CRISPR (also known as CRISPR-Cas9) is a powerful biotechnology tool that gives scientists unprecedented access to the genetic makeup of all living organisms, including humans. It originally evolved as an adaptive immune system in bacteria to defend against viruses. When artificially harnessed in the laboratory it allows scientists to accurately and precisely edit genes, almost as if using a word processor. In mice, CRISPR has already been used to treat diabetes, muscular dystrophy, cancer, and blindness. CRISPR has made cultured human cells immune to HIV, and a variety of CRISPR experiments involving human embryos are well under way. But CRISPR is not limited to biomedical applications. It is also revolutionizing the food industry and many areas of biological research. This article provides science educators a broad and up-to-date overview of CRISPR, including its discovery, application, and bioethical challenges. It is imperative that science educators help prepare students, both majors and nonmajors, for this compelling new era of biology.

CRISPR (also known as CRISPR-Cas9) is a powerful biotechnology tool that gives scientists unprecedented access to the genetic makeup of all living organisms, including humans. It originally evolved as an adaptive immune system in bacteria to defend against viruses. When artificially harnessed in the laboratory it allows scientists to accurately and precisely edit genes almost as if using a word processor. In mice, CRISPR has already been used to treat diabetes, muscular dystrophy, cancer, and blindness. CRISPR has made cultured human cells immune to HIV, and a variety of CRISPR experiments involving human embryos are well under way. But CRISPR is not limited to biomedical applications. It is also revolutionizing the food industry and many areas of biological research. It is imperative that science educators help prepare students for this compelling new era of biology. This article presents wet and dry lab simulations to help introduce high school and undergraduate students to CRISPR-based gene editing technology.

The central dogma of molecular biology is key to understanding the relationship between genotype and phenotype, although it remains a challenging concept to teach and learn. We describe an activity sequence that engages high school students directly in modeling the major processes of protein synthesis using the major components of translation. Students use a simple system of codes to generate paper chains, allowing them to learn why codons are three nucleotides in length, the purpose of start and stop codons, the importance of the promoter region, and how to use the genetic code. Furthermore, students actively derive solutions to the problems that cells face during translation, make connections between genotype and phenotype, and begin to recognize the results of mutations. This introductory activity can be used as an interactive means to support students as they learn the details of translation and molecular genetics.

A key question in teaching a General Genetics course is whether to present the major concepts of Mendelian genetics first, or to start with the essential ideas of molecular genetics. A comparison of two sequential courses at Creighton University with similar groups of students indicated that there were no statistically significant differences in exam scores or final grades with the two approaches. It thus may be better to focus on the questions of how best to present the material in each area to contemporary students and how better to prepare them to take exams that involve different types of questions requiring analytical, numerical, and writing skills. These issues are discussed in the context of the modern biology curriculum.

One of the eight Next Generation Science Standards (NGSS) scientific practices is using mathematics and computational thinking (CT). CT is not merely a data analysis tool, but also a problem-solving tool. By utilizing computing concepts, people can sequentially and logically solve complex science and engineering problems. In this article, we share a successful lesson using protein synthesis to teach CT. This lesson focuses primarily on modeling and simulation practices with an extension activity focusing on the computational problem-solving practices of CT. We identify and define five CT concepts within the aforementioned practices that form the foundation of CT: algorithm, abstraction, iteration, branching, and variable. In this lesson, we utilize a game to familiarize students with CT basics, and then use their new CT foundation to design, construct, and evaluate algorithms within the context of protein synthesis. As an optional extension to the lesson, students enter the problem-solving environment to create a program that translates mRNA triplet codons to an amino acid chain. We argue that biology classrooms are ideal contexts for CT learning because biological processes function as a system, and understanding how the system functions requires algorithmic thinking and problem-solving skills.

This structured set of lab activities allows students to explore the evolution of pelvic spine reduction in stickleback fish. The exercise draws upon the field of evolutionary and developmental biology (evo-devo) and information presented in the HHMI Holiday Lecture entitled “Fossils, Genes, and Embryos.” Students analyze fossil data from a rich stickleback deposit in Nevada, documenting the evolution of pelvic spine reduction in a preserved population, and then use Hardy-Weinberg analysis to explore the role of natural selection in this type of evolutionary event. Finally, students use molecular genetics and polymerase chain reaction to uncover the evolutionary role of gene switches in pelvic spine reduction. Collectively, the lab activities explore a specific evolutionary event from the combined perspectives of fossil evidence, natural selection, and molecular genetics. The lab also serves as a good introduction to the concepts of gene switches and evo-devo.

Students often have difficulty understanding inheritance patterns and issues associated with the nature of science as a process. To help address these issues, we developed a unit plan based on Gregor Mendel’s well-known research on inheritance patterns among pea plants. The unit introduces students to Mendel’s background and the questions he sought to address. Students then conduct their own investigation, using Virtual Genetics Lab II (VGLII) software to attempt to confirm Mendel’s results. In the course of completing their investigations, students learn about alternative inheritance patterns to Mendelian genetics. The unit was created in the context of a college introductory biology course but could be implemented in a high school course.