Dramatic increase in the signal and sensitivity of detection <Emphasis Type="Italic">via</Emphasis> self-assembly of branched DNA

In molecular testing using PCR, the target DNA is amplified via PCR and the sequence of interest is investigated via hybridization with short oligonucleotide capture probes that are either in a solution or immobilized on solid supports such as beads or glass slides. In this report, we report the discovery of assembly of DNA complex(es) between a capture probe and multiple strands of the PCR product. The DNA complex most likely has branched structure. The assembly of branched DNA was facilitated by the product of asymmetric PCR. The amount of branched DNA assembled was increased five fold when the asymmetric PCR product was denatured and hybridized with a capture probe all in the same PCR reaction mixture. The major branched DNA species appeared to contain three reverse strands (the strand complementary to the capture probe) and two forward strands. The DNA was sensitive to S1 nuclease suggesting that it had single-stranded gaps. Branched DNA also appeared to be assembled with the capture probes immobilized on the surface of solid support when the product of asymmetric PCR was hybridized. Assembly of the branched DNA was also increased when hybridization was performed in complete PCR reaction mixture suggesting the requirement of DNA synthesis. Integration of asymmetric PCR, heat denaturation and hybridization in the same PCR reaction mixture with the capture probes immobilized on the surface of solid support achieved dramatic increase in the signal and sensitivity of detection of DNA. Such a system should be advantageously applied for development of automated process for detection of DNA.     

Site-directed immobilization of antibody onto solid surfaces for the construction of immunochip

The performance of an immuno-analytical system can be assessed in terms of its analytical sensitivity,i.e., the detection limit of an analyte, which is determined by the amount of analyte molecules bound to the capture antibody that has been immobilized onto a solid surface. To increase the number of the binding complexes, we have investigated a site-directed immobilization of an antibody that has the ability to resolve a current problem associated with a random arrangement of the insolubilized immunoglobulin. The binding molecules were chemically reduced to produce thiol groups that were limited at the hinge region, and then, the reduced products were coupled to biotin. This biotinylated antibody was bound to a streptavidincoated surface via the streptavidin-biotin reaction. This method can control the orientation of the antibody molecules present on a solid surface and also can significantly reduce the possibility of steric hindrance in the antigen-antibody reactions. In a two-site immunoassay, the introduction of the site-directly immobilized antibody as the capture enhanced the sensitivity of analyte detection approximately 10 times compared to that of the antibody randomly coupled to biotin. Such a novel approach would offer a protocol of antibody immobilization in order for the possibility of constructing a high performance immunochip.     

A method for incorporating labeled lacithin into serum low density lipoproteins in vitro.

A sonicated dispersion of [14C]lecithin was incubated with high density lipoproteins (HDL) coupled to Sepharose. After washing the gels thoroughly with a buffer, the gels were incubated with low density lipoproteins (LDL); [14C]lecithin was transferred from the sonicated dispersion via HDL-Sepharose to the LDL. The LDL fraction thus prepared showed no contamination with lecithin dispersion or HDL. The lecithin:cholesterol acyltransferase (LCAT) reaction could be completely inhibited during preparation, and the net recovery of radioactivity in LDL was 16% of that of the original lecithin dispersion. The [14C]lecithin in the washed HDL-Sepharose was shown to be a substrate of the LCAT reaction in vitro.     

Isolation of Y-chromosomal repetitive DNA sequences of Drosophila hydei via enrichment of chromosome-specific sequences by heterogeneous hybridization between female and male DNA

Male or female DNA of Drosophila hydei was sheared by sonication, denatured, reannealed to different C0t-values and fractionated by hydroxyapatite. The highly repetitive, moderately repetitive and unique fractions of female DNA were denatured again and coupled via diazotization or cyanogen bromide to macroporous Sephacryl S-500. Enrichment of Y-chromosomal sequences was achieved by cycling each of the different fractions of male DNA under optimized hybridization conditions over a column with a manifold excess of immobilized female DNA of the corresponding complexity. Thereby, Y-chromosomal sequences of D. hydei could be enriched about 100-fold for highly and moderately repetitive DNA and about 10-fold for unique DNA. When a library of male D. hydei DNA was screened with Y-enriched highly repetitive DNA, more than 98% of all hybridizing phages contained inserts of repetitive Y-chromosomal DNA of at least four different sequence families.     

Sequence specific purification of a particular tRNA by solid phase DNA probe.

A novel method for the purification of a specific tRNA using solid phase DNA probe is developed. With this method, the probe DNA immobilized on HPLC gel hybridized with target tRNA within a minute at room temperature. The hybridizing capacity of the solid phase probe was about 20 O.D. per gram dry gel when yeast phenylalanine tRNA was used. The specificity of this method was extremely high and the recovery rate was about 90%.     

Immobilized Alkaline Phosphatase for Molecular Cloning

Alkaline phosphatase from E. coli was immobilized on Sepharose-4B, macroporous cellulose and chitosan-based carriers. The yields of immobilization were over 60% in most cases. It was shown that immobilized alkaline phosphatase can be used for dephosphorylation of DNA 5'-termini.     

Determination of rate constants of antigen-antibody reaction. A theory

A new method of determination of rate constants for antigen-antibody interactions is proposed. This method is based on a solid phase immunoenzymatic analysis of the dynamics of elution of immobilized antigen-bound antibodies in the presence of a free antigen. The kinetics of this process is described by a system of differential equations, whose solution results in expression defining the dynamics of antibody interaction with immobilized and free antigens. Simple formulas were derived for the calculation of the rate and equilibrium constants for the antibody-antigen reaction on the basis of experimental kinetic curves. The use of theoretical kinetic curves for antibody elution showed that these formulas reflect with a high degree of accuracy the kinetic properties of the reaction under study.     

Target site selection for an RNA-cleaving catalytic DNA.

A small catalytic DNA, known as the 10-23 DNA enzyme or deoxyribozyme, has been shown to efficiently hydrolyze RNA at purine-pyrimidine (R-Y) junctions in vitro. Although these potentially cleavable junctions are ubiquitous, they are often protected from deoxyribozyme activity by RNA secondary structure. We have developed a multiplex cleavage assay for screening the entire length of a target RNA molecule for deoxyribozyme cleavage sites that are efficient, both in terms of kinetics and accessibility. This strategy allowed us to simultaneously compare the RNA cleaving activity of 80 deoxyribozymes for a model target gene (HPV16 E6), and an additional 60 deoxyribozymes against the rat c-myc target. The human papilloma virus (HPV) target was used primarily to characterize the multiplex system and determine its validity. The c-myc target, coupled with a smooth muscle cell proliferation assay, allowed us to assess the relationship between in vitro cleavage efficiency and c-myc gene suppression in cell culture. The multiplex reaction approach streamlines the process of revealing effective deoxyribozymes in a functional assay and provides accessibility data that may also be applicable to site selection for other hybridization-based agents.     

Immobilized Alkaline Phosphatase for Molecular Cloning

Alkaline phosphatase from E. coli was immobilized on Sepharose-4B, macroporous cellulose and chitosan-based carriers. The yields of immobilization were over 60% in most cases. It was shown that immobilized alkaline phosphatase can be used for dephosphorylation of DNA 5'-termini.     

Effect of salicylic acid,methyl jasmonate,ethephon and cantharidin on anthraquinone production by Rubia cordifolia callus cultures transformed with the rolB and rolC genes

A novel method for immobilizing large DNA fragments on a solid surface was developed. A mixed self-assembled monolayer of thiolated single-stranded DNA with inert alkanethiol was generated on a gold (Au) surface through the Au-S reaction. Surface-tethered DNA generated by this method was compatible with various genetic engineering techniques, including hybridization, polymerization, restriction enzyme digestion and ligation. Kinetic control of surface coverage of immobilized DNA was critical for optimizing genetic engineering techniques on solid-phase. Multi-step reaction schemes utilizing various genetic engineering techniques described above were employed for solid-phase gene assembly. We were able to immobilize DNA fragments of up to 1180 bp on a solid surface. Furthermore, we showed that these immobilized genes can be regenerated by PCR. The present work suggests that these types of assembled genes can be used to store and regenerate genes on solid-phase.     

Tag/hybridization-based sensitive detection of polymerase chain reaction products

The polymerase chain reaction (PCR) is an important technology to amplify a single copy or a few copies of DNA segment in genomic DNAs, visualizing the segment as DNA fragment. Thus, PCR is frequently used in various examinations such as detection of bacteria and fungi in the food industry. Here, we report a simple and sensitive method for detection of PCR products using single-strand tag sequence and hybridization of the tag sequence to the complementary tag sequence immobilized on solid material (STH). The detection sensitivity was found to be at least 50 times higher than electrophoresis/ethidium bromide (EtBr) visualization for approximately a 500-bp fragment and higher than the ordinary hybridization, that is, hybridization of denatured PCR product to probe sequence immobilized on solid material.     

Application of DNA sonication in the study of reassociation kinetics]

Single-stranded breaks arising is DNA under sonication divide the molecule in short double-stranded regions of lengths depending on sonication conditions. The reassociation rate of DNA with single-stranded breaks is considerably lowered as compared with intact DNA of the same length. For sonicated DNA the slowing of reassociation and the deflection to higher orders of C(o)t of the reaction is observed at the late stages. Further process of sonication occurs likely on single-stranded breaks and DNA fragments obtained as a result of infinite sonication are practically intact. Reassociation of DNA, degraded to a "saturation", proceeds as a second order reaction in precise accordance with the obtained fragment length.     

Colorimetric quantification of in vitro-amplified template DNA to be used for solid phase sequencing.

A protocol for colorimetric determination of DNA amplified by the polymerase chain reaction (PCR) and subsequently immobilized to a solid support is described. The protocol consists of three steps: (i) binding of PCR amplified lac operator-containing DNA to magnetic beads; (ii) binding of a Lac repressor-beta-galactosidase fusion protein to the lac operator and (iii) colorimetric detection of the immobilized beta-galactosidase. In practice, steps (i) and (ii) are performed concurrently. The protocol is well suited both for manual and automated procedures and the immobilized template can, after melting, be used directly for solid phase sequencing. The assay is used to demonstrate that template concentration is important for the quality of sequence data obtained from an automated DNA sequencer.     

A general method for highly selective cross-linking of unprotected polypeptides via pH-controlled modification of N-terminal alpha-amino groups

A method is described for the highly selective modification of the alpha-amino groups at the N-termini of unprotected peptides to form stable, modified peptide intermediates which can be covalently coupled to other molecules or to a solid support. Acylation with iodoacetic anhydride at pH 6.0 occurs with 90-98% selectivity for the alpha-amino group, depending on the N-terminal residue (as shown with a series of model hexapeptides containing a competing Lys residue). Although Cys residues must be protected (reversibly or irreversibly) before the anhydride reaction, there are no detectable side reactions of the alpha-amino moiety--of the reagent or of modified peptide--with the side chains of His, Met, or Lys. The reaction works well in denaturants, so that inhibitory effects of noncovalent structure can be minimized. In a second step the iodoacetyl-peptide can be reacted with a thiol group on a protein, on a solid chromatography matrix, on a spectroscopic probe, etc. This is illustrated by reaction of a series of N alpha-iodoacetyl-peptides with murine interferon-gamma, which contains a C-terminal Cys residue. Data are presented which suggest that this iodoacetic anhydride scheme is superior in selectivity for alpha-amino groups to conventional chemical approaches to cross-linking such as use of 2-iminothiolane or N-hydroxysuccinimide-activated carboxylic acid esters. The reaction is ideally suited for modifying peptide fragments, as pure species or as mixtures, derived from proteolytic or chemical fragmentation of proteins. Furthermore, polypeptides synthesized biosynthetically, for example via recombinant DNA techniques, can be cross-linked in this way.(ABSTRACT TRUNCATED AT 250 WORDS)     

Continuous production of maltotetraose using immobilized Pseudomonas stutzeri amylase

A continuous production process of maltotetraose was investigated by using immobilized maltotetraose (G(4))- forming amylase (1,4-alpha-D-glucan maltotetraohydrolase, EC3.2.1.60) from Pseudomonas stutzeri adsorbed on a macroporous hydrophobic resin. The maximum reaction rate was obtained at 55 degrees C and the activation energy of hydrolysis by immobilized G(4)-forming amylase was calculated to be 8.45 kcal/mol. The maltotetraose yield was greatly influenced by the flow rate of substrate solution, its concentration, and the immobilized enzyme activity. The newly defined factor "specific space velocity" was successfully introduced to normalize the operating parameters. Using this factor, the immobilized enzyme reactor then can be simulated and the operating dynamics can be determined.     

Activity and operational stability of immobilized mandelonitrile lyase in methanol/water mixtures

Summary The enzyme mandelonitrile lyase was covalently immobilized on solid support materials using different methods. Immobilization on porous silica using coupling with glutaraldehyde afforded preparations with high enzyme loading (up to 9% (w/w)). The immobilized enzyme was used in a packed bed reactor for the continuous production of d-mandelonitrile from benzaldehyde and cyanide. The influence of the flow rate, pH, substrate concentrations and enzyme loading on the reaction yield and the enantiomeric purity of the product was investigated. In order to suppress the competing spontaneous reaction, the enzymatic reaction must be rapid. A flow rate of 9.5 ml/min (0.1 M benzaldehyde and 0.3 M HCN) through a 3 ml reactor afforded a 86% yield of mandelonitrile with 92% enantiomeric excess. No leakage of enzyme occurred under continuous operation. One column was used continuously for 200 h without any decrease in yield or enantiomeric purity of the product. High concentrations of benzoic acid were shown to decrease the operational stability of the system.     

Detecting minimal traces of DNA using DNA covalently attached to superparamagnetic nanoparticles and direct PCR-ELISA

A single bond covalent immobilization of aminated DNA probes on magnetic particles suitable for selective molecular hybridization of traces of DNA samples has been developed. Commercial superparamagnetic nanoparticles containing amino groups were activated by coating with a hetero-functional polymer (aldehyde-aspartic-dextran). This new immobilization procedure provides many practical advantages: (a) DNA probes are immobilized far from the support surface preventing steric hindrances; (b) the surface of the nanoparticles cannot adsorb DNA ionically; (c) DNA probes are bound via a very strong covalent bond (a secondary amine) providing very stable immobilized probes (at 100 degrees C, or in 70% formamide, or 0.1N NaOH). Due to the extreme sensitivity of this purification procedure based on DNA hybridization, the detection of hybridized products could be coupled to a PCR-ELISA direct amplification of the DNA bond to the magnetic nanoparticles. As a model system, an aminated DNA probe specific for detecting Hepatitis C Virus cDNA was immobilized according to the optimised procedure described herein. Superparamagnetic nanoparticles containing the immobilized HCV probe were able to give a positive result after PCR-ELISA detection when hybridized with 1 mL of solution containing 10(-18) g/mL of HCV cDNA (two molecules of HCV cDNA). In addition, the detection of HCV cDNA was not impaired by the addition to the sample solution of 2.5 million-fold excess of non-complementary DNA. The experimental data supports the use of magnetic nanoparticles containing DNA probes immobilized by the procedure here described as a convenient and extremely sensitive procedure for purification/detection DNA/RNA from biological samples. The concentration/purification potential of the magnetic nanoparticles, its stability under a wide range of conditions, coupled to the possibility of using the particles directly in amplification by PCR greatly reinforces this methodology as a molecular diagnostic tool.     

The biophysics of DNA hybridization with immobilized oligonucleotide probes.

A mathematical model based on receptor-ligand interactions at a cell surface has been modified and further developed to represent heterogeneous DNA-DNA hybridization on a solid surface. The immobilized DNA molecules with known sequences are called probes, and the DNA molecules in solution with unknown sequences are called targets in this model. Capture of the perfectly complementary target is modeled as a combined reaction-diffusion limited irreversible reaction. In the model, there are two different mechanisms by which targets can hybridize with the complementary probes: direct hybridization from the solution and hybridization by molecules that adsorb nonspecifically and then surface diffuse to the probe. The results indicate that nonspecific adsorption of single-stranded DNA on the surface and subsequent two-dimensional diffusion can significantly enhance the overall reaction rate. Heterogeneous hybridization depends strongly on the rate constants for DNA adsorption/desorption in the non-probe-covered regions of the surface, the two-dimensional (2D) diffusion coefficient, and the size of probes and targets. The model shows that the overall kinetics of DNA hybridization to DNA on a solid support may be an extremely efficient process for physically realistic 2D diffusion coefficients, target concentrations, and surface probe densities. The implication for design and operation of a DNA hybridization surface is that there is an optimal surface probe density when 2D diffusion occurs; values above that optimum do not increase the capture rate. Our model predicts capture rates in agreement with those from recent experimental literature. The results of our analysis predict that several things can be done to improve heterogeneous hybridization: 1) the solution phase target molecules should be about 100 bases or less in size to speed solution-phase and surface diffusion; 2) conditions should be created such that reversible adsorption and two-dimensional diffusion occur in the surface regions between DNA probe molecules; 3) provided that 2) is satisfied, one can achieve results with a sparse probe coverage that are equal to or better than those obtained with a surface totally covered with DNA probes.     

Macroporous and hydrophilic polymer resins modified with isothiocyanate groups for immobilization of enzymes

Hydrophilic and macroporous polymer resins composed of glycerylmethacrylate, styrene, and divinylbenzene were quite easily modified with isothiocyanate groups using a Friedel-Crafts reaction with 3-chloropropionyl chloride and subsequent nucleophilic reaction with KSCN. Alkaline phosphatase and trypsin could be covalently bound to the isothiocyanate-carrying polymer resins, and the immobilized enzymes obtained were sufficiently active and stable due to a covalent bonding via a spacer group between the carrier resins and the enzymes and also due to a hydrophilic environment around the enzymes. A heterogeneity of the immobilized enzyme was taken into account to interpret the thermal denaturation process of the enzyme immobilized onto the resins.     

Effect of molecular mobility on coupled enzymatic reactions involving cofactor regeneration using nanoparticle-attached enzymes

Cofactor-dependent multi-step enzymatic reactions generally require dynamic interactions among cofactor, enzyme and substrate molecules. Maintaining such molecular interactions can be quite challenging especially when the catalysts are tethered to solid state supports for heterogeneous catalysis for either biosynthesis or biosensing. The current work examines the effects of the pattern of immobilization, which presumably impacts molecular interactions on the surface of solid supports, on the reaction kinetics of a multienzymic system including glutamate dehydrogenase, glucose dehydrogenase and cofactor NAD(H). Interestingly, particle collision due to Brownian motion of nanoparticles successfully enabled the coupled reactions involving a regeneration cycle of NAD(H) even when the enzymes and cofactor were immobilized separately onto superparamagnetic nanoparticles (124 nm). The impact of particle motion and collision was evident in that the overall reaction rate was increased by over 100% by applying a moderate alternating magnetic field (500 Hz, 17 Gs), or using additional spacers, both of which could improve the mobility of the immobilized catalysts. We further observed that integrated immobilization, which allowed the cofactor to be placed in the molecular vicinity of enzymes on the same nanoparticles, could enhance the reaction rate by 1.8 fold. These results demonstrated the feasibility in manipulating molecular interactions among immobilized catalyst components by using nanoscale fabrication for efficient multienzymic biosynthesis.