Protein structure
Proteins participate in numerous functions within living organisms, and protein function is largely dependent on the protein structure. Many diseases are caused by proteins whose structures have been modified, either due to amino acid substitutions (sicle cell anemia, cancer) resulting from DNA changes or by incorrect protein folding (alzheimer's).
Basis of protein structure
A Protein is a linear polymer of different amino acids, whose properties vary. To a large degree the shape of a protein is determined by the hydrophobic (water hating) amino acids which prefer not to be solvated and by the hydrophilic (water loving) amino acids, which like to be exposed to water. Proteins typically fold up in such as way to minimize the solvent exposure of the hydrophobic amino acids while exposing the hydrophilic ones. This is accomplished by both local secondary structure and by the overall tertiary structure of the protein. Hydrogen bonding also plays a significant role in a protein's structure, especially in regards to the secondary structure elements. Some proteins, often those with a very high percentage of hydrophilic amino acids, are natively unfolded, or are said to have a random coil structure. For example, many hormone receptor proteins, or large portions of them, are natively unfolded. Most of the proteins for which structures has been determined have secondary structures consisting largely of alpha helices and/or beta-sheets which are tighly packed together to bury the hydrophobic amino acids (typically aliphatic and aromatic amino acids) away from the solvent.
Alpha helix structure
A helix is generally a 310-helix (seldom) or an alpha-helix, depending on the degree of twist in the protein backbone. By coiling the backbone atoms (black in the figure) to form a helix, a protein forms energetically favorable hydrogen bonds between the carboxyl oxygen atoms (end of red bonds) at a particular position (say i for example) with the amide proton atom (end of blue bonds) at position i+4 (see figure). This formation also minimizes steric interactions between adjacent side chains. When two helices are packed against each other, they often point in opposite directions to reduce the dipole-dipole interaction between them. The dipole of each helix is caused by the alignment of the polar bonds within a helix. Often, one side of a helix is hydrophobic while the other side is hydrophilic, and such a helix is said to be amphiphilic. Some proteins are made entirely or nearly entirely of only alpha helices. Musle tissue and keratin are two examples.
Beta sheet structure
The other major element of secondary structure is the beta-sheet which is comprised of individual beta-strands. In a beta-strand, the protein backbone atoms (N,Ca and C) form a zig-zag pattern (see figure). The result is that both the carboxyl group oxygen atoms and the amide group protons alternative back and forth on the strand. When two beta-strands interact, favorable hydrogen bonds can be formed between the carboxyl oxygen atoms and the amide group protons, thus stabilizing the structure. Like helices, beta-strands often have a hydrophilic side and a hydrophobic side, so that interactions between them and other secondary structure elements can be used to bury the hydrophobic amino acids and leave the hydrophilic amino acids exposed. The ends of beta-strands often end with beta-turns (read below). There are four types of beta-turns, called Types I, II, I' and II'. I' and II' are mirror images of types I and II. The ends of beta-strand may be flexible loop structures as well.
Tertiary structure
A protein's tertiary structure (see first image) describes how all of the secondary structure elements fold upon one another. In order to bury the hydrophobic amino acid side chains (or residual groups), the secondary structural elements collapse upon each other so that most of the hydrophobic side chains are secluded away from the solvent, while the hydrophlic amino acids are exposed to the solvent. Thus, a beta-sheet might be protected on both sides by alpha-helices such that the polar side of the helix is exposed to the solvent while the non-polar, hydrophic side of the helix interacts with the hydrophobic residues of the beta-sheet.
Quaternary structure
Quarternary structure describes the interaction (structure) of a group of proteins. Many proteins exist in dimer form, meaning that two molecules of protein bind to each other. Many DNA binding proteins are homodimers. Other proteins form homotrimers and homotetramers. If different protein bind together, they are referred to as hetero-dimers, hetero-trimers, and so forth. Many biological processes occur when dozens of proteins or proteins/DNA/RNA molecules bind together to form a quaternary structure.