How do scientists read a person’s DNA? – James, aged 11, Thame, UK
DNA (which stands for deoxyribonucleic acid) contains all the information needed to make your body work. It is also surprisingly simple.
DNA is made from four chemical building blocks, which are arranged one after each other. This sequence is the instruction manual for your body. The building blocks are called adenine, thymine, guanine and cytosine, but we usually just call them A, T, G and C.
The information in your DNA is bunched into sections called genes. The genes are like sentences in an instruction manual.
Most genes control the everyday running of your body - how it grows hair, digests food or carries oxygen around. So 99.9% of your DNA is exactly the same as everyone else on the planet. The rest is what makes you unique. For example, if you have blue eyes, then a few of the letters in some genes will be different from someone with brown eyes.
As we grow, cells in our body divide. One cell becomes two. Every time this happens each of the new cells needs a full copy of DNA. DNA makes this easy, because it’s made of two strands. When a cell divides the strands split up, and a new copy is made of each one. Let’s look at how this is done.
The letter A on one strand is always opposite the letter T on the other, and G is always opposite C. So a short double strand of DNA might looks like this:
Let’s see what happens with one of the strands in a dividing cell. First a T is added opposite the first A to make:
Then an A gets attached to the T like this:
Next, C get placed opposite G:
And so on until a whole new double-stranded piece of DNA is made.
We can use this knowledge of how DNA copies itself to read a person’s DNA.
To do this, a scientist puts the DNA into four tubes. Then they add all the machinery that the cell uses to copy DNA, and lots of extra As, Ts, Cs and Gs into each of the tubes.
Next, they add some DNA letters that have been changed so they can’t join with the next letter in the sequence. You can think of them like pieces of Lego, but with flat tops so you can’t add a brick on top of it. Let’s call these special DNA letters A*, T*, G* and C*.
Each of our four tubes gets some of the special DNA letters added to it: A*s in the first tube, T*s in the second, G*s in the third and C*s in the fourth.
Let’s imagine what happens with our DNA sequence in the tube containing A*.
First, just like before, T is added opposite the first A to make:
Next, though, an A* might get added to make this:
If this happens, then the next letter can’t get attached to the A*. This is as long as this stretch of DNA gets.
But there’s plenty more DNA and letters in the tube and in some cases a normal A will have been added at that point, followed by two Cs to make this:
Next there is a choice again. If an A* gets added the DNA sequence will look like this:
Every time we reach the point where we need to add an A there is a chance an A* might get added, which stops the DNA getting any longer. So in the end these DNA strands get made:
The scientist reading the DNA knows that each strand in this tube ends in an A*. She then counts how many pairs are in each strand of DNA. By doing this, she can work out that the 2nd, 5th and 8th letters are all As.
She then does exactly the same thing with the other tubes and works out that the 1st and 6th letters are Ts, the 3rd, 4th and 9th letters are Cs and the 7th is a G. By putting that all together, she can read the whole DNA sequence.
Reading DNA is useful because sometimes the letters in the genes aren’t quite right, like a misspelled word in a set of instructions. This might cause some of your cells to not work properly.
For example, just one wrong letter in one particular gene might mean someone is more likely to become diabetic, or get cancer when they are older. Reading someone’s DNA allows doctors to spot and treat these diseases before they become too bad.
This article has been amended to correct an error. A previous version stated that the 9th letter in the example DNA strand was an A. It is in fact the 8th letter.
This Article was originally published on The Conversation.
Author: Mark Lorch
Read the original article here.