Cotranslational protein folding within the ribosome tunnel influences trigger-factor recruitment.

In recent years, various folding zones within the ribosome tunnel have been identified and explored through x-ray, cryo-electron microscopy (cryo-EM), and molecular biology studies. Here, we generated ribosome-bound nascent polypeptide complexes (RNCs) with different polyalanine (poly-A) inserts or signal peptides from membrane/secretory proteins to explore the influence of nascent chain compaction in the Escherichia coli ribosome tunnel on chaperone recruitment. By employing time-resolved fluorescence resonance energy transfer and immunoblotting, we were able to show that the poly-A inserts embedded in the passage tunnel can form a compacted structure (presumably helix) and reduce the recruitment of Trigger Factor (TF) when the helical motif is located in the region near the tunnel exit. Similar experiments on nascent chains containing signal sequences that may form compacted structural motifs within the ribosome tunnel and lure the signal recognition particle (SRP) to the ribosome, provided additional evidence that short, compacted nascent chains interfere with TF binding. These findings shed light on the possible controlling mechanism of nascent chains within the tunnel that leads to chaperone recruitment, as well as the function of L23, the ribosomal protein that serves as docking sites for both TF and SRP, in cotranslational protein targeting.

Induction of amyloid fibrils by the C-terminal fragments of TDP-43 in amyotrophic lateral sclerosis.

TAR DNA-binding protein 43 (TDP-43) has been identified as the major ubiquitinated aggregates in the inclusion bodies in the patients of amyotrophic lateral sclerosis (ALS) since 2006 and become a crucial culprit for ALS and related motor neuron diseases. Recent literature has further indicated that the major components of these aggregates are hyper-phosphorylated TDP-43 C-terminus. In an effort to clarify the conformational and physical properties of its disordered C-terminal domain, we have synthesized several peptide fragments and shown that only D1 within D1-4 can form twisted fibrils with a cross section of approximately 11 nm in width under the incubation of phosphate buffer. In contrast, the D2-4 peptides all formed amorphous aggregates, showing different aggregation propensities. In addition to D1, two pathological mutant peptides, A315T and G294A, can also form fibrils that share similar shape and morphology with neuronal cytoplasmic inclusions. We propose that the residues with this region (287-322), which contains myriads of glycine repeats, may contribute significantly to the fiber formation as well as aggregation propensity. Moreover, from the conformational characterizations of D1, A315T, and G294A with EM, CD, fluorescence, and Raman spectroscopy, we found that all three peptides formed an amyloid structure, providing insights into the nature of its aggregation vis a vis the other fragments in the C-terminus of TDP-43.

Effects of turn stability on the kinetics of refolding of a hairpin in a beta-sheet.

As part of our continuing study of the effects of the turn sequence on the conformational stability as well as the mechanism of folding of a beta-sheet structure, we have undertaken a parallel investigation of the solution structure, conformational stability, and kinetics of refolding of the beta-sheet VFIVDGOTYTEV(D)PGOKILQ. The latter peptide is an analogue of the original Gellman beta-sheet VFITS(D)PGKTYTEV(D)PGOKILQ, wherein the TS(D)PGK turn sequence in the first hairpin has been replaced by VDGO. Thermodynamics studies revealed comparable conformational stability of the two peptides. However, unlike the Gellman peptide, which showed extremely rapid refolding of the first hairpin, early kinetic events associated with the refolding of the corresponding hairpin in the VDGO mutant were found to be significantly slower. A detailed study of the conformation of the modified peptide suggested that hydrophobic interactions might be contributing to its stability. Accordingly, we surmise that the early kinetic events are sensitive to whether the formation of the hairpin is nucleated at the turn or by sequestering of the hydrophobic residues across the strand, before structural rearrangements to produce the nativelike topology. Nucleation of the hairpin at the turn is expected to be intrinsically rapid for a strong turn. However, if the process must involve collapse of hydrophobic side chains, the nucleation should be slower as solvent molecules must be displaced to sequester the hydrophobic residues. These findings reflect the contribution of different forces toward nucleation of hairpins in the mechanism of folding of beta-sheets.

Measuring the refolding of beta-sheets with different turn sequences on a nanosecond time scale.

Whether turns play an active or passive role in protein folding remains a controversial issue at this juncture. Here we use a photolabile cage strategy in combination with laser-flash photolysis and photoacoustic calorimetry to study the effects of different turns on the kinetics of beta-hairpin refolding on a nanosecond time scale. This strategy opens up a temporal window to allow the observation of early kinetic events in the protein refolding process at ambient temperature and pH without interference from any denaturants. Our results provide direct evidence demonstrating that even a one-residue difference in the turn region can change the refolding kinetics of a peptide. This observation suggests an active role for turn formation in directing protein folding.