Biochemistry Questions Biochemistry Questions / Biostructures, Energetics, and Synthesis

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Compare and contrast photosystem I and photosystem II. What are their roles in photosynthesis?
Compare and contrast primary pathways and secondary pathways in terms of their functions, regulation, and metabolite products.
Compare and contrast the functions of Gαs and Gαi in GPCR signalling.
Compare and contrast the storage of excess glucose as glycogen in muscle and its conversion to fat.
Compare and contrast the structure and selectivity of porins and α-helical membrane proteins.
Compare and contrast the structures and functions of rhodopsin and β2-adrenergic receptor (β2-AR) as GPCRs.
Compare passive, primary active, and secondary active transport across membranes. Give examples of each.
Compare the ATP synthesis efficiency of a 14 C-subunit ring and an 8 C-subunit ring in ATP synthase.
Compare the efficiency of ATP synthesis with 8 C ring subunits to that with 13 C ring subunits. What factors contribute to the difference in efficiency?
Compare the process of dehydrating K+ ions versus Na+ ions in ion channels, and explain why it requires more energy to remove water molecules from Na+.
Describe the different types of protein-membrane interactions.
Describe the function of biotin as a carrier and its role in metabolism.
Describe the mechanism of receptor-tyrosine kinases and their significance in signalling.
Describe the process of cryo EM and its advantages over X-ray crystallography for protein structure determination.
Describe the process of ligand-mediated endocytosis and how it is mediated by membrane rafts. Discuss the role of caveolin in this process.
Describe the process of neurotransmitter diffusion and how it contributes to signal transmission between cells.
Describe the process of primary active transport and how it is powered by ATPases.
Describe the process of protein trafficking in the endoplasmic reticulum and how proteins are tagged for their destination.
Describe the process of β-oxidation and its significance in fatty acid catabolism.
Describe the relationship between the number of ion channels open and the voltage across the membrane. Discuss the role of voltage-gated Na+ channels and voltage-gated K+ channels in nerve cells.
Describe the reversible enzyme lactate dehydrogenase (LDH) and its role in converting pyruvate to lactate. How does endurance training affect the proportion of LDH subunits in muscle tissue?
Describe the role of membrane rafts in controlling the localisation of membrane proteins.
Describe the role of Mg2+ in the Calvin cycle and its importance for rubisco activity.
Describe the signalling pathway involving GPCRs, cAMP, and protein kinase A (PKA), and explain how it leads to the activation of genes.
Describe the structure of a photosystem and the function of the antenna complex in capturing and concentrating light energy.
Discuss Jardetzky's allosteric model for membrane pumps and how it explains the alternating access mechanism.
Discuss Marcus theory and its relevance in explaining electron transfer reactions in Photosystem I.
Discuss the advantage of having a greater number of C ring subunits in ATP synthesis. How does this allow for continual ATP production in changing environmental conditions?
Discuss the differences between alpha helix and beta sheets in protein secondary structure.
Discuss the importance of an antenna in photosynthesis and how it increases the excitation rate of the reaction centre.
Discuss the importance of folate in the production of glycine and DNA synthesis.
Discuss the mechanism by which Gα-GTP activates adenylyl cyclase and the role of cAMP as a second messenger.
Discuss the relationship between catabolism and anabolism, and explain how insufficient catabolism can constrain biosynthesis.
Discuss the role of adaptor proteins in signalling and how they recognize phosphorylated receptors.
Discuss the role of arrestin in turning off GPCR signalling and the process of GPCR recycling.
Discuss the role of chemiosmotic theory in bioenergetics and its impact on our understanding of cellular processes.
Discuss the role of cholesterol in membrane thickness and fluidity.
Discuss the role of G proteins in signalling and how they are switched on and off.
Discuss the role of G-protein coupled receptors (GPCRs) in cell signalling and their significance in drug targeting.
Discuss the role of glycolysis in the production of energy in cells.
Discuss the role of group carriers in catalysis and genetic information storage.
Discuss the role of isozymes in controlling amino acid synthesis. How do they allow for better control of the amino acids present?
Discuss the role of membrane channels in allowing the movement of nutrients and waste in and out of a cell.
Discuss the role of microtubules in membrane trafficking and how disruption of microtubules can affect organelle movement.
Discuss the role of pigment environment in altering the excited state properties of chlorophyll and carotenoids.
Discuss the role of retinal in the colour change of bacteriorhodopsin.
Discuss the role of rubisco in the Calvin cycle and its significance in plant metabolism.
Discuss the role of SecB and SecY in the translocation of membrane proteins.
Discuss the role of the H+ gradient in ATP synthesis. How does the pH difference between the inside and outside of the membrane affect ATP production?
Discuss the role of the S-state cycle in stabilizing charge separation in Photosystem II.
Discuss the role of transport proteins in allowing molecules and ions to cross the membrane.
Discuss the role of β-arrestin in GPCR deactivation and its impact on further G protein activation.
Discuss the significance of C ring size in ATP synthase and how it relates to energy input and ATP synthesis.
Discuss the significance of group carriers in the synthesis of ethylene and plant ripening.
Discuss the significance of myelin sheaths in increasing the speed of nervous transmission.
Discuss the significance of the NPA motif in aquaporins.
Discuss the significance of the Stokes shift in light harvesting.
Discuss the various methods of protein attachment to the membrane.
Explain how bacteriorhodopsin uses light as a direct energy input to transport H+ across the membrane.
Explain how carrier proteins facilitate the transport of glucose across the membrane.
Explain how cells control membrane curvature through lipid composition.
Explain how changes in substrate concentration can affect the rate of a metabolic pathway. How does metabolic flux analysis help determine the impact of substrate concentration?
Explain how cholera toxin and the Bordetella pertussis toxin disrupt GPCR signalling and the consequences of these disruptions.
Explain how Förster resonance energy transfer (FRET) allows for the transfer of energy in photosynthesis.
Explain how multiple sclerosis (MS) is caused by a loss of myelin and its impact on nervous transmission.
Explain how sugar molecules formed through photosynthesis contribute to various metabolic pathways in plants.
Explain how the Nernst equation can be used to calculate the membrane resting potential. What factors contribute to the membrane potential?
Explain how voltage-gated Na+ channels and voltage-gated K+ channels open and close in response to changes in membrane potential. Discuss the concept of refractory period.
Explain the chemiosmotic theory and discuss an experiment that provides evidence for this theory.
Explain the concept of anaplerotic reactions and their role in the Krebs cycle.
Explain the concept of cumulative control of a single enzyme. Provide an example of an enzyme that can be inhibited independently by multiple different products.
Explain the concept of feedback inhibition in metabolic pathways and how it helps prevent wasteful reactions. Provide examples.
Explain the concept of hydropathy and its significance in determining transmembrane regions.
Explain the concept of lipid composition in membranes and how it contributes to the formation of bilayers and the fluid mosaic structure.
Explain the concept of membrane trafficking via vesicles and how it allows for the control of molecule movement in eukaryotic cells.
Explain the concept of negative entropy and its importance in sustaining life.
Explain the concept of quaternary structure in proteins and provide examples of homo-oligomers and hetero-oligomers.
Explain the concept of voltage-gating in K+ channels and how it allows for the control of ion transport.
Explain the difference between passive (facilitated) transport and active transport. Give examples of each.
Explain the difference between primary and secondary membrane lipids.
Explain the different types of signal anchors and their role in determining the orientation of membrane proteins.
Explain the function of plastoquinone in the electron transport chain of Photosystem II.
Explain the importance of CO2 in metabolic reactions and why reactions producing CO2 are energetically favourable.
Explain the importance of glucose as the main source of energy in cells.
Explain the importance of membranes in biological systems and how they act as a barrier between the interior and exterior of a cell.
Explain the importance of transamination reactions in amino acid metabolism.
Explain the main uses of acetyl CoA and how it is produced.
Explain the process of action potential propagation along an axon and the role of voltage-gated channels.
Explain the process of protein translocation in bacteria and its conservation in eukaryotes.
Explain the process of vibrational relaxation and its role in the fate of the S2 excited state.
Explain the process of X-ray crystallography and how it is used to determine protein structure.
Explain the relationship between group carriers and the RNA world hypothesis.
Explain the role of acetyl CoA in carrying carbon units and its significance in the link reaction and fatty acid biosynthesis.
Explain the role of chlorophyll in photosynthesis and how it is involved in the light reactions.
Explain the role of cytochrome b6f as an electrical connection between PSII and PSI in photosynthesis.
Explain the role of GPCRs in signal transduction and how ligand binding leads to the activation of G proteins.
Explain the role of plastocyanin and ferredoxin in electron transfer in Photosystem I.
Explain the role of rhodopsin in detecting light in the eye and how it is able to detect different wavelengths.
Explain the role of S-adenosylmethionine (SAM) as a carrier in methylation reactions.
Explain the role of the manganese cluster in the oxidation of H2O to O2 in Photosystem II.
Explain the role of the neutral zone around the reaction centre in preventing electron escape in Photosystem I.
Explain the role of threshold enzymes in biosynthetic pathways and why they are tightly controlled and non-constitutive.
Explain the significance of stable ADP and Pi concentrations for ATP synthesis. How can changes in these concentrations impact the energy required for ATP synthesis?
Explain the structure and function of membrane channels.
Explain the technique of patch clamping and how it is used to measure the current across a membrane. Discuss the different geometries that can be studied using patch clamping.
Explain the three stages of the Calvin cycle (carboxylation, reduction, regeneration). What is the overall purpose of the Calvin cycle?
Explain the three stages of the Calvin cycle and their respective inputs and outputs.
Explain why animals are more mobile than plants due to the difference in energy storage.
Explain why the electron transfer rate in Photosystem I is optimal when the driving force ΔG is equal to the reorganisation energy.
How does the light reaction of photosynthesis regulate the Calvin cycle? Explain the role of thioredoxin in this regulation.
How does the lipid composition of a membrane affect its fluidity?
What is the phase problem in structure determination and how is it solved?
What is the purpose of atomic force microscopy in studying membrane components?
What is the Z-scheme and how does it describe changes in redox potential during photosynthesis?
What mechanisms help control metabolic pathway activity? Give examples to illustrate different mechanisms.