The variation in electrophoretic mobility of DNA under conditions of marginal helix stability provides a useful means for investigation of the relation between the helix-random chain transition and base sequence in natural DNA and a powerful procedure for separation of DNA molecules according to sequence. The use of statistical mechanical theory for analysis of the transition equilibria together with new, simplified theoretical considerations on the effect of strand unravelling on mobility have shown that the gel behavior is predictable for known sequences. A number of the distinctive consequences of the theory and their correspondence with the properties of real molecules have been demonstrated. These include the extremely close cooperative linkage of large blocks of bases into domains, the existence of sharp boundaries between domains, the major role of nearest-neighbor interaction in determining stability, the dependence of domain structures on neighboring and more remote sequences, and the depression of domain melting temperature if the sequence lies at the end of a molecule. New and unusual applications derive from the possibility of separating DNA molecules by properties of their sequence. Exceedingly complex mixtures, such as the sum of all fragments produced by the action of a sixbase specific restriction endonuclease on a complete bacterial genome, can be resolved completely. Additional inserted sequences are easily discerned. The difference of a single base pair in a molecule permits detection and isolation of mutant sequences. The need for full sequential analysis of long molecules for characterization of mutants can be reduced by localizing a change within a small fragment.
The aim of this work was to develop an assay capable of detecting adulteration of high premium milk with milk from cheaper sources. An indirect, competitive ELISA was developed for the rapid detection of cows' milk in the milk of goat, sheep, and buffalo. The assay uses a monoclonal antibody produced against bovine IgG. This antibody recognizes a species-specific epitope on the heavy chain of both bovine IgG1 and IgG2. A peroxidase-conjugated anti-mouse IgG antibody was used to detect bound monoclonal antibody and subsequent enzymatic conversion of substrate resulted in clear differences in absorbance when assaying different mixtures of milks adulterated with cows' milk. Once optimized, the ELISA was found to be highly specific. Detection limits of the assay are 1.0 microg/mL of bovine IgG, or 0.1% (vol/vol) adulteration with cows' milk. The assay was highly reproducible (CV < 10%) and performed equally well when used to detect bovine IgG in mixtures with the 3 types of milk tested. The ELISA performance makes it suitable for development as a kit, for use in the field as a high throughput screening ELISA.
A number of enzyme-linked immunosorbent assays (ELISAs) have been developed for the detection of milk adulteration in dairy products. Target antigens have been caseins, lactoglobulins, immunoglobulins and other whey proteins. Polyclonal and monoclonal antibodies have been used in a variety of formats including direct, indirect, competitive and sandwich ELISAs. ELISAs have been successfully applied to the detection of cows' milk adulteration of sheep, goat and buffalo milk. Goat milk adulteration of sheep milk has also been detected. A number of ELISAs have also been applied to cheese. It is recommended that ELISA should be used in combination with PCR to ensure compliance with current legislation.
Torsional thermal oscillations of the DNA double helix within the electron paramagnetic resonance (EPR) time scale (10(-10)-10(-3) s) as indicated by a rigid, intercalating probe are much smaller in the spacer segment between nucleosomes in chromatin than in long, free DNA molecules. Still smaller DNA oscillation is indicated in intact nuclei and yet smaller if the nuclei have been treated with glutaraldehyde. The values of EPR measurements are not affected by the loading density of probe. If the probe were capable of substantial oscillations or movement different from that of the helix, those oscillations would be expected to dominate the spectra when movement of the helix is restrained. We conclude that the correlation time for torsional movement of free DNA inferred from EPR spectra is characteristic of the double helix and that there is no significant independent motion of the probe. The correlation time for the DNA double helix in molecules longer than approximately 500 base pairs is close to 30 ns, corresponding to an elastic constant of 1.5 X 10(-19) ergs cm for deformation by twisting. The motions observed in chromatin are consistent with a model in which spheres of 50-60-A radius are connected by simple elastic rods with the length of spacer DNA and the same elastic constant. The spin-labeled ethidium probe has been characterized in detail by nuclear magnetic resonance, infrared, fluorescence, and visible light spectroscopy. The binding equilibria are consistent with the hypothesis that strongly immobilized probe molecules are preferentially bound to spacer DNA.
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