Masked

  • Pale back, masked and masked old type, three allelic versions

    Why are the mutations in zebrafinch of pale back, masked (new type) and masked old type combined with each other so difficult to predict !?
    Quite simply because we cannot speak at the genetic level of different mutations but rather of allelic versions of a single gene. The pale back, the masked and the old type mask are due to the same gene but which has three allelic versions.
    To understand well let's make the parallel with man, the color of the eyes for example, whatever our eye color, our iris color and coded by the same gene, but this gene has many different versions (alleles) which allow us to have the color panel that we know.

    Now that we know a little more about what complicates these crosses, let's take a look at how each allele behaves in relation to each other.
    Everything is a story of dominance and co-dominance or recessivity.

    A small table to illustrate all this :

    Allele / allele Pale back Masqued Masqued OT
    Pale back x Pale back Pale back
    Masqued Pale back x Masqued
    Masqued OT Pale back Masqued x

    *OT = Old type

    In this double entry table you can see that it allele dominates the other, the bird will therefore have the phenotype of the allele which dominates, be careful, it is not because the allele is dominated that it does not not influence. See pale back / OT mask, the back is more diluted because of the masked OT allele.

    From this result we can draw the first conclusions :

    • The pale back can be masked or OT masked.
    • The masked can be a masked OT split but cannot be a pale back wearer (pb dominates masked = pb / masked). *pb = pale back
    • The masked OT cannot carry a pale back, nor a masked person because the latter two dominate him.

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  • The crossing-over

    It was in 1960 that the first zebrafinch pale Brown back appeared in Belgium.
    Let us try to understand how such a combination of colours could have been born.

    It is known that the brown and pale back factors, related to sex, are located on X chromosomes, but different and at different locations (loci): (1) and (2).
    They are therefore not normally linked (otherwise all the browns would also be pale backs: which is not the case).
    How could they get linked on the same chromosome ? (3)

    Crossing over1 1

    When you mate a brown male with a pale grey back female (or vice versa), each time you get grey males, carriers of brown and pale backs. Each male therefore has two different X chromosomes: One carries the "brown" "no light back" genes, the other carries the "no brown" and "light back" genes. Being recessive, none of these genes can be expressed since they are in a single copy; being non-alleles, neither can dominate the other; It is therefore a natural grey colour that is expressed.

    How will these genes be transmitted by the male to his offspring ? To understand it, some explanations are necessary.

    Chromosomes are very long molecules (2 millionths of a mm thick, average 5 cm long in humans) that are normally entangled with each other in the nucleus of the cell. At the time of meiosis (cell division allowing, in males, the formation of spermatozoa from the mother cells of the testes), these chromosomes split into two rigorously identical chromatids linked together by a centromere.
    Each chromatid then spirals. Only then does the chromosome become visible under the optical microscope. The chromosomes group together and join two to two homologous pairs.

    During this phase, two chromatids of the two joined chromosomes can cross, break and then join together by exchanging more or less important segments. This is the phenomenon called spanning.
    The “brown” gene could thus be found linked to the “pale back” gene on the same X chromosome. A grey male with brown back and pale back can (but only this way) produce pale grey, grey, brown back and pale brown back females. (12.5% of each).

    With this crossing over, this same male could also have:

    • Crossed with a pale back female: 12.5% of pale grey back males split brown.
    • Crossed with a brown female: 12.5% of brown males split pale backs.

    By mating one or the other of these with their "pale brown back" sister, it is possible to obtain (in 3rd generation): 25% pale brown back males and 25% pale brown back females.

    L enjambement image 2

    CHROMATID

    A : Normal
    B : Spirally contracted
    C : Schematized

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