Answer:
The whole progeny will be <u>not-blinded</u>. All the individuals in the F1 will be able to see.
Explanation:
Multiple genes can affect the same trait. Two blind fishes can produce not-blinded offspring because parents have mutations in two different genes. This is a case of <u>complementation</u>. When parents have a mutation in the same gene, this process is known as non-complementation, and in these cases, their progeny will exhibit the mutated trait.
We know that blindness is a trait controlled by multiple genes and inherited in a recessive manner. So we need at least two genes to have not-blinded eyes, and in the exposed example the mutation that causes blindness is in fact in two different genes.
So let´s say that genes B and E are two genes involved in eye formation and that their respective recessive alleles will express blindness. Then:
Cross: A blind fish from a true-breeding line in B gene crossed to a blind fish from a true-breeding line in E gene.
Parental) BB ee x bb EE
Gametes) Be Be Be Be
bE bE bE bE
Punnet square) Be Be Be Be
bE BbEe BbEe BbEe BbEe
bE BbEe BbEe BbEe BbEe
bE BbEe BbEe BbEe BbEe
bE BbEe BbEe BbEe BbEe
F1) 100 % BbEe, heterozygote for both genes. None of the F1 individuals are blind.
