Greigite et magnétite : les déterminants environnementaux et génétiques contrôlant la biominéralisation chez les bactéries magnétotactiques / Greigite and magnetite : environmental and genetic determinants controlling biomineralization in magnetotactic bacteria

Descamps, Elodie

12 February 2018

Les bactéries magnétotactiques représentent un groupe d’une grande diversité écologique et phylogénétique. Elles sont capables de biominéraliser des nanocristaux de magnétite [un oxyde de fer (Fe(II)Fe(III)2O4)] ou de greigite [un sulfure de fer (Fe(II)Fe(III)2S4)] dans leurs magnétosomes, organites alignés en chaînes permettant la navigation le long des lignes de champ magnétique terrestre. Jusqu'à récemment, seules des souches produisant de la magnétite étaient disponibles en culture pure, conduisant à des études sur les mécanismes de biominéralisation de cet oxyde de fer. En 2011, une nouvelle bactérie capable de former de la magnétite et de la greigite, Desulfamplus magnetovallimortis souche BW-1, a été cultivée avec succès en laboratoire. Dans cette thèse, nous proposons d'utiliser une approche intégrée et multidisciplinaire pour comprendre les mécanismes de biominéralisation de la greigite en utilisant comme modèle d’étude la souche BW-1. Nous avons donc cherché à déterminer les conditions environnementales et biologiques favorisant la formation de la magnétite et de la greigite. Ces travaux ont également conduit à la caractérisation physiologique et phylogénétique de BW-1. Puis, l’utilisation d’approches globales et ciblées de transcriptomique ont permis d'évaluer le taux d'expression des gènes impliqués dans la formation des magnétosomes (magnétite vs. greigite) dans diverses conditions de croissance. Une approche de protéomique a permis d’apporter des informations supplémentaires à cette étude. Ces résultats ont permis de progresser dans la compréhension fondamentale de la biominéralisation in vivo, en particulier pour des bactéries formant de la greigite. / Magnetotactic bacteria represent a phylogenetically and ecologically diverse group of prokaryotes able to biomineralize magnetic nanocrystals composed of magnetite [an iron oxide (Fe(II)Fe(III)2O4)] or greigite [an iron sulfide (Fe(II)Fe(III)2S4)] in their magnetosomes, a prokaryotic organelle whose cytoplasmic alignement in chain allows the cell to navigate along the Earth’s magnetic field lines. Until recently, only magnetite-producing strains were available in pure culture. Thus, only the magnetite biomineralization has been studied. In 2011, a new bacterium able to form both magnetite and greigite, Desulfamplus magnetovallimortis strain BW-1, was isolated from Death Valley, California and cultivated in pure culture. In this work, we propose to use an integrated and multidisciplinary approach to understand the mechanisms involved in greigite biomineralization in BW-1 strain. First, we determined the environmental and biological conditions in which magnetite and greigite are formed. This first part of my thesis also contributed to the physiologic and phylogenetic characterization of this bacterium. Secondly, we used global and targeted transcriptomic approaches to evaluate the transcription levels of genes putatively involved in magnetosomes formation (magnetite vs. greigite) under various growth conditions. A proteomic approach provided additional informations to this study.Results obtained during my thesis contribute to the understanding of in vivo biomineralization, particularly for greigite production in magnetotactic bacteria.

Bactéries magnétotactiques

Biominéralisation

Greigite

Magnétite

Organite procaryote

Magnétosome

Magnétotaxie

Magnetotactic bacteria

Biomineralization

Greigite

Magnetite

Prokaryotic organelle

Magnetosome

Magnetotaxis

579

Further Structural Studies on Jacalin and Genomics Search for Mycobacterial and Archeal Lectins

Abhinav, K V

January 2016

This thesis consists of two parts. The first part is concerned with further structural and related studies of jacalin, one of the two lectins found in jack fruit seeds. The second part deals with the search of mycobacterial and archeal genomes for lectins. The β-prism I fold was identified as a lectin fold through the X-ray analysis of jacalin way back in 1996. Subsequent structural studies on jacalin are described in the first chapter in context of the overall efforts on lectins with particular reference to those on lectins with β-prism I fold. The structure of jacalin has been thoroughly characterized through the analysis of several crystals. The extended binding site of the lectin, made up of the primary binding site and secondary sites A and B, has also been characterized through studies on different jacalin-sugar complexes. However, nuances of jacalin-carbohydrate interactions remain underexplored with respect to two specific issues. The first issue is concerned with the structural basis for the lower affinity of jacalin for β-substituted sugars. The second has to do with the influence of the anomeric nature of the glycosidic linkage on the location of the reducing and non-reducing sugars in disaccharides when interacting with jacalin. Part of the work described in the thesis addresses these two issues. It was surmised that the lower affinity of β-galactosides to jacalin as compared to α-galactosides, is caused by steric interactions of the substituents in the former with the protein. This issue is explored both energetically and structurally in Chapter 2 using appropriately derivatized monosaccharide complexes of jacalin. It turns out that the earlier surmise is not correct. The interactions of the substituent with the binding site remain essentially the same irrespective of the anomeric nature of the substitution. This is achieved through a distortion of the sugar ring in β-galactosides. The difference in energy, and therefore affinity, is caused by the distortion of the sugar ring in β-galactosides. The elucidation of this unprecedented distortion of the ligand as a strategy for modulating affinity is of general interest. The crystal structures also provide a rationale for the relative affinities of the different carbohydrate ligands to jacalin. The crystal structures of jacalin complexed with α-linked oligosaccharides Gal α-(1,4) Gal and Gal α-(1,3) Gal β-(1,4) Gal, as described in Chapter 3, have been determined with the primary objective of exploring the effect of linkage on the location of reducing and non-reducing sugars in the extended binding site of the lectin, an issue which has not been studied thoroughly. Contrary to the earlier surmise based on simple steric considerations, the two structures demonstrate that α-linked sugars can bind to jacalin with non-reducing sugar at the primary binding site. This is made possible substantially on account of the hitherto underestimated plasticity of a non-polar region of the extended binding site. Modelling studies involving conformational search and energy minimization, along with available crystallographic and thermodynamic data, indicate a strong preference for complexation with Gal β-(1,3) Gal with the reducing Gal at the primary site, followed by that with Gal α-(1,3) Gal, with the reducing or non-reducing Gal located at the primary binding site. This observation is in consonance with the facility of jacalin to bind mucin type O-glycans containing T-antigen core. Crystal structures of jacalin in complex with GlcNAc β-(1,3) Gal-β-OMe and Gal β-(1,3) Gal-β-OMe have also been described in Chapter 4. The binding of the ligands to jacalin is similar to that of analogous α-substituted disaccharides. However, the β-substituted β-(1,3) linked disaccharides get distorted at the anomeric centre and the glycosidic linkage. The distortion results in higher internal energies of the ligands leading to lower affinity to the lectin. This confirms the possibility of using ligand distortion as a strategy for modulating binding affinity. Unlike in the case of β-substituted monosaccharides bound to jacalin, where a larger distortion at the anomeric centre was observed, smaller distortions are distributed among two centres in the structures of the two β-substituted β-(1,3) linked disaccharides presented here. These disaccharides, like the unsubstituted and α-substituted counterparts, bind jacalin with the reducing Gal at the primary binding site, indicating that the lower binding affinity of β-substituted disaccharides is not enough to overcome the intrinsic propensity of Gal β-(1,3) Gal based disaccharides to bind jacalin with the reducing sugar at the primary site. Although originally isolated from plants, lectins were also found subsequently in all forms of life, including bacteria. Studies on microbial lectins have not been as extensive as on those from plants and animals, although there have been some outstanding individual investigations on bacterial toxins like ADP-ribosylating toxins and neurotoxins. In addition to bacterial toxins, adhesins, β-trefoil lectins and cyanobacterial lectins form other important subgroups which have been explored using crystallography. Features pertaining to their three dimensional folds, carbohydrate specificity and biological properties are described in Chapter 5, to set the stage for the work discussed in the second part of the thesis. Studies on mycobacterial lectins were unexplored until work was initiated in the area in this laboratory some years ago. One of the lectins, identified on the basis of a bioinformatics search of M. tuberculosis H37Rv genome was cloned, expressed and crystallized. Also cloned, expressed and crystallized is another lectin from M. smegmatis. Biophysical and modelling studies were carried out on the full length protein containing this lectin. However, systematic efforts on mycobacterial lectins were conspicuous by their absence. The first chapter (Chapter 6) in the second part of the thesis is concerned with a genomic search for lectins in mycobacterial genomes. It was also realized that hardly anything is known about archeal lectins. Therefore, as discussed in the final chapter, a genomic search for archeal lectins was undertaken. Sixty-four sequences containing lectin domains with homologs of known three-dimensional structure were identified through a search of mycobacterial genomes and are described in detail in Chapter 6. They appear to belong to the β-prism II, the C-type, the Microcystis virdis (MV), and the β-trefoil lectin folds. The first three always occur in conjunction with the LysM, the PI-PLC, and the β-grasp domains, respectively while mycobacterial β-trefoil lectins are unaccompanied by any other domain. Thirty heparin binding hemagglutinins (HBHA), already annotated, have also been included in the study although they have no homologs of known three-dimensional structure. The biological role of HBHA has been well characterized. A comparison between the sequences of the lectin from pathogenic and non-pathogenic mycobacteria provides insights into the carbohydrate binding region of the molecule, but the structure of the molecule is yet to be determined. A reasonable picture of the structural features of other mycobacterial proteins containing one of the four lectin domains can be gleaned through the examination of homologous proteins, although the structure of none of them is available. Their biological role is yet to be elucidated. The work presented here is among the first steps towards exploring the almost unexplored area of the structural biology of mycobacterial lectins. As mentioned in Chapter 7, forty six lectin domains, which have homologues among well established eukaryotic and bacterial lectins of known three dimensional structure, have been identified through a search of 165 archeal genomes using a multi-pronged approach involving domain recognition, sequence search and analysis of binding sites. Twenty one of them have the 7-bladed β-propeller lectin fold while 16 have the β-trefoil fold and 7 the legume lectin fold. The remainder assumes the C-type lectin, the β-prism I and the tachylectin folds. Acceptable models for almost all of them could be generated using the appropriate lectins of known three dimensional structure as templates, with binding sites at one or more expected locations. The work represents the first comprehensive bioinformatics study of archeal lectins. The presence of lectins with the same fold in all domains of life indicates their ancient origin well before the divergence of the three branches. Further work is necessary to identify archeal lectins which have no homologues among eukaryotic and bacterial species.

Mycobacterial Lectins

Archeal Lectins

Jacalin

Prokaryotic Lectins

Bacterial Lectins

Jacalin-carbohydrate Interactions

Lectins

Molecular Biology

CRISPR RNA biogenesis by a Cas6 nuclease

Sokolowski, Richard D.

January 2015

Clustered regularly interspaced short palindromic repeats (CRISPRs) and associated (Cas) proteins form the basis of a prokaryotic adaptive immune system. Acquired sections of viral DNA are stored within the host genome as ‘spacers' flanked by ‘repeat' sequences. The CRISPR arrays are transcribed and processed to release mature CRISPR RNAs (crRNAs) – containing a single, intact spacer sequence – that are used by effector complexes to base-pair with matching hostile genetic elements and silence future infections. crRNA-biogenesis is thus an essential step within the defence pathway. Within Type I and III systems, the primary processing of the CRISPR transcript at repeat sites is performed almost exclusively by the CRISPR-specific riboendonuclease, Cas6. This thesis seeks to probe the catalytic mechanism of a Cas6 enzyme from the crenarchaeon Sulfolobus solfataricus (sso). Despite analogous generation of crRNA, ssoCas6 paralogues differ from previously characterised Cas6 examples in their lack of a canonical active site histidine residue. The work here builds on recent crystallographic evidence that the ssoCas6-1 paralogue unexpectedly adopts a dimeric conformation (PDB 3ZFV, 4ILR), to show that not only is the ssoCas6-1 dimer stable in solution but that this atypical arrangement is important to the activity of this particular enzyme. Furthermore, the ssoCas6-1 paralogue is shown to be the first in this family of endonucleases to employ multiple-turnover kinetics. The widespread diversity in Cas6 catalytic mechanisms reflects the plastic nature of the Cas6 active site and rapid co-evolution with substrate repeat sequences. The CRISPR/Cas environment within S. solfataricus is highly complex, containing three co-existing system types (Type I-A, III-A, III-B), five Cas6 paralogues and two families of CRISPR loci (AB and CD) that differ by repeat sequence. By probing the activity of an additional ssoCas6 paralogue (ssoCas6-3), which reveals different substrate specificities to those of ssoCas6-1, evidence emerges for functional coupling between ssoCas6 paralogues and downstream effector complexes, sufficient to regulate crRNA uptake and possibly even complex assembly.

570

Improving algorithms of gene prediction in prokaryotic genomes, metagenomes, and eukaryotic transcriptomes

Tang, Shiyuyun

27 May 2016

Next-generation sequencing has generated enormous amount of DNA and RNA sequences that potentially carry volumes of genetic information, e.g. protein-coding genes. The thesis is divided into three main parts describing i) GeneMarkS-2, ii) GeneMarkS-T, and iii) MetaGeneTack. In prokaryotic genomes, ab initio gene finders can predict genes with high accuracy. However, the error rate is not negligible and largely species-specific. Most errors in gene prediction are made in genes located in genomic regions with atypical GC composition, e.g. genes in pathogenicity islands. We describe a new algorithm GeneMarkS-2 that uses local GC-specific heuristic models for scoring individual ORFs in the first step of analysis. Predicted atypical genes are retained and serve as ‘external’ evidence in subsequent runs of self-training. GeneMarkS-2 also controls the quality of training process by effectively selecting optimal orders of the Markov chain models as well as duration parameters in the hidden semi-Markov model. GeneMarkS-2 has shown significantly improved accuracy compared with other state-of-the-art gene prediction tools. Massive parallel sequencing of RNA transcripts by the next generation technology (RNA-Seq) provides large amount of RNA reads that can be assembled to full transcriptome. We have developed a new tool, GeneMarkS-T, for ab initio identification of protein-coding regions in RNA transcripts. Unsupervised estimation of parameters of the algorithm makes unnecessary several steps in the conventional gene prediction protocols, most importantly the manually curated preparation of training sets. We have demonstrated that the GeneMarkS-T self-training is robust with respect to the presence of errors in assembled transcripts and the accuracy of GeneMarkS-T in identifying protein-coding regions and, particularly, in predicting gene starts compares favorably to other existing methods. Frameshift prediction (FS) is important for analysis and biological interpretation of metagenomic sequences. Reads in metagenomic samples are prone to sequencing errors. Insertion and deletion errors that change the coding frame impair the accurate identification of protein coding genes. Accurate frameshift prediction requires sufficient amount of data to estimate parameters of species-specific statistical models of protein-coding and non-coding regions. However, this data is not available; all we have is metagenomic sequences of unknown origin. The challenge of ab initio FS detection is, therefore, twofold: (i) to find a way to infer necessary model parameters and (ii) to identify positions of frameshifts (if any). We describe a new tool, MetaGeneTack, which uses a heuristic method to estimate parameters of sequence models used in the FS detection algorithm. It was shown on several test sets that the performance of MetaGeneTack FS detection is comparable or better than the one of earlier developed program FragGeneScan.

Gene prediction

Genome annotation

Prokaryotic genomes

Ribosomal binding site

Hidden Markov models

Adaptive training

Unsupervised self-training

Heuristic models

RNA-Seq

RNA transcripts

Frameshift prediction

Metagenomics

Microbial phenomics information extractor (MicroPIE): a natural language processing tool for the automated acquisition of prokaryotic phenotypic characters from text sources

Mao, Jin, Moore, Lisa R., Blank, Carrine E., Wu, Elvis Hsin-Hui, Ackerman, Marcia, Ranade, Sonali, Cui, Hong

13 December 2016

Background: The large-scale analysis of phenomic data (i.e., full phenotypic traits of an organism, such as shape, metabolic substrates, and growth conditions) in microbial bioinformatics has been hampered by the lack of tools to rapidly and accurately extract phenotypic data from existing legacy text in the field of microbiology. To quickly obtain knowledge on the distribution and evolution of microbial traits, an information extraction system needed to be developed to extract phenotypic characters from large numbers of taxonomic descriptions so they can be used as input to existing phylogenetic analysis software packages. Results: We report the development and evaluation of Microbial Phenomics Information Extractor (MicroPIE, version 0.1.0). MicroPIE is a natural language processing application that uses a robust supervised classification algorithm (Support Vector Machine) to identify characters from sentences in prokaryotic taxonomic descriptions, followed by a combination of algorithms applying linguistic rules with groups of known terms to extract characters as well as character states. The input to MicroPIE is a set of taxonomic descriptions (clean text). The output is a taxon-by-character matrix-with taxa in the rows and a set of 42 pre-defined characters (e.g., optimum growth temperature) in the columns. The performance of MicroPIE was evaluated against a gold standard matrix and another student-made matrix. Results show that, compared to the gold standard, MicroPIE extracted 21 characters (50%) with a Relaxed F1 score > 0.80 and 16 characters (38%) with Relaxed F1 scores ranging between 0.50 and 0.80. Inclusion of a character prediction component (SVM) improved the overall performance of MicroPIE, notably the precision. Evaluated against the same gold standard, MicroPIE performed significantly better than the undergraduate students. Conclusion: MicroPIE is a promising new tool for the rapid and efficient extraction of phenotypic character information from prokaryotic taxonomic descriptions. However, further development, including incorporation of ontologies, will be necessary to improve the performance of the extraction for some character types.

Information extraction

Phenotypic data extraction

Prokaryotic taxonomic descriptions

Microbial phenotypes

Character matrices

Support vector machine

Machine learning

Text mining

Algorithm evaluation

Natural language processing

Spatiotemporal dynamics of cytoskeletal and chemosensory proteins in the bacterium Rhodobacter sphaeroides

Chiu, Sheng-Wen

January 2014

The discovery of the prokaryotic cytoskeleton has revolutionized our thinking about spatial organisation in prokaryotes. However, the roles different bacterial cytoskeletal proteins play in the localisations of diverse biomolecules are controversial. Bacterial chemotaxis depends on signalling through large protein clusters and each cell must inherit a cluster on cytokinesis. In Escherichia coli the membrane chemosensory clusters are polar and new static clusters form at pre-cytokinetic sites, ensuring positioning at new poles after cytokinesis and suggesting a role for the bacterial FtsZ and MreB cytoskeletons. Rhodobacter sphaeroides has both polar, membrane-associated and cytoplasmic, chromosome-associated chemosensory clusters. This study sought to investigate the roles of FtsZ and MreB in the partitioning of the two chemosensory clusters in R. sphaeroides. The relative positioning between the two chemosensory systems, FtsZ and MreB in R. sphaeroides cells during the cell cycle was monitored using fluorescence microscopy. FtsZ forms polar spots after cytokinesis, which redistribute to the midcell forming nodes from which gradients of FtsZ extend circumferentially to form the Z-ring. The proposed node-precursor model might represent a common mechanism for the formation of cytokinetic rings. The MreB cytoskeleton continuously reorganizes between patchy and filamentous structures, and colocalises with FtsZ at midcell. Membrane chemosensory proteins form individual dynamic unit-clusters with mature clusters containing about 1000 CheW₃ proteins. These unit-clusters diffuse randomly within the membrane but have a higher propensity for curved regions like cell poles. Membrane clusters do not colocalise with FtsZ and MreB and appear excluded from the Z-ring vicinity. The bipolar localisation of membrane clusters is established after cell division via random diffusion and polar trapping of clusters. The cytoplasmic chemosensory clusters colocalise with FtsZ at midcell in new-born cells. Before cytokinesis one cluster moves to a daughter cell, followed by the second moving to the other cell. FtsZ and MreB do not participate in the positioning of cytoplasmic clusters. Therefore the two homologous chemosensory clusters use different mechanisms to ensure partitioning, and neither system utilizes FtsZ or MreB for positioning.

572

Oxidace ellipticinu lidskými cytochromy P450 exprimovanými v prokaryotním a eukaryotním systému / Oxidation of ellipticine by human cytochromes P450 expressed in prokaryotic and eukaryotic systems

Vejvodová, Lucie

January 2013

Ellipticine is an alkaloid with antitumor activity, whose mechanism of action is based on intercalation into DNA, inhibition of topoisomerase II and formation of covalent adducts with DNA, after its enzymatic activation by cytochromes P450 and/or peroxidases. Ellipticine is oxidized by cytochromes P450 to form up to five metabolites (7-hydroxy-, 9-hydroxy, 12- hydroxy-, 13-hydroxyellipticine and N2 -oxide ellipticine). 9-Hydroxy- and 7- hydroxyellipticine are considered to be detoxification metabolites, whereas 12-hydroxy-, 13- hydroxyellipticine and N2 -oxide of ellipticine are considered as activation metabolites, which are responsible for formation of covalent DNA adducts. The aim of this thesis was to examine the efficiency of human recombinant cytochromes P450 expressed in eukaryotic (SupersomesTM ) and two prokaryotic expression systems (Bactosomes) in oxidation of ellipticine. Cytochromes P450 expressed in prokaryotic systems differed in the amounts of "coexpressed" NADPH:CYP reductase. The resulting ellipticine metabolites were analyzed by HPLC. The results obtained in this thesis demonstrate that human cytochromes P450 2C9/2D6/2C19 expressed in prokaryotic or eukaryotic systems oxidize ellipticine to form up to four metabolites: 9-hydroxy-, 12-hydroxy-, 13-hydroxyellipticine and N2 -oxide...

Využití strukturní biologie ke studiu interakce protilátek a transkripčních faktorů s jejich ligandy / Understanding the interaction of antibodies and transcription factors with their ligands through structural biology

Škerlová, Jana

January 2015

Understanding protein function highly benefits from the knowledge of its three-dimensional structure, especially in the case of protein-ligand complexes. Structural biology methods such as X-ray crystallography, SAXS and NMR are therefore widely used for structural studies of protein-ligand interaction. In this work, these methods were used to understand two biological processes involving protein interactions: X-ray structural analysis was used to study binding of effector molecule to a prokaryotic transcription factor. NMR and SAXS techniques were used to study interaction of a monoclonal antibody with its protein antigen. Transcriptional regulator DeoR negatively regulates the expression of catabolic genes for the utilization of deoxyribonucleosides and deoxyribose in Bacillus subtilis. DeoR comprises an N-terminal DNA-binding domain and a C-terminal effector-binding domain (C-DeoR), and its function is regulated by binding of a small-molecular effector deoxyribose-5-phosphate. We determined crystal structures of C-DeoR both in the free form and in complex with deoxyribose-5-phosphate. Structural analysis revealed unique covalent binding of effector molecule through a reversible Schiff-base double bond with an effector-binding-site lysine residue. The physiological nature of this binding mode was...

Clonagem, expressão e caracterização do fator estimulador de colônia de granulócito humano recombinante (rhG-CSF) em Escherichia coli / Cloning, expression and characterization of the colonystimulating factor recombinant human granulocyte (rhG-CSF) in Escherichia coli

Carmo, Fillipe Luiz Rosa do

03 September 2014

O sistema de expressão em Escherichia coli foi o primeiro a ser utilizado para produzir produtos farmacêuticos recombinantes e tem muitas vantagens quando comparado com sistemas eucarióticos, como o fácil cultivo, baixo custo e alto potencial de produção. O fator estimulador de colônias de granulócito (G-CSF) atua principalmente promovendo a maturação dos neutrófilos e estimulando sua atividade fagocítica e quimiotática, além de estar envolvido com o processo de segmentação nuclear dessas células. O fator estimulador de colônias de granulócitos humano recombinante (rhG-CSF) tem sido produzido por engenharia genética em Escherichia coli, e é usado no tratamento de diversas patologias, sobretudo em neutropenias provocadas pela quimioterapia usada no tratamento de tumores, pela radioterapia e pelo uso de drogas que suprimem a produção de células mieloides. Desse modo, o presente estudo teve como objetivo a expressão da proteína rhGCSF em bactérias Escherichia coli. A clonagem do gene rhG-CSF no vetor de expressão pET-28a(+) foi realizada nos sítios de restrição das enzimas EcoRI e XhoI, e a expressão da proteína recombinante em cepas de bactéria Escherichia coli BL21DE3 foi obtida com sucesso. A proteína rhG-CSF, fundida à cauda de seis histidinas, foi purificada com êxito e identificada pelas técnicas de Western Blotting e por espectrometria de massas. São necessários estudos para avaliar a integridade estrutural e atividade biológica da proteína produzida, que se confirmada, possibilita que esta seja produzida em escala piloto. / The expression system in Escherichia coli was the first to be used to produce recombinant pharmaceuticals and has many advantages compared to eukaryotic systems, such as easy cultivation and high production potential at low costs. The granulocyte colony (G-CSF) stimulating factor acts primarily by promoting the maturation of neutrophils and stimulating their phagocytic and chemotactic activity. G-CSF is also involved with the process of neutrophils nuclear segmentation. The recombinant human granulocyte colonies stimulating factor (rhG-CSF) has been produced by genetic engineering in Escherichia coli, and it is used to treat of several conditions, especially neutropenia caused by chemotherapy used in the treatment of tumors, by radiotherapy and by the use of drugs that suppress the production of myeloid cells. The present study aimed the expression of rhG-CSF protein in Escherichia coli bacteria. The cloning of rhG-CSF gene in the expression vector pET- 28a (+) was carried out on the restriction sites of the EcoRI and XhoI enzymes. Expression of the recombinant protein in Escherichia coli BL21DE3 was successfully achieved. The rhG-CSF protein, fused with a six histidine tag, was obtained and successfully purified and identified by the Western Blotting and by mass spectrometry techniques. Studies are needed to assess the structural integrity and biological activity of the protein produced, which, if confirmed, enables the production on a pilot scale.

BL21DE3

BL21DE3

Expressão heteróloga

Filgrastima

G-CSF

G-CSF

Prokaryotic system

Proteína recombinante

Recombinant protein

rhG-CSF

rhG-CSF

Sistema procarioto

Structure function studies on lectin nucleotide phosphohydrolases (LNPs)

Chen, Chunhong

January 2008

Lectin nucleotide phosphohydrolases (LNPs) are proteins which possess both apyrase catalytic activity (E.C. 3.6.1.5) and specific carbohydrate binding properties, and these are linked. To investigate the structural and functional properties for these proteins, two putative soluble plant LNPs, 4WC and 7WC (from white clover), and a putative soluble plant apyrase 6RG (from ryegrass) were chosen. Rabbit polyclonal antibodies for each plant apyrase were generated using highly purified, overexpressed recombinant 4WC or 7WC. In the case of 6RG, the C-terminal half of the protein constituted the best antigen for generating polyclonal antibodies. These antibodies showed high specificity and sensitivity. Active, recombinant 4WC and 6RG were overexpressed and purified using the baculoviral insect cell expression system (4WCbac-sup and 6RG:Hisbac), while 7WC (7WCcoli) was produced from E. coli inclusion bodies and subsequently refolded to give active enzyme. In course of overexpression, recombinant 4WC was localised in both the cellular fraction (4WCbac) and in the media supernatant (4WCbac-sup), while recombinant 6RG:Hisbac was only found in the cellular fraction (6RG:Hisbac) indicating that it was not secreted during insect cell growth. Secretion of 4WCbac was found to be dependent on N-glycosylation at N313 but not at N85 and elimination of one or both of these sites appeared to have little influence on apyrase activity. In addition, both 4WCbac and 6RG:Hisbac from the cellular fraction were fully functional. These results were compared with similar work performed on the animal ecto-apyrases which have different specific N-glycosylation sites required for secretion and activity. The 4WCbac-sup, 7WCcoli and 6RG:Hisbac proteins all showed apyrase activity, that is they catalysed the hydrolysis of nucleotide tri- and/or di-phosphates to their corresponding nucleotide monophosphates, and released inorganic phosphate in a divalent cation-dependent manner. However, the proteins exhibited different activities, substrate specificities, pH profiles and influence of inhibitors: 4WCbac-sup had a preference for NDPs with a pH optimum ≥9.5; 7WCcoli had a modest preference for NTPs with a pH optimum at 8.5; 6RG:Hisbac was almost exclusively an NTPase with a pH optimum at 6.5. Contrary to predictions based on phylogeny the proteins all bound to sulphated disaccharides and their catalytic activities were influenced both positively and negatively by the binding of specific chitosans. The data indicates that all three soluble plant apyrases investigated here were LNPs, in contrast to predictions from the literature. In order to pinpoint the regions responsible for determining substrate specificity and chitosan binding, chimeras were made using the N- and C-terminal halves of 4WC and 6RG. This resulted in fully functional reciprocal chimeras. Comparison of the apyrase activity for parents and chimeras, substrate specificity, optimal pH, influence of inhibitors on activity and effects of chitosans indicated that the C-terminus was responsible for determining substrate specificity. However, the influence of specific chitosans on the chimeras appeared to be dependent on both the N- and C-terminal portions of the proteins. In addition, chimeras were found to bind to the same sulphated disaccharides as the parent proteins. Preliminary crystal screening experiments were performed with highly purified preparations of 7WCcoli and 6RG:Hisbac. Under specific conditions 7WCcoli was found to form cube-like crystalline arrangements while 6RG:Hisbac formed hexagonal-like crystalline structures. A potential model for carbohydrate binding by LNPs is proposed and the possible biological roles of plant LNPs are discussed.

Apyrase

lectin

chimeras

glycosylation