As you’re probably well aware, our DNA is like this humongous blueprint of information on how to make a human. Usually, this massive document is packaged up nicely into a storage bin called a chromosome. Actually, usually, we have 46 chromosomes that we use to neatly organize all our information, depending on how you define organizes. Each of the 46 chromosomes is actually part of a pair of chromosomes since you get one from each parent, so 23 pairs. If you wanted to make another human, first you’d have to find someone that feels the same way, and then you both contribute half of your chromosomes, so one from each pair is Fifty-fifty.
Now, what if someone contributes one
too many? Say Dad contributes 23 and Mom contributes 24, is that possible? Yes,
and it’s the basis of one of the most common chromosomal disorders—Down
Syndrome. Someone with Down syndrome has 47 chromosomes instead of 46,
specifically, they have an extra copy of chromosome 21, so instead of two, they
have three, so Down Syndrome’s also known as trisomy 21, in other words, “three
chromosomes 21s”. Alright, so in order to package up half the chromosomes into
either a sperm cell or an egg cell, you actually start with a single cell that
has 46 chromosomes, let’s just say we’re making an egg cell for the mother, I’m
just going to show one pair of chromosomes, but remember that all 23 pairs do
this. 
So the process of meiosis starts, which is what produces our sex
cells, and the chromosomes replicate, and so now they’re sort of shaped like an
‘X’—even though there are two copies of DNA here, we still say it’s one
chromosome since they’re hooked together in the middle by this thing called a
centromere.
Then the cell splits in two and
pulls apart the paired chromosomes, so in each of these cells, you’ve now got 23
chromosomes. Now the two copies of the chromosome get pulled apart, and the
cells split again, which means four cells, each still with 23 chromosomes. Now, these are ready to pair up with a sperm cell from dad that has 23 chromosomes
as well, totaling 46 chromosomes, and voila–nine months down the road you’ve
got yourself a baby. Now, with Down Syndrome Or Trisomy 21, a process called non-disjunction
accounts for about 95% of cases.
Non-disjunction means the
chromosomes don’t split apart. If the chromosomes in this first step don’t
split apart, then one cell ends up with both chromosomes and the other gets
none. Then the final result is 2 cells with an extra chromosome, and two cells
missing a chromosome. Non-disjunction can also happen in the second step
though, so the first step goes great, and both cells have a chromosome, but if
they don’t split apart in the second step, then the final result is one cell
with an extra chromosome, one cell missing chromosome, and two with the right
number of chromosomes.
Now, if a sperm cell combines with
any of these that have a duplicate of chromosome 21, then the combined cell
will have one extra copy of chromosome 21, in other words, “3 chromosome 21s”,
or trisomy 21. In case you were wondering, the sperm could also combine with
these cells that have the missing chromosome, if that’s the case then there
would be a total of only one chromosome 21, and we would call it monosomy 21. In
my example, we followed the egg cell from the mother, but this process could
happen the opposite way where the sperm starts out with too many or too few
copies of chromosome 21. Apart from nondisjunction, Robertsonian translocation
accounts for about 4% of trisomy 21 cases. Translocation, in this case, is a
fancy way of saying move from one place to another; so a part of one chromosome
moves and switches places with a part from another chromosome.
In this case, the long arm of
chromosome 21 translocates over to chromosome 14, and you end up with two
hybrids, one with both long arms and one with both short arms. This little guy
with the short arms carries just a little bit off, usually nonessential genetic
information, and is typically lost by the end of meiosis. So there are a few
ways this can go down, first, including the translocated chromosomes, they
replicate, and now these could split into one with both normal chromosomes, and
one with the long guy and short guy, in which case after splitting again you’d
have two normal cells and two cells with a big guy since we lost the little guy
along the way. So now contribute the other parents' DNA, and you’ve got two
normal cases, and then these two cases are called “balanced carriers”, and we
say it’s balanced because you’ve got both long arms, and so most of the genes
are still here, kind of like a two-for-one deal.
Now let’s say the normal chromosome
14 ends up with the short and normal chromosome 21 with the long. Now you get
two cells with the normal and long-arm, and two cells with the normal and short
arm, which remember is usually lost. So these ones have one extra chromosome
21 since the long arms carry most of the genetic material for both chromosomes
14 and 21, and these ones are missing chromosomes. Now combine these with the
other parents again, and you have trisomy 21 here, and monosomy 21 here, since
it’s missing a chromosome 21. If this process was switched such that chromosome
14 ended up with the long chromosome first, then you’d ultimately end up with
trisomy 14 and monosomy 14. So of the 12 possibilities, two end up being
trisomy 21. With Robertsonian translocation, one of these chromosomes needs to
be chromosome 21. Even though the other is usually chromosome 14, it can
actually be other chromosomes as well, like chromosome 22.
Finally, about 1% of patients are mosaics, meaning their cells are mixed, and some have 46 chromosomes and some have 47. How does that happen though? Well, let’s think about what happens after conception. So you’ve got this one cell, called the zygote that needs to develop into a human. Since we’re not single-celled organisms, it has to divide, over and over again, essentially producing every kind of cell in the body. Now, each of these divisions is called mitosis. Non-disjunction of chromosome 21 can also happen during mitosis, in which case you’d end up with one cell that has an extra chromosome 21, and one without, so one with 47 total chromosomes and one with 45. The cell with 45 chromosomes isn’t able to survive, but the one with 47 does survive, and continues to replicate and produce more cells with 47 chromosomes.
If this happens early on in
development, then you can imagine that a lot of cells down the line can have 47
chromosomes. If it happens later on, then fewer cells will have 47 chromosomes. Mosaics
can also happen when the zygote starts with trisomy 21, or 47 total
chromosomes. In this case, non-disjunction would produce one cell with another
extra chromosome 21, so this one has four chromosome 21s, totaling 48 chromosomes,
and this cell can’t survive, The other cell, though, loses one of its three
chromosome 21s, so now it has 46 chromosomes, which happens to be the normal
amount of chromosomes. And this is sort of like the opposite situation, because
now, through a mistake, you’ve actually ended up with the right amount of
chromosomes. So if it happens early in development, you’ll actually end up with
the normal amount of chromosomes. If it’s late in development though, then fewer
cells will have the normal 46 chromosomes.
Now a major risk factor for Down
syndrome is maternal age, the age of the mother. Trisomy 21 happens about once
in about 1500 births where the mother is younger than 20 years old, contrasted
to about one in 25 births where the mother’s older than 45 years old.
During pregnancy, some screening
tests can be done, and certain markers suggest a higher risk that a baby might
have Down syndrome. Alpha-fetoprotein or AFP, unconjugated estriol or uE3,
is on average lower when compared to unaffected pregnancies, and human
chorionic gonadotropin, or HCG, as well as inhibin A, are both
typically elevated compared to unaffected pregnancies. An imaging test,
using ultrasound, can also be performed, where clinicians look for nuchal translucency,
literally seeing how much light passes through the neck area of the fetus. None
of these are exact indicators of Down syndrome, however, but they do give
valuable information about the overall risk of Down syndrome. Even though
there’s a long list of complications and hardships for people with down
syndrome, improved medical care has led to much greater longevity and quality
of life. Many individuals with down syndrome are able to thrive and lead full
lives.
Thank You