Protein Structure

Biochemists refer to four distinct aspects of a protein's structure:

'' Primary Structure '': the amino acid sequence

'' and Beta Sheet --or segments of chain that Assume No Stable Shape . Secondary structures are locally defined, meaning that there can be many different secondary motifs present in one single protein molecule

'' Tertiary Structure '': the overall shape of a single protein molecule; the spatial relationship of the secondary structural motifs to one another

''s'' in this context, which function as part of the larger assembly or Protein Complex .

In addition to these levels of structure, proteins may shift between several similar structures in performing of their biological function. In the context of these functional rearrangements, these tertiary or quaternary structures are usually referred to as " Conformation s," and transitions between them are called conformational changes.

The primary structure is held together by Covalent Peptide Bond s, which are made during the process of Translation . The secondary structures are held together by Hydrogen Bond s. The tertiary structure is held together primarily by Hydrophobic interactions but Hydrogen Bond s, ionic interactions, and Disulfide Bond s are usually involved too.

The two ends of the amino acid chain are referred to as the Carboxy Terminus (C-terminus) and the Amino Terminus (N-terminus) based on the nature of the free group on each extremity.

AMINO ACID STRUCTURE

The basic structure of an α-amino acid is quite simple. R denotes any one of the 20 possible side chains (see table below). We notice that the Cα-atom has 4 different ligands (the H is omitted in the drawing) and is thus Chiral . An easy trick to remember the correct L-form is the CORN-rule: when the Cα-atom is viewed with the H in front, the residues read "CO-R-N" in a clockwise direction.
The different side chains R determine the chemical properties of the amino acid or residue (the residue is the amino acid side chain plus the peptide backbone, see below).

SIDE CHAIN CONFORMATION

The atoms along the side chain are named with Greek letters in Greek alphabetical order: alpha, beta, gamma, delta, epsilon... and so on. Alpha refers to the carbon atom closest to the carbonyl group of that amino acid, beta the second closest and so on. The alpha atom is usually considered a part of the backbone. The dihedral angles around the bonds between these atoms are named chi1, chi2, chi3... E.g. the first and second carbon atom in the side chain of lysine is named alpha and beta and the dihedral angle around the alpha-beta bond is named chi1. Side chains can be in different conformations called gauche(-), trans and gauche(+). Side chains generally tend to try to come into a Staggered Conformation around chi2.

THE POLYPEPTIDE CHAIN

Two amino acids are combined in a Condensation Reaction . Notice that the Peptide Bond is in fact planar due to the delocalization of the Electron s. The sequence of the different amino acids is considered the Primary Structure of the peptide or protein. Counting of residues always starts at the N-terminal end (NH₂-group).

In contrast to the rather rigid peptide Bond Angle ω(the bond between C₁ and N) (always close to 180 degrees), the Dihedral Angle s phi φ (the bond between N and Cα) and psi ψ (the bond between Cα and C₁) can have a certain range of possible values. These angles are the degrees of freedom of a protein, they control the protein's three dimensional structure. They are restrained by geometry to allowed ranges typical for particular secondary structure elements, and represented in a Ramachandran Plot . A few important Bond Length s are given in the table below.

SECONDARY STRUCTURE ELEMENTS

The polypeptide chain of a protein seldom forms just a Random Coil . Remember that proteins have either a chemical (enzymes) or structural function to fulfil.
High specificity requires an intricate arrangement of 3-dimensional interactions and therefore a defined conformation of the polypeptide chain. In fact, some neurodegenerative diseases like Huntington's may be related to Random Coil Formation in certain proteins. The two most common Secondary Structure arrangements are the right-handed Alpha Helix and the Beta Sheet , which can be connected into a larger ''' Tertiary Structure ''' (or fold) by turns and loops of a variety of types. These two secondary structure elements satisfy a strong hydrogen bond network within the geometric constraints of the bond angles ω, ψ, and φ. The β-sheets can be formed by parallel or, most common, antiparallel arrangement of individual β-strands.

Only the atoms of the backbone are involved in secondary structure, not the amino acid side chains ("R groups").

Turns, loops and a few other secondary structure elements such as a 3-10
helix complete the picture. We have now enough pieces to assemble a complete protein, displaying its typical tertiary structure.

MULTIMERIC STATES

A protein comprised of a single polypeptide is called a monomeric protein. If it is a complex of two or more polypeptides (i.e. multiple subunits), it is called a multimer. Specifically it would be called a dimer if it contains two subunits, a trimer if it contains three subunits, and a tetramer if it contains four subunits. Multimers made up of identical subunits may be referred to with a prefix of "homo-" (e.g. a homotetramer) and those made up of different subunits may be referred to with a prefix of "hetero-" (e.g. a heterodimer).

FOLDS AND MOTIFS OF PROTEIN STRUCTURE

Despite that there are about 100,000 different proteins expressed in
eukaryotic systems, there are much fewer different Structural Motif s and folds, partly as a consequence of evolved pathways and mechanisms. Motif in this sense refers to a small specific combination of secondary structural elements (such as Helix-turn-helix ). These elements are often called Supersecondary Structure s. Fold refers to a global type of arrangement, like Helix-bundle or β-barrel . Structure motifs usually consist of just a few elements, e.g. the 'helix-turn-helix' has just three. Note that while the ''spatial sequence'' of elements is the same in all instances of a motif, they may be encoded in any order within the underlying Gene . Protein structural motifs often include loops of variable length and unspecified structure, which in effect create the "slack" necessary to bring together in space two elements that are not encoded by immediately adjacent DNA Sequence s in a gene. Note also that even when two genes encode secondary structural elements of a motif in the same order, nevertheless they may specify somewhat different sequences of Amino Acid s. This is true not only because of the complicated relationship between tertiary and primary structure, but because the size of the elements varies from one protein and the next.

PROTEIN FOLDING

''Main article: Protein Folding ''

The process by which the higher structures form is called protein folding and is a consequence of the primary structure. A unique polypeptide may have more than one stable folded conformation, which could have a different biological activity, but usually, only one conformation is considered to be the active, or native conformation.

STRUCTURAL DOMAIN

''Main article: Structural Domain ''

Within a Protein , a structural domain ("domain") is an element of Overall Structure that is self-stabilizing and often Folds independently of the rest of the protein chain. Many domains are not unique to the protein products of one Gene or one Gene Family but instead appear in a variety of proteins. Domains often are named and singled out because they figure prominently in the biological function of the protein they belong to; for example, the "calcium-binding domain of Calmodulin . Because they are self-stabilizing, domains can be "swapped" by Genetic Engineering between one protein and another to make Chimera s. A domain may be composed of one, more than one or not any Structural Motif s.

STRUCTURE CLASSIFICATION

There have been developed several ways of structural classification of proteins. These seek to classify the data in the Protein Data Bank in a structured order. Several databases have been made which classifies proteins with different methods. SCOP , CATH and FSSP are the largest ones. The methods used are purely manual, manual and automated, and purely automated. Work is being done to better integrate the current data. The classification is consistent between SCOP, CATH and FSSP for the majority of proteins which have been classified, but there are still some differences and inconsistencies.

PROTEIN STRUCTURE DETERMINATION

Around 90% of the protein structures available in the Protein Data Bank have been determined by X-ray Crystallography . This method allows the exact 3D coordinates of all the atoms in the protein to be determined to within a certain resolution. Roughly 9% of the known protein structures have been obtained by Nuclear Magnetic Resonance techniques, which can also be used to determine secondary structure. Note that secondary structure can be determined via other biochemical techniques such a circular dichromism. Secondary structure can also be predicted with a high degree of accuracy (see next section).

COMPUTATIONAL PREDICTION OF PROTEIN STRUCTURE

The generation of a Protein Sequence is much simpler than the generation of a protein structure. However, the structure of a protein gives much more insight in the function of the protein than its sequence. Therefore, a number of methods for the computational prediction of protein structure from its sequence have been proposed. ''Ab initio'' prediction methods use just the sequence of the protein. Threading uses existing protein structures.

SOFTWARE

There are many available software packages, such as free web-based STING , used to visualize and analyze protein structures.

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Protein Structure