protein structure Flashcards
peptide bonds
very stable, cleaved by proteolytic enzymes (proteases or peptidases)
• Partial double-bonds, Flexibility around C atoms not involved in bonds
Van der Waals
weak attractive interactions between atoms due to fluctuating electric charges. Only important when 2 macromolecular surfaces fit closely in shape, can also be repulsive at very short distances
hydrogen bonds
interaction between dipoles involving hydrogen and an O/N
hydrophobic forces
uncharged and non-polar side chains are poorly soluble in water are repelled by water. Hydrophobic side chains tend to form tightly packed cores in the interior of proteins
ionic bonds
between fully or partially charged groups
disulphide bonds
in extracellular domains of proteins. Conditions can be harsher so extra stability is conferred by covalent bonds between side chains of cysteine residues
primary structure
linear sequence of aa linked by peptide bonds, determines its 3D structure
secondary structure
alpha helix: H-bonds between each carbonyl group and the H attached to the N which Is 4 aa along the chain. Proline breaks the helix. Beta-sheet: formed by H-bonds between linear regions, cains from 2 proteins or same protein, parallel or anti-parallel, if chain folds back it is called a hairpin loop
tertiary structure
3D conformation, more bonds, barrels, bundles, saddle, can change with pH
quaternary structure
3D structure composed of multiple subunits, same non-covalent interactions as tertiary structures
how do we determine structure?
x-ray diffraction of protein crystals
enzymes
Bind to reactants (substrates) and convert them into products then release the products and return their original form, speed up and regulate reactions. Can be used as disease markers and drug targets
Haemoglobin and myoglobin
- Porphyrin ring – at the core, holds iron atom so is called heme, iron atom is the site of oxygen bonding
- Temperature, H+ and carbon dioxide affects saturation of haemoglobin by modifying its structure and altering its affinity for oxygen
sickle cell anaemia
- Genetic disorder characterised by the formation of hard, sticky, sickle-shaped red blood cells
- Disease is caused by a mutation in haemoglobin
- Adaptation to malaria
immunoglobulin (antibodies)
- Produced to bind antigens, typically toxins or proteins on the surface of microbial agents. Targets are labelled for destruction by cells of the immune system of by lysis through the complement system
- Structure – supporting scaffold that displays highly variable loops of complimentary determining regions allows range of reversible bonding affects between antibody and antigen, antigen binding site positioned at tip of supporting structural framework. Arms of antibody can hinge to allow degree of movement
- Antibody/antigen interaction is the close proximity of the antibody CDR regions and the antigen surface, intimate contact allows combination of weak interactions to produce a strong binding surface
- Proportion of antigen bound – epitope
- Bulky amino acid groups can project from the antigen surface
