Andreas Matouschek

The folding of an enzyme: I. Theory of protein engineering analysis of stability and pathway of protein folding

The theory, assumptions and limitations are outlined for a simple protein engineering approach to the problem of the stability and pathway of protein folding. It is a general procedure for analysing structure-activity relationships in non-covalent bonding, including enzyme catalysis, that relates experimentally accessible data to changes in non-covalent bonding. Kinetic and equilibrium measurements on the unfolding and refolding of mutant proteins can be used to map the formation of structure in transition states and folding intermediates. For example, the ratio of the changes in the activation energy of unfolding and the free energy of unfolding on mutation is measured to give a parameter phi. There are two extreme values of phi that are often found in practice and may be interpreted in a simple manner. A value of phi = 0 implies that the structure at the site of mutation is as folded in the transition state as it is in the folded state. Conversely, phi = 1 shows that the structure at the site of mutation is as unfolded in the transition state as it is in the unfolded structure. Fractional values of phi are more difficult to interpret and require a more sophisticated approach. The most suitable mutations involve truncation of side-chains to remove moieties that preferably make few interactions with the rest of the protein and do not pair with buried charges. Fractional values of phi found for this type of mutation may imply that there is partial non-covalent bond formation or a mixture of states. The major assumptions of the method are: (1) mutation does not alter the pathway of folding; (2) mutation does not significantly change the structure of the folded state; (3) mutation does not perturb the structure of the unfolded state; and (4) the target groups do not make new interactions with new partners during the course of reaction energy. Assumptions (2) and (3) are not necessarily essential for the simple cases of phi = 0 or 1, the most common values, since effects of disruption of structure can cancel out. Assumption (4) may be checked by the double-mutant cycle procedure, which may be analysed to isolate the effects of just a pair of interactions against a complicated background. This analysis provides the formal basis of the accompanying studies on the stability and pathway of folding of barnase, where it is seen that the theory holds very well in practice.

The folding of an enzyme. II. Substructure of barnase and the contribution of different interactions to protein stability

Barnase is described anatomically in terms of its substructures and their mode of packing. The surface area of hydrophobic residues buried on formation and packing of the structural elements has been calculated. Changes in stability have been measured for 64 mutations, 41 constructed in this study, strategically located over the protein. The purpose is to provide: (1) information on the magnitudes of changes in stabilization energy for mutations of residues that are important in maintaining the structure; and (2) probes for the folding pathway to be used in subsequent studies. The majority of mutations delete functional moieties of side-chains or make isosteric changes. The energetics of the interactions are variable and context-dependent. The following general conclusions may be drawn, however, from this study about the classes of interactions that stabilize the protein. (1) Truncation of buried hydrophobic side-chains has, in general, the greatest effect on stability. For fully buried residues, this averages at 1.5 kcal mol-1 per methylene group with a standard deviation of +/- 0.6 kcal mol-1. Truncation of partly exposed leucine, isoleucine or valine residues that are in the range of 50 to 80 A2 of solvent-accessible area (30 to 50% of the total solvent-accessible area on a Gly-X-Gly tripeptide, i.e. those packed against the surface) has a smaller, but relatively constant effect on stability, at 0.81 kcal mol-1 per methylene group with a statistical standard deviation of +/- 0.18 kcal mol-1. (2) There is a very poor correlation between hydrophobic surface area buried and the free energy change for an extensive data set of hydrophobic mutants. The best correlation is found to be between the free energy change and the number of methylene groups within a 6 A radius of the hydrophobic groups deleted. (3) Burial of the hydroxyl group of threonine in a pocket that is intended for a gamma-methyl group of valine costs 2.5 kcal mol-1, in the range expected for the loss of two hydrogen bonds.(ABSTRACT TRUNCATED AT 400 WORDS)

ATP-dependent proteases degrade their substrates by processively unraveling them from the degradation signal.

Protein unfolding is a key step in several cellular processes, including protein translocation across some membranes and protein degradation by ATP-dependent proteases. ClpAP protease and the proteasome can actively unfold proteins in a process that hydrolyzes ATP. Here we show that these proteases seem to catalyze unfolding by processively unraveling their substrates from the attachment point of the degradation signal. As a consequence, the ability of a protein to be degraded depends on its structure as well as its stability. In multidomain proteins, independently stable domains are unfolded sequentially. We show that these results can explain the limited degradation by the proteasome that occurs in the processing of the precursor of the transcription factor NF-kappaB.

Aggregated and Monomeric α-Synuclein Bind to the S6′ Proteasomal Protein and Inhibit Proteasomal Function

The accumulation of aggregated α-synuclein is thought to contribute to the pathophysiology of Parkinsons disease, but the mechanism of toxicity is poorly understood. Recent studies suggest that aggregated proteins cause toxicity by inhibiting the ubiquitin-dependent proteasomal system. In the present study, we explore how α-synuclein interacts with the proteasome. The proteasome exists as a 26 S and a 20 S species. The 26 S proteasome is composed of the 19 S cap and the 20 S core. Aggregated α-synuclein strongly inhibited the function of the 26 S proteasome. The IC50 of aggregated α-synuclein for ubiquitin-independent 26 S proteasomal activity was 1 nm. Aggregated α-synuclein also inhibited 26 S ubiquitin-dependent proteasomal activity at a dose of 500 nm. In contrast, the IC50 of aggregated α-synuclein for 20 S proteasomal activity was > 1 μm. This suggests that aggregated α-synuclein selectively interacts with the 19 S cap. Monomeric α-synuclein also inhibited proteasomal activity but with lower affinity and less potency. Recombinant monomeric α-synuclein inhibited the activity of the 20 S proteasomal core with an IC50 > 10 μm, exhibited no inhibition of 26 S ubiquitin-dependent proteasomal activity at doses up to 5 μm, and exhibited only partial inhibition (50%) of the 26 S ubiquitin-independent proteasomal activity at doses up to 10 mm. Binding studies demonstrate that both aggregated and monomeric α-synuclein selectively bind to the proteasomal protein S6′, a subunit of the 19 S cap. These studies suggest that proteasomal inhibition by aggregated α-synuclein could be mediated by interaction with S6′.

An unstructured initiation site is required for efficient proteasome-mediated degradation.

The proteasome is the main ATP-dependent protease in eukaryotic cells and controls the concentration of many regulatory proteins in the cytosol and nucleus. Proteins are targeted to the proteasome by the covalent attachment of polyubiquitin chains. The ubiquitin modification serves as the proteasome recognition element but by itself is not sufficient for efficient degradation of folded proteins. We report that proteolysis of tightly folded proteins is accelerated greatly when an unstructured region is attached to the substrate. The unstructured region serves as the initiation site for degradation and is hydrolyzed first, after which the rest of the protein is digested sequentially. These results identify the initiation site as a novel component of the targeting signal, which is required to engage the proteasome unfolding machinery efficiently. The proteasome degrades a substrate by first binding to its ubiquitin modification and then initiating unfolding at an unstructured region.

Inefficient degradation of truncated polyglutamine proteins by the proteasome

Accumulation of mutant proteins into misfolded species and aggregates is characteristic for diverse neurodegenerative diseases including the polyglutamine diseases. While several studies have suggested that polyglutamine protein aggregates impair the ubiquitin–proteasome system, the molecular mechanisms underlying the interaction between polyglutamine proteins and the proteasome have remained elusive. In this study, we use fluorescence live‐cell imaging to demonstrate that the proteasome is sequestered irreversibly within aggregates of overexpressed N‐terminal mutant Huntingtin fragment or simple polyglutamine expansion proteins. Moreover, by direct targeting of polyglutamine proteins for proteasomal degradation, we observe incomplete degradation of these substrates both in vitro and in vivo. Thus, our data reveal that intrinsic properties of the polyglutamine proteins prevent their efficient degradation and clearance. Additionally, fluorescence resonance energy transfer is detected between the proteasome and aggregated polyglutamine proteins indicative of a close and stable interaction. We propose that polyglutamine‐containing proteins are kinetically trapped within proteasomes, which could explain their deleterious effects on cellular function over time.

The folding of an enzyme. III: Structure of the transition state for unfolding of barnase analysed by a protein engineering procedure

The structure of the first significant transition state on the unfolding pathway of barnase has been analysed in detail by protein engineering methods. Over 50 mutations placed strategically over the whole protein have been used as probes to report on the local structure in the transition state. Several different probes for many regions of the protein give consistent results as do multiple probes at the same site. The overall consistency of phi values indicates that the mutations have not produced changes in the protein that significantly alter the transition state for unfolding. A fine-structure analysis of interactions has also been conducted by removing different parts of the same side-chains. Many of the results of simple mutations fall nicely into the two clear-cut cases of phi = 1 or 0, indicating that the local noncovalent bonds are either fully broken or fully made in the transition state. Much of the structure of barnase in the transition state for unfolding is very similar to that in the folded protein. Both major alpha-helices fray at the N terminus. The last two turns in helix1 are certainly intact, as is the C terminus of helix2. The general picture of the beta-sheet is that the three central beta-strands are completely intact while the two edge beta-strands are mainly present but certainly weakened. The first five residues of the protein unwind but the C terminus remains folded. Three of the five loops are unfolded. The edges of the main hydrophobic core (core1) are significantly weakened, however, and their breaking appears partly rate determining. The centre of the small hydrophobic core3 remains intact. Core2 is completely disrupted. The first events in unfolding are thus: the unfolding of several loops, the unwinding of the helices from the N termini, and the weakening and disruption of the hydrophobic cores. The values of phi are found to be substantially the same under conditions that favour folding as under conditions that are highly denaturing, and so the structure of the unfolding transition state is substantially the same in water as in the presence of denaturant. The structure of the final kinetically significant transition state for refolding is identical to that for unfolding. The final events in refolding are, accordingly, the consolidation of the hydrophobic cores, the closing of many loops and the capping of the N termini of the helices.

The folding of an enzyme. IV. Structure of an intermediate in the refolding of barnase analysed by a protein engineering procedure

The pathway of refolding of barnase has been analysed by the protein engineering method using phi plots. The description comprises a folding intermediate, a major transition state (the unfolding transition state) and the fully folded structure. Over 40 mutations have been analysed in the different structural motifs, frequently with several probes in each region. Many of the mutations in this study give phi values for formation of the intermediate of 0, showing that the relevant regions of the structure are as fully unfolded in the intermediate as the unfolded state. Some folding phi values are close to unity, indicating that those regions are fully formed in the intermediate. Even if the data do not report back on a single intermediate but give the averaged properties of a heterogeneous population of sequential or parallel intermediates, then this simplicity of phi data shows that the intermediates tend to have structural features in common. Many phi values are intermediate between those for the unfolded state and the transition state, consistent with either partial structure formation in a single intermediate or a heterogeneous mixture of populations, although the former is more likely. The data are consistent with the intermediate, or collection of intermediates, being on the reaction pathway, rather than side products, because the phi values increase throughout the folding pathway. The main conclusions on the formation of substructure and sequence of folding events from the phi plots are as follows. (1) The major hydrophobic core (core1) begins to form in the intermediate and strengthens in the major transition state. The centre of the core is formed earlier and is stronger in the intermediate and in the transition state than are the edges. (2) Core2 is not formed until after the major transition state. (3) Core3 begins to form in the intermediate and is compact in the transition state. (4) Loop2, loop4 and part of loop1 do not fold until after the major transition state, but the guanosine-binding loop (loop3) is formed in the intermediate and loop5 is partially formed in the intermediate and the transition state. (5) The centre of the beta-sheet is substantially formed in the intermediate, and is fully present in the transition state, but the edges, and associated turns, are definitely weakened.(ABSTRACT TRUNCATED AT 400 WORDS)

Targeting proteins for degradation

Protein degradation plays a central role in many cellular functions. Misfolded and damaged proteins are removed from the cell to avoid toxicity. The concentrations of regulatory proteins are adjusted by degradation at the appropriate time. Both foreign and native proteins are digested into small peptides as part of the adaptive immune response. In eukaryotic cells, an ATP-dependent protease called the proteasome is responsible for much of this proteolysis. Proteins are targeted for proteasomal degradation by a two-part degron, which consists of a proteasome binding signal and a degradation initiation site. Here we describe how both components contribute to the specificity of degradation.

Lack of a Robust Unfoldase Activity Confers a Unique Level of Substrate Specificity to the Universal AAA Protease FtsH

FtsH, a member of the AAA family of proteins, is the only membrane ATP-dependent protease universally conserved in prokaryotes, and the only essential ATP-dependent protease in Escherichia coli. We investigated the mechanism of degradation by FtsH. Other well-studied ATP-dependent proteases use ATP to unfold their substrates. In contrast, both in vitro and in vivo studies indicate that degradation by FtsH occurs efficiently only when the substrate is a protein of low intrinsic thermodynamic stability. Because FtsH lacks robust unfoldase activity, it is able to use the protein folding state of substrates as a criterion for degradation. This feature may be key to its role in the cell and account for its ubiquitous distribution among prokaryotic organisms.