Transcription factor-DNA interactions are life sustaining and therefore the subject of intensive research. In spite of vast effort, quantitative in vivo studies of the molecular mechanisms underlying these fundamental interactions remain challenging. In the preceding paper, we designed synthetic Sex combs reduced (Scr) peptides and validated genetically their function as transcriptional regulators. Here we present a controllable system for quantitative studies of protein-DNA interactions in live cells that enables us to "titrate" the concentration of the synthetic Scr peptides in a single cell. Using methods with single-molecule sensitivity, advanced fluorescence imaging and fluorescence correlation spectroscopy (FCS), we were able to study the kinetics of Scr-DNA interactions in live salivary gland cells, where Scr is normally expressed during development. We discerned freely moving Scr molecules, characterized the specific and nonspecific Scr peptide-DNA interactions, and estimated their corresponding dissociation constants (K d ) in vivo. Our results suggest that the synthetic Scr transcription factors find their specific target sites primarily by multiple association/dissociation events, the rapidity of which is largely owed to electrostatic interactions. Based on these new findings, we formulate a model mechanism and emulate the kinetics of Scr homeodomain-DNA interactions in live cells using numerical simulations.fluorescence correlation spectroscopy | single-molecule sensitivity | homeodomain | Sex combs reduced | synthetic peptides T ranscription factor-DNA interactions, the assembly of functional transcriptional complexes, and the mechanisms involved in target site recognition are central to understanding gene regulation in vivo. In spite of such relevance, kinetic studies of transcription factor-DNA interactions are limited and have been performed only for a handful of proteins. Most prominent studies include the lac repressor in Escherichia coli (1-4), nuclear receptor-directed transcription (5), helicase translocation along DNA (6), and restriction enzymes-DNA interactions (7,8). The majority of these studies are carried out with naked DNA or reconstituted chromatin, reflecting the in vivo situation only to a limited extent. Chromatin structure in live cells is highly dynamic, involving multiple interactions and transformations (9)(10)(11). Moreover, a number of cofactors and coactivators/corepressors are involved in transcriptional regulation, suggesting that gene expression is accomplished through a dynamic, spatiotemporally entangled interplay between concomitant processesprotein searching for specific target sites, rearrangements of DNA conformation, and recruitment of cofactors and/or coregulators (5, 12, 13). Such complexity is not easily mimicked in solution, therefore necessitating live cell experimentation. However, these measurements are complex, and kinetic studies of protein-DNA interactions in live cells remain scarce (3,4,14,15), mainly due to the limited number of experimental approach...
