Temperature-gradient gel electrophoresis of nucleic acids: analysis of conformational transitions, sequence variations, and protein-nucleic acid interactions.

Temperature-gradient gel electrophoresis (TGGE) is applied to analyze conformational transitions and sequence variations of nucleic acids and protein-nucleic acid interactions. A linear and highly reproducible temperature-gradient is established perpendicular or parallel to the direction of the electrophoresis. The instrument consists of an electrically insulated metal plate, which is heated at one edge and cooled at the other edge by two thermostating baths and is used as an ancillary device for commercial horizontal gel electrophoresis instruments. Biopolymers are separated in TGGE according to size, shape and thermal stability of their conformational transitions. If the temperature-gradient is established perpendicular to the electrophoresis, monomolecular conformational transitions of nucleic acids show up as continuous transition curves; strand-separation leads to discontinuous transitions. In the studies on viroid RNA it was shown that natural circular viroid RNA undergoes one highly cooperative transition detected by TGGE as a drastic retardation in mobility. Oligomeric replication intermediates of viroids exhibit coexisting structures which could not be detected by any other technique. Double-stranded satellite RNA from cucumber mosaic virus is a mixture of sequence variants, all of which have the identical length of 335 nucleotides. In TGGE six different strains were resolved. Sequence variants of viroids were analyzed by hybridizing viroid RNA to (-)strand viroid RNA transcripts from viroid cDNA clones. Sequence variations lead to mismatches in the double strands and thereby to a shift of the transition curve to lower temperature. Mutations in plasmids, particularly in cloned inserts, were detected by mixing plasmids of two different clones, linearizing, denaturing, renaturing, and searching for shifts in the transition curves, which are generated by mismatch-formation during the renaturation of (+)- and (-)strands from different clones. Examples are given for different viroid clones and HIV-clones from one and the same patient. In another example, clones with point mutations from site-directed mutagenesis are analyzed and selected by TGGE. TGGE is also applied to study the effect of amino acid exchanges in the Tet repressor from E. coli on the thermal stability of the repressor and on the mode of binding of the repressor to the operator DNA. The results are discussed under the aspect that TGGE may be applied as routine analytical laboratory procedure.

Thermal denaturation of engineered tet repressor proteins and their complexes with tet operator and tetracycline studied by temperature gradient gel electrophoresis.

The effects of Trp to Phe exchanges in the Tet repressor on the thermal stability of the proteins and their complexes with operator DNA and inducer have been studied by temperature gradient polyacrylamide gel electrophoresis. The denaturation temperatures obtained by this method are compared with the results from temperature-dependent fluorescence and binding activities of the proteins. It is established that exchanging the interior Trp75 to Phe reduces the thermal stability of the Tet repressor by 8 degrees C while exchanging the exterior Trp43 to Phe has no effect on the stability of the protein. Binding of the inducer tetracycline increases the thermal stability of wild-type and Trp43 to Phe mutant Tet repressors by 5 degrees C, while the ones with the Trp75 to Phe mutation are stabilized by 10 degrees C. The stabilizing effect of operator binding is 20 degrees C in the Trp75 to Phe mutant and only 9 degrees C in the ones with the Trp43 to Phe exchange. In addition to the denaturation temperatures, the gel mobility shifts observed in temperature gradient gel electrophoresis reveal also information about the intermediates of the denaturation reaction. The free proteins and their complexes with the inducer tetracycline exhibit monophasic transitions upon denaturation. The operator complexes of wild-type and Trp75 to Phe mutant repressors denature in more complex reactions. At low temperature they exhibit a stoichiometry of two repressor dimers per tandem tet operator DNA. Upon elevating the temperature they form complexes with only one repressor dimer per DNA fragment. When the temperature is further increased the double-stranded DNA begins to melt from one end resulting in a complex with partially single-stranded DNA which exists only in a narrow temperature range. Finally, the denatured protein and single-stranded DNA are formed at high temperature. The associated mobility shifts are analyzed by changing the ionic strength and characterizing multiphasic melting of a pure DNA fragment by temperature gradient gel electrophoresis.