Chapter 34: Protein Aggregates as Entropy Traps

"In aggregation, ψ falls into its own trap—multiple proteins collapsing together into disordered masses, entropy winning over information, chaos overcoming order."

34.1 The Aggregation Phenomenon

Protein aggregation represents ψ's thermodynamic trap—when exposed hydrophobic surfaces drive proteins together into amorphous assemblies, creating cellular inclusions that disrupt function and resist dissolution.

Definition 34.1 (Aggregate Types): $\text{Aggregates} \in \{\text{Amorphous}, \text{Ordered (amyloid)}, \text{Inclusion bodies}\}$

Different morphologies of multi-protein assemblies.

34.2 The Hydrophobic Catastrophe

Theorem 34.1 (Driving Force): $\Delta G_{\text{agg}} = \Delta H_{\text{interaction}} - T\Delta S_{\text{translational}} < 0$

Favorable when hydrophobic burial overcomes entropy loss.

34.3 Kinetic Partitioning

Equation 34.1 (Competition): $\frac{d[\text{Native}]}{dt} = k_{\text{fold}}[\text{Unfolded}]$ $\frac{d[\text{Aggregate}]}{dt} = k_{\text{agg}}[\text{Unfolded}]^n$

Folding vs aggregation—concentration dependence critical.

34.4 The Inclusion Body Problem

Definition 34.2 (Bacterial Aggregates): $\text{IB} = \text{Overexpressed protein} + \text{Chaperones} + \text{RNA/lipids}$

Dense, refractile bodies in recombinant expression.

34.5 Aggresomes

Theorem 34.2 (Cellular Response): $\text{Dispersed aggregates} \xrightarrow{\text{Dynein}} \text{Aggresome at MTOC}$

Active transport concentrating aggregates.

34.6 The Phase Diagram

Equation 34.2 (Solubility Boundary): $C_{\text{sat}} = C_0 \exp(-\Delta G_{\text{agg}}/RT)$

Above saturation, aggregation thermodynamically favored.

34.7 Molecular Chaperone Suppression

Definition 34.3 (Kinetic Protection): $[\text{Aggregate}]_{\text{+chaperone}} << [\text{Aggregate}]_{\text{-chaperone}}$

Chaperones kinetically blocking aggregation.

34.8 Heat Shock and Aggregation

Theorem 34.3 (Temperature Effect): $\frac{d[\text{Unfolded}]}{dT} > 0 \Rightarrow \frac{d[\text{Aggregate}]}{dT} > 0$

Heat increasing unfolded population drives aggregation.

34.9 Liquid-Liquid Phase Separation

Equation 34.3 (Droplet Formation): $\text{Proteins} + \text{RNA} \rightarrow \text{Liquid droplets} \rightarrow \text{Solid aggregates}$

Phase transitions preceding aggregation.

34.10 Disaggregase Systems

Definition 34.4 (Active Resolution): $\text{Aggregate} + \text{ClpB/Hsp104} + \text{ATP} \rightarrow \text{Soluble proteins}$

Energy-dependent aggregate dissolution.

34.11 Autophagy of Aggregates

Theorem 34.4 (Clearance Pathway): $\text{Aggregate} \rightarrow \text{p62 recognition} \rightarrow \text{Autophagosome} \rightarrow \text{Degradation}$

Selective autophagy removing aggregates.

34.12 The Trap Principle

Protein aggregates embody ψ's recognition of thermodynamic inevitability—that exposed hydrophobic surfaces will find each other, that concentration drives association, that entropy can trap function.

The Aggregation Equation: $\frac{d[\text{Agg}]}{dt} = k_{\text{nuc}}[\text{U}]^{n_c} + k_{\text{elong}}[\text{Agg}][\text{U}]$

Nucleation and growth kinetics.

Thus: Aggregate = Trap = Entropy = Disorder = ψ's thermodynamics

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"In protein aggregates, ψ confronts the price of hydrophobicity—the very forces that drive folding can drive aggregation, creation and destruction emerging from the same source. Each aggregate is entropy's victory over information, thermodynamics asserting its dominion over biology."