding site for the Rieske protein in the cytochrome bf complex. Cytochrome c and plastocyanin are shown to compete for binding at Site I. The competition appears to involve electrostatic screening rather than simple steric occlusion of the binding site.     

The “Monkey-Bar” Mechanism for Searching for the DNA Target Site: The Molecular Determinants

DNA recognition by DNA-binding proteins, which is a pivotal event in most gene regulatory processes, is often preceded by an extensive search for the correct site. A facilitated diffusion process, in which a DBP combines 3D diffusion in solution with 1D sliding along DNA, has been suggested to explain how proteins can locate their target sites on DNA much faster than predicted by 3D diffusion alone. One of the key mechanisms in the localization of the target by a DNA-binding protein is intersegment transfer in which the protein forms a bridged intermediate between two distant DNA regions. This jumping mechanism is more enhanced when the DNA-binding protein is asymmetric in its structure or its dynamics. We suggest that asymmetry supports the “monkey bar” mechanism, in which different domains of the protein interact with different DNA regions. In this minireview, we discuss how the molecular architectures of the proteins and DNA may modulate the efficiency of monkey bar dynamics.     

Rapid isolation of high-affinity protein binding peptides using bacterial display

A robust bacterial display methodology was developed that allows the rapid isolation of peptides that bind to arbitrarily selected targets with high affinity. To demonstrate the utility of this approach, a large library (5 x 10(10) clones) was constructed composed of random 15-mer peptide insertions constrained within a flexible, surface exposed loop of the Escherichia coli outer membrane protein A (OmpA). The library was screened for binding to five unrelated proteins, including targets previously used in phage display selections: human serum albumin, anti-T7 epitope mAb, human C-reactive protein, HIV-1 GP120 and streptavidin. Two to four rounds of enrichment (2-4 days) were sufficient to enrich peptide ligands having high affinity for each of the target proteins. Strong amino acid consensus sequences were apparent for each of the targets tested, with up to seven consensus residues. Isolated peptide ligands remained functional when expressed as insertional fusions within a monomeric fluorescent protein. This bacterial display methodology provides an efficient process for identifying peptide affinity reagents and should be useful in a variety of molecular recognition applications.     

DeepDISE: DNA Binding Site Prediction Using a Deep Learning Method

It is essential for future research to develop a new, reliable prediction method of DNA binding sites because DNA binding sites on DNA-binding proteins provide critical clues about protein function and drug discovery. However, the current prediction methods of DNA binding sites have relatively poor accuracy. Using 3D coordinates and the atom-type of surface protein atom as the input, we trained and tested a deep learning model to predict how likely a voxel on the protein surface is to be a DNA-binding site. Based on three different evaluation datasets, the results show that our model not only outperforms several previous methods on two commonly used datasets, but also demonstrates its robust performance to be consistent among the three datasets. The visualized prediction outcomes show that the binding sites are also mostly located in correct regions. We successfully built a deep learning model to predict the DNA binding sites on target proteins. It demonstrates that 3D protein structures plus atom-type information on protein surfaces can be used to predict the potential binding sites on a protein. This approach should be further extended to develop the binding sites of other important biological molecules.     

Binding of helix-threading peptides to E. coli 16S ribosomal RNA and inhibition of the S15-16S complex

Helix-threading peptides (HTPs) constitute a new class of small molecules that bind selectively to duplex RNA structures adjacent to helix defects and project peptide functionality into the dissimilar duplex grooves. To further explore and develop the capabilities of the HTP design for binding RNA selectively, we identified helix 22 of the prokaryotic ribosomal RNA 16S as a target. This helix is a component of the binding site for the ribosomal protein S15. In addition, the S15-16S RNA interaction is important for the ordered assembly of the bacterial ribosome. Here we present the synthesis and characterization of helix-threading peptides that bind selectively to helix 22 of E. coli 16S RNA. These compounds bind helix 22 by threading intercalation placing the N termini in the minor groove and the C termini in the major groove. Binding is dependent on the presence of a highly conserved purine-rich internal loop in the RNA, whereas removal of the loop minimally affects binding of the classical intercalators ethidium bromide and methidiumpropyl-EDTAFe (MPEFe). Moreover, binding selectivity translates into selective inhibition of formation of the S15-16S complex.     

Affinity maturation of a Taq DNA polymerase specific affibody by helix shuffling

The possibility of increasing the affinity of a Taq DNA polymerasespecific binding protein (affibody) was investigated by an -helixshuffling strategy. The primary affibody was from a naive combinatoriallibrary of the three-helix bundle Z domain derived from staphylococcalprotein A. A hierarchical library was constructed through selectivere-randomization of six amino acid positions in one of the two-helices of the domain, making up the Taq DNA polymerase bindingsurface. After selections using monovalent phage display technology,second generation variants were identified having affinities(K_D) for Taq DNA polymerase in the range of 30–50 nM asdetermined by biosensor technology. Analysis of binding dataindicated that the increases in affinity were predominantlydue to decreased dissociation rate kinetics. Interestingly,the affinities observed for the second generation Taq DNA polymerasespecific affibodies are of similar strength as the affinitybetween the original protein A domain and the Fc domain of humanimmunoglobulin G. Further, the possibilities of increasing theapparent affinity through multimerization of affibodies wasdemonstrated for a dimeric version of one of the second generationaffibodies, constructed by head-to-tail gene fusion. As comparedwith its monomeric counterpart, the binding to sensor chip immobilizedTaq DNA polymerase was characterized by a threefold higher apparentaffinity, due to slower off-rate kinetics. The results showthat the binding specificity of the protein A domain can bere-directed to an entirely different target, without loss ofbinding strength.     

Aptamers can discriminate alkaline proteins with high specificity

Aptamers are single-stranded nucleic acids that fold into stable three-dimensional structures with ligand binding sites that are complementary in shape and charge to a desired target. Aptamers are generated by an iterative process known as in vitro selection, which permits their isolation from pools of random sequences. While aptamers have been selected to bind a wide range of targets, it is generally thought that these molecules are incapable of discriminating strongly alkaline proteins due to the attractive forces that govern oppositely charged polymers (e.g., polyelectrolyte effect). Histones, eukaryotic proteins that make up the core structure of nucleosomes are attractive targets for exploring the binding properties of aptamers because these proteins have positively charged surfaces that bind DNA through noncovalent sequence-independent interactions. Previous selections by our lab and others have yielded DNA aptamers with high affinity but low specificity to individual histone proteins. Whether this is a general limitation of aptamers is an interesting question with important practical implications in the future development of protein affinity reagents. Here we report the in vitro selection of a DNA aptamer that binds to histone H4 with a K(d) of 13 nM and distinguishes other core histone proteins with 100 to 480-fold selectivity, which corresponds to a ΔΔG of up to 3.4 kcal mol(-1) . This result extends our fundamental understanding of aptamers and their ability to fold into shapes that selectively bind alkaline proteins.     

Synthetic DNA aptamers to detect protein molecular variants in a high-throughput fluorescence quenching assay

Real-time protein detection in homogeneous solutions is necessary in many biotechnology and biomedical studies. The recent development of molecular aptamers, combined with fluorescence techniques, may provide an easy and efficient approach to protein elucidation. This report describes the development of a fluorescence-based assay with synthetic DNA aptamers that can detect and distinguish molecular variants of proteins in biological samples in a high-throughput process. We used an aptamer with high affinity for the B chain of platelet-derived growth factor (PDGF), labeled it with a fluorophore and a quencher at the two termini, and measured fluorescence quenching by PDGF. The specific quenching can be used to detect PDGF at picomolar concentrations even in the presence of serum and other cell-derived proteins in cell culture media. This is the first successful application of a synthetic aptamer for the detection of tumor-related proteins directly from the tumor cells. We also show that three highly related molecular variants of PDGF (AA, AB, and BB dimers) can be distinguished from one another in this single-step assay, which can be readily adapted to a microtiter plate assay for high-throughput analysis. The use of fluorescence quenching as a measure of binding between the DNA probe and the target protein eliminates potential false signals that may arise in traditional fluorescence enhancement assays as a result of degradation of the DNA aptamer by contaminating nucleases in biological specimens. This assay is applicable to proteins that are not naturally DNA binding. The excellent specificity, ultrahigh sensitivity, and simplicity of this one-step assay addresses a growing need for high-throughput methods that detect changes in the expression of gene products and their variants in cell cultures and biological specimens.     

A Novel Family of Winged-Helix Single-Stranded DNA-Binding Proteins from Archaea

The winged helix superfamily comprises a large number of structurally related nucleic acid-binding proteins. While these proteins are often shown to bind dsDNA, few are known to bind ssDNA. Here, we report the identification and characterization of Sul7s, a novel winged-helix single-stranded DNA binding protein family highly conserved in Sulfolobaceae. Sul7s from Sulfolobus islandicus binds ssDNA with an affinity approximately 15-fold higher than that for dsDNA in vitro. It prefers binding oligo(dT)₃₀ over oligo(dC)₃₀ or a dG-rich 30-nt oligonucleotide, and barely binds oligo(dA)₃₀. Further, binding by Sul7s inhibits DNA strand annealing, but shows little effect on the melting temperature of DNA duplexes. The solution structure of Sul7s determined by NMR shows a winged helix-turn-helix fold, consisting of three α-helices, three β-strands, and two short wings. It interacts with ssDNA via a large positively charged binding surface, presumably resulting in ssDNA deformation. Our results shed significant light on not only non-OB fold single-stranded DNA binding proteins in Archaea, but also the divergence of the winged-helix proteins in both function and structure during evolution.     

Identification of indispensable residues for specific DNA-binding in the imperfect tandem repeats of c-Myb R2R3

The individual repeats, R2 and R3, of the minimum specific DNA-binding domain (R2R3) of c-Myb have very similar structures, with a helix-turn- helix variation motif, although their sequence identity in the tandem repeats is only 31%. From previous mutational and structural studies, the third helices in both repeats were shown to directly recognize the specific base sequence, PyAACG/TG. In order to elucidate the reason for the imperfection of the tandem repeats at amino acid positions other than the recognition helices, a series of R2R3 mutants was generated by swapping the helices and the N-terminus in R2 to those in R3. Consequently, the sequence composing the first helix of R2 was found to be essential for specific DNA-binding, in addition to the third recognition helix of R2. Further mutational studies revealed that the only indispensable residues in the first helix are Val103 and Val1O7, which are involved in the hydrophobic core of R2. These residues do not directly interact with the DNA, but they contribute to the correct formation of helix 1 and the characteristic packing of R2, which is slightly different from that of R3, and are required for specific base recognition through strong cooperativity with R3.      

Protein interactions in the Escherichia coli cytosol: an impediment to in-cell NMR spectroscopy

Protein science is shifting towards experiments performed under native or native-like conditions. In-cell NMR spectroscopy for instance has the potential to reveal protein structure and dynamics inside cells. However, not all proteins can be studied by this technique. (15)N-labelled cytochrome c (cyt c) over-expressed in Escherichia coli was undetectable by in-cell NMR spectroscopy. When whole-cell lysates were subjected to size-exclusion chromatography (SEC) cyt c was found to elute with an apparent molecular weight of >150 kDa. The presence of high molecular weight species is indicative of complex formation between cyt c and E. coli cytosolic proteins. These interactions were disrupted by charge-inverted mutants in cyt c and by elevated concentrations of NaCl. The physiologically relevant salt, KGlu, was less efficient at disrupting complex formation. Notably, a triple mutant of cyt c could be detected in cell lysates by NMR spectroscopy. The protein, GB1, yields high quality in-cell spectra and SEC analysis of lysates containing GB1 revealed a lack of interaction between GB1 and E. coli proteins. Together these data suggest that protein "stickiness" is a limiting factor in the application of in-cell NMR spectroscopy.     

Cyclic Peptides for Efficient Detection of Collagen

We report here a new class of collagen‐binding peptides, cyclic collagen‐mimetic peptides (cCMPs), that efficiently hybridize with the triple‐helix‐forming portions of collagen. cCMPs are composed of two parallel collagen‐like (Xaa‐Yaa‐Gly)_n strands with both termini tethered by covalent linkages. Enzyme‐linked immunosorbent assays and western blotting analysis showed that cCMPs exhibit more potent affinity toward collagen than reported collagen‐binding peptides and can specifically detect different collagen polypeptides in a mixture of proteins. Collagen secreted from cultured cells was detected by confocal microscopy with fluorescein‐labeled cCMP. The cCMP is also shown to detect sensitively folding intermediates in the endoplasmic reticulum, something that was difficult to visualize with conventional collagen detectors. Molecular‐dynamics simulations suggested that a cCMP forms a more stably hybridized product than its single‐chain counterpart; this could explain why cCMP has higher affinity toward denatured collagen. These results indicate the usefulness of cCMPs as tools for detecting denatured collagen.