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BASIC PRINCIPLES OF GENETIC INHERITANCE STATE STANDARDS See AHA Biology Text Ch 10,11,12 (1) Describe that genes are carried on chromosomes. (2) Describe that typical animal cells contain two copies of each chromosome, one from each biological parent, with genetic information that regulates body structure and function. (3) Describe the process of mitosis (e.g., the genetic information is copied and each of two new cells receives exact copies of the original chromosomes) and/or the product of mitosis (e.g., two cells each with the same number of chromosomes as the original cell). (4) Describe the process of meiosis (e.g., each egg (ova) or sperm cell receives only one representative chromosome from each pair of chromosomes found in the original cell) and/or product of meiosis (e.g., egg and sperm cells with only one set of chromosomes). (5) Describe that the processes of recombination during meiosis (e.g., segregation, independent assortment) result in a unique combination of genetic information in the egg (ova) or sperm cell. (6) Describe the relationship between the unique combination of genetic information in an egg (ova) or sperm cell and the differing characteristics in offspring from a single set of parents. (7) Describe the process of fertilization as restoring the original chromosome number (e.g., an egg and sperm, each with half the number of chromosomes of the original cell, combine to restore the number of chromosomes from the original cell). (8) Describe that the process of fertilization allows for variation among offspring from a single set of parents. (9) Describe possible allele combinations in an egg (ova) or sperm cell given a combination of two traits and a parent’s genotype for the two traits. (10) Describe the possible combinations of offspring in a simple Mendelian genetic cross for two traits (e.g., given a Punnett square for two traits, fill in one missing cell). (11) Describe the possible combinations of offspring in a genetic cross involving codominance or incomplete dominance for a single trait. (12) Predict the effect on a population of a given change in inherited variability of offspring, potential for population growth, resources, and/or environmental pressure (e.g., decreased variation in alleles). (13) Describe inherited traits (e.g., eye color, hair texture, attached earlobes, tongue rolling) and cell functions as primarily determined by the proteins expressed by genes. (14) Describe that cell functions (e.g., cell growth and division, response to the environment) can be regulated by changing the activity of proteins and/or by changing whether and how often particular genes are expressed. BASIC PRINCIPLES OF GENETIC INHERITANCE 1. What are carried on chromosomes? 2. How many copies of each chromosome does the typical animal cell contain? 3. What sources provides the copies of chromosomes? 4. What regulates body structure and function? 5. The process of _______ describes that the genetic information gets copied, and then the cell divides once. 6. What is the product of mitosis? 7. What is the process of meiosis? 8. The product of _________________________________ creates up to four sex cells with only one set of chromosomes from the original cell. 9. How are unique combinations of genetic information created? 10. Unique combinations of genetic information in offspring is due to ___. 11. The original number of chromosomes in sex cells is restored by ___. 12. What must combine to restore the original (diploid) number of chromosomes? 13. Variation among offspring from parents is due to _____. 14. What are the possible genotype combinations for the sex cells of a parent that is heterozygous for two traits, such as Height (tall is dominant to short) and Freckles (having freckles is dominant to not having freckles)? 15. Complete the following Punnett square for a trait that involves complete dominance for plant height. TALL (T) Tt Tt short (t) tt short (t) short (t) 16. How many possible phenotypic combinations of offspring would result in a genetic cross involving a co-dominant trait? 17. How many possible phenotypic combinations of offspring would result in a genetic cross involving an incomplete dominant trait? 18. The gene for tasting bitterness is an example of incomplete dominance. Two people who are heterozygote tasters for bitterness mate. What are the possible phenotype and genotype ratios of offspring in this genetic cross? 19. Blood type is an example of co-dominace. A heterozygote for type A (IAIi) mates with a heterozygote for type B (IBIi). What are the possible phenotype ratios of offspring in this genetic cross? 20. What is the the frequency of alleles in a population is dependent on? 21. The four consequences of biological evolution may result in the change of the variation of ____ frequencies in a population. 22. What determines whether a trait is good, bad, or neutral? 23. What are the 4 conditions that allow biological evolution to occur?