Faculty Opinions recommendation of In vivo conformational dynamics of hsp90 and its interactors.

TNF Receptor Associated Factor 2 (TRAF2) is a trimeric protein that belongs to the TNF receptor associated factor family (TRAFs). The TRAF2 oligomeric state is crucial for receptor binding and for its interaction with other proteins involved in the TNFR signaling. The monomer-trimer equilibrium of a C- terminal domain truncated form of TRAF2 (TRAF2-C), plays also a relevant role in binding the membrane, causing inward vesiculation. In this study, we have investigated the conformational dynamics of TRAF2-C through circular dichroism, fluorescence, and dynamic light scattering, performing temperature-dependent measurements. The data indicate that the protein retains its oligomeric state and most of its secondary structure, while displaying a significative increase in the heterogeneity of the tyrosines signal, increasing the temperature from ≈15 to ≈35 °C. The peculiar crowding of tyrosine residues (12 out of 18) at the three subunit interfaces and the strong dependence on the trimer concentration indicate that such conformational changes mainly involve the contact areas between each pair of monomers, affecting the oligomeric state. Molecular dynamic simulations in this temperature range suggest that the interfaces heterogeneity is an intrinsic property of the trimer that arises from the continuous, asymmetric approaching and distancing of its subunits. Such dynamics affect the results of molecular docking on the external protein surface using receptor peptides, indicating that the TRAF2-receptor interaction in the solution might not involve three subunits at the same time, as suggested by the static analysis obtainable from the crystal structure. These findings shed new light on the role that the TRAF2 oligomeric state might have in regulating the protein binding activity in vivo.

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Heterodimer Formation of the Homodimeric ABC Transporter OpuA

International Journal of Molecular Sciences ◽

10.3390/ijms22115912 ◽

2021 ◽

Vol 22 (11) ◽

pp. 5912

Author(s):

Patricia Alvarez-Sieiro ◽

Hendrik R. Sikkema ◽

Bert Poolman

Keyword(s):

Abc Transporter ◽

Conformational Dynamics ◽

Host Organism ◽

Affinity Tag ◽

Practical Applications ◽

Fundamental Research ◽

Protein Multimerization ◽

Biochemical Analyses

Many proteins have a multimeric structure and are composed of two or more identical subunits. While this can be advantageous for the host organism, it can be a challenge when targeting specific residues in biochemical analyses. In vitro splitting and re-dimerization to circumvent this problem is a tedious process that requires stable proteins. We present an in vivo approach to transform homodimeric proteins into apparent heterodimers, which then can be purified using two-step affinity-tag purification. This opens the door to both practical applications such as smFRET to probe the conformational dynamics of homooligomeric proteins and fundamental research into the mechanism of protein multimerization, which is largely unexplored for membrane proteins. We show that expression conditions are key for the formation of heterodimers and that the order of the differential purification and reconstitution of the protein into nanodiscs is important for a functional ABC-transporter complex.

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Conformational entropy of a single peptide controlled under force governs protease recognition and catalysis

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1803872115 ◽

2018 ◽

Vol 115 (45) ◽

pp. 11525-11530 ◽

Cited By ~ 4

Author(s):

Marcelo E. Guerin ◽

Guillaume Stirnemann ◽

David Giganti

Keyword(s):

Single Molecule ◽

Conformational Dynamics ◽

Conformational Sampling ◽

Enzymatic Reactions ◽

Sequence Specificity ◽

Proteomics Data ◽

Conformational Entropy ◽

Substrate Peptide ◽

The Impact

An immense repertoire of protein chemical modifications catalyzed by enzymes is available as proteomics data. Quantifying the impact of the conformational dynamics of the modified peptide remains challenging to understand the decisive kinetics and amino acid sequence specificity of these enzymatic reactions in vivo, because the target peptide must be disordered to accommodate the specific enzyme-binding site. Here, we were able to control the conformation of a single-molecule peptide chain by applying mechanical force to activate and monitor its specific cleavage by a model protease. We found that the conformational entropy impacts the reaction in two distinct ways. First, the flexibility and accessibility of the substrate peptide greatly increase upon mechanical unfolding. Second, the conformational sampling of the disordered peptide drives the specific recognition, revealing force-dependent reaction kinetics. These results support a mechanism of peptide recognition based on conformational selection from an ensemble that we were able to quantify with a torsional free-energy model. Our approach can be used to predict how entropy affects site-specific modifications of proteins and prompts conformational and mechanical selectivity.

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Conformational dynamics is key to understanding loss-of-function of NQO1 cancer-associated polymorphisms and its correction by pharmacological ligands

Scientific Reports ◽

10.1038/srep20331 ◽

2016 ◽

Vol 6 (1) ◽

Cited By ~ 23

Author(s):

Encarnación Medina-Carmona ◽

Rogelio J. Palomino-Morales ◽

Julian E. Fuchs ◽

Esperanza Padín-Gonzalez ◽

Noel Mesa-Torres ◽

...

Keyword(s):

Protein Dynamics ◽

Protein Function ◽

Conformational Dynamics ◽

Loss Of Function ◽

Quinone Oxidoreductase ◽

Protein Levels ◽

Terminal Domain ◽

Directional Preference

Abstract Protein dynamics is essential to understand protein function and stability, even though is rarely investigated as the origin of loss-of-function due to genetic variations. Here, we use biochemical, biophysical, cell and computational biology tools to study two loss-of-function and cancer-associated polymorphisms (p.R139W and p.P187S) in human NAD(P)H quinone oxidoreductase 1 (NQO1), a FAD-dependent enzyme which activates cancer pro-drugs and stabilizes several oncosuppressors. We show that p.P187S strongly destabilizes the NQO1 dimer in vitro and increases the flexibility of the C-terminal domain, while a combination of FAD and the inhibitor dicoumarol overcome these alterations. Additionally, changes in global stability due to polymorphisms and ligand binding are linked to the dynamics of the dimer interface, whereas the low activity and affinity for FAD in p.P187S is caused by increased fluctuations at the FAD binding site. Importantly, NQO1 steady-state protein levels in cell cultures correlate primarily with the dynamics of the C-terminal domain, supporting a directional preference in NQO1 proteasomal degradation and the use of ligands binding to this domain to stabilize p.P187S in vivo. In conclusion, protein dynamics are fundamental to understanding loss-of-function in p.P187S and to develop new pharmacological therapies to rescue this function.

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Conformational Dynamics of a Bacterial Actin Filament Predict In Vivo Filament Length

Biophysical Journal ◽

10.1016/j.bpj.2018.11.053 ◽

2019 ◽

Vol 116 (3) ◽

pp. 5a

Author(s):

Kerwyn C. Huang

Keyword(s):

Actin Filament ◽

Conformational Dynamics ◽

Filament Length

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From isolated light-harvesting complexes to the thylakoid membrane: a single-molecule perspective

Nanophotonics ◽

10.1515/nanoph-2017-0014 ◽

2018 ◽

Vol 7 (1) ◽

pp. 81-92 ◽

Cited By ~ 6

Author(s):

J. Michael Gruber ◽

Pavel Malý ◽

Tjaart P.J. Krüger ◽

Rienk van Grondelle

Keyword(s):

Single Molecule ◽

Thylakoid Membrane ◽

Light Harvesting ◽

Protein Complexes ◽

Conformational Dynamics ◽

Physical Models ◽

Photochemical Quenching ◽

Light Harvesting Complexes ◽

Fluorescence Measurements

AbstractThe conversion of solar radiation to chemical energy in plants and green algae takes place in the thylakoid membrane. This amphiphilic environment hosts a complex arrangement of light-harvesting pigment-protein complexes that absorb light and transfer the excitation energy to photochemically active reaction centers. This efficient light-harvesting capacity is moreover tightly regulated by a photoprotective mechanism called non-photochemical quenching to avoid the stress-induced destruction of the catalytic reaction center. In this review we provide an overview of single-molecule fluorescence measurements on plant light-harvesting complexes (LHCs) of varying sizes with the aim of bridging the gap between the smallest isolated complexes, which have been well-characterized, and the native photosystem. The smallest complexes contain only a small number (10–20) of interacting chlorophylls, while the native photosystem contains dozens of protein subunits and many hundreds of connected pigments. We discuss the functional significance of conformational dynamics, the lipid environment, and the structural arrangement of this fascinating nano-machinery. The described experimental results can be utilized to build mathematical-physical models in a bottom-up approach, which can then be tested on larger in vivo systems. The results also clearly showcase the general property of biological systems to utilize the same system properties for different purposes. In this case it is the regulated conformational flexibility that allows LHCs to switch between efficient light-harvesting and a photoprotective function.

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Unravelling the Stability and Capsid Dynamics of the Three Virions of Brome Mosaic Virus Assembled Autonomously In Vivo

10.1101/811653 ◽

2019 ◽

Author(s):

Antara Chakravarty ◽

Christian Beren ◽

Rees Garmann ◽

A.L.N. Rao

Keyword(s):

Mosaic Virus ◽

Transient Expression ◽

Rna Binding ◽

Conformational Dynamics ◽

Brome Mosaic Virus ◽

Crystallographic Structure ◽

Binding Motif ◽

Genomic Rnas ◽

Viral Capsids

ABSTRACTViral capsids are dynamic assemblies that undergo controlled conformational transitions to perform various biological functions. The replicated three-molecule RNA progeny of Brome mosaic virus (BMV) are packaged by a single capsid protein (CP) into three types of morphologically indistinguishable icosahedral virions with T=3 quasi-symmetry. Type 1 (B1v) and type 2 (B2v) virions respectively package genomic RNA1 or RNA2, while type 3 (B3+4v) co-packages genomic RNA3 (B3) and its sub-genomic RNA4 (B4). In this study, the application of a robust Agrobacterium-mediated transient expression system allowed us to assemble each virion type separately in planta. Physical and biochemical approaches analyzing the morphology, size, and electrophoretic mobility failed to distinguish between the virion types, so protease-based mapping experiments were used to analyze the conformational dynamics of the individual virions. The crystallographic structure of the BMV capsid shows four trypsin-cleavage sites (K65, R103, K111 and K165 on the A, B and C subunits) exposed on the exterior of the capsid. Irrespective of the digestion time, while retaining their capsid structural integrity, B1v and B2v released only two peptides involving amino acids 2-8 and 16-22 from the N-proximal arginine-rich RNA binding motif. In contrast, B3+4v capsids are unstable to trypsin, releasing several peptides in addition to the four sites predicted to be exposed on the capsid exterior. These results, demonstrating qualitatively different dynamics for the three types of BMV virions, suggest that the different RNA genes they contain may have different translational timing and efficiency and may even impart different structures to their capsids.IMPORTANCEThe majority of viruses contain RNA genomes protected by a shell of capsid proteins. Although crystallographic studies show that viral capsids are static structures, accumulating evidence suggests that in solution virions are highly dynamic assemblies. The three genomic RNAs (RNAs 1, 2 and 3) and a single subgenomic RNA (RNA4) of Brome mosaic virus (BMV), an RNA virus pathogenic to plants, are distributed among three physically homogeneous virions. This study examines the capsid dynamics by MALDI-TOF analyses following trypsin digestion of the three virions assembled separately in vivo using the Agrobacterium-mediated transient expression approach. The results provide compelling evidence that virions packaging genomic RNAs1 and 2 are more stable and dynamically distinct from those co-packaging RNA3 and 4, suggesting that RNA-dependent capsid dynamics play an important biological role in the viral life cycle.

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Mapping of an Internal Protease Cleavage Site in the Ssy5p Component of the Amino Acid Sensor of Saccharomyces cerevisiae and Functional Characterization of the Resulting Pro- and Protease Domains by Gain-of-Function Genetics

Eukaryotic Cell ◽

10.1128/ec.5.3.601-608.2006 ◽

2006 ◽

Vol 5 (3) ◽

pp. 601-608 ◽

Cited By ~ 22

Author(s):

Peter Poulsen ◽

Leila Lo Leggio ◽

Morten C. Kielland-Brandt

Keyword(s):

Saccharomyces Cerevisiae ◽

Amino Acid ◽

Functional Characterization ◽

Conformational Dynamics ◽

Partial Purification ◽

Response Analysis ◽

Protease Domain ◽

And Function ◽

Amino Acid Sensor

ABSTRACT Ssy5p is a 77-kDa protein believed to be a component of the SPS amino acid sensor complex in the plasma membrane of Saccharomyces cerevisiae. Ssy5p has been suggested to be a chymotrypsin-like serine protease that activates the transcription factor Stp1p upon exposure of the yeast to extracellular amino acid. Here we overexpressed and partially purified Ssy5p to improve our understanding of its structure and function. Antibodies against Ssy5p expressed in Escherichia coli were isolated and used to detect Ssy5p processing in S. cerevisiae cells. Partial purification and N-terminal sequencing of processed Ssy5p revealed in vivo cleavage of Ssy5p between amino acids 381 and 382. We also isolated constitutively signaling SSY5 mutants and quantified target promoter activation and Stp1p processing. One mutant contained an amino acid substitution in the prodomain, whereas three others harbored amino acid substitutions in the protease domain. Dose-response analysis indicated that all four mutants exhibited increased basal levels of Stp1p processing. Interestingly, whereas the three constitutive mutants mapping to the protease domain of Ssy5p exhibited the decreased 50% effective concentration (EC50) characteristic of constitutive mutations previously found in Ssy1p, Ptr3p, and Ssy5p, the EC50 of the mutation that maps to the prodomain of Ssy5p remained essentially unchanged. In a model of Ssy5p derived from its similarities with α-lytic protease from Lysobacter enzymogenes, the sites corresponding to the mutations in the protease domain are clustered in a region facing the prodomain, suggesting that this region interacts with the prodomain and participates in the conformational dynamics of sensing.

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Single-molecule spectroscopy reveals dynamic allostery mediated by the substrate-binding domain of a AAA+ machine

10.1101/2020.09.13.295345 ◽

2020 ◽

Author(s):

Marija Iljina ◽

Hisham Mazal ◽

Pierre Goloubinoff ◽

Inbal Riven ◽

Gilad Haran

Keyword(s):

Single Molecule ◽

Substrate Binding ◽

Conformational Dynamics ◽

Nucleotide Binding ◽

Binding Domain ◽

Regulatory Pathways ◽

Time Dynamics ◽

Binding Domains ◽

Substrate Binding Domain

AbstractClpB is an ATP-dependent protein disaggregation machine that is activated on demand by co-chaperones and by aggregates caused by heat shock or mutations. The regulation of ClpB’s function is critical, since its persistent activation is toxic in vivo. Each ClpB molecule is composed of an auxiliary N-terminal domain (NTD), an essential regulatory middle domain (MD) that activates the machine by tilting, and two nucleotide-binding domains that are responsible for ATP-fuelled substrate threading. The NTD is generally thought to serve as a substrate-binding domain, which is commonly considered to be dispensable for ClpB’s activity, and is not well-characterized structurally due to its high mobility. Here we use single-molecule FRET spectroscopy to directly monitor the real-time dynamics of ClpB’s NTD and reveal its involvement in novel allosteric interactions. We find that the NTD fluctuates on a microsecond timescale and, unexpectedly, shows little change in conformational dynamics upon binding of a substrate protein. During its fast motion, the NTD makes crucial contacts with the regulatory MD, directly affecting its conformational state and thereby influencing the overall ATPase and unfolding activity of this machine. Moreover, we also show that the NTD mediates signal transduction to the nucleotide-binding domains through conserved residues. The two regulatory pathways revealed here enable the NTD to suppress the MD in the absence of protein substrate, and to limit ATPase and disaggregation activities of ClpB. The use of multiple parallel allosteric pathways involving ultrafast domain motions might be common to AAA+ molecular machines to ensure their fast and reversible activation.

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Single-molecule conformational dynamics of a transcription factor reveals a continuum of binding modes controlling association and dissociation

Nucleic Acids Research ◽

10.1093/nar/gkab874 ◽

2021 ◽

Author(s):

Wei Chen ◽

Wei Lu ◽

Peter G Wolynes ◽

Elizabeth A Komives

Keyword(s):

Transcription Factor ◽

Transcription Factors ◽

Single Molecule ◽

Bound States ◽

Conformational Dynamics ◽

Conformational Ensemble ◽

Binding Modes ◽

Loss Of Function ◽

Binding Domains

Abstract Binding and unbinding of transcription factors to DNA are kinetically controlled to regulate the transcriptional outcome. Control of the release of the transcription factor NF-κB from DNA is achieved through accelerated dissociation by the inhibitor protein IκBα. Using single-molecule FRET, we observed a continuum of conformations of NF-κB in free and DNA-bound states interconverting on the subseconds to minutes timescale, comparable to in vivo binding on the seconds timescale, suggesting that structural dynamics directly control binding kinetics. Much of the DNA-bound NF-κB is partially bound, allowing IκBα invasion to facilitate DNA dissociation. IκBα induces a locked conformation where the DNA-binding domains of NF-κB are too far apart to bind DNA, whereas a loss-of-function IκBα mutant retains the NF-κB conformational ensemble. Overall, our results suggest a novel mechanism with a continuum of binding modes for controlling association and dissociation of transcription factors.

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