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Download Information Flow in Eukaryotes (PowerPoint) Madison 2008
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Transcript
Team 6: Gene Expression II Teaching Unit - Information Flow in Eukaryotes: Differential Gene Expression Rich Walker Dave Hawthorne Reid Compton Mary Lipscomb Jill Sible Edgar Moctezuma Lil Tong Information Flow in Eukaryotes: Differential Gene Expression 1. Learning Goal Understand the conversion of genotype to phenotype. Learning Outcome(s) Diagram the flow of genetic information from DNA to protein in eukaryotic cells. Define new terms in information flow. Distinguish between /among frequently confused terms (e.g. transcription and translation). a. Understand that information flow b. is regulated at multiple levels. Appreciate consequences of misregulation. c. Understand that not all mutations are bad (a common misconception) 2. Apply an experimental approach 3. to information flow. Appreciate universality of information flow in all eukaryotes. Identify points of regulation along the information flow pathway. Provide positive and negative consequences of misregulation (mutation Š internal vs. external) Provide positive and negative consequences of misregulation (mutation Š internal vs. external) Outline experiments that would identify the regulatory points. Provide examples of information flow in fungi, plants, animals. Information Flow in Eukaryotes: Differential Gene Expression 1. Learning Goal Understand the conversion of genotype to phenotype. Learning Outcome(s) Diagram the flow of genetic information from DNA to protein in eukaryotic cells. Define new terms in information flow. Distinguish between /among frequently confused terms (e.g. transcription and translation). a. Understand that information flow b. is regulated at multiple levels. Appreciate consequences of misregulation. Identify points of regulation along the information flow pathway. Provide positive and negative consequences of misregulation (mutation Š internal vs. external) c. Understand that not all mutations Provide positive and negative consequences of misregulation (mutation Š internal vs. external) 2. Apply an experimental approach Outline experiments that would identify the regulatory points. Provide examples of information flow in fungi, plants, animals. are bad (a common misconception) 3. to information flow. Appreciate universality of information flow in all eukaryotes. Information Flow in Eukaryotes: Differential Gene Expression Context: •Freshman Biology course No prerequisites Some majors, some non-majors •Material covered before this unit: Concept of a gene Prokaryotic gene expression Appreciate and are effective in group work •Reading assignment before class on eukaryotic gene expression Tidbit 1: To make sure everyone understands the steps of genetic information flow in eukaryotes, order the following events. Mature protein Nuclear export of RNA Polypeptide elongation Recognition of start codon Positioning and activation of RNA polymerase Termination of transcription Ribosome encounters stop codon RNA processing Protein folding RNA elongation Tidbit 2a: Anthocyanin and grape color • Anthocyanins are flavonoid pigments in plant cells that make them look red, purple or blue. • The final step in the synthesis of anthocyanin is catalyzed by the enzyme UFGT. • Green grapes lack anthocyanins due to a mutation in the MYB transcription factor. Red Green Clicker activity Based on the strip sequence, which step in the UFGT expression pathway would be affected by mutation in the MYB transcription factor? A. Termination of transcription B. Recognition of the start codon C. Positioning and activation of RNA polymerase D. Protein folding E. None of the above Red Green Tidbit 2b: Musclehead Analysis of the human genome indicates a single a-tropomyosin gene. However, tropomyosin protein isolated from muscle and brain are structurally different. Clicker activity Regulation at which point in the tropomyosin gene expression pathway could account for two structurally different protein products encoded by the same gene? A. B. C. D. Termination of transcription RNA processing Nuclear export of RNA Protein folding Mini lecture on points of regulation and experiments to study them. Take home assignment: Design an experimental approach to determine which point of control along the gene expression pathway accounts for the different forms of tropomyosin in muscle and brain. Next class:The a-tropomyosin gene is alternatively spliced. Diversity considerations: By allowing a range of correct answers for tidbit 1, we accommodated both linear and non-linear approaches to solving the problem. Tidbit 1 also engaged kinesthetic and visual learners. We used grapes rather than wine (alcohol) as an example. We used an example from the plant/agricultural field because not all students are pre-med. We were sensitive to potential color-blindness by pointing out different grape colors. Thank You! From the GrapeStormers
