Spearin Surname Project |
Where & When ... Temporal & Geographic Distribution DNA - everything you wanted to know but were afraid to ask There are two types - nuclear/chromosomal DNA which is found in the nucleus of
every cell and is arranged into 23 pairs of chromosomes; and mitochondrial DNA
which is found in the mitochondria (energy-producing structures within every
cell). For the purposes of the Spearin Y-DNA Project, we are only interested in
the chromosomal DNA, and specifically the Y chromosome. We'll look closer at
the structure of this DNA later. The Y-chromosome is the smallest of all the chromosomes and contains
very little genetic material compared to the other chromosomes. From the point
of view of the family researcher, a useful characteristic of the Y-chromosome
is that it is passed on from father to son virtually unchanged, generation
after generation, with little variation. And of course the other thing that is
passed (largely) unchanged from father to son, generation after generation, is
the surname! So when we find someone with the same surname we may ask ourselves: I wonder if they're related to me? ... and testing the Y-chromosome can supply
the answer because if the two people have exactly the same Y-chromosome, then
it must have come from a common ancestor sometime in the last 1000 years or so
(i.e. since the invention of surnames)! If you looked at this uncoiled
chromosome under a microscope, it might look like a railway track[1],
stretching from London to Aberdeen, or Sydney to Perth, or New Jersey to Los
Angeles. The track consists of the two metal rails (two parallel backbones of
sugar and phosphate molecules) and the wooden sleepers. Each 'sleeper' along
this track represents a 'base pair', either T bound to A, or C bound to G,
where T, A, C, and G are the 'nucleotides' thymine, adenosine, cytosine or
guanine. The important thing to note is that T can only bind to A (and vice
versa) and C can only bind to G (and vice versa). So if we were to follow the
nucleotides attached to a single rail, they might read something like:
TTAGCTCCTGGAATACAGATCGATA ... and this is the genetic code. Clusters of these
letters (i.e. base pairs) make up a gene. So all along the chromosome, there is
a sequence of genes, interspersed with codes for turning the gene on and off, as
well as junk DNA (that doesn't code for anything). For more information on DNA,
visit http://en.wikipedia.org/wiki/DNA. In reproduction, the process of cell division ('meiosis') is slightly
different. New human beings are created when a male sex cell (the sperm) unites
with a female sex cell (the egg). Each of these sex cells contains only half of
the chromosomes of a normal cell. In other words, instead of containing 23
chromosome pairs (i.e. 46 chromosomes), they only contain 23 single chromosomes.
When the cells unite, the 23 chromosomes in each cell pair up with each other
and the full quota of 46 chromosomes is restored. This is how we get half our
chromosomes from our mother and half from our father. Why do the sex cells only have 23 chromosomes? Well, in the original
cell, each of the chromosomes still unzips, and two replicas of the original
are still produced, but the cell, instead of splitting once, splits twice! And
instead of producing two new cells, it produces four! So first the chromosomes
are doubled (from 46 to 92), then split in two (back to 46), and then split in
two again (down to 23). And it is only by uniting with another sex cell (during
fertilization/conception) that the full quota of 46 chromosomes will be
restored. The sex chromosomes undergo the same process as all the other
chromosomes - unzipping, replication, and allocation to one of the four new
cells. However, here's an interesting thing. Women have two X chromosomes in
pair 23, men have an X and a Y. So women will produce 4 sex cells that each
contain an X chromosome, whereas men will produce 4 sex cells, two of which
will contain an X chromosome and two a Y chromosome. So the gender of the new
human being will depend on which of the male sex cells unites with the female
sex cell - if it's a Y-containing sperm it will produce a boy (XY), if it's an
X-containing sperm it will produce a girl (XX). For more information on
reproduction and meiosis, visit http://en.wikipedia.org/wiki/Meiosis. The animation below shows an extra step in the process that is not discussed above, namely 'recombination' - this is where two chromosomes 'swap' bits with each other. This is a very important step in the process but has no relevance to the discussion about Y-DNA inheritance (because the Y-chromosome does not 'swap' genes with the X-chromosome) . However, it is a very very relevant step for all the other 22 pairs of 'autosomes' and will be discussed further when we talk about the 'Family Finder' test in the next section. Check out some cool video tutorials on the basics of genetic genealogy at http://www.genetree.com/tutorials Join us today ... you could find out more than you ever imagined! Maurice
Gleeson, April 2011
Every cell in our body contains DNA, the genetic code that controls the
production of everything in our bodies (cells, tissues, organs) and makes us
who we are i.e. humans and not potatoes (in most cases)!
The genetic code - one long railway track
You'll see from the first diagram that DNA in a chromosome is arranged
in a long chain (the double helix) that is heavily coiled and twisted, so much
so that if you were to uncoil it and stretch it out in a straight line it would
be 6 feet long! And that's just one chromosome!
Reproduction - how we pass our genetic code to the next generation
Before we look at reproduction, let's look at the process called 'mitosis'. The cells in our bodies are constantly renewing themselves. They do
this by dividing in two to form two new cells (mitosis). But in order to
preserve the number of chromosomes in each cell, they first have to make new
versions of all 46 chromosomes and then divide them equally between the two new
cells. They do this by first of all 'unzipping' the DNA molecule in each
chromosome (i.e. splitting the railway track in half, right up the middle, all
the way to Aberdeen) and then rebuilding an extra half on to each half track to
make it whole again. In short, each railway track is split in two and then each
half is used as a template to reconstruct two exact replicas of the original.
One replica of each chromosome is passed on to each of the two new cells so
that they each end up with 46 chromosomes in total. For more information on
mitosis, visit http://en.wikipedia.org/wiki/Mitosis
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Last update: April 2011