Learn about the different types of proteins that exist on the cell membrane. By William Tsai.

Learn about polymers.  They are all around us. From the proteins we consume to the plastic cups we drink from, polymers dominate our lives and our earth. They package our snacks but can also pollute our oceans. But do you REALLY know what a polymer is? Join Camille Schrier, science lover and Miss America 2020, to explore the science of polymers by making some slimy sodium alginate worms, and biodegradable corn plastic that is good for the earth!!

In this activity on page 1 of the PDF, learners compare the relative sizes of biological objects (like DNA and bacteria) that can't be seen by the naked eye. Learners will be surprised to discover the range of sizes in the microscopic world. This activity can be followed up with a second activity, "What's in a microbe?", located on page 3 in the same resource.

This Protein Purification video lesson is intended to give students some insight into the process and tools that scientists and engineers use to explore proteins. It is designed to extend the knowledge of students who are already somewhat sophisticated and who have a good understanding of basic biology. The question that motivates this lesson is, ''what makes two cell types different?'' and this question is posed in several ways. Such scientific reasoning raises the experimental question: how could you study just a subset of specialized proteins that distinguish one cell type from another? Two techniques useful in this regard are considered in the lesson.

In this activity, students interact with 12 models to observe emergent phenomena as molecules assemble themselves. Investigate the factors that are important to self-assembly, including shape and polarity. Try to assemble a monolayer by "pushing" the molecules to the substrate (it's not easy!). Rotate complex molecules to view their structure. Finally, create your own nanostructures by selecting molecules, adding charges to them, and observing the results of self-assembly.

Video description:  In this close-up video, Jacob Torres, Technical and Horticultural Scientist at NASA's Kennedy Space Center, shares how space biology brings together his love of engineering and growing plants. For his work, he builds technology that supports growing crops in ways that have never been done before.  Video length:  2:35.NASA eClipsTM is a suite of online student-centered, standards-based resources that support instruction by increasing STEM literacy in formal and nonformal settings.  These free digital and downloadable resources inform and engage students through NASA-inspired, real-world connections.NASA eClips Ask SME: Close-up with a NASA Subject Matter Expert videos are professionally developed to capture a glimpse of NASA SME's personal interests and career journeys. Each can be used to spark student interest and broaden their ideas of the STEM workforce. Additional videos in this series can be found by searching GoOpenVA using "NASA eClips Ask SME".

Video Description:  No matter where plants grow, they have the same basic needs: water, nutrients, light, temperature, and atmosphere. No matter where humans may live, they need plants. Dr. Gioia Massa explains how NASA grows plants on the International Space Station in preparation for growing plants beyond Earth and, someday, on the Moon and Mars. Jacob Torres describes the hardware needed to provide open and closed systems for plant growth in space. This video shows how NASA scientists and engineers work together to learn more about ways plants live, grow, and adapt to live in varying environments.  Video Length:  5:44.NASA eClips Our World videos (grades 3-5) help students understand the differences between science (the natural world) and engineering (the designed world).  These video segments supplement elementary learning objectives not only in science, technology, engineering and mathematics, but also in reading, writing, visual and performing arts.

Primary, secondary, tertiary and quaternary protein structure. Beta pleated sheets and alpha helices.

The goal of proteomics is to analyze the varying proteomes of an organism at different times, in order to highlight differences between them. Put more simply, proteomics analyzes the structure and function of biological systems. [8] For example, the protein content of a cancerous cell is often different from that of a healthy cell. Certain proteins in the cancerous cell may not be present in the healthy cell, making these unique proteins good targets for anti-cancer drugs. The realization of this goal is difficult; both purification and identification of proteins in any organism can be hindered by a multitude of biological and environmental factors. [9]

Learn about cooking and baking. They are really all about science. Using her kitchen as her laboratory, Camille Schrier, Miss America 2020, explores the power of food and the science of cooking. She dissects what happens when she's in the kitchen preparing two of her favorite foods- eggs and cookies. Join Miss America as she explores the biological building blocks of food and the molecular changes that happen when we cook. Developed for students in grades 6-10.

All cells, organs and tissues of a living organism are built of molecules. Some of them are small, made from only a few atoms. There is, however, a special class of molecules that make up and play critical roles in living cells. These molecules can consist of many thousands to millions of atoms. They are referred to as macromolecules (or large biomolecules).

Uniporters, symporters, and antiporters are proteins that are used in ƒ??transportƒ?? of substances across a cell membrane. Uniporters are involved in facilitated diffusion and work by binding to one molecule of substrate at a time to move it along its concentration gradient. Symporters and antiporters are involved in active transport. Antiporters transport molecules in opposite directions, while symporters transport molecules in the same direction.