Which of the following is true about non-competitive inhibition?

Km remains same, Vmax decreases

Km increases, Vmax remains same

Which of the following is an example of allosteric inhibition?

Decreased synthesis of glucokinase by glucagon

Inactivation of glycogen synthase by phosphorylation

Phosphofructokinase-1 occupies a key position in regulating glycolysis and is also subjected to feedback control. Which among the following are the allosteric activators of phosphofructokinase-1?

2,3-Bisphosphoglycerate (2,3-BPG)

Which statement is false about allosteric regulation?

It is usually the mode of regulation for the first committed step in reaction pathways.

Cellular response is faster with allosteric control than by controlling enzyme concentration in the cell.

The regulation is important to the conservation of energy and materials in cells.

Allosteric modulators bind non-covalently at sites other than the active site and induce conformational changes in the enzyme.

Allosteric Regulation for UPSC-CMS: High-Yield Biochemistry Lessons

Allosteric Regulation Basics - Switch On, Switch Off

Allosteric Enzyme: An enzyme with an allosteric site, distinct from its active site, allowing activity modulation.
Allosteric Site: 📌 'Allo' = 'other'. Specific regulatory site on the enzyme, separate from active site, where effectors bind.
Allosteric Effectors (Modulators): Small molecules binding to allosteric sites, altering enzyme activity (↑ positive, ↓ negative).
- Positive Effectors (Activators): ↑ enzyme activity.
- Negative Effectors (Inhibitors): ↓ enzyme activity.
Key Characteristics:
- Reversible, non-covalent effector binding.
- Induces conformational change, transmitted to active site, altering substrate affinity/catalytic rate.

Allosteric regulation mechanisms and cooperativity

⭐ Allosteric enzymes are often oligomeric (multisubunit) proteins, enabling cooperativity.

Allosteric Mechanisms & Models - Shape Shifters at Work

Allosteric enzymes: effectors bind to allosteric sites (not active site), inducing conformational changes altering activity.

Conformational States:
- T (Tense) state: ↓ affinity, favored by inhibitors.
- R (Relaxed) state: ↑ affinity, favored by activators.
Cooperativity: Ligand binding affects further binding.
- Homotropic: Substrate as effector (e.g., O₂ for Hb).
- Heterotropic: Different effector (e.g., ATP/CTP for ATCase).

MWC concerted model of allosteric transitions

Models of Allostery:

Feature	MWC (Concerted)	KNF (Sequential)
Transition	All subunits change simultaneously	Sequential change, induced fit
Pre-existing Eqm.	Yes ($T \rightleftharpoons R$ equilibrium)	Ligand induces fit; sequential change
Symmetry	Preserved (all-T or all-R)	Intermediates (mixed T/R) possible
Negative Coop.	Not easily explained	Can explain

⭐ The MWC model assumes all subunits change conformation simultaneously, while the KNF model allows for sequential changes.

Allosteric Enzyme Kinetics - Curve Ball Kinetics

Curve: Sigmoidal (S-shaped) v vs. [S] plot, distinct from Michaelis-Menten's hyperbolic curve. Indicates cooperativity.
K0.5: [S] for 1/2 $V_{max}$; reflects enzyme affinity in allosteric enzymes.
Allosteric Activators:
- Shift curve left (↓K0.5, ↑affinity).
- Favor R (relaxed, high-affinity) state.
- Types: K-type (↓K0.5), V-type (↑$V_{max}$).
Allosteric Inhibitors:
- Shift curve right (↑K0.5, ↓affinity).
- Favor T (taut, low-affinity) state.
- Types: K-type (↑K0.5), V-type (↓$V_{max}$).
Hill Equation: Describes cooperativity: $v = V_{max} [S]^{n_H} / (K_{0.5}^{n_H} + [S]^{n_H})$.
Hill Coefficient ($n_H$): Measures degree of cooperativity.
- $n_H > \textbf{1}$: Positive cooperativity.
- $n_H < \textbf{1}$: Negative cooperativity.
- $n_H = \textbf{1}$: No cooperativity (Michaelis-Menten like).

⭐ Positive cooperativity: one substrate binding increases the enzyme's affinity for subsequent substrate molecules.

Key Examples & Clinical Impact - Allostery in Action

Key allosteric molecules:

Phosphofructokinase-1 (PFK-1): Pivotal enzyme in glycolysis.
- Activators: AMP, Fructose-2,6-bisphosphate (signal low energy).
- Inhibitors: ATP, Citrate (signal high energy).
- 📌 PFK-1: 'ATP inhibits, AMP activates Progress of glycolysis'.
⭐ High ATP levels allosterically inhibit PFK-1, signaling that the cell has sufficient energy.
Aspartate Transcarbamoylase (ATCase): Early step in pyrimidine biosynthesis.
- Activator: ATP.
- Inhibitor: CTP (end-product feedback inhibition).
Hemoglobin (Hb): Classic allosteric protein (not an enzyme), crucial for $O_2$ transport.
- Homotropic positive effector: $O_2$.
- Heterotropic negative effectors: $H^+$, $CO_2$, 2,3-Bisphosphoglycerate (2,3-BPG).

Models of Allostery and Allosteric Modulation

Clinical Relevance: Allosteric drugs act as precise modulators.
- Examples: Cinacalcet (CaSR in parathyroid disorders), Maraviroc (CCR5 in HIV).

High‑Yield Points - ⚡ Biggest Takeaways

Allosteric enzymes possess regulatory sites distinct from their active sites.

Binding of allosteric modulators (activators or inhibitors) causes conformational changes.

They typically display sigmoidal kinetics (cooperativity), not Michaelis-Menten.

Homotropic effectors are substrates; heterotropic effectors are non-substrate molecules.

PFK-1 (glycolysis) is a classic example, regulated by ATP (inhibitor) and AMP (activator).

This regulation provides fine-tuned control over metabolic pathways.

K-type modulators alter Km (substrate affinity); V-type modulators alter Vmax (maximal velocity).

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