Southwestern Blotting Assay.

Southwestern blotting is a technique used to study DNA-protein interactions. This method detects specific DNA-binding proteins by incubating radiolabeled DNA with a gel blot, washing, and visualizing through autoradiography. A blot resulting from 1-dimensional SDS-PAGE reveals the molecular weight of the binding proteins. To increase separation and determine isoelectric point a 2-dimensional gel can be blotted. Additional dimensions of electrophoresis, such as a gel shift (EMSA), can precede isoelectric focusing and SDS-PAGE to further improve separation. Combined with other techniques, such as mass spectrometry, the DNA-binding protein can be identified.

Method for trapping affinity chromatography of transcription factors using aldehyde-hydrazide coupling to agarose.

The use of a method of coupling DNA was investigated for trapping and purifying transcription factors. Using the GFP-C/EBP (CAAT/enhancer binding protein) fusion protein as a model, trapping gives higher purity and comparable yield to conventional affinity chromatography. The chemistry used is mild and was shown to have no detrimental effect on GFP fluorescence or GFP-C/EBP DNA binding. The method involves introducing a ribose nucleotide to the 3' end of a DNA sequence. Reaction with mM NaIO4 (sodium metaperiodate) produces a dialdehyde of ribose that couples to hydrazide-agarose. The DNA is combined at nM concentration with a nuclear extract or other protein mixture, and DNA-protein complexes form. The complex is then coupled to hydrazide-agarose for trapping the DNA-protein complex and the protein eluted by increasing NaCl concentration. Using a different oligonucleotide with the proximal E-box sequence from the human telomerase promoter, USF-2 transcription factor was purified by trapping, again with higher purity than results from conventional affinity chromatography and similar yield. Other transcription factors binding E-boxes, including E2A, c-Myc, and Myo-D, were also purified, but myogenin and NFκB were not. Therefore, this approach proved to be valuable for both affinity chromatography and the trapping approach.

Promoter trapping method: transcription factor purification using human telomerase reverse transcriptase promoter.

BACKGROUND: Transcription factors bind to response elements on the promoter regions of genes to regulate transcriptional activity. One of the major problems with identifying transcription factors is their low abundance relative to other proteins in the cell. Developing a purification technique specific for transcription factors is crucial to the understanding of gene regulation. Promoter trapping is a method developed that uses the promoter regions as bait to trap proteins of interest and then purified using column chromatography. Here we utilize this technique to study the telomerase promoter, which has increased transcriptional activity in cancer cells. Gaining insight on how to control the enzyme at the promoter level may give new routes towards cancer treatments. RESULTS: Our findings show that the telomerase promoter (-170 - +91) and Promoter Trapping isolate a transcriptionally active and reproducible complex, when analyzed by liquid chromatography tandem mass spectrometry. We were also able to identify transcription factors, including AP-2 and SP1 known to bind this promoter, as well as show that these two proteins can bind to each other's response element. CONCLUSION: Here we focus on verifying the ability and versatility of Promoter Trapping coupled with additional well-characterized methods to identify already known factors responsible for telomerase transcriptional regulation.

Coupling of deoxyribonucleic acid to solid supports using 3' terminal ribose incorporation.

To develop a new form of DNA coupling under mild reaction and coupling conditions, DNA oligonucleotides were synthesized containing a 3' ribonucleotide. Upon reaction with millimolar sodium metaperiodate (NaIO4), the ribose is oxidized to a dialdehyde at pH 6.8. This reaction is complete in 30min, is quenched with millimolar sodium metabisulfite (Na2S2O5) and is then suitable for coupling to hydrazide-agarose supports. Coupling occurs with a half-time of 27min and 80% couples in 2h. The EP18 oligonucleotide which binds to the CAAT enhancer binding protein (C/EBP) was synthesized with a 3' ribose (rEP18) and coupled to hydrazide-agarose. The columns prepared show no significant loss of the oligonucleotide after 50 days. A crude bacterial extract from cells expressing a chimeric fusion protein of GFP-C/EBP was applied to the columns and eluted with different salt concentrations. The active protein elutes in 0.5M NaCl and SDS-PAGE/silver stained gels show a single major band which comigrates with GFP-C/EBP as well as three minor contaminants. This provides a new alternative way of coupling DNA to solid supports using mild chemistry which is non-detrimental to the DNA and can be performed if required in the presence of nuclear extract.

Asymmetric polymerase chain reaction provides alternatives for preparation of (GT)5-tailed duplex DNA promoter for promoter trapping.

Synthesis of (GT)5-tailed duplex DNA promoter is an important first step for purifying transcription complexes by promoter trapping purification. In our previous publication, we showed that the purification of the c-jun promoter using lambda exonuclease digestion of polymerase chain reaction (PCR) produced DNA with single-stranded tails. Asymmetric PCR can also produce tailed single strands that can be annealed to yield the desired promoter. An effective method uses asymmetric PCR and double digestion. After PCR, first a restriction enzyme, in this case SacII, cuts duplex strands remaining after asymmetric PCR, leaving 5' phosphoryl ends susceptible to a second digestion with lambda exonuclease to effectively degrade any duplex. The resulting single strands are then annealed to produce a duplex DNA with a single-stranded (GT)5 tail at the 3' end of each strand of the duplex. Unlike the previously described method, this novel procedure produces the desired tailed promoter devoid of any untailed duplex.

Transcription factor proteomics: identification by a novel gel mobility shift-three-dimensional electrophoresis method coupled with southwestern blot and high-performance liquid chromatography-electrospray-mass spectrometry analysis.

Transcription factor (TF) purification and identification is an important step in elucidating gene regulatory mechanisms. In this study, we present two new electrophoretic mobility shift assay (EMSA)-based multi-dimensional electrophoresis approaches to isolate and characterize TFs, using detection with either southwestern or western blotting and HPLC-nanoESI-MS/MS analysis for identification. These new techniques involve several major steps. First, EMSA is performed with agents that diminish non-specific DNA-binding and the DNA-protein complex is separated by native PAGE gel. The gel is then electrotransferred to PVDF membrane and visualized by autoradiography. Next, the DNA-protein complex, which has been transferred onto the blot, is extracted using a detergent-containing elution buffer. Following detergent removal, concentrated extract is separated by SDS-PAGE (EMSA-2DE), followed by in-gel trypsin digestion and HPLC-nanoESI-MS/MS analysis, or the concentrated extract is separated by two-dimensional gel electrophoresis (EMSA-3DE), followed by southwestern or western blot analysis to localize DNA binding proteins on blot which are further identified by on-blot trypsin digestion and HPLC-nanoESI-MS/MS analysis. Finally, the identified DNA binding proteins are further validated by EMSA-immunoblotting or EMSA antibody supershift assay. This approach is used to purify and identify GFP-C/EBP fusion protein from bacterial crude extract, as well as purifying AP1 and CEBP DNA binding proteins from a human embryonic kidney cell line (HEK293) nuclear extract. AP1 components, c-Jun, Jun-D, c-Fos, CREB, ATF1 and ATF2 were successfully identified from 1.5 mg of nuclear extract (equivalent to 3×10(7) HEK293 cells) with AP1 binding activity of 750 fmol. In conclusion, this new strategy of combining EMSA with additional dimensions of electrophoresis and using southwestern blotting for detection proves to be a valuable approach in the identification of transcriptional complexes by proteomic methods.

Repeated probing of Southwestern blots using alkaline phosphatase stripping.

Southwestern blotting is when a DNA sequence is used to probe DNA-binding proteins on an electrophoretic gel blot. It would be highly desirable to be able to probe a blot repeatedly with different DNA sequences. Alkaline phosphatase can remove 5'-phosphoryl groups from DNA and radiolabeled 5'-(32)P-DNA probes are commonly used in Southwestern blotting. Here is shown that once probed, the radioisotope signal on the blot can be effectively removed by brief digestion with alkaline phosphatase, and the blot can then be repeatedly probed at least six times with different DNA probes. This exceeds the repetitions possible with another commonly used method using SDS. The technique can be used with either one-dimensional or multi-dimensional Southwestern blots and does not have a large effect on the phosphorylation state of the blotted proteins. An alternative method using T4 polynucleotide kinase stripping is also introduced but was less well characterized.

Two-dimensional southwestern blotting and characterization of transcription factors on-blot.

Two-dimensional Southwestern blotting (2D-SW) described here combines several steps. Proteins are separated by two-dimensional gel electrophoresis and transferred to nitrocellulose (NC) or polyvinylidene fluoride (PVDF) membrane. The blotted proteins are then partially renatured and probed with a specific radiolabeled oligonucleotide for Southwestern blotting (SW) analysis. The detected proteins are then processed by on-blot digestion and identified by LC-MS/MS analysis. A transcription factor, bound by a specific radiolabeled element, is thus characterized without aligning with protein spots on a gel. In this study, we systematically optimize conditions for 2D-SW and on-blot digestion. By quantifying the SW signal using a scintillation counter, the optimal conditions for SW were determined to be PVDF membrane, 0.5% PVP40 for membrane blocking, serial dilution of guanidine HCl for denaturing and renaturing proteins on the blot, and an SDS stripping buffer to remove radiation from the blot. By the quantification of the peptide yields using nano-ESI-MS analysis, the optimized conditions for on-blot digestions were found to be 0.5% Zwittergent 3-16 and 30% acetonitrile in trypsin digestion buffer. With the use of the optimized 2D-SW technique and on-blot digestion combined with HPLC-nano-ESI-MS/MS, a GFP-C/EBP model protein was successfully characterized from a bacterial extract, and native C/EBP beta was identified from 100 microg of HEK293 nuclear extract without any previous purification.