Computer-Aided Protein Visualization Lab
Knowing the three-dimensional structure of a protein can be a very powerful tool for biologists. Much can be learned about enzyme function, interaction of molecules in your immune system, the appearance of the surface of viruses, and the interaction of ligands and receptors.
One particularly key area of current research is the design of drugs against specific protein targets. Scientists may look for drugs to block the activity of an enzyme of an attacking bacteria, protist or virus. After first finding an enzyme that is slightly different between humans and the invading species, the scientists can then use computers to look at the enzyme and try to fit tens of thousands of compounds into the enzyme in such a way as to block its activity; most commonly this involves plugging the active site of the invading species enzyme selectively. Using computers to analyze this problem can speed up the screening of 50,000 potential drugs from many years down to one week! Once a few compounds with potential are approved by the computer, the scientist can look to chemically modify those compounds to make them even better and then try them out in drug trials against the enzyme in test tubes, and eventually in drug trials in animals and humans.
First some background: (make sure that you understand the underlined words)
Proteins are synthesized on ribosomes by linking together many amino acids into a long chain. If you could observe a protein as it is made, it would look like a string of pearls (amino acids) feeding out the end of the ribosome as it floats in the cytoplasm of the cell Video of Translation (DNALC). This structure is called the primary structure (or 1° structure) and refers to the sequence of amino acids of the protein. After protein synthesis has started, two choices are possible:
(1) if the protein is destined to be secreted or to reside in an organelle of the secretory pathway, the first twenty or so amino acids will comprise a signal sequence. These act to direct the ribosome to the endoplasmic reticulum (ER) where the protein will be fed through a channel in the membrane into the interior of the ER. Once inside the ER, the protein will fold and receive sugar modifications called glycosylations.
(2) if the protein is destined to remain in the cytoplasm or move to the mitochondria or nucleus, the ribosome will remain free in the cytoplasm. The protein would then be folded as it emerges from the ribosome.
Protein folding:
The most important rule about protein structure is that it is determined by the primary sequence of the protein. Protein folding is a complicated multi-step process. The first step results in the secondary structure (or 2o structure) of the protein. Secondary structures come in two flavors: alpha helices and beta sheets (or beta-pleated sheets). Alpha helices are spiral staircase structures (see structure 1 below), and beta-pleated sheets are flat regions where the amino acids run back and forth next to each other in long ribbons (see structure 2 below). These two structures form spontaneously based on the shape/hydrophobicity/charges of the amino acids and are held together by hydrogen bonds. The protein will now look like a string of pearls with twists or zig-zags at intervals along its length.
1.
2.
The second step of protein folding results in the tertiary structure (or 3° structure). Tertiary structure gives the protein an overall three-dimensional structure. The tertiary structure of a protein is determined by a combination of factors including hydrogen bonds, ionic bonds (between positively and negatively charged amino acids), covalent disulfide bonds (between cysteine residues), and Van der Waals interactions. Tertiary structure can also be affected by repulsive forces between similarly charged amino acids, as well as hydrophobic and hydrophilic interactions with a solvent (commonly water). At a distance many proteins form what look to be large globs at this point, and it is only upon more careful and close up inspection that one can see the true uniqueness of the shape.
Figure 3: The various intramolecular interactions that help determine teriary structure
Proteins may contain only alpha helices, only beta sheets, or a combination of the two. The same holds true for the bonds giving a protein its tertiary structure - all, some or none may be present. These different folding patterns existing in different proteins are what give the proteins their distinctive shapes and sizes. A protein that is 300 amino acids long will be 100 nm as an extended chain. If the protein is an alpha helix, it will be 45 nm long; a beta sheet will be 7 x 7 x 0.8 nm; and a small globular form will form a sphere only 4.5 nm in diameter!
Domains:
Parts of the secondary and tertiary structures of a protein are usually arranged to form domains, functional units associated with a particular structure. For example, a pair of alpha helices situated side by side might form a binding site, or a particular folding pattern might form the active site of an enzyme, where it binds to its substrate, or the site at which it binds to a coenzyme such as NAD+. The structure of the domain (though not necessarily the exact amino acid sequence) is frequently preserved in different proteins from the same organism that have a similar function (to move phosphate groups, for instance). Domains are also conserved in proteins from different species that have the same function (such as hemoglobins for oxygen transport or cytochromes in the electron transfer system of mitochondria). Variations in the amino acid sequences in similar domains (or in the nucleotide sequences or genes that code for the proteins) give important clues about evolutionary relationships between organisms. Individual domains are sometimes found (but not always, a fact that makes this a very controversial topic) contained within single exons of eukaryotic genes. In other words, a single exon might represent all of the protein coding sequence required to generate a functional domain within the context of the whole protein structure. This finding has implications for the evolution of eukaryotic genes, since it implies that new proteins can be generated by simply duplicating preexisting protein domain encoding exons and recombining them into new combinations (a process known as exon-shuffling). Thus, a vast variety of proteins with new functions can be generated from preexisting genes, allowing great evolutionary flexibility. Looking at the genes of many eukaryotic organisms shows that this is exactly what appears to happen.
A good example of all of these principles can be found in immunoglobulins (see figure 4). They are protein molecules that form one of the main lines of defense against foreign organism invasion of the body and are part of the humoral immune response (this is the branch of the immune system that is activated when you are given a vaccine). They are made up of four subunits: two identical heavy chains and two identical light chains. Immunoglobulins are divided into several domains, including the 2 variable domains on the tips of the “Y” arms and are involved in binding specific antigens, and the constant domains which make up the rest of the molecule. The constant domains serve to determine the type of antibody (IgG, IgM, IgA, etc) the molecule represents and to mediate the response of the immune system to the antibody tagged antigen. Each of these domains is defined by it’s own exon within the immunoglobulin gene structure.
Figure 4: Immunoglobulins. Three views of the immunoglobulin complex IgG. On top is a schematic of an immunoglobulin complex showing the two light chains, the two heavy chains and the variable and constant domains. In the middle is a space filling model based on an X-ray crystal structure. This clearly shows the 4 subunits that make up antibodies, and how they are divided into functional (and structural) domains. On the bottom is the same structure represented in a ribbon diagram that shows secondary structure. The flat ribbons show beta-sheets while the cylindrical barrels represent alpha-helices. The interaction of secondary structure to form tertiary structure, and the interaction of these structures to form quaternary structure is apparent.
The final step of protein folding results in quarternary structure (or 4° structure). This step is only taken in proteins that are made of multiple subunits; meaning that strands of proteins - coded for on separate mRNAs and synthesized independently - come together to form a single functional molecule. Many proteins have multiple subunits; for example, immunoglobulins are made up of four subunits (figure 4).
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Structural highlights
This is a sample scene created with SAT to by Group, and another to make of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes.
