New insights into the structure and assembly of nuclear lamins from chemical cross-linking and mass spectrometry

Makarov, Alexandr

January 2017

Now that the functioning of microtubules and the actin cytoskeleton has been worked out in enormous detail, the next important task is defining the structure of intermediate filaments that are far behind the other two major skeletal networks due to their inherent resistance to most structural techniques. The evolution of novel structural approaches for flexible proteins is making this possible now. In my thesis I will aim to elucidate the structure and assembly principles of lamin A nuclear intermediate filament protein. To study lamin A, I principally employed chemical cross-linking that allows the capturing of full-length protein structures in solution. I combined this with mass spectrometry approaches to identify cross-linked residues at the various stages of lamin A assembly that were additionally tracked with SILAC labelling and rotary metal shadowing TEM. Unlike previous cross-linking studies on intermediate filaments I use a zero-length self-excluding cross-linking agent EDC that is better tailored for investigation of the polar interactions between multiple unstructured or otherwise flexible charged sequences of lamins. Using this composite approach I interrogated lamin A dimeric and tetrameric assemblies. I elucidated hinge-like properties of the L12 and found indications that L1 and the region containing coil 2A and L2 and the beginning of coil 2B possess properties of linker-like flexibility and of predicted linear α-helical bundle and could act as molecular springs or compression buffers for the nuclear intermediate filaments. Further I confirm the role of the N-terminal unstructured region in lamin A assembly and for the first time show similar role for the C-terminal unstructured region flanking the rod domain of lamin A. Collected data strongly supports the model where both positively charged unstructured regions participate in extensive interaction with acidic rod termini and act as molecular bridges between these in the head-to-tail interface, confirming the uniformity of this principle between cytoplasmic and nuclear intermediate filaments. Formation of these bridges requires conformational change likely happening due to proline residues in the mitotic phosphorylation sites. Finally I suggest a mechanism of regulation of the order of assembly unique to the nuclear intermediate filament where C-terminal unstructured region blocks lateral interactions until it is tethered to the head-to-tail interface. Collected data on the dynamic behaviour of the C-terminal unstructured region and its ability to tether lamin A Ig domain may have far reaching implications for filament assembly and regulation of binding of hundreds of lamin A partner proteins presenting an important step in our understanding of relationship between lamin A structure and function and how altering the former could lead to disease.

Structure - functional relationships of Right handed coiled-coil (RHCC) from the Archaea, Staphylothermus marinus

Ogbomo, Efehi Kelly

10 September 2010

Hyperthermophilic proteins are of great interest in both the academic and industrial world in understanding how these proteins are capable of retaining their biological activity under such harsh environmental conditions. This thesis studies a tetrabrachion stalk domain from Staphylothermus marinus, know as Right Handed Coiled Coil (RHCC). This protein is of interest due to its extreme thermostability and its affinity for heavy metals. We aim to better understand the reason for the extreme thermal stability of the protein and to take advantage of the proteins affinity for heavy metals with a view to developing a novel approach to bioremediate Hg2+, a major environmental pollutant. Our results clearly indicated that the protein is more thermostable in alkaline conditions in comparison to acidic conditions. This observation can be explained by careful inspection of the high resolution structure. Our data also clearly show that RHCC is able to bind ionic mercury compounds such as mercury nitrate and dipotassium mercury iodide.

Hyperthermophile

Coiled coil

S-layer

Mercury

Hydrophobic cavity

Bioremediation

Structure - functional relationships of Right handed coiled-coil (RHCC) from the Archaea, Staphylothermus marinus

Ogbomo, Efehi Kelly

10 September 2010

Hyperthermophilic proteins are of great interest in both the academic and industrial world in understanding how these proteins are capable of retaining their biological activity under such harsh environmental conditions. This thesis studies a tetrabrachion stalk domain from Staphylothermus marinus, know as Right Handed Coiled Coil (RHCC). This protein is of interest due to its extreme thermostability and its affinity for heavy metals. We aim to better understand the reason for the extreme thermal stability of the protein and to take advantage of the proteins affinity for heavy metals with a view to developing a novel approach to bioremediate Hg2+, a major environmental pollutant. Our results clearly indicated that the protein is more thermostable in alkaline conditions in comparison to acidic conditions. This observation can be explained by careful inspection of the high resolution structure. Our data also clearly show that RHCC is able to bind ionic mercury compounds such as mercury nitrate and dipotassium mercury iodide.

Hyperthermophile

Coiled coil

S-layer

Mercury

Hydrophobic cavity

Bioremediation

Characterization of the Dynein-Dynactin Interaction

Findeisen, Peggy

01 August 2014

No description available.

570

Dynactin

Dynein

Crystallisation

Coiled-coil

Cross-linking

Biologie (PPN619462639)

Die a-Untereinheiten von Ionenkanälen assemblieren durch eine Tetramerisierung von Coiled-Coils

Jenke, Marc.

Unknown Date

Universiẗat, Diss., 2003--Frankfurt (Main).

Characterization of the intrinsically disordered and multimerization regions of the Henipavirus P proteins / Caractérisation des régions intrinsèquement désordonnées et multimérisation des protéines P de Henipavirus

Beltrandi, Matilde

20 December 2016

Le objectif de ma thèse était la caractérisation moléculaire de la P des virus Nipah et Hendra (BL4) du genre Henipavirus. Le génome est encapsidé par la N qui sert de substrat pour la transcription et la réplication. La polymérase est composée par la L e son cofacteur la P. La P est composée d’un domaine N-terminal (PNT) désordonné et un domaine C-terminal (PCT) constitué d’une alternance de régions désordonnés et ordonnés (PMD domaine de multimerization). J'ai étudié PMD, PCT et PNT utilisant le «cross-linking», le CD, le SAXS, la RMN et la modélisation moléculaire. J'ai montré que le PMD du Hendra et Nipah sont un coiled-coil triméreric. La région PCT, est également un trimère en solution. Les protéines P des henipavirus constituent à ce jour le seul exemple de protéines P paramyxovirales ayant une organisation trimérique. En utilisant le SAXS, j'ai obtenu une description de Hendra PNT en tant qu’ensemble conformationnel. J'ai entrepris la caractérisation de la PNT par RMN. J’ai divisée la PNT avec l’approche divide et impera (PNT1,2,3,4). J’ai pu réaliser des expériences permettant l’attribution de PNT1, et j’ai également effectué des mesures de relaxation (R1, R2 et NOE) sur les fragments PNT1, PNT2 et PNT3. Les résultats issus des travaux effectués ont ouvert la voie vers l’obtention d’une description atomistique de la PNT en tant qu'ensemble conformationnel. Ces informations avec les informations structurales que j’ai sur PCT, PMD et XD, devraient conduire à une description atomistique de la P entière en tant qu’ensemble conformationnel. Ces informations structurales détaillées constitueront aussi un socle pour des approches antivirales rationnelles. / The objective of my PhD project was the molecular characterization of the P protein from the Nipah and Hendra viruses (BL4) belonging to the Henipavirus genus. The genome is encapsidated by the N that is the substrate for transcription and replication. The polymerase is made up the L and its cofactor the P. The P protein consists of an intrinsically disordered N-terminal domain (PNT), and a C-terminal domain (PCT) made of alternating disordered and ordered domain (PMD or P multimerization domain). I investigated the PMD, PCT and PNT regions, using cross-linking, AUC, CD, SAXS, NMR and molecular modeling. I showed that Hendra and Nipah PMD are a trimeric coiled-coil in solution. The Henipavirus proteins constitute so far the unique examples of a trimeric organization in paramyxoviral P proteins. The PCT is a trimer as well. Using SAXS, I obtained an ensemble description of PNT. To obtain site-specific information that improve SAXS-based models, I undertook the characterization of Hendra PNT by NMR. The latter was divided using the “divide et impera” approach to get four fragments (PNT1,2,3,4). Experiments for the assignment have been performed for PNT1. R1, R2 and NOE were carried out on PNT1,2,3. Altogether the results laid the basis for achieving an atomic-resolution conformational ensemble description of Hendra PNT. This information, combined with structural information that I collected on PCT, PMD and XD, is expected to lead an atomistic ensemble description of the full-length P, which would represent the first, such a description of a paramyxoviral P protein. This detailed structural information will also constitute an asset for rational antiviral approaches.

Idp

Saxs

Nmr

Coiled-Coil

Nipah Handra virus

Idp

Saxs

Nmr

Coiled-Coil

Nipah Handra virus

572

Peptide und Peptidnukleinsäuren zur Markierung und Organisation von Rezeptoren auf lebenden Zellen

Gröger, Katharina

14 August 2018

Nukleinsäuren und Peptide erlauben es, Kontrolle über molekulare Prozesse auszuüben. In dieser Arbeit werden strukturgebende Elemente wie Coiled-Coil-Peptide oder PNA∙DNA-Strukturen genutzt, um Rezeptoren auf lebenden Zellen zu markieren und in ihrem Verhalten zu modulieren, oder cytosolische Proteine in ihrem Bindungsverhalten zu steuern. Im ersten Konzept wird die Interaktion des Coiled-Coil-Paars K3/E3 genutzt, um eine Transferreaktion, in welcher eine PNA-Sequenz vom K3-Donor auf den E3-Akzeptor übertragen wird, zu induzieren. Durch die Fusion des Akzeptorpeptids mit einem Rezeptor werden kovalente PNA-Rezeptorkonjugate auf der Oberfläche lebender Zellen geschaffen. Die Reaktion zwischen Thiol und Thioester erlaubt dabei einen schnellen Transfer. So wurden Rezeptoren aus der Familie der GPCR sowie der EGFR mit einem PNA-Strang versehen und durch fluoreszente PNA oder DNA selektiv markiert. Zusätzlich wurden verzweigte DNA-Architekturen mit mehreren Fluorophoren genutzt, um die Helligkeit der Markierung quantitativ zu erhöhen. Die PNA-EGFR-Konjugate wurden durch eine zwei Rezeptoren verbrückende Cy3-DNA adressiert und so zeitgleich markiert und dimerisiert. Dadurch wurde die Rezeptoraktivität gesteigert, was über Western Blot-, Immunofluoreszenz- und Fluoreszenzmikroskopieanalyse belegt wurde. In weiteren Ansätzen wurden Coiled-Coil-Systeme genutzt, um i) parallel zwei verschiedene Akzeptorpeptide mit verschiedenen Fluorophoren zu markieren und ii) Coiled-Coil-Peptide schaltbar zu machen. Durch die asymmetrische Verlängerung von K3/E3-Paaren mit Coiled-Coil-Sequenzen kann die Interaktion der Peptide an und aus geschaltet werden. Dies wurde sowohl in einem Fluoreszenzassay als auch in einer direkten Anwendung an der Syk-Kinase demonstriert. Die Liganden der Kinase wurden an den schaltbaren Peptiden angebracht und so die Affinität zur Syk-Kinase kontrolliert. / Nucleic acids and peptides can be used to obtain control over molecular processes within living cells. In this work, structural elements as coiled-coil peptides or PNA∙DNA-structures were used to label and modulate receptor behavior on living cells and to control ligand binding of cytosolic proteins. For the first concept the K3/E3-coiled-coil peptide pair was used to establish a proximity-guided, covalent transfer of a PNA strand from a K3-donor peptide onto the complementary E3-acceptor peptide. By fusion of the acceptor peptide to a receptor, PNA-receptor-conjugates were generated selectively on living cells. The native chemical ligation type of reaction allowed a fast PNA-transfer within minutes. Receptors from the family of GPCRs and the EGFR were tagged with a PNA-sequence and subsequently labeled by the addition of a fluorescent DNA or PNA. By recruiting branched DNA architectures which were decorated with several fluorophores, the total brightness of the labeling was increased quantitatively. A twice complementary Cy3-DNA was used to simultaneously label and dimerize the EGFR. Thereby, an artificially induced increase in receptor activity could be achieved, which was shown in Western Blot and immunofluorescence analysis as well as in fluorescence microscopy. In two other approaches coiled-coil peptides were used to i) label two different acceptor peptides simultaneously with two different dyes and ii) introduce coiled-coil peptides as part of a dynamic switchable system. Using an asymmetric coiled-coil elongation on the K3/E3 pair the interaction of both can be turned on and off. This was demonstrated in a fluorescence assay and applied to the Syk kinase, were Syk ligands were attached to the switchable peptides. Those ligands were changed from a bi- to a monovalent presentation status and thus the affinity of the Syk kinase towards its ligands can be controlled.

Coiled-Coil-Peptide

Rezeptordimerisierung

Proteinmarkierung

PNA-Transfer

Coiled-Coil-Peptides

Receptor Dimerization

Protein Labelling

PNA-Transfer

547 Organische Chemie

VK 8567

ddc:547

Peptidtemplat-vermittelte Transferreaktionen

Reinhardt, Ulrike

06 March 2017

Um die Funktion von Proteinen in ihrer natürlichen Umgebung zu verstehen, ist es unerlässlich ihre Lokalisation und Bewegung im lebenden System durch z.B Fluoreszenz-markierung sichtbar zu machen. Eine ideale Markierungsmethode zeichnet sich dadurch aus, dass sie das Zielprotein (protein of interest, POI) selektiv und in kurzer Zeit mit einer maßgeschneiderten Reportergruppe ausstattet, ohne die Proteinfunktion und -lokalisation zu beeinflussen. Dabei ist die Größe der Erkennungssequenz von großer Bedeutung. In dieser Arbeit wird die Entwicklung einer Markierungsstrategie beschrieben, bei der die Ausbildung eines parallelen Coiled-Coil-Motivs den Transfer einer Reportergruppe auslöst. Untersucht wurde dabei die Übertragung eines Sulfonat-gebundenen Fluorophors auf ein Cystein in der Erkennungssequenz durch nukleophile Substitution. Ebenfalls untersucht wurde der Transfer verschiedener Thioester-verknüpfter Reporter auf ein N-terminales Cystein der Erkennungssequenz durch eine Acyltransferreaktion. Beide Strategien zeichnen sich durch eine hohe Selektivität und einen geringen Massenzuwachs am Zielprotein aus. Der Acyltransfer mit Arylthioestern zeigte zudem eine bemerkenswerte Reaktivität und erlaubte eine Markierung innerhalb weniger Minuten Reaktionszeit. Die Vielfältigkeit dieser Methode wurde anhand der Fluoreszenzmarkierung von sieben verschiedenen G-Protein gekoppelten Membranrezeptoren auf der Oberfläche lebender Zellen demonstriert. Die markierten Rezeptoren blieben dabei funktional und konnten ihren entsprechenden Liganden mit hoher Affinität binden. / In order to understand the function of proteins in their native environment, it is crucial to visualize their localization and trafficking in living cells by means of e.g. fluorescence labeling. An ideal labeling method adds a custom reporter group to the protein of interest (POI) in a selective and fast manner without disturbing the POIs function and localization. Hence the size of the recognition sequence is of major concern. This work describes the development of a labeling strategy in which the formation of a parallel coiled coil motif triggers the transfer of a reporter group. The transfer of a sulfonate-linked fluorescence dye onto the cysteine-modified recognition sequence via a nucleophilic substitution reaction was tested. Also the transfer of various thioester-linked reporters onto the N-terminal cysteine of the recognition sequence via an acyl transfer reaction was investigated. Both strategies are characterized by a high selectivity and low mass increase at the target protein. The acyl transfer with aryl thioesters also showed a remarkable reactivity and allowed labeling reactions to proceed within minutes. The versatility of this method was demonstrated by applying it to the labeling of seven different G-protein coupled membrane receptors on the surface of living cells. The labeled receptors remained functional and were able to bind their respective ligand with high affinity.

Transferreaktionen

Peptidtemplate

Proteinmarkierung

Coiled-Coil-Peptide

transfer reactions

peptide templates

protein labeling

coiled coil peptides

540 Chemie

30 Chemie

VK 8567

ddc:540

Monomeric states of the beta-amyloid peptide investigated under high pressure by nuclear magnetic resonance spectroscopy / Estados monoméricos do peptídeo beta-amiloide investigados sob alta pressão por espectroscopia de ressonância magnética nuclear

Cavini, Ítalo Augusto

17 December 2018

The main histological feature of Alzheimer\'s disease is the presence of amyloid plaques in the patient\'s brain. The most abundant element of these plaques is the β-amyloid peptide (Aβ). Initially soluble, the peptide exhibits in solution an intricate equilibrium among monomeric, oligomeric (some of which are regarded as the toxic species) and fibrillar states, which prevents its crystallization and subsequent structural determination by X-ray diffraction. High-pressure nuclear magnetic resonance (NMR) spectroscopy has been used by our group to detect rare, high-energy monomeric Aβ (1-40) states, coexisting in equilibrium with oligomers and fibrils. This work aims to characterize the thermodynamics and the structure of the rare excited states of the Aβ peptide through the use of high pressure NMR. A large collection of NMR spectra of the Aβ (1-40) peptide as a function of pressure was recorded and analyzed. Secondary structure predictions revealed that the Aβ peptide adopts extended β-strand-like structures, similar to those found in amyloid-fibril structures. From the pressure curves of chemical shifts and cross-peak volumes, at least three monomeric states could be detected, which were thermodynamically characterized by the calculation of the variation of their Gibbs free energy (ΔGij) and molar partial volumes (ΔVij). The study of nuclear Overhauser effects (NOEs) and 3JHα-HN NMR couplings reinforces the existence of extended structures with β-strand propensity, both at ambient (0.1 MPa) and high (275 MPa) pressures. The interaction between the Aβ peptide and the D-peptides RD2 and RD2D3, D-enantiomeric fibril inhibitors, was also characterized. Our results indicate that the D-peptides recognize and bind to a more compact conformation of Aβ. The formation of the Aβ-D-peptide heterodimers ultimately prevents the formation of toxic oligomers, therefore representing a potential therapy against Alzheimer´s disease. Additionally, in the second chapter, we present results on the coiled-coils (CC) from group-III human septins (SEPT1, SEPT2, SEPT4 and SEPT5) also studied by NMR spectroscopy. Septins are GTP-binding proteins present in most eukaryotic organisms and capable of forming filaments, which are essential in cell division. In this study, we used 1H-1H-NOESY spectra to detect the orientation and helix pairings adopted by the C-terminal coiled-coils in solution. The NOE analysis, aided by back-calculated spectra, showed that the only sequence to show an antiparallel structure was SEPT2CC; all the others are parallel. However, the disappearance of specific peaks in the NMR spectrum of SEPT5CC caused by the attachment of a paramagnetic spin label indicates an antiparallel orientation, contrary to our other NMR result. A simple evaluation of the coiled-coil heptameric positions, based on the occurrence of each amino acid residue occupying each position, revealed that both orientations are equally stable. Despite being far less stable compared to other coiled-coils, both could exist physiologically. Other results from the group also suggest that these peptides could have the ability to form both parallel and antiparallel coiled-coils. We speculate that the antiparallel conformation might be related to cross-linking between filaments. / A principal característica histológica da doença de Alzheimer é a presença de placas amiloides no cérebro de pacientes. O constituinte mais abundante dessas placas é o peptídeo β-amiloide (Aβ). Inicialmente solúvel, o peptídeo exibe em solução um intrincado equilíbrio entre estados monoméricos, oligoméricos (alguns deles tidos como as espécies tóxicas) e fibrilares, o que impossibilita sua cristalização e posterior determinação estrutural por difração de raios-X. A espectroscopia de ressonância magnética nuclear (RMN) de alta pressão foi utilizada por nosso grupo para detectar estados monoméricos raros e de alta energia do Aβ(1-40), coexistindo em equilíbrio com oligômeros e fibras. Esse trabalho visa caracterizar a termodinâmica e a estrutura dos estados excitados raros do peptídeo Aβ através do uso da RMN de alta pressão. Uma grande coleção de espectros de RMN do peptídeo Aβ(1-40) em função da pressão foi coletada e analisada. Predições de estrutura secundária revelaram que o peptídeo Aβ adota estruturas estendidas do tipo fitas-β, similares àquelas encontradas em estruturas de fibras amiloides. A partir das curvas de deslocamento químico e volume de pico pela pressão, ao menos três estados monoméricos puderam ser detectados, os quais foram termodinamicamente caracterizados através do cálculo da variação das suas energias livres de Gibbs (ΔGij) e volumes parciais molares (ΔVij). O estudo de efeitos Overhauser nucleares (NOEs) e de acoplamentos 3JHα-HN de RMN reforçam a existência de estruturas estendidas com propensão a fitas-β, tanto a pressão ambiente (0,1 MPa) quanto em alta pressão (275 MPa). A interação entre o peptídeo Aβ e os D-peptídeos RD2 e RD2D3, inibidores D-enatioméricos de fibras, também foi caracterizada. Nossos resultados indicam que os D-peptídeos reconhecem e se ligam a uma conformação mais compacta de Aβ. A formação dos heterodímeros Aβ-D-peptídeo previne, por fim, a formação dos oligômeros tóxicos, representando uma potencial terapia contra a doença de Alzheimer. Adicionalmente, no segundo capítulo, apresentamos resultados sobre os coiled-coils (CC) das septinas humanas do grupo III (SEPT1, SEPT2, SEPT4 e SEPT5) também estudados por espectroscopia de RMN. Septinas são proteínas ligantes de GTP presentes na maioria dos organismos eucarióticos e capazes de formar filamentos, os quais são essenciais à divisão celular. Nesse estudo, utilizamos espectros 1H-1H-NOESY a fim de detectar a orientação e o pareamento de hélices adotados pelos coiled-coils em solução. A análise dos NOEs, auxiliada por espectros retrocalculados, mostrou que a única sequência a mostrar uma estrutura antiparalela foi SEPT2CC; todas as outras são paralelas. Entretanto, o desaparecimento de picos específicos no espectro de RMN de SEPT5CC causado pela presença de um marcador paramagnético de spin indica uma orientação antiparalela, contrário ao nosso outro resultado de RMN. Uma avaliação simples das posições heptaméricas dos coiled-coils, baseada na ocorrência de cada resíduo de aminoácido em ocupar cada posição, revelou que ambas as orientações são igualmente estáveis. Apesar de serem bem menos estáveis comparadas a outros coiled-coils, ambas poderiam existir fisiologicamente. Outros resultados do grupo também sugerem que esses peptídeos poderiam formar tanto coiled-coils paralelos quanto antiparalelos. Nós especulamos que a conformação antiparalela pode estar relacionada a ligações cruzadas entre filamentos.

Alzheimer's disease

Beta-amyloid peptide

Coiled-coil

Coiled-coil

Doença de Alzheimer

Nuclear magnetic resonance

Peptídeo beta-amiloide

Ressonância magnética nuclear

Septin

Septina

Estudos termodinâmicos e estruturais da interação cabeça-cauda da , alpha-tropomiosina muscular / Thermodynamic and structural studies of the head-to-tail complex of the muscular alpha-Tropomyosin

Fernando Corrêa

20 June 2008

Tropomiosina (Tm) é uma das proteínas que compõe o filamento fino (actina, Tm, Troponina) do sistema muscular esquelético e desempenha um importante papel na regulação da contração muscular. Tm é um coiled-coil de 284 resíduos que forma longos homopolímeros lineares através da sobreposição de onze resíduos entre os terminais de Tms adjacentes (Interação cabeça-cauda) em condições de baixa força iônica. A presença de vários resíduos carregados (D2, K5, K6, K7, D275, H276 e D280) nas extremidades da Tm sugere que contatos intermoleculares eletrostáticos entre estes aminoácidos podem ter um importante papel na estabilidade dos polímeros. Entretanto, a estrutura do complexo cabeça-cauda demonstra que a maioria dos contatos intermoleculares na interface é de natureza hidrofóbica. A fim de analisarmos a contribuição dos grupos carregados para a estabilidade do complexo cabeça-cauda, construímos fragmentos recombinantes correspondentes à metade amino (ASTm1-142 ) e carboxi (Tm143-284(5OHW269)) terminais da proteína contendo mutações pontuais daqueles resíduos para alanina, e adicionalmente H276 para Glu. Medimos a afinidade entre todas as possíveis combinações destes fragmentos na ausência e presença de íons Mg2+, visto que este cátion está sempre presente em condições fisiológicas e é importante para estabilizar a interação entre Tm e actina. Os efeitos das mutações foram analisados por simulações de docking, desnaturações térmicas e ciclos de duplos mutantes. Os resultados demonstram que os aminoácidos K5, K7 e D280 presentes na interface formam contatos intermoleculares essenciais para a estabilidade do complexo. Enquanto, D2, K6, D275 e H276 não participam na formação de contatos intermoleculares, no entanto, contribuem para a estabilidade da interação cabeça- cauda através de suas interações intramoleculares que atuam na estabilidade das hélices individuais. Os aumentos na estabilidade da metade C-terminal da Tm (Tm143-284(5OHW)) induzidos por Mg2+ foram dependentes das mutações neste trecho da proteína sugerindo a presença de um sítio de ligação para este íon na extremidade carboxi terminal da molécula no trecho que forma a interação cabeça- cauda. Construímos um fragmento menor do C-terminal (Tm259-284(W269)) para acompanharmos mudanças no deslocamento químico induzidas pela ligação do íon usando ressonância magnética nuclear. Os resultados obtidos comprovaram nossa hipótese e nos permitiram definir pela primeira vez que a estrutura da Tm tem um ou mais sítios de ligação Mg2+ em uma região próxima ao resíduo H276 que está localizado entre vários resíduos carregados negativamente que participam da interação cabeça-cauda. Por último, estudamos os efeitos de solventes cosmótropicos (TFE e glicerol) nas estabilidades dos fragmentos da Tm, uma vez que a instabilidade (flexibilidade) da extremidade C-terminal é importante para a formação do complexo cabeça-cauda. Observamos que TFE, porém não glicerol, reduziu a afinidade entre os terminais. Ambos os co-solventes induziram aumentos na estabilidade dos fragmentos, no entanto, apenas TFE induziu um aumento no conteúdo de α-hélice e causou uma redução significativa na cooperatividade de desenovelamento das proteínas. Estes resultados indicam que estes compostos orgânicos estabilizam as estruturas dos fragmentos individuais da Tm de maneiras diferentes e que estas diferenças podem estar relacionadas aos diferentes efeitos observados na formação da interação cabeça-cauda. / Tropomyosin (Tm) is a protein component of the skeletal muscle thin filament (actin, Tm, Troponin) which has an important role in the regulation of muscle contraction. Tm is a dimeric coiled-coil (284 aminoacids) which forms long linear homopolymers through the overlap of eleven residues of adjacent Tm termini (Head- to-tail interaction) in low ionic strength conditions. The presence of several charged amino acids (D2, K5, K6, K7, D275, H276 e D280) in Tm extremities suggests that electrostatic contacts among those residues may have an important role in the stability of the polymers. Nevertheless, the solution structure of the head-to-tail complex demonstrated that most of the contacts in the interface are hydrophobic. In order to study the contribution of these charged residues to the stability of the head- to-tail complex, we built recombinant fragments corresponding to the amino (ASTm1-142) and carboxy (Tm143-284(5OHW269)) termini containing single mutations of those amino acids to alanine, and additionally a substitution of H276 for Glu. We measured the binding affinities among all possible combinations of wild-type and mutant fragments in the absence or presence of Mg2+ ions. This cation is always physiologically present in the muscle and it is known to strengthen the binding of Tm to actin. The effects of the mutations were analyzed by protein-protein docking, thermodynamic cycles and thermal denaturations. The results show that residues K5, K7 and D280 are essential to the stability of the complex. Though D2, K6, D275 and H276 are exposed to the solvent and do not participate in intermolecular contacts in the NMR structure, they may contribute to the complex stability by modulating the stability of the helices at the Tm termini. Mg2+-induced increases in stability of the C- terminal were sensitive to mutations in residues located in the head-to-tail overlap region, suggesting that Mg2+ ions may bind specifically to the carboxy extremity of the protein. We produced a small peptide (Tm259-284(W269)) to follow amide chemical shift perturbations upon Mg2+ binding by nuclear magnetic resonance measurements. The results obtained with this peptide allowed us to define for the first time that the Tm structure has one or more Mg2+ binding sites in a region centered in the vicinity of H276 in which are located several negatively charged residues that participate in the head-to-tail interaction. We also studied the effects of kosmotropic co-solvents (TFE and glycerol) in the stability of Tm fragments, as the instability (flexibility) of the C- terminal region has been pointed as important for the formation of the head-to-tail complex. We observed that TFE, but not glycerol, reduces the affinity between the termini. Both TFE and glycerol increased the stability of the isolated N- and C- terminal fragments; however, only TFE caused an increase in the helical content and a significant reduction in the cooperativity of unfolding of the proteins. Our results show that these two co-solvents stabilize the structures of individual Tm fragments in different manners and that these differences may be related to their different effects on head-to-tail complex formation.

Ciclo de duplos mutantes

Coiled-coil

Docking

Interação cabeça-cauda

Proteínas

Ressonância magnética nuclear

Tropomiosina

Coiled-coil

Docking

Double mutant cycles

Head-to-tail interaction

Nuclear magnetic resonance

Tropomyosin