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Transcript
Name _______________________________________________ Colorblindness Lab.2015 Date __________ Activity: How is Colorblindness Transmitted? Goal: To model how a sex-linked gene is transmitted. Background Information: Is there a special pattern of inheritance for genes located on the X chromosome or the Y chromosome? The answer is yes. Because these chromosomes determine sex, genes located on them are said to be sex-linked genes. Many sex-linked genes are found on the X chromosome. More than 100 sex-linked genetic disorders have now been mapped to the X chromosome. These include colorblindness and hemophilia. The Y chromosome is much smaller than the X chromosome and appears to contain only a few genes. Three human genes associated with color vision are located on the X chromosome. In males, a defective version of any one of these genes produces colorblindness, an inability to distinguish certain colors. The most common form of this disorder, red-green colorblindness, is found in about 1 in 10 males in the United States. Among females, however, colorblindness is rare – only about 1 in 100 has colorblindness. Why the difference? Males have just one X chromosome. Thus, all X-linked alleles are expressed in males, even if they are recessive. In order for a recessive allele, such as the one for colorblindness, to be expressed in females, there must be two copies of the allele, one on each of the two X chromosomes. This means that the recessive phenotype for a sex-linked genetic disorder tends to be much more common among males than among females. Take the colorblind test! Go to: http://www.copresco.com/links/colblind.htm Materials: 2 paper bags, 3 white beans, black or green marker, and one red bean Procedure: 1. What I Know: Write two sentences describing what you already know about sex-linked traits. 1 2. Label one bag “female” and the other bag “male.” 3. The white beans represent X chromosomes. Use the marker to make a dot on 1 white bean to represent the X-linked allele for colorblindness. Place this bean, plus 1 unmarked white bean, into the bag labeled “female.” 4. Place a white bean and a red bean into the bag labeled “male.” The red bean represents a Y chromosome. 5. Close your eyes and pick one bean from each bag to represent how each parent contributes a sex chromosome to a fertilized egg. 6. Fill in the attached data table. Record the color of each bean and the sex of an individual who would carry this pair of sex chromosomes. Also record how many Xlinked alleles for colorblindness this individual has. Put the beans back in the bags they came from. 7. Determine whether the individual would have colorblindness. 8. Continue choosing beads from the bags for a total of 10 trials. 9. What I Observed: This section should include the handout provided. A. Expected Results: Create a Punnett square showing your expected results for your cross. The cross represented in the activity is XC XC x XCY. XC is the allele for colorblindness. Punnett square: XC XC XC Y % of colorblind males _______ % of colorblind females _______ 2 B. Observed Results: Complete the following table to obtain your observed results. Trials Example Alleles White/Red X cY Sex of Individual Male 1 2 3 4 5 6 7 8 9 10 3 Number of Xlinked Alleles for Colorblindness 1 Colorblind? Yes/No yes C. Summary of Observed Results: Number of Colorblind Females Total Number of Females Percentage of Colorblind Females number of colorblind females total number of females Number of Colorblind Males Total Number of Males Percentage of Colorblind Males number of colorblind males total number of males 10. Questions: Answer the following questions in complete statements. a. Why did you select one bean from each bag? b. From your observed results, what percentage of females were colorblind? c. From your observed results, what percentage of males were colorblind? 4 d. How do your expected and observed results compare? e. Is it possible for a son to inherit red-green color blindness from his father? Explain your answer. f. How would the results be different if both parents carried a recessive allele for colorblindness? 11. What I Wonder: Pose a question that arises from this activity or topic. 12. What I Learned: Complete the following writing prompts. . Goal: State the goal of this lesson. Question: Restate your goal in a question format. 5 Claim: What did you find out after completing this activity that is related to the goal of the lesson? In other words, describe how this activity answers the question you stated above. Evidence: Provide proof for your claim from the data you collected in this lab. Include your observed and expected results. 6 7
