Protein folding and misfolding

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Protein folding and misfolding Harini Chandra Affiliations Folding of proteins into their native conformations occurs spontaneously under physiological conditions and is dictated by the primary structure of the protein.

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Harini Chandra Affiliations. Protein folding and misfolding. Folding of proteins into their native conformations occurs spontaneously under physiological conditions and is dictated by the primary structure of the protein. Master Layout (Part 1). 1. This animation consists of 5 parts: - PowerPoint PPT Presentation

Transcript of Protein folding and misfolding

Page 1: Protein folding and misfolding

Protein folding and misfolding

Harini ChandraAffiliations

Folding of proteins into their native conformations occurs spontaneously under physiological conditions and is dictated by the primary structure of the protein.

Page 2: Protein folding and misfolding

Master Layout (Part 1)

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Source: Biochemistry by Lehninger, 4th edition (ebook)

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Unfolded polypeptide chain

Partially folded polypeptide

Native state -helix

This animation consists of 5 parts:Part 1 – Thermodynamics of protein foldingPart 2 – Anfinsen’s experimentPart 3 – Amino acid structure determines 3-D foldingPart 4 – Molecular chaperones for protein foldingPart 5 – Protein misfolding diseases

Entropy

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Definitions of the components:Part 1 – thermodynamics of protein folding

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11. Entropy: Entropy is a measure of randomness or how disorganized a system is and forms the basis of the second law of thermodynamics, which states that the total entropy of a system cannot decrease without correspondingly increasing the entropy of another system. In other words, the entropy of the universe (system + surrounding) is constantly increasing. Entropy helps in predicting the spontaneity of any process. An unfolded polypeptide chain has high entropy which goes on decreasing as the protein folds into its native state.

2. Free energy: The free energy, also known as Gibbs free energy, is the maximum amount of mechanical work that can be done by a system at constant temperature and pressure. In general, all systems try to attain minimum free energy and a reaction takes place spontaneously only when the associated free energy change is negative.

3. Unfolded polypeptide chain: The amino acids that have been joined together by peptide bonds but have not yet formed their secondary or tertiary structures. This conformation has the highest free energy and entropy.

4. Partially folded polypeptide: The amino acids in the polypeptide chain start interacting by means of hydrogen bonds across the polypeptide backbone in order to initiate the folding process. The free energy and entropy of the system gradually decrease as the folding takes place.

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Definitions of the components: Part 1 – thermodynamics of protein folding

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15. Native state -helix: The polypeptide chain assumes its most stable, native conformation in the form of an -helix with the folding being directed largely by its amino acid residues. This conformation corresponds to minimum free energy and entropy, thereby conferring very high stability. The lowering of entropy is favoured by a corresponding increase in entropy in the surroundings composed of water molecules.

6. Molten globule: Initial collapsed state of a protein with very little thermodynamic stability is known as the molten globule. The amino acid side chains are extremely disordered in this state with several fluctuations being observed.

7. Percentage residues in native conformation: This refers to the number of residues that have assumed their favourable, lowest energy states. The percentage increases gradually as the folding process takes place.

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Part 1, Step 1:

Action Audio Narration

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4Description of the action

Unfolded polypeptide chain, high free energy & entropy

Helix formation commences, free energy & entropy decrease

Entropy

Free

ene

rgy

Beginning of helix formation

The green chain and blue circles shown must assume the different arrangements as shown.

H2OH2O

H2O

H2O

H2O

H2O

H2O

H2O

H2OH2O

H2OH2O

(Please redraw all figures.)First show the green chain on the top. Then show the blue circles appearing around it . The green chain must then be shown to bend in various ways until it assumes the shape below. And the blue circles must also rearrange themselves as shown. The graph on the right must gradually take shape in the direction indicated.

An unfolded polypeptide chain has very high free energy and entropy. Protein folding acts to decrease the free energy of the system by forming favorable interactions and assuming a more stable state. The entropy of the polypeptide chain decreases during this process.

Source: Biochemistry by Lehninger, 4th edition (ebook)

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Part 1, Step 2:

Action Audio Narration

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The black dotted lines must gradually appear on the green chain on top. The chain and blue circles must rearrange themselves.

H2O

H2O

H2O

H2O

H2OH2O

H2O H2O

Entropy

Intrachain hydrogen bonds

Entropy of water molecules increase, and polypeptide decreases

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Stable native state -helix

H2OH2O H2O

H2OH2O H2O

H2OH2O

H2OH2O H2O

(Please redraw all figures.)The blue circles must move around away from the green chain on top and form small clusters.The black dotted lines must appear on as shown on the green chain on top.The figure below must appear as shown and the graph on the right must be gradually completed.

As the protein continues to fold in order to assume its stable, low energy native state conformation, the entropy also decreases. While this would seem unfavorable for the system, it must be recalled that the entropy of the surrounding water molecules increases during the process, thereby increasing the overall entropy and making it favorable and spontaneous.

Source: Biochemistry by Lehninger, 4th edition (ebook)

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Master Layout (Part 2)

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1 This animation consists of 5 parts:Part 1 – Thermodynamics of protein foldingPart 2 – Anfinsen’s experimentPart 3 – Amino acid structure determines 3-D foldingPart 4 – Molecular chaperones for protein foldingPart 5 – Protein misfolding diseases

Native ribonuclease A

6M urea

-mercaptoethanol

Denatured ribonuclease A

Remove urea & -mercaptoethanol

Broken disulphide linkages

Disulphide bonds

Noncovalent interaction

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Definitions of the components:Part 2 – Anfinsen’s experiment

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11. Native ribonuclease A: This is an endonuclease enzyme composed of 124 amino acids that cleaves single-stranded RNA molecules. It has four disulphide bonds in its native state that are essential for conformational folding and enzymatic activity. This was used by Christian Anfinsen to postulate the thermodynamic hypothesis of protein folding, according to which the folded form of a protein represents its free energy minimum.

2. -mercaptoethanol: or 2-mercaptoethanol with the formula OHCH2CH2SH is a chemical compound that is used commonly to reduce disulphide linkages in proteins, thereby disrupting the tertiary and quaternary structures.

3. 6M urea: It is an organic compound having two amine groups joined by a carbonyl group and used at concentrations up to 10 M for denaturing proteins by breaking the noncovalent interactions.

4. Denatured ribonuclease A: On treatment with -mercaptoethanol and urea, the ribonuclease A loses its native conformation due to breaking of the disulphide and noncovalent linkages. Activity of the enzyme is also lost during this process. However, it was observed by Anfinsen that removal of both urea and -mercaptoethanol allows the enzyme to fold into its native conformation again with more than 90% enzymatic activity.

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Part 2, Step 1:

Action Audio Narration

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4Description of the action

6M urea

-mercaptoethanol

The green pie shaped objects must break the black lines while the blue pie objects must be break the dotted lines.

First show the structure on the left. Then show the green pie shaped objects moving towards the black lines and breaking them and simultaneously the blue pie shaped objects breaking the dotted lines. The structure must then unfold and give rise to the open chain displayed below with the green & blue objects remaining bound to it.

Denatured ribonuclease A

Broken disulphide linkages

Native state ribonuclease A

Ribonuclease A in its native state has four disulphide bonds between its cysteine residues. When treated with b-mercaptoethanol and 6M urea, the protein undergoes denaturation and the disulphide linkages are broken. Enzyme activity is lost in the denatured state.

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Part 2, Step 2:

Action Audio Narration

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The chain must twist itself and reform the structures shown below. Movement in 3-D must be shown.

First show the structure on top followed by the right arrow & text. The green pie-shaped objects must be removed & the structure on the right must appear. Next the left arrow & text must be shown with disappearance of the blue pie-shaped objects & appearance of the figure on the left.

Native state ribonuclease A

It was observed by Anfinsen that removal of urea and -mercaptoethanol led to the refolding of the enzyme to assume its native state with more than 90% enzyme activity being intact. However, if only -mercaptoethanol was removed in presence of urea, the formation of disulphide bonds was random, leading to enzyme with only around 1% activity.

Inactive ribonuclease A

Remove -mercaptoethanol only

Remove urea and -mercaptoethanol

Denatured ribonuclease A

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Master Layout (Part 3)

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Source: Biochemistry by Stryer, 5th edition (ebook)

This animation consists of 5 parts:Part 1 – Thermodynamics of protein foldingPart 2 – Anfinsen’s experimentPart 3 – Amino acid structure determines 3-D foldingPart 4 – Molecular chaperones for protein foldingPart 5 – Protein misfolding diseases

1 2 3 4

1 2 3 4

Amino acid sequence 1

Amino acid sequence 2

Protein 1

Protein 2

Protein folding

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Definitions of the components:Part 3 – Amino acid structure determines 3-D structure

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11. Amino acid sequence 1, 2: These are two completely different amino acid sequences that will give rise to different protein structures.

2. Protein 1, 2: The protein structure corresponding to amino acid sequence 1 and 2 respectively. The first amino acid sequence cannot give rise to the second protein structure & vice versa.

3. Protein folding: The process by which the amino acid side chains in the proteins interact with one another to form energetically favourable bonds with each other thereby allowing regions that are far away from one another to move closer. This process is determined by the amino acid sequence of the proteins and needs to be energetically feasible in order to take place.

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Part 3, Step 1:

Action Audio Narration

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Folding of the grey chain.

First show the structure on the left with the blue & green projections. Next show this chain folding such that all the green parts come on the inside & blue parts are on the outside as shown in figure on the right. This must be surrounded by water molecules which must move towards the blue regions as depicted in the animations.

The process of protein folding is governed by the distribution of polar and non-polar amino acid residues in the protein. Hydrophobic amino acids are driven to interact with one another, a process termed as hydrophobic collapse. They come together andin the process, eliminate water molecules around them. The polar residues remain on the surface and form hydrogen bonds with water molecules while the hydrophobic residues get buried within the core of the protein.

Polar side chains

Non-polar side chains

H2OH2O

H2O

H2O

H2O

H2O

H2O

Folded protein

Aqueous environment

Hydrophobic residues buried inside

Protein folding is governed by distribution of polar & non-polar amino acid residues in proteins

Hydrogen bond interactions

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Part 3, Step 2:

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Show the figures above appearing one at a time followed by the graph.

(Please redraw all figures.)First show each of the figures appearing one after another. In each, the chain must become more compact as it progresses. Once the last figure has been shown, the graph must appear with the blue figure being unfolded to give the red chain. As soon as the structure starts getting modified, there must be a rapid increase in the graph curve.

Proteins typically adopt only one characteristic functional native state conformation which has lowest free energy and is most stable. Folding is limited to one conformation due to properties of the amino acid side chains such as hydrophobicity, size, shape etc. Folding is a highly cooperative process wherein there is progressive stabilization of the intermediates. Although it is theoretically possible to predict protein structure from the amino acid sequence, several long-range interactions often limit these predictions.

Protein folding is a cooperative process while unfolding is a sharp, quick transition

Unfolded statePartially folded

Folded native state

Partially folded conformations

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Master Layout (Part 4)

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Source: Biochemistry by Lehninger, 4th edition (ebook)

This animation consists of 5 parts:Part 1 – Thermodynamics of protein foldingPart 2 – Anfinsen’s experimentPart 3 – Amino acid structure determines 3-D foldingPart 4 – Molecular chaperones for protein foldingPart 5 – Protein misfolding diseases

Folded native conformation protein

Unfolded proteinDnaJ

DnaK

2Pi

GrpE

ADP + GrpE + DnaJ

Partially folded protein

To GroEL system

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Definitions of the components:Part 4 – Molecular chaperones for protein folding

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11. Unfolded protein: This refers to the protein or polypeptide chain that has not been folded or is in a partially folded state.

2. DnaJ and Dna K: These are molecular chaperones found in E.coli that are analogous to the eukaryotic heat shock protein (Hsp) chaperone system. These chaperones are proteins that interact with unfolded or partially folded proteins and provide them with suitable microenvironments in which folding can occur. In addition to this chaperone system, the Hsp proteins have also been studied and have been found in abundance in cells that have been stressed by elevated temperatures.

3. ATP: Adenosine triphosphate (ATP) is the energy currency of the cell due to its high energy phosphate bonds. It gets hydrolyzed to liberate adenosine diphosphate (ADP) and a phosphate group (Pi).

4. GrpE: This is a nucleotide exchange factor present in bacterial systems that facilitates the release of bound ADP.

5. GroEL system: The GroEL system refers to another group of elaborate protein complexes known as chaperonins that assist the folding of several cellular proteins.

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Part 4, Step 1:

Action Audio Narration

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ATP

ATP

ATP

ATP

Unfolded protein

DnaJ

DnaK

ADP

ADP

Pi

Blue squares and purple figures must bind to the red ribbon. After this, colour of circle must change as shown below.

(Please redraw all figures.)First show the red ribbon binding to the blue squares followed by purple figure (DnaK). The blue squares must interact with the circles which must then change colour as shown in the bottom figure and the arrow stemming out of the downward arrow must appear.

The unfolded protein is bound by DnaJ and then by DnaK which is an ATP bound protein. The hydrolysis of ATP into ADP and Pi by DnaK is stimulated by DnaJ. The resulting DnaK-ADP remains tightly bound to the unfolded protein.

Source: Biochemistry by Lehninger, 4th edition (ebook)

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Part 4, Step 2:

Action Audio Narration

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ADP

ADP

The green pie objects must remove the grey circles from the attached rectangle.

(Please redraw all figures.)First show the figure on top left. Then show the green pie shapes moving to the grey circles such that they must remove them from the attached rectangle.The blue squares must also get detached resulting in the figure at the bottom.

The nucleotide exchange factor GrpE present in bacteria facilitates release of ADP along with DnaJ. This leaves the DnaK bound to the partially folded protein which continues to undergo folding to a more favorable low energy conformation.

GrpE

ADP

ADP

ADP

ADP

DnaJ

DnaK

Source: Biochemistry by Lehninger, 4th edition (ebook)

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Part 4, Step 3:

Action Audio Narration

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The red ribbon must detach from purple square which must again bind the yellow circle.

(Please redraw all figures.)First show the red ribbon being detached from the purple squares followed by binding of yellow circles to the purple squares.

Once the protein gets completely folded, it gets detached from DnaK which then binds ATP again, thereby completing the cycle and preparing it for the next round of protein folding. Any protein which may not have been folded completely is then taken over by the GroEL chaperonin system which completes the folding.

DnaK

ATP

ATP

Folded native protein

Partially folded protein

ATP

DnaK regenerated for next round of protein folding

To GroEL system

Source: Biochemistry by Lehninger, 4th edition (ebook)

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Master Layout (Part 5)

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1 This animation consists of 5 parts:Part 1 – Thermodynamics of protein foldingPart 2 – Anfinsen’s experimentPart 3 – Amino acid structure determines 3-D foldingPart 4 – Molecular chaperones for protein foldingPart 5 – Protein misfolding diseases

Alzheimer’s disease Creutzfeldt–

Jakob disease

Cystic fibrosis

Pulmonary emphysema

Huntington’s disease

Lathyrism

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Definitions of the components:Part 5 – Protein misfolding diseases

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11. Alzheimer’s Disease: Structure of certain normal soluble cellular proteins normally rich in alpha helical

regions converted into beta strand conformations which further link with each other to form beta sheet aggregates known as amyloids.

Insoluble amyloid plaques are essentially made up of a single polypeptide chain or fibrils known as amyloid--protein (A

bserved in the brain of patients with Alzheimer’s where dead or dying neurons surround plaques

Neurotoxicity believed to be caused by the A fibrils before they get deposited as amyloid plaques.

The disease presents various symptoms such as memory loss, decreased neuromuscular coordination, confusion and dementia.

2. Huntington’s disease: Neurodegenerative disorder of genetic origin affecting muscular coordination. Caused by increased number of trinucleotide repeats, CAG, in Huntingtin gene

leading to increased number of glutamine residues incorporated in corresponding protein.

This alters the folding of the Huntington protein which has highest concentration in brain and testes.

Exact function of the protein is unclear but is known to interact with several other proteins.

Mutated protein has also been found to have effects on chaperone proteins which in turn help in folding several other proteins.

Prominently affects basal ganglia which plays a key role in movement and behavioural control.

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Definitions of the components:Part 5 – Protein misfolding diseases

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13. Creutzfeldt–Jakob disease: Initially believed to be caused by viruses or bacteria. Later discovered to be transmitted by small proteins known as prions. Prion proteins composed of beta sheet structures that have been modified from previously existing alpha helices. Protein aggregates of one abnormal protein sufficient to function as a nuclei for other normal proteins to attach themselves to. Characterized by muscular spasms, loss of muscle control and memory loss.

4. Cystic fibrosis: Autosomal recessive disorder caused by a mutation in gene for the protein cystic fibrosis transmembrane conductance regulator (CFTR) .CFTR regulates components of sweat, digestive juices and mucus. Caused by a deletion of three nucleotides leading to the elimination of a phenylalanine residue from the protein and therefore abnormal folding.Dysfunctional protein gets degraded by the cell. Disorder can affect several body parts such as the lungs, GI tract and reproductive organs.

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Definitions of the components:Part 5 – Protein misfolding diseases

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15. Pulmonary emphysema: Progressive disease of the lung causing shortness of breath. Can be caused by deficiency of the protein alpha-1-antitrypsin (A1AT).A1AT is responsible for protecting the lung tissues from damage by enzyme neutrophil elastase. Abnormally secreted A1AT gets accumulated in the liver thereby allowing lung tissue damage. Causes wheezing, shortness of breath, asthma-like symptoms and also liver cirrhosis.

6. Lathyrism: Regular ingestion of seeds from sweet pea (Lathyrus odoratus) causes disruption of cross-linking in the muscle protein, collagen. Collagen is an important structural protein having a triple helical structure.Cross-links formed are due to the oxidation of lysine residues by the enzyme lysyl oxidase to form allysine. These are essential for proper folding of collagen, giving it the required strength. -aminopropionitrile, present in abundance in sweet pea, deactivates this enzyme by binding to its active site This prevents cross-linking and proper folding of the protein.Causes muscle fragility and weakness.

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Part 5, Step 1:

Action Audio Narration

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Alzheimer’s disease Creutzfeldt–

Jakob disease

Cystic fibrosis

Pulmonary emphysema

Huntington’s disease

Lathyrism

User should be allowed to click on any of the given labels to understand more about it.

User should be allowed to click on any of the given labels to understand more about it as given by the definitions in the previous three slides.

<As given in the definitions slides.>

Page 25: Protein folding and misfolding

Interactivity option 1:Step No:1

Boundary/limitsInteracativity Type Options Results

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Choose the correct option.

User has to choose one of the four options. If a, c or d are chosen, they must turn red. User can however continue till he gets the right answer (b) which must turn green. User is then directed to step 2.

User has to choose one of the four options. If a, c or d are chosen, they must turn red. User can however continue till he gets the right answer (b) which must turn green. User is then directed to step 2.

Protein folding is an extremely quick process with a time scale of few milliseconds to seconds. Monitoring the process is therefore a formidable task requiring very rapid measurements to be made. One of the suitable techniques for this measurement is the pulsed hydrogen-deuterium (H/D) exchange reaction. This relies on the differential measurement of hydrogen and deuterium which give different signals by a particular spectroscopic technique. Which technique is this?

a) UV spectroscopy b) NMR

c) ESR d) Mass spectroscopy

Page 26: Protein folding and misfolding

Interactivity option 1:Step No:2

Urea

Guanidinium chloride

D2O

Native protein with regular hydrogen atoms

Denatured protein with deuterated peptide nitrogen atoms.

Deuterium labelled peptide N atoms

Stopped -flow device

Light source

Denatured protein solution

Denaturant solution with H2O

Mixer

Detector

Computer

Stopping syringe

Stop switch

Page 27: Protein folding and misfolding

Interactivity option 1:Step No:3 Folding initiated in denatured protein by mixing with denaturant diluted H2O and decreasing pH to arrest exchange reaction.

Folding takes place for preset time t, after which pH is rapidly increased again for exchange reaction to occur.

Only those D atoms that have not been involved in hydrogen bonding by time t will get exchanged now.

pH lowered finally to terminate labelling pulse and H/D ratio at each exchangeable site determined by 2-D NMR.

Denatured protein solution

Denaturant solution with H2O

Mixer

Light source

Detector

Computer

Stopping syringe Stop

switch

Denatured protein

Folding for time ‘t’

Low pH – no exchange reaction

Deuterium label

pH increased

Regular hydrogen from H2O

Not involved in H-bonding

H-D exchange reaction

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Questionnaire1

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1. If the free energy of a reaction is negative, the reaction will be

Answers: a) Endothermic b) Exothermic c) Non-spontaneous d) Spontaneous

2. -mercaoptoethanol is responsible for breaking which type of interactions in proteins?

Answers: a) Disulphide b) Hydrophobic c) Hydrogen bonds d) Peptide bond

3. In the absence of -mercaoptoethanol but presence of urea what happens to a denatured protein?

Answers: a) It gets further denaturedb)Random disulphide links are formedc) The native state is restored d) Only non-covalent interactions are restored

4. Which of the following is a trinucleotide repeat disorder?

Answers: a) Cystic fibrosis b) Alzheimer’s c) Huntington’s d) Lathyrism

5. Which enzyme is inactivated in the disease lathyrism?

Answers: a) Hexokinase b) Lysyl oxidase c) Collagenase d) Prolyl hydroxylase

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Links for further reading

Books:

Biochemistry by Stryer et al., 5&6th edition

Biochemistry by A.L.Lehninger et al., 4th edition

Biochemistry by Voet & Voet, 3rd edition