Difference between revisions of "Team:NAIT Edmonton/Modeling"
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+ | <font style="12px">Figure 2, An Autodesk Maya render of a protein linearizing and denaturing in the presence of SDS </font> <br><br> | ||
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+ | <h3>Polyacrylamide gel acts like a mesh that strains and separates proteins based on size or molecular weight. Larger, bulkier proteins have a difficult time twisting and turning through the pores while smaller proteins slip through quite easily. Therefore, smaller proteins travel further down the gel within the specific time that the current is on while larger proteins stay closer to the top of the gel. </h3> | ||
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Latest revision as of 18:20, 2 November 2015
Modeling
We find that in science, it is hard to fully grasp a real life concept when it is shown to us only in two dimensions. We live in a three dimensional world! Why are we learning how things work only in 2D? We visualized our project with 3D models and made animations so that anyone of the general public could watch the videos, understand and get excited about the science behind our project.
If a picture is worth a thousand words, a video is worth a million. Take a gander through our 3D models and animations!
Above is a typical textbook representation of the protein, apoferritin. From this 2D representation, personally we find it difficult to gauge the actual structure and shape of the protein. Since the shape of the protein is essential to its function, why do we limit ourselves to such a primitive 2D drawing?
Below is an interactive 3D model of apoferritin. Through 3D technology, you can gain a better appreciation of the shape, contours and therefore function of the protein.
How Does SDS PAGE Work?
SDS PAGE is a technique used to separate proteins by their molecular weight. Within a sample, there are multiple different types of protein. If we wanted to study a specific one, we would have to separate the different types first and isolate our desired protein.
Source: apoferritin: complex with SDS, RCSB Protein Data Bank