Created by Laura Conner, Susan Hester, Anne-Marie Hoskinson, Mary Beth Leigh, Andy Martin ,and Tom Powershis, and contributed by Yale University's Center for Scientific Teaching, this case study lesson reinforces the concept of coevolution and gives students practice with the analysis and interpretation of data.
This lesson, created by Graciela Unguez, Erika Abel, Vanessa Castleberry, Rizalia Klausmeyer, Aaron Snead, Martina Rosenberg, William S. Garver, and Marcy Osgood for the National Academies Summer Institute for Undergraduate Education in Biology uses clickers, pair and share, and other exercises to help students "understand the effect of environmental pH on the ionization status of weak acids and weak bases."... Read more about Shakespeare on Acid: To ionize or not to ionize?
Created by Paul Ogg, Melissa Krebs, Vida Melvin, Amanda Charlesworth, and Melanie Badtke, this lesson teaches how cells regulate cell division using some lecture interspersed with interactive activities including clicker questions, pair/share, and class discussion, applying concepts to Angelina Jolie's BRCA1 mutation.
Created by Moriah Beck, Masih Shokrani, Karen Koster, William Soto, David McDonald, and David Swanson for the National Academies Northstar Institute for Undergraduate Teaching in Biology, this activity spans 2-3 classes and uses lecture, clicker questions, jigsaws, and group discussions to teach the relationship between protein structure and function.... Read more about Protein Function Follows Form: Two-Lesson Activity
Created by Ned Dochtermann, Erin Gillam, Timothy Greives, Kristina Holder, Steve Travers, and Jennifer Weghorst, this lesson focuses on the evolutionary mechanism of random genetic drift. Students explore how population size affects allele frequencies by engaging in a group activity that involves generating and plotting data, interpreting graphs, and formulating hypotheses.... Read more about Understanding the mechanisms of evolution: random genetic drift
Introduction/Background: In Jacob Barandes' Physics 302, students are driven to learn how to teach and communicate physics by giving small, mini-lessons throughout the semester. They are then driven to perform a longer lesson as a final project to show what they have learned during the term.