NMR spectroscopy in adsorption studies of metal-organic frameworks

Sin, Maria

19 January 2019

The present thesis deals with the investigation of liquid-phase and gas-phase adsorption of metal-organic frameworks (MOFs) using NMR spectroscopy. NMR-based methods are developed and then applied to characterize the surface polarity of studied materials and the influence of structural flexibility on the adsorption selectivity. In the first part of the thesis a new methodology for surface polarity screening of MOFs is proposed based on quantitative 1H NMR spectroscopic measurements of liquid-phase adsorption. The influence of the surface polarity on the adsorption process was studied on several materials, e.g. activated carbons, PAF-1, MIL-101(Cr), HKUST-1, and UiO-67-series. The surface polarity was characterized through the difference in the 1,4-dioxane adsorption uptake from two solvents of opposite polarity, namely n-heptane and N,N-dimethylformamide. An NMR-derived surface polarity index was defined where the polarity of the MOF corresponds to its affinity to polar substances. It was demonstrated that the structural modifications of MOF materials, which should affect the polarity of these MOFs, are indeed reflected by the proposed polarity index. The second part of the thesis focuses on gas mixture adsorption experiments. Metal-organic frameworks are promising candidates for selective separation processes such as CO2 from methane. Framework flexibility is observed only for some special MOFs. The main question is: Does framework flexibility influence the adsorption selectivity? High-pressure in situ 13C NMR spectroscopy was used to monitor the adsorption of 13CO2/13CH4 gas mixtures. This method allows to distinguish between the two gases as well as between adsorbed molecules and the interparticle gas phase. Gas mixture adsorption was performed under isothermal conditions. The selectivity factor for CO2 adsorption from CO2/CH4 mixtures was measured as a function of total gas pressure. The flexible material SNU-9 as well as the flexible and the non-flexible forms of DUT-8(Ni) were compared. Maximum selectivity factors for CO2 were observed for the flexible form of DUT-8(Ni) in its open-pore state. In contrast, the rigid form of DUT-8(Ni) and SNU-9 especially in its intermediate state exhibit lower adsorption selectivity factors. This observation indicates significant influence of the framework flexibility on the adsorption selectivity.

info:eu-repo/classification/ddc/540

ddc:540

Molecular Mechanisms of Allosteric Inhibition in Cylic-Nucleotide Dependent Protein Kinases / Allosteric Inhibition in Protein Kinases

Byun, Jung Ah

January 2020

Allosteric inhibition of kinases provides high selectivity and potency due to lower evolutionary pressure in conserving allosteric vs. orthosteric sites. The former are regions distinct from the kinase active site, yet, when perturbed through allosteric effectors, induce conformational and/or dynamical changes that in turn modulate kinase function. Protein kinases involved in cyclic nucleotide signalling are important targets for allosteric inhibition due to their association with diseases, from infections to Cushing’s syndrome. This dissertation specifically focuses on elucidating the molecular mechanism of allosteric inhibition in the cAMP-dependent protein kinase (PKA) and the Plasmodium falciparum cGMP-dependent protein kinase (PfPKG), which are targets for a generalized tumor predisposition commonly referred to as Carney Complex and for malaria, respectively. In chapters 2 and 3, we focus on the agonism-antagonism switch (i.e. allosteric pluripotency) observed as the phosphorothioate analog of cAMP, Rp-cAMPS (Rp), binds to PKA. Utilizing Nuclear Magnetic Resonance (NMR), Molecular Dynamics (MD) simulations and Ensemble Allosteric Model (EAM), we determined that two highly homologous cAMP-binding domains respond differently to Rp, giving rise to a conformational ensemble that includes excited inhibition-competent states. The free energy difference between this state and the ground inhibition-incompetent state is tuned to be similar to the effective free energy of association of the regulatory (R) and catalytic (C) subunits, leading to allosteric pluripotency depending on conditions that perturb the R:C affinity. The general significance of these results is a re-definition of the concept of allosteric target to include not only the isolated allosteric receptor, but also its metabolic and proteomic sub-cellular environment. In chapter 4, we utilize a mutant that silences allosteric pluripotency to reveal that the agonism-antagonism switch of PKA not only arises from the mixed response of tandem domains, but also from the mixed response of allosteric regions within a single domain that mediates interactions with Rp. In chapter 5, the allosteric inhibition of PfPKG associated with malaria is induced through base-modified cGMP-analogs and the underlying inhibitory mechanism is determined. We show that, when bound to a PfPKG antagonist, the regulatory domain of PfPKG samples a mixed intermediate state distinct from the native inhibitory and active conformations. This mixed state stabilizes key cGMP-binding regions, while perturbing the regions critical for activation, and therefore it provides an avenue to preserve high affinity, while promoting significant inhibition. Overall, in this thesis, previously elusive mechanisms of allosteric inhibition were elucidated through the combination of NMR, MD, and EAM methods. Through this integrated approach, we have unveiled an emerging theme of inhibitory ‘mixed’ states, either within a single domain or between domains, which offer a simple but effective explanation for functional allostery in kinases. / Thesis / Candidate in Philosophy

Allostery

Protein-Ligand Interactions

Cell Signalling

Kinase Inhibition

Protein Dynamics

Cyclic Nucleotides

NMR Spectroscopy

Ensemble Allosteric Model

Isolation, Analysis, and Partial Characterization of an Inhibitor of Neisseria gonorrhoeae

Paul, Natania

01 May 2019

There is an emerging threat of Neisseria gonorrhoeae strains that are resistant to all antibiotics. Because of this, the purpose of this research is to isolate, analyze, and partially characterize a new inhibitor(s) of N. gonorrhoeae. Since there is an unknown molecule secreted by Candida albicans that inhibits N. gonorrhoeae, this molecule can be partially characterized using 1H NMR Spectroscopy to assist in the development of a new antibiotic compound. It was hypothesized that quorum-sensing molecules, trans, trans- farnesol, tyrosol, phenylethyl alcohol, and tryptophol, could be possible candidates for the inhibitor. Because of this, 1H NMR spectra for these quorum-sensing molecules were obtained to serve as controls. Column chromatography and fractionation was used to isolate the inhibitor in large scale from C. albicans grown in salts-based media. Attempts to isolate the inhibitor in large scale, however, was unsuccessful since no inhibition of N. gonorrhoeae was observed. Because of this, analysis of growth media was conducted to test the media effect on producing the inhibitor. C. albicans was grown in liquid chocolate, liquid white chocolate, salts-based, and YPD media in aerobic and candle jar environments. Analysis of growth media in different environments suggests that liquid chocolate and salts-based media retain the inhibitory activity. 1H NMR spectra were obtained for the isolated molecule in liquid chocolate and salts-based media in both aerobic and candle jar environments. Analysis of this 1H NMR suggested that the inhibitor could be isolated from either the aerobic or candle jar environment for both liquid chocolate and salt-based media because a clear peak between 3.5 and 4.0 ppm was observed in all spectra. Comparison of 1H NMR spectra from quorum-sensing molecules with spectra from the isolated molecule suggests that the inhibitor is not a quorum-sensing molecule. The peaks represented by the inhibitor cannot be fully characterized and thus, either correspond to a single molecule or a complex molecular structure. It can be concluded that the inhibitor secreted by C. albicans to inhibit N. gonorrhoeae is a new unknown compound.

Candida albicans

quorum-sensing molecules

NMR spectroscopy

Amino Acids, Peptides, and Proteins

Macromolecular Substances

Medicine and Health Sciences

Pathogenic Microbiology

Folding of <i>ortho</i>-phenylene oligomers

Mathew, Sanyo

31 July 2014

No description available.

Chemistry

Organic Chemistry

Materials Science

Physical Chemistry

ortho-phenylene

conformation

folding

oligomers

monomer

NMR spectroscopy

substituent effect

refunctionalization

Study Of Structure, Dynamics & Self-Assembly Of Human Insulin-Like Growth Factor Binding Protein-2 By Novel NMR And Biophysical Methods

Swain, Monalisa

07 1900

My research work for PhD has focused on: (i) the development and application of new NMR methodologies to solve challenging problems in structural biology and (ii) studying important biological systems to correlate their structural and functional aspects. I have worked on diverse research projects ranging from NMR methodology development to the study of structure and dynamics of protein-based nanotubes. Chapter 1 of my thesis gives brief introduction to bio-molecular NMR spectroscopy and the different biological systems that I have studied. In recent years, several new methods have emerged for rapid NMR data collection. One class of methods is G-matrix Fourier transform (GFT) projection NMR spectroscopy. GFT NMR spectroscopy involves phase sensitive joint sampling of two or more chemical shifts in an indirect dimension of a multidimensional NMR experiment. Chapter 2 describes a new method based on the principle of GFT NMR for increasing further the speed of data collection. In the current implementations of the GFT method, cosine/sine modulation of all chemical shifts involved in the joint sampling are collected and stored as separate FIDs. A post-acquisition data processing step (application of G-matrix) then separates the different inter-modulations of chemical shifts. Thus, joint sampling of K+1 spins results in 2K combination of chemical shifts (also representing 2K projection angles). One limitation of this approach is that even if only a few of the 2K components of the multiplet (or projection angles) is desired, an entire data set containing information for all 2K shift combinations is collected. We have proposed a simple method which releases this restriction and allows one to selectively detect only the desired linear combination of chemical shifts/projection angles out of 2K combinations in a phase sensitive manner. The method involves selecting the appropriate cosine/sine modulations of chemical shifts and forming the desired linear combination by phase cycling of the radiofrequency pulses and receiver. This will benefit applications where only certain linear combination of shifts are desired or/and are sufficient. Further, G-matrix transformation required for forming the linear combination is performed within the pulse sequence. This avoids the need for any post-acquisition data processing. Taken together, this mode of data acquisition will foster new applications in projection NMR spectroscopy for rapid resonance assignment and structure determination. Chapter 3 describes another GFT NMR-based method for rapid estimation of secondary structure in proteins. This involves the detection of specific linear combination of backbone chemical shifts and facilitates a clear separation and estimation of residues in different secondary structures of a given protein. This methodology named as CSSI-PRO (Combination of Shifts for Secondary structure Identification in PROteins), involves detection of specific linear combination of backbone 1Hα and 13C’ chemical shifts in a two dimensional (2D) NMR experiment. Such linear combination of shifts facilitates editing of residue belonging to α-helical/ β-strand regions into distinct spectral regions nearly independent of the amino acid type. This helps in the estimation of overall secondary structure content of the protein. Comparison of the estimated secondary structure content with those obtained from the respective 3D structures and/or the method of Chemical Shift Index (CSI) was carried out for 254 proteins and gives a correlation of more than 90% and an overall RMSD of 6.5%. The method has high sensitivity and data can be acquired in a few minutes. This methodology has several applications such as for high-throughput screening of proteins in structural proteomics and for monitoring conformational changes during protein folding and/or ligand-binding events. Chapter 4 (Part-A and Part-B) describes an area of my research which involves the study of structure and function in the Insulin-like Growth Factor Binding Protein (IGFBP) family. IGFBPs (six in number; IGFBP1-6) belong to the IGF-system, which plays an important role in growth and development of the human body. This system is comprised of the following components: (i) Two peptide hormones, IGF-1 and -2, (ii) type 1 and type 2 IGF receptors, (iii) six IGF-binding proteins (IGFBP; numbered 1-6) and (iv) IGFBP proteases. IGF-1 and -2 are small signalling peptides (~7.5 kDa) that stimulate action by binding to specific cell surface receptors (IGF-1R) evoking subsequent response inside the cell. Six soluble IGF binding proteins, the IGFBPs, which range in 22-31 kDa in size and share overall sequence and structural homology with each other, regulate the activity of the IGFs. IGFBPs bind strongly to IGFs (KD ~ 300-700 pM) to ensure that all the circulating IGF in the blood stream is sequestered and inhibit the action of IGFs by blocking their access to the receptors. Proteolysis of the IGFBPs dissociates IGFs from the complex, enabling them to bind and activate the cell surface receptors. IGFBPs have been recently implicated in different cancers and HIV/AIDS. However, the nature of their interaction with the ligand: IGF-1 or IGF-2 at a molecular level poorly understood. This is due to the difficulty in over-expressing these proteins in large scale and in soluble amounts which is required for structural studies. We have for the first time developed an efficient method for bacterial expression of full-length human IGFBP-2, a 33 kDa system, in soluble (upto 30 mg/ml) and folded form. Using a single step purification protocol, hIGFBP-2 was obtained with >95% purity and structurally characterized using NMR spectroscopy. The protein was found to exist as a monomer at the high concentrations required for structural studies and to exist in a single conformation exhibiting a unique intra-molecular disulfide-bonding pattern. The protein retained full biologic activity as evident from its strong binding to IGF-1 and IGF-2 detected using surface plasmon resonance (SPR). This study represents the first high-yield expression of wild-type recombinant human IGFBP-2 in E. coli and first structural characterization by NMR. Using different NMR methods, we are now in the process of elucidating the 3D structure of this molecule. Chapter 5 (Part-A and Part-B) describes our discovery of nanotubular structures formed by spontaneous self-assembly of a small fragment from the C-terminal domain of hIGFBP-2. The nanotubular structures are several micrometers long and have a uniform outer diameter of ~35 nm. These structures were studied extensively by NMR and other techniques such as TEM, fluorescence and circular dichroism (CD). The water soluble nanotubes form through intermolecular disulphide bonds due to the presence of three cysteines in the polypeptide chain and exhibit enhanced tyrosine fluorescence. Based on different experimental evidences we have proposed a mechanism for the formation of the nanotubes. This was considered as a breakthrough by the journal ChemComm and featured on the cover-page of the journal. An article highlighting the discovery was also published in RSC news. In recent years, a number of novel polypeptide and DNA based nanotubes have been reported. Our study reveals intrinsically fluorescent self-assembling nanotubes made up of disulphide bonds having the following novel properties: (i) their formation/dissociation can be controlled by tuning the redox conditions, (ii) they do not require the support of any additional chemical agent for self-assembly, (iii) they have high stability due to the involvement of covalent interactions, (iv) the monomer is a small polypeptide chain which can be chemically synthesized or produced using simple recombinant methods and (v) they possess high inherent fluorescence and can thus be easily detected against a background of other proteins. In addition, the presence of an RGD motif in this polypeptide fragment offers avenues for novel biomedical applications. The RGD motif is known to be recognized by integrins. The design of such self-assembling polypeptide fragments containing an RGD motif can be utilized to enhance the efficacy of cancer therapeutics. Towards this end, we have investigated the structural basis of formation of these nanotubular structures by NMR spectroscopy and proposed its application for cancer cell imaging.

NMR Spectroscopy

Structural Biology

Protein Function

Protein Structure

Protein NMR Sprectroscopy

GFT-NMR Spectroscopy

Protein-based Nanotubes

Self-assembled Nanotubes

G-Matrix Fourier Transorm

hIGFBP-2

Human IGFBP-2

GFT Projection NMR Spectroscopy

Biochemistry

Biochemical and biophysical studies of the prokaryotic proton dependent oligopeptide transporters

Solcan, Nicolae Claudiu

January 2013

The proton dependent oligopeptide transporters (POT family) are members of the Major Facilitator Superfamily of secondary active transporter proteins. They use the transmembrane proton gradient to drive the uptake of di- and tripeptides into the cytoplasm. Members of the family are highly conserved in pro- and eukaryotic genomes, and in humans they are responsible for the oral absorption of many drug families, including -lactam antibiotics. Recently, the crystal structures of PepTSo and PepTSt, two prokaryotic homologues of the human proteins PepT1 and PepT2, captured the proteins in two distinct conformations, providing insight into the structural aspects of the transport mechanism. A protocol was designed for functional liposome reconstitution of POT proteins, and transport assays were conducted to characterise their substrate specificity, pH dependence and kinetic properties. Using site-directed mutagenesis, we identified binding site residues involved in peptide recognition and proton translocation, and distinguished between the two roles by comparing protein activity in proton- and peptide-driven conditions. We also investigated the roles of key residues in the conformational transitions that accompany the transport cycle, using data from biochemical assays, molecular dynamics simulations and modeling, as well as electron paramagnetic resonance measurements. In addition, several bacterial POT members were screened for crystallisation, in order to assess their stability and crystal diffraction quality in different detergents. Further work was performed with bacterial POT homologues YdgR and GkPOT, including binding studies using NMR spectroscopy and assaying drug transport in vivo and in vitro. Together, the data establish bacterial POTs as model systems for studying the mammalian oligopeptide transporters, and a mechanistic model for peptide transport is proposed.

572

Highly efficient quantum spin dynamics simulation algorithms

Edwards, Luke J.

January 2014

Spin dynamics simulations are used to gain insight into important magnetic resonance experiments in the fields of chemistry, biochemistry, and physics. Presented in this thesis are investigations into how to accelerate these simulations by making them more efficient. Chapter 1 gives a brief introduction to the methods of spin dynamics simulation used in the rest of the thesis. The `exponential scaling problem' that formally limits the size of spin system that can be simulated is described. Chapter 2 provides a summary of methods that have been developed to overcome the exponential scaling problem in liquid state magnetic resonance. The possibility of utilizing the multiple processors prevalent in modern computers to accelerate spin dynamics simulations provides the impetus for the investigation found in Chapter 3. A number of different methods of parallelization leading to acceleration of spin dynamics simulations are derived and discussed. It is often the case that the parameters defining a spin system are time-dependent. This complicates the simulation of the spin dynamics of the system. Chapter 4 presents a method of simplifying such simulations by mapping the spin dynamics into a larger state space. This method is applied to simulations incorporating mechanical spinning of the sample with powder averaging. In Chapter 5, implementations of several magnetic resonance experiments are detailed. In so doing, use of techniques developed in Chapters 2 and 3 are exemplified. Further, specific details of these experiments are utilized to increase the efficiency of their simulation.

543

NMR δομικός χαρακτηρισμός του RING τομέα της Ε3 λιγάσης ουβικιτίνης ARKADIA, με τροποποιημένο μοτίβο δέσμευσης ιόντων Ψευδαργύρου, του τύπου Cys3-His-Cys4

Βλάχου, Πολυτίμη-Μαρία

11 October 2013

Η αποικοδόμηση των πρωτεϊνών είναι μια διαδικασία απαραίτητη για τη διατήρηση της ομοιόστασης του κυττάρου. Ένας από τους κύριους μηχανισμούς αποικοδόμησης των βραχύβιων πρωτεϊνών καθώς και όσων εμφανίζουν λανθασμένη αναδίπλωση, χωρεί μέσω του μονοπατιού ουβικιτίνης- πρωτεασώματος. Η ουβικιτινίωση είναι μια μετα-μεταφραστική διαδικασία, η οποία έγκειται στη σηματοδότηση των υποψήφιων για αποικοδόμηση πρωτεϊνών με ουβικιτίνη και περιλαμβάνει τρεις ενζυμικές ενεργότητες: Ε1 (εκκινητής ουβικιτίνης), Ε2(μεταφορέας ουβικιτίνης) και Ε3 (λιγάση ουβικιτίνης). Η πρωτεΐνη Arkadia (Rnf11) είναι μια Ε3 λιγάση ουβικιτίνης με συνολικό μήκος 994 αμινοξέα. Σε μοριακό επίπεδο, ενισχύει το TGF-β σηματοδοτικό μονοπάτι, διαμεσολαβώντας την εξαρτώμενη από το πρωτεάσωμα αποικοδόμηση των αρνητικών ρυθμιστών του, c-Ski και Sno-N. Η δραστικότητα Ε3 λιγάσης ουβικιτίνης εδράζεται στον C΄-τελικό RING-H2 τομέα, που σχηματίζεται από τα τελευταία 60 περίπου αμινοξέα της ακολουθίας. Η δομή και η σταθερότητα του RING τομέα εξαρτώνται από την πρόσδεση δύο ιόντων Zn μέσω ενός χαρακτηριστικού μοτίβου, που περιλαμβάνει 6 κυστεϊνικά και 2 ιστιδινικά κατάλοιπα. Στην προσπάθεια αποσαφήνισης της σχέσης δομής-δράσης της πρωτεΐνης Arkadia, ένα από τα κατάλοιπα που συναρμόζονται με Zn -συγκεκριμένα η His965- αντικαταστάθηκε από κυστεΐνη μέσω κατευθυνόμενης μεταλλαξιγένεσης. Η μετάλλαξη αυτή, με την οποία, ουσιαστικά, μετατρέψαμε τον RING-H2 σε RING-HC τομέα, μελετήθηκε με χρήση πολυπυρηνικής/πολυδιάστατης φασματοσκοπίας πυρηνικού μαγνητικού συντονισμού (NMR). H NMR δομή του RING-H2 τομέα της Η965C Arkadia επιλύθηκε σε υψηλή διακριτικότητα (tf=0.94±7.53*10-2, RMSD=0.75±0.20 και RMSD=1.45±0.24 για τα άτομα του πολυπεπτιδικού σκελετού και τα βαρέα άτομα αντίστοιχα) και αποκάλυψε μια ββαββ τοπολογία. Παράλληλα, πραγματοποιήθηκε μελέτη κινητικότητας, από την οποία προέκυψε ότι η εν λόγω μετάλλαξη υφίσταται ως μονομερές και διαθέτει έναν συμπαγή πυρήνα, που περικλείεται μεταξύ δύο ευκίνητων άκρων. / Protein degradation is necessary for the maintenance of cell homeostasis. A major mechanism for the degradation of short-lived as well as misfolded proteins involves the ubiquitin-proteasome pathway. Ubiquitination is a post translational modification, which targets the proteins to be degraded through the covalent attachment of a ubiquitin tag and consists of three enzyme activities: Ε1 (ubiquitin activator), E2 (ubiquitin carrier) and E3 (ubiquitin ligase). Arkadia (Rnf11) is a 994 amino acid protein, which acts as an E3 ubiquitin ligase. On a molecular level, Arkadia enhances TGF-β signaling by mediating the proteasome-dependent degradation of its negative regulators, c-Ski and Sno-N. Its E3 ubiquitin ligase activity lies on a C΄-terminal RING-H2 domain, formed by the last 60 residues. The structure as well as stability of the RING finger domain depend strongly on the binding of two zinc ions in a unique ΄΄cross-brace΄΄ arrangement through a defined motif of six cysteines and two histidines. Trying to elucidate the structure-activity relationship in the case of Arkadia, one of the amino acid ligands –specifically His965- was replaced by cysteine through site-directed mutagenesis. This particular mutation, which, in reality, transformed the RING-H2 to a RING-HC domain, was studied with the use of multinuclear/multidimensional nuclear magnetic resonance spectroscopy (NMR). The NMR solution structure of the H965 Arkadia RING-H2 domain was determined in high resolution (tf=0.94±7.53*10-2, RMSD=0.75±0.20 και RMSD=1.45±0.24 for backbone and heavy atoms respectively) and revealed a ββαββ topology. Furthermore, a mobility study was conducted with the following results: the mutated protein is not expected to form dimers and shows a compact core region including the four metal binding motifs flanked by two flexibly disordered termini.

NMR φασματοσκοπία

RING finger τομέας

Ε3 λιγάση ουβικιτίνης

612.398

NMR spectroscopy

Structural characterization

RING finger domain

E3 ubiquitin ligase

Structure and dynamics of the aggregation mechanism of the Parkinson´s disease-associated protein alpha-synuclein / Strukturelle Studien des alpha-synuclein, ein Protein impliziert mit der Parkinson-Krankheit

Bertoncini, Carlos Walter

05 July 2006

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Amyloid

NMR-Spektroskopie

Aggregation des Proteins

neurodegenerative-Krankheit

Amyloid

NMR spectroscopy

Protein agregation

Neurodegenerative diseases

35.25

42.12

Structural studies of integrin activation

Anthis, Nicholas J.

January 2009

Fundamental to cell adhesion and migration, integrins are large heterodimeric membrane proteins that link the extracellular matrix to the actin cytoskeleton. Uniquely, these adhesion receptors mediate inside-out signal transduction, whereby extracellular adhesion is activated from within the cell by talin, a large cytoskeletal protein that binds to the cytoplasmic tail of the β integrin subunit via its PTB-like F3 domain. Features of the interface between talin1 and small β3 fragments only have been described previously. Through NMR studies of full-length integrin β tails, we have found that β tails differ widely in their interactions with different talin isoforms. The muscle-specific β1D/talin2 complex exhibited particularly high affinity, leading to the X-ray crystal structure of the β1D tail/talin2 F2-F3 complex. Further NMR and biological experiments demonstrated that integrin activation is induced by a concerted series of interactions between the talin F3 domain and the β tail and between the talin F2 domain and the cell membrane. Additional studies revealed the structural determinants of tight talin2/β1D binding and the basis of more general differences between β1 and β3 talin binding. NMR studies were also performed on tyrosine-phosphorylated integrin tails binding to the PTB domains of talin1 and Dok1, an inhibitor of integrin activation; these revealed that phosphorylation can inhibit integrin activation by increasing the affinity of the β tail for talin competitors. Key residues governing this switch were identified, and proteins were engineered with reversed affinities, offering potentially useful biological tools. Taken together, these results reveal the remarkable complexity of structural features that enable talin and its competitors to mediate this important form of transmembrane signalling.

571.6