Visualization of Surface-tethered Large DNA Molecules with a Fluorescent Protein DNA Binding Peptide

Seonghyun Lee; Kyubong Jo

doi:10.3791/54141

Visualization of Surface-tethered Large DNA Molecules with a Fluorescent Protein DNA Binding Peptide

JoVE Journal
Biology

A subscription to JoVE is required to view this content. Sign in or start your free trial.

JoVE Journal Biology

Visualization of Surface-tethered Large DNA Molecules with a Fluorescent Protein DNA Binding Peptide

Full Text

11,310 Views

08:51 min

June 23, 2016

DOI: 10.3791/54141-v

Seonghyun Lee¹, Kyubong Jo¹

¹Department of Chemistry and Interdisciplinary Program of Integrated Biotechnology,Sogang University

Overview

This article presents a method for visualizing fluorescent protein DNA binding peptide (FP-DBP)-stained large DNA molecules. The technique involves tethering these molecules on a polyethylene glycol (PEG) and avidin-coated glass surface and stretching them using microfluidic shear flows.

Key Study Components

Area of Science

DNA visualization
Fluorescent microscopy
Single molecule manipulation

Background

The study focuses on analyzing DNA and DNA binding proteins.
It aims to improve the convenience of DNA analysis systems.
This method allows for the observation of moving DNA.
It is designed for use with epifluorescent microscopes.

Purpose of Study

To develop a system for manipulating single molecule DNA.
To enhance the visualization of DNA and associated proteins.
To facilitate the analysis of DNA dynamics.

Methods Used

Preparation of glass coverslips on a PTFE rack.
Securing coverslips with PTFE thread seal tape.
Cleaning procedure for the modified glass surfaces.
Utilization of microfluidic shear flows for stretching DNA.

Main Results

Successful tethering of large DNA molecules on modified surfaces.
Effective visualization of DNA dynamics using FP-DBP staining.
Enhanced ability to analyze moving DNA in real-time.
Demonstration of the method's potential in DNA research.

Conclusions

The technique offers a novel approach to DNA visualization.
It provides insights into DNA interactions with binding proteins.
This method can advance research in the field of molecular biology.

Frequently Asked Questions

What is the main advantage of this technique?

The main advantage is the ability to observe and analyze moving DNA with ease.

How are the glass coverslips prepared?

Coverslips are placed on a PTFE rack and secured with PTFE thread seal tape.

What is the purpose of the PTFE thread seal tape?

It is used to secure the coverslips in place during the cleaning procedure.

What type of microscope is used in this study?

An epifluorescent microscope is used for DNA analysis.

What does FP-DBP stand for?

FP-DBP stands for fluorescent protein DNA binding peptide.

What is the role of microfluidic shear flows in this method?

Microfluidic shear flows are used to stretch the DNA molecules for visualization.

We present an approach for visualizing fluorescent protein DNA binding peptide (FP-DBP)-stained large DNA molecules tethered on the polyethylene glycol (PEG) and avidin-coated glass surface and stretched with microfluidic shear flows.

The overall goal of this procedure, is to make a convenient DNA analysis system for an epifluorescent microscope, to manipulate single molecule DNA on modified glass surfaces. This method can help answer key questions in DNA visualization field. When examining DNA self, as well as DNA binding proteins and other small molecules.

The main advantage of this technique is the ability to observe and analyze moving DNA with ease. To begin, place glass coverslips on a PTFE rack and secure them in place, using a piece of PTFE thread seal tape. After wrapping the coverslips, leave a five centimeter long piece of the tape to be used for handling the rack during the cleaning procedure.

View the full transcript and gain access to thousands of scientific videos

Explore More Videos

DNA Visualization Single Molecule DNA DNA Binding Proteins Fluorescent Protein DNA Binding Peptide Piranha Etching Aminosilanization Biotin PEG Succinimidyl Carbonate PEG Succinimidyl Valerate Epifluorescent Microscope DNA Analysis System