Partly folded states of members of the lysozyme/lactalbumin superfamily: a comparative study by circular dichroism spectroscopy and limited proteolysis

The partly folded states of protein members of the lysozyme (LYS)/alpha-lactalbumin (LA) superfamily have been analyzed by circular dichroism (CD) measurements and limited proteolysis experiments. Hen, horse, dog, and pigeon LYSs and bovine LA were used in the present study. These are related proteins of 123- to 129-amino-acid residues with similar three-dimensional structures but low similarity in amino acid sequences. Moreover, notable differences among them reside in their calcium-binding properties and capability to adopt partly folded states or molten globules in acid solution (A-state) or on depletion of calcium at neutral pH (apo-state). Far- and near-UV CD measurements revealed that although the structures of hen and dog LYS are rather stable in acid at pH 2.0 or at neutral pH in the absence of calcium, conformational transitions to various extents occur with all other LYS/LA proteins herewith investigated. The most significant perturbation of tertiary structure in acid was observed with bovine LA and LYS from horse milk and pigeon egg-white. Pepsin and proteinase K were used as proteolytic probes, because these proteases show broad substrate specificity, and therefore, their sites of proteolysis are dictated not by the specific amino acid sequence of the protein substrate but by its overall structure and dynamics. Although hen LYS at pH 2.0 was fully resistant to proteolysis by pepsin, the other members of the LYS/LA superfamily were cleaved at different rates at few sites of the polypeptide chain and thus producing rather large protein fragments. The apo-form of bovine LA, horse LYS, and pigeon LYS were attacked by proteinase K at pH 8.3, whereas dog and hen LYSs were resistant to proteolysis when reacted under identical experimental conditions. Briefly, it has been found that the proteolysis data correlate well with the extent of conformational transitions inferred from CD spectra and with existing structural informations regarding the proteins herewith investigated, mainly derived from NMR and hydrogen exchange measurements. The sites of initial proteolytic cleavages in the LYS variants occur at the level of the beta-subdomain (approximately chain region 34-57), in analogy to those observed with bovine LA. Proteolysis data are in agreement with the current view that the molten globule of the LYS/LA proteins is characterized by a structured alpha-domain and a largely disrupted beta-subdomain. Our results underscore the utility of the limited proteolysis approach for analyzing structure and dynamics of proteins, even if adopting an ensemble of dynamic states as in the molten globule.     

CONTROLLED PROTEOLYSIS OF NASCENT POLYPEPTIDES IN RAT LIVER CELL FRACTIONS : I. Location of the Polypeptides within Ribosomes

Free ribosomes containing nascent polypeptide chains labeled in vitro were submitted to proteolysis at 0° by a mixture of trypsin and chymotrypsin. Sucrose gradient analysis showed that polysome patterns are retained even after 24 hr of proteolysis in the cold, while messenger RNA-free ribosomes (generated progressively during in vitro incorporation) are, within 2 hr, completely dissociated into subunits by trypsin. Although ribosomes and subunits are not extensively degraded into smaller fragments during low temperature proteolysis, changes in the acrylamide gel electrophoresis pattern showed that most ribosomal proteins are accessible to and are partially degraded by the proteases. Ribosome-bound nascent polypeptides are partially resistant to proteolysis at 0°, although they are totally digested at 37° or when the ribosomal subunit structure is disrupted by other means. Radioactivity incorporated into nascent chains during incubation times shorter than 3 min was mostly resistant to digestion at 0°. A larger fraction of the initial radioactivity became degraded in ribosomes which incorporated for longer times. In these ribosomes, the amount of radioactivity which was resistant to proteolysis was constant and independent of the initial value, which reflects the labeled length of the nascent chains. These results suggest that the growing end of the nascent polypeptide is resistant to digestion and is protected from proteolytic attack by the ribosomal structure. A pulse and chase experiment confirmed this suggestion, showing that the protected segment is located at the carboxy-terminal end of the nascent chain. The protected segment was contained in the large ribosomal subunit and had a length of ~39 amino acid residues, as estimated by chromatography on Sephadex G-50.     

Degradation of proteins microinjected into HeLa cells. The role of substrate flexibility

Increasing the flexibility of a protein enhances its susceptibility to defined proteases in vitro. To ascertain whether flexibility also affects protein stability in vivo, radioiodinated proteins with similar structures, but dissimilar flexibilities, were introduced into HeLa cells using red cell-mediated microinjection. Intracellular proteolysis was then measured as the rate of release of 125I-tyrosine into the medium. Ribonuclease A was considerably more resistant to degradation by purified proteases or in reticulocyte lysate than its flexible derivatives ribonuclease S and S-protein. In contrast, all three proteins were equally stable within HeLa cells. Like the results obtained for RNases, the rates of degradation of trypsin inhibitors, trypsin analogs, and their complexes correlated with flexibility in reticulocyte lysate. However, the intracellular half-lives of anhydrotrypsin and various proteinaceous trypsin inhibitors were not affected upon formation of enzyme-inhibitor complexes. Furthermore, trypsinogen was degraded more slowly than the structurally similar anhydrotrypsin in HeLa cells, although trypsinogen has additional segmental flexibility in its activation domain. Electrophoretic analyses revealed that trypsin-inhibitor complexes remained intact following injection into HeLa cells, and that neither free inhibitors nor anhydrotrypsin formed Triton-stable complexes with soluble cytoplasmic proteins. The observation that the components of the trypsin-inhibitor complexes were degraded simultaneously indicates that neither constituent unfolded prior to the onset of proteolysis. These studies provide evidence that RNases, trypsin, and trypsin inhibitors are degraded by an intracellular proteolytic pathway(s) which recognizes surface features of the folded proteins.     

Cleavage site selection within a folded substrate by the ATP-dependent lon protease

Mechanistic studies of ATP-dependent proteolysis demonstrate that substrate unfolding is a prerequisite for processive peptide bond hydrolysis. We show that mitochondrial Lon also degrades folded proteins and initiates substrate cleavage non-processively. Two mitochondrial substrates with known or homology-derived three-dimensional structures were used: the mitochondrial processing peptidase alpha-subunit (MPPalpha) and the steroidogenic acute regulatory protein (StAR). Peptides generated during a time course of Lon-mediated proteolysis were identified and mapped within the primary, secondary, and tertiary structure of the substrate. Initiating cleavages occurred preferentially between hydrophobic amino acids located within highly charged environments at the surface of the folded protein. Subsequent cleavages proceeded sequentially along the primary polypeptide sequence. We propose that Lon recognizes specific surface determinants or folds, initiates proteolysis at solvent-accessible sites, and generates unfolded polypeptides that are then processively degraded.     

Protein interactions leading to conformational changes monitored by limited proteolysis: apo form and fragments of horse cytochrome c

Proteolysis experiments have been used to monitor the conformational transitions from an unfolded to a folded state occurring when the apo form of horse cytochrome c (cyt c) binds the heme moiety or when two fragments of cyt c form a native-like 1:1 complex. Proteinase K was used as a proteolytic probe, in view of the fact that the broad substrate specificity of this protease allows digestion at many sites along a polypeptide chain. The rather unfolded apo form of cyt c binds heme with a concomitant conformational transition to a folded species characterized by an enhanced content of helical secondary structure. While the holoprotein is fully resistant to proteolytic digestion and the apoprotein is digested to small peptides, the noncovalent complex of the apoprotein and heme exhibits an intermediate resistance to proteolysis, in agreement with the fact that the more folded structure of the complex makes the protein substrate more resistant to proteolysis. The noncovalent native-like complex of the two fragments 1-56 and 57-104 of cyt c, covering the entire polypeptide chain of 104 residues of the protein, is rather resistant to proteolysis, while the individual fragments are easily digested. Fragment 57-104 is fast degraded to several peptides, while fragment 1-56 is slowly degraded stepwise from its C-terminal end, leading initially mostly to fragments 1-48 and 1-40 and, at later stages of proteolysis, fragments 1-38, 1-35, 1-33, and 1-31. Thus, proteolysis data indicate that the heme containing fragment 1-56 has a rather compact core and a C-terminal flexible tail. Upon prolonged incubation of the complex of fragments 1-56 and 57-104 (nicked cyt c) with proteinase K, a chain segment is removed from the nicked protein, leading to a gapped protein complex of fragments of 1-48 and 57-104 and, on further digestion, fragments 1-40 and 57-104. Of interest, the chain segment being removed by proteolysis of the complex matches the omega-loop which is evolutionarily removed in cyt c of microbial origin. Overall, rates and/or resistance to proteolysis correlates well with the extent of folding of the protein substrates, as deduced from circular dichroism measurements. Thus, our results underscore the utility of proteolytic probes for analyzing conformational and dynamic features of proteins. Finally, a specific interest of the cyt c fragment system herewith investigated resides in the fact that the fragments are exactly the exon products of the cyt c gene.     

Structure and evolution of ribosomes

Ribosomes are the only cell organelles occurring in all organisms. E. coli ribosomes, which are the best characterized particles, consist of three RNAs and 53 proteins. All components have been isolated and characterized by chemical, physical and immunological methods. The primary structures of the RNAs and of all the proteins are known. Information about the secondary structure of the proteins derives from circular dichroism measurements and from secondary structure prediction methods. The tertiary structure is being studied by limited proteolysis, proton magnetic resonance and crystallization followed by X-ray analysis. Various methods are being used to elucidate the architecture of the ribosomal particle: three-dimensional image reconstruction of crystals of bacterial ribosomes and/or their subunits; immune electron microscopy; neutron scattering; protein-protein, protein-RNA and RNA-RNA crosslinking; total reconstitution of ribosomal subunits. The results from these studies yield valuable information on the architecture of the ribosomal particle. Many mutants have been isolated in which one or a few ribosomal proteins are altered or even deleted. The genetic and biochemical characterization of these mutants allows conclusions about the importance of these proteins for the function of the ribosome. Ribosomal proteins from various prokaryotic and eukaryotic species have been compared by two-dimensional gel electrophoresis, immunological methods, reconstitution and amino acid sequence analysis. These studies show a strong homology among prokaryotic ribosomal proteins but only a weak homology between proteins from prokaryotic and eukaryotic ribosomes. Comparison of the primary and secondary structures of the ribosomal RNAs from various organisms shows that the secondary structure of the RNA molecules has been strongly conserved throughout evolution.     

Proteolytic susceptibility of creatine kinase isozymes and arginine kinase

The time course and dose-response to proteolysis of three dimeric isozymes of creatine kinase, CK-MM (muscle), CK-BB (brain), and CK-MB (heart) and the homologous monomer, arginine kinase were compared. Chymotrypsin and trypsin cause a rapid and significant loss of intact CK-BB, but limited hydrolysis of CK-MM. After 1h of hydrolysis by chymotrypsin, 80% of CK-MM is intact as judged by quantification of monomers after electrophoresis in sodium dodecyl sulfate. While 50% of the intact monomers of CK-MB remain under these conditions, no CK-BB monomers are detected. These results indicate that treatment with chymotrypsin leads to a CK-MB devoid of the B-subunit. When treated with trypsin for 1h, CK-MM is totally resistant to hydrolysis and all CK-BB is highly degraded. However, CK-MB exhibits approximately 90% intact monomers, indicating survival of intact B-subunit in CK-MB. This suggests that heterodimerization of a B-subunit with an M-subunit may have a protective effect against hydrolysis by trypsin. In view of the considerably larger number of potentially tryptic sensitive sites on the muscle isozyme, the resistance of CK-MM and susceptibility of CK-BB dimers to trypsin implies that differences in subunit tertiary structure are a factor in proteolysis of the homodimeric isozymes. Arginine kinase is rapidly degraded by trypsin, but is minimally affected by chymotrypsin. The finding that both a monomeric (arginine kinase) and dimeric (CK-BB) phosphagen kinase are highly susceptible to proteolysis by trypsin indicates that quaternary structure is not, in and of itself, an advantage in resistance to proteolysis. Since both arginine kinase and muscle creatine kinase are resistant to chymotryptic hydrolysis, it seems unlikely that in general, the increased packing density, which may result from dimerization can account for the stability of CK-MM towards trypsin.     

Strategies for Selection from Protein Libraries Composed of de Novo Designed Secondary Structure Modules

As more and more protein structures are determined, it has become clear that there is only a limited number of protein folds in nature. To explore whether the protein folds found in nature are the only solutions to the protein folding problem, or that a lack of evolutionary pressure causes the paucity of different protein folds found, we set out to construct protein libraries without any restriction on topology. We generated different libraries (all alpha-helix, all beta-strand and alpha-helix plus beta-strand) with an average length of 100 amino acid residues, composed of designed secondary structure modules (alpha-helix, beta-strand and beta-turn) in various proportions, based primarily on the patterning of polar and non-polar residues. From the analysis of proteins chosen randomly from the libraries, we found that a substantial portion of pure alpha-helical proteins show properties similar to native proteins. Using these libraries as a starting point, we aim to establish a selection system which allows us to enrich proteins with favorable folding properties (non-aggregating, compactly folded) from the libraries. We have developed such a method based on ribosome display. This selection is based on two concepts: (1) misfolded proteins are more sensitive to proteolysis, (2) misfolded and/or aggregated proteins are more hydrophobic. We show that by applying each of these selection criteria proteins that are compactly folded and soluble can be enriched over insoluble and random coil proteins.     

Protease accessibility laddering: a proteomic tool for probing protein structure

Limited proteolysis is widely used in biochemical and crystallographic studies to determine domain organization, folding properties, and ligand binding activities of proteins. The method has limitations, however, due to the difficulties in obtaining sufficient amounts of correctly folded proteins and in interpreting the results of the proteolysis. A new limited proteolysis method, named protease accessibility laddering (PAL), avoids these complications. In PAL, tagged proteins are purified on magnetic beads in their natively folded state. While attached to the beads, proteins are probed with proteases. Proteolytic fragments are eluted and detected by immunoblotting with antibodies against the tag (e.g., Protein A, GFP, and 6xHis). PAL readily detects domain boundaries and flexible loops within proteins. A combination of PAL and comparative protein structure modeling allows characterization of previously unknown structures (e.g., Sec31, a component of the COPII coated vesicle). PAL's high throughput should greatly facilitate structural genomic and proteomic studies.     

Global Stabilization of rRNA Structure by Ribosomal Proteins S4, S17, and S20

Ribosomal proteins stabilize the folded structure of the ribosomal RNA and enable the recruitment of further proteins to the complex. Quantitative hydroxyl radical footprinting was used to measure the extent to which three different primary assembly proteins, S4, S17, and S20, stabilize the three-dimensional structure of the Escherichia coli 16S 5′ domain. The stability of the complexes was perturbed by varying the concentration of MgCl₂. Each protein influences the stability of the ribosomal RNA tertiary interactions beyond its immediate binding site. S4 and S17 stabilize the entire 5′ domain, while S20 has a more local effect. Multistage folding of individual helices within the 5′ domain shows that each protein stabilizes a different ensemble of structural intermediates that include nonnative interactions at low Mg²⁺ concentration. We propose that the combined interactions of S4, S17, and S20 with different helical junctions bias the free-energy landscape toward a few RNA conformations that are competent to add the secondary assembly protein S16 in the next step of assembly.     

Domain structure of tropomodulin: distinct properties of the N-terminal and C-terminal halves.

The structure of tropomodulin, the unique capping protein for the pointed end (the slow-growing end) of an actin filament, was studied. An improved Escherichia coli expression system for chicken E-tropomodulin was established and tropomodulin was prepared, Tmod (N39), in which 15 amino acid residues from the original C-terminus are deleted at the DNA level. This expression and purification system accidentally co-produces an 11-kDa fragment with the original N-terminus (N11). By applying limited proteolysis to Tmod (N39), a 20-kDa C-terminal fragment (C20) was obtained. The limited proteolysis data, as well as the fluorescence spectrometry and CD analyses of Tmod (N39), C20 and N11, revealed that tropomodulin is an alpha-helical protein that consists of two distinct domains. The C-terminal half (20 kDa) is resistant to proteolysis, which suggests that this domain is tightly folded. In contrast, the N-terminal half is susceptible to proteolysis, indicating that in solution this half is likely to be extended or to form a highly flexible structure. Cross-linking experiments with glutaraldehyde indicated that Tmod (N39) and N11 can form complexes with tropomyosin, whereas C20 cannot. This confirms the previous report that the site(s) of interaction with tropomyosin resides in the N-terminal 11-kDa region of tropomodulin.     

Determination of peptide regions on the surface of the eubacterial and archaebacterial ribosome by limited proteolytic digestion.

Limited proteolysis was used in combination with two-dimensional gel electrophoresis, blotting, and amino acid sequence analysis to investigate the surface of intact ribosomal subunits at the peptide and amino acid level. Surface sites of 14 ribosomal proteins from Escherichia coli 50S subunits were determined using proteases with different specificities. To assess the evolutionary conservation of ribosomal topography among eubacteria, large subunits from Bacillus stearothermophilus were also subjected to limited proteolysis. The results obtained indicate a conservation of the three-dimensional ribosomal structure at the peptide level. The data for the eubacterial ribosomes are in full agreement with the model of the 50S protein topography derived from immunological data. Furthermore, peptide surface regions of archaebacterial ribosomes have been investigated. The results presented in this work prove that limited proteolysis can successfully be applied to halophilic and thermophilic ribosomes from archaebacteria.     

Limited proteolysis analysis of the ribosome is affected by subunit association

Our understanding of the structural organization of ribosome assembly intermediates, in particular those intermediates that result from misfolding leading to their eventual degradation within the cell, is limited because of the lack of methods available to characterize assembly intermediate structures. Because conventional structural approaches, such as NMR, X‐ray crystallography, and cryo‐EM, are not ideally suited to characterize the structural organization of these flexible and sometimes heterogeneous assembly intermediates, we have set out to develop an approach combining limited proteolysis with matrix‐assisted laser desorption/ionization mass spectrometry (MALDI‐MS) that might be applicable to ribonucleoprotein complexes as large as the ribosome. This study focuses on the limited proteolysis behavior of appropriately assembled ribosome subunits. Isolated subunits were analyzed using limited proteolysis and MALDI‐MS and the results were compared with previous data obtained from 70S ribosomes. Generally, ribosomal proteins were found to be more stable in 70S ribosomes than in their isolated subunits, consistent with a reduction in conformational flexibility on subunit assembly. This approach demonstrates that limited proteolysis combined with MALDI‐MS can reveal structural changes to ribosomes on subunit assembly or disassembly, and provides the appropriate benchmark data from 30S, 50S, and 70S proteins to enable studies of ribosome assembly intermediates. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 410–422, 2009. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

The proteasome: a macromolecular assembly designed for controlled proteolysis

In eukaryotic cells, the vast majority of proteins in the cytosol and nucleus are degraded via the proteasome-ubiquitin pathway. The 26S proteasome is a huge protein degradation machine of 2.5 MDa, built of approximately 35 different subunits. It contains a proteolytic core complex, the 20S proteasome and one or two 19S regulatory complexes which associate with the termini of the barrel-shaped 20S core. The 19S regulatory complex serves to recognize ubiquitylated target proteins and is implicated to have a role in their unfolding and translocation into the interior of the 20S complex where they are degraded into oligopeptides. While much progress has been made in recent years in elucidating the structure, assembly and enzymatic mechanism of the 20S complex, our knowledge of the functional organization of the 19S regulator is rather limited. Most of its subunits have been identified, but specific functions can be assigned to only a few of them.     

Structure and stability of the neurotoxin PV2 from the eggs of the apple snail Pomacea canaliculata

There is little information on the egg proteins of gastropod mollusks. Here we focus on PV2, a novel neurotoxin from snail eggs, studying its size, shape, structure, and stability, using small angle X-ray scattering (SAXS), absorption and fluorescence spectroscopy, circular dichroism, electron microscopy and partial proteolysis. Results indicate that PV2 is a compact and well folded oligomer of 130 × 44 Å. It is an octamer of four 98 kDa heterodimers composed of 67 and 31 kDa subunits. Subunits are held together by disulfide bonds. Dimers are assembled into native PV2 by non-covalent forces. The larger subunit is more susceptible to proteolysis, indicating it is less compactly folded and/or more exposed. Quenching of tryptophan fluorescence showed a single class of tryptophyl side chains occluded in hydrophobic regions. Native structure shows loss of secondary structure (α+β) at 6 M urea or 60–70 °C; the effects on the quaternary structure suggest an unfolding without disassembling of the protein. The 3D model of PV2 presented here is the first for an egg proteinaceous neurotoxin in animals.     

The transmembrane anchor of the T-cell antigen receptor beta chain contains a structural determinant of pre-Golgi proteolysis.

Studies with the T-cell antigen receptor (TCR) have shown that the endoplasmic reticulum, or an organelle closely associated with it, can retain and degrade membrane proteins selectively. The observation that only three (alpha, beta, and delta) of the six (alpha beta gamma delta epsilon zeta) subunits of the TCR are susceptible to proteolysis implies that structural features within the labile proteins mark them for degradation. The TCR beta chain is degraded in the endoplasmic reticulum, and, in this study, we have started to define the domains of the protein that make it susceptible to proteolysis. The experiments show that the transmembrane anchor and short five-amino-acid cytoplasmic tail of the protein contain a dominant determinant of proteolysis. When these residues were removed from the beta chain, the protein became resistant to proteolysis. Even though the resulting ectodomain of the beta chain lacked a transmembrane anchor, it was not secreted by cells and was retained in the endoplasmic reticulum. We conclude that retention in the endoplasmic reticulum alone does not lead to degradation. The results suggest that structural features within the membrane anchor of the protein predispose the beta chain to proteolysis. This was confirmed by replacing the membrane anchor of the interleukin 2 (IL2) receptor, a protein that was stable within the secretory pathway, with that of the TCR beta chain. The unmodified IL2 receptor was transported efficiently to the surface of cells, and an "anchor minus" construct was secreted quantitatively into the culture media. When the membrane anchor of the IL2 receptor was replaced with that of the TCR beta chain, the chimera was unable to reach the Golgi apparatus and was degraded rapidly.     

Preliminary structural studies of the hydrophobic ribosomal P0 protein from Trypanosoma cruzi, a part of the P0/P1/P2 complex

The Trypanosoma cruzi ribosomal P0 protein (TcP0) is part of the ribosomal stalk, which is an elongated lateral protuberance of the large ribosomal subunit involved in the translocation step of protein synthesis. The TcP0 C-terminal peptide is highly antigenic and a major target of the antibody response in patients with systemic lupus erythematosus and patients suffering chronic heart disease produced by Trypanosoma cruzi infection. The structural properties of TcP0 have been explored by circular dichroism, tryptophan fluorescence and limited proteolysis experiments. These studies were complemented by secondary structure consensus prediction analysis. The results suggest that the tertiary structure of TcP0 could be described as a compact, stable, trypsin-resistant, 200 residues long N-terminal domain belonging to the alpha/beta class and a more flexible, degradable, helical, 123 residues long C-terminal domain which could be involved in the formation of an unusual hydrophobic zipper with the ribosomal P1/P2 proteins to form the P0/P1/P2 complex.     

Degradation of the Twin-Arginine Translocation Substrate YwbN by Extracytoplasmic Proteases of Bacillus subtilis

Bacterial twin-arginine translocases can export fully folded proteins from the cytoplasm. Such proteins are usually resistant to proteolysis. Here we show that multiple extracellular proteases degrade the B. subtilis Tat substrate YwbN. This suggests either that secreted YwbN is not fully folded or that folded YwbN exposes protease cleavage sites.     

Structural properties of substrate proteins determine their proteolysis by the mitochondrial AAA+ protease Pim1

The protease Pim1/LON, a member of the AAA+ family of homo-oligomeric ATP-dependent proteases, is responsible for the degradation of soluble proteins in the mitochondrial matrix. To establish the molecular parameters required for the specific recognition and proteolysis of substrate proteins by Pim1, we analyzed the in organello degradation of imported reporter proteins containing different structural properties. The amino acid composition at the amino-terminal end had no major effect on the proteolysis reaction. However, proteins with an amino-terminal extension of less than 60 amino acids in front of a stably folded reporter domain were completely resistant to proteolysis by Pim1. Substrate proteins with a longer amino-terminal extension showed incomplete proteolysis, resulting in the generation of a defined degradation fragment. We conclude that Pim1-mediated protein degradation is processive and is initiated from an unstructured amino-terminal segment. Resistance to degradation and fragment formation was abolished if the folding state of the reporter domain was destabilized, indicating that Pim1 is not able to unravel folded proteins for proteolysis. We propose that the requirement for an exposed, large, non-native protein segment, in combination with a limited unfolding capability, accounts for the selectivity of the protease Pim1 for damaged or misfolded polypeptides.     

Selection based on the folding properties of proteins with ribosome display

Ribosome display is a powerful tool for selecting and evolving protein functions through ligand-binding. Here, this in vitro system was used to perform selection based on the folding properties of proteins, independent of specific ligand-binding. The selection is based on two properties of misfolded proteins: (1) increased sensitivity to proteolysis and (2) greater exposure of hydrophobic area. By targeting these properties, we show that compactly folded and soluble proteins can be enriched over insoluble and random coil proteins. This approach may be especially useful for selection and evolution of folded proteins from random sequence libraries.