Biophysical properties of the turnip yellow mosaic virus explored by coat protein mutagenesis

Powell, Joshua D.

05 April 2012

Plant viruses have been instrumental in our understanding of the biophysical properties pertaining to non-enveloped icosahedral virus particles. A substantial amount of research has been performed over five decades on Turnip yellow mosaic virus (TYMV), arguably one of the most extensively studied icosahedral plant viruses and the type-member of the Tymovirus plant virus genus. Even with a substantial body of published scientific literature, little is known about the role of specific coat protein (CP) residues in TYMV assembly, disassembly and disencapsidation. We have shown through our mutagenesis studies that the N-terminal region of the CP that is involved in the formation of an annulus structure and is disordered in A-subunit pentamers is not essential in vivo, but annulus-forming residues are critical in ensuring virion stability and low accessibility after virus is purified (Chapter 2). We have shown that a range of amino acid residue types is tolerated within the CP N-terminus in vivo, although they can greatly affect the stability of virions and empty particles, most notably at low pH (Chapter 3). Unlike full-length CP, N-terminal deletion and substitution mutants fail to reassemble into particles in vitro (Chapter 2, 3) suggesting a critical determinant for the N-terminus in reassembly (discussed Chapter 7). This is the first documented in vitro reassembly reported for a member of the Tymoviridae family and should provide a framework for further studies. We have identified a new way to create empty artificial top component (ATC)-particles through treatment with EDTA (Chapter 6) and we also show that tymoviruses can be engineered with altered pH-dependent enhanced stability (Chapter 4). In collaboration with the Qian Wang laboratory from the University of South Carolina we have shown that an RGD (Arg-Gly-Asp) motif can be genetically engineered within the CP of TYMV, resulting in infectious particles with attractive stem-cell adhesion properties (Chapter 5). With focus on basic viral mechanisms, we have crystallized the TYMV virion and ATC particle at pH 7.7 and collected data to less than 5 Å resolution (Chapter 4, supplementary). These structures represent the first tymovirus-based structures solved above pH 5.5 and will provide insight into the N-terminal conformations within the TYMV particle. Finally, we have characterized an N-terminal CP cleavage seen after ATC formation (Chapter 4) suggesting an additional and yet uncharacterized feature associated with decapsidation. / Graduation date: 2012

TYMV

plant virus

RGD arg-gly-asp

virus-like particle: VLP

Turnip yellow mosaic virus

Viruses -- Reproduction

Viral envelopes

Estudos estruturais e funcionais de proteinas da familia SBDS com enfase nas ortologas de Trypanosoma cruzi e humana / Strutural and functional analysis of the SBDS protein family

Oliveira, Juliana Ferreira de

14 August 2018

Orientadores: Ana Carolina de Mattos Zeri, Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-14T05:56:20Z (GMT). No. of bitstreams: 1 Oliveira_JulianaFerreirade_D.pdf: 4266971 bytes, checksum: b6c93b83027283390194f44df501c5b2 (MD5) Previous issue date: 2009 / Resumo: Proteínas da família SBOS (Shwachman-Bodian-Diamond Syndrome) ocorrem largamente na natureza e s.ão bastante conservadas, apresentando ortólogas em Archaea e eucariotos. Estudos de análises genômica e biofísica tem relacionado a SBOS com o metabolismo de RNA e biosíntese de ribossomos. O gene ortólogo da SBOS de Archaea está localizado em um operon conservado que contém genes do processamento de RNA; estudos de perfil de expressão gênica tem agrupado o gene da proteína SBOS de Saccharomyces cerevisiae, Sdo1p, com fatores do processamento de rRNA e estudos de análise proteômica identificaram a interação da proteína Sdo1p com fatores da biossíntese de ribossomos; ortólogas de planta contém um C-terminal estendido apresentando motivo de ligação a RNA. Mutações identificadas no gene SBDS tem sido relacionadas com a síndrome Shwachman-Oiamond (80S), uma doença caracterizada por insuficiência exócrina pancreática e disfunção na medula óssea, cujos pacientes apresentam grandes chances de desenvolver leucemia. SOS representa, portanto, um importante modelo para entender os processos envolvidos no desenvolvimento da leucemia. O objetivo principal desse trabalho consistiu na caracterização estrutural e funcional de proteínas da família SBOS. Foram realizados ensaios de cristalização com ortólogas ; da SBOS de Archaea, levedura, tripanossoma e humana. A SBOS de Pyrococcus abyssi foi cristalizada, porém os cristais difrataram a baixa resolução (3,50 A). A ' caracterização da SBOS ortóloga de Trypanosoma cruzi (TcSBOS) mostrou que esta, proteína contém uma região C-terminal estendida. Ensaios de proteólise limitada,' dicroismo circular e espectroscopia por Ressonância Magnética Nuclear (RMN) indicaram que a região adicional da TcSBOS se comporta como um fragmento de proteína intrinsicamente desenovelado, responsável pela interação da TcSBOS com RNA, verificada por ensaios de Electrophoretic Mobility Shift Assay (EMSA). Também foi realizada a determinação da estrutura da ortóloga humana (HsSBOS) em solução por espectroscopia de RMN. A proteína HsSBOS é composta de três domínios bem estruturados, apresentando mobilidade conformacional entre os domínios N-terminal e central. Experimentos de titulação de RNA, novamente utilizando-se RMN, possibilitaram a confirmação da interação direta da SBOS humana com RNA. A região de ligação ao RNA foi identificada no N-terminal da proteína, região bastante conservada na família e considerada o principal alvo das mutações relacionadas à doença SDS / Abstract: The Shwachman-Bodian-Oiamond syndrome (SBOS) protein family occurs widely in nature and is highly conserved, with orthologues in Archaea and eukaryotes. Genomic and biophysical studies have suggested involvement of this protein in RNA metabolism and in ribosome biogenesis. Archaeal SBOS orthologue genes are located within highly conserved operons that include RNA-processing genes; transcriptional profiling analysis has clustered the yeast ortholog protein Sdo 1 p with rRNA processing factors and proteomic analysis have identified potential interactions between Sd01 p and ribosome biogenesis factors; several plant SBOS orthologues contain extended C-terminal region with putative RNA binding motif. Mutations in the SBDS gene are associated to the Shwachman-Oiamond syndrome (SOS), arare multisystem disorder characterized by exocrine pancreatic insufficiency, bone marrow dysfunction, and an increased risk of acute myeloid leukemia. SOS therefore represents an extremely useful model for understanding leukaemogenesis. The objective of the present work was the structural and functional characterization of the SBOS protein family. SBOS orthologues from Archaea, yeast, trypanosomatid and human were assayed for crystallization. The Archaeal SBOS orthologue, PaUPF0023 in Pyrococcus abyssi, was crystallized, but the crystals 'diffracted to a relatively low resolution (3.50 A). Characterization of the Trypanosoma cruzi SBOS ortholog (TcSBOS) by using limited proteolysis, circular dichroism and NMR analyses indicated that the C-terminal additional region of TcSBOS behaves as a natively unfolded protein segment, responsible for TcSBOS-RNA interaction activity in electrophoretic mobility shift assays. We have also determined the solution structure and backbone dynamics of the human SBOS protein using NMR spectroscopy. The overall structure of human SBOS comprises three well-folded domains with conformational exchange in the linker between the N-terminal and the central domains. RNA titration experiments using NMR spectroscopy provide evidence that human SBOS interacts with RNA via the N-terminal domain, a conserved region in the SBOS family and the most frequent target for SOSassociated mutations / Doutorado / Bioquimica / Doutor em Biologia Funcional e Molecular

Proteina SBDS

Ribossomos - Biossíntese

Trypanosoma cruzi

Ressonância magnética nuclear

Proteinas - Estrutura

SBDS protein

Ribosomes - Biosynthesis

Trypanosoma cruzi

Nuclear magnetic resonance

Proteins - Structure

Estudo funcional e estrutural de Nip7p, uma proteina conservada envolvida na sintese de ribossomos / Functional and structural analysis of Nip7p, a conserved protein involved in ribosome biogenesis

Coltri, Patricia Pereira

12 October 2007

Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-09T15:29:14Z (GMT). No. of bitstreams: 1 Coltri_PatriciaPereira_D.pdf: 4564852 bytes, checksum: f11b831da981a8969c20f8f03ae8c617 (MD5) Previous issue date: 2007 / Resumo: A síntese de ribossomos é um processo conservado em eucariotos e se inicia com a transcrição dos rRNAs no nucléolo. Mais de 170 fatores atuam de forma transitória no processamento dos precursores para gerar os rRNAs maduros que formarão as subunidades ribossomais no citoplasma. Entre as proteínas envolvidas na síntese de ribossomos está a Nip7p, uma proteína nucleolar de 21 kDa associada ao complexo pré-60S em Saccharomyces cerevisiae. Nip7p é conservada e possui ortólogas em eucariotos e em Archaea. A análise da seqüência primária revela a presença de um domínio conservado na região C-terminal, denominado PUA, encontrado em diversas proteínas associadas a modificações no RNA. Neste trabalho, foram realizadas análises estruturais e funcionais com o objetivo de investigar a função molecular da proteína Nip7 no processamento e modificação do rRNA. A estrutura tri-dimensional de PaNip7, ortóloga de Nip7p em Pyrococcus abyssi foi resolvida por difração de raios-X até 1,8Å de resolução, utilizando o método SIRAS. Comparação estrutural seguida por ensaios in vitro confirmaram o envolvimento do domínio PUA na interação com RNA. Além disso, tanto Nip7p como suas ortólogas PaNip7 e HsNip7 interagem com seqüências ricas em uridina, indicando que atuam de forma semelhante no processamento do rRNA. Essa preferência por uridina pode ainda explicar a afinidade da proteína Nip7p de S. cerevisiae pelo RNA da região ITS2, conforme observado em ensaios de interação utilizando UV-crosslinking. De fato, uma análise funcional realizada por primer extension comprovou que ocorre um bloqueio no processamento da região espaçadora ITS2 na ausência de Nip7p. Nip7p interage com várias proteínas do complexo pré-60S, entre as quais Nop8p e Nop53p, ambas associadas ao processamento do pré-27S. Embora os ensaios de co-purificação tenham confirmado a interação com as proteínas do complexo H/ACA box, deficiência em Nip7p não afeta a pseudo-uridinilação do rRNA. O duplo-híbrido realizado com a ortóloga humana de Nip7p, HsNip7, revelou interações com FTSJ3 e com a proteína SUMO-2. A interação direta de HsNip7 com estas proteínas foi confirmada por ensaios in vitro. HsNip7 e FTSJ3 colocalizaram na região nucleolar de células HEK293. FTSJ3 é uma proteína não caracterizada que possui o domínio FtsJ, descrito inicialmente para rRNA metiltransferases de procariotos. Além disso, FTSJ3 apresenta similaridade de sequência à proteína Spb1p de levedura, cuja função na metilação do rRNA 25S na posição Gm2922 já foi estabelecida. Embora a Nip7p não interaja com a Spb1p, estes dados indicam que FTSJ3 deve ser a ortóloga humana da Spb1p. As proteínas SUMO estão envolvidas na modificação pós-traducional (sumoylation) que regula a localização subcelular de proteínas. Em levedura, a provável ortóloga de SUMO, Smt3p, foi descrita na partícula pré-60S, portanto a interação HsNip7-SUMO-2 pode ser específica. Estes dados sugerem que as proteínas atuem no mesmo complexo da formação da subunidade 60S também em células humanas / Abstract: Ribosome biogenesis is conserved throughout eukaryotes and takes place in the nucleolus, a specialized nuclear compartment where the rRNA precursors are transcribed. More than 170 trans-acting factors coordinately interact to generate the mature rRNAs. Among the proteins identified in the pre-60S particle in Saccharomyces cerevisiae is Nip7p. Highly conserved Nip7p orthologues are found in all eukaryotes and Archaea. The analysis of Nip7p sequence reveals a conserved C-terminal domain named PUA, also found in a number of RNA-interacting proteins. In this work, we performed structural and functional analysis to investigate Nip7p molecular role on rRNA processing and modification. The structure of Pyrococcus abyssi Nip7p ortholog, PaNip7, was solved using X-ray diffraction data to 1,8Å resolution. Structural analysis followed by in vitro assays confirmed the involvement of PUA domain in RNA interaction. S. cerevisiae Nip7p and its archaeal and human counterparts show preference for binding uridine-rich sequences, indicating conserved functional features among the orthologues. The preference for uridine can explain the higher affinity of S. cerevisiae Nip7p for ITS2 sequence, as observed by UV-crosslinking assays. Consistently, functional analysis revealed pre-rRNA processing in the ITS2 region is seriously impaired. Yeast two-hybrid analysis confirmed by pull down assays revealed Nip7p interacts with Nop8p and Nop53p, two nucleolar proteins involved in pre-27S processing and components of pre-60S particle. Although yeast two-hybrid and pull down assays indicated that Nip7p interacts with H/ACA box core proteins, pseudouridylation is not affected under conditions of Nip7p depletion. In addition, yeast two-hybrid analysis confirmed by GST-pull down revealed HsNip7 interaction with FTSJ3 and SUMO-2. Both HsNip7 and FTSJ3 showed nucleolar subcellular localization in HEK293 cells. FTSJ3 is an uncharacterized protein containing the FtsJ domain, initially described in prokaryotic rRNA methyl-transferases. FTSJ3 shows sequence similarity to yeast Spb1p, an rRNA methyl-transferase involved in methylation of Gm2922, indicating that FTSJ3 may be the human orthologue of Spb1p. Sumoylation is a post-transcriptional covalent modification involved in regulation of protein subcellular localization. Putative yeast orthologues of SUMO, such as Smt3p, have been described in the pre-60S ribosomal particle, suggesting that SUMO-2 might play a specific role in 60S subunit biogenesis / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular

Ribossomos

RNA ribossomico

Proteínas - Síntese

Proteinas - Estrutura

Técnicas do sistema de duplo-híbrido

Ribosomes

RNA, Ribosomal

Proteins - Synthesis

Proteins - Structure

Yeast two-hybrid system

Structure Determination of Proteins of Unknown Origin by a Marathon MR Protocol and Investigations on Parameters Important for Molecular Replacement Structure Solution

Hatti, Kaushik S

January 2016

Occasionally, crystallisation of proteins works in mysterious ways! One might obtain crystals of a protein of unknown identity in place of the protein for which crystallisation experiments were performed. If the investigator is not aware of such possibilities, valuable time and resources might be lost in attempting to determine the structure of such proteins. Instances of non-target protein getting crystallised may not come to light at all or may be realised only when attempts to determine the structure completely fail by conventional procedures after collecting and processing the diffraction data. Usually, it is not possible to reproduce the crystals of the same protein as their occurrence is serendipitous. Such rare instances of crystallisation are probably caused by fluctuating environmental or crystallisation conditions and are not reproducible. It could also be due to contaminating microbes, which is more likely when the experimentalist is not well experienced. Therefore, experimental phasing of the data collected on serendipitously obtained crystals could be a challenging task. With the rapid increase in the number of structures deposited in the protein data bank (PDB), molecular replacement has become the method of choice for structure determination in macromolecular X-ray crystallography. This is due to the fact that it is possible to select a suitable phasing model for most target proteins based on their sequence information. However, if the identity of the target protein itself is uncertain, all attempts of structure determination using phasing models selected on the basis of target protein sequence-dependent search would fail. Sequence-independent ab initio phasing techniques such as ARCIMBOLDO (Meindl et al., 2012), which has recently become available, could provide leads only if the non-target protein is an all-α-protein and the associated diffraction data extends to a resolution better than 2 Å. Even then, the success rate with this technique is low. Hence, it becomes important to employ a sequence-independent method of structure determination for such mysteriously obtained crystals. This thesis reports crystal structures of proteins which are serendipitously crystallised using a large-scale application of Molecular Replacement (MR) technique (referred in this thesis as MarathonMR). This thesis also presents an evaluation of molecular replacement strategies for structure determination. The thesis begins with an overview of crystallographic methods of structure determination with an emphasis on the method of molecular replacement (Chapter 1). The most prominent of the results obtained in the course of these investigations pertains to a crystal obtained during routine crystallisation of a viral protein mutant in the year 2011. The cell parameters were different from cell constants of crystals obtained with other known viral protein mutants crystallised earlier in the same laboratory. Unfortunately, this crystal could not be reproduced in the same form in subsequent crystallisation trials. All attempts to determine the structure through conventional molecular replacement techniques using a combination of domains from a nearly identical virus coat protein protomer as the phasing model had failed. The data was shelved as “not-solvable” in late 2011. However, the crystal had diffracted to 1.9 Å and had excellent merging statistics. Therefore, the data was retrieved recently and additional attempts were made to determine the structure through phasing techniques that have become available recently. Techniques such as AMPLE (Bibby et al., 2013) and Rosetta (DiMaio, 2013), which use large-scale homology models coupled with molecular replacement, did not lead to meaningful solutions. A couple of helices identified by ARCIMBOLDO (Meindl et al., 2012) were neither correct (retrospectively) nor sufficient to determine the entire structure. Given the excellent merging statistics of the crystal data, there was significant motivation to determine the structure, though it meant developing a fresh protocol. It was at this time that we came across the work of Stokes-Rees and Sliz (2010) in which they had demonstrated that it is possible to determine structure of proteins of unknown identity by employing almost every known protein structure as a potential phasing model. The work reported in the thesis is a result of an earlier project to examine the relationship between properties of phasing models and the quality of target protein model generated through MR by employing large scale molecular replacement runs. This project was initiated because of the realisation that the recent explosion in crystallographic structural studies has resulted in near complete exploration of the “fold-space” of proteins and PDB now has a representative structure for most plausible folds of proteins. Some folds are highly represented in the PDB. Hence, it is likely that there would be at least one homologue in the PDB which could be used as a phasing model to successfully determine the structure of a protein of unknown identity if the diffraction dataset is of excellent quality. Hence, the single dataset which had diffracted to 1.9 Å resolution was used to develop a MarathonMR procedure for structure determination. MarathonMR procedure takes sequence-independent approach to structure determination and employs large-scale molecular replacement calculations to identify the closest homologue (in structural terms initially). This protocol is described in Chapter 2 (Materials and methods) of the thesis. Through MarathonMR, structure of the dataset which had remained unsolved for 5 years was finally determined. Nearly complete sequence of the polypeptide could be deduced by inspecting the electron density map due to the high resolution and quality of the map. The protein was found to be a phosphate binding protein from a soil bacterium Stenotrophomonas maltophilia (SmPBP). The way in which the structure was determined and possible explanations for the mysterious source of this protein which had crystallised instead of the target protein is discussed in Chapter 3. Though MarathonMR procedure was developed to solve a single dataset, it was soon realised that the same procedure could be applied to other similar datasets, all of which had diffracted to reasonable resolutions with good merging statistics but had remained unsolved for unknown reasons. Among such datasets, one of the datasets which was collected in 2007 and had diffracted to 2.3 Å resolution had cell parameters very close to that of SmPBP. Hence, a poly-alanine model of the structure of SmPBP, which was determined by then, was used as the phasing model to run molecular replacement and the structure was readily solved. It was surprising to note that SmPBP had crystallised serendipitously not once but twice, once in 2011 resulting in crystals that diffracted to 1.9 Å resolution and earlier in 2007 in crystals that diffracted to 2.3 Å resolution independently by two different investigators in the same laboratory. Both the structures are nearly identical and a comparison of these structures is presented in Chapter 4. Structure of SmPBP determined at 2.3 Å resolution by MarathonMR also corresponds to the dataset that had remained unsolved for the longest period of time (9 years). This success of structure determination after the lapse of such a long period emphasises the importance of carefully preserving X-ray diffraction data irrespective of its immediate outcome. In Chapter 5 of the thesis, another instance of non-target protein crystallisation, the structure of which was determined using the MarathonMR procedure is described. The crystal was obtained while carrying out crystallisation of mutants of a survival protein (SurE) expressed in Salmonella typhimurium when the bacterium is subjected to environmental or internal stresses. The original investigator had used the structure of SurE as the phasing model to determine structure of the mutant crystals and obtained a model with R and Rfree of 35% and 40%, respectively. However, the model did not refine further to lower R-factors suggesting that the solution obtained may not be correct. MarathonMR indicated that the fold of the crystallised protein could be similar to that of glycerol dehydrogenase. As SurE shares some fold similarity with one of the domains of GlyDH, the original investigator might have been able to achieve a limited success with R/Rfree factors of 35% and 40%, respectively. As the merging statistics for this diffraction data set was poor, the diffraction images were reprocessed in XDS program on Xia2 automated spot processing pipeline. The data statistics indicated merohedral twinning (14%). However, using appropriate parameters, it was possible to refine the structure obtained by MarathonMR to acceptable R/Rfree using the Refmac program. Four protomers were present in the crystal asymmetric unit (ASU). Non-crytsallographic symmetry averaging of electron density over these four molecules further improved the electron density. As the data was limited to 2.7 Å resolution, it was not possible to deduce the identity of every residue of the protein unambiguously based solely on the resulting electron density map. With the identity of the amino acids that could be deduced with certainty, it was clear that the protein belongs to glycerol dehydrogenase from a species of Enterobacteriacea family. Though a similar structure of glycerol dehydrogenase has been reported from Serratia, there are clear differences in many unambiguously determined residues which suggest that the protein is not from Serriatia. The protein has been named EnteroGlyDH as the source of the protein is likely to be from a species of Enterobacteriacea family. The structure of the protein, its biochemical implications and possible reasons for the serendipitous crystallisation of a non-target are discussed. Chapter 6 discusses the structure determination of an inorganic pyrophosphatase and catalytic domain of Succinyl transferase, the crystals of which had diffracted to 2.3 Å and 3.1 Å, respectively, but had remained unsolved. Neither of the datasets corresponds to the intended target proteins. The dataset corresponding to the protein whose structure was determined as that of an inorganic pyrophosphatase was provided by a colleague from a different laboratory in the Indian Institute of Science. It is interesting to note that the investigator had carried this dataset to one of the CCP4 workshops and had tried to determine the structure with the help of experts in the workshop. The attempts to determine its structure had however failed for reasons that are obvious now. The original investigator was unfortunately making efforts with an erroneous assumption on the identity of the target protein. As these enzymes are well studied, their structures and functions are briefly discussed. It is already well established that molecular replacement is being used with increasing frequency as the phasing technique when compared to other experimental phasing techniques. With the ever growing number of structures in the PDB, high population of certain folds and a near-plateau attained in the identification and growth of new folds, it is reasonable to expect that molecular replacement will be used even more frequently in the years to come. Therefore, for carrying out molecular replacement for a given diffraction dataset of a target protein, it is very likely that several homologous structures would be available in the PDB that could be used as potential phasing models. Hence, it becomes important to understand the influence of phasing model on the quality and accuracy of model generated through MR to achieve the best structure solution. To understand this relationship between phasing model and model obtained by MR protocol, re-determination of already known structures deposited in the PDB starting with their respective structure factors and various phasing models was initiated. Structures belonging to TIM beta/alpha-barrel (SCOPe ID: c.1) and Lysozyme-like (SCOPe ID: d.2) folds were chosen as targets. The structure of each target was re-determined serially starting with poly-alanine models of all available unique homologues as phasing models. Due to the multi-dimensional nature of this study, the results obtained were represented in a graphical form with nodes and edges. Detailed methodology of the work carried out and the data representation model are discussed in the Chapter 2 (Materials and methods). It was found that after a certain sequence identity cut-off, sequence identity between phasing model and target seems to have little influence on the quality and accuracy of the model generated through MR. Instead, other qualities of the phasing model such as Rfree and RSCC influence the quality of MR models. These results are discussed in Chapter 7. Learning from the work reported in this thesis are discussed in concluding chapter. The possible logical and programmatic upgrades to MarathonMR protocol and future path in which the relationship between phasing models and models generated through MR can be studied are discussed in Chapter 8 (Conclusion and future prospects).

Proteins Structure Determination

Crystal Systems

Protein Crystallisation

Molecular Replacement (MR)

Crystallisation

Marathon MR Procedure

Crystal Structures of Proteins

Crystallisation of Proteins

Molecular Biophysics

Binding sites in protein structures: characterisation and relation with destabilising regions

Dessailly, Benoît

20 September 2007

An increasing number of proteins with unknown function have their three-dimensional structure solved at high resolution. This situation, largely due to structural genomics initiatives, has been stimulating the development of automated structure-based function prediction methods. Knowledge of residues important for function – and more particularly – for binding can help automated prediction of function in different ways. The properties of a binding site such as its shape or amino acid composition can provide clues on the ligand that may bind to it. Also, having information on functionally important regions in similar proteins can refine the process of annotation transfer between homologues.<p>Experimental results indicate that functional residues often have an unfavourable contribution to the stability of the folded state of a protein. This observation is the underlying principle of several computational methods for predicting the location of functional sites in protein structures. These methods search protein structures for destabilising residues, with the assumption that these are likely to be important for function.<p>We have developed a method to detect clusters of destabilising residues which are in close spatial proximity within a protein structure. Individual residue contributions to protein stability are evaluated using detailed atomic models and an energy function based on fundamental physico-chemical principles.<p>Our overall aim in this work was to evaluate the overlap between these clusters of destabilising residues and known binding sites in proteins.<p>Unfortunately, reliable benchmark datasets of known binding sites in proteins are sorely lacking. Therefore, we have undertaken a comprehensive approach to define binding sites unambiguously from structural data. We have rigorously identified seven issues which should be considered when constructing datasets of binding sites to validate prediction methods, and we present the construction of two new datasets in which these problems are handled. In this regard, our work constitute a major improvement over previous studies in the field.<p>Our first dataset consists of 70 proteins with binding sites for diverse types of ligands (e.g. nucleic acids, metal ions) and was constructed using all available data, including literature curation. The second dataset contains 192 proteins with binding sites for small ligands and polysaccharides, does not require literature curation, and can therefore be automatically updated.<p>We have used our dataset of 70 proteins to evaluate the overlap between destabilising regions and binding sites (the second dataset of 192 proteins was not used for that evaluation as it constitutes a later improvement). The overlap is on average limited but significantly larger than random. The extent of the overlap varies with the type of bound ligand. Significant overlap is obtained for most polysaccharide- and small ligand-binding sites, whereas no overlap is observed for nucleic acid-binding sites. These differences are rationalised in terms of the geometry and energetics of the binding sites.<p>Although destabilising regions, as detected in this work, can in general not be used to predict all types of binding sites in protein structures, they can provide useful information, particularly on the location of binding sites for polysaccharides and small ligands.<p>In addition, our datasets of binding sites in proteins should help other researchers to derive and validate new function prediction methods. We also hope that the criteria which we use to define binding sites may be useful in setting future standards in other analyses. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Biologie

Protein binding

Molecular biology -- Data processing

Proteins -- Structure

Protéines -- Fixation

Biologie moléculaire -- Informatique

Protéines -- Structure

protein structure

bioinformatics

protein

ligand

binding site

molecular biology

Identification des protéines FBP1 et FBP2 comme partenaires des protéines de liaison aux éléments riches en adénine et uridine (ARE) TIA-1 et TIAR

Rothé, Françoise

27 January 2006

Dans les cellules eucaryotes, l’expression d’un gène peut être régulée à de nombreux niveaux. Les études réalisées sur le contrôle de l’expression génique se sont généralement intéressées aux mécanismes de contrôle transcriptionnel. Cependant de nombreux exemples mettent de plus en plus en évidence l’importance des mécanismes post-transcriptionnels dans cette régulation. Les contrôles post-transcriptionnels de l’expression génique reposent essentiellement sur des interactions spécifiques entre les régions 5’ et 3’ non traduites de l’ARNm et des protéines agissant en trans qui contrôlent spécifiquement la maturation des ARNs messagers (ARNms), leur localisation cytoplasmique, leur stabilité et/ou leur traduction. Les éléments riches en adénine et en uridine (ARE), localisés dans la région 3’ non traduite de nombreux ARNms, font partie des séquences régulatrices les plus étudiées. Elles sont notamment présentes dans les ARNms codant pour des cytokines et des proto-oncogènes. Les protéines de liaison à l’ARN jouent donc un rôle central dans la régulation de l’expression des gènes. Les protéines TIA-1 et TIAR appartiennent à la famille des protéines qui fixent l’ARN et qui contiennent des domaines RRM (RNA Recognition Motif). Elles sont impliquées dans des mécanismes permettant la régulation de l’expression génique tels que l’épissage alternatif et la traduction. En particulier, elles participent à l’arrêt général de la traduction qui accompagne un stress environnemental en séquestrant les ARNms poly(A)+ non traduits dans des foci cytoplasmiques appelés granules de stress (SGs). Elles sont également impliquées dans la répression traductionnelle d’ARNms spécifiques en liant les ARE présents dans les extrémités 3’ non traduites de certains ARNms, et notamment des ARNs messagers codant pour le TNF-α et la cyclooxygénase-2 (Cox-2). L’invalidation des gènes tia-1 et tiar chez la souris conduit à une létalité embryonnaire élevée suggérant que ces protéines jouent également un rôle important au cours de l’embryogenèse. Afin de comprendre les mécanismes par lesquels les protéines TIA-1 et TIAR remplissent leurs différentes fonctions, nous avons réalisé un criblage par la technique du double hybride en levure afin d'identifier des partenaires d’interaction de ces deux protéines. Les protéines TIA-1 et TIAR interagissent avec les protéines FBPs (Fuse Binding Proteins). Celles-ci participent notamment à la maturation et à la dégradation des ARNs. Nous avons montré que les protéines FBPs co-localisent parfaitement avec TIA-1 dans le noyau et migrent dans les granules de stress en réponse à un stress oxydatif. De plus, des expériences de retard de migration sur gel réalisées à partir d’extrait cytosolique de macrophages ont montré que les protéines FBPs sont présentes dans le même complexe liant l’ARE du TNF-α que TIA-1. Enfin, la surexpression du domaine de liaison à l’ARN KH3 de FBP2 en fusion à l’EGFP induit la séquestration spécifique des protéines TIA-1 et TIAR dans des foci cytoplasmiques, empêchant ainsi leur accumulation nucléaire. Nos résultats indiquent que les protéines TIA-1/R et FBPs pourraient être fonctionnellement impliquées dans des étapes communes du métabolisme de l’ARN dans le noyau et/ou le cytoplasme. / Doctorat en sciences, Spécialisation biologie moléculaire / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Biologie

Proteins -- Structure

RNA

Genetic transcription -- Regulation

Protéines -- Structure

ARN

Transcription génétique -- Régulation

ARE

domaine RRM

ARN-BP

régulations post-transcriptionnelles

Structure et interactions de la lysyl oxydase et de fragments de la matrice extracellulaire / Structure and interactions of lysyl oxidase and extracellular matrix fragments

Vallet, Sylvain D.

14 December 2018

La matrice extracellulaire est un réseau tridimensionnel complexe qui joue le rôle de support aux cellules ainsi que de réservoir de molécules bioactives régulant le comportement cellulaire. Elle est composée de 1027 protéines chez l’Homme (Naba et al., Matrix Biol. 2016), 274 protéines constituant le matrisome et 753 associées (facteurs de croissance et protéines régulatrices de la matrice extracellulaire) et de 6 glycosaminoglycanes dont 5 sulfatés. La matrice extracellulaire est impliquée dans de nombreuses pathologies (Bonnans et al., Nat. Rev. Mol. Cell Biol. 2014). La lysyl oxydase, responsable de la réticulation des collagènes et de l’élastine est impliquée dans de nombreux cancers. La matrice extracellulaire est un réservoir de fragments bioactifs, nommés matricryptines, qui sont libérés par protéolyse des biomolécules de la matrice et régulent de nombreux processus biologiques tels que l’angiogenèse et l’adipogenèse (Ricard-Blum et Vallet Matrix Biol. 2017). Nous avons exprimé en cellules humaines plusieurs matricryptines dont les ectodomaines des collagènes membranaires XIII, XVII, XXIII et XXV et identifié leurs partenaires extracellulaires. Nous avons caractérisé le propeptide de la lysyl oxydase par SEC-MALS, diffusion dynamique de la lumière et par SAXS et avons modélisé à partir des données de SAXS sa structure tridimensionnelle. Nous avons identifié 17 nouveaux partenaires de ce fragment et analysé le mutant Arg158Gln dépourvu d’activité biologique. Cette mutation identifiée chez l’Homme inhibe les activités anti-prolifératives du propeptide et est associée à un risque accru de cancer du sein (Min et al., Cancer Res. 2009). Nous avons exprimé la lysyl oxydase mature et modélisé sa structure tridimensionnelle en utilisant toutes les données disponibles. Les interactions identifiées au cours de ce travail ont été associées à celles obtenues par curation manuelle de la littérature pour construire la première version de l’interactome extracellulaire humain / The extracellular matrix is an intricate tridimensional network supporting cells and a bioactive molecule reservoir involved in the regulation of cell behavior. It is composed of 1027 proteins in humans (Naba et al., Matrix Biol. 2016), including 274 of the core matrisome and 753 associated proteins (growth factors and extracellular matrix regulators) and 6 glycosaminoglycans including 5 sulfated. The extracellular matrix is altered in numerous pathologies (Bonnans et al., Nat. Rev. Mol. Cell Biol. 2014). The lysyl oxidase is responsible for the cross-linking of collagens and elastin and is involved in many cancers. The extracellular matrix is a reservoir of bioactive fragments named matricryptins which are released by proteolysis of extracellular matrix proteins and regulate numerous biological processes like angiogenesis and adipogenesis (Ricard-Blum et Vallet, Matrix Biol. 2017). We have expressed under a recombinant form in human cells some matricryptins including the ectodomains of the membrane collagens XIII, XVII, XXIII and XXV and have identified their extracellular partners. We have characterized the propeptide of lysyl oxidase by SEC-MALS, dynamic light scattering, and SAXS and have built a coarse-grained 3D model by SAXS-derived constraints. We have identified 17 new partners of this fragment and analyzed the mutant Arg158Gln which has no biological activity. This mutation has been identified in humans and inhibits the propeptide anti-proliferative properties. It is associated to an increased risk of breast cancer (Min et al., Cancer Res. 2009). We have expressed the mature lysyl oxidase and modelled its tridimensional structure using available data. All the interactions identified in this study were associated to manually curated interactions described in the literature to build the first version of the human extracellular interactions network

Lysyl oxydase

Matricryptines

Modélisation

Réseaux d’interactions

SAXS

Structure des protéines

Extracellular matrix

Glycosaminoglycans

Interaction networks

Lysyl oxidase

Matricryptins

Modeling

Proteins structure

SAXS

572

Computational Simulations of Cancer and Disease-Related Enzymatic Systems Using Molecular Dynamics and Combined Quantum Methods

Walker, Alice Rachel

05 1900

This work discusses applications of computational simulations to enzymatic systems with a particular focus on the effects of various small perturbations on cancer and disease-related systems. First, we cover the development of carbohydrate-based PET imaging ligands for Galectin-3, which is a protein overexpressed in pancreatic cancer tumors. We uncover several structural features for the ligands that can be used to improve their binding and efficacy. Second, we discuss the AlkB family of enzymes. AlkB is the E. coli DNA repair protein for alkylation damage, and has human homologues with slightly different functions and substrates. Each has a conserved active site with a catalytic iron and a coordinating His...His...Asp triad. We have applied molecular dynamics (MD) to investigate the effect of a novel single nucleotide polymorphism for AlkBH7, which is correlated with prostate cancer and has an unknown function. We show that the mutation leads to active site distortion, which has been confirmed by experiments. Thirdly, we investigate the unfolding of hen egg white lysozyme in 90% ethanol solution and low pH, to show the initial steps of unfolding from a native-like state to the disease-associated beta-sheet structure. We compare to mass spectrometry experiments and also show differing pathways based on protonation state. Finally, we discuss three different DNA polymerase systems. DNA polymerases are the primary proteins that replicate DNA during cell division, and have various extra or specific functions. We look at a proofreading-deficient DNA polymerase III mutant, the effects of solvent on DNA polymerase IV's ability to bypass bulky DNA adducts, and a variety of mutations on DNA polymerase kappa.

molecular dynamics

theoretical chemistry

biochemistry

computational chemistry

enzymes

AlkB

AlkBH7

HEWL

DNA polymerase

Cancer -- Computer simulation.

Diseases -- Computer simulation.

Proteins -- Structure.

Enzymes.

Molecular dynamics.

Bases moleculares do efeito do pH na atividas catalítica de duas lisozimas digestivas de Musca domestica (Diptera) / Molecular basis of the pH effect on the catalytic activity of two digestive lysozymes from Musca domestica (Diptera)

Cançado, Fabiane Chaves

16 December 2008

Lisozimas são enzimas que fazem parte do mecanismo de defesa contra bactérias, no entanto lisozimas com função digestiva também são encontradas no trato digestivo de vertebrados e no intestino médio de insetos. As lisozimas digestivas de insetos são do tipo c e assim compartilham semelhanças estruturais e mecanísticas com a lisozima da clara de ovo de galinha (HEWL). Entretanto, para desempenhar sua função digestiva, as lisozimas de insetos apresentam algumas propriedades particulares entre as quais se destaca um pH ótimo mais ácido em relação às lisozimas não-digestivas. Para elucidar as bases moleculares dessa diferença no pH ótimo, duas lisozimas digestivas (lisozima 1 AAQ20048 e lisozima 2 AAQ20047) da larva de Musca domestica (mosca Diptera Cyclorrhapha), clonadas em Pichia pastoris e purificadas, foram caracterizadas estruturalmente e cineticamente com o substrato sintético (MUQ3) e natural (cápsulas de Micrococcus lysodeikticus). Foi observado que o efeito do pH na atividade das lisozimas 1 e 2 sobre o MUQ3 é uma curva com formato de sino e pH ótimo mais ácido que o da HEWL. Essas curvas foram reflexos da diminuição simultânea dos valores de pKas do nucleófilo e do doador de prótons. Estruturas cristalográficas das lisozimas digestivas de Musca domestica foram obtidas a 1,9 Å e análise comparativa com a estrutura terciária da HEWL revelou resíduos de aminoácidos no ambiente do nucleófilo (N46) e do doador de prótons (S106 e T107) que podem estar envolvidos na modulação das constantes de ionização dos resíduos essenciais à catálise. Esses resíduos foram substituídos via mutagênese sítio-dirigida por D, V e A respectivamente e três mutantes simples (N46D, S106V e T107A) e um triplo (N46DS106V- T107A) foram produzidos e purificados. Caracterização revelou que as contribuições individuais da N46, S106 e T107 foram pequenas e próximas do limite de detecção da técnica utilizada. Por outro lado, o conjunto dos 3 aminoácidos foi responsável pelo pH ótimo ácido frente ao substrato sintético, elevando os valores de pKas do nucleófilo e doador de prótons para valores muito semelhantes ao da HEWL. Diferentemente, essa tripla mutação não foi suficiente para elevar o pH ótimo da lisozima 2 sobre cápsulas de Micrococcus lysodeikticus para valores próximos àqueles de HEWL, sugerindo que as bases moleculares do pH ótimo frente ao substrato natural e sintético são diferentes. Uma comparação estrutural entre lisozima 1 e HEWL sugere que os resíduos de aminoácidos carregados na superfície dessas lisozimas sejam importantes para determinação do pH ótimo. A investigação dessa hipótese foi feita substituindo 5 aminoácidos neutros e 1 ácido, via mutagênese sítio-dirigida, por resíduos básicos. A caracterização do mutante sêxtuplo revelou um aumento significativo nos valores de pH ótimo da lisozima 1, indicando que a redução da basicidade da superfície das lisozimas digestivas é determinante para seus pHs ótimos ácidos. / Lysozymes are enzymes that are part of the defence mechanism against bacteria, however lysozymes with digestive function are also found in the digestive tract of vertebrates and in the insect midgut. The digestive lysozymes from insects are c type, so they share similar structural and mechanistic characteristics with hen egg-white lysozyme (HEWL). However, to perform their digestive function, insect lysozymes present some particular properties among them a more acidic pH optimum than that of non-digestive lysozymes. To elucidate the molecular basis of this pH optimum difference, two digestive lysozymes (lysozyme 1 AAQ20048 and lysozyme 2 AAQ20047) from Musca domestica larvae (housefly Diptera Cyclorrhapha), cloned in Pichia pastoris and purified, were structurally and kinecticly characterized with synthetic (MUQ3) and natural (lyophilized cells of Micrococcus lysodeikticus) substrates. It was observed that the pH effect on the activity of lysozymes 1 and 2 upon MUQ3 is a bell shaped curve exhibiting a more acidic pH optimum than that of HEWL. These curves result from simultaneous decrease of pKas values of the nucleophile and proton donor. Crystallographic structures of these digestive lysozymes from Musca domestica were obtained at 1.9 Å and comparative analysis with the terciary structure of HEWL revealed amino acid residues in the catalytic nucleophile (N46) and proton donor environment (S106 and T107) that may be involved in the modulation of ionization constants of those catalytic residues. N46, S106, and T107 were replaced via site-directed mutagenesis by D, V and A respectively and three simple (N46D, S106V and T107A) and one triple (N46D-S106V-T107A) mutants were produced and purified. Their characterization revealed that the individual contributions of N46, S106 and T107 were small and close to the detection borderline of the technique utilized. On the other hand, a set of these 3 amino acids was responsible by acidic pH optimum upon synthetic substrate, increasing the pKas values of nucleophile and proton donor to similar values to that of the HEWL. Differently, this triple mutation was not enough to increase the pH optimum of lysozyme 2 upon lyophilized cells of Micrococcus lysodeikticus to values close to those of HEWL, suggesting that the molecular bases of pH optimum upon natural and synthetic substrates are different. A structural comparison between lysozyme 1 and HEWL suggests that the charged amino acid residues on the surface of these lysozymes are important for pH optimum determination. The investigation of this hypothesis was done replacing 5 neutral and 1 acidic amino acids, via site-directed mutagenesis, by basic residues. The characterization of this mutant revealed a significant increase in the pH optimum values of lysozyme 1, suggesting that the reduction of basicity on the surface of the digestive lysozymes is a important factor in the determination of their acidic pH optimum.

Biologia molecular

Digestão animal

Digestive lysozyme

Insects (Enzymology; Study)

Insetos (Enzimologia; Estudo)

Lisozima

Lisozima digestiva

Lysozyme

Molecular biology

Musca domestica

Musca domestica

pH optimum

pH ótimo

Proteínas (Estrutura)

Proteins (Structure)

Estudo estrutural e funcional das proteínas PilZ e YaeQ do fitopatógeno Xanthomonas axonopodis pv citri / Structural and functional studies of PilZ and YaeQ from Xanthomonas axonopodis pv citri proteins

Guzzo, Cristiane Rodrigues

25 February 2010

O trabalho aqui desenvolvido teve como objeto o estudo estrutural e funcional de várias proteínas do fitopatógeno Xanthomonas axonopodis pv citri (Xac), dentre as quais se destacam as proteínas hipotéticas conservadas YaeQ e SufE, as proteínas RpfC, RpfF e RpfG envolvidas em quorum sensing e proteínas PilZ, FimX e PilB envolvidas na biogênese do pilus tipo IV. Para o desenvolvimento deste trabalho foram utilizadas diferentes técnicas incluindo: clonagem, expressão, purificação, desnaturação térmica, cristalografia, difração de raios-X, RMN, ensaios de 2-híbrido, produção de nocautes, mutação sítio dirigida, Western- e Far- Western, entre outras. Dentre os resultados mais importantes obtidos temos a determinação estrutural das proteínas YaeQ e PilZ pela técnica MAD. Em ambos os casos, as estruturas representaram topologias inéditas. Com base nos dados estruturais, mostramos que YaeQ pertence à família PD-(D/E)XK presente em endonucleases dependentes de magnésio, e a partir de ensaios funcionais obtivemos evidências que sugerem que YaeQ está envolvida em alguma via de reparo de DNA em Xac. A estrutura tridimensional de PilZ revelou uma inesperada variedade estrutural dentro da família PilZ e mostrou de forma clara porque ortólogos não interagem com o segundo mensageiro bacteriano, c-diGMP. A cadeia principal de PilZ foi assinalada por RMN e a estrutura secundária de PilZ em solução é consistente com aquela determinada por cristalografia. Duas proteínas que interagem com PilZ foram identificadas: PilB e FimX. Como PilZ, ambos exercem papéis na biogênese do pilus tipo IV (T4P). Mostramos que PilZ interage especificamente com o domínio EAL de FimX e que resíduos conservados na região do C-terminal de PilZ estão envolvidos na interação com PilB, mas não com FimX. Ensaios de mutação sítio dirigida mostraram que a Y22 de PilZ pode estar envolvida na regulação da interação de PilZ com FimX e com PilB. Apesar de PilZ não interagir com c-diGMP seu parceiro, FimX, interage. PilZ consegue interagir com PilB ao mesmo tempo em que interage com FimX, formando um complexo ternário que é independente da interação de FimX com c-diGMP. Com base em todos estes resultados propusemos possíveis mecanismos de ação de PilZ e FimX no controle da biogênese do T4P. Além dos resultados acima descritos, determinamos a estrutura de SufE e mostramos que esta aumenta a atividade cisteína dessulfarase de seu parceiro, SufS, em torno de 10 vezes, como ocorre com SufE-SufS de E.coli. Clonamos, expressamos, purificamos e fizemos ensaios de cristalização de algumas proteínas envolvidas no controle de quorum sensing em Xac. Tivemos êxito na cristalização do domínio HPT (histidina fosfotransferase) da proteína chave deste sistema, RpfC / The aim of the project was to perform structural and functional studies of different Xanthomonas axonopodis pv citri (Xac) proteins including the hypothetical proteins YaeQ and SufE; RpfC, RpfF and RpfG involved in the quorum sensing and PilZ, FimX and PilB that play roles in type IV pilus (T4P) biogenesis. Several experimental techniques were employed including cloning, expression and purification of recombinant proteins, thermal denaturation, protein crystallography, X-ray diffraction, NMR, two-hybrid assays, Western- and Far-Western Blotting assays, site direct mutagenesis, and the production of Xac knockouts strains. The most important results include the determination of the three-dimensional crystal structures of PilZ and YaeQ using the MAD technique. In both cases, the structures reveled new protein topologies. The comparison of the YaeQ structure with others deposited in public databases revealed that YaeQ proteins represent a new variation within the PD-(D/E)XK magnesium dependent endonucleases superfamily. Functional assays suggest that YaeQ may be envolved in DNA repair in Xac. The PilZ three-dimensional structure revealed an unexpected structural variation within the PilZ domain superfamily and showed why PilZ orthologs are not able to bind the important bacterial second messenger, c-diGMP. We assigned the PilZ main chain by NMR and used this information to demonstrate that the PilZ secondary structure in solution is consistent with the PilZ crystal structure. We identified two proteins that interact with PilZ: PilB and FimX. As with PilZ, both PilB and FimX are involved in T4P biogenesis. PilZ binds specifically to the EAL domain of FimX and the conserved residues located in the PilZ unstructured C-terminal region contribute to binding with PilB but not with FimX. Site direct mutagenesis studies showed that PilZ residue Y22 is necessary for its capability to interact with both PilB and FimX. Although PilZ does not bind c-diGMP, her partner, FimX, does. We present evidence that PilZ can bind simultaneously to FimX and PilB, forming a ternary complex that is independent of c-diGMP. These results allow us to propose possible mechanisms by which PilZ and FimX control T4P biogenesis. Other results obtained during this period include the resolution of the crystal structure of the SufE protein from Xac using the molecular replacement technique. We show that SufE induces a 10-fold increase in the cysteine desulfurase activity of SufS, similar to that observed for the SufE-SufS complex from E. coli. Several proteins involved in quorum sensing and c-di-GMP signaling were cloned, expressed and submitted to crystallization trials. Crystals of the HPT (histidine phophotransferase) domain) of the RpfC sensor histidine kinase were obtained

Difração de raios-X

Pilus tipo IV)

PilZ

PilZ

Quorum sensing

Quorum sensing

SufE

SufE

Type IV pilus

X-ray diffraction

YaeQ

YaeQ