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Published byLee Copeland Modified over 8 years ago
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Inheritance controlled by dominant and recessive paired alleles is often referred to as simple Mendelian genetics. Many inherited patterns are more complex that those studied by Mendel.
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Read About Complex Patterns of Heredity on pages 177, 178 & 179 of your textbook Use this information to create a “Main Idea” chart like the one shown above in your notebook
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In Mendel’s pea-plant crosses, one allele was completely dominant over another.
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In some organisms, however, an individual displays a trait that is intermediate between the two parents, a condition known as Incomplete Dominance
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However, when you cross 2 of the F 1 ’s, you end up with a 1:2:1 phenotypic ratio;
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In the monster world, fang length is an example of incomplete dominance. For example, if a homozygous long fanged monster (L L) is crossed with a homozygous recessive short fanged monster (L I L I ), all of the F 1 offspring have medium length fangs. In your notebook create a Punnett square illustrating this cross
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Now, in your notebook create a Punnett square that shows the cross of 2 of the F 1 offspring
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How many long Fanged monsters will appear in the F2 generation? Short fanged monsters? How many F2 monsters will have medium length fangs?
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For some traits, two dominant alleles are expressed at the same time. In this case, both forms of the trait are displayed, a phenomenon called Codominance.
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In monsters, purple people-eaters and green people-eaters are homozygous for the P and G alleles. If you cross a purple people-eater with a green people-eater, you get a people-eater with spots. In your notebook create a Punnett square to show the cross of a purple people eater with a green people-eater.
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Now, in your notebook create a Punnett square that shows the cross of 2 of the F 1 offspring from the previous problem
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The situation of human ABO blood groups is an example of codominance. Different combinations of the three alleles I A, I B, and i result in four different blood phenotypes, A, AB, B, and O. For example, a person with the alleles I A and i would have blood type A.
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A man with AB blood marries a woman who has type O blood. What are the possible blood types of their children?
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A man who has type A blood, marries a woman who has type B blood. Their first child has type O blood. How is this possible? If they were to have more children, what possible blood types might these children have?
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