L1 Define Bronsted acids and bases!
acid: proton donor
base: proton acceptor
L1 Define Lewis acids and bases and compare this to the Bronsted concept!
acid: EP acceptor
base: EP donor
includes Brønsted acids/bases but also metals
L1 Define the terms nucleophile and electrophile!
nucleophile: EP donor
electrophile: EP acceptor
L1 Describe the mechanism of electrophilic addition of acid-catalyzed hydration of 2-methyl- propene!
double bond attacks proton -> carbocation formed (Markovnikov!)
EP of O of water attacks
proton cleaved -> alcohol formed
L1 Compare the two major nucleophilic substitution reactions regarding formed intermediates and the type of substrates!
SN1
SN2
steps
2 steps: cleavage & attack
1 step
reaction course
intermediate (stable)
transition state (unstable)
dependent on nucleophilicity of substrate
no
yes
carbons
primary & secondary
tertiary
inversion of steric centrum
no, racemates
L1 Name the two major groups of compounds bearing a carbonyl group and compare their reactivities!
aldehydes & ketones
carboxylic acids
negative charge stabilised?
leaving group
ususally no
L1 Order the following compounds according to their reactivity starting with the most reactive species: thioester, amide, acyl phosphate and ester! Draw the functional group for each compound!
acy phosphate > thioester > ester > amide
L1 Name three mechanisms of elimination reactions and draw one of those explicitly!
E1
E2
E1cb
2 steps: ionisation, deprotonation
2 steps: leavig groups leaves, deprotonation
base
weak/no
strong
E1:
E2:
E1cb:
L1 Which proteinogenic amino acids exhibit predominantly a charged side-chain at pH 7?
negative: Glu, Asp
positive: Arg, Lys, His
L1 Which amino acids occurs most frequently in the active site of enzymes? Rationalize why this might be the case.
His: proton & electron carrier, stabilises charged residues
Cys: nucleophile, disulfide bonds
Lys: Schiff base
L1 Explain why cysteine is the most commonly occurring amino acid in covalent catalysis.
disulfide bonds -> can stabilise substrates
L2 Name common principles and differences between chemical and enzyme catalysts!
common principles:
enhance reaction rate (don’t affect equilibrium)
catalyst regenerated
enzymes:
milder reaction conditions
substrate specific
higher molecular weight
work in aquaous solvent
neutral pH
L2 Name five different chemical mechanisms of enzymes!
covalent catalysis
acid-base catalysis
electrostatic/nucleophilic catalysis
metal ion catalysis
proximity and orientation effects
transition state stabilisation, destabilisation of ground state
L2 Draw the reaction coordinate of an enzymatic reaction going from substrate to product via two intermediates! Indicate the free energy change of the reaction and the activation energy for the enzymatic reaction in comparison to the uncatalyzed reaction!
L2 What is the “orientation effect” in enzyme catalysis and provide an estimate for how large the rate enhancement can be in principle for an enzyme by properly orienting substrates?
enzyme orientates substrates to one another for the most effective reaction -> enforced orientation
rate enhancement: 5*10^7
L2 Describe an example where an enzyme physically distorts its substrate with an emphasis on bond activation and energy of the substrate!
thiamin (vitamin B1)
substrate: xylulose-5-phosphate
elongates bond that is later cleaved
L2 Describe the principle of ground-state destabilization and transition-state stabilization and provide an example for each!
ground-state destabilisation:
ground state is instable when bound to enzyme
ΔG of substrate is increased
example: orotidine monophsophate decarboxylase (orotidine moophosphate -> uridine monophsophate)
transition-state stabilisation:
enzymatic active site becomes complementary to transition state
G of transition state is reduced
example: citrate synthase (actyl-CoA + oxalacetate -> citrate)
L2 Describe the key steps and involved intermediates of the reaction mechanism of serine proteases!
catalytic triad
pKa of Ser changes by environment
mechanism:
L2 Compare a normal (ionic) hydrogen-bond with a low-barrier hydrogen bond and a single-well hydrogen bond! Name an enzyme where a low-barrier hydrogen bond is thought to be catalytically relevant!
hydrogen bond
low-barrier haydrogen bond
single-well hydrogen bond
O-H……..O
O……H……O
O..H..O
2.8 Å
2.55 Å
2.29 Å
example: serine protease
L2 Detail the currently accepted mechanism of lysozyme action!
?
L2 Name four different classes of proteases including one example for each and draw the mechanism for two families! Indicate where enzyme magics is required to catalyze chemically difficult steps!
serine protease: chymotrypsin
cystein protease: papain
aspartic protease: pepsin
metalloprotease: carboxypeptidase A
threonine protease: proteasome
mechanisms:
serine protease:
cystein protease:
L2 Compare proteases and esterases regarding their active site machinery and explain the differences!
esters are more labile and prone to ydrolysis -> less dependent on LHBH
esterases need Ser -> not always a catalytic triad
L2 Draw the mechanism of acetylcholine esterase! Name two classes of acetylcholine esterase inhibitors and explain how they function!
L3 Describe briefly the mechanism of phosphomutases!
transfer of phophate group within a molecule
addition of second phosphate group by already phosphorylated Ser (creation of biphosphate)
cleavage of original phosphate group -> rebound to Ser (dephosphorylation to monophosphate)
Abb. F.17
L3 Explain the term ‘isomer’! What types of isomerism are known? Derive a scheme for all types of isomerism. Provide examples (molecules or pairs of molecules) for the different types of isomerism!
isomer: same atoms but different order/steric orientation
constitutional
stereoisomers
same atoms, different connections
same atoms, same connections
pentane
2-methyl butane
diastereomers
enantiomers
not mirror images
mirror images
S-lactic acid
R-lactic acid
epimers
anomers
cis/trans-isomers
difference in one steroic centrum (but not the last)
difference in anomeric steric centrum
difference in double bond
glucose
mannose
alpha-glucose
beta-glucose
cis-2-butene
trans-2-butene
L3 Explain two different mechanisms of epimerases acting on sugar substrates!
NAD+ based: UDP-galactose-4 epimerase
NAD+ takes hydride from OH group
conformational change in protein flips chair
NAD+ brings hydride back
metal based: Ribulose-5-phosphate epimerase
metal ion stabilises enolate
cleavage of C-C bond
product is flipped and ligated again
L3 Name three different enzymatic reaction mechanisms used by racemases! Name one example each and name commonalities and differences between the three mechanisms?
PLP-depencdent racemases: Asp transaminase
PLP as cofactor
covalent bond by Schiff base
proline/glutamate racemase
two-base mechanism
two Cys as acid-base pair
metal racemases: mandelate racemase
Mg2+ -> lowering pKa
Lys, His
general mechanism:
deprotonation
stabilisation of negative charge
reprotonation -> random choice of isomers (racemate)
L3 Radical isomerases: name the two radical initiators cofactors including the mechanism of radical formation! Name one enzyme for each cofactor!
Cobalamin (vitamin B12): Gluamate mutase
S-Adenosyl methionine (SAM): Lysine-2,3-aminomutase
L3 Explain the two possible chemical routes for isomerization between aldoses and ketoses! Name one example each for an aldose-ketose isomerase using this mechanism! Name experimental strategies to distinguish between the two alternative mechanisms for a given isomerase! Which enzymatic reaction steps are particularly difficult to catalyze?
Abb. F.6
enolisation: acid-base catalyst exchanges protons with solvent (in D2O D will be incorporated)
hydride transfer: formally transfer of H-
L4 Explain possible chemical routes (4) to afford a decarboxylation of metabolites?
Abb F.50
A: TPP, PLP or pyrovoyl dependent, Schiff base intermediate
-> pyruvate dehydrogenase complex
B: leaving groups leaves, carbocation is formed, decarboxylation
-> mevalonate pryophosphate decarboxylase (MPP-DC)
C: leaving group in place where alpha-crabon would be, leaves with an electron pair
-> formate dehydrogenase
D: radical fragemntation, requires secondray electron transfer to create the radical center
L4 Compare thiamin diphosphate-dependent and PLP-dependent decarboxylases! Name commonalities and differences in the mechanisms! Describe how PLP enzymes control reaction specificity by stereoelectronic control!
L4 Explain the mechanism of pyruvoyl-dependent decarboxylations!
Abb. F.56
L4 Which reaction is catalyzed by acetoacetate decarboxylase? Draw the mechanism and explain the different functional roles of the two neighboring lysine residues!
Abb. F.58
Lys with lower pKa since it is in hydrophobic pocket
L4 Explain the catalytic strategy employed by mevalonate pyrophosphate decarboxylase!
L4 Name different suggested mechanisms for oritidine-5’-monophosphate decarboxylase! Which one(s) are supported or rules out by the experimental results?
L4 Explain the mechanism of pyruvate formate lyase (PFL) and of the required PFL activase!
L5 Draw the chemical structure of the nicotinamide ring of NAD(P) + in the oxidized and reduced NAD(P)H state!
L5 Draw the mechanism of hydride transfer in a NAD+ -dependent dehydrogenase that interconverts alcohols and ketones!
L5 Is hydride transfer in NAD+ -dependent dehydrogenases stereospecific? Explain the underlying mechanism and suggest an experiment that can prove or rule out stereospecific hydride transfer!
stereospecific: enzymes are either pro-S or pro-R
active site of enzyme only allows addition to one side
experiment: D instead of H on alcohol -> if D is always R/S the enzyme is stereospecific
L5 Draw the chemical structure of thiamin diphosphate and mark the reactive atom! Why is that particular atom so reactive?
L5 Draw the chemical structures of substrate classes of thiamin enzymes and indicate which bonds are susceptible to cleavage by thiamin!
L5 Draw the chemical structure of the central carbanion-enamine intermediate in thiamin enzymes and name two possibilities how reaction can progress from this state!
Abb.
dehydration: phoyphoketolase
redox/free radical chemistry: ferredoxin oxidoreductase
L5 Draw mesomeric structures of the alpha-carbanion derived upon PLP-assisted decarboxylation!
L5 Draw the chemical structure of PLP in covalent linkage with an alpha-amino acid for a PLP i) decarboxylase and ii) racemase!
L5 Draw the isoalloxazine ring system of flavin cofactors in the oxidized and two-electron reduced state!
L5 Name the two half-reactions typically catalyzed by flavoenzymes and provide an example!
oxidation: H-transfer, disulfide reaction
reduction: H-transfer, thiol oxidation
L5 Draw the structure of the biotin cofactor in resting and “cargo-loaded” state! Explain how cargo (substrate) is chemically activated in biotin enzymes?
L5 Draw the chemical structure of the pyruvoyl “cofactor” and name a reaction where this cofactor is acting!
L5 What are quinoproteins? Name two classes of these and the reactions they are typically catalyzing!
enzymes with quinones as cofactors
typical reactions:
alcohol dehydrogenase (PQQ: pyrolloquinoline quinone)
amine oxidase (TPQ: topaquinone)
L6 Write the Michaelis-Menten equation and draw the corresponding v-S plot highlighting Vmax and KM!
L6 Explain the terms and provide units for catalytic constant, Michaelis constant and catalytic efficiency!
Michaelis constant KM
mol/L
substrate concentration at 1/2 vmax
affinity for enzyme substrtae complex
catalytic constant Kcat
1/s
vmax/[E]T
number of conversions of substrate molecules persecond at one active site
[E]T enzyme concentration
concentration independent reaction velocity
catalytic efficiency Kcat/KM
specificty of enzyme to substrate
L6 Write the Michaelis-Menten equation of an enzyme displaying positive cooperativity and draw an associated v_S plot! Name a method to estimate the Hill coefficient! What is the Hill coefficient?
Abb. F.50
Hill coefficient: cooperativity of an allosterically binding molecule and subtrate
estimate Hill coefficient:
plot log(v_observed/vmax-V_observed) against log[S]0
slope=n
L6 Name different types of bisubstrate enzyme reactions! How can these different mechanisms be distinguished by appropriate kinetic experiments?
ordered sequential mechanism
random sequential mechanism
ping piong mechanism
Abb. F.22
L6 Explain how a competitive inhibitor is acting! Draw the corresponding v_S plot and the Dixon plot! Which kinetic constants are affected by a competitive inhibitor? Write the Michaelis-Menten equation for an enzyme reaction that is inhibited by a competitive inhibitor!
competes with subtrate for active site
Abb. F.24 + F.25
Km changes
vmax stays the same (time after which it is reached changes -> KM)
Michaelis-Menten: v0 = vmax*[S] / KMapp+[S]
KMapp = KM* ([I] / 1+KI)
L6 Explain how a non-competitive inhibitor is acting! Draw the corresponding v-S plot and the Dixon plot! Which kinetic constants are affected by a non-competitive inhibitor? Write the Michaelis-Menten equation for an enzyme reaction that is inhibited by a non-competitive inhibitor!
binds to different site than substrate
can bind to enzyme or enzyme substrate complex -> same affinity
prevents reaction to product but does not affect binding of the substrate
Abb. F.27
KM stays the same
vmax changes
Michaelis-Menten: V0 = vmaxapp*[S] / KM+[S]
vmaxapp = vmax / 1 + ([I]/KI)
L6 Explain how a uncompetitive inhibitor is acting! Draw the corresponding v-S plot and the Dixon plot! Which kinetic constants are affected by a uncompetitive inhibitor? Write the Michaelis-Menten equation for an enzyme reaction that is inhibited by a uncompetitive inhibitor!
binds to enzyme-substrate complex
Abb. F.31
KM changes
L7 Draw the reaction profile for an enzyme-catalyzed reaction and indicate the pre-steady-state and steady-state phases! Highlight the concentration profile for E (free enzyme), ES (enzyme-substrate complex), S (substrate) and P (product)!
Abb. F.9 (b)
L7 Name three different methods used for pre-steady-state analysis of enzyme reactions! Name the time regime that can be analyzed with each method, the type of reaction amenable for analysis and the signals/readout used! Explain one method in greater detail!
method
time regime
signal/readout
problems
stopped flow
0.5-2 ms
UV-vis,
diode array fluorescence,
CD,
FTIR
requires chromo-/fluorophor
quenched flow
2 ms
NMR,
EPR,
Mössbauer spectroscopy,
MS
discontinous method
temperature/pressure jump
ms-s
fluorescence
only for equilibrium
flash photolysis
ns-s
L7 Write the rate law for a first-order reaction and draw the corresponding progress curve!
L8 How is protein homeostasis maintained in eukaryotes?
homeostasis between:
protein synthesis
quality control
chaperoning system -> folding
proteasome -> degradation
L8 Name two major protein degradation pathways in eukaryotes.
ubiquitin-proteasome system (UPS) -> shorter lived proteins
>70% of protein degradation
protein marked by ubiquitin
degraded to petodes by proteasome
autophagy-lysosome and endosomal-lysosome pathway -> longer lived proteins, complexes, organelles
protein is enclosed in vesicle and degraded in lysosome
autophagy: proteins from inside the cell
endosomal: proteins from membrane, endocytosis
L8 Which cellular systems monitor protein folding?
chaperoning system
incorrect/partial folding can cause aggregates
Hsp70 folds partially unfolded protein protein correctly
Hsp104 separates aggregates into monomers
if those fail -> degradation by proteasome
L8 Name abundant AAA ATPase family proteins and their functions.
proteasome: protein degradation
p97: protein degregation
Hsp104: protein disaggregation
Spastin: microtuble disassembly
NSF: SNAREs disassembly
L8 Which amino acids are included in the pore-loop that interacts with extended polypeptides?
hydrophobic aas -> aromatic
e.g. Phe, Val
easier movement of peptide through loop -> grip on peptide
L8 Outline the mechanism by which AAA+ ATPases unfold substrates.
substrate pulled through cyclic polypeptide
ATP and “hands” (hydrophobic interaction: Phe, Val) to pull
ATP hydrolysis changes conformation of unfoldase -> substrate is pulled down
L8 What is the number of ATPase subunits required to constitute a proteasome ATPase motor?
6 subunits
spiral staircase
L8 Name three peptidase activities of the proteasome.
caspase-like -> after ASP
trypsine-like -> after basic aas
chemotrypsine-like -> after large hydrophobic aas (Phe, Tyr)
L9 For each of the enzyme classes (E1, E2, E3, and DUB) list the reaction educts and products.
For each enzyme class, list the names of the chemical reactions that are catalyzed by it.
enzyme class
educt
product
reactions
Ub
ATP
Ub~E2
PPi
AMP
adenylation,
thioesterification,
trans-thioesterification
E1~Ub (HECT) bzw. E2~Ub (RING)
E3
Ub~E3 + E2 -> HECT
UB~E2~E3 -> RING
E3~Ub (HECT) bzw. Ub~E2~E3 (RING)
S
Ub-S + E3 -> HECT
Ub-S + E2 + E3 (RING)
isopeptide bond formation
DUB
S-Ub
2 nucleophilic attacks,
hydrolysis, nucleophilic attack
-isopeptide
~thioester
L9 Define and draw the structural formula of an amide bond, peptide bond, and isopeptide bond?
Draw by a combination of cartoon (protein elements) and formula (decisive chemical bonds) a substrate protein that is ubiquitinated at a serine residue and at a lysine residue.
Abb. F.4
Ser: ester bond -> Ser-O-CO-Ub
Lys: isopeptide bond -> Lys-NH-CO-Ub
L9 Describe in what sense the E1-catalyzed reaction resembles a step during protein synthesis. What is the common principle that renders both reactions irreversible?
E1-catalysed reaction
Ub bound to ATP
PPi cleaved -> Ub activated
activated Ub transferred to E1
aa bound to ATP
PPi cleaved —> aa activated
activated aa transferred to tRNA
L9 Can you think of why the ubiquitination system may have evolved as a catalytic cascade (rather than single enzymes catalyzing ubiquitination)?
more options to regulate -> several levels
separation of steps -> reduced evolutionary cost
more specificity
L9 Ubiquitination sites on cellular proteins are typically identified by a trpysin-mediated digest of the sample followed by mass spectrometry. Use a cartoon representation of a ubiquitinated substrate to explain schematically which ubiquitin-derived digestion products are searched for.
Hint: You need to look up the amino acid sequence preference of trypsin and the amino acid sequence of ubiquitin.
Trypsin cleaves after Arg(R)/Lys(K)
LRLRGG motif at ubiquitin C-terminus
if Lys ubiquitinylated cleavage by trypsin is not possible
cleavage of Ub instead -> GG overhang stays
L9 What are specific challenges in developing PROTACs for therapeutic applications? Consider the molecule have to have, its dosage, and requirements with regard to the target protein and ligase?
PROTAC: adaptor between substrate and E3
should not be too long or big
Lipinskis rule of 5 for drugs to enter cell
small enough (>500 Da)
hydrophobic (cellular permeability logp < 5)
Hook effect: high dosgae could lead to only binding to one side
L9 If you had the opportunity to develop drugs against ubiquitin-system enzymes, which family would you choose and why?
more general, only 2 subtypes
ATP binduuing site can be exploited
E3:
more specific for targeting certain proteins
L9 Do you expect the ubiquitin system will furnish as many drugs as protein kinases and why? What are the fundamental differences between these groups of targets in terms of drug discovery?
kinases: ATP-binding site -> will work for E1 but not E3
for E3: block protein-protein interaction (difficult)
L10 Use the simplified Eyring equation:
k = kBT/H * exp(-deltaG / RT),
with kB as the Boltzmann constant, h the Planck constant and R the gas constant, to derive the predicted energy barriers for reactions with a k=1000 s-1, 1 s-1 and 0.001 s-1 at 300 K. Compare these energies and their differences to the strength of a hydrogen bond between two water molecules (~20 kJ/mol).
rearrange to:
deltaG = -RTln(kh / kBT)
L10 Discuss the differences between a “real” bond potential and a model harmonic potential.
real bond potential does not include bond breaking
L10 Why might it be difficult to computationally model metalloenzymes with molecular mechanics?
L10 For many systems, it has been postulated that the origin of catalysis comes from electrostatic transition state stabilization. Choose one example from previous lectures and discuss how this stabilization is specific to the TS. Can you find one or more reasons why this should be a particularly dominant feature in enzymatic catalysis?
L10 What experimental approaches could one use to assess whether electrostatic stabilization is the main catalysis factor? (you may again pick a system to discuss)
L10 Consider the following scenarios. In which cases would you deem simple MM studies applicable and in which cases do you believe QM/MM is required?
a) diffusion-controlled reactions
b) proton transfer reactions
c) elongated bonds/structural stress
d) stereoselectivity imposed through steric shielding
e) radical reactions
QM: too excact ->will take too long
MM: can’t model bond breaking or forming
a) MM
b) QM/MM?
c) MM
d) MM?
e) QM
L10 Give an example of an experimental method to track intermediates of an enzymatic reaction, and list its limitations.
About 40 different tRNAs are sufficient to decode 61 sense codons. Why is this possible and what is the molecular basis for this phenomenon?
genetic code is degenerated -> several codons for the same aa
Wobble base pair in third position
sometimes only one tRNA for several codons and same aa -> 1-2 Watson-Crick base pair/s the other/s is/are Wobble base pairs
Explain how the high speed and accuracy in translation is achieved. How long does it take to synthesize an average E. coli protein (333 amino acids)? Assuming an error frequency of 3x10-3, what is the probability that it is synthesized with a mistakes?
kinetic discrimination -> forward reaction favoured for right aa (faster)
initial selection step and proofreading step
last step of each is irreversible (GTP hydrolysis/peptide bond formation)
induced fit mechanism -> substrate induces conformational change in binding site that catalyses reaction
average frequency of bacterial translation: f = 14 1/s -> only elongation phase!
t = N/f
In an elegant experiment performed in 1962, a cysteine that was already attached to tRNACys was chemically converted to an alanine. These alanyl-tRNACys molecules were then added to a cell-free translation system from which the normal cysteinyl-tRNACys molecules had been removed. When the resulting protein was analyzed, it was found that alanine had been inserted at every point in the protein chain where cysteine was supposed to be. Discuss what that experiment tells you about the role of aminoacyl-tRNA synthetases and the ribosome during normal translation of the genetic code.
aminoacyl-tRNA-synthetase binds correct aa to tRNA with anticodon -> connection between genetic code and aa
ribosome does not have proofreading activity -> if incorrect aa bound to tRNA it is inserted
How is the energy of ATP and GTP hydrolysis utilized during translation? How is ATP/GTP consumption coupled to acceleration of protein synthesis? Which of the translation factors are GTPases? What is the role of GTP hydrolysis in translation?
ATP: energy for formation of peptide bond -> aa activated, then bound to tRNA
GTP: binding of large subunit to small subunit
GTPases:
eIF1A
eIF2
eIF5
eEFsec
eEF2
EF-Tu
EF-G
RF3
eRF3
SelB
GTP hydrolysis: energy for f. e. translocation
How do aa-tRNA synthetases recognize the proper tRNA and amino acid? How do they correct errors of amino acid recognition? Isoleucine and Valine are almost identical. They differ by one CH2 group. How do isoleucyl tRNA and valyl-tRNA synthetases discriminate between the two amino acids? The extra methyl group of isoleucine could be expected to provide -2 to -3 kcal/mol of free energy in binding; hence 1/100 would be the error frequency. What is the observed error frequency and how is it achieved?
recognition: ARS (autonomously replicating sequence) specific for aa and tRNA -> specific activation for aa, editing domain
error correction:
pre-transfer editing -> hydrolysis of wrong aa faster
post-transfer editing -> hydrolysis of wrong aa faster
Ile/Val: Val-pocket smaller, Ile:positioning effects
error frequency: 1:3000
In an in vitro translation system from Staphylococcus aureus, the model mRNA directs for synthesis of a protein that starts with amino acid sequence fMet-Phe-Thr-Ile… Three new antibiotics isolated by a company you are now working for inhibit the translation of the mRNA in a different way. Compound RI-333 inhibits synthesis of peptides that are longer than fMetPhe; formation of fMetPhe is not affected however. In contrast, compound RI-506 allows for synthesis of peptides that are 6-7 amino acids long, after which the synthesis is stalled. Finally, with the third compound, RI-700, many oligopeptides of different length are synthesized, but a large part of them does not have an expected amino acid composition. What can you suggest as to the mode of action of these antibiotics? How would you test your suggestions? What are the following steps to further develop these drug leads? What are the structural and functional differences between prokaryotic and eukaryotic ribosomes? What about mitochondrial ribosomes?
…
Which chemical reactions are catalyzed by the ribosome?
transfer of polypeptide chain from tRNA in P site to aa in A site formation of peptide bond -> catalysed by rRNA (no protein)
peptide release -> RFs contribute
(translocation -> catalysed by EF-G)
Which part of the ribosome catalyzes the peptide bond formation - the RNA or the protein? How would you address this question experimentally?
RNA
change residues in active center -> ribose to desoxyribose -> inhibits catalytic activity of RNa without changing structure
The ribosome is a molecular machine. Explain why.
definition: made from macromolecules, unidirectional movements, cost of external energy
ribosome translocates mRNA nd tRNA using GTP
Is the genetic code identical in all organisms? Is recoding and redefinition the same thing? Provide examples. Why is recoding used?
genetic code should be universal -> different codon usage within one organism (cytosolic and mitochondrial)
redefinition is a type of recoding
examples:
redefinition: Seleno-Cys (readthrough), stop codon is redefined as Sel-Cys codon
recoding: frameshifting
The company where you ordered the plasmid encoding for a mammalian gene for expression in E. coli suggests implementing the “optimal codon usage” for the coding region. What is that? Will you choose this option? You made a choice and tried to express the protein, but it does not express well in E. coli. Why do you think this might happen? What would you suggest to improve the expression level?
optimal codon usage: not using rare codons -> depends on organism
with optimal codon usage:
codons might impact speed of tanslation -> therefore folding
without optimal codon usage:
add tRNAs for rare codons
harmonize codons -> make codon usage frequency as similar to original organism as possible
What are the main steps in prokaryotes and eukaryotes initiation? Name some main differences.
prokaryotic:
IF3, IF2, IF1, fMezt-tRNAfMet, mRNA recruited (independently)
ORF (open reading frame) selected -> SD (Shine Dalgarno sequence) to aSD (anti-Shine-Dalgarno sequence)
fidelity checks through IFs
large subunit joins, GTP hydrolysis, IFs dissociate
eukaryotic: more IFs!
pre-initiation complex
one complex: some IFs, mRNa
another complex: initiator tRNa, some IFs
both complexes bind to small subunit
ORF found
large subunits binds, IFs released
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