Can this marriage be saved?
Meet Mrs and Mr Mouse.
They are hard-working, sober, and not given to being imaginative. Both have completely
normal teeth. Mrs Mouse gives birth to her first litter,
paints the nursery, 
picks
out nicely rhyming names, and … but what's this? Two of the nine micekins
have what can only be described as … fangs. Mr Mouse peers suspiciously at
Mrs Mouse. Mrs Mouse murmurs weakly that it must be from Mr Mouse's side
of the family. Mr Mouse is thinking more likely from the milkman. Accusations
fly. Fur flies. Baby mice wail. Another broken marriage, derailed by a lack
of basic genetic understanding.
What went wrong? How could two fangless mice end up with vampire babies?
Remember that recessive alleles don't disappear, they just, well, bide their time. They can hang out for generations, on seemingly perpetual recess, until they meet another recessive allele. The key is that Mr Mouse and Mrs Mouse both have the recessive allele vam37. Neither of them knows, because the allele is just lurking in the genotype, not showing its fangs. On the outside, nothing is different about these 2 mice. When searching for a mate, neither Mr nor Mrs Mouse could tell that anything was amiss. But when sperm meets egg, those two recessive alleles meet. And suddenly they don't have to recede anymore. Without the dominant ‘normal teeth' genes (T), vam37 (t) can show its true colors.
And
how often does that happen? Let's go back to the coin analogy. Each genotype
is like a coin with 2 sides, so when Mr and Mrs Mouse get together to make
a baby, its like flipping one coin for each of their genotypes. Mr Mouse's
coin might come up normal or vampire. Mrs Mouse's coin might come up normal
or vampire. If one or either or both are normal, so is the kid mouse. But if both
come up vampire, then that kid mouse is … vampiric.
Copyright University of Maryland, 2007
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