Analysis of gamma radiation-induced damage to plasmid DNA using dynamic size-sieving capillary electrophoresis.

Bacterial plasmids and the chromosomal DNA of many organisms adopt naturally the negatively supercoiled conformation. Therefore, the irradiation of such plasmids could be used to model conformational changes of chromosomal DNA associated with externally-induced damage. We have applied dynamic size-sieving capillary electrophoresis (CE) to monitor the damage of three DNA plasmids, over an unprecedented base pair (bp) size range (2870-27 500 bp), upon exposure to gamma-radiation (20-400 Gy). Predominantly, CE with UV absorbance detection in the absence of DNA intercalating dyes was employed to preclude undesirable, induced plasmid conformational changes. Plasmid samples and their enzymatic digestion products were analyzed using both CE and slab gel electrophoresis (SGE) in order to verify the conformation of sample components. Relative to SGE, CE analyses revealed more fine structural features of plasmid degradation.

Genetic fingerprinting of grape plant (Vitis vinifera) using random amplified polymorphic DNA (RAPD) analysis and dynamic size-sieving capillary electrophoresis.

Dynamic size-sieving capillary electrophoresis with laser-induced fluorescence detection (DSCE-LIF) was combined with random amplified polymorphic DNA (RAPD) analysis to demonstrate the feasibility of the genetic analysis of grape plant varieties and clones within a variety. Parameters of the genomic DNA extraction process, as well as those of the RAPD analysis, were optimized specifically for this application. Polymorphic DNA fragments were generated for four different grape plant varieties including Cabernet Franc, Cabernet Sauvignon, Merlot, and Chardonnay. Relative to slab gel electrophoresis (SGE) with ethidium bromide staining, DSCE-LIF provided superior separation efficiency and detection limits in the analysis of DNA polymorphic bands. Optimal DSCE-LIF analyses were achieved using a 10-fold RAPD sample dilution, hydrodynamic sample injection, and 100 ng/mL of YO-PRO-1 DNA intercalator in the dynamic size-sieving buffer solution. In addition, the reproducibility of both the DSCE-LIF and RAPD analyses were demonstrated.

Mutation identification DNA analysis system (MIDAS) for detection of known mutations.

We introduce a novel experimental strategy for DNA mutation detection named the Mismatch Identification DNA Analysis System (MIDAS) [1, 2], which has an associated isothermal probe amplification step to increase target DNA detection sensitivity to attomole levels. MIDAS exploits DNA glycosylases to remove the sugar moiety on one strand (the probe strand) at a DNA base pair mismatch. The resulting apyrimidinic/ apurinic (AP) site is cleaved by AP endonucleases/lyases either associated with the DNA glycosylase or externally added to the reaction mixture. MIDAS utilizes 32p- or FITC-labeled oligonucleotides as mutation probes. Generally between 20-50 nucleotides in length, the probe hybridizes to the target sequence at the reaction temperature. Mismatch repair enzymes (MREs) then cut the probe at the point of mismatch. Once the probe is cleaved, the fragments become thermally unstable and fall off the target, thereby allowing another full-length probe to hybridize. This oscillating process amplifies the signal (cleaved probe). Cleavage products can be detected by electrophoretic separation followed by autoradiography, or by laser-induced fluorescence-capillary electrophoresis (LIF-CE) of fluorophore-labeled probes in two minutes using a novel CE matrix. In the present experiments, we employed the mesophilic Escherichia coli enzyme deoxyinosine 3'-endonuclease (Endo V), and a novel thermostable T/G DNA glycosylase, TDG mismatch repair enzyme (TDG-MRE). MIDAS differentiated between a clinical sample BRCA 1 wild-type sequence and a BRCA1 185delAG mutation without the need for polymerase chain reaction (PCR). The combination of MIDAS with LIF-CE should make detection of known point mutations, deletions, and insertions a rapid and cost-effective technique well suited for automation.

The use of dynamic size-sieving capillary electrophoresis and mismatch repair enzymes for mutant DNA analysis.

The detection of base pair mismatches in limiting amounts of DNA is important in the early diagnosis of cancer and other genetic diseases. The specific type and exact location of a bp mismatch in certain genes can yield information on the likelihood of a patient developing a genetic disease, as well as the severity of the disease. We demonstrate two methods of specific DNA point mutation detection and identification that involve the integration of mismatch repair cleavage enzyme analyses with dynamic size-sieving capillary electrophoresis. The mismatch repair cleavage enzymes employ the very mechanism that a cell uses in its own mismatch recognition and repair systems. One analysis employs an isothermal signal amplification process, and the other involves polymerase chain reaction (PCR) (Hoffmann-LaRoche, Nutley, NJ, U.S.A.) for amplification of the DNA. Separation of the DNA fragments using dynamic size-sieving CE yields a cleaved fragment, providing definitive evidence of a bp mismatch. The specificity and sensitivity of the assay are facilitated by the detection of fluorescently labeled DNA fragments using laser-induced fluorescence detection; picogram quantities of a target DNA can be analyzed reproducibly.

Analysis of DNA fragmentation using a dynamic size-sieving polymer solution in capillary electrophoresis.

Various natural and induced processes cause DNA fragmentation. Examples of these processes include apoptosis, enzymatic digestion, free radical production from ionizing radiation, photoscission by laser radiation and thermal degradation. Slab gel electrophoresis has been used most often to monitor such DNA damage. We have investigated with capillary electrophoresis the use of a new size-sieving polymer solution, TreviSol-CE (TS-CE), to monitor the DNA fragments produced from a variety of degradation processes. This polymer solution provides high run-to-run migration time and peak width reproducibilities and high separation efficiency of double-stranded DNA fragments in the 500 to 7000 base pair size range. Analysis of apoptotic DNA fragments suggested the presence of multiple nucleosomes within each cell type investigated. For irradiated DNA standards, peak-width-at-half-height and peak area were used to monitor the progress of DNA fragmentation. For both apoptotic DNA and irradiated DNA standards, fine structural features of fragmentation were revealed.

The characterization of composite agarose/hydroxyethylcellulose matrices for the separation of DNA fragments using capillary electrophoresis.

Mixtures of the polysaccharide derivatives, 19% hydroxyethylated SeaPrep agarose (SP-AG) and hydroxyethylcellulose (HEC), in aqueous buffer solutions are applied for the first time to the separation of DNA fragments using capillary electrophoresis (CE). These matrices form unique size-sieving networks that allow the separation of a wide size range of DNA fragments in a single analysis. Relative to their homogeneous counterparts, the composite separation matrices provide enhanced selectivity properties of DNA fragments, especially for fragments greater than 1000 base pairs (bp) in length. Additionally, the effects on separation performance of capillary temperature, the incorporation of a DNA intercalator, and applied field strength are demonstrated. Solution viscosity measurements of the homogeneous and composite matrix solutions were made in order to establish the entanglement threshold concentrations for the unique size-sieving solutions. The relatively low solution viscosities of the composite separation matrices allow reproducible replacement of the separation matrix between analyses. The mechanism of separation of DNA fragments for the composite matrices is proposed.

The characterization of a new size-sieving polymeric matrix for the separation of DNA fragments using capillary electrophoresis.

A low-viscosity, polysaccharide matrix (TreviSol-CE [TS-CE], Trevigen, Inc., Gaithersburg, MD, U.S.A.) has been characterized experimentally in capillary electrophoresis for the separation of DNA fragments. The mass fraction (%) of the matrix in buffer solution and the applied field strength may be varied according to the size of DNA fragments to be separated. The use of tris-phosphate-EDTA (TPE) buffer at pH 7, instead of the more commonly used tris-borate-EDTA (TBE) and tris-acetate-EDTA (TAE) buffers at pH 8.3, provides higher separation efficiency in conjunction with this matrix and simultaneously preserves the internal coating of the capillary for high run-to-run reproducibility. In comparison with other commercially available DNA separation matrices for CE, TS-CE provides enhanced separation ability of DNA fragments greater than 600 base pairs (bp) in length and lower UV absorbance background for enhanced detectability.

The use of a new gel matrix for the separation of DNA fragments: a comparison study between slab gel electrophoresis and capillary electrophoresis.

TreviGel-500, a new polysaccharide matrix containing AgaCryl, commercially available as a powder for slab gel electrophoresis, is now being applied to the separation of DNA fragments in capillary electrophoresis. The capillary mode allows the use of one to two orders of magnitude lower mass fractions of matrix and approximately five to six orders of magnitude lower sample quantities than the slab gel electrophoresis counterpart for optimal separation of DNA fragments in the 100 to 2,000 base pair size range. In the capillary mode, this new separation matrix forms a semi-rigid gel that demonstrates enhanced selectivity for DNA fragments in the 1,000 to 7,000 base pair size range relative to alternative size-sieving polymer solutions. In addition, this matrix offers the advantages of lower toxicity than acrylamide. Comparisons are drawn between the use of this matrix in both slab gel electrophoresis and capillary electrophoresis for the separation of DNA fragments with respect to the mass fraction of the matrix in buffer, the buffer composition and sample loading or injection parameters.

Retention and selectivity of flavanones on homopolypeptide-bonded stationary phases in both normal- and reversed-phase liquid chromatography.

Three linear polymers of repeating amino acid units, or homopolypeptides, have been individually covalently bonded to microparticulate silica and evaluated for liquid chromatographic separations. The retention and selectivity of seven flavanones were investigated on these stationary phases and a structurally similar, commercially available reference stationary phase, Chiraspher. All three of the homopolypeptide stationary phases retain solutes in the normal-phase mode. The aromatic-containing homopolypeptide stationary phases also retain solutes in the reversed-phase mode. Selectivity values for the flavanones were higher in the normal-phase mode; chiral selectivity was observed for the amphiphilic homopolypeptide stationary phase in the reversed-phase mode. The retention mechanism of each stationary phase is suggested based on the chemical nature and conformation of the corresponding homopolypeptide ligand.