Estudo da interação entre domínios C-terminais de septinas humanas: implicação na formação e estabilidade do filamento / Study of Interaction between human C-terminal domains septins: implication for filament formation and stability

Fernanda Angélica Sala

10 April 2015

Septinas compreendem uma conservada família de proteínas de ligação a nucleotídeo de guanina e formação de heterofilamentos. Em termos estruturais, elas possuem uma organização comum: um domínio GTPase central, uma região N-terminal e um domínio C-terminal, este último é predito para formar estruturas em coiled coil. Atualmente, o heterocomplexo de septinas humanas (SEPT2/SEPT6/SEPT7) mais bem caracterizado revela a importância do domínio GTPase na formação do filamento, todavia a ausência de densidade eletrônica para os domínios C-terminais faz com que sua função permaneça obscura. Estudos com septinas de mamíferos, e de outros organismos como C. elegans e S. cerevisea sugerem que alguns grupos de septinas (por exemplo, II e IV em mamíferos) interagem através de seus domínios C-terminais, e estes poderiam atuar de modo determinante para a montagem correta do filamento. Assim, o presente projeto objetivou estudar a afinidade homo/heterotípicas para os domínios C-terminais das septinas humanas dos grupos II (SEPT6C/8C/10C/11C) e IV (SEPT7C), investigando se esses domínios contribuem para preferência das septinas interagirem com proteínas de grupos distintos durante a formação do heterofilamento. Os domínios C-terminais foram expressos em E. coli e purificados. Foram conduzidos estudos de ultracentrifugação analítica e espectropolarimetria de dicroísmo circular, que permitiram identificar maior afinidade e estabilidade da associação heterotípica comparada à homotípica. Foram obtidas constantes de dissociação aparente para homodímeros em torno de baixo µM, enquanto que para heterodímeros os dados já existentes no grupo revelaram constante de dissociação na ordem de nM. Para entender os fatores no nível atômico responsáveis pela significativa predileção na interação entre os domínios C-terminais dos grupos II e IV foram realizados estudos utilizando modelagem e análise das sequências primárias. As análises sugerem a presença de um alto número de resíduos carregados na posição a do coiled coil como responsável pela seletividade. Consequentemente, o heterodímero seria favorecido em virtude do menor efeito repulsivo proveniente do intercalamento dos resíduos carregados em a. Desse modo, os resultados indicaram a atuação decisiva ou cooperativa dos domínios C-terminais na organização preferencial das septinas durante a formação do filamento, favorecendo a interface NC entre septinas dos grupos II e IV. / Septins comprise a conserved protein family that binds guanidine nucleotide and forms heterofilaments. In structural terms they have a common organization: a central GTPase domain, a N-terminal domain and a C-terminal domain, this last one is predicted to form coiled coil structures. Currently, the human septin heterocomplex best characterized (SEPT2/SEPT6/SEPT7) reveals the importance of the GTPase domain in filament assembly, however the absence of electron density for the C-terminal domains makes its function still unknown. Studies with mammals septins, and of others organisms like C. elegans and S. cerevisea suggests that some septins groups (e.g. II e IV in mammals) interact via its C-terminal domains and this could act in a determinative way to correct filament assembly. In this way, this project aimed to study the homo/heterotypical affinity for the C-terminal domains of human septins belonging to groups II (SEPT6C/8C/10C/11C) e IV (SEPT7C), investigating whether this domain contributes with the preference of septins to interact with proteins of different groups during assembly of the heterofilament. The C-terminal domains were expressed in E. coli and purificated. It was carried out studies using analytical ultracentrifugation and circular dichroism spectropolarimetry tecniques which allowed identification of major affinity and stability in the heterotypical association compared to homotypical. It was measured apparent dissociation constants for homodimers of low µM range while for heterodimers our group\'s data shows dissociation constants in the nM range. To understand at atomic level the factors responsible for this significant preference in the C-terminal domains interaction between groups II and IV was performed molecular modelling studies and analysis of the primary sequence. These analysis suggests the presence of a high number of charged residues in position a of the coiled coil as responsible for selectivity. Consequently, the heterodimer would be therefore favoured because of the minor repulsive effect coming from the staggered of charged residues in a. Thus, these results indicate the crucial or cooperative action of C-terminal domains in preferential organization of septins during filament assembly, favouring the NC interface between septins of groups II and IV.

AUC

CD

Coiled coil

Homo e hetero-interação

Septinas

AUC

CD

Coiled coil

Homo and hetero-interaction

Septins

Die Bedeutung der Coiled-coil-Domäne für die Inaktivierung des Transkriptionsfaktors STAT1 / The role of the coiled-coil domain in inactivation of the transcriptionfactor STAT1

Petersen, Jana

26 May 2020

No description available.

610

STAT1

Coiled-coil-Domäne

STAT1

coiled-coil domain

GOK-MEDIZIN

Genetically Encoded Sensors for Detection of Proteases Utilizing Auto-Inhibited Coiled Coils and Split-Protein Reassembly

Shekhawat, Sujan Singh

January 2011

The detection of cellular events is central to understanding biomoleculer processes as well as aid in therapeutic intervention strategies. One of the most fascinating biomoleculer events during the life cycle of a cell is proteolytic cleavage of proteins by enzymes known as proteases. Proteases are ubiquitous and participate in essential functions such as fertilization, embryo development, cell cycle regulation, immune response, tissue remodeling and programmed cell death. As proteases are involved in fundamental cellular processes any dysregulation of protease activity is usually associated with a diseased state. Thus methods for detection of protease activity are desirable as it may facilitate the identification of many pathological conditions which are associated with the aberrant expression and activity of proteases.Towards the goal of a general and modular strategy we have utilized split protein reassembly and coiled coils to develop genetically encoded sensors for detection of proteases. We established our first generation protease design utilizing split firefly luciferase and anti-parallel coiled coils and detected Tobacco Etch Virus (TEV) as a model protease. Two further iterations of the coiled-coil design led to the development of second and third generation of protease sensors which showed substantial improvement in the sensor response and was applied towards detection of therapeutically relevant proteases such as caspase-3, prostate specific antigen (PSA), ß-secretase and calpain-1.We applied our methodolgy to develop protease biosensors for the detection of a family of cysteine protease known as caspases. Caspases are involved in programmed cell death and their misregulation is implicated in cancer as well as neurodegenerative disorders. The panel of caspase biosensors was utilized to investigate caspase cleavage specificity as well as caspase activation in mammalian cytosolic extracts and live mammalian cells. Perhaps more importantly, we discovered cross talk between members of the caspase family which perform different biological functions.Finally, we detail our progress towards mimicking a naturally occurring multicomponent complex formed during programmed cell death, known as the apoptosome which leads to the activation of caspases. We have successfully utilized principles of self assembly and multivalency to assemble multi component complexes which exhibit proteolytic activity similar to the natural apoptosome.

Protease

Split Protein Reassembly

Chemistry

Casapse

Coiled Coils

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.

Geometry Of Alpha And Beta Protein Structures

Shah, Aalok K.

January 2015

Proteins have a wide array of essential functions: from serving as enzymatic catalysts to protecting the immune system as antibodies. Proteins spontaneously self-organize into specific, folded structures determined by their amino acid sequences and the interaction between molecular forces. Since the 3-dimensional structure into which they fold often relates to the specific function of the protein, much effort has been directed towards methods to predict the folded structure from a given sequence, with the hope of being able to understand protein functions from sequence information. The protein folding problem can be summarized as the attempt to understand the relationship between a protein sequence and a protein's geometric shape, or fold. Thus, there are two principal problems: given a sequence, what 3-dimensional form will the protein take (forward problem), and given a particular fold, what sequence or sequences code for that form (the inverse problem). In this work, models that represent folds as continuous structures are explored. Models of the two prevalent motifs in protein folds, α helices and β barrels, are developed using axially deformed tubes and surfaces of revolution. These models are then analyzed and used to develop coordinate models of known and unknown structures.

coiled coils

continuous

geometry

proteins

Applied Mathematics

beta barrel

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).

Rational design of synthetic metalloproteins

Morozov, Vasily A.

30 May 2013

No description available.

Chemistry

Metalloprotein design

Coiled Coils

Metal clusters

Silver nanoclusters