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Published byConrad Gardner Modified over 9 years ago
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Key Terms- P1 + F1 Generations
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Boy or a Girl? If you was two have a child, what would be the likelihood of them being a boy or girl? How do you know this? Explain your answer with a genetic Diagram
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This shows that there will always be a 1:1 ratio of males to females. Note that female gametes (eggs) always contain a single X chromosome, while the male gametes (sperm) can contain a single X or a single Y chromosome. Sex is therefore determined solely by the sperm. There are techniques for separating X and Y sperm, and this is used for planned sex determination in farm animals using artificial insemination (AI). In humans it is the Y chromosome that actually determines sex: all embryos start developing as females, but if the sex-determining “SRY” gene on the Y chromosome is expressed, male hormones are produced in the embryo, causing the development of male characteristics. In the absence of male hormones, the embryo continues to develop as a female. The X chromosome is not involved in sex determination.
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Sex Linked Some characteristics are sex-linked. That means the alleles that code for them are located on a sex chromosome. The Y chromosome is smaller that the X chromosome and carries fewer genes. So most genes on the sex chromosome are only carried on the X chromosome (called X- Linked genes).
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Eye Colour In Fruit flies The first example of sex linked genes discovered was eye colour in Drosophila fruit flies. Red eyes (R) are dominant to white eyes (r) and when a red-eyed female is crossed with a white-eyed male, the offspring all have red eyes, as expected for a dominant characteristic. However, when the opposite cross was done (a white-eye male with a red-eyed male) all the male offspring had white eyes.
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Colour Blindness Another well-known example of a sex linked characteristic is colour blindness in humans. 8% of males are colour blind, but only 0.7% of females. There are three different light-receptor proteins involved in colour vision, sensitive to red, green and blue light. The genes for the green-sensitive and red-sensitive proteins are on the X chromosome, and mutations in either of these lead to colour blindness.
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The diagram below shows two crosses involving colour blindness, using the symbols X R for the dominant allele (normal rhodopsin, normal vision) and X r for the recessive allele (non-functional rhodopsin, colour blind vision).
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