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Title: Proteins and Enzymes
Description: Second year Proteins and Enzymes module, taught by Russ Morphew. Covered protein structures, thermodynamics, catalysts, folding, targeting, and experimenting.
Description: Second year Proteins and Enzymes module, taught by Russ Morphew. Covered protein structures, thermodynamics, catalysts, folding, targeting, and experimenting.
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Amino Acids
30 September 2015
11:40
History
• First amino acid isolated was asparagine in 1806
○ Louis-Nicolas Vauqelin
○ Extracted and isolated from asparagus
• Term amino acid introduced in 1898
• More than 200 discovered, only 20 found in protein
Alpha, Beta, Gamma - amino acids
• Carbons extending from the carboxylic carbon are labelled with greek letters
• Amine group can be attached to alpha, beta, or gamma
○ Alpha amino acids are found in proteins
•
Weak acids and bases
•
•
•
•
•
pKa = -log10(Ka)
Alpha-carboxylic range: 2-2
...
86, glu=4
...
6
Higher pKa, lower pH
Effect of pH on Amino Acids
• Le chatelier's principle
○ Alter equilibrium and the system will try to correct the change
•
• 1
...
equilibrium moves right
• Zwitterion
○ Molecule with 2 charges groups
○ Low pH, no charge on COOH (1)
Proteins ^M Enzymes Page 1
○ Low pH, no charge on COOH (1)
○ High pH, no charge on NH3 (2)
○ Intermediate both charged
○
pH and Amino Acids
• pH affects polarity of zwitterions
• Side chain pKa affects folding and structure
Stereoisomers
•
•
•
•
•
•
Molecules with a chiral centre (C with 4 different groups)
Different plane polarised light diffraction
L (laevorotatory)-amino acids are most proteinogenic
D (dextrorotatory)-amino acids found in sea dwelling organisms and bacterial cell wall
•
Electronegativity
• Tendency of an atom to attract electron bonding pair
○ Shown on the Pauling Scale
•
• Intermolecular Forces
○ Polar
Permanent dipoles
Hydrogen bonding (hydrophilic)
○ Covalent
○ Van der Waals
Temporary dipoles - weak interaction
Hydrophobic
Proteins ^M Enzymes Page 2
20 Amino Acids (+2)
•
•
•
•
•
Proteins ^M Enzymes Page 3
•
•
•
Essential Amino Acids
• Isoleucine
• Leucine
• Lysine
• Methionine
• Phenylalanine
• Threonine
• Tryptophan
• Valine
• Lysine and methionine can be limiting
Detection of Amino Acids
• Spectrophotometric assay
○ React with ninhydrin
○ Ruhemann's purple produced - can be measured with colorimetry
• Aromatic amino acids absorb UV260-280nm
• Mass spectroscopy
Proteinogenic and Non-proteinogenic
• Proteinogenic
○ ‘Protein building’ – amino acids within proteins
○ standard amino acids– 20 which are directly encoded for by codons (3 bases) in the
genetic code
○ Two non-standard- proteinogenic amino-acids, directly encoded- selenocysteine,
pyrrolysine
○ ‘Protein building’ – amino acids within proteins
• Non-proteinogenic
○ Not found in proteins
○ Not directly encoded by genetic code
Peptides
• Linear polymers of amino acids
• Properties determined by amino acid sequence
• Written from NH to CO
• Synthesis
○ Condensation (amide bond)
Proteins ^M Enzymes Page 4
○
○
○ Reversible, but stable (reverse reaction very slow)
Proteins ^M Enzymes Page 5
Peptides
06 October 2015
10:05
• Linear polymers of amino acids
○ Properties determined by amino acid sequence
• Amino acids termed residues
• <50 amino acids = oligopeptide
• Named from the N terminal residue
• 50-2000 residues
• Mean Mr of amino acids is 110Da
• Proteins range from 5kDa to 250kDa
Peptide Synthesis
• Condensation
• Peptide bond
•
SP2 and SP3 bonding
• SP3 - 109o bond angles, sigma bonds
•
• Sigma C-H bonds, sigma C=C bond
• P orbitals of C atoms interact to create pi bond
• This bond is rigid and cannot rotate
Cis and Trans Isomerism
Proteins ^M Enzymes Page 6
• Structural Features
○ Resonance
C-N 40% double bond character
Resonance between C=O and C-N
□ More rigid
□ No free rotation
□ Isomerism
Trans isomers favoured
○ Proline
Imino acid
Only trans synthesised
□ Prolyl isomerase can make cis form
Ramachandran Plot
•
A Ramachandran plot (also known as a Ramachandran diagram or a [φ,ψ] plot), originally
developed in 1963 by G
...
Ramachandran, C
...
Sasisekharan,[1] is a way to
visualize backbonedihedral angles ψ against φ of amino acid residues in protein structure
...
wikipedia
...
Adjacent amino acids can adopt different configurations by
rotation around the two other bonds in the backbone
...
These angles are measured in degrees where 180° is the angle of the bonds when all
of the atoms of both residues lie in the most extended conformation
...
Proteins ^M Enzymes Page 8
is positive so the values go from 0° to 180° and in the other direction they go from 0° to -180°
...
)
From
co
...
html>
Most of the amino acid residues in a given protein are found in some form of secondary
structure such as α helix,β strands, or turns
...
This is why the structure is so regular
...
Since the residues in a β stand are in an extended form, the Φ
and Ψ angles in this conformation are close to 180°
...
These can
be plotted on a diagram called a Ramachandran plot, named after the biophysicist G
...
Ramachandran (1922 - 2001)
...
Similarly, residues in a right-handed α helix have very similar bond angles around Ψ=-45°, Φ=+
45°
...
Some regions of the
Ramachandran plot will be empty because of steric clashes between the oxygen atoms
[see The Peptide Bond]
...
From
co
...
html>
Alpha-helix and Beta-sheet
• 1951 7 papers
• 2o structures proposed
• x-ray crystallography
• Linus Pauling - 1954 Nobel Prize
• Beta-sheet
○ Parallel sheet
○ h-bonds to 2 different amino acids
○
○ 2 or more polypeptide chains - beta-strands
○ Extended
○ Side chains point opposite directions
2-10 chains (4-5 normal)
Proteins ^M Enzymes Page 9
○ 2-10 chains (4-5 normal)
• Alpha-helix
○ Pauling and Corey predicted
○ Fully exploited H bonding of CO-NH
○ Every 4th amino acid is a full loop
Each residue rotate 100o
○
○
○
○
○
Each residue rises by 1
...
Only 1400 recognised - limited in
nature
• Common motifs and folds present in many proteins (even unrelated amino acid sequence)
• Domains: recognisable fold with known function
Proteins ^M Enzymes Page 12
Tertiary Structure and Protein Classes
07 October 2015
11:49
Alpha-keratin
• Alpha-helical proteins which entwine into coiled coils through R group interaction
• Protofilament
• Soft or hard depending on cysteine content (disulphide bridges)
○ Soft (skin) low cysteine content
○ Hard (horns) high cysteine content
○ Human hair ~14% cysteine
Porins
• Large β-barrel composed of 16 antiparallel sheets in barrel shape
•
• Channels through membranes - non-polar environments
• Hydrophobic groups to outside
• Hydrophilic groups inside - filled with water
Myoglobin
• Globin fold
• Similar structure to haemoglobin
• 1st protein structurally resolved
○ X-ray crystallography 1958
• 153 residues
• Compact molecule
• 8 alpha helices connected by loops
• Metallic prosthetic group
• Water soluble
• Non-polar residues internal
○ Leucine, methionine, phenylalanine
• 2 internal polar residues - histidine, covalent bond with Fe2+
Haemoglobin
• Oxygen transport metalloprotein
• Vertebrates and some invertebrates
• 97%DM of blood cells
• 1
...
g
...
g
...
g
...
Reacts with phenolic residues
○ Bradford assay - coomassie blue dye
• Isoelectric Focussing
○ Charged protein migrates down gel to point of neutral charge
Balance between dissociation of acid and basic groups
○ Every protein has a different number of acid/basic groups
PI point is balance
○
Proteins ^M Enzymes Page 17
Protein Sequence
• Chemical or enzymatic
• Must be relatively small in size
• Separated before further analysis
• Most methods relatively specific
• Cyanogen bromide:
○ Chemical
○ Carboxyl side of methionine residues cleaved
• Trypsin
○ Enzymatic
○ Carboxyl side lys and arg
○ Proteins containing 9 lysines and 7 arginines will give 17 peptides
Separation by chromatography
• Amino acids/short peptides separated by chromatography
• AAs/peptides elute at different times
• Measured with detector
Protein Sequencing
• Frederick Sanger sequenced Insulin in 1952
○ Insulin widely available (at Boots)
○ Took 10 year stop sequence - separate subunits
○ Breakthroughs
Cleaved into separate AAs
Labelled N-terminal amino acids
○ Demonstrated 2 n-terminal AAs - 1 glycine and 1 phenylalanine
○ 12k molecular weight
• Pehr Edman developed sequencing technique - 1950
○ Current techniques still based on his
○ Automated in 1967
○ Label N-terminal aa of peptide, cleave and identify
○ Different segment from different cleavage enzyme/treatment
○
• Protein Sequence Alignment
○ Trypsin cleaves c-end of lys and arg
○ CNBr cleaves c-end of met
○ Different peptide segments are generated
Overlapping short peptides
Proteins ^M Enzymes Page 18
○ Overlapping short peptides
○ Can be aligned to give larger sequence
• Location of disulphide bridges
○ Method by Brown and Hartley
○ Tryptic digestion of protein and separated along 1st dimension
S-S intact
○ Peptides treated with performic acid and separated by electrophoresis, repeated along
2nd deimension (breaks S-S)
○ Peptides not S-S linked will migrate the same distance
○ Peptides cleaved will give 2 new spots
These are purified and S-S location is established
○
Protein Configuration in Space
• 1-100nm - hard to visualise in 3D
○ 400-700nm visible
○ 200nm with oil lens max resolution
• x-ray range 0
...
1-100Angstroms)
○ Average atomic distance 1
...
Gives split signal
Rule = number of H on neighbouring C plus 1
Proteins ^M Enzymes Page 20
Rule = number of H on neighbouring C plus 1
○ NMR of proteins
Aqueous samples of high concentration pure protein
Recombinant proteins easier to produce and can have active isotope labels added
Sample in buffered solution in thin walled glass tube
Measurement time varies
Most protons resolved in proton by 1D (deuterium) 1H NMR
H in water gives strong signal, so deuterated water must be used 2H2O (D2O)
We can study how bonds shift with pH etc
...
31JM-1K-1
• Free energy and equilibrium constant
○ At equilibrium ΔG = 0
0 = ΔG0' + RTln
R = 0
...
303RTlog10K'eq
Proteins ^M Enzymes Page 24
ΔG0' = -2
...
303RT = 10-ΔG0'/5
...
69kJ/mol
○ DHAP --> GAP during glycolysis
At equilibrium K'eq = 0
...
303RTlog10K'eq
= -2
...
008315x298xlog10(0
...
53kJ/mol
Endergonic - not spontaneous
When [DHAP] = 2x10-4 moles and [GAP] = 3x10-6 moles
ΔG = ΔG0' + RTln
= 7
...
303RTlog10
=7
...
41kJ/mol
= -2
...
g
...
01-1
...
○ Units of k = s-1
• If 2 substrates then 2nd order
○ A+B --> P
○ V = k[A][B]
○ K = M-1s-1
○ Sometime appears to be 1st order
One S may be saturating, so doesn't appear to affect the rate
• At high [S] a reaction may appear independent of [S] because E is saturated - 0 order
Multiple Substrates
• Most biochemical systems start with 2 substrates and yield 2 products
• Can be classified sequential or double displacement
• Sequential
○ S bind with E to form ternary complex before product released
○ Binding ordered or random
○ Many enzymes binding NADH exhibit ordered sequential
○
• Double-displacement
○ 1 or more products released before all substrates bind
○ Defining feature is formation of a substituted enzyme intermediate in which the enzyme is temporarily
modified
○
Allosteric Enzymes
• Don't follow M-M rules
• Consist of multiple subunits and active sites
○ Binding of substrate influences active site for other substrate to bind
• Show sigmoidal not hyperbolic V0/[S] plot
○
Proteins ^M Enzymes Page 30
Enzyme Inhibition
21 October 2015
12:10
• Small molecules/ion bind with enzymes
○ Inhibitory
○ Enzyme-substrate complex
• Variety of uses
○ Biological control
○ Medicinal control
○ Toxic attack
• Vital info about mechanisms
• 2 classes
○ Irreversible
○ Reversible
Irreversible Inhibitor
• Dissociates very slowly from target
○ Bind tightly
• Bound covalently or non-covalently
• Drugs --> irreversible inhibitors
○ Penicillin
○ Transpeptidase (bacterial cell walls)
○ Aspirin
○ Cyclooxygenase - inflammation
• Cysteine residues vulnerable
Reversible
• Rapid dissociation
• Weaker binding
• Useful in design of drugs
○ Basis of 1st antibiotic
○ Sulphonamides and dihydropteroate synthase (DHPS)
• 3 main types
○ Competitive
EI complex formed
Inhibitor resembles the substrate
□ Binds to active site
Catalysis diminished
Can be relieved by greater [S] - increased apparent Km
Cancer drugs
□ Methotrexate resembles dihydrofolate reductase (nucleotide replication)
Ki (inhibition constant) = [I][E]/[EI]
□ Smaller ki = more potent inhibition
Vmax not changed - just need more substrate
□ Apparent Km (Kmapp) increased
Proteins ^M Enzymes Page 31
○ Uncompetitive
Anti-competitive inhibition
I binds to ES only
Slows catalysis
□ Slower P release
Forms ESI complex
No product
Lowered Vmaxapp
Increasing [S] has no effect
Few examples in single substrates
○ Noncompetitive
I and S bind to E
Proteins ^M Enzymes Page 32
I and S bind to E
□ Different binding sites
□ Simultaneous binding - no overlap
Proteins flexible
□ Alter shape of molecule
Reduces catalysis by reducing Kcat (molecules/sec)
□ Not formation of ES complexes
□ Proportion of E binding to S unchanged
Increased [S] has no effect
Lowered apparent Vmax
Km unchanged
Lowers functional [E]
□ dilution
○ Mixed Inhibition
Effects of inhibitor don't fall into the 3 categories
Inhibitor acts as
□ Non- or uncompetitive
□ Competitive inhibitor
Reduces
□ Binding of E and S
□ Kcat
Irreversible Inhibitors - Mapping the Active Site
• Determine catalytic groups
• Irreversible inhibitors can modify catalytic groups
• 3 groups
○ Group-specific
Covalently binds to a group, results in changed conformation
Proteins ^M Enzymes Page 33
○ Reactive substrate analogues
Resembles S
More reactive chemically
□ Binds to nearby amino acids so we can see
○ Suicide inhibitors
Normally resembles S
Binds in active site
Locks E into dead-end product
□ Covalent modification
Many drugs
Monoamine oxidase (neurotransmitter) inhibited by N,N-dimethyl propargylamine
○ Transition State Analogues
Substance mimics transition state
□ Potent inhibitors (Pauling 1948)
□ Geometry of transition state
Greater affinity for E
□ Lactone analogue of tetra-NAG
Isomerisation of L-proline to D-Proline
□ Proline racemase
□ Pyrrole 2-carboxylate transition state analogue
□
Proteins ^M Enzymes Page 34
Proteins ^M Enzymes Page 35
Catalytic Strategies - Covalent and Acid/Base
27 October 2015
10:05
• Substrate bound
○ Catalytic functional groups
○ 4 strategies
• Covalent catalysis
○ Active site binds covalently with substrate
○ Nucleophile (electron pair donor)
• General acid base catalysis
○ Proton donating or accepting
○ Not H2O as a donor
• Catalysis by approximation
○ Bringing reactive substrates together
• Electrostatic/metal-ion catalysis
○ Redox reactions and/or increased binding energy
Proteases
• Cleave proteins - hydrolysis
○ Addition of water molecule to peptide bond
○
• Hydrolysis of peptide bonds is thermodynamically spontaneous
○ Reaction very slow - 10-100s of years without catalyst
○ Milliseconds in presence of an enzyme
• Nucleophilic attack of the carbonyl group
• Families of proteases
○ Single amino acid substitution studies
Importance of certain amino acids in catalytic group
○ 4 major functional groups of proteases
Defined in relation to active moieties
Serine
Covalent and acid/base
Cysteine
Covalent and acid/base
Aspartate
Covalent and acid/base
Metalloproteases Electrostatic and metal-ion
○ Serine proteases - Chymotrypsin
Breakdown of protein in the digestive tract
Cleaves peptide bonds selectively
□ Carboxyl terminal side
□ Large hydrophobic amino acids
Covalent/acid-base catalysis
Nucleophilic serine attacks unreactive carbonyl carbon of substrate
□ Binds covalently
Chromogenic substrate (easy to monitor colour change)
□ Kinetics - evidence to catalytic serine
□ N-acetyl-L-phenylalanine p-nitrophenyl ester
Hydrolysed to yellow p-nitrophenolate
□ Under steady state conditions obeys M-M kinetics
Km 20µM Kcat 77s-1
□ Stopped flow method
Initial burst of colour
Followed by slower release rate to eqm
□ Indicates 2 step reaction
Step 1 - nucleophile in enzyme attacks peptide bond; split off c-terminal half, N-terminal half
bonded to enzyme
...
◊
Decreased overall ΔG
Enzyme-protein attachment
□ Chymotrypsin-substrate peptide
Groove on surface
Proteins ^M Enzymes Page 36
Decreased overall ΔG
Enzyme-protein attachment
□ Chymotrypsin-substrate peptide
Groove on surface
□ Weak H bond forms between groove amino acids and substrate
□ Strong binding of target residue
Adjacent side chain fits into S1 hydrophobic pocket, lining target residue up with active site
Specificity depends on amino acid directly N-terminal side of the bond
□ S1 pocket explains specificity
Chymotrypsin's catalytic group
□ Catalytic triad
3 residues
□ Aspartate 102
-ve charge
Isolated from exterior
□ Histidine 57
+ve charge
Weak base
□ Serine 195
Hydroxy side chain - nucleophilic
Required to lose a proton (his57)
□ H-bonding
Serine side chain to his imidazole ring
Imidazole ring to carboxylate of asp
□ His57 orientate ser195
Polarise hydroxyl group
Alkoxide ion
□ Asp102 orientate his57
Improved proton acceptor
Chymotrypsin mechanism step 1
□
□ Fast burst
□ Cooperative action of the triad
First transition state
□ His57 acts as a base
Removes a proton from ser195
□ Nucleophilic ser195 attacks the C=O of the substrate
□ -ve Asp102 stabilises the +ve charge of His57
Oxyanion hole (stabilises negative charge on substrate created by tetrahedral binding of C)
◊ Strong H bonds
◊ Helps reach transition state 1
□ Transition state breaks up
His57 acts as acid
◊ Donates proton
◊ N-H group on substrate
Peptide bond
C-terminal half free to leave
N-terminal bound to Ser195
Proteins ^M Enzymes Page 37
N-terminal bound to Ser195
Chymotrypsin mechanism step 2
□
□ Water enters active site
c-terminal removed
Hydrolysis of ester
□ His57 acts as base
Steals proton from water
Produces nucleophilic OH◊ Attacks carbonyl
His general acid catalyst
□ Unstable tetrahedral transition state
Breaks up - HisH+57 acting as acid
Donates proton back to ser195
□ Breaking Serine-substrate bond
□ N-terminal half of S carries target aa as new c-terminal
□ Formation of carboxylic group
Moves C=O
□ Enzyme recharged
Proteins ^M Enzymes Page 38
□ Enzyme recharged
Importance of pH
□ Effective His57
pKa of 6
...
1mM
Enhances specificity and binding energy (-ve charge)
○ Approximation excludes water
Successful transfer requires no H2O
□ Phosphorylates more easily than NMPs
Induced fit binding
□ P-loop closes - structural change
□ Fold over and holds phosphate
○ Other uses of approximation
Enzyme serves as template
□ Bind substrates
□ Close proximity in reaction centre
NMP kinase
□ NMP and NTP
□ Stabilises transition state
Bring substrate into contact with catalytic group or other substrate
□ Increased encounter rate
Freeze translational and rotational motion
Proteins ^M Enzymes Page 42
Enzyme Regulation
03 November 2015
10:08
• Enzyme activity
○ Regulated
○ Ensures function at time and place
• Regulation essential
○ Coordination of biochemical processes
• Taking place all the time and in all organisms
5 strategies
1
...
Isoenzymes
○ Multiple forms - different Km and Vmax
3
...
Zymogen
○ Proteolytic cleaving - inactive form
5
...
Allosteric Control
• Control by
○ Binding an effector molecule
○ Allosteric site
• Distinctions
○ Regulatory/allosteric site
○ Catalytic/active site
• Allosteric and catalytic subunits (4o structure)
○ Separate polypeptide chains
• Allosteric effectors
○ Positive effect - Activators
Enhances attraction
□ Substrate or other catalytic site
Not limited to enzymes
□ O2 and haemoglobin
□ Substrate and effector
Binding to one subunit
□ Conformational change
□ Interacts with remaining active sites
□ Enhance O2 affinity
□ Cooperation efficiency
□ Hb allosteric activation
4o structure consists of 2 alpha, 2 beta
Binds O2 - left Fe atom, electron rearrangement, fits closer into molecule, tugs His
His protein chain - alpha helix, 15o rotation
Binding O2 - alters interface, additional O2 binding (20 fold increase)
○ Negative affect - Inhibitors
Binding of effector reduces affinity
O2 affinity in pure Hb much higher than in blood - O2 released more from blood into cells
2,3-bisphopshoglycerate
□ Binds to allosteric site on Hb
□ Reduces affinity to O2
Feedback mechanisms
Proteins ^M Enzymes Page 43
Feedback mechanisms
□ Preferentially to deoxyhaemoglobin
□ Structurally unmodified
ATCase - feedback control
□ Aspartate transcarbamoylase
2 regulatory chains
3 catalytic chains
□ Catalyses 1st step in pyrimidine synthesis
□
□
□
□
□
□
Condensation reaction
Committed step is the ultimate formation of nucleotides
ATCase inhibited by CTP (cytidine trisphosphatase) - end product
CTP structurally different to active site - not competitive inhibitor
PALA analogue used to test effects (competitive inhibitor
2 4o states (with and without PALA) - mechanism of regulation
□ 2 models
Enzyme either tense or relaxed
◊ Relaxed binds S more readily, T has lower affinity
◊ T much more compact, relatively inactive - equilibrium state of ATCase favours T
(factor of 200)
◊ PALA causes shift to R
◊ CTP favours T, carbamoyl phosphate and aspartate favour R
Concerted Model
◊ Enzyme subunits all connected
Conformational changes conferred to all
◊ All R or all T
Sequential
◊ Subunits less connected
Varying states
◊ Effector
Induced fit to sequential changes
Influences other adjacent subunits
Change state and increases affinity
Combination of models generally the case in practice
2
...
Reversible Covalent Modification
• Covalent attachement
○ Another moelcule modifies enzume activity
• Donor molecule
○ Functional moiety
○ Enzyme properties
• Most common types
○ Phosphorylation
○ Acetylation
• Regulation of acetyltransferase and deacetylase
○ Regulated by phosphorylation
• Most are reversible
• Phosphorylation
○ Most common regulatory mechanism
Intracellular proteins
30% eukryotic protons phosphorylated
Reversible
Enzymes/membrane channels
Proteins ^M Enzymes Page 45
○ Enzymes/membrane channels
○ Catalyse reactions
500 kinases in humans
Kinome
Multiplicity - fine tuning metabolism
○ Transfers terminal g phosphate group
Ser and Thr
Tyr
○ Phosphatase
Catalytic removal of phosphate group
Trn off signalling pathways (activated by kinases)
○ Phosphorylation and dephosphorylation
Essentially irreversible reactions under physiological condition
Without enzymes = negligible
○ Phosphorylation only when
Specific kinase
ATP cleavage
○ Net process of 2 reactions
Hydrolysis of ATP
ADP + Pi
Highly favourable (free energy) - unidirectional
• Phosphorylation is a highly effective means of control
○ Protein activation - structural/thermodynamic/kinetic/regulatory
○ Negative charge
Addition to protein - new electrostatic interactions
After substrate binding/catalytic activity
○ Hydrogen bonds
Phosphoryl group increases H bond formation
Tetrahedral geometry
○ Free energy
Increase free energy of enzyme
Changing conformational state
○ Rapid - less than 1 second, but can take hours if needed
○ Highly amplified effects
Reaction amplified
Single t hundreds
Activation of enzymes
○ ATP cellular currency
Links energy states
Enzyme activity
Regulation of metabolism
• Protein kinase specificity
○ Dedicated protein kinases - single protein
○ Multifunctional protein kinases
Protein kinase A
Many proteins
Coordination
Proteins ^M Enzymes Page 46
Coordination
○ Determination of specificity
Sequence surrounding Ser or Thr
Consensus
□ Arg-Arg-X-(Ser/Thr)-Z
□ Variations
□ Distant residues
Activation of protein kinase A
□ PKA - covalent/allosteric
□ Fright, fight, flight reaction
Adrenaline
Adrenaline triggers cAMP formation
◊ Intracellular messanger
cAMP activates PKA
◊ Altering of 4o structure
◊ Phosporylation
□ PKA is a holoenzyme - subunits R (regulatory) and C (catalytic)
Without cAMP R2C2 structure
cAMP causes dissociation to R2 and 2xC
R chain pseudosubstrate - blocking C active site
4
...
l
• Digestive enzymes
○ Pepsinogen --> pepsin
○ Trypsinogen --> trypin
○ Proelastase --> elastase
• Zymogen systems
○ Blood clotting
Cascade of zymogen conversions
Rapid response
○ Hormones
Transcribed as zymogens
Proinsulin - activated by cleavage
○ Collagen
Major bodily constituent
Transcribed as procollagen
○ Developmental stages
Metamorphosis
Parturition (uterus post-birth)
Proteins ^M Enzymes Page 47
Parturition (uterus post-birth)
Rapid breakdown of collage
Procollagenase
○ Apoptosis
Programmed cell death
Conversion of procaspases
• Chymotrypsinogen Activation
○ Synthesised by pancreas
Acinar cells
Membrane bound granules
○ Single polypeptide chain
No enzymatic activity
○ Converted to pi-chymotrypsin
Arg15-Ile16 cleaved (by trypsin)
□ N-terminal Ile16 turns inwards, forms ionic bond with Asp194
□ Electrostatic changes causes met192 to move to the surface
□ S1 pocket formed (specificity)
□ Shifts form oxyanion hole
○ Pi-chymotrypsin acts on itself
Dipeptides (146 and 149, 13 and 16)
○ Results
Fully activated alpha-chymotrypsin
Three polypeptide chains linked by disulphide bridges
○
• Common activators
○ Uidenum - concurrent activation
○ Digestion of proteins and blood clotting
Switching numerous enzymes/proteins simultaneously
○ Common activator
Coordinate control
○ Food enters duodenum
Enteropeptidase
Hydrolysis lys-Ile bond in trypsinogen
○ Pancreatic trypsin inhibitor
Zymogen activation irreversible
Lies in active site
□ S1 pocket
□ Maximum inhibition
Other inhibitors
□ Inhibit common activator
□ Rapid enzyme turnover
Tight binding of inhibitor
Proteins ^M Enzymes Page 48
Tight binding of inhibitor
□ Haemorrhaging
□ Tissue necrosis
□ Pancreatitis
Proteins ^M Enzymes Page 49
Protein Folding
10 November 2015
10:06
Primary Structure of Bovine Insulin
•
•
•
•
•
•
•
Secreted in beta-cells in islets of Langerhans
Signal of high blood glucose
2 chains
Linked by disulphide bonds
Secretion directed by signal peptide
Extensively processed in the Golgi
Domains: Glyceralderhyde-3-phosphate dehydrogenase
○ G-3-P binding
○ NAD+ Binding
○ Large polypeptides >200 amino acids divide into domains
○ Each domain is distinct, with defined combination of secondary elements
○ Domains linked by loops
Christian B
...
, Christian Anfinsen
○ 1957 Science 125 691-692
○ Reductive cleavage of disulphide bridges in ribonuclease
Ribonuclease A
Hydrolyses RNA to ribonucleotides
Tight core of beta-sheets
4 disulphide bridges
○ Result
8M urea disrupts H bonds and hydrophobic interaction
Beta-mercaptoethanol (reducing agent) disrupts disulphide bonds
□ If urea is and BEM are removed at the same time the native state is achieved
□ If BEM is removed first disulphide bridges form incorrectly
Can be renatured by addition of trace amounts of BEM
Anfinsen's Thermodynamic Hypothesis
Proteins ^M Enzymes Page 50
Anfinsen's Thermodynamic Hypothesis
□ Each unique 1o structure is key for a defined final conformation
□ 1o structure determines higher order protein assembly
○ Anfinsen's work showed that proteins can adopt their native conformation spontaneously
Sequence determine structure
Forces driving protein folding
1
...
1 kJ/mole), but proteins have many atoms so cumulative effect is important
2
...
3
...
Hydrophobic interactions – crucial in protein folding, hydrophobic core, “oily centre”
...
Disulphide bonds (some proteins only, dependent on intra/extracellular environment
...
Small chaperones <300kDa
○ Grabs exposed hydrophobic regions
○ Bind and release
○ Prevents aggregation
2
...
coli, highly conserved
DnaJ binds to unfolded protein then to DnaK
DnaJ stimulates ATP hydrolysis by DnaK
GrpE stimulates ADP release (Bacteria)
• Chaperonins
○ GroEL
Hsp60 - 14 protein complex
Binds ATP/Adp
2 halves - 2 cycles at the same time
Anfinsen Cage
○ GroES cochaperone - 7 subunits in ring matching GroEL
Forms cap and enlarges cavity through conformational changes to GroEL
○
• Hsp90 - steroid hormone receptors
Proteins ^M Enzymes Page 54
• Hsp90 - steroid hormone receptors
○ Regulatory functions
○ Increased during stress
○ Cytosolic and ER forms 82-94kDa
○ Reversible binding with target acts as on/off switch
○ Regulates wide range of functions
Proteins ^M Enzymes Page 55
Protein Targeting
17 November 2015
10:28
• Problem of protein localisation
○ Eukaryotic cell contains 5x109 proteins
○ 105 different proteins
○ Different proteins in different organelles
○ Different 1/2 lives
○ Must be targeted throughout cell
Pulse-chase labelling
• Palade 1975
• Irradiate proteins and trace through secretory pathway
• Proteins for export always synthesised on ER polysomes
○ Never completely form in cytosol
• Palade Pathway through ER, Golgi, Vesicles, Release
•
•
• Endoplasmic reticulum stacks of flattened cisternae
○ RER abundant in secretory cells
○ Ribosomes must bind to ER if secretory protein, remain in cytosol if not
Signal Sequence
• Tell ribosome whether to associate with RER or remain in cytosol
• 1st sequence = signal sequence
○ Hydrophobic
• Cleavage site - signal sequence removed
Microsomes
Proteins ^M Enzymes Page 56
Microsomes
• Pulp up ER - breaks into smaller vesicles
• Proteins within microsomes won't be digested by protease addition
• Add detergent - permeable membranes - proteases can digest proteins
• Translocation coupled to translation
○ Cell-free protein synthesis
Contains ribosomes
RNAse to remove RNA
○ Can add RNA and produce protein of choice
○ Give RNA for secretory protein
Complete protein will not move to microsomes added afterwards
Signal sequence not enough to determine
○ If microsomes present during translation, ribosome moves and protein ends up in
microsome (with signal sequence removed)
Signal Recognition Particle
• SRP
• Lots of proteins
• RNA backbone
Translocation into ER
• SRP binds signal sequence
• SRP receptor in membrane
• Translocon through membrane
• Signal peptidase inside membrane cleaves signal sequence
• GTP driven
• Chaperones inside ER
○ BiP binding protein - bind and release mechanism
Topology of Membrane Proteins
• Type I
○ Glycoprotein, insulin receptor, growth hormone receptor
○ Same mechanism
Transmembrane helix stop transfer anchor
Hydrophobic
Shuts down translocon
Holds protein within membrane
○ NH3+ terminal inside, COO- cytosolic
Proteins ^M Enzymes Page 57
○
• Type II
○ Asialoglycoprotein receptor, transferin receptor
○ COO- inside, NH3+ outside
○ Enter through translocon
○ Signal peptide within sequence - signal anchor
○ Anchored within membrane and extruded sideways
○
• Type IV
○ Multiple loops/helices through membrane
○ COO- or NH4+ on either side
○
• Determined by location and order of stop transfer, signal, anchor segments
• Hydrophobic (Leucine L, Isoleucine, Valine V)
○ Hydrophobicity plot - +ve = more hydrophobic
Mitochondrial Uptake
• Proteins synthesised in cytosol
○ Uptaken if mitochondria then added (unlike ER)
• Translocons at each membrane
○ Translocons conjugate to 'skip' intermembrane space
○ Chaperone proteins within membrane
Proteins ^M Enzymes Page 58
•
Chloroplast Targeting
• 3 membranes
• Stromal import signal cleaves
• Thylakoid targeting sequence
○ Chloroplast SRP
Similar to ER insertion
○ Or twin arginine transporter
Different to all other translocons
More like sphincter - monomer recruited or shed from membrane to change size
Allow proteins of various sizes through - already folded
□ Protein must be folded around metal ions to enter thylakoid
□ Twin arganine (R) recognised - sphincter dilates as much as needed
□ Signal removed inside thylakoid
○
Proteins ^M Enzymes Page 59
Bacterial Translocation
• Sec dependent
• Translocon pumps through
• Sequence cleaved
• Lipoproteins
○ Type II signal sequence
○ Lipid groups added
○ Sequence cleaved
• Type III Sequences
○ Pushes through plasma membranes
○ Similar to flagellum
○ Push proteins down core
○
Prediction of Localisation/Targeting
• Known sequences can be used to predict
Protein Modification
• Post translational
• Normal coincident with targeting
• Only proteins with disulphide bonds are secretory (ER, Golgi)
• Ubiquitination
• Pyrrolysine and selenocysteine
• Phosphate groups
• Glycose
• Acyl groups
• Lots of important functions
○ Carboxylated glutamate important in clotting
○ Failure to g-carboxylate due to vitamin K deficiency
• Hydroxylation stabilises collagen fibres
• Sugar coating
○ Recognition sites
○ Shield protein surface - protection from protease and non-specific interaction
○ Increased solubility - less aggregation of new glycoproteins
• N-linked glycoprotein sugars
○ Core created in cytosol
○ Flipase flips through membrane
Hydrophilic sugars, mechanism not understood
○ Further sugars added in ER
○ Some sugars act as timers
Fall off, cell recognises degraded cells
• Spontaneous glycosylation
Proteins ^M Enzymes Page 60
• Spontaneous glycosylation
○ Accumulate sugar
○ More likely with age
GPI Anchor
• Amphipathic molecule
○ Hydrophobic and polar regions
• Made independently of protein in membrane
• Protein enters into lumen
○ Signal sequence cleaves and protein bind to anchor
Proteins ^M Enzymes Page 61
Experimenting with Proteins
24 November 2015
10:06
Proteins ^M Enzymes Page 62
Solving Structures
24 November 2015
10:06
Protein Structure Determination
• 2 main methods
○ NMR spectroscopy
○ X-ray crystallography
• x-ray crystallography requires protein to be crystalline
○ Very difficult
○ Most proteins don't crystallise
○ 39,000 structures mapped
• NMR can be performed on proteins in solution
○ Data analysis very hard
○ 6,000 structures mapped
How to determine structure
• Primary methods
○ x-ray crystallography
○ NMR spectroscopy
○ Cryo-electron microscopy
• Secondary methods
○ Circular dichroism
○ Fluorescence
○ Neutron scattering
Cryo-Electron Microscopy
• Sample flash frozen - liquid ethane
• Solvent not given time to form ice crystals
○ Obtain snapshot of sample in solution
• 2 approaches
○ 2D crystals
2D layer forms
Tilted and snapshots taken
3D image built up from different angles
○ Image reconstruction
Proteins don't always form flat layer - random aggregations
Many photos taken at different angles
Common features used to identify the same regions
Can be wrong, giving incorrect proteins
How Accurate are the structures?
• Resolution of structure
○ Measure of how many data collected
• More data - greater ratio of observations to number of atomic coordinates to be determined in principle the greater accuracy
• Resolution in Angstroms
○ Lower number greater accuracy and level of atomic detail
• Hydrogen atoms visible at 1
...
5 Å
2Å
1
...
confirmations
Proteins ^M Enzymes Page 63
confirmations
Orientation of peptide planes
-
-
Fair
Good
Very good
Protein hydrogen atoms visible?
-
-
-
-
Very good
• NMR and x-ray crystallography <1Å-5Å
• Cryo-EM >5Å, usually ~10Å
X-Ray
NMR
Cryo-EM
Sample Size
Almost all
< 40kDa
Sample
Composition
Non-aggregated, crystalline,
not good with floppy or
disordered structures
Pure but in solution specialised Pure, frozen in solution
...
Liganded
Sometimes
Yes, arguably a better way to
study interactions
Yes, although small molecule
ligands are unlikely to be seen
...
> 5Å, usually higher (10Å - 20Å
...
<1 Å - 5Å
Circular Dichroism
• UV radiation
○ Chiral molecules/structures
• UV polarised
○ 2 circular waves
○ Rapid alternation
• Difference in absorption measurable
○ 200nm
○ Structures
• Deconvolute spectra
○ Fractions of helix, sheet, and 'coil'
Proteins ^M Enzymes Page 64
Handling Proteins
24 November 2015
10:06
Extraction/Purification
• Source material/tissue
○ Often limited in amount
○ Yield important
• Extraction of crude protein
○ Physical release of protein from cells
○ Time consuming and harsh
• Protect from denaturation
○ Extremes of heat and pH
○ Keep on ice (4oC)
○ Extraction buffer
• Protect from proteases
○ Protease inhibitors
• Physical separation
○ Relies on properties
○ Solubility, size, activity, stability (pH/oC), isoelectric point
Ammonium sulphate precipitation, reverse phase HPLC Solubility
Isoelectric focussing, ion exchange chromatography
○ Gel filtration, size exclusion chromatography, PAGE
pI/polarity
Size
Heat denaturation
Stability
Affinity chromatography, zymography
Activity
• Precipitation
○ Alter nature of a solution
Salt
Organic solvent
Changing pH
○ Low Salt
Protein solubility increases
Salting-in
○ High salt
Protein solubility decreases
Salting-out
○ Addition of an organic solvent
e
...
acetone
Decrease of dielectric constant
Decrease in protein solubility
Denaturation in some case
○ Changing pH
Related to functional groups
Isoelectric point crucial
Trichloroacetic acid (TCA)
Will probably denature
Normal Phase/Reverse Phase Chromatography
• RP
○ Resin in column
Stationary phase
Non-polar
○ Solvent
Mobile phase
Proteins ^M Enzymes Page 65
Mobile phase
Polar
Contains proteins
○ Non-polar protein favours stationary phase
○ Polar washes out in solvent faster
○ Less polar solvent stepping - different proteins washed out
○
• NP
○ Non-polar mobile phase
○ Polar stationary phase
Isoelectric Point
• pH gradient
• Current run through
• Proteins move according to charge
○ Positively charged move to negative end
• pH alters charge of proteins
• At isoelectric point no net charge, no movement through gel
•
Ion Exchange Chromatography
• Anion exchange
• Immobilised cation surface
• Mix of amino acids carried through in solution
• Negative residues immobilised on surface
• Positive residues carried through with solution
• Can change pH to alter charge and release
• Can use positive resin
Proteins ^M Enzymes Page 66
•
Size-Exclusion Chromatography
• Small proteins interacts with beads
• Large proteins don't, and pass through faster
• In complex mixtures of sizes
○ Size exclusion makes mixtures less complex
Differential Centrifugation
Affinity Chromatography
• Antibodies on column
• Appropriate proteins bind
• Elute unbound
• Only protein of interest left
Proteins ^M Enzymes Page 67
• Can have enzyme bound to column
○ Glutathione (GSH)
○ Enzyme has affinity for ligand
○ Can elute with the same enzyme
Confirming it's Worked
• Quantify the purification
○ Total amount of protein (start)
○ Total amount of target protein (end)
• Total protein
○ Assays
○ Lowry's, bradford, Absorbance280
• Target protein
○ Specific assay
○ Antibodies
• Yield = % target protein remaining
• Enrichment = increase in proportion of target within membrane
○ 1/20h --> 1/5, enrichment of 4
Combined With Genetics
• 6His binds to nickel
○ Engineer a gene to make a 6His-tagged protein
• Allows affinity purification
○ Immobilised metal affinity chromatography IMAC
Purity
• Proportion of mixture
• Contaminants
• Polyenylamide gel electrophoresis
○ PAGE
○ Cheap and easy
○ SDS gives -ve charge
○ Proteins migrate
○ Based on size
• Can be 2D process
○ Separate by pI
○ Run SDS PAGE
○ If proteins same size PAGE shows 1 band
2D shows them as separate
Proteins ^M Enzymes Page 68
○
2D Staining and Analysis
• Coomassie >75ng
• Silver staining >5ng
• Fluorescent staining >5ng
Zymography
• Impregnate gel with substrate
• Run gel
• Incubate at appropriate temp (e
...
37oC)
• Bands of clearing
○ Staining coomassie blue
○ Active proteins digest
•
Quantifying
• Software identifies and compares spots
Western Blotting
• Run gel
• Transfer to membrane
• Attach antibodies
○ Target protein
• 2o antibdy with enzyme
○ Colour change
Proteins ^M Enzymes Page 69
•
Proteins ^M Enzymes Page 70
Identifying Proteins
25 November 2015
12:10
Mass Spectrometry
• 2 common approaches
○ Peptide mass fingerprinting
○ Tandem sequencing
• Proteomics
○ 2D gel
○ Protein of interest identified
○ Chop up with trypsin
○ Put peptides into MS
○ Database finds protein from m/z
Peptide Mass Fingerprinting
• Peptide fragments
• Separated by mass
•
Tandem Sequencing
• Individual peptide fragments
○ 1 through
• Interact with inert gas - fragments
○ Separate and detect
• Compare with database
• Fragment at different points along peptide
• B or Y
• Gives sequence information and masses
Proteins ^M Enzymes Page 71
•
Proteins ^M Enzymes Page 72
Researching Proteins
01 December 2015
10:03
Proteins ^M Enzymes Page 73
Russ Morphew - FhGST-S1
01 December 2015
10:03
Fasciola hepatica Glutathione Transferase - Sigma class protein 1
Liver Fluke
• F
...
1-50
...
waste
○ Source of damage?
• Eggs
• Surface
○ Outer coat
○ Protection
○ Antibodies
• Drugs
○ How they work
○ How new drugs work
○ New vaccines focussed on targets
GSTs
• Glutathione transferase
• Phase II detoxification
I
...
Conjugation - adhere molecules covalently onto xenomolecules, more water soluble
III
...
a
...
Sigma class not identified before
...
coli - expressed sigma GST
○ Purified
• In situ expression
○ Got antibodies by infecting rabbits
○ 1D gel, probed with anti-GST antibodies
Heavily expressed in eggs and juvenile, present in adult and adult excretion
Immuno-localisation
• Liver and bile ducts
• Testes free of protein
• Surface free (but near)
• Heavily in ovaries/eggs
Function?
• Activity rFhGST-S1
○ Model system substrates
○
○ Lipid peroxide metabolism
Detoxification of worm
○ Inhibition (conc
Title: Proteins and Enzymes
Description: Second year Proteins and Enzymes module, taught by Russ Morphew. Covered protein structures, thermodynamics, catalysts, folding, targeting, and experimenting.
Description: Second year Proteins and Enzymes module, taught by Russ Morphew. Covered protein structures, thermodynamics, catalysts, folding, targeting, and experimenting.