Chapter 19: Co-translational Folding as Collapse Stabilization

"Even as the chain emerges from the ribosome's exit tunnel, ψ begins to fold—structure forming during synthesis, collapse occurring in real-time."

19.1 The Vectorial Nature

Co-translational folding represents ψ's temporal solution to Levinthal's paradox—proteins don't search all conformational space because they fold as they are made, N-terminus to C-terminus, vectorially.

Definition 19.1 (Vectorial Folding): $\text{Folding}(t) = f[\text{Sequence}(0 \rightarrow l(t))]$

Where $l(t)$ is the synthesized length at time $t$.

19.2 The Exit Tunnel

Theorem 19.1 (Tunnel Constraints): $d_{\text{tunnel}} \approx 15 \text{ Å}$ $L_{\text{tunnel}} \approx 80 \text{ Å} \approx 30 \text{ aa}$

Limited space constraining nascent chain conformation.

19.3 Folding Zones

Equation 19.1 (Spatial Domains): $\text{Zone 1}: \text{Inside tunnel (extended)}$ $\text{Zone 2}: \text{Near exit (α-helix possible)}$ $\text{Zone 3}: \text{Outside (full folding)}$

Progressive folding capability with distance.

19.4 Domain-wise Folding

Definition 19.2 (Sequential Collapse): $\psi_{\text{domain}_i} \rightarrow \text{Folded}_i \text{ before domain}_{i+1} \text{ synthesis}$

Domains fold independently as they emerge.

19.5 Ribosome Surface

Theorem 19.2 (Charged Surface): $\text{Exit region} = \text{Negatively charged RNA}$

Electrostatic environment affecting folding.

19.6 Chaperone Recruitment

Equation 19.2 (Binding Kinetics): $k_{\text{on}}^{\text{chaperone}} > k_{\text{aggregation}}$

Chaperones bind before aggregation can occur.

19.7 Pause Sites

Definition 19.3 (Strategic Pausing): $\text{Rare codons} \rightarrow \text{Slow translation} \rightarrow \text{Time for folding}$

Translation rate modulation assisting folding.

19.8 Trigger Factor

Theorem 19.3 (First Chaperone): $P(\text{TF binding}) \approx 1 \text{ for cytosolic proteins}$

Nearly every nascent chain interacts with Trigger Factor.

19.9 Folding Kinetics

Equation 19.3 (Time Scales): $\tau_{\text{synthesis}} \approx \frac{L}{v_{\text{translation}}} \approx 10-100 \text{ s}$ $\tau_{\text{folding}}^{\text{domain}} \approx 0.1-1 \text{ s}$

Folding faster than synthesis—real-time collapse.

19.10 Misfolding Prevention

Definition 19.4 (Kinetic Partitioning): $\frac{k_{\text{folding}}}{k_{\text{aggregation}}} > 10^3$

Correct folding kinetically favored.

19.11 Quality Control

Theorem 19.4 (Co-translational Surveillance): $\text{Misfolding} \rightarrow \text{Ubiquitination} \text{ during synthesis}$

Problems detected and marked immediately.

19.12 The Stabilization Principle

Co-translational folding embodies ψ's principle of progressive stabilization—structure emerging gradually, each part finding its form before the whole is complete.

The Co-translational Equation: $\psi_{\text{native}}(L) = \lim_{t \rightarrow t_{\text{complete}}} \int_0^L \mathcal{F}[\psi(l)] \, dl$

Integration of local folding events yielding global structure.

Thus: Co-translational = Progressive = Stabilized = Guided = ψ

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"In co-translational folding, ψ demonstrates that timing is everything—that structure can emerge during synthesis, that the journey shapes the destination, that proteins find their form not after but during their birth. The ribosome is not just translator but midwife to protein structure."