AboutDana Krempels, Ph.D. Expertise I can answer biology-related questions in the areas of evolution, zoology, botany, genetics, and ecology. But I don't answer homework questions or provide ideas for your science fair projects. So students please do your learning the right way by reading your text assignments and studying!
Experience At the University of Miami, I teach Evolution and Biodiversity, Botany, Zoology, Genetics, Ecology, and a variety of seminars (e.g., the Biology and Evolution of Human Gender Roles).
Education/Credentials I have a B.S. in Biology and an A.B. in English from the University of Southern California (1980).
I earned my Ph.D. in Biology in the area of evolutionary biology/visual physiology from the University of Miami in 1989.
Past/Present Clients I am currently an "expert" in both the "Rabbits" and "Wild Animals" categories.
Question I had dark hair as a baby and it eventually turned to blonde. My mom has blonde hair. And my dad had blonde hair when he was a baby which eventually turned dark.
My husband has blonde hair. His dad has dark hair and his mom has blonde hair.
What color hair will my baby have?
Thank you, please answer ASAP!
Answer Dear Amanda,
Human hair, eye, and skin color are very complex and difficult to predict, because each of these traits is controlled by more than one gene. What determines the physical appearance (expression) of each trait is the dominant versions of the various genes that affect the traits in question, because these are the ones most likely to be expressed by the child--though not always. I'll try to explain.
Every human carries two copies of every gene. Scientists now estimate that a human has about 30,000 genes in the genome, and every human has two copies of that genome: one from mom, and one from dad. The versions of each gene (called *alleles) that a child gets from each parent may be the same in a single person, or they may be different. For example, if there's a gene we'll call X, and the father's alleles are XX and the mother's are xx, then the child will get one from each parent, and have the genotype Xx for that particular green.
How does this affect the physical appearance of a trait? Here's a brief example. Let's say that there's a human gene that codes for the shape of the forehead hairline. There are two versions of the gene. One, which we'll call "W" codes for a small "V" of hair to point down onto the forehead (Widow's Peak). The other version, which we'll call "w", codes for a straight hairline. In this case, the W allele of the gene masks the expression of the w allele. The W is *dominant*, and the w is *recessive*. So if every person has two copies of this gene, then the possible combinations are:
WW - Widow's peak
Ww - Widow's peak
ww - straight
Human hair, skin and eye color are not that simple. Instead of being controlled by only one gene, these traits are each controlled by *several* different genes, each with two or more versions (alleles).
This means that the different versions can combine in unpredictable ways to produce a wide range of phenotypes (physical appearance).
A trait that is controlled by several genes is called a POLYGENIC TRAIT. A polygenic trait is the expression of a single phenotypic trait that is affected by the action of more than one gene.
There are too many examples to list, since most traits are, at least to some degree, polygenic. But human hair color, eye color, and skin color are among them.
One cute, easy-to-see example of a polygenic trait is the inheritance of fruit color in bell peppers, and it is a bit analogous to the human traits just named. There are at least three genes involved here, which we'll abbreviate as:
* Y - timing of chlorophyll (green pigment) elimination
(Y - early; y - normal)
* R - color of carotenoid pigments
(R - red; r - yellow)
* C - regulation of carotenoid deposition
(C - normal; c1, c2 - two alleles for lower concentration)
(The capital letters indicate the dominant alleles; the lower case indicate various versions of recessive alleles.)
This leads to a few possible genotypes producing interesting phenotypes:
o Y- rr c1c2 - pale yellow
o Y- rr Cc2 - darker yellow
o yy rr CC - green
o Y- R- CC - red
o yy Rr CC - purple
o Y- Rr Cc2 - pale yellow
See? It is a little bit like human color, but in this case there are only *three* genes involved. Imagine how complicated things get when there are more than three genes, as there are in human hair, eye, and skin color!
The more genes involved in the expression/appearance of a trait, the more possible variations there are, and the more impossible it becomes to guess what a baby will look like, especially if you don't know the exact genetics of the parents. (Knowing the grandparents' phenotypes can help, but usually not very much.)
Hair color is a result of interaction between several genes that not only control the *color* of the hair pigmentation (brown eumelanin pigment or red phaeomelanin pigment), but also *how much* pigment is deposited in the hair shaft. The darker the hair, the greater the melanin deposition, but one can't really predict how dark a baby's hair will be, since s/he may inherit a wide variety of "darkness level" genes from both parents, and they can recombine in various ways.
Similarly, light colored eyes (blue, green, hazel, grey, etc.) are usually considered recessive to dark-colored eyes. But this trait, too, is controlled by at least five different genes.
Skin color is probably the most complex of all the traits. Freckles are apparently controlled by only one gene, and freckles are considered dominant to non-freckles. But various factors during development can affect this, and exposure to sunlight can also determine the level of freckling that is expressed. Genetics of overall skin tone is much more complex, and nearly impossible to predict. For example, two people of African American descent (which means they usually will have some Caucasoid skin pigmentation genes that are recessive to the darker pigmentation genes) and medium-brown skin can produce children with skin tones ranging from very pale to extremely dark, depending on the combination of skin color genes each child inherits.
I know this doesn't give you the answer you were seeking, but I hope it at least gives you an idea of how truly complicated (if not impossible) it is to predict something like this.
Whatever color the baby, I hope s/he will be happy and healthy! Good luck!
