4 - 1 - Week 4 - 1 Introduction to DNA (16_15).txt

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This lecture is about DNA.
Since the introduction of DNA
technology a few decades ago,
forensic science has been revolutionized,
and Edmond Locard's
statement that "Every
contact leaves a trace" 
has really come true, or
almost completely true.
And with DNA technology,
those traces can often be
individualized to a particular person.
One area where DNA technology has made
an enormous change is in sex crimes.
Because previously in a sexual assault or
rape case, there might be only
the victim and the perpetrator,
and of course, if it's a rape-murder,
there's only the perpetrator left alive.
But DNA
technology means that
forensic scientists can
identify the perpetrator of these crimes,
even though there is no witness.
Well, let's talk about, what is DNA?
A human being is made up of
an enormous number of cells,
and inside every single cell,
there's the nucleus.
Well, every single cell, except for
your red blood cells. Your genetic
material is inside the nucleus of each
cell, except for the red blood cells.
In the genetic material,
inside the nucleus of a single cell,
there are the complete instructions
to create a human being
and it's amazing to think that all
that information is packaged inside
your little bit of DNA which
weighs about seven picograms.
So you may think that your new laptop
has a fantastic amount of memory on it,
but that is really nothing compared to
the information that's contained in
the DNA molecule.
While we're thinking about where is
the DNA in the cell, there's an important
thing that we must think about in
terms of DNA at the crime scene.
You never find DNA directly
at the crime scene.
You can't go round a crime scene with
a very big magnifying glass, picking up
pieces of DNA.
What is collected at the crime scene is
biological material that contain DNA.
The DNA can then be extracted from
that material back in the laboratory.
Examples of such materials would be blood,
semen, saliva, skin cells,
hair, though that's often not very good,
and of course, body parts.
Now, back to the DNA.
The DNA in the nucleus of your cell is
packaged into 23 pairs of chromosomes.
So lets look at the chromosomes.
So, we humans have 23 pairs of
chromosomes for a grand total of 46.
Different species
have different numbers of chromosomes.
The pea plant manages with a total
of 14 chromosomes, whereas
dogs need a bigger total of 78.
Well, out of our 23 pairs of chromosomes,
22 pairs are normal chromosomes
containing genetic information.
The remaining two chromosomes contain
the information that determines sex.
So of course,
if you have the XY combination
of chromosomes, you'll be male;
if you have the XX combination,
you would be female.
So forensic scientists, by
looking at these chromosomes,
can determine the gender of the person.
The different chromosomes which
are shown here in this scheme,
they are different sizes and
different shapes.
And when they've been dyed, they show up
with particular distinctive patterns so
you can tell them apart,
and they are numbered one from the biggest
through the 22 and then the X and the Y.
Your genes are contained within
the different chromosomes.
Okay.
Now, an important point that we'll come
back to later in the lecture is that
some of this is inherited from the mother
and some of it is inherited from the father.
And this will be important
later on in the lecture.
Let's take a close look at a chromosome.
There's a chromosome.
It's basically a length of DNA which is
wrapped up into a particular shape,
and it's wrapped up in this particular
shape with the assistance of
small protein molecules which are called histones.
So basically, you're keeping
your DNA tidy and organized.
So that's the chromosomes and
as we said, the genes are contained
within the chromosomes.
So let's have a look at the genes.
Now one of the surprising things about
DNA is that your genetic information,
the information to create a human being,
appears to be contained in only part of the DNA.
That part of the DNA is known as
the coding region, which has the genes.
The rest of the DNA is known
as the non-coding region.
The non-coding regions of DNA
is a lot of your DNA.
90 or 95% of your DNA is
these non-coding regions.
Why do we have them?
We don't really know,
but it's there,
and it's often referred to as junk DNA.
Presumably, it has a purpose, but
we don't really know what it is,
so we call it junk DNA.
Okay, now the genes that are contained
within these chromosomes,
just as the number of chromosomes
varies from species to species, so
does the number of genes.
And typically,
simple organisms have much
smaller number of genes,
complex organisms have a lot.
So bacteria have a relatively
small number, and
humans, it's estimated, have
somewhere like 30,000.
Now, what are genes made of?
Okay, genes are made of
what are called base pairs,
and a single gene will have about
1,000 to 10,000 base pairs.
Okay, let's get down to
the molecular level, so
that we can understand
this concept of a base pair.
And let's look at DNA at the molecular
level to see what it's made of.
And it turns out to be very, very simple.
DNA is made of a sugar.
Not the ordinary sugar that we put
in coffee, and tea, and so forth.
It's a sugar based on a simpler
sugar molecule called ribose.
[SOUND].
But it's not exactly ribose.
It's actually a derivative of ribose,
where the hydroxyl group in
the two position of the molecule is absent,
so it's called 2-deoxyribose.
And it's the D of deoxyribose
that gives us the D of DNA.
In addition to 2-deoxyribose,
we have a phosphate molecule.
So if we combine 2-deoxyribose
with phosphoric acid
at the exact right position,
we get a phosphate ester of 2-deoxyribose.
All right, now the third component
are the bases.
Where do the bases go?
Okay, the bases are attached
to the 2-deoxyribose,
and now we have the basic building
block of DNA containing the sugar,
the phosphate and the base,
and this molecule is called a nucleotide.
Okay, now which bases are they?
The bases are heterocyclic,
nitrogen-containing aromatic molecules,
and there are four of them used in DNA.
And they are adenine, guanine,
cytosine, and thymine.
So we have 2-deoxyribose,
we have phosphate, and
we have these four bases.
Therefore, we have four
possible nucleotides,
and these four nucleotides are known by
their initial letters, A, G, C, and T.
So how do we take these four nucleotides
and build them up into a molecule of DNA?
The key is the deoxyribose portion and
the phosphate portion.
DNA is actually a polymer of
the deoxyribose phosphate ester with
the bases attached on the side.
So we form a molecule which is in a long
chain with alternating sugar, phosphate,
sugar, phosphate, sugar, phosphate, and
along the chain we have the bases
attached onto the sugar.
In the example shown here, the sequence
we have an A, a G and a C and a T.
But because the base is not
involved in forming the chain,
we can actually make any sequence we want.
Now, you probably heard of this
concept of the double helix.
What does it mean?
Well, the DNA double helix.
DNA consists of two chains, not just one,
and these are wound together,
and these two chains are held together
by a chemical interaction which is
known as a hydrogen bond.
Now, a hydrogen bond is not
a very strong interaction, but
it occurs all the way down the DNA chain,
so the double helix is
stable under normal conditions.
Now hydrogen bonds are actually
quite common in chemistry.
Okay, and they are in fact
what makes water a liquid.
If you simply look at an
ordinary water molecule, and
look at just the properties of a water molecule,
you would think that water should be
a gas at room temperature and pressure.
But it's not, it's a liquid.
And the reason water is a liquid
is because the molecules stick
together through hydrogen bonds.
And that is an interaction between
a hydrogen of one water molecule and
an oxygen atom of another water molecule.
And it's the same interaction that
holds the DNA chains together.
Now, these hydrogen bonds in DNA are not
just between any old bits of the molecule.
They are very specifically between
the bases on the different chains.
But its more than just sticking
the chains together through the bases,
there are specific interactions so
that the bases go in pairs.
So if you have a nucleotide
of an A on one chain and
a T on the other chain, the A and
the T will interact strongly together.
In fact, A and T will recognize
each other and bind together.
Similarly, C and G
will bind together through hydrogen bonds.
And you can see from the diagram that
A and T complement each other very nicely.
G and C also complement each other very nicely.
So, this is called complementary base pairing.
So in the human DNA,
there's about three billion base pairs.
Okay, and once again,
this varies from species to species,
and it not clear why some species have so
many more base pairs than others.
For instance, this cute little plant here,
Paris japonica, it's believed
that it probably has
the most base pairs of any species,
150 billion base pairs.
And if you took that DNA molecule and
you stretched it out straight,
it would be 91 meters long.
And why this plant needs so
many base pairs is a mystery.
Okay.
So we know why different nucleotides
can stick to each other.
It's complementary base pairing.
So what happens in the DNA molecule
is that you have this complementary
base pairing where you match up
the base pairs.
This forms the helix, and
then further hydrogen bonds
fix it in this double helix.
Now, let's take a quick look at
the information in the genetic code.
So this is a quick look at what
goes on in the coding region.
The coding region stores the information
by the sequence of the base pairs.
So it's like having an alphabet with
four letters, A, T, C, and G,
and DNA manages perfectly well with
just four letters in its alphabet,
whe...