Proteins and Ligands

Question 1

What is the central dogma?

Answer 1

The information flow from DNA to RNA to Proteins

replication, transcription, translation

Question 2

Protein function is determined by its shape, what is its shape determined by?

Answer 2

Its amino acid sequence

Question 3

How many standard amino acids are there?

Answer 3

20 plus some post-transcriptionally modified ones

Question 4

What is chirality?

Answer 4

When two molecules are optical isomers. They’re asymmetric and cannot be superimposed into one another

Question 5

What are the two stereoisomers of amino acids and which ones form peptide bonds with ribosomes?

Answer 5

L + D

Ribosomes only form peptide bonds with L amino acids

Question 6

What is the primary sequence?

Answer 6

The sequence of amino acids in the polypeptide chain

Question 7

What part of an amino acid chain is the N-terminus?

Answer 7

NH3+

Question 8

What part of the amino acid chain is the alpha carbon?

Answer 8

The carbon before each C=O bond

Question 9

What part of the amino acid chain is the peptide bond?

Answer 9

O=C-N-H-

Question 10

What part of the amino acid chain is the C terminus?

Answer 10

O=CO-

Question 11

What is resonance and what does it do for the peptide bond?

Answer 11

The electron in the C=O can jump between C=O and C=N

This gives the peptide bond double bond properties

Question 12

What are phi and psi angles?

Answer 12

They describe the protein backbone shape, some are more favoured than others. The angles for an alpha carbon can be plotted on a Ramachandran plot

Question 13

Are peptide bonds usually in trans or cis? What does this mean?

Answer 13

Trans.

This means the alpha carbons are further apart. This conformation is more stable due to steric hinderance

Question 14

What is steric hindrance?

Answer 14

Where molecules bump into each other, making the conformation less stable and less favourable

Question 15

What does urea do to purified proteins? What does this show?

Answer 15

High concentrations of urea denature and unfold proteins. When the urea is removed, the protein folds back into its original shape. This shows that the shape of a protein is determined by its amino acid sequence.

Question 16

What physiochemical interactions are involved in the folding of a.acid chains? (6)

Answer 16

Ionic interactions
Van der waals interactions
Hydrophobic/hydrophilic interactions
Disulfide bonds
Covalent bonds
Hydrogen Bonds

Question 17

What are some examples of amino acids with charged side chains (at neutral pH)?

Answer 17

Glutamate + Aspartate are negative

Lysine and Histidine are positive

Question 18

How does pKa affect the form of an acid?

Answer 18

When above its pKa, an acid is in its base form

When below its pKa, an acid is in its acid form

Question 19

What are Van der Waals interactions?

Answer 19

When brought close together, atoms not sharing electrons experience VDW interactions. They will attract as they become closer until they become too close and repel instead.

Question 20

How do hydrophobic interactions dominate protein structure?

Answer 20

Non-polar side chains tend to be buried in the core of the protein.
Polar side chains stay outside to form hydrogen bonds to water

Question 21

How are covalent bonds made and broken?

Answer 21

Made through oxidation. Lost through reduction

Question 22

What is the secondary structure?

Answer 22

Regular, repeated structures like alpha-helices and beta-sheets, formed out of the amino acid chain.

Question 23

What is the tertiary structure?

Answer 23

The 3D shape of a single polypeptide chain

Question 24

What is a quaternary structure?

Answer 24

The 3D shape of a protein that consists of more than one polypeptide chain.

Question 25

What is the general structure of an alpha helix? 4

Answer 25

Tight with no free space inside,
Usually twists right,
Sidechains can point out of the helix,
Every carbonyl oxygen forms a hydrogen bond with the amide hydrogen

Question 26

Why are alpha helices very common?

Answer 26

They are very stable structures. Every backbone atom that can form a hydrogen bond is forming one.

Question 27

Why are other helices important?

Answer 27

They are usually short and can come in between an alpha helix to allow kinks and bends.

Question 28

What is the structure of a collagen triple helix?

Answer 28

Three polypeptide chains with very condensed sequences. Every third R-group is a Glycine to allow structure and hydrogen bonds.

Question 29

What is the basic structure of a beta-sheet?

Answer 29

Hydrogen bonds between adjacent backbones.

Question 30

Whats the difference between anti-parallel and parallel beta-sheets?

Answer 30

Antiparallel: N-C and C-N, perpendicular H-bonds, more stable
Parallel: N-C and N-C, not perpendicular, less stable.

Question 31

How does retinol-binding protein use hydrophobic and hydrophilic side chains?

Answer 31

Hydrophobic chains allow it to interact with the hydrophobic retinol.
Hydrophilic chains on the outside allow it to dissolve in the blood.

Question 32

What is the importance of loops and turns?

Answer 32

Form variable and biologically active parts of proteins. Loops can interact with other molecules and form their active sites.

Question 33

What is a coiled coil?

Answer 33

When two alpha-helices assemble together. This is very common in nature.

Question 34

What are motifs and domains?

Answer 34

The building blocks of many proteins. Inbetween secondary and tertiary structure. These are made of more than one polypeptide chain but are not the completed protein. The same domains are found in many different proteins all with different functions.

Question 35

What does Levinthal’s paradox state?

Answer 35

That for a protein to try every possible composition before finding the correct, most energetically favourable one, it would take millions of years. Therefore it can be said that proteins do not find the correct structure by random.

Question 36

What are Vf and Vr and what do they rely on?

Answer 36

Vf = velocity of forward reaction
Vr = velocity of reverse reaction
They depend on reactant concentration

Question 37

How can ligand binding be observed?

Answer 37

Using a signal (i.e colour change) to show the fraction of the protein bound to the ligand (Y)

Question 38

What happens when ligand concentration is equal to Kd? What about when it is much higher than Kd?

Answer 38

When equal, half the binding sites are occupied.

When much higher, most of the binding sites are occupied.

Question 39

What happens to affinity as Kd increases?

Answer 39

Affinity decreases as it binds ligands more weakly.

Question 40

What is Kd?

Answer 40

The ligand concentration required to occupy half the binding sites

Question 41

What are the two forms of haemoglobin?

Answer 41

Deoxyhaemoglobin (T) : tense form with a low affinity for O2

Oxyhaemoglobin (R) : relaxed form with a high affinity for O2.

Question 42

What changes haemoglobin structure between R and T form?

Answer 42

The proximal histidine on heame is bound to Fe2+ + part of an alpha helix. This increases the specificity of Hb to bind to O2 to become oxyhaemoglobin.

Question 43

what does a sigmoidal binding curve of O2 to haemoglobin show?

Answer 43

The binding of the first O2is much harder.

Once the first one has bound, the others bind much more easily

Question 44

What are allosteric effectors in Hb?

Answer 44

Substances that bind to Hb at a site other than the O2 binding site

Question 45

What does BPG do when bound to Hb?

Answer 45

Stabilises the t-state Hb to increase the p50 at higher altitudes or in response to airway obstruction

Question 46

What is the role of serine histidines in fetal Hb (HbF)?

Answer 46

• makes BPG bind less tightly
• gives it a smaller p50
• binds O2 more tightly so it can be taken from the mothers normal Hb

Question 47

What is the Bohr effect? What is an example of where this happens?

Answer 47

H+ can bind to deoxy-Hb when pH is low, releasing the O2.

E.g in the production of lactic acid

Question 48

Describe the path of CO2 from the tissues to the lungs.

Answer 48

• CO2 produced by tissues
• Converted into HCO3- and H+ in RBC
• H+ binds to Hb, releasing O2 which diffuses into the tissues.
• HCO3 diffuses into the plasma and is transported to the lungs
• converted back into CO2 and H2O where CO2 diffuses into the lungs and is expelled

Question 49

How and where do salt bridges help stabilise Hb?

Answer 49

• only in the T-state
  O2 binds to the amino terminal groups of Hb by forming carbamate
  -carbamate helps to build these salt bridges

Question 50

Does CO2 or drop in pH reduce O2 affinity in Hb more?

Answer 50

CO2

Question 51

What effects can mutations on the surface of Hb have?

What about mutations on the inside?

Answer 51

Mutations on the surface often have no phenotype

Mutations on the inside can cause hemolytic anemia

Question 52

How does sickle cell anaemia affect red blood cells?

Answer 52

• sickle shape
• broken down more easily
• molecules interact in ways they shouldn’t and can form fibres
• can block capillaries

Question 53

How does antibody specificity arise through combinational rearrangement?

Answer 53

Many different types of random antibodies are produced by B cells. Some of these will happen to bind to the antigen. The ones that bind to the antigen will be specific and can replicate to produce clonal antibodies.

Question 54

What is cross-reactivity? What is an example of this?

Answer 54

When one antibody binds to more than one antigen.

E.g antibodies against cowpox can also bind to smallpox antigens due to their similar structure

Question 55

How do vaccines work?

Answer 55

Stimulate B cell proliferation, including memory B cells.

The body can then generate clonal B cells rapidly in the event of future infection.

Question 56

How can antibodies be produced using an animal?

Answer 56

• inject animal with protein
• collect serum a few weeks later
• serum will contain specific antibodies which can then be easily purified

Question 57

What are reporter molecules?

Answer 57

Enzymes, radioisotopes or fluorescent molecules that bind covalently to the antibody and report the binding event

Question 58

What do the Fab and Fc regions do in antibody technology?

Answer 58

Fab region gives specitivity

Fc region allows binding to be detected

Question 59

What is a western blot?

Answer 59

• mixture of proteins containing antigen is separated by gel electrophoresis (weight)
• antibody is added to the gel
• antibody binds to the antigen of interest and a reporter molecule shows which protein is the antigen

Question 60

What is the globin fold?

Answer 60

a recurring structure of a set of αlpha helices in myoglobin and hemoglobin

Question 61

What is the functional role of the “distal histidine”?

Answer 61

It donates a hydrogen bond the bound oxygen molecule to stabilize the complex between iron and oxygen.

Question 62

How does the Bohr effect change the oxygen binding curve?

Answer 62

Moves it to the right

Question 63

What fragment of the antibody is responsible for effector function

Answer 63

Fc

Question 64

What parts of the antibody bind to the antigen?

Answer 64

Fab and variable regions

Question 65

What fragments determine antibody specificity?

Answer 65

variable regions of both light and heavy chains