Using structural motif templates to identify proteins with DNA binding function

This work describes a method for predicting DNA binding function from structure using 3-dimensional templates. Proteins that bind DNA using small contiguous helix–turn–helix (HTH) motifs comprise a significant number of all DNA-binding proteins. A structural template library of seven HTH motifs has been created from non-homologous DNA-binding proteins in the Protein Data Bank. The templates were used to scan complete protein structures using an algorithm that calculated the root mean squared deviation (rmsd) for the optimal superposition of each template on each structure, based on C_α backbone coordinates. Distributions of rmsd values for known HTH-containing proteins (true hits) and non-HTH proteins (false hits) were calculated. A threshold value of 1.6 Å rmsd was selected that gave a true hit rate of 88.4% and a false positive rate of 0.7%. The false positive rate was further reduced to 0.5% by introducing an accessible surface area threshold value of 990 Ų per HTH motif. The template library and the validated thresholds were used to make predictions for target proteins from a structural genomics project.     

Regulation of alpha-ketoglutarate dehydrogenase cooperative properties in substrate binding by thiol-disulfide exchange

The influence of reducing the KGD non-cooperative form by DTT on the KG binding by the enzyme was investigated. The chemical modification of KGD by DEP has revealed that reduction of KGD cysteine residues results in the appearance of the interaction of the dimer active sites upon the enzyme-substrate complex formation. The reduction of 2 SH-groups per KGD subunit: the most reactive one and a buried one--was established to be sufficient for the appearance of KGD cooperative properties in substrate binding as well as for the change in the enzyme activity plots versus substrate concentration. It is suggested that KGD can be regulated by thiol-disulfide exchange in the cell.     

Recognition of methylated DNA through methyl-CpG binding domain proteins

DNA methylation is a key regulatory control route in epigenetics, involving gene silencing and chromosome inactivation. It has been recognized that methyl-CpG binding domain (MBD) proteins play an important role in interpreting the genetic information encoded by methylated DNA (mDNA). Although the function of MBD proteins has attracted considerable attention and is well characterized, the mechanism underlying mDNA recognition by MBD proteins is still poorly understood. In this article, we demonstrate that the methyl-CpG dinucleotides are recognized at the MBD-mDNA interface by two MBD arginines through an interplay of hydrogen bonding and cation-π interaction. Through molecular dynamics and quantum-chemistry calculations we investigate the methyl-cytosine recognition process and demonstrate that methylation enhances MBD-mDNA binding by increasing the hydrophobic interfacial area and by strengthening the interaction between mDNA and MBD proteins. Free-energy perturbation calculations also show that methylation yields favorable contribution to the binding free energy for MBD-mDNA complex.     

Preparation of bioconjugates by solid-phase conjugation to ion exchange matrix-adsorbed carrier proteins

A solid-phase conjugation method utilizing carrier protein bound to an ion exchange matrix was developed. Ovalbumin was adsorbed to an anion exchange matrix using a batch procedure, and the immobilized protein was then derivatized with iodoacetic acid N-hydroxysuccinimid ester. The activated protein was conjugated with glutathione, the conjugation ratio determined by acid hydrolysis, and amino acid analysis performed with quantification of carboxymethyl cysteine. Elution of conjugates from the resin by a salt gradient revealed considerable heterogeneity in the degree of derivatization, and immunization experiments with the eluted conjugates showed that the more substituted conjugates gave rise to the highest titers of glutathione antibodies. Direct immunization with the conjugates adsorbed to the ion exchange matrix was possible and gave rise to high titers of glutathione antibodies. Conjugates of ovalbumin and various peptides were prepared in a similar manner and used for production of peptide antisera by direct immunization with the conjugates bound to the ion exchanger. Advantages of the method are its solid-phase nature, allowing fast and efficient reactions and intermediate washings, and the ability to release conjugates from the solid phase under mild conditions.     

Generation of high specificity of effect through low-specificity binding of proteins to DNA

It is proposed that proteins can bind with relatively low-affinity and specificity to multiple sites, defined as sequence motifs, on polynucleotide chains, and that such binding can collectively be turned into high-affinity, high-specificity binding through cooperative effects, especially when the sequence motifs recur periodically. The selection of individual nucleotides has in general been thought to be the condition of the existence and conservation of function in most of the noncoding sequences. This condition seems unnecessary. Calculations are presented as a step in the direction of giving credibility to a model of stable gene repression.     

Azathioprine suppresses ezrin-radixin-moesin-dependent T cell-APC conjugation through inhibition of Vav guanosine exchange activity on Rac proteins

We have shown recently that the azathioprine metabolite 6-Thio-GTP causes immunosuppression by blockade of GTPase activation in T lymphocytes. In the present study, we describe a new molecular mechanism by which 6-Thio-GTP blocks GTPase activation. Although 6-Thio-GTP could bind to various small GTPases, it specifically blocked activation of Rac1 and Rac2 but not of closely related Rho family members such as Cdc42 and RhoA in primary T cells upon stimulation with alphaCD28 or fibronectin. Binding of 6-Thio-GTP to Rac1 did not suppress Rac effector coupling directly but blocked Vav1 exchange activity upon 6-Thio-GTP hydrolysis, suggesting that 6-Thio-GTP loading leads to accumulation of 6-Thio-GDP-loaded, inactive Rac proteins over time by inhibiting Vav activity. In the absence of apoptosis, blockade of Vav-mediated Rac1 activation led to a blockade of ezrin-radixin-moesin dephosphorylation in primary T cells and suppression of T cell-APC conjugation. Azathioprine-generated 6-Thio-GTP thus prevents the development of an effective immune response via blockade of Vav activity on Rac proteins. These findings provide novel insights into the immunosuppressive effects of azathioprine and suggest that antagonists of the Vav-Rac signaling pathway may be useful for suppression of T cell-dependent pathogenic immune responses.     

PrgB promotes aggregation,biofilm formation,and conjugation through DNA binding and compaction

Gram‐positive bacteria deploy type IV secretion systems (T4SSs) to facilitate horizontal gene transfer. The T4SSs of Gram‐positive bacteria rely on surface adhesins as opposed to conjugative pili to facilitate mating. Enterococcus faecalis PrgB is a surface adhesin that promotes mating pair formation and robust biofilm development in an extracellular DNA (eDNA) dependent manner. Here, we report the structure of the adhesin domain of PrgB. The adhesin domain binds and compacts DNA in vitro. In vivo PrgB deleted of its adhesin domain does not support cellular aggregation, biofilm development and conjugative DNA transfer. PrgB also binds lipoteichoic acid (LTA), which competes with DNA binding. We propose that PrgB binding and compaction of eDNA facilitates cell aggregation and plays an important role in establishment of early biofilms in mono‐ or polyspecies settings. Within these biofilms, PrgB mediates formation and stabilization of direct cell‐cell contacts through alternative binding of cell‐bound LTA, which in turn promotes establishment of productive mating junctions and efficient intra‐ or inter‐species T4SS‐mediated gene transfer.     

Pausing of DNA polymerases on duplex DNA templates due to ligand binding in vitro

Using the recently developed peptide nucleic acid (PNA)-assisted assay, which makes it possible to extend a primer on duplex DNA, we study the sequence-specific inhibition of the DNA polymerase movement along double-stranded DNA templates imposed by DNA-binding ligands. To this end, a plasmid vector has been prepared featuring the polylinker with two flanking priming sites to bi-directionally initiate the primer-extension reactions towards each other. Within this plasmid, we have cloned a set of random DNA sequences and analyzed the products of these reactions with several phage and bacterial DNA polymerases capable of strand-displacement synthesis. Two of them, ?29 and modified T7 (Sequenase 2.0) enzymes, were found to be most potent for primer extension in the presence of DNA-binding ligands. We used these enzymes for a detailed study of ligand-induced pausing effects with four ligands differing in modes of binding to the DNA double-helix. GC-specific intercalator actinomycin D and three minor groove-binders, chromomycin A(3) (GC-specific), distamycin A and netropsin (both AT-specific), have been chosen. In the presence of each ligand both selected DNA polymerases experienced multiple clear-cut pauses. Each ligand yielded its own characteristic pausing pattern for a particular DNA sequence. The majority of pausing sites could be located with a single-nucleotide resolution and corresponded to the preferred binding sites known from the literature for the ligands under study. Besides, DNA polymerases stalled exactly at the positions occupied by PNA oligomers that were employed to initiate the primer extension. These findings provide an important insight into the DNA polymerase performance. In addition, the high-resolution ligand-induced pausing patterns we obtained for the first time for DNA polymerase elongation on duplex DNA may become a valuable addition to the existing arsenal of methods used to monitor duplex DNA interactions with various DNA-binding ligands, including drugs.     

Enzymes of thiol-disulfide metabolism of proteins

Occurrence, properties and physiological role of protein disulfide reductases (EC 1.6.4.4 and 1.8.4.2), protein disulfide isomerase (EC 5.3.4.1), and thiol oxidase (EC 1.8.3.2) catalyzing thiol-disulfide interchange reactions in proteins are reviewed with a particular emphasis on seed storage proteins. An important role of the enzymes in the formation and degradation of seed storage protein complexes is discussed.     

The adenovirus DNA binding protein and adenovirus DNA polymerase interact to catalyze elongation of primed DNA templates

The adenovirus-encoded 140-kDa DNA polymerase (Ad Pol) and the 59-kDa DNA binding protein (Ad DBP) are both required for the replication of viral DNA in vivo and in vitro. Previous studies demonstrated that, when poly(dT).oligo(dA) was used as a template-primer, both proteins were required for poly(dA) synthesis. In this report, the interaction between the Ad Pol and Ad DBP was further investigated using poly(dT).oligo(dA) as well as a linear duplex molecule containing 3' poly(dT) tails. DNA synthesis with the tailed template required Ad Pol, Ad DBP, and an oligo(dA) primer hydrogen bonded to the poly(dT) tails. Incorporation was stimulated 8-10-fold by ATP; however, no evidence of ATP hydrolysis to ADP was observed. Synthesis was initiated at either end of the tailed molecule and proceeded through the duplex region to the end of the molecule. This ability to translocate through duplex DNA and to synthesize long poly(dA) chains suggests that the Ad Pol.Ad DBP complex can act efficiently in the elongation reactions involved in the replication of Ad DNA (both type I and type II). During the replication reaction, substantial hydrolysis of deoxynucleoside triphosphates to the corresponding deoxynucleoside monophosphates occurred. This reaction required DNA synthesis and most likely reflects an idling reaction similar to that observed with other DNA polymerases containing 3'----5' exonuclease activity in which the polymerase first incorporates and then hydrolyzes a dNMP.     

Inactivation of ribonuclease inhibitor by thiol-disulfide exchange.

Porcine ribonuclease inhibitor (RI) contains 30 1/2-cystinyl residues, all of which occur in the reduced form. Reaction of the native protein with 5,5'-dithiobis (2-nitrobenzoic acid) resulted in the release of 30 mol of the product 5-mercapto-2-nitrobenzoate, and the loss of the RNase inhibitory activity. A linear relationship between the degree of modification and inactivation was observed. The rate of modification was greatly increased in the presence of 6 M guanidinium HCl. Reaction with substoichiometric amounts of 5,5'-dithiobis(2-nitrobenzoic acid) was found to yield a mixture of fully reduced active molecules, and fully oxidized inactive ones, but no partially oxidized forms were detected. This suggests that an "all-or-none" type of modification and inactivation took place. All 1/2-cystinyl residues in the inactive, monomeric inhibitor had formed disulfide bridges, judged by the absence of either free thiol groups or mixed disulfides with 5-mercapto-2-nitrobenzoate. This fully disulfide-cross-linked molecule had an open conformation compared to the native one, as shown by gel filtration and limited proteolysis. Reaction of phenylarsinoxide with vicinal dithiols yields products that are much more stable than those with monothiols. Titration of RI with this reagent yielded complete inactivation at a reagent/thiol ratio of 0.5. Taken together, these observations suggest that the thiol groups in RI have a diminished reactivity due to three-dimensional constraints. After the initial modification of a small number of thiol groups, a conformational change occurs which causes an increase in reactivity of the remaining thiols. The thiol groups are situated close enough together to permit the formation of 15 disulfide bridges in the inactive molecule.     

Specific versus nonspecific binding of cationic PNAs to duplex DNA

Although peptide nucleic acids (PNAs) are neutral by themselves, they are usually appended with positively charged lysine residues to increase their solubility and binding affinity for nucleic acid targets. Thus obtained cationic PNAs very effectively interact with the designated duplex DNA targets in a sequence-specific manner forming strand-invasion complexes. We report on the study of the nonspecific effects in the kinetics of formation of sequence-specific PNA-DNA complexes. We find that in a typical range of salt concentrations used when working with strand-invading PNAs (10-20 mM NaCl) the PNA binding rates essentially do not depend on the presence of nontarget DNA in the reaction mixture. However, at lower salt concentrations (<10 mM NaCl), the rates of PNA binding to DNA targets are significantly slowed down by the excess of unrelated DNA. This effect of nontarget DNA arises from depleting the concentration of free PNA capable of interacting with DNA target due to adhesion of positively charged PNA molecules on the negatively charged DNA duplex. As expected, the nonspecific electrostatic effects are more pronounced for more charged PNAs. We propose a simple model quantitatively describing all major features of the observed phenomenon. This understanding is important for design of and manipulation with the DNA-binding polycationic ligands in general and PNA-based drugs in particular.     

Concentration-dependent exchange accelerates turnover of proteins bound to double-stranded DNA

The multistep kinetics through which DNA-binding proteins bind their targets are heavily studied, but relatively little attention has been paid to proteins leaving the double helix. Using single-DNA stretching and fluorescence detection, we find that sequence-neutral DNA-binding proteins Fis, HU and NHP6A readily exchange with themselves and with each other. In experiments focused on the Escherichia coli nucleoid-associated protein Fis, only a small fraction of protein bound to DNA spontaneously dissociates into protein-free solution. However, if Fis is present in solution, we find that a concentration-dependent exchange reaction occurs which turns over the bound protein, with a rate of k_exch = 6 × 10⁴ M⁻¹s⁻¹. The bacterial DNA-binding protein HU and the yeast HMGB protein NHP6A display the same phenomenon of protein in solution accelerating dissociation of previously bound labeled proteins as exchange occurs. Thus, solvated proteins can play a key role in facilitating removal and renewal of proteins bound to the double helix, an effect that likely plays a major role in promoting the turnover of proteins bound to DNA in vivo and, therefore, in controlling the dynamics of gene regulation.     

Specific protein-protein binding in many-component mixtures of proteins

Proteins must bind to specific other proteins in vivo in order to function. The proteins are required to bind to only one or a few other proteins of the few thousand proteins typically present in vivo. To quantify this requirement we introduce a property of proteins called the capability. The capability is the maximum number of specific-binding interactions possible in a mixture, or in other words the size of largest sustainable interactome. This calculation of the maximum number possible is closely analogous to the work of Shannon and others on the maximum rate of communication through noisy channels. Using a simple model of proteins, we find specific binding to be a demanding function in the sense that it demands that the binding sites of the proteins be encoded by long sequences of elements, and the requirement for specific binding then strongly constrains these sequences.     

Specific binding of chartreusin, an antitumor antibiotic, to DNA

Chartreusin, an antitumor and antibacterial antibiotic, was found to inhibit negatively superhelical DNA-relaxation catalyzed by prokaryotic topoisomerase I and conversion of the superhelical DNA into unit length linear form catalyzed by single-strand-specific S1 nuclease. The inhibitory effect of the agent was due to the binding to DNA causing the alteration of tertiary structure. To characterize the binding specificity, we investigated the protection of DNA against cleavages by various restriction endonucleases. It was evidenced that the binding of the agent is not at random and correlates to the sequence 5'CGC 3' 3'GCG 5' on DNA stretch.