Characterization of the ATPase activity of the Escherichia coli RecG protein reveals that the preferred cofactor is negatively supercoiled DNA

RecG is a member of the superfamily 2 helicase family. Its possible role in vivo is ATP hydrolysis driven regression of stalled replication forks. To gain mechanistic insight into how this is achieved, a coupled spectrophotometric assay was utilized to characterize the ATPase activity of RecG in vitro. The results demonstrate an overwhelming preference for negatively supercoiled DNA ((-)scDNA) as a cofactor for the hydrolysis of ATP. In the presence of (-)scDNA the catalytic efficiency of RecG and the processivity (as revealed through heparin trapping), were higher than on any other cofactor examined. The activity of RecG on (-)scDNA was not due to the presence of single-stranded regions functioning as loading sites for the enzyme as relaxed circular DNA treated with DNA gyrase, resulted in the highest levels of ATPase activity. Relaxation of (-)scDNA by a topoisomerase resulted in a 12-fold decrease in ATPase activity, comparable to that observed on both linear double-stranded (ds)DNA and (+)scDNA. In addition to the elevated activity in the presence of (-)scDNA, RecG also has high activity on model 4Y-substrates (i.e. chicken foot structures). This is due largely to the high apparent affinity of the enzyme for this DNA substrate, which is 46-fold higher than a 2Y-substrate (i.e. a three-way with two single-stranded (ss)DNA arms). Finally, the enzyme exhibited significant, but lower activity on ssDNA. This activity was enhanced by the Escherichia coli stranded DNA-binding protein (SSB) protein, which occurs through stabilizing of the binding of RecG to ssDNA. Stabilization is not afforded by the bacteriophage gene 32 protein, indicating a species specific, protein-protein interaction is involved. These results combine to provide significant insight into the manner and timing of the interaction of RecG with DNA at stalled replication forks.     

A small-molecule-linked DNA–graphene oxide-based fluorescence-sensing system for detection of biotin

In this paper, we establish a novel fluorescence-sensing system for the detection of biotin based on the interaction between DNA and graphene oxide and on protection of the terminal of the biotinylated single-stranded DNA fluorescent probe by streptavidin. In this system, streptavidin binds to the biotinylated DNA, which protects the DNA from hydrolysis by exonuclease I. The streptavidin–DNA conjugate is then adsorbed to the graphene oxide resulting in the fluorescence being quenched. Upon the addition of free biotin, it competes with the labeled biotin for the binding sites of streptavidin and then the exonuclease I digests the unbound DNA probe from the 3′ to the 5′ terminal, releasing the fluorophore from the DNA. Because of the weak affinity between the fluorophore and graphene oxide, the fluorescence is recovered. Under optimal conditions, the fluorescence intensity is proportional to the concentration of biotin in the concentration range of 0.5–20 nmol/L. The detection limit for biotin is 0.44 nmol/L. The proposed fluorescence-sensing system was applied to the determination of biotin in some real samples with satisfactory reproducibility and accuracy. This work could provide a common platform for detecting small biomolecules based on protein–small molecule ligand binding.     

Molecular necklaces. Cross-linking hemoglobin with reagents containing covalently attached ligands

Hemoglobin can be cross-linked and converted to a bioconjugate in one step by a "molecular necklace", a reagent that contains two reacting sites and a pendant ligand. The compound to be conjugated is activated as an electrophile. The activated material is then combined with a reagent (3-aminoisophthalic acid) that contains a nucleophilic (amino) site and two latent (carboxyl) sites. The latent sites of the product are activated as 3,5-dibromosalicylates to produce the cross-linker. Illustrative examples of cross-linking are presented with pendant biotin [bis(3,5-dibromosalicyl) N-biotinyl-5-aminoisophthalate] and pendant N-trifluoroacetyl-L-isoleucylglycine [bis(3,5-dibromosalicyl) N-(N-trifluoroacetyl-L-isoleucylglycyl)-5-aminoisophthalate) ]. The resulting modified hemoglobins contain two principal types of cross-link: (beta-Lys-82-beta'-Lys-82) and (alpha-Lys-99-alpha'-Lys-99). The functional properties of the modified hemoglobin containing biotin in a (beta-Lys-82-beta'-Lys-82) cross-link are (pH 7.4, 55 microM heme, 25 degrees C, 0.1 M chloride, and 50 mM Bis-Tris) P(50) = 4.9 Torr, n(50) = 3.0, values which are approximately the same as for native hemoglobin. The results of affinity chromatography of the biotinylated cross-linked hemoglobin using a column of immobilized avidin indicate that the pendant biotin is much less accessible than free biotin. We suggest that the results are consistent with the pendant species being strongly attracted into the hemoglobin environment.     

Isolation of DNA-protein complexes based on streptavidin and biotin interaction

We describe a method for the purification of proteins binding to specific DNA sites based on the strong interaction between streptavidin and biotin. We tested the efficiency of this method using the Escherichia coli lactose operon operator-repressor system. dUTP coupled to biotin is incorporated into a DNA fragment containing the lactose operator. A crude E. coli extract is first incubated with the biotinylated fragment and the reaction mixture is filtered on a streptavidin-agarose column. Proteins retained on the column are either eluted alone by high salt or isopropyl beta-D-thiogalactoside, or as a complex with the DNA site by enzymatic digestion of the DNA. We thus obtained a 3400-fold enrichment of the repressor complexed to the operator in one step. The method is simple and makes use of commercially available reagents. The large concentration of biotin-binding sites of the streptavidin-agarose matrix (0.1 mumol/ml packed gel) provides a very high capacity for the concentration and purification of large amounts of proteins. The advantage of this method for the detection and purification of other DNA-binding proteins is discussed.     

Method for preparing single-stranded DNA templates for Pyrosequencing using vector ligation and universal biotinylated primers

In Pyrosequencing, the addition of nucleotides to a primer-template hybrid is monitored by enzymatic conversion of chemical energy into detectable light. The technique yields both qualitative and quantitative sequence information because the chemical energy is released by a stoichiometric split off of pyrophosphates from incorporated deoxynucleotide triphosphates and a defined nucleotide dispensation order is given. Because Pyrosequencing works best if single-stranded DNA templates are used, template generation usually requires PCR with a target-specific biotinylated primer and a subsequent purification involving interaction of the biotin label with immobilized streptavidin. To circumvent the need for numerous and expensive template-specific biotinylated primers, we developed a method that uses the ligation of amplified DNA fragments into a plasmid vector, thereby facilitating subsequent PCR using a universal vector-specific biotinylated primer. This approach allows easy and straightforward isolation of single-stranded templates of any PCR product. As a proof of principle, we used the method for genotyping two single-nucleotide polymorphisms in the human genes CARD15 and A2M and for characterization of four multisite variations in the human DEFB104 gene.     

Functional interactions of alcohol-sensitive sites in the N-methyl-D-aspartate receptor M3 and M4 domains

The N-methyl-D-aspartate receptor is an important mediator of the behavioral effects of ethanol in the central nervous system. Previous studies have demonstrated sites in the third and fourth membrane-associated (M) domains of the N-methyl-D-aspartate receptor NR2A subunit that influence alcohol sensitivity and ion channel gating. We investigated whether two of these sites, Phe-637 in M3 and Met-823 in M4, interactively regulate the ethanol sensitivity of the receptor by testing dual substitution mutants at these positions. A majority of the mutations decreased steady-state glutamate EC(50) values and maximal steady-state to peak current ratios (I(ss)/I(p)), whereas only two mutations altered peak glutamate EC(50) values. Steady-state glutamate EC(50) values were correlated with maximal glutamate I(ss)/I(p) values, suggesting that changes in glutamate potency were attributable to changes in desensitization. In addition, there was a significant interaction between the substituents at positions 637 and 823 with respect to glutamate potency and desensitization. IC(50) values for ethanol among the mutants varied over the approximate range 100-325 mm. The sites in M3 and M4 significantly interacted in regulating ethanol sensitivity, although this was apparently dependent upon the presence of methionine in position 823. Molecular dynamics simulations of the NR2A subunit revealed possible binding sites for ethanol near both positions in the M domains. Consistent with this finding, the sum of the molecular volumes of the substituents at the two positions was not correlated with ethanol IC(50) values. Thus, there is a functional interaction between Phe-637 and Met-823 with respect to glutamate potency, desensitization, and ethanol sensitivity, but the two positions do not appear to form a unitary site of alcohol action.     

Dinucleosome DNA of human K562 cells: experimental and computational characterizations

Dinucleosome formation is the first step in the organization of the higher order chromatin structure. With the ultimate aim of elucidating the dinucleosome structure, we constructed a library of human dinucleosome DNA. The library consists of PCR-amplifiable DNA fragments obtained by treatment of nuclei of erythroid K562 cells with micrococcal nuclease followed by extraction of DNA and adaptor ligation to the blunt-ended DNA fragments. The library was then cloned using a plasmid vector and the sequences of the clones were determined. The dominating clones containing the Alu elements were removed. A total of 1002 clones, which comprised a dinucleosome database, contained 84 and 918 clones from the clones before and after removing Alu elements, respectively. Approximately 70% of the clones were between 300 and 400 bp in size and they were distributed to various locations of all chromosomes except the Y chromosome. The clones containing A(2)N(8)A(2)N(8)A(2) or T(2)N(8)T(2)N(8)T(2) sequences were classified into three types, Type I (N shape), Type II (V shape) and Type III (M shape) according to DNA curvature plots. The locations of experimentally determined curved DNA segments matched well with the calculated ones though the clones of Types I and III showed additional curved DNA segments as revealed by the curvature plots. The distributions of complementary dinucleotides in the nucleosome DNA, at the ends of the dinucleosome DNA clones, allowed us to predict the positions of the nucleosome dyad axis, and estimate the size of the nucleosome core DNA, 125nt. The distributions of AA and TT dinucleotides, as well as other RR and YY dinucleotides, showed a periodicity with an average period of 10.4 bases, close to the values observed before. Mapping of nucleosome positions in the dinucleosome database based on the observed periodicity revealed that the nucleosomes were separated by a linker of 7.5+ approximately 10 x n nt. This indicates that the nucleosome-nucleosome orientations are, typically, halfway between parallel and antiparallel. Also an important finding is that the distributions of AA/TT and other RR/YY dinucleotides, apparently, reflect both DNA curvature and DNA bendability, cooperatively contributing to the nucleosome formation.     

Interactions between lac repressor protein and site-specific bromodeoxyuridine-substituted operator DNA. Ultraviolet footprinting and protein-DNA cross-link formation

Specific contacts between the lac repressor and operator have been explored using 5-bromodeoxyuridine-substituted DNA. Substitution of BrdU for single thymidine positions in a synthetic 40-base pair operator provides substrate for ultraviolet irradiation; upon irradiation, strand scission occurs at the BrdU residues. When bound, lac repressor protein provides protection against UV-induced breakage depending on the nature of the sites and type of interaction. We have confirmed 13 unique sites of inducer-sensitive protection along the operator sequence using this method compared to complete substitution with BrdU; differences were observed at two positions for singly substituted versus completely substituted DNAs (Ogata, R., and Gilbert, W. (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 4973-4976). The ability of these photosensitive DNAs to form short range cross-links to bound protein has been used to determine the efficiency with which cross-linked protein-DNA complexes are generated at each individual site of BrdU substitution. Five sites of high efficiency cross-linking to the repressor protein have been identified. At one site, cross-linking without protection from strand scission was observed; this result suggests an unusual mechanism of strand scission and/or cross-linking at this site. Comparison of the UV protection results and the cross-linking data show that these processes provide complementary tools for identifying and analyzing individual protein-DNA contacts.     

Unique translational positioning of nucleosomes on synthetic DNAs.

A computational study was previously carried out to analyze DNA sequences that are known to position histone octamers at single translational sites. A conserved pattern of intrinsic DNA curvature was uncovered that was proposed to direct the formation of nucleosomes to unique positions. The pattern consists of two regions of curved DNA separated by preferred lengths of non-curved DNA. In the present study, 11 synthetic DNAs were constructed which contain two regions of curved DNA of the form [(A5.T5)(G/C)5]4 separated by non-curved regions of variable length. Translational mapping experiments of in vitro reconstituted mononucleosomes using exonuclease III, micrococcal nuclease and restriction enzymes demonstrated that two of the fragments positioned nucleosomes at a single site while the remaining fragments positioned octamers at multiple sites spaced at 10 base intervals. The synthetic molecules that positioned nucleosomes at a single site contain non-curved central regions of the same lengths that were seen in natural nucleosome positioning sequences. Hydroxyl radical and DNase I digests of the synthetic DNAs in reconstituted nucleosomes showed that the synthetic curved element on one side of the nucleosomal dyad assumed a rotational orientation where narrow minor grooves of the A-tracts faced the histone surface with all molecules. In contrast, the curved element on the other side of the nucleosome displayed variable rotational orientations between molecules which appeared to be related to the positioning effect. These results suggest that asymmetry between the two halves of nucleosomal DNA may facilitate translational positioning.     

Lipid synthesis in mycobacteria: characterization of the biotin carboxyl carrier protein genes from Mycobacterium leprae and M. tuberculosis.

The causative agents of leprosy and tuberculosis, Mycobacterium leprae and Mycobacterium tuberculosis, have a lipid-rich cell envelope which contributes to virulence and antibiotic resistance. Acyl coenzyme A carboxylase, which catalyzes the first committed step of lipid biosynthesis, consists in mycobacteria of two subunits, one of which is biotinylated. Genes from M. leprae and M. tuberculosis encoding a biotinylated protein have been cloned and sequenced. Analysis of the derived protein sequences demonstrated the presence of biotin-binding sites and putative ATP-bicarbonate interactions sites, consistent with the proteins having a biotin carboxylase function as well as their being biotin carrier proteins.     

Evaluation of the relative effectiveness of hybridization probes prepared by action of hydrazides of biotin derivatives on DNA

Efficiencies of biotinylated DNAs as hybridisation probes in a model system of non-radioactive detection were compared. Probes were obtained by interaction of single-stranded DNA and each of four different hydrazides of biotin derivatives. The most sensitivity in detection of complementary target was obtained using (biocytin hydrazide)-treated DNA. Relations between hydrazide structures and sensitivity of biotinylated probes are discussed.     

A lipid-based method for the preparation of a piezoelectric DNA biosensor

A piezoelectric DNA biosensor was prepared by immobilizing DNA probes on a quartz crystal microbalance (QCM) using a lipid-based method. A QCM electrode was coated with a hybrid bilayer membrane composed of an octadecanethiol monolayer and a lipid monolayer containing biotinylated lipids to establish biotin groups on the electrode surface. A DNA biosensor was prepared by sequentially immobilizing avidin and the biotinylated probe. The DNA biosensor was stable throughout repeated surface regeneration and showed higher sensitivity than that prepared by the conventional chemical method using diimide. We also optimized the surface regeneration conditions and flow rate for flow injection analysis.     

Interaction of poly(ADP-ribose) polymerase 1 with apurinic/apyrimidinic sites within clustered DNA damage

To study the interaction of poly(ADP-ribose) polymerase 1 (PARP1) with apurinic/apyrimidinic sites (AP sites) within clustered damages, DNA duplexes were created that contained an AP site in one strand and one of its analogs situated opposite the AP site in the complementary strand. Residues of 3-hydroxy-2-hydroxymethyltetrahydrofuran (THF), diethylene glycol (DEG), and decane-1,10-diol (DD) were used. It is shown for the first time that apurinic/apyrimidinic endonuclease 1 (APE1) cleaves the DNA strands at the positions of DEG and DD residues, and this suggests these groups as AP site analogs. Insertion of DEG and DD residues opposite an AP site decreased the rate of AP site hydrolysis by APE1 similarly to the effect of the THF residue, which is a well-known analog of the AP site, and this allowed us to use such AP DNAs to imitate DNA with particular types of clustered damages. PARP1, isolated and in cell extracts, efficiently interacted with AP DNA with analogs of AP sites producing a Schiff base. PARP1 competes with APE1 upon interaction with AP DNAs, decreasing the level of its cross-linking with AP DNA, and inhibits hydrolysis of AP sites within AP DNAs containing DEG and THF residues. Using glutaraldehyde as a linking agent, APE1 is shown to considerably decrease the amount of AP DNA-bound PARP1 dimer, which is the catalytically active form of this enzyme. Autopoly(ADP-ribosyl)ation of PARP1 decreased its inhibitory effect. The possible involvement of PARP1 and its automodification in the regulation of AP site processing within particular clustered damages is discussed.     

Chemically synthesized non-radioactive biotinylated long-chain nucleic acid hybridization probes.

A new method for the chemical labelling of nucleic acid with biotin to produce non-radioactive probes has been developed. NN'-Bis-(3-aminopropyl)butane-1,4-diamine (spermine) and long-chain diamino compounds (diaminohexane, diaminodecane and diaminododecane) were linked covalently to biotin and the resultant conjugates were attached to nucleic acid by using a cross-linking reagent (glutaraldehyde or diepoxyoctane). Iodoacetylation and biotinylation of the long-chain diamino compounds produced modified biotinylated conjugates that can be linked to DNA without the use of a cross-linking reagent. These types of probes attach one biotin molecule to each linker arm of spermine, diamino and iodoacetylated amino derivatives. Such probes have long linker arms separating the biotin moiety from the hybridization sites of the nucleic acid. These probes can detect 10 pg of target DNA by dot-blot hybridization.     

Affinity purification of lipid vesicles

We present a novel column chromatography technique for recovery and purification of lipid vesicles, which can be extended to other macromolecular assemblies. This technique is based on reversible binding of biotinylated lipids to monomeric avidin. Unlike the very strong binding of biotin and biotin-functionalized molecules to streptavidin, the interaction between biotin-functionalized molecules and monomeric avidin can be disrupted effectively by ligand competition from free biotin. In this work, biotin-functionalized lipids (biotin-PEG-PE) were incorporated into synthetic lipid vesicles (DOPC), resulting in unilamellar biotinylated lipid vesicles. The vesicles were bound to immobilized monomeric avidin, washed extensively with buffer, and eluted with a buffer supplemented with free biotin. Increasing the biotinyl lipid molar ratio beyond 0.53% of all lipids did not increase the efficiency of vesicle recovery. A simple adsorption model suggests 1.1 x 10(13) active binding sites/mL of resin with an equilibrium binding constant of K = 1.0 x 10(8) M(-1). We also show that this method is very robust and reproducible and can accommodate vesicles of varying sizes with diverse contents. This method can be scaled up to larger columns and/or high throughput analysis, such as a 96-well plate format.     

A plasmid expression system for quantitative in vivo biotinylation of thioredoxin fusion proteins in Escherichia coli.

The high affinity binding interaction of biotin to avidin or streptavidin has been used widely in biochemistry and molecular biology, often in sensitive protein detection or protein capture applications. However, in vitro chemical techniques for protein biotinylation are not always successful, with some common problems being a lack of reaction specificity, inactivation of amino acid residues critical for protein function and low levels of biotin incorporation. This report describes an improved expression system for the highly specific and quantitative in vivo biotinylation of fusion proteins. A short 'biotinylation peptide', described previously by Schatz, is linked to the N-terminus of Escherichia coli thioredoxin (TrxA) to form a new protein, called BIOTRX. The 'biotinylation peptide' serves as an in vivo substrate mimic for E. coli biotin holoenzyme synthetase (BirA), an enzyme which usually performs highly selective biotinylation of E.coli biotin carboxyl carrier protein (BCCP). A plasmid expression vector carrying the BIOTRX and birA genes arranged as a bacterial operon can be used to obtain high level production of soluble BIOTRX and BirA proteins and, under appropriate culture conditions, BIOTRX protein produced by this system is completely biotinylated. Fusions of BIOTRX to other proteins or peptides, whether these polypeptides are linked to the C-terminus or inserted into the BIOTRX active site loop, are also quantitatively biotinylated. Both types of BIOTRX fusion can be captured efficiently on avidin/streptavidin media for purification purposes or to facilitate interaction assays. We illustrate the utility of the system by measurements of antibody and soluble receptor protein binding to BIOTRX fusions immobilized on streptavidin-conjugated BIAcore chips.     

Imaging proteins in live mammalian cells with biotin ligase and monovalent streptavidin

This protocol describes a simple and efficient way to label specific cell surface proteins with biophysical probes on mammalian cells. Cell surface proteins tagged with a 15-amino acid peptide are biotinylated by Escherichia coli biotin ligase (BirA), whereas endogenous proteins are not modified. The biotin group then allows sensitive and stable binding by streptavidin conjugates. This protocol describes the optimal use of BirA and streptavidin for site-specific labeling and also how to produce BirA and monovalent streptavidin. Streptavidin is tetravalent and the cross-linking of biotinylated targets disrupts many of streptavidin's applications. Monovalent streptavidin has only a single functional biotin-binding site, but retains the femtomolar affinity, low off-rate and high thermostability of wild-type streptavidin. Site-specific biotinylation and streptavidin staining take only a few minutes, while expression of BirA takes 4 d and expression of monovalent streptavidin takes 8 d.