Your search keyword '"S Walter"' showing total 134 results

1. HX and Me: Understanding Allostery, Folding, and Protein Machines.

Author

Englander SW

Subjects

Biophysics, Protein Folding

Abstract

My accidental encounter with protein hydrogen exchange (HX) at its very beginning and its continued development through my scientific career have led us to a series of advances in HX measurement, interpretation, and cutting edge biophysical applications. After some thoughts about how life brought me there, I take the opportunity to reflect on our early studies of allosteric structure and energy change in hemoglobin, the still-current protein folding problem, and our most recent forward-looking studies on protein machines.

Published

2023

2. Folding of maltose binding protein outside of and in GroEL.

Author

Ye X, Mayne L, Kan ZY, and Englander SW

Subjects

Adenosine Triphosphate metabolism, Chaperonin 60 chemistry, Chaperonin 60 genetics, Escherichia coli genetics, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Kinetics, Maltose-Binding Proteins genetics, Maltose-Binding Proteins metabolism, Protein Binding, Protein Conformation, Chaperonin 60 metabolism, Escherichia coli chemistry, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Maltose-Binding Proteins chemistry, Protein Folding

Abstract

We used hydrogen exchange-mass spectrometry (HX MS) and fluorescence to compare the folding of maltose binding protein (MBP) in free solution and in the GroEL/ES cavity. Upon refolding, MBP initially collapses into a dynamic molten globule-like ensemble, then forms an obligatory on-pathway native-like folding intermediate (1.2 seconds) that brings together sequentially remote segments and then folds globally after a long delay (30 seconds). A single valine to glycine mutation imposes a definable folding defect, slows early intermediate formation by 20-fold, and therefore subsequent global folding by approximately twofold. Simple encapsulation within GroEL repairs the folding defect and reestablishes fast folding, with or without ATP-driven cycling. Further examination exposes the structural mechanism. The early folding intermediate is stabilized by an organized cluster of 24 hydrophobic side chains. The cluster preexists in the collapsed ensemble before the H-bond formation seen by HX MS. The V9G mutation slows folding by disrupting the preintermediate cluster. GroEL restores wild-type folding rates by restabilizing the preintermediate, perhaps by a nonspecific equilibrium compression effect within its tightly confining central cavity. These results reveal an active GroEL function other than previously proposed mechanisms, suggesting that GroEL possesses different functionalities that are able to relieve different folding problems. The discovery of the preintermediate, its mutational destabilization, and its restoration by GroEL encapsulation was made possible by the measurement of a previously unexpected type of low-level HX protection, apparently not dependent on H-bonding, that may be characteristic of proteins in confined spaces., Competing Interests: The authors declare no conflict of interest., (Copyright © 2018 the Author(s). Published by PNAS.)

Published

2018

3. The case for defined protein folding pathways.

Author

Englander SW and Mayne L

Subjects

Cytochromes c chemistry, Cytochromes c metabolism, Kinetics, Nuclear Magnetic Resonance, Biomolecular, Ribonuclease H chemistry, Ribonuclease H metabolism, Models, Molecular, Protein Folding, Proteins chemistry, Proteins metabolism

Abstract

We consider the differences between the many-pathway protein folding model derived from theoretical energy landscape considerations and the defined-pathway model derived from experiment. A basic tenet of the energy landscape model is that proteins fold through many heterogeneous pathways by way of amino acid-level dynamics biased toward selecting native-like interactions. The many pathways imagined in the model are not observed in the structure-formation stage of folding by experiments that would have found them, but they have now been detected and characterized for one protein in the initial prenucleation stage. Analysis presented here shows that these many microscopic trajectories are not distinct in any functionally significant way, and they have neither the structural information nor the biased energetics needed to select native vs. nonnative interactions during folding. The opposed defined-pathway model stems from experimental results that show that proteins are assemblies of small cooperative units called foldons and that a number of proteins fold in a reproducible pathway one foldon unit at a time. Thus, the same foldon interactions that encode the native structure of any given protein also naturally encode its particular foldon-based folding pathway, and they collectively sum to produce the energy bias toward native interactions that is necessary for efficient folding. Available information suggests that quantized native structure and stepwise folding coevolved in ancient repeat proteins and were retained as a functional pair due to their utility for solving the difficult protein folding problem., Competing Interests: The authors declare no conflict of interest.

Published

2017

4. Cytochrome c folds through foldon-dependent native-like intermediates in an ordered pathway.

Author

Hu W, Kan ZY, Mayne L, and Englander SW

Subjects

Kinetics, Models, Molecular, Cytochromes c metabolism, Protein Folding, Thermodynamics

Abstract

Previous hydrogen exchange (HX) studies of the spontaneous reversible unfolding of Cytochrome c (Cyt c) under native conditions have led to the following conclusions. Native Cyt c (104 residues) is composed of five cooperative folding units, called foldons. The high-energy landscape is dominated by an energy ladder of partially folded forms that differ from each other by one cooperative foldon unit. The reversible equilibrium unfolding of native Cyt c steps up through these intermediate forms to the unfolded state in an energy-ordered sequence, one foldon unit at a time. To more directly study Cyt c intermediates and pathways during normal energetically downhill kinetic folding, the present work used HX pulse labeling analyzed by a fragment separation-mass spectrometry method. The results show that 95% or more of the Cyt c population folds by stepping down through the same set of foldon-dependent pathway intermediates as in energetically uphill equilibrium unfolding. These results add to growing evidence that proteins fold through a classical pathway sequence of native-like intermediates rather than through a vast number of undefinable intermediates and pathways. The present results also emphasize the condition-dependent nature of kinetic barriers, which, with less informative experimental methods (fluorescence, etc.), are often confused with variability in intermediates and pathways.

Published

2016

5. The nature of protein folding pathways.

Author

Englander SW and Mayne L

Subjects

Kinetics, Models, Chemical, Protein Folding

Abstract

How do proteins fold, and why do they fold in that way? This Perspective integrates earlier and more recent advances over the 50-y history of the protein folding problem, emphasizing unambiguously clear structural information. Experimental results show that, contrary to prior belief, proteins are multistate rather than two-state objects. They are composed of separately cooperative foldon building blocks that can be seen to repeatedly unfold and refold as units even under native conditions. Similarly, foldons are lost as units when proteins are destabilized to produce partially unfolded equilibrium molten globules. In kinetic folding, the inherently cooperative nature of foldons predisposes the thermally driven amino acid-level search to form an initial foldon and subsequent foldons in later assisted searches. The small size of foldon units, ∼ 20 residues, resolves the Levinthal time-scale search problem. These microscopic-level search processes can be identified with the disordered multitrack search envisioned in the "new view" model for protein folding. Emergent macroscopic foldon-foldon interactions then collectively provide the structural guidance and free energy bias for the ordered addition of foldons in a stepwise pathway that sequentially builds the native protein. These conclusions reconcile the seemingly opposed new view and defined pathway models; the two models account for different stages of the protein folding process. Additionally, these observations answer the "how" and the "why" questions. The protein folding pathway depends on the same foldon units and foldon-foldon interactions that construct the native structure.

Published

2014

6. Folding of a large protein at high structural resolution.

Author

Walters BT, Mayne L, Hinshaw JR, Sosnick TR, and Englander SW

Subjects

Mass Spectrometry methods, Protein Denaturation, Scattering, Small Angle, Escherichia coli chemistry, Maltose-Binding Proteins chemistry, Models, Molecular, Protein Conformation, Protein Folding

Abstract

Kinetic folding of the large two-domain maltose binding protein (MBP; 370 residues) was studied at high structural resolution by an advanced hydrogen-exchange pulse-labeling mass-spectrometry method (HX MS). Dilution into folding conditions initiates a fast molecular collapse into a polyglobular conformation (<20 ms), determined by various methods including small angle X-ray scattering. The compaction produces a structurally heterogeneous state with widespread low-level HX protection and spectroscopic signals that match the equilibrium melting posttransition-state baseline. In a much slower step (7-s time constant), all of the MBP molecules, although initially heterogeneously structured, form the same distinct helix plus sheet folding intermediate with the same time constant. The intermediate is composed of segments that are distant in the MBP sequence but adjacent in the native protein where they close the longest residue-to-residue contact. Segments that are most HX protected in the early molecular collapse do not contribute to the initial intermediate, whereas the segments that do participate are among the less protected. The 7-s intermediate persists through the rest of the folding process. It contains the sites of three previously reported destabilizing mutations that greatly slow folding. These results indicate that the intermediate is an obligatory step on the MBP folding pathway. MBP then folds to the native state on a longer time scale (~100 s), suggestively in more than one step, the first of which forms structure adjacent to the 7-s intermediate. These results add a large protein to the list of proteins known to fold through distinct native-like intermediates in distinct pathways.

Published

2013

7. Stepwise protein folding at near amino acid resolution by hydrogen exchange and mass spectrometry.

Author

Hu W, Walters BT, Kan ZY, Mayne L, Rosen LE, Marqusee S, and Englander SW

Subjects

Biophysics methods, Escherichia coli enzymology, Hydrogen-Ion Concentration, Peptides chemistry, Protein Denaturation, Software, Amino Acids chemistry, Hydrogen chemistry, Mass Spectrometry methods, Protein Folding, Ribonuclease H chemistry

Abstract

The kinetic folding of ribonuclease H was studied by hydrogen exchange (HX) pulse labeling with analysis by an advanced fragment separation mass spectrometry technology. The results show that folding proceeds through distinct intermediates in a stepwise pathway that sequentially incorporates cooperative native-like structural elements to build the native protein. Each step is seen as a concerted transition of one or more segments from an HX-unprotected to an HX-protected state. Deconvolution of the data to near amino acid resolution shows that each step corresponds to the folding of a secondary structural element of the native protein, termed a "foldon." Each folded segment is retained through subsequent steps of foldon addition, revealing a stepwise buildup of the native structure via a single dominant pathway. Analysis of the pertinent literature suggests that this model is consistent with experimental results for many proteins and some current theoretical results. Two biophysical principles appear to dictate this behavior. The principle of cooperativity determines the central role of native-like foldon units. An interaction principle termed "sequential stabilization" based on native-like interfoldon interactions orders the pathway.

Published

2013

8. The foldon substructure of staphylococcal nuclease.

Author

Bédard S, Mayne LC, Peterson RW, Wand AJ, and Englander SW

Subjects

Amides, Circular Dichroism, Fluorescence, Hydrogen, Kinetics, Mutant Proteins chemistry, Mutant Proteins metabolism, Protein Denaturation, Thermodynamics, Time Factors, Micrococcal Nuclease chemistry, Micrococcal Nuclease metabolism, Protein Folding, Staphylococcus aureus enzymology

Abstract

To search for submolecular foldon units, the spontaneous reversible unfolding and refolding of staphylococcal nuclease under native conditions was studied by a kinetic native-state hydrogen exchange (HX) method. As for other proteins, it appears that staphylococcal nuclease is designed as an assembly of well-integrated foldon units that may define steps in its folding pathway and may regulate some other functional properties. The HX results identify 34 amide hydrogens that exchange with solvent hydrogens under native conditions by way of large transient unfolding reactions. The HX data for each hydrogen measure the equilibrium stability (Delta G(HX)) and the kinetic unfolding and refolding rates (k(op) and k(cl)) of the unfolding reaction that exposes it to exchange. These parameters separate the 34 identified residues into three distinct HX groupings. Two correspond to clearly defined structural units in the native protein, termed the blue and red foldons. The remaining HX grouping contains residues, not well separated by their HX parameters alone, that represent two other distinct structural units in the native protein, termed the green and yellow foldons. Among these four sets, a last unfolding foldon (blue) unfolds with a rate constant of 6 x 10(-6) s(-1) and free energy equal to the protein's global stability (10.0 kcal/mol). It represents part of the beta-barrel, including mutually H-bonding residues in the beta 4 and beta 5 strands, a part of the beta 3 strand that H-bonds to beta 5, and residues at the N-terminus of the alpha2 helix that is capped by beta 5. A second foldon (green), which unfolds and refolds more rapidly and at slightly lower free energy, includes residues that define the rest of the native alpha2 helix and its C-terminal cap. A third foldon (yellow) defines the mutually H-bonded beta1-beta2-beta 3 meander, completing the native beta-barrel, plus an adjacent part of the alpha1 helix. A final foldon (red) includes residues on remaining segments that are distant in sequence but nearly adjacent in the native protein. Although the structure of the partially unfolded forms closely mimics the native organization, four residues indicate the presence of some nonnative misfolding interactions. Because the unfolding parameters of many other residues are not determined, it seems likely that the concerted foldon units are more extensive than is shown by the 34 residues actually observed.

Published

2008

9. Protein folding and misfolding: mechanism and principles.

Author

Englander SW, Mayne L, and Krishna MM

Subjects

Models, Molecular, Proteins chemistry, Protein Folding

Abstract

Two fundamentally different views of how proteins fold are now being debated. Do proteins fold through multiple unpredictable routes directed only by the energetically downhill nature of the folding landscape or do they fold through specific intermediates in a defined pathway that systematically puts predetermined pieces of the target native protein into place? It has now become possible to determine the structure of protein folding intermediates, evaluate their equilibrium and kinetic parameters, and establish their pathway relationships. Results obtained for many proteins have serendipitously revealed a new dimension of protein structure. Cooperative structural units of the native protein, called foldons, unfold and refold repeatedly even under native conditions. Much evidence obtained by hydrogen exchange and other methods now indicates that cooperative foldon units and not individual amino acids account for the unit steps in protein folding pathways. The formation of foldons and their ordered pathway assembly systematically puts native-like foldon building blocks into place, guided by a sequential stabilization mechanism in which prior native-like structure templates the formation of incoming foldons with complementary structure. Thus the same propensities and interactions that specify the final native state, encoded in the amino-acid sequence of every protein, determine the pathway for getting there. Experimental observations that have been interpreted differently, in terms of multiple independent pathways, appear to be due to chance misfolding errors that cause different population fractions to block at different pathway points, populate different pathway intermediates, and fold at different rates. This paper summarizes the experimental basis for these three determining principles and their consequences. Cooperative native-like foldon units and the sequential stabilization process together generate predetermined stepwise pathways. Optional misfolding errors are responsible for 3-state and heterogeneous kinetic folding.

Published

2007

10. Branching in the sequential folding pathway of cytochrome c.

Author

Krishna MM, Maity H, Rumbley JN, and Englander SW

Subjects

Amides chemistry, Animals, Deuterium Exchange Measurement, Enzyme Stability, Horses, Hydrogen-Ion Concentration, Models, Biological, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Oxidation-Reduction, Protein Denaturation, Protein Structure, Secondary, Cytochromes c chemistry, Cytochromes c metabolism, Protein Folding

Abstract

Previous results indicate that the folding pathways of cytochrome c and other proteins progressively build the target native protein in a predetermined stepwise manner by the sequential formation and association of native-like foldon units. The present work used native state hydrogen exchange methods to investigate a structural anomaly in cytochrome c results that suggested the concerted folding of two segments that have little structural relationship in the native protein. The results show that the two segments, an 18-residue omega loop and a 10-residue helix, are able to unfold and refold independently, which allows a branch point in the folding pathway. The pathway that emerges assembles native-like foldon units in a linear sequential manner when prior native-like structure can template a single subsequent foldon, and optional pathway branching is seen when prior structure is able to support the folding of two different foldons.

Published

2007

11. A unified mechanism for protein folding: predetermined pathways with optional errors.

Author

Krishna MM and Englander SW

Subjects

Egg Proteins chemistry, Kinetics, Muramidase chemistry, Models, Biological, Protein Folding

Abstract

There is a fundamental conflict between two different views of how proteins fold. Kinetic experiments and theoretical calculations are often interpreted in terms of different population fractions folding through different intermediates in independent unrelated pathways (IUP model). However, detailed structural information indicates that all of the protein population folds through a sequence of intermediates predetermined by the foldon substructure of the target protein and a sequential stabilization principle. These contrary views can be resolved by a predetermined pathway--optional error (PPOE) hypothesis. The hypothesis is that any pathway intermediate can incorporate a chance misfolding error that blocks folding and must be reversed for productive folding to continue. Different fractions of the protein population will then block at different steps, populate different intermediates, and fold at different rates, giving the appearance of multiple unrelated pathways. A test of the hypothesis matches the two models against extensive kinetic folding results for hen lysozyme which have been widely cited in support of independent parallel pathways. The PPOE model succeeds with fewer fitting constants. The fitted PPOE reaction scheme leads to known folding behavior, whereas the IUP properties are contradicted by experiment. The appearance of a conflict with multipath theoretical models seems to be due to their different focus, namely on multitrack microscopic behavior versus cooperative macroscopic behavior. The integration of three well-documented principles in the PPOE model (cooperative foldons, sequential stabilization, optional errors) provides a unifying explanation for how proteins fold and why they fold in that way.

Published

2007

12. Order of steps in the cytochrome C folding pathway: evidence for a sequential stabilization mechanism.

Author

Krishna MM, Maity H, Rumbley JN, Lin Y, and Englander SW

Subjects

Oxidation-Reduction, Protein Structure, Secondary, Protons, Thermodynamics, Cytochromes c chemistry, Cytochromes c metabolism, Protein Folding

Abstract

Previous work used hydrogen exchange (HX) experiments in kinetic and equilibrium modes to study the reversible unfolding and refolding of cytochrome c (Cyt c) under native conditions. Accumulated results now show that Cyt c is composed of five individually cooperative folding units, called foldons, which unfold and refold as concerted units in a stepwise pathway sequence. The first three steps of the folding pathway are linear and sequential. The ordering of the last two steps has been unclear because the fast HX of the amino acid residues in these foldons has made measurement difficult. New HX experiments done under slower exchange conditions show that the final two foldons do not unfold and refold in an obligatory sequence. They unfold separately and neither unfolding obligately contains the other, as indicated by their similar unfolding surface exposure and the specific effects of destabilizing and stabilizing mutations, pH change, and oxidation state. These results taken together support a sequential stabilization mechanism in which folding occurs in the native context with prior native-like structure serving to template the stepwise formation of subsequent native-like foldon units. Where the native structure of Cyt c requires sequential folding, in the first three steps, this is found. Where structural determination is ambiguous, in the final two steps, alternative parallel folding is found.

Published

2006

13. Functional role of a protein foldon--an Omega-loop foldon controls the alkaline transition in ferricytochrome c.

Author

Maity H, Rumbley JN, and Englander SW

Subjects

Alkalies, Cytochromes c genetics, Enzyme Stability, Magnetic Resonance Spectroscopy, Models, Molecular, Mutation genetics, Protein Denaturation, Protein Structure, Tertiary, Cytochromes c chemistry, Cytochromes c metabolism, Protein Folding

Abstract

Hydrogen exchange results for cytochrome c and several other proteins show that they are composed of a number of foldon units which continually unfold and refold and account for some functional properties. Previous work showed that one Omega-loop foldon controls the rate of the structural switching and ligand exchange behavior of cytochrome c known as the alkaline transition. The present work tests the role of foldons in the alkaline transition equilibrium. We measured the effects of denaturant and 14 destabilizing mutations. The results show that the ligand exchange equilibrium is controlled by the stability of the same foldon unit implicated before. In addition, the results obtained confirm the epsilon-amino group of Lys79 and Lys73 as the alkaline replacement ligands and bear on the search for a triggering group., (2005 Wiley-Liss, Inc.)

Published

2006

14. Protein folding: the stepwise assembly of foldon units.

Author

Maity H, Maity M, Krishna MM, Mayne L, and Englander SW

Subjects

Animals, Deuterium Exchange Measurement, Protein Conformation, Cytochromes c chemistry, Horses metabolism, Models, Molecular, Protein Folding, Protein Subunits chemistry

Abstract

Equilibrium and kinetic hydrogen exchange experiments show that cytochrome c is composed of five foldon units that continually unfold and refold even under native conditions. Folding proceeds by the stepwise assembly of the foldon units rather than one amino acid at a time. The folding pathway is determined by a sequential stabilization process; previously formed foldons guide and stabilize subsequent foldons to progressively build the native protein. Four other proteins have been found to show similar behavior. These results support stepwise protein folding pathways through discrete intermediates.

Published

2005

15. The N-terminal to C-terminal motif in protein folding and function.

Author

Krishna MM and Englander SW

Subjects

Amino Acid Motifs, Probability, Protein Structure, Secondary, Protein Folding

Abstract

Essentially all proteins known to fold kinetically in a two-state manner have their N- and C-terminal secondary structural elements in contact, and the terminal elements often dock as part of the experimentally measurable initial folding step. Conversely, all N-C no-contact proteins studied so far fold by non-two-state kinetics. By comparison, about half of the single domain proteins in the Protein Data Bank have their N- and C-terminal elements in contact, more than expected on a random probability basis but not nearly enough to account for the bias in protein folding. Possible reasons for this bias relate to the mechanisms for initial protein folding, native state stability, and final turnover.

Published

2005

16. Protein misfolding: optional barriers, misfolded intermediates, and pathway heterogeneity.

Author

Krishna MM, Lin Y, and Englander SW

Subjects

Animals, Cytochromes c chemistry, Horses, Hydrogen-Ion Concentration, Kinetics, Protein Structure, Tertiary, Time Factors, Cytochromes c metabolism, Protein Folding

Abstract

To investigate the character and role of misfolded intermediates in protein folding, a recombinant cytochrome c without the normally blocking histidine to heme misligation was studied. Folding remains heterogeneous as in the wild-type protein. Half of the population folds relatively rapidly to the native state in a two-state manner. The other half collapses (fluorescence quenching) and forms a full complement of helix (CD) with the same rate and denaturant dependence as the fast folding fraction but then is blocked and reaches the native structure (695nm absorbance) much more slowly. The factors that transiently block folding are not intrinsic to the folding process but depend on ambient conditions, including protein aggregation (f(concentration)), N terminus to heme misligation (f(pH)), and proline mis-isomerization (f(U state equilibration time)). The misfolded intermediate populated by the slowly folding fraction was characterized by hydrogen exchange pulse labeling. It is very advanced with all of the native-like elements fairly stably formed but not the final Met80-S to heme iron ligation, similar to a previously studied molten globule form induced by low pH. To complete final native state acquisition, some small back unfolding is required (error repair) but the misfolded intermediate does not revisit the U state before proceeding to N. These properties show that the intermediate is a normal on-pathway form that contains, in addition, adventitious misfolding errors that transiently block its forward progress. Related observations for other proteins (partially misfolded intermediates, pathway heterogeneity) might be similarly explained in terms of the optional insertion of error-dependent barriers into a classical folding pathway.

Published

2004

17. How cytochrome c folds, and why: submolecular foldon units and their stepwise sequential stabilization.

Author

Maity H, Maity M, and Englander SW

Subjects

Amino Acid Sequence, Circular Dichroism, Cytochrome c Group genetics, Deuterium metabolism, Escherichia coli genetics, Gene Deletion, Hydrogen metabolism, Hydrogen-Ion Concentration, Kinetics, Magnetic Resonance Spectroscopy, Models, Molecular, Protein Denaturation, Protein Engineering, Recombinant Proteins metabolism, Spectrophotometry, Ultraviolet, Thermodynamics, Cytochrome c Group chemistry, Cytochrome c Group metabolism, Protein Folding

Abstract

Native state hydrogen exchange experiments have shown that the cytochrome c (Cyt c) protein consists of five cooperative folding-unfolding units, called foldons. These are named, in the order of increasing unfolding free energy, the nested-Yellow, Red, Yellow, Green, and Blue foldons. Previous results suggest that these units unfold in a stepwise sequential way so that each higher energy partially unfolded form includes all of the previously unfolded lower free energy units. If this is so, then selectively destabilizing any given foldon should equally destabilize each subsequent unfolding step above it in the unfolding ladder but leave the lower ones before it unaffected. To perform this test, we introduced the mutation Glu62Gly, which deletes a salt link in the Yellow unit and destabilizes the protein by 0.8 kcal/mol. Native state hydrogen exchange and other experiments show that the stability of the Yellow unit and the states above it in the free energy ladder are destabilized by about the same amount while the lower lying states are unaffected. These results help to confirm the sequential stepwise nature of the Cyt c unfolding pathway and therefore a similar refolding pathway. The steps in the pathway are dictated by the concerted folding-unfolding property of the individual unit foldons; the order of steps is determined by the sequential stabilization of progressively added foldons in the native context. Much related information for Cyt c strongly conforms with this mechanism. Its generality is supported by available information for other proteins.

Published

2004

18. Hydrogen exchange methods to study protein folding.

Author

Krishna MM, Hoang L, Lin Y, and Englander SW

Subjects

Animals, Cytochrome c Group chemistry, Hydrogen-Ion Concentration, Nuclear Magnetic Resonance, Biomolecular, Protein Structure, Secondary, Time Factors, Deuterium Exchange Measurement, Hydrogen chemistry, Protein Folding

Abstract

The measurement of amino acid-resolved hydrogen exchange (HX) has provided the most detailed information so far available on the structure and properties of protein folding intermediates. Direct HX measurements can define the structure of tenuous molten globule forms that are generally inaccessible to the usual crystallographic and NMR methods (C. Redfield review in this issue). HX pulse labeling methods can specify the structure, stability and kinetics of folding intermediates that exist for less than 1 s during kinetic folding. Native state HX methods can detect and characterize folding intermediates that exist as infinitesimally populated high energy excited state forms under native conditions. The results obtained in these ways suggest principles that appear to explain the properties of partially folded intermediates and how they are organized into folding pathways. The application of these methods is detailed here.

Published

2004

19. Intimate view of a kinetic protein folding intermediate: residue-resolved structure, interactions, stability, folding and unfolding rates, homogeneity.

Author

Krishna MM, Lin Y, Mayne L, and Englander SW

Subjects

Animals, Cytochrome c Group metabolism, Horses, Hydrogen metabolism, Hydrogen-Ion Concentration, Kinetics, Models, Chemical, Models, Molecular, Protein Conformation, Thermodynamics, Cytochrome c Group chemistry, Protein Folding

Abstract

A cytochrome c kinetic folding intermediate was studied by hydrogen exchange (HX) pulse labeling. Advances in the technique and analysis made it possible to define the structured and unstructured regions, equilibrium stability, and kinetic opening and closing rates, all at an amino acid-resolved level. The entire N-terminal and C-terminal helices are formed and docked together at their normal native positions. They fray in both directions from the interaction region, due to a progression in both unfolding and refolding rates, leading to the surprising suggestion that helix propagation may proceed very slowly in the condensed milieu. Several native-like beta turns are formed. Some residues in the segment that will form the native 60s helix are protected but others are not, suggesting energy minimization to some locally non-native conformation in the transient intermediate. All other regions are unprotected, presumably dynamically disordered. The intermediate resembles a partially constructed native state. It is early, on-pathway, and all of the refolding molecules pass through it. These and related results consistently point to distinct, homogeneous, native-like intermediates in a stepwise sequential pathway, guided by the same factors that determine the native structure. Previous pulse labeling efforts have always assumed EX2 exchange during the labeling pulse, often leading to the suggestion of heterogeneous intermediates in alternative parallel pathways. The present work reveals a dominant role for EX1 exchange in the high pH labeling pulse, which will mimic heterogeneous behavior when EX2 exchange is assumed. The general problem of homogeneous versus heterogeneous intermediates and pathways is discussed.

Published

2003

20. Folding units govern the cytochrome c alkaline transition.

Author

Hoang L, Maity H, Krishna MM, Lin Y, and Englander SW

Subjects

Animals, Horses, Hydrogen chemistry, Hydrogen-Ion Concentration, Kinetics, Models, Molecular, Protein Structure, Tertiary, Spectrum Analysis, Titrimetry, Cytochrome c Group chemistry, Protein Folding

Abstract

The alkaline transition of cytochrome c is a model for protein structural switching in which the normal heme ligand is replaced by another group. Stopped flow data following a jump to high pH detect two slow kinetic phases, suggesting two rate-limiting structure changes. Results described here indicate that these events are controlled by the same structural unfolding reactions that account for the first two steps in the reversible unfolding pathway of cytochrome c. These and other results show that the cooperative folding-unfolding behavior of protein foldons can account for a variety of functional activities in addition to determining folding pathways.

Published

2003

21. Cooperative omega loops in cytochrome c: role in folding and function.

Author

Krishna MM, Lin Y, Rumbley JN, and Englander SW

Subjects

Hydrogen chemistry, Hydrogen-Ion Concentration, Models, Molecular, Mutation, Protein Structure, Tertiary, Thermodynamics, Cytochrome c Group chemistry, Protein Folding

Abstract

Hydrogen exchange experiments under slow exchange conditions show that an omega loop in cytochrome c (residues 40-57) acts as a cooperative unfolding/refolding unit under native conditions. This unit behavior accounts for an initial step on the unfolding pathway, a final step in refolding, and a number of other structural, functional and evolutionary properties.

Published

2003

22. Submolecular cooperativity produces multi-state protein unfolding and refolding.

Author

Englander SW, Mayne L, and Rumbley JN

Subjects

Cytochrome c Group chemistry, Models, Molecular, Protein Denaturation, Protein Folding

Abstract

Hydrogen exchange experiments show that cytochrome c and other proteins under native conditions reversibly unfold in a multi-step manner. The step from one intermediate to the next is determined by the intrinsically cooperative nature of secondary structural elements, which is retained in the native protein. Folding uses the same pathway in the reverse direction, moving from the unfolded to the native state through relatively discrete intermediate forms by the sequential addition of native-like secondary structural units., (Copyright 2002 Elsevier Science B.V.)

Published

2002

23. Fast and slow intermediate accumulation and the initial barrier mechanism in protein folding.

Author

Krantz BA, Mayne L, Rumbley J, Englander SW, and Sosnick TR

Subjects

Animals, Bacterial Proteins, Guanidine pharmacology, Heart, Horses, Kinetics, Models, Chemical, Models, Molecular, Protein Conformation, Protein Denaturation, Thermodynamics, Time Factors, Cytochrome c Group chemistry, Nerve Tissue Proteins chemistry, Protein Folding, Ribonuclease, Pancreatic chemistry, Ribonucleases chemistry, Ubiquitin chemistry

Abstract

Do stable intermediates form very early in the protein folding process? New results and a quantity of literature that bear on this issue are examined here. Results available provide little support for early intermediate accumulation before an initial search-dependent nucleation barrier.

Published

2002

24. Molecular chaperones--cellular machines for protein folding.

Author

Walter S and Buchner J

Subjects

Chaperonin 10 metabolism, Chaperonin 10 physiology, Chaperonin 60 metabolism, Chaperonin 60 physiology, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Fungal Proteins metabolism, HSP70 Heat-Shock Proteins metabolism, HSP70 Heat-Shock Proteins physiology, HSP90 Heat-Shock Proteins metabolism, HSP90 Heat-Shock Proteins physiology, Molecular Chaperones metabolism, Protein Conformation, Yeasts metabolism, Escherichia coli Proteins physiology, Fungal Proteins physiology, Molecular Chaperones physiology, Protein Folding

Abstract

Proteins are linear polymers synthesized by ribosomes from activated amino acids. The product of this biosynthetic process is a polypeptide chain, which has to adopt the unique three-dimensional structure required for its function in the cell. In 1972, Christian Anfinsen was awarded the Nobel Prize for Chemistry for showing that this folding process is autonomous in that it does not require any additional factors or input of energy. Based on in vitro experiments with purified proteins, it was suggested that the correct three-dimensional structure can form spontaneously in vivo once the newly synthesized protein leaves the ribosome. Furthermore, proteins were assumed to maintain their native conformation until they were degraded by specific enzymes. In the last decade this view of cellular protein folding has changed considerably. It has become clear that a complicated and sophisticated machinery of proteins exists which assists protein folding and allows the functional state of proteins to be maintained under conditions in which they would normally unfold and aggregate. These proteins are collectively called molecular chaperones, because, like their human counterparts, they prevent unwanted interactions between their immature clients. In this review, we discuss the principal features of this peculiar class of proteins, their structure-function relationships, and the underlying molecular mechanisms.

Published

2002

25. Folding of malate dehydrogenase inside the GroEL-GroES cavity.

Author

Chen J, Walter S, Horwich AL, and Smith DL

Subjects

Adenosine Triphosphate metabolism, Animals, Binding Sites, Chromatography, High Pressure Liquid, Deuterium metabolism, Dimerization, Hydrogen Bonding, Kinetics, Mass Spectrometry, Mitochondria, Heart, Models, Molecular, Peptide Fragments chemistry, Peptide Fragments metabolism, Protein Binding, Protein Denaturation, Protein Structure, Secondary, Protein Structure, Tertiary, Protein Subunits, Swine, Chaperonin 10 metabolism, Chaperonin 60 metabolism, Malate Dehydrogenase chemistry, Malate Dehydrogenase metabolism, Protein Folding

Abstract

The chaperonin GroEL binds nonnative substrate protein in the hydrophobic central cavity of an open ring. ATP and GroES binding to the same ring converts this cavity into an encapsulated, hydrophilic chamber that mediates productive folding. A 'rack' mechanism of initial protein unfolding proposes that, upon GroES and ATP binding, the polypeptide is stretched between the binding sites on the twisting apical domains of GroEL before complete release into the chamber. Here, the structure of malate dehydrogenase (MDH) subunit during folding is monitored by deuterium exchange, peptic fragment production and mass spectrometry. When bound to GroEL, MDH exhibits a core of partially protected secondary structure that is only modestly deprotected upon ATP and GroES binding. Moreover, deprotection is broadly distributed throughout MDH, suggesting that it results from breaking hydrogen bonds between MDH and the cavity wall or global destabilization, as opposed to forced mechanical unfolding.

Published

2001

26. Stability, folding, dimerization, and assembly properties of the yeast prion Ure2p.

Author

Thual C, Bousset L, Komar AA, Walter S, Buchner J, Cullin C, and Melki R

Subjects

Amyloid metabolism, Circular Dichroism, Dimerization, Fungal Proteins chemistry, Fungal Proteins genetics, Fungal Proteins ultrastructure, Glutathione Peroxidase, Guanidine, Kinetics, Molecular Weight, Peptide Fragments chemistry, Peptide Fragments genetics, Peptide Fragments metabolism, Peptide Fragments ultrastructure, Prions chemistry, Prions genetics, Prions ultrastructure, Protein Denaturation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Recombinant Proteins ultrastructure, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae ultrastructure, Solubility, Spectrometry, Fluorescence, Fungal Proteins metabolism, Prions metabolism, Protein Folding, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins

Abstract

The [URE3] factor of Saccharomyces cerevisiae propagates by a prion-like mechanism and corresponds to the loss of the function of the cellular protein Ure2. The molecular basis of the propagation of this phenotype is unknown. We recently expressed Ure2p in Escherichia coli and demonstrated that the N-terminal region of the protein is flexible and unstructured, while its C-terminal region is compactly folded. Ure2p oligomerizes in solution to form mainly dimers that assemble into fibrils [Thual et al. (1999) J. Biol. Chem. 274, 13666-13674]. To determine the role played by each domain of Ure2p in the overall properties of the protein, specifically, its stability, conformation, and capacity to assemble into fibrils, we have further analyzed the properties of Ure2p N- and C-terminal regions. We show here that Ure2p dimerizes through its C-terminal region. We also show that the N-terminal region is essential for directing the assembly of the protein into a particular pathway that yields amyloid fibrils. A full-length Ure2p variant that possesses an additional tryptophan residue in its N-terminal moiety was generated to follow conformational changes affecting this domain. Comparison of the overall conformation, folding, and unfolding properties, and the behavior upon proteolytic treatments of full-length Ure2p, Ure2pW37 variant, and Ure2p C-terminal fragment reveals that Ure2p N-terminal domain confers no additional stability to the protein. This study reveals the existence of a stable unfolding intermediate of Ure2p under conditions where the protein assembles into amyloid fibrils. Our results contradict the intramolecular interaction between the N- and C-terminal moieties of Ure2p and the single unfolding transitions reported in a number of previous studies.

Published

2001

27. A thermodynamic coupling mechanism for GroEL-mediated unfolding.

Author

Walter S, Lorimer GH, and Schmid FX

Subjects

Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Kinetics, Protein Conformation, Protein Denaturation, Thermodynamics, Chaperonin 60 metabolism, Protein Folding, Ribonuclease T1 metabolism

Abstract

Chaperonins prevent the aggregation of partially folded or misfolded forms of a protein and, thus, keep it competent for productive folding. It was suggested that GroEL, the chaperonin of Escherichia coli, exerts this function 1 unfolding such intermediates, presumably in a catalytic fashion. We investigated the kinetic mechanism of GroEL-induced protein unfolding by using a reduced and carbamidomethylated variant of RNase T1, RCAM-T1, as a substrate. RCAM-T1 cannot fold to completion, because the two disulfide bonds are missing, and it is, thus, a good model for long-lived folding intermediates. RCAM-T1 unfolds when GroEL is added, but GroEL does not change the microscopic rate constant of unfolding, ruling out that it catalyzes unfolding. GroEL unfolds RCAM-T1 because it binds with high affinity to the unfolded form of the protein and thereby shifts the overall equilibrium toward the unfolded state. GroEL can unfold a partially folded or misfolded intermediate by this thermodynamic coupling mechanism when the Gibbs free energy of the binding to GroEL is larger than the conformational stability of the intermediate and when the rate of its unfolding is high.

Published

1996

28. Catalyzed and assisted protein folding of ribonuclease T1.

Author

Schmid FX, Frech C, Scholz C, and Walter S

Subjects

Amino Acid Isomerases metabolism, Carrier Proteins metabolism, Catalysis, Chaperonin 60 metabolism, Isomerases metabolism, Models, Chemical, Oxidation-Reduction, Peptidylprolyl Isomerase, Protein Disulfide-Isomerases, Substrate Specificity, Protein Folding, Ribonuclease T1 metabolism

Abstract

The small single-domain protein ribonuclease T1 (RNase T1) and variants thereof are good substrates for investigating the mechanisms of catalyzed and assisted protein folding. RNase T1 contains two cis prolines and two disulfide bonds, and the kinetic mechanism of its folding is well known. The wild-type form and designed variants that differ in the number prolines and of disulfide bonds were used as substrates to study the catalysis of folding by prolyl isomerases and protein disulfide isomerases. In its unfolded form, a marginally stable variant of RNase T1 binds to the chaperone GroEL and could thus be used to elucidate the kinetic mechanism of GroEL-mediated protein unfolding.

Published

1996

29. A Protein Folding Pathway with Multiple Folding Intermediates at Atomic Resolution

Author

Feng, Hanqiao, Zhou, Zheng, Bai, Yawen, and Englander, S. Walter

Published

2005

30. The N-Terminal to C-Terminal Motif in Protein Folding and Function

Author

Englander, S. Walter

Published

2005

31. Differences in the Folding Transition State of Ubiquitin Indicated by φ and ψ Analyses

Author

Sosnick, Tobin R., Dothager, Robin S., Krantz, Bryan A., and Englander, S. Walter

Published

2004

32. Cytochrome c Folding Pathway: Kinetic Native-State Hydrogen Exchange

Author

Hoang, Linh, Bédard, Sabrina, Lin, Yan, and Englander, S. Walter

Published

2002

33. An Amino Acid Code for Protein Folding

Author

Rumbley, Jon, Hoang, Linh, Mayne, Leland, and Englander, S. Walter

Published

2001

34. Chaperonin Function: Folding by Forced Unfolding

Author

Shtilerman, Mark, Lorimer, George H., and Englander, S. Walter

Published

1999

35. Missense mutations in dystrophin that trigger muscular dystrophy decrease protein stability and lead to cross-β aggregates

Author

Singh, Surinder M., Kongari, Narsimulu, Cabello-Villegas, Javier, Mallela, Krishna M. G., and Englander, S. Walter

Published

2010

36. Native State Dynamics Drive the Unfolding of the SH3 Domain of PI3 Kinase at High Denaturant Concentration

Author

Wani, Ajazul Hamid, Udgaonkar, Jayant B., and Englander, S. Walter

Published

2009

37. The Mad2 Partial Unfolding Model: Regulating Mitosis through Mad2 Conformational Switching

Author

Skinner, John J., Wood, Stacey, Shorter, James, Englander, S. Walter, and Black, Ben E.

Published

2008

38. Protein Folding: Independent Unrelated Pathways or Predetermined Pathway with Optional Errors

Author

Bédard, Sabrina, Krishna, Mallela M. G., Mayne, Leland, and Englander, S. Walter

Published

2008

39. Folding Trajectories of Human Dihydrofolate Reductase inside the GroEL-GroES Chaperonin Cavity and Free in Solution

Author

Horst, Reto, Fenton, Wayne A., Englander, S. Walter, Wüthrich, Kurt, and Horwich, Arthur L.

Published

2007

40. Protein Folding Intermediates: Native-State Hydrogen Exchange

Author

Bai, Yawen, Sosnick, Tobin R., Mayne, Leland, and Englander, S. Walter

Published

1995

41. Folding of maltose binding protein outside of and in GroEL

Author

Leland Mayne, Zhong-yuan Kan, Xiang Ye, and S. Walter Englander

Subjects

HX MS, 0301 basic medicine, Protein Folding, Protein Conformation, Free solution, GroEL, Maltose-Binding Proteins, 03 medical and health sciences, Maltose-binding protein, Adenosine Triphosphate, Escherichia coli, Side chain, Multidisciplinary, 030102 biochemistry & molecular biology, biology, Chemistry, Escherichia coli Proteins, Chaperonin 60, Biological Sciences, Biophysics and Computational Biology, Kinetics, 030104 developmental biology, Biophysics, biology.protein, Protein folding, Protein Binding

Abstract

Significance The GroEL/ES chaperonin is known to prevent protein aggregation during folding by passive containment within the central cavity. The possible role of more active intervention is controversial. The HX MS method documents an organized hydrophobically stabilized folding preintermediate in the collapsed ensemble of maltose binding protein. A mutational defect destabilizes the preintermediate and greatly slows folding of the subsequent on-pathway H-bonded intermediate. GroEL encapsulation alone, without ATP and substrate protein cycling, restabilizes the preintermediate and restores fast folding. The mechanism appears to depend on forceful compression during confinement. More generally, these results suggest that GroEL can repair different folding defects in different ways., We used hydrogen exchange–mass spectrometry (HX MS) and fluorescence to compare the folding of maltose binding protein (MBP) in free solution and in the GroEL/ES cavity. Upon refolding, MBP initially collapses into a dynamic molten globule-like ensemble, then forms an obligatory on-pathway native-like folding intermediate (1.2 seconds) that brings together sequentially remote segments and then folds globally after a long delay (30 seconds). A single valine to glycine mutation imposes a definable folding defect, slows early intermediate formation by 20-fold, and therefore subsequent global folding by approximately twofold. Simple encapsulation within GroEL repairs the folding defect and reestablishes fast folding, with or without ATP-driven cycling. Further examination exposes the structural mechanism. The early folding intermediate is stabilized by an organized cluster of 24 hydrophobic side chains. The cluster preexists in the collapsed ensemble before the H-bond formation seen by HX MS. The V9G mutation slows folding by disrupting the preintermediate cluster. GroEL restores wild-type folding rates by restabilizing the preintermediate, perhaps by a nonspecific equilibrium compression effect within its tightly confining central cavity. These results reveal an active GroEL function other than previously proposed mechanisms, suggesting that GroEL possesses different functionalities that are able to relieve different folding problems. The discovery of the preintermediate, its mutational destabilization, and its restoration by GroEL encapsulation was made possible by the measurement of a previously unexpected type of low-level HX protection, apparently not dependent on H-bonding, that may be characteristic of proteins in confined spaces.

Published

2018

42. The case for defined protein folding pathways

Author

Leland Mayne and S. Walter Englander

Subjects

Models, Molecular, 0301 basic medicine, Protein Folding, Multidisciplinary, Protein Conformation, Energy landscape, Computational biology, Biological Sciences, Biology, 010402 general chemistry, ENCODE, 01 natural sciences, 0104 chemical sciences, Folding (chemistry), Kinetics, 03 medical and health sciences, Crystallography, 030104 developmental biology, Thermodynamics, Protein folding, Native structure

Abstract

We consider the differences between the many-pathway protein folding model derived from theoretical energy landscape considerations and the defined-pathway model derived from experiment. A basic tenet of the energy landscape model is that proteins fold through many heterogeneous pathways by way of amino acid-level dynamics biased toward selecting native-like interactions. The many pathways imagined in the model are not observed in the structure-formation stage of folding by experiments that would have found them, but they have now been detected and characterized for one protein in the initial prenucleation stage. Analysis presented here shows that these many microscopic trajectories are not distinct in any functionally significant way, and they have neither the structural information nor the biased energetics needed to select native vs. nonnative interactions during folding. The opposed defined-pathway model stems from experimental results that show that proteins are assemblies of small cooperative units called foldons and that a number of proteins fold in a reproducible pathway one foldon unit at a time. Thus, the same foldon interactions that encode the native structure of any given protein also naturally encode its particular foldon-based folding pathway, and they collectively sum to produce the energy bias toward native interactions that is necessary for efficient folding. Available information suggests that quantized native structure and stepwise folding coevolved in ancient repeat proteins and were retained as a functional pair due to their utility for solving the difficult protein folding problem.

Published

2017

43. Protein Folding—How and Why: By Hydrogen Exchange, Fragment Separation, and Mass Spectrometry

Author

Zhong-yuan Kan, S. Walter Englander, Wenbing Hu, and Leland Mayne

Subjects

0301 basic medicine, Protein Folding, Magnetic Resonance Spectroscopy, Protein Conformation, Biophysics, Bioengineering, 010402 general chemistry, Mass spectrometry, 01 natural sciences, Biochemistry, Article, Mass Spectrometry, 03 medical and health sciences, Structural Biology, Hydrogen exchange, Chemistry, Ms analysis, Proteins, Energy landscape, Cell Biology, Mass spectrometric, 0104 chemical sciences, Crystallography, 030104 developmental biology, Thermodynamics, Separation method, Protein folding, Hydrogen

Abstract

Advanced hydrogen exchange (HX) methodology can now determine the structure of protein folding intermediates and their progression in folding pathways. Key developments over time include the HX pulse labeling method with nuclear magnetic resonance analysis, the fragment separation method, the addition to it of mass spectrometric (MS) analysis, and recent improvements in the HX MS technique and data analysis. Also, the discovery of protein foldons and their role supplies an essential interpretive link. Recent work using HX pulse labeling with MS analysis finds that a number of proteins fold by stepping through a reproducible sequence of native-like intermediates in an ordered pathway. The stepwise nature of the pathway is dictated by the cooperative foldon unit construction of the protein. The pathway order is determined by a sequential stabilization principle; prior native-like structure guides the formation of adjacent native-like structure. This view does not match the funneled energy landscape paradigm of a very large number of folding tracks, which was framed before foldons were known and is more appropriate for the unguided residue-level search to surmount an initial kinetic barrier rather than for the overall unfolded-state to native-state folding pathway.

Published

2016

44. Reply to Eaton and Wolynes: How do proteins fold?

Author

S. Walter Englander and Leland Mayne

Subjects

010101 applied mathematics, 0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Multidisciplinary, Protein folding, Computational biology, Fold (geology), 0101 mathematics, 01 natural sciences, Mathematics, Landscape model

Abstract

Eaton and Wolynes (1) take issue with our recent paper on protein folding (2) in which we compare the defined-pathway model (3, 4) and the many-pathway funneled-energy landscape model (5, 6) with informative experimental results. Eaton and Wolynes (1) do not dispute our main points. Over a dozen proteins have now been shown to be constructed of separately cooperative foldon units. They fold through foldon-dependent intermediates in well-defined pathways. Multiple alternative pathways, if they existed, would have been seen in these experiments; they have not. The multiple trajectories visualized in the funneled-landscape … [↵][1]1To whom correspondence should be addressed. Email: engl{at}mail.med.upenn.edu. [1]: #xref-corresp-1-1

Published

2017

45. Stepwise protein folding at near amino acid resolution by hydrogen exchange and mass spectrometry

Author

Benjamin T. Walters, Laura E. Rosen, Wenbing Hu, S. Walter Englander, Leland Mayne, Zhong-yuan Kan, and Susan Marqusee

Subjects

Protein Denaturation, Protein Folding, Hydrogen, Resolution (mass spectrometry), Ribonuclease H, Biophysics, chemistry.chemical_element, Cooperativity, Mass spectrometry, Mass Spectrometry, Escherichia coli, Amino Acids, RNase H, chemistry.chemical_classification, Multidisciplinary, biology, Chemistry, Biological Sciences, Hydrogen-Ion Concentration, Amino acid, Folding (chemistry), Crystallography, biology.protein, Protein folding, Peptides, Software

Abstract

The kinetic folding of ribonuclease H was studied by hydrogen exchange (HX) pulse labeling with analysis by an advanced fragment separation mass spectrometry technology. The results show that folding proceeds through distinct intermediates in a stepwise pathway that sequentially incorporates cooperative native-like structural elements to build the native protein. Each step is seen as a concerted transition of one or more segments from an HX-unprotected to an HX-protected state. Deconvolution of the data to near amino acid resolution shows that each step corresponds to the folding of a secondary structural element of the native protein, termed a “foldon.” Each folded segment is retained through subsequent steps of foldon addition, revealing a stepwise buildup of the native structure via a single dominant pathway. Analysis of the pertinent literature suggests that this model is consistent with experimental results for many proteins and some current theoretical results. Two biophysical principles appear to dictate this behavior. The principle of cooperativity determines the central role of native-like foldon units. An interaction principle termed “sequential stabilization” based on native-like interfoldon interactions orders the pathway.

Published

2013

46. Crystallization and preliminary X-ray analysis of mouse RANK and its complex with RANKL

Author

Changzhen Liu, David I. Stuart, Jingshan Ren, Peng Huang, Raymond J. Owens, Lucy R. Wedderburn, Bin Gao, Peifu Tang, Thomas S. Walter, and Shiqian Zhang

Subjects

musculoskeletal diseases, Protein Folding, Rotation, Recombinant Fusion Proteins, Genetic Vectors, Molecular Sequence Data, Statistics as Topic, Cell, Biophysics, Biochemistry, Mice, X-Ray Diffraction, Structural Biology, Osteoclast, Escherichia coli, Genetics, medicine, Animals, Histidine, Amino Acid Sequence, Cloning, Molecular, Receptor, Glutathione Transferase, Inclusion Bodies, Receptor Activator of Nuclear Factor-kappa B, biology, Activator (genetics), Chemistry, Data Collection, RANK Ligand, Dendritic cell, Condensed Matter Physics, Protein Structure, Tertiary, Cell biology, Molecular Weight, medicine.anatomical_structure, Solubility, Ectodomain, Crystallization Communications, RANKL, biology.protein, Crystallization

Abstract

The interaction between the TNF-family molecule receptor activator of NF-kappaB ligand (RANKL) and its receptor RANK induces osteoclast formation, activation and survival in the process of bone remodelling. RANKL-RANK also plays critical roles in T-cell/dendritic cell communication and lymph-node formation and in a variety of pathologic conditions such as tumour-cell migration and bone metastasis. Both the ectodomain of mouse RANKL and the extracellular domain of mouse RANK have been cloned, expressed and purified. Crystals of RANK alone and of RANK in complex with RANKL have been obtained that are suitable for structure determination.

Published

2016

47. Protein hydrogen exchange: Testing current models

Author

Ben E. Black, John J. Skinner, S. Walter Englander, Woon Ki Lim, and Sabrina Bédard

Subjects

Hydrogen exchange, Hydrogen, biology, Chemistry, chemistry.chemical_element, Electrostatics, Biochemistry, Solvent, chemistry.chemical_compound, Crystallography, Chemical physics, Amide, Static electricity, biology.protein, Protein folding, Molecular Biology, Micrococcal nuclease

Abstract

To investigate the determinants of protein hydrogen exchange (HX), HX rates of most of the backbone amide hydrogens of Staphylococcal nuclease were measured by NMR methods. A modified analysis was used to improve accuracy for the faster hydrogens. HX rates of both near surface and well buried hydrogens are spread over more than 7 orders of magnitude. These results were compared with previous hypotheses for HX rate determination. Contrary to a common assumption, proximity to the surface of the native protein does not usually produce fast exchange. The slow HX rates for unprotected surface hydrogens are not well explained by local electrostatic field. The ability of buried hydrogens to exchange is not explained by a solvent penetration mechanism. The exchange rates of structurally protected hydrogens are not well predicted by algorithms that depend only on local interactions or only on transient unfolding reactions. These observations identify some of the present difficulties of HX rate prediction and suggest the need for returning to a detailed hydrogen by hydrogen analysis to examine the bases of structure-rate relationships, as described in the companion paper (Skinner et al., Protein Sci 2012;21:996-1005).

Published

2012

48. Protein dynamics viewed by hydrogen exchange

Author

S. Walter Englander, John J. Skinner, Woon Ki Lim, Sabrina Bédard, and Ben E. Black

Subjects

Hydrogen, Chemistry, Protein dynamics, chemistry.chemical_element, Biochemistry, Acceptor, Solvent, Crystallography, Chemical physics, Side chain, Bound water, Molecule, Protein folding, Molecular Biology

Abstract

To examine the relationship between protein structural dynamics and measurable hydrogen exchange (HX) data, the detailed exchange behavior of most of the backbone amide hydrogens of Staphylococcal nuclease was compared with that of their neighbors, with their structural environment, and with other information. Results show that H-bonded hydrogens are protected from exchange, with HX rate effectively zero, even when they are directly adjacent to solvent. The transition to exchange competence requires a dynamic structural excursion that removes H-bond protection and allows exposure to solvent HX catalyst. The detailed data often make clear the nature of the dynamic excursion required. These range from whole molecule unfolding, through smaller cooperative unfolding reactions of secondary structural elements, and down to local fluctuations that involve as little as a single peptide group or side chain or water molecule. The particular motion that dominates the exchange of any hydrogen is the one that allows the fastest HX rate. The motion and the rate it produces are determined by surrounding structure and not by nearness to solvent or the strength of the protecting H-bond itself or its acceptor type (main chain, side chain, structurally bound water). Many of these motions occur over time scales that are appropriate for biochemical function.

Published

2012

49. The Foldon Substructure of Staphylococcal Nuclease

Author

Ronald W. Peterson, Leland Mayne, Sabrina Bédard, A. Joshua Wand, and S. Walter Englander

Subjects

Protein Denaturation, Protein Folding, Staphylococcus aureus, Circular dichroism, Time Factors, Sequence (biology), Article, Fluorescence, Reaction rate constant, Structural Biology, Micrococcal Nuclease, Molecular Biology, biology, Chemistry, Circular Dichroism, Amides, Folding (chemistry), Kinetics, Crystallography, Helix, biology.protein, Thermodynamics, Mutant Proteins, Protein folding, Heteronuclear single quantum coherence spectroscopy, Hydrogen, Micrococcal nuclease

Abstract

To search for submolecular foldon units, the spontaneous reversible unfolding and refolding of staphylococcal nuclease under native conditions was studied by a kinetic native-state hydrogen exchange (HX) method. As for other proteins, it appears that staphylococcal nuclease is designed as an assembly of well-integrated foldon units that may define steps in its folding pathway and may regulate some other functional properties. The HX results identify 34 amide hydrogens that exchange with solvent hydrogens under native conditions by way of large transient unfolding reactions. The HX data for each hydrogen measure the equilibrium stability (Delta G(HX)) and the kinetic unfolding and refolding rates (k(op) and k(cl)) of the unfolding reaction that exposes it to exchange. These parameters separate the 34 identified residues into three distinct HX groupings. Two correspond to clearly defined structural units in the native protein, termed the blue and red foldons. The remaining HX grouping contains residues, not well separated by their HX parameters alone, that represent two other distinct structural units in the native protein, termed the green and yellow foldons. Among these four sets, a last unfolding foldon (blue) unfolds with a rate constant of 6 x 10(-6) s(-1) and free energy equal to the protein's global stability (10.0 kcal/mol). It represents part of the beta-barrel, including mutually H-bonding residues in the beta 4 and beta 5 strands, a part of the beta 3 strand that H-bonds to beta 5, and residues at the N-terminus of the alpha2 helix that is capped by beta 5. A second foldon (green), which unfolds and refolds more rapidly and at slightly lower free energy, includes residues that define the rest of the native alpha2 helix and its C-terminal cap. A third foldon (yellow) defines the mutually H-bonded beta1-beta2-beta 3 meander, completing the native beta-barrel, plus an adjacent part of the alpha1 helix. A final foldon (red) includes residues on remaining segments that are distant in sequence but nearly adjacent in the native protein. Although the structure of the partially unfolded forms closely mimics the native organization, four residues indicate the presence of some nonnative misfolding interactions. Because the unfolding parameters of many other residues are not determined, it seems likely that the concerted foldon units are more extensive than is shown by the 34 residues actually observed.

Published

2008

50. Folding trajectories of human dihydrofolate reductase inside the GroEL–GroES chaperonin cavity and free in solution

Author

Kurt Wüthrich, Arthur L. Horwich, Reto Horst, S. Walter Englander, and Wayne A. Fenton

Subjects

Protein Denaturation, Protein Folding, Magnetic Resonance Spectroscopy, Chaperonins, Protein Structure, Secondary, Chaperonin, Adenosine Triphosphate, Dihydrofolate reductase, Chaperonin 10, Native state, Humans, Peptide sequence, Multidisciplinary, biology, Chemistry, Chaperonin 60, GroES, Biological Sciences, GroEL, Solutions, Folding (chemistry), Kinetics, Tetrahydrofolate Dehydrogenase, Crystallography, Solvents, biology.protein, Biophysics, Protein folding, Protein Binding

Abstract

The chaperonin GroEL binds non-native polypeptides in an open ring via hydrophobic contacts and then, after ATP and GroES binding to the same ring as polypeptide, mediates productive folding in the now hydrophilic, encapsulated cis chamber. The nature of the folding reaction in the c is cavity remains poorly understood. In particular, it is unclear whether polypeptides take the same route to the native state in this cavity as they do when folding spontaneously free in solution. Here, we have addressed this question by using NMR measurements of the time course of acquisition of amide proton exchange protection of human dihydrofolate reductase (DHFR) during folding in the presence of methotrexate and ATP either free in solution or inside the stable cavity formed between a single ring variant of GroEL, SR1, and GroES. Recovery of DHFR refolded by the SR1/GroES-mediated reaction is 2-fold higher than in the spontaneous reaction. Nevertheless, DHFR folding was found to proceed by the same trajectories inside the cis folding chamber and free in solution. These observations are consistent with the description of the chaperonin chamber as an “Anfinsen cage” where polypeptide folding is determined solely by the amino acid sequence, as it is in solution. However, if misfolding occurs in the confinement of the chaperonin cavity, the polypeptide chain cannot undergo aggregation but rather finds its way back to a productive pathway in a manner that cannot be accomplished in solution, resulting in the observed high overall recovery.

Published

2007