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Other Nucleic Acid Applications

Sephadex. Other carbohydrate matrices such as Sephadex (based on dextran) have more uniform particle sizes. Their advantages over the celluloses include faster and more reproducible flow rates and they can be used directly without removal of fines . Sephadex, which can also be obtained in a variety of ion-exchange forms (see Table 15) consists of beads of a cross-linked dextran gel which swells in water and aqueous salt solutions. The smaller the bead size, the higher the resolution that is possible but the slower the flow rate. Typical applications of Sephadex gels are the fractionation of mixtures of polypeptides, proteins, nucleic acids, polysaccharides and for desalting solutions. [Pg.23]

One of the most important and exciting advances in modern biochemistry has been the application of spectroscopic methods, which measure the absorption and emission of energy of different frequencies by molecules and atoms. Spectroscopic studies of proteins, nucleic acids, and other biomolecules are providing many new insights into the structure and dynamic processes in these molecules. [Pg.99]

Although thi.s appendix i.s entitled Protein Techniques, tlie.se metliods are also applicable to other macromolecules. such as nucleic acids. [Pg.153]

The reactivity of substituted aromatic compounds, more than that ol any other class of substances, is intimately tied to their exact structure. As a result, aromatic compounds provide an extraordinarily sensitive probe for studying the relationship between structure and reactivity We ll examine that relationship in this and the next chapter, and we ll find that the lessons learned are applicable to all other organic compounds, including such particularly important substances as the nucleic acids that control our genetic makeup. [Pg.517]

The theory and application of this fluorescence method have been discussed in detail by LePecq and others (3,8). The assay requires that there is sufficient ionic strength to minimize ionic binding (e.g., O.IM sodium chloride), that the pH is 4-10, that no heavy metals are present, that the fluorescence is not enhanced on binding to other excipients (e.g., proteins) and that at least portions of the nucleic acids are not complexed. These requirements can usually he met when dealing with recombinant products in some cases the samples must he manipulated to create the appropriate conditions. In the intercalative method of dye binding, proteins rarely interfere with the assay, and procedures have been developed to remove the few interferences they may cause (e.g., the use of heparin or enzymatic digestion of the protein 9). [Pg.46]

It should be pointed out that when using ethidium bromide the sensitivity of the assays varies depending on the physical state of the nucleic acids (see Table I). Ethidium does not discriminate between RNA and DNA, although dyes are available which bind DNA exclusively, so the relative amounts of each may be determined by taking two sets of measurements. Alternatively, nucleases (DNA-ase or RNA-ase) can be used to exclusively remove one or the other in a mixture. Nucleic acids from different sources (see Table II) also show a variation in sensitivity, and the fluorescence assay lacks the selectivity of the hybridization technique. Nevertheless, for rapid screening or quality-control applications the fluorescence assay is still the method of choice. [Pg.48]

The refinement of other analytical methods, such as electrophoresis [34,36], the various techniques of optical spectroscopy [103-105], and nuclear magnetic resonance [201], is supplemented by the recent advances in real-time affinity measurements [152,202], contributing to the understanding of biomolecular reactivity. Taken together, the improvement of analytical methods will eventually allow a comprehensive characterization of the structure, topology, and properties of the nucleic acid-based supramolecular components under consideration for distinctive applications in nanobiotechnology. [Pg.423]


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Nucleic acids applications

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