Bloodlines
Are you good-looking? Honestly, are you? Oh, don’t fret. Beauty or lack of it is not a curse or divine providence. We are what we are because of the genes passed on to us by our parents. Sadly, some genes transmit certain conditions which challenge medical doctors and those who carry them.
Doctors or not, we try to find answers to such questions as “Are you good-looking?” especially when at a loss on how to answer them. Genetics, the science of genes, therefore, plays a role when faced with questions regarding one’s physicality (or lack thereof) and/or medical condition. Now, I cordially invite you to learn the fundamentals of inheritance a.k.a. genetics.
The basics
Chromosomes are threadlike structures found in the nucleus
(center) of the cell. Cells resemble
fried eggs (sunny side up) under the microscope, and the egg yolk is the
nucleus that contains the chromosomes.
Chromosomes contain the genetic material that codes
for specific traits or attributes that will make us what we are, i.e.,
black-haired, dark, tall, etc. Humans
have 46 or 23 pairs of chromosomes: 23 from the mother and 23 from the
father. A pair is called sex chromosomes
because they confer one’s biological sex, i.e., XX in females and XY in males. The other 22 pairs are called autosomes and
they determine traits (hair color, height, etc.) other than one’s biological
sex.
The genetic material contained in
chromosomes is called DNA.
Deoxyribonucleic acid (DNA) is commonly described as the blueprint of
life and is organized into units called genes.
Genes are units of heredity.
We, humans and animals, always inherit a pair of genes from our parents
because we, as Earth-born beings, have two biological parents. Each gene codes for a specific attribute or
trait and is designated a letter for easier identification. For example, the “a” gene stands for the
black color (if we assign “a” as black) and makes the animal appear black, “d”
for opal, etc.
Alleles are alternate forms of genes, i.e., different
versions of a given gene. Therefore,
alleles are also genes. Let us assume
that “MS Word” is a gene. It has alleles
(versions) such as 97 and 2000. While MS
Word 2000 is different from 97, both of them are word processing software and,
therefore, function the same way, i.e., they make typing much easier.
Locus is a specific site in the chromosome where the genes
that code for a trait or attribute are located.
For example, the A locus contains genes/alleles (A, a, etc.) that code
for the color black and its gradations.
The “MS Word” locus contains the alleles 2000, 97, etc.
There are three usual modes of
inheritance: recessive, dominant, and sex-linked. Other modes of inheritance are beyond the
scope of this article.
Inheritance is recessive if both parents have to contribute the same allele
(I will use “gene” and “allele” interchangeably from this point forward) for
the trait to manifest. Let us say that
the black color (trait) is recessive and is designated “a.” For the offspring to appear black, both
parents have to contribute “a” so that the child will have “aa” genes: one “a”
from the mother and another “a” from the father. Genotype
is the genetic makeup of an individual.
In this instance, the genotype is “aa.”
Phenotype is the appearance
or expression of the genotype. In this
instance, the phenotype of “aa” is black.
Recessive inheritance is
represented by lowercase letters, e.g., aa, bb, cc, etc.
Inheritance is dominant if only one allele is needed for the trait to
manifest. Let us say that the black
color is dominant and is designated “A.”
For the offspring to appear black, only one parent has to contribute
“A.” The offspring will appear black
whatever its companion allele is. “AA”
will appear black and so will “Aa.”
Dominant inheritance is represented
by uppercase letters, e.g., Aa, AA, Bb, BB, Cc, etc.
Remember that alleles/genes come in
pairs because non-magical Earth-born human beings always have two biological
parents.
Identical gene pairs are called homozygous, e.g., AA, aa. “AA” is homozygous dominant (uppercase) and
“aa” is homozygous recessive (lowercase).
Non-identical gene pairs are called
heterozygous, e.g., Aa. Heterozygous gene pairs contain both dominant
(A) and recessive (a) genes.
Dominant and recessive modes of
inheritance are processed through the autosomes.
Autosomal inheritance
Let us assume that ugliness is
inherited dominantly and is designated as “U”; “u” therefore is the opposite of
ugliness and represents non-ugliness or beauty.
If an ugly man mates with a
beautiful woman, what will their children look like?
In predicting inheritance, we
create a Punnett square that tabulates possible genotypes and their
corresponding phenotypes. A Punnett
square is a table that crosses the genes contributed by each parent, like this:
u
|
u
|
|
U
|
||
u
|
Uu = ugly male
uu =
non-ugly/beautiful female
Males are usually placed
vertically, while females are placed horizontally. Follow whatever is convenient for you.
Match u (first row, second column)
with U (first column, second row) to get Uu, and so on. The initial Punnett square drawn above now
looks like this:
u
|
u
|
|
U
|
Uu
|
Uu
|
u
|
uu
|
uu
|
The Punnett square above shows that
two out of four children will have the genotype Uu, while two will have
uu. This means that half of the children
will be ugly (Uu), while the other half will be non-ugly (uu).
Please note that the “u” in Uu
signifies that the ugly child carries a gene for beauty. “Ugly split for beautiful” is the genetic
jargon for this.
What if the mating is between ugly
“UU” and non-ugly “uu”?
u
|
u
|
|
U
|
||
U
|
u
|
u
|
|
U
|
Uu
|
Uu
|
U
|
Uu
|
Uu
|
The Punnett square above shows only
one genotype: Uu. This means that all
the children will be ugly. Again, the
“u” in Uu signifies beauty. Therefore,
they also carry genes for beauty but do not manifest the desirable phenotype.
What if ugliness is inherited
recessively?
Let us designate it as “u.” “UU” and “Uu” represent non-ugliness (or
beauty) and are dominant as their capitalization indicates. “uu” represents ugliness and is recessive as
indicated by lowercase letters.
Let us mate a beautiful person (Uu)
to an ugly one (uu).
U
|
u
|
|
u
|
||
u
|
U
|
u
|
|
u
|
Uu
|
uu
|
u
|
Uu
|
uu
|
The table above shows that half the
children will be non-ugly (Uu) and half will be ugly (uu).
What if the non-ugly person has two
doses of non-ugly genes, i.e., has the genotype UU and is mated to an ugly
person? The table should look like this:
U
|
U
|
|
u
|
||
u
|
U
|
U
|
|
u
|
Uu
|
Uu
|
u
|
Uu
|
Uu
|
The table above shows that all the
children will be non-ugly (Uu) no matter how ugly (uu) one of the parents
is. Please note that the “u” in Uu
signifies ugliness. This means that
these beautiful children carry genes for ugliness (beautiful split for ugly).
Please note that the above are only
examples to illustrate autosomal modes of inheritance. Beauty or ugliness is multifactorial and is
not limited by genes. Dermatologists and
plastic surgeons not only save lives.
They also do wonders on one’s physical assets, augmenting or adding
beauty not accorded by genes.
Sex-linked inheritance
In humans, female sex chromosomes
are represented by XX, while male chromosomes are XY.
Sex-linked inheritance means the
trait is transmitted via the sex chromosomes.
All (but one) human sex-linked conditions are transmitted via the X
chromosome. That is why sex-linked is
called X-linked inheritance in medical literature. The most well-known X-linked condition is
hemophilia A. Hemophilia A is a
condition where one lacks clotting factor VIII, resulting in easy bruising and
bleeding.
Hemophilia A is carried only in the
X chromosome. The Y chromosome does not
carry the trait. There is another catch
in hemophilia A and X-linked inheritance in general in humans: males only need
one X chromosome to manifest the condition (to become symptomatic). There is no carrier condition in males. Females are carriers (have no symptoms) if
only one X chromosome is affected. They
only become symptomatic if both their X chromosomes carry the trait. One rationale for this is that the X chromosome
is so large that it can accommodate a whole bunch of genes. The Y chromosome, on the other hand, is so
small that it can only accommodate maleness.
Let us mate a hemophilic man to a
non-carrier, non-hemophilic woman.
Xh
|
Y
|
|
X
|
||
X
|
XX = woman
XhY = man with
hemophilia A
Attach any letter of your choice to
X to indicate hemophilia. I just used
“h” for simplicity. Please remember that
female humans have XX chromosomes, and male humans have XY chromosomes.
Xh
|
Y
|
|
X
|
XXh
|
XY
|
X
|
XXh
|
XY
|
The Punnett square above shows that
all the daughters will be carriers (no symptoms because only one X is
affected), while all the sons (XY) will be hemophilia-free.
What if the woman is a carrier and
the man is hemophilia-free? This seems
to be the usual case because either one has no symptoms.
XY = man with no
hemophilia
XXh = asymptomatic
woman who carries hemophilia A
X
|
Y
|
|
Xh
|
||
X
|
X
|
Y
|
|
Xh
|
XXh
|
XhY
|
X
|
XX
|
XY
|
From the Punnett square above, half
the daughters (XXh) will be carriers while half (XX) will be free of hemophilia
A, and half the sons (XhY) will have symptoms of hemophilia A and half (XY)
will be hemophilia-free.
What if a carrier woman mates with
a symptomatic man?
XhY = man with
hemophilia A
XXh = asymptomatic
woman who carries hemophilia A
Xh
|
Y
|
|
Xh
|
||
X
|
Xh
|
Y
|
|
Xh
|
XhXh
|
XhY
|
X
|
XXh
|
XY
|
The table shows that half the
daughters (XhXh) will be symptomatic while half (XXh) will be carriers, and
half the sons (XhY) will be symptomatic while half (XY) will be
hemophilia-free.
Lastly, what if a symptomatic woman
mates with a hemophilia-free man?
XhXh = symptomatic
woman
XY = man with no
hemophilia
X
|
Y
|
|
Xh
|
||
Xh
|
X
|
Y
|
|
Xh
|
XXh
|
XhY
|
Xh
|
XXh
|
XhY
|
The table above shows that all the
daughters will become carriers (XXh), while all the sons (XhY) will have
hemophilia A.
The gay gene
Which would you prefer?
Looks transmitted via autosomal modes (recessive and dominant) or the X
chromosome (X-linked)? Alas, some things
are not given to us by choice, like beauty, like homosexuality. This brings us to the question: Is there a
gay gene? How is it transmitted?
Some claim the existence of a gay gene, but this remains
to be proven beyond the shadow of a doubt.
Would it be
better for us if a gay gene were found?
Such a gene would finally put to rest the argument that homosexuality is
“nurtured.” This, however, would pose
another problem: homophobes trying to excise the gay gene. Scientific research would then focus on ways
to counter our precious DNA. Can you
imagine the X-Men taking their last stand?
Genes are snippets
of what makes us tick. We have no choice
on what attribute they accord us.
However, we have a choice whether or not we let their prescription rule
our lives. If you have a gay gene in you,
will you embrace or shun it?
Reminder
While genetics can give us an idea how many of our
children will inherit our traits, it does not always reflect the truth.
In some families, children are of one sex only, either
all male or all female, when there should have been females and males in equal
distribution.
Real-life scenarios shy away from genetics.
Letter symbols used in genetics vary from breed to breed
and species to species. Chromosome
number also differs between species.
Humans have 46 chromosomes. Cats
have 38. The principles of genetics are
the same.
===
The above article first
appeared in L magazine (now defunct) in 2006 in a slightly different
form. L was a beefcake gay magazine in
the Philippines. The prose and poetry
were written by the country’s finest like J. Neil Garcia, Danton Remoto, Roel
Manipon, et al. I was the health
columnist.
