Initial state of DNA-Dye complex sets the stage for protein induced fluorescence modulation

Replication protein A (RPA) is a multisubunit, single-stranded DNA-binding protein that is absolutely required for replication of SV40 DNA. The three cDNAs encoding the subunits of human replication protein A (70, 32, and 14 kDa) have been expressed individually and in combination in Escherichia coli. When subunits were expressed individually, appropriately sized polypeptides were synthesized, but were found to be either insoluble or aggregated with other proteins. We examined the interactions between individual RPA subunits by expressing pairs of subunits and determining if they formed stable complexes. Only the 32- and 14-kDa subunits formed a soluble complex when coexpressed. This complex was purified and characterized. The 32-14 kDa subcomplex did not have any effect on DNA replication and was not phosphorylated efficiently in vitro. We believe that the 32.14-kDa subcomplex may be a precursor in the assembly of the complete RPA complex. Coexpression of all three subunits of RPA resulted in a significant portion of each polypeptide forming a soluble complex. We have purified recombinant RPA complex from E. coli and demonstrated that it has properties similar to those of human RPA. Recombinant human RPA has the same subunit composition and the same activities as the authentic complex from human cells. Recombinant human RPA binds single-stranded DNA and is capable of supporting SV40 DNA replication in vitro. In addition, recombinant RPA became phosphorylated when incubated under replication conditions.

Single-molecule FRET has been widely used for monitoring protein-nucleic acids interactions. Direct visualization of the interactions, however, often requires a site-specific labeling of the protein, which can be circuitous and inefficient. In addition, FRET is insensitive to distance changes in the 0-3-nm range. Here, we report a systematic calibration of a single molecule fluorescence assay termed protein induced fluorescence enhancement. This method circumvents protein labeling and displays a marked distance dependence below the 4-nm distance range. The enhancement of fluorescence is based on the photophysical phenomenon whereby the intensity of a fluorophore increases upon proximal binding of a protein. Our data reveals that the method can resolve as small as a single base pair distance at the extreme vicinity of the fluorophore, where the enhancement is maximized. We demonstrate the general applicability and distance sensitivity using (a) a finely spaced DNA ladder carrying a restriction site for BamHI, (b) RNA translocation by DExH enzyme RIG-I, and (c) filament dynamics of RecA on single-stranded DNA. The high spatio-temporal resolution data and sensitivity to short distances combined with the ability to bypass protein labeling makes this assay an effective alternative or a complement to FRET.