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1. Restriction Endonuclease Protection Assays using Infrared-Fluorescent Probes

   https://doi.org/10.17504/protocols.io.bi5ikg4e  

   Van Dyke, Michael; Gracien, Isabelle (July 2020, Protocolsio)

   null (Ed.)

   Many proteins sequence-specifically bind duplex DNA, e.g., transcriptional regulatory proteins. Analysis of their interactions can be performed by a variety of methods, including electrophoretic mobility shift assays (EMSA) and quantitative DNase I footprinting. Here we describe an additional electrophoretic method, restriction endonuclease protection assays (REPA), to qualitatively and quantitatively study the interactions of thermophilic transcription regulatory proteins to PCR-generated, infrared-fluorescent DNA probes. REPA utilizes type IIS restriction endonucleases (IISRE), which cleave double-stranded DNA without specificity at a fixed distance from their recognition sequence. Thus, IISREs can be used to probe the occupancy of a suitably situated DNA-binding site for a variety of ligands. REPA has certain advantages as it does not require the maintenance of ligand-DNA complex stability during gel electrophoresis, as is the case with EMSA and is technically far less challenging than quantitative DNase I footprinting. 

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2. Electrophoretic Mobility Shift Assays using Infrared-Fluorescent DNA Probes

   https://doi.org/10.17504/protocols.io.mbdc2i6  

   Van Dyke, Michael; Cox, James (December 2018, Protocols.io)

   Protein-DNA binding interactions are critical in several biological processes, especially the regulation of gene expression at the level of transcription initiation. An important technique for studying these interactions is the electrophoretic mobility shift assay (EMSA), whereby protein-DNA complexes are resolved on the basis of their mass:charge ratio using native polyacrylamide gel electrophoresis (nPAGE). Here we describe EMSA using PCR-generated, near infrared-fluorescent DNA probes, and IR fluorescence imaging to qualitatively and quantitatively study the interaction of transcriptional regulatory proteins from thermophilic organisms with different DNAs. Direct imaging of IR fluorophore-labeled DNA probes is advantageous because it provides high sensitivity (subnanomolar) without the need for intermediate staining steps or costly and problematic radiolabeled probes, thereby providing a more affordable and sensitive option to image protein-DNA on polyacrylamide gels by techniques such as EMSA. 

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3. Using Restriction Endonuclease, Protection, Selection, and Amplification to Identify Preferred DNA-Binding Sequences of Microbial Transcription Factors

   https://doi.org/10.1128/spectrum.04397-22  

   Barrows, John K.; Van Dyke, Michael W. (February 2023, Microbiology Spectrum)

   Polen, Tino (Ed.)

   ABSTRACT Regulation of gene expression is a vital component of cellular biology. Transcription factor proteins often bind regulatory DNA sequences upstream of transcription start sites to facilitate the activation or repression of RNA polymerase. Research laboratories have devoted many projects to understanding the transcription regulatory networks for transcription factors, as these regulated genes provide critical insight into the biology of the host organism. Various in vivo and in vitro assays have been developed to elucidate transcription regulatory networks. Several assays, including SELEX-seq and ChIP-seq, capture DNA-bound transcription factors to determine the preferred DNA-binding sequences, which can then be mapped to the host organism’s genome to identify candidate regulatory genes. In this protocol, we describe an alternative in vitro , iterative selection approach to ascertaining DNA-binding sequences of a transcription factor of interest using restriction endonuclease, protection, selection, and amplification (REPSA). Contrary to traditional antibody-based capture methods, REPSA selects for transcription factor-bound DNA sequences by challenging binding reactions with a type IIS restriction endonuclease. Cleavage-resistant DNA species are amplified by PCR and then used as inputs for the next round of REPSA. This process is repeated until a protected DNA species is observed by gel electrophoresis, which is an indication of a successful REPSA experiment. Subsequent high-throughput sequencing of REPSA-selected DNAs accompanied by motif discovery and scanning analyses can be used for determining transcription factor consensus binding sequences and potential regulated genes, providing critical first steps in determining organisms’ transcription regulatory networks. IMPORTANCE Transcription regulatory proteins are an essential class of proteins that help maintain cellular homeostasis by adapting the transcriptome based on environmental cues. Dysregulation of transcription factors can lead to diseases such as cancer, and many eukaryotic and prokaryotic transcription factors have become enticing therapeutic targets. Additionally, in many understudied organisms, the transcription regulatory networks for uncharacterized transcription factors remain unknown. As such, the need for experimental techniques to establish transcription regulatory networks is paramount. Here, we describe a step-by-step protocol for REPSA, an inexpensive, iterative selection technique to identify transcription factor-binding sequences without the need for antibody-based capture methods. 

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4. Direct Double-Stranded DNA Quantitation from PCR Reactions V.2

   https://doi.org/10.17504/protocols.io.k5pcy5n  

   Van Dyke, Michael (December 2018, Protocols.io)

   For convenience and for PCR products that are challenging to purify with high efficiency (e.g., chemically modified DNAs), it is often desirable to quantitate synthesized DNA directly from a PCR reaction. Here we describe the use of a high-sensitivity Quant-iT™ PicoGreen® dye-based fluorescence assay to quantitate PCR-synthesized, double-stranded, low molecular weight, 5’-modified DNA probes in the presence of single-stranded primers and deoxyribonucleotides. 

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5. A programmable DNA roadblock system using dCas9 and multivalent target sites

   https://doi.org/10.1371/journal.pone.0268099  

   Matozel, Emily K.; Parziale, Stephen; Price, Allen C. (May 2022, PLOS ONE)

   Volkert, Michael R. (Ed.)

   A protein roadblock forms when a protein binds DNA and hinders translocation of other DNA binding proteins. These roadblocks can have significant effects on gene expression and regulation as well as DNA binding. Experimental methods for studying the effects of such roadblocks often target endogenous sites or introduce non-variable specific sites into DNAs to create binding sites for artificially introduced protein roadblocks. In this work, we describe a method to create programmable roadblocks using dCas9, a cleavage deficient mutant of the CRISPR effector nuclease Cas9. The programmability allows us to custom design target sites in a synthetic gene intended for in vitro studies. These target sites can be coded with multivalency—in our case, internal restriction sites which can be used in validation studies to verify complete binding of the roadblock. We provide full protocols and sequences and demonstrate how to use the internal restriction sites to verify complete binding of the roadblock. We also provide example results of the effect of DNA roadblocks on the translocation of the restriction endonuclease NdeI, which searches for its cognate site using one dimensional diffusion along DNA. 

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