DNA Sequencing - 3D

yourgenome

28 Sept 201604:55

Summary

TLDRDNA sequencing involves determining the order of DNA bases in a strand. The process begins with cutting DNA into smaller pieces, inserting them into plasmids, and multiplying them in bacterial cells. DNA is isolated, sequenced by adding ingredients like DNA polymerase and terminator bases, and heated to create single strands. The sequencing reaction produces DNA fragments of varying lengths, which are separated by electrophoresis. DNA fragments are read by their terminator base colors—green for 'A', blue for 'C', yellow for 'G', and red for 'T'—recorded to reveal the DNA sequence.

Takeaways

🧬 DNA sequencing involves determining the order of nucleotide bases in a DNA molecule.
🔪 DNA must be fragmented into smaller pieces before sequencing.
🧫 Fragments are inserted into plasmid DNA and introduced into bacterial cells for replication.
📦 The DNA is isolated from the bacteria for sequencing.
🧪 Sequencing reaction involves a mixture of free DNA bases, DNA polymerase, primers, and terminator bases with fluorescent tags.
🔥 Initial heating to 96°C separates the DNA into single strands.
🌡️ Temperature adjustments allow primer binding and DNA polymerase activity.
🔬 DNA polymerase adds bases until a terminator base is incorporated, halting the process.
🔄 The cycle of heating and cooling is repeated to produce various DNA fragment lengths.
🚀 Electrophoresis separates DNA fragments by length through a capillary tube.
🌈 Fluorescent terminator bases are identified by color, correlating to specific bases.
📝 The sequence is determined by converting the recorded colors into the corresponding DNA bases.

Q & A

What is the primary purpose of DNA sequencing?
-The primary purpose of DNA sequencing is to determine the order of the building blocks, or bases (A, C, G, T), in a strand of DNA.
Why is it necessary to cut DNA into smaller pieces before sequencing?
-Cutting DNA into smaller pieces allows for the insertion of these pieces into plasmid DNA, which can then be inserted into bacterial cells. This process enables the production of many copies of the DNA as the bacterial cells multiply, facilitating the sequencing process.
How does the process of bacterial cell multiplication help in DNA sequencing?
-Bacterial cell multiplication helps in DNA sequencing by creating multiple copies of the inserted DNA fragment. This amplification makes it easier to isolate and analyze the DNA for sequencing.
What are DNA primers and what is their role in the sequencing process?
-DNA primers are short pieces of DNA that provide a starting point for DNA polymerase to begin synthesizing a new strand of DNA. They bind to the plasmid DNA at a lower temperature, enabling the start of the sequencing reaction.
What are terminator bases and how do they affect the sequencing reaction?
-Terminator bases are modified DNA bases that are labeled with colored fluorescent tags and are chemically altered to prevent further addition of bases to the new strand of DNA. When a terminator base is incorporated into the growing DNA strand, the DNA polymerase stops and falls away, marking the end of that particular sequence.
How does the temperature variation during the sequencing process affect the reaction?
-The temperature variation is crucial for the sequencing process. High temperatures (96°C) are used to separate the DNA into single strands, a lower temperature (50°C) allows primers to bind, and a moderate temperature (60°C) enables DNA polymerase to bind and start synthesizing the new DNA strand.
What is the role of electrophoresis in reading the DNA sequence?
-Electrophoresis is used to separate the various DNA fragments by length. An electrical charge is applied, causing the negatively-charged DNA molecules to move through a capillary tube containing a porous gel. The shorter fragments move through the gel more easily, allowing them to be arranged by size and read in order.
How does the color of the terminator bases help in determining the DNA sequence?
-Each terminator base is labeled with a different color that fluoresces when illuminated by a laser at the end of the capillary. A camera detects these colors, and by associating each color with its corresponding base (A=green, C=blue, G=yellow, T=red), the sequence of the DNA can be determined.
What is the significance of the different lengths of DNA fragments produced during sequencing?
-The different lengths of DNA fragments are crucial as they represent the sequence at different points where the terminator base was added. The length of each fragment determines the order in which the fragments are read during electrophoresis, contributing to the overall DNA sequence.
How does the sequencing machine record the DNA sequence?
-The sequencing machine records the DNA sequence by capturing the color of the terminator bases as a series of colored blocks. Each colored block corresponds to the labeled terminator base at the end of each DNA fragment, which is then converted into the corresponding letter to represent the DNA sequence.
What happens to the DNA after it is isolated from the bacteria?
-After the DNA is isolated from the bacteria, it is transferred to a plate where the sequencing reaction takes place. A mixture of ingredients, including free DNA bases, DNA polymerase enzyme, DNA primers, and modified terminator bases, is added to initiate the sequencing process.
Why are the DNA fragments arranged from the shortest to the longest during electrophoresis?
-During electrophoresis, the negatively-charged DNA fragments move through the porous gel in the capillary tube. The shorter fragments can move through the gel more easily and quickly than the longer fragments, resulting in a size-based arrangement from shortest to longest, which aids in the accurate reading of the DNA sequence.