Students will participate in a 5E lesson. To ENGAGE, students will connect their understanding of similarities between parent and offspring to the fundamental molecule of life: DNA. To EXPLORE, students will participate in interactives to observe, analyze and summarize how genes are used to create proteins and traits. In the EXPLAIN section, students will take notes on DNA replication and the Central Dogma. To ELABORATE on their understanding of DNA, students will participate in a protein synthesis race (game) to practice transcription and translation. Formative evaluations of students's ability to explain the process of protein synthesis include (1) a protein synthesis and codon practice sheet, (2) a labeling activity, and (3) making a recording that models and explain the process. As an extension, students can apply their understanding of mRNA to explain how the Pfizer and Moderna COVID-19 vaccines work. Finally, int summative EVALUATE, students model replication, transcription, and translation as they build an organism!

As a class, students work through an example showing how DNA provides the "recipe" for making our body proteins. They see how the pattern of nucleotide bases (adenine, thymine, guanine, cytosine) forms the double helix ladder shape of DNA, and serves as the code for the steps required to make genes. They also learn some ways that engineers and scientists are applying their understanding of DNA in our world.

Explore the relationship between the genetic code on the DNA strand and the resulting protein and rudimentary shape it forms. Through models of transcription and translation, you will discover this relationship and the resilience to mutations built into our genetic code. Start by exploring DNA's double helix with an interactive 3D model. Highlight base pairs, look at one or both strands, and turn hydrogen bonds on or off. Next, watch an animation of transcription, which creates RNA from DNA, and translation, which 'reads' the RNA codons to create a protein.

Express yourself through your genes! See if you can generate and collect three types of protein, then move on to explore the factors that affect protein synthesis in a cell.

Students learn how engineers apply their understanding of DNA to manipulate specific genes to produce desired traits, and how engineers have used this practice to address current problems facing humanity. They learn what genetic engineering means and examples of its applications, as well as moral and ethical problems related to its implementation. Students fill out a flow chart to list the methods to modify genes to create GMOs and example applications of bacteria, plant and animal GMOs.

This lesson uses the fundamentals of protein synthesis as a context for investigating the closest living relative to Tyrannosaurus rex and evaluating whether or not paleontologist and dinosaur expert, Jack Horner, will be able to "create" live dinosaurs in the lab. The first objective is for students to be able to access and properly utilize the NIH's protein sequence database to perform a BLAST, using biochemical evidence to determine T rex's closest living relative. The second objective is for students to be able to explain and evaluate Jack Horner's plans for creating live dinosaurs in the lab. The main prerequisite for the lesson is a basic understanding of protein synthesis, or the flow of information in the cell from DNA to RNA during transcription and then from RNA to protein during translation

Overview of gene regulation in the Lac operon. Discussion of CAP, cAMP, lac repressor and allolactose in regulation of lac operon.

Proteins carry out the essential functions of life processes through systems of specialized cells. The structure of DNA serves as a code for the production of proteins through the process of protein synthesis. Protein synthesis is a biochemical process that uses information coded in DNA to construct proteins.  The central dogma illustrates the flow of genetic information in this process:  DNA-->RNA-->Proteins.  (Enduring Understandings of BIO.2d).This module was developed by Kris Scheible as part of a Virginia Commonwealth University STEM initiative sponsored by the Virginia Department of Education.

A deep dive into how mRNA is translated into proteins with the help of ribosomes and tRNA.

The trp operon is a well-studied operon when it comes to gene regulation. It is involved in the biosynthesis of the amino acid tryptophan.