which hydrogen bonds are stabilizing the secondary structure
Hydrogen bonding between the Carbonyl group and the amino group
between N-H and C=O of i and i4 of Helix
pair the Amino acids according to their function
hydrophilic (polar)
proton-donor/-acceptor
absorbs UV-light
is situated in the protein core (→ often hydrophobic)
A. Valine
B. Threonine
C. Tyrosine
D. Histidine
1 + B
2 + D
3 + C
4 + A
multiple choice: which steps of Glycolysis are exergonic and non-reversible
Glucose -> Glucose-6-phosphate
(Hexokinase)
Fructose-6-phosphate -> Fructose-1,6-bisphosphate
(Phosphofructokinase)
Phosphoenolpyruvate -> Pyruvat
(pyruvatkinase)
multiple choice: which molecule is crucial for glycolysis
ATP
NAD+
What is the initial reaction of the citric acid cycle? name the substrates and the product
Oxalacetate + H2O + Acetyl-CoA -> Citrate
During which step of the citric cycle is carbondioxide released?
Isocitrate + NADH + H+ + CO2 -> alpha-Ketoglutarate
(Isocitratdehydrogenase)
alpha-Ketoglutarate + NADH + H+ + CO2 -> Succinyl-CoA
(alpha-Ketoglutaratedehydrogenase complex)
Name the order in which the following molecules are synthesized in the citrat-cycle (citrate → oxalacetat)
Citrate
Isocitrate
alpha-Ketoglutarate
Succinyl-CoA
Succinate
Fumerate
Malate
Oxalacetate
Draw the cornish diagram for ternary complex and random bi-bi-mechanism ?
define how an uncompetitive inhibitor interacts with an enzyme. Does it bind to the free enzyme or to the substrate-enzyme complex?
The inhibitor binds only to the enzyme-substrate complex (ES) in what is essentially substrate-dependent inhibition.
explain mixed type inhibitors with examples
mix of competitve and uncompetitive inhibition
inhibitor binds either enzyme or enzyme-substrate complex
Ki and Ki’ are different
influence on KM and Vmax
example
alpha-amylase + starch -> maltose inhibitor: arcabose
succinate dehydrogenase + succinate -> fumarate
inhibitor: malonate
is ki=1nm strong or weak, explain why
strong -> binds tightly to the enzyme
Ki -> affinity of an inhibitor to its target
strong= nm, moderate= micromolar, weak= millimolar
Explanation of mode of action of an enzyme that reacts after the ping-pong mechanism (+example)
Double-displacement (ping-pong) reactions are characterized by the formation of a substituted enzyme intermediate.
two substrate mechanism
parallel lines at increasing concentrations of the second substrate
no ternary complex is formed
what does a competitive enzyme inhibitors do? Is kcat and km changed? Draw a linearization and indicate where ki is?
competitive inhibitor is structurally similar to the substrate and can bind to the free enzyme → prevent the substrate from binding
In competitive inhibition, Vmax of the enzyme is unchanged because the inhibition can be overcome by a sufficiently high concentration of substrate.
However, KM in the presence of inhibitor, called KMapp, is increased.
x-intercept: -Ki (Ki = dissociation constant of inhibitor)
Inhibitions and explanation
which strategys
what happens to KM and Vmax
competitive
inhibitor binds to the free enzyme
Vmax no effect
KM is increased
uncompetitive
inhibitor binds only Enzyme-Substrate complex
Vmax is decreased
KM is decreased
linear mixed
KM is increaased
noncompetitve
inhibitor binds enzyme or enzyme-substrate complex
KM no effect
Why is the pH relevant for acidic based reactions ?
catalysis often sensitive to pH changes (pKa)
acid-base reaction governed by sidechains
What is the definition of a catalyst
A Catalyst is a compound that takes part in a reaction by increasing the rate of the reaction without being consumed and without changing the chemical equilibrium of the reaction.
The reaction is accelerated by a reduction of the activation energy.
Name 4 different catalytic strategies by which enzymes decrease the activation energy of a catalyzed reaction
Acid base catalysis
electrostatic catalysis
metal ion catalysis
catalysis by approximation
covalent catalysis
covalent catalysis: Which AA can be used for covalent catalysis? Draw 1 modification
serine 195 is one of 28 serine residues in chymotrypsin
Serine is part of a catalytic triad that also includes Histidine and Aspartate
Histidine removes a proton from serine 195, generating a highly reactive alkoxide ion.
The alkoxide ion attacks the peptide bond of the substrate
Aspartate orients the histidine and renders it a better proton acceptor
The oxyanion hole, a region of the active site, stabilizes the tetrahedral reaction intermediate
Muscles mainly use ATP from Glycolysis as an energy source. Which amino acid is produced as a result and what is it converted into in the liver ?
Pyruvate can be converted to Alanine (via transamination) per transport into the liver
→ Alanine is converted into glucose in liver
→ generation of Glucose from Pyruvate
Why is arginine-glutamate injected to help against toxic accumulation of ammonia during Hyperammonemia?
Hyperammonemia = elevated levels of ammonia in the blood, common symptoms of liver failure
Primary degradation product is Ammonia (NH3) –toxic!!!
Solution: Conversion of toxic NH3 into non-toxic, soluble molecule: Urea
Ammonia collected by glutamate is removed by glutamate-dehydrogenase
(Arg) enhances conversion of ammonia to urea which is excreted then
What is gout (Gicht) and what plasma level is increased? What does it have do to with urea and uric acid?
Gout is a type of arthritis that occurs when urate crystals accumulate in the joints, often toes, leading to inflammation and pain
Why is the ribonucleotide reductase a good target for cancer cells? What is the consequence of inhibited ribonucleotide reductase for the cell?
disrupts the production of deoxyribonucleotides needed for DNA synthesis
→ leads to a halt in cell division
Without a sufficient supply of deoxyribonucleotides, cells cannot efficiently repair damaged DNA
→ leads to the accumulation of genetic errors and eventual cell death/apoptosis
Ribonucleotide reductase (RNR) is target for several anticancer drugs such as gemcitabine. Explain consequences for the cell when inhibiting ribonucleotide reductase
Ribonucleotide reductase is important for catalyzing the conversion of ribonucleotides to deoxyribonucleotides
Gemcitabine = nucleoside analog
it reduces the hydroxygroup at the C-2 of the ribose of the nucleotides → suicide inhibitor
→ no replication
→ no repair → accumulation of damage
→ no DNA synthesis
→ cell apoptosis
What Enzyme is inhibited by methotrexate and which nucleotide can not be synthesized as a result?
dihydrofolate reductase (DHFR) enzyme
→ thymidine (dTMP) de novo synthesis requires this enzyme
It impairs the DNA and RNA replication, induces cell cycle arrest and eventually apoptosis
Some anticancer drugs such as methotrexate block dihydrofolate reductase. Explain how this is effecting the cells.
cell death, because they cannot synthesise thymine anymore to create more DNA
What happens in cyclic photophosphorylation? When does it take place?
reverse flow → electrons from PSI can be transferred back to cytochrome b6f by ferredoxin instead of NADP+
Plastocyanine gets reduced and reoxidized by P700+
ATP generation without NADPH formation
takes place at high NADPH : NADP+ ratios
no PSII, no O2 released
What is the principle photoreceptor in oxygenic photosynthesis & anoxygenic photosynthesis? To which compound class are these belonging?
oxygenic: chlorophyll a and b → PSI (P700) + PSII (P680)
anoxygenic: bacteriochlorophyll a and b (P775 + P790)
circular, substituted tetrapyrroles (porphyrins) → pigments
What reducing power, carbon source and energy source do oxygenic and anoxygenic photosynthesis use? // What is the reducing power in oxygenic and anoxygenic photosynthesis?
oxygenic: H20, CO2, light (ADP → ATP)
anoxygenic: H2S, CO2, light (ADP → ATP)
Differences of oxygenic and anoxygenic photosynthesis?
oxygenic:
uses both photosystems
linear electron transport
electron donor: H2O
pigments: chlorophyll
byproducts: O2
organism: plants, algae, cyanobacteria
anoxygenic:
1 PS used
cyclic electron transport
electron donor: H2S, H2, organic compounds
pigments: bacteriochlorophyll
byproducts: no O2
organism: certain bacteria
Two core proteins of PSI and PSII of oxygenic organisms?
PSI
Core: Pair of homologous subunits PsaA and PsaB
PS I catalyzes final stage of the light reactions
chlorophyll special pair P700 at the center
absorbs at 700 nm, initiating charge separation
PSII
PSII core formed by D1 (gene: psbA) and D2 (gene: psbA) proteins (homologs of L + M of purple bacteria)
Contains large number of additional subunits (e.g, chlorophyll bound proteins, increasing efficiency of light energy absorption)
Stochiometry of the light reaction?
2H2O + 2NADPH + 10H+ -> O2 + 2NADPH + 12H+
a) What happens in RubisCO oxygenation reaction? Name 2 products and
b) why the oxygenation reaction is bad for the plant during their growth phase?
a)
in presence of oxygen RuBisCO catalyzes oxygenation of RuBP
formation of 3-Phosphoglyerate + Phosphoglycolate
b)
Phosphogylcolate -> photorespiration
no useful organic compound is produced
release of CO2 without carbon fixation
Cofactor of RubisCO and what are the activation steps of RubisCO?
Cofactor: Mg2+ → CO2 (not substrate) reacts with a lysine side chain to form a carbonate
→ negative charge adduct → stabilized by cofactor Mg2+
Describe principle of transketolase reaction.
Transketolase facilitates the exchange of functional groups between a ketose and an aldose, resulting in the formation of a new ketose and aldose with swapped residues
C7 and C3 → C5
Stochiometry of the Calvin cycle? How many ATP and how many NADPH need to be incorporated in a hexose for each CO2 molecule?
For each CO2 molecule incorporated in a hexose, 3 ATP and 2 NADPH are required
6CO2 + 12NADPH + 12H+ + 18ATP -> C6H12O6 + 12NADP+ + 18ADP + 18Pi + 6H2O
What are the schematic parts of an glycerophospholipid? What part is hydrophobic and which is polar?
polar head has at least one phosphate group)
Glycerol backbone
2 fatty acids (usually one saturated and one unsaturated) linked via ester bonds to glycerol backbone
C-3 carbon has phosphoric acid group
What are the three different molecular mechanisms of diffusion through a lipid membrane?
Diffusion (Substances will diffuse down their concentration gradient (Entropy))
Osmosis (semipermeable membrane)
facilitated diffusion (transport proteins are helping molecules to cross membrane)
What is the difference between glycerolipids and sphingolipids?
Difference lies in their backbone
Glycerophospholipids:
3 carbon glycerol backbone
polar head with at least one phosphate group
backbone bonded to 2 fatty acids via ester linkages
Sphingolipids:
Sphingosine backbone
backbone bonded to 1 fatty acid chain via amide linkage
(organic aliphatic amino alcohol sphingosine)
What characteristics describe fluid mosaic model best?
mixture of different lipids and proteins, peripheral or integral
Why do saturated fatty acids lead to a higher melting temperature of membranes?
Saturated fatty acids
No double bond → straight and more packed molecular structure
tight packing makes it more difficult for the molecules to move past each other, requiring a higher temperature to transition from a solid to a liquid state
What can you say about the melting temperature of a saturated fatty acid? Which powers play a role?
Quality of fatty acids: More unsaturated fatty acids → Kinks in the PM → Fatty acid residues can no longer be arranged in an optimal way → Less hydrophobic interactions => Structure is less stabilized → Less energy in form of temperature is needed → Lower melting temperature (membrane is more fluid)
Number of double bonds: More double bonds → More kinks → Lower melting temperature (membrane is more fluid)
Length of fatty acids: Shorter fatty acids → Less surface to hydrophobically interact and stabilize the structure → Lower melting temperature (membrane is more fluid)
Cholesterol: Cholesterol has a complex role in modulating the fluidity and melting temperature of the lipid bilayer. It acts as a stabilizer, promoting membrane integrity and preventing excessive changes in fluidity across a range of temperatures. The precise effect of cholesterol on the melting temperature depends on the specific lipid composition and the environmental conditions of the membrane.
Difference between bitopic and polytopic membrane proteins?
→ bitopic span the membrane only once
→ polytopic span the membrane multiple times
What are extrinsic membrane and intrinsic membrane proteins
Extrinsic = Peripheral (Associated with the membrane surface but are not embedded in the hydrophobic interior)
Intrinsic = Integral (Embedded within the lipid bilayer)
→ Bitopic and polytopic belongs to the intrinsic membrane proteins
What role do special/ ordered zones in membranes play as lipid rafts for the lifecycle of the influenca virus?
lipid raft microdomains are enriched in sphingomyelin & cholesterol
function as platforms for signal transduction as receptor signaling
function as the site of budding of several enveloped viruses (including influenza)
The virus uses these Lipid-Rafts to enrich there proteins in these small regions to make the assembly of there proteins more efficient
→ this leads to the formation of the envelope of the virus
Which type of membrane lipids preferentially accumulate in lipid rafts?
Sphingolipids (e.g., Sphingomyelin, Glycosphingolipids)
Cholesterol
→ Higher order and tighter packing of lipids
Why is the plasma membrane transiently deformed in a viral budzone? Which molecules might be responsible for this curvature?
specific viruses bind as proteins which are at high concentration in lipid rafts
matrix proteins cause the membrane deformation
Cellular proteins involved in vesicle formation and membrane remodeling, such as ESCRT (endosomal sorting complexes required for transport) proteins, can contribute to membrane curvature during viral budding.
→ ESCRT-I and ESCRT-III as an example
What are GUV’s and for what are they used in the lab?
giant unilamellar vesicles
Large, 10-100 μm, can be observed via optical microscopy e.g. fluorescence microscopy
used for
Protein-Lipid Interactions
GUVs are used to investigate the interactions between proteins and lipid membranes.
Fluorescence Microscopy and Imaging
Drug Delivery Studies
Why is it useful to look at molecular brightness? Which technique can be used for this?
Molecular brightness is the intensity of the light emitted by one molecule
It can be used for Quantitative Analysis, Detection of Molecular Interactions (like multimerization), Monitoring Environmental Changes, Studying Molecular Dynamics:
Methode: N&B (number and brightness)
Why does it make sense to look at fluctuations in fluorescence and what is a method for doing so?
To get information about molecule interactions, conformational changes, diffusion dynamics, binding kinetics
Possible because fluctuations in the signal occur due to diffusion which is linked to many specific molecule properties (e.c. size, photostability)
Method: FCS (Fluorescence Correlation Spectroscopy)
Multiple choice: What molecule is shown?
w-3 fatty acid
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