* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Teacher`s Guide - Discovery Education
Nutriepigenomics wikipedia , lookup
Cre-Lox recombination wikipedia , lookup
Genealogical DNA test wikipedia , lookup
Quantitative trait locus wikipedia , lookup
Therapeutic gene modulation wikipedia , lookup
Metagenomics wikipedia , lookup
Vectors in gene therapy wikipedia , lookup
Mitochondrial DNA wikipedia , lookup
Biology and consumer behaviour wikipedia , lookup
Extrachromosomal DNA wikipedia , lookup
Transposable element wikipedia , lookup
Oncogenomics wikipedia , lookup
No-SCAR (Scarless Cas9 Assisted Recombineering) Genome Editing wikipedia , lookup
Human–animal hybrid wikipedia , lookup
Pathogenomics wikipedia , lookup
Helitron (biology) wikipedia , lookup
Genetic engineering wikipedia , lookup
Microevolution wikipedia , lookup
Human genetic variation wikipedia , lookup
Whole genome sequencing wikipedia , lookup
Artificial gene synthesis wikipedia , lookup
Site-specific recombinase technology wikipedia , lookup
Public health genomics wikipedia , lookup
Genomic library wikipedia , lookup
Non-coding DNA wikipedia , lookup
Designer baby wikipedia , lookup
Minimal genome wikipedia , lookup
Human genome wikipedia , lookup
Genome (book) wikipedia , lookup
Genome editing wikipedia , lookup
History of genetic engineering wikipedia , lookup
Human Genome: Teacher’s Guide Grade Level: 9-12 Curriculum Focus: Human Body Lesson Duration: Two class periods Program Description It’s a project of enormous magnitude: mapping the human genome. Learn how what began with the discovery of DNA has now led to the understanding of which human genes are responsible for specific human traits, including growth, development, health, and even personality. Onscreen Questions Part I—Before watching the video • What do you know about DNA and its role in building unique genetic structures? As you watch the program, consider the benefits of knowing the sequence of genes that make up human DNA. • Consider how an understanding of the human genetic code may influence the future of our species? Part I—After watching the video • In 1990, the Human Genome Project began identifying all the genes that make up human DNA. What are some of the challenges of deciphering the human genome? • Debate the moral and social implications of this project. Part II—Before watching the video • Scientists have proved that some types of cancer are related to an individual’s genetic code. As you watch the program, look for technologies that allow us to alter our genes. • How might these methods help eliminate some diseases or increase human lifespan? Part II—After watching the video • The protein P-53 plays a critical role in preventing cancer. Discuss what people with defective P-53 genes or other inheritable genetic diseases should know before having children. • What are the genetic risks to their children? Human Genome: Teacher’s Guide 2 Lesson Plan Student Objectives • Learn about the goals of the Human Genome Project (HGP). • Discuss the scientific and ethical implications of the project. Materials • Human Genome video and VCR • Internet access • News media articles and other current resources about the Human Genome Project • Posterboard Procedures 1. Begin the lesson by asking students what they know about genes. Explain that genes are made up of double strands of deoxyribonucleic acid, or DNA, which provides the genetic instructions for everything a cell does. In particular, the sequence of the bases, or subunits of DNA, play a part in determining whether a person will get sick and how that person will respond to medication. To understand how the body works, scientists must understand the human genome, or the complete set of genetic instructions. They are mapping these instructions in the Human Genome Project, or HGP. 2. Share the information below about the HGP with the students. • The primary goal was to locate the estimated 30,000 or more human genes on all the chromosomes and determine their sequence along each strand of DNA. • By June 2000, scientists had completed a rough draft of the human genome. The final draft was finished in April 2003, two years ahead of schedule. • Scientists use this information to understand how genes function, how genetic material varies among people, and how some genetic variations predispose people to disease. 3. Tell students that the HGP has scientific, ethical, and medical ramifications. During this lesson, students will work in small groups to research the project. Before students divide into groups, provide them with an overview of the HGP. The following Web sites will be useful: • http://www.ornl.gov/sci/techresources/Human_Genome/home.shtml • http://www.genome.gov/ 4. Divide the class into three groups to research different facets of the HGP. Have them use the Web sites listed in step 3 to begin their research in the following areas: • Group 1: Scientific findings. The number of genes discovered and their sequence, and definitions of key scientific terms such as chromosome, DNA, gene, and protein • Group 2: Potential applications. The tools used to detect genes carrying disease and how this information can be applied to individual treatment plans Published by Discovery Education. © 2005. All rights reserved. Human Genome: Teacher’s Guide • 3 Group 3: Ethical implications. Issues involved with screening adults and fetuses for genetic diseases, using new technology to treat diseases, and others associated with mapping the human genome 5. Give students time in class to work on their research. Students can record their findings on the computer or in notebooks. Tell students that they can use illustrations to depict some of their findings, such as the structure of DNA or the shape of a chromosome. 6. Have each group present its findings. Then have them create displays. Scientific findings could include a labeled diagram showing the relationships among DNA, genes, chromosomes, and proteins. Potential applications could be a case study showing how scientists identified the genes responsible for an illness and how they developed treatment. Ethical implications could present a list of issues that have emerged from new knowledge. 7. Place the displays on a large piece of posterboard. Use them to discuss the complexity of the project. 8. Conclude by discussing students’ overall reaction to the Human Genome Project. Do the advantages outweigh the challenges? Does this information have the potential to save lives: Assessment Use the following three-point rubric to evaluate students’ work during this lesson. • 3 points: Students exhibited strong research skills; showed above-average ability to compile findings and present them to the class; demonstrated the ability to share keen insights and ideas during class discussions. • 2 points: Students exhibited on-grade research skills; showed average ability to compile findings and present them to the class; demonstrated on-grade ability to share insights and ideas during class discussions. • 1 point: Students exhibited slightly below-average research skills; had some problems in compiling findings and presenting them to the class; demonstrated difficulty sharing insights and ideas during class discussions. Vocabulary chromosome Definition: A physically separate molecule made up of DNA Context: DNA in the human genome is arranged into 24 chromosomes. DNA (deoxyribonucleic acid) Definition: The chemical inside a cell’s nucleus that carries the instructions for everything the cell does; made up of four chemical sub-units referred to as bases Context: The human genome contains 600,000 pairs of DNA. Published by Discovery Education. © 2005. All rights reserved. Human Genome: Teacher’s Guide 4 gene Definition: The functional and physical unit of heredity passed from parent to offspring Context: Scientists estimate that human beings each have between 30,000 and 35,000 genes. human genome Definition: The complete set of DNA in each human being Context: Scientists completed a rough draft of a map of the human genome in June 2000. Academic Standards National Academy of Sciences The National Science Education Standards provide guidelines for teaching science as well as a coherent vision of what it means to be scientifically literate for students in grades K-12. To view the standards, visit http://books.nap.edu. This lesson plan addresses the following science standards: • Life Science: Molecular basis of heredity • Science as Inquiry: Understandings about scientific inquiry Mid-continent Research for Education and Learning (McREL) McREL’s Content Knowledge: A Compendium of Standards and Benchmarks for K-12 Education addresses 14 content areas. To view the standards and benchmarks, visit http://www.mcrel.org/. This lesson plan addresses the following national standards: • Science—Life Sciences: Understands the principles of heredity and related concepts • Language Arts—Viewing: Uses viewing skills and strategies to understand and interpret visual media; Reading: Uses reading skills and strategies to understand and interpret a variety of informational texts Support Materials Develop custom worksheets, educational puzzles, online quizzes, and more with the free teaching tools offered on the Discoveryschool.com Web site. Create and print support materials, or save them to a Custom Classroom account for future use. To learn more, visit • http://school.discovery.com/teachingtools/teachingtools.html Published by Discovery Education. © 2005. All rights reserved.