Expressão e caracterização de proteínas envolvidas na via da quinase mTOR e na divisão celular bacteriana / Expression and characterization of proteins involved in the mTOR kinase pathway and bacterial cell division

Nogueira, Maria Luiza Caldas, 1984-

21 August 2018

Orientador: Ana Carolina de Mattos Zeri / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-21T00:57:37Z (GMT). No. of bitstreams: 1 Nogueira_MariaLuizaCaldas_M.pdf: 8261820 bytes, checksum: 7c9ed2193fd77623b3a8beea794eb743 (MD5) Previous issue date: 2012 / Resumo: A mTOR é uma via de sinalização muito conservada que controla o crescimento celular em resposta à presença de nutrientes e fatores de crescimento. A desregulação dessa via em humanos está relacionada a doenças como câncer e diabetes. A quinase TOR é ativada na presença de aminoácidos e recentemente descobriu-se que as pequenas GTPases da família Rag são mediadoras da sinalização por Leucina. Essas GTPases são ancoradas na superfície do lisossomo por meio da interação com um complexo de três proteínas denominado Ragulator. Esse complexo também ancora um braço da via das MAPKs (MEK-ERK) aos lisossomos. O entendimento deste complexo pode nos ajudar a elucidar doenças em que a via da mTOR se encontra desregulada. Neste trabalho obtivemos o complexo Ragulator, através da expressão da proteína p18 em corpos de inclusão e sua renaturação através da adição de suas parceiras Mp1/p14 à diálise. Foram realizados estudos biofísicos com a intenção de caracterização do complexo, entretanto o alto grau de dissociação do mesmo resultou em certa dificuldade para caracterizá-lo completamente. Neste trabalho caracterizamos os agregados formados pela p18 e conseguimos reduzir sua formação através de diálise contendo agente redutor e suas proteínas parceiras. A renaturação da p18 na presença de MP1/p14 favoreceu seu rendimento, indicando a interação entre estas proteínas, porém não foi possível estabilizar o complexo Ragulator O estudo da divisão bacteriana é centralmente dependente de FtsZ, um homólogo procariótico das tubulinas. FtsZ desencadeia a divisão ao formar o "anel Z", uma estrutura supramolecular constituída por polímeros de FtsZ que circunda o interior da célula e funciona como arcabouço do aparato de divisão. A formação do anel Z é regulada por moduladores, proteínas que afetam tanto negativamente como positivamente a capacidade de FtsZ polimerizar-se. A proteína MinC é um inibidor da polimerização de FtsZ, recrutada por MinD para a face interna da membrana plasmática, onde o complexo MinCD exerce sua função. MinCD representa um inibidor sítio-específico da polimerização da FtsZ, previnindo a formação do anel Z nos pólos das células mas permitindo que isto aconteça na região central. A elucidação deste processo seria de grande valia para o desenho racional de inibidores da divisão bacteriana. Neste trabalho, comprovamos a interação entre MinC e FtsZ por Ressonância Magnética Nuclear. Estes proteínas não se encontravam em sua forma monomérica e o alto peso molecular do complexo impossibilitou a identificação dos aminoácidos envolvidos nesta interação, devido a limites da técnica 15NHSQC. No momento, a proteína MinC está sendo expressa em presença de deutério, o que aumenta significativamente o limite da técnica de 15NHSQC. Foram realizados ainda estudos biofísicos com intuito de caracterização da interação / Abstract: The mTOR signaling pathway is a very well conserved pathway that controls cell growth in response to the presence of nutrients and growth factors. Deregulation of this pathway in humans is related to diseases like cancer and diabetes. The TOR kinase is activated in the presence of amino acids and it was recently discovered that the Rag small GTPases family are mediators of signaling by Leucine. These GTPases are anchored on the surface of the lysosome through interactions with a complex of three proteins called Ragulator. This complex also anchors an arm of the pathway of MAPKs (MEK-ERK) to lysosomes. Understanding this can help us to elucidate complex diseases in which the mTOR pathway is upregulated. In this work, the Ragulator complex was obtained through the expression of p18 protein in inclusion bodies and their refolding by adding their partners MP1/p14 to dialysis. Biophysical studies were conducted with the intention of characterizing the complex, however its high degree of dissociation resulted in some difficulty to characterize it completely. In this work we characterized the aggregates formed by p18 and managed reduce its formation by dialysis containing reducing agent and its partner proteins. The p18 renatuation with MP1/p14 improve its yield, indicating interaction among these proteins, however the Ragulator complex wasn't stabilized. The study of bacterial division is centrally dependent on FtsZ, a prokaryotic homologue of tubulin. FtsZ triggers the division to form the "Z ring", a supramolecular structure consisting in FtsZ polymers that surrounds the cell and acts as a frame of the division apparatus. The formation of the Z ring is regulated by modulators, proteins that affect both negatively and positively the ability of FtsZ to polymerize. The MinC protein is an inhibitor of FtsZ polymerization, recruits MinD to the inner surface of the plasma membrane, where the complex MinCD exerts its function. MinCD is an inhibitor of site-specific polymerization of FtsZ, preventing the formation of the Z ring at the poles of the cells but allowing this to happen in the central region. The elucidation of this process would be invaluable for the rational design of bacterial division inhibitors. In this work, we confirmed the interaction between MinC and FtsZ by Nuclear Magnetic Resonance. These proteins were not in their monomeric form and the high molecular weight of the complex prevented the identification of the amino acids involved in this interaction, due to limitations of the 15NHSQC technology. At present, the MinC protein is being expressed in the presence of deuterium, which significantly increases the limit of this technique 15NHSQC. Biophysical studies were also performed with the aim of characterizing the interaction / Mestrado / Bioquimica / Mestre em Biologia Funcional e Molecular

Redobramento de proteína

Mapeamento de interação de proteínas

Proteínas FtsZ

Proteínas MinC

Complexo Ragulator

Protein refolding

FtsZ proteins

MinC proteins

Ragulator complex

Protein interacion mapping

Estudo genético da interação entre FtsZ e o modulador de divisão ZapA em Bacillus subtilis / Genetic Study of the interaction between FtsZ and the division modulator ZapA in Bacillus subtilis

Alexandre Wilson Bisson Filho

01 April 2009

A citocinese bacteriana é controlada por diversas proteínas que se agrupam em um complexo chamado divisomo. O cerne do divisomo é constituído por FtsZ, uma proteína homóloga à tubulina eucariótica, que se auto-associa formando uma estrutura chamada anel Z. O anel Z serve como arcabouço e recruta diversas outras proteínas componentes do divisomo para o sítio onde o septo será sintetizado na célula. A formação do anel Z é modulada por proteínas que se ligam diretamente a FtsZ e regulam a sua auto-associação, tanto induzindo como inibindo a sua polimerização. Apesar de muitos destes moduladores de FtsZ já serem conhecidos, muito pouco se sabe sobre o mecanismo pelo qual eles controlam a estruturação do anel Z in vivo. O objetivo do presente trabalho foi estudar a interação entre FtsZ e um modulador de divisão, a proteína ZapA, da bactéria gram-positiva Bacillus subtilis. Para isso construímos uma biblioteca de mutantes de ftsZ por \"Error Prone PCR\", com aproximadamente 1 substituição por cópia de ftsZ e contendo um total de 1x105 clones. A partir dessa biblioteca, utilizamos duas triagens genéticas para identificar mutantes incapazes de interagir com ZapA. Na primeira estratégia, selecionamos 12 mutantes de FtsZ resistentes à superexpressão de uma forma tóxica de ZapA, que bloqueia a divisão, causando filamentação e morte das células. Surpreendentemente, apesar destes mutantes serem insensíveis ao efeito de ZapA, ensaios citológicos mostraram que nenhum deles perdeu a interação com ZapA. Como as mutações foram mapeadas nas vizinhanças do sítio catalítico e de polimerização de FtsZ, e como a maioria delas confere resistência cruzada aos efeitos de outros moduladores de FtsZ, suspeitamos que elas afetassem a estabilidade do polímero de FtsZ e, consequentemente, o comportamento do anel Z. Essas suspeitas foram confirmadas em ensaios de FRAP e cálculos de proporção de FtsZ no anel Z, indicando que os mutantes formam um anel Z mais estável que o normal. Como não obtivemos mutantes que perderam a interação com ZapA na primeira triagem, aplicamos a biblioteca em uma segunda estratégia de triagem genética, procurando um mutante de FtsZ que voltasse a interagir com um mutante de ZapA que não se liga mais a FtsZ (ZapAN62A). Esta estratégia de ganho de função identificou um candidato, FtsZE91V , que, tanto por critérios genéticos como citológicos, voltou a interagir com ZapAN62A. Apesar do mutante FtsZE91V mostrar-se capaz de restaurar a interação com ZapAN62A, ele não afetou a interação com ZapA selvagem, segundo nossos ensaios de microscopia de fluorescência e viabilidade. O mutante FtsZE91V, mapeia na hélice H3 de FtsZ. Esta hélice está exposta na superfície de FtsZ (compõe um dos lados da molécula de FtsZ) de uma maneira compatível com a idéia de que ela seria importante para interações laterais entre polímeros de FtsZ. Nossos resultados apontam, portanto, que a hélice H3 deve ser o sítio de interação para ZapA em FtsZ. / The bacterial cytokinesis is ruled by a number of proteins that constitute the divisome complex. FtsZ, a homologue of eukaryotic tubulin, is the main component of the divisome and self-associates in a structure named Z ring. The Z ring works as a scaffold and recruits the other components of divisome, establishing itself where the septum will be synthesized in the cell. Some of these proteins interact directly with FtsZ and control self-association, promoting polymerization or preventing it. Although there have been discovered many of FtsZ modulators, little is known about the mechanisms that control the formation of the Z ring in vivo. The aim of this work was study de interaction between FtsZ e one of its division modulators, ZapA protein, on Bacillus subtilis grampositive bacteria. We created a mutagenized ftsZ plasmid library by error prone PCR, which contained 1,0x105 transformants and exhibited a mutation rate of one substitution per ftsZ copy. The library was transformed into a modified Bacillus subtilis strain and we performed two genetic screenings to select cells with FtsZ mutants incapable of interacting with ZapA. In first strategy, we selected 12 resistant ftsZ mutants for a toxic ZapA overexpression, that blocked division and caused filamentation and cell death. Surprisingly, although these mutants were insensitive to ZapA effect, cytological assays showed that none of them lost interaction with ZapA. As the substitutions were mapped around the catalytic and interaction site of FtsZ structure and showed resistance to other modulators, we suspected that the mutations were affecting the polymer stability of FtsZ and, consequently, the behavior of Z ring. This hypothesis was confirmed by FRAP experiments and by calculations of FtsZ proportions in Z ring, pointing out that the mutants form more stable Z rings. As we didnt\' find mutants that lost their ZapA´s interaction, we applied our library in a second genetic screen, looking for mutants that return to interact with a ZapA mutant (ZapAN62A) that doesn´t bind to FtsZ anymore. This gain of function strategy identified one candidate, FtsZE91V, which returns to interact with ZapAN62A in our genetic and cytological assays. Although the mutant FtsZE91V showed itself capable to interact with ZapAN62A, that didn´t affect the interaction with wild type ZapA by our fluorescent microscopy and viability assays. The substitution E91V was mapped on H3 helix of FtsZ structure. This helix is exposed on FtsZ surfaces (on FtsZ´s lateral side), being compatible with the idea that lateral interaction is important in FtsZ polymers. So, we concluded that helix H3 is the binding site of ZapA in FtsZ.

Bacillus subtilis

Anel Z

Biologia molecular

Divisão celular

Divisomo

FtsZ

Genética bioquímica

Moduladores

ZapA

Bacillus subtilis

Divisome

FtsZ

Modulators

Molecular biology

Z ring

ZapA

Investigating the Structure of FtsZ to Understand its Functional Role in Bacterial Cell Division

Moore, Desmond Antoine

January 2016

<p>FtsZ, a bacterial tubulin homologue, is a cytoskeleton protein that plays key roles in cytokinesis of almost all prokaryotes. FtsZ assembles into protofilaments (pfs), one subunit thick, and these pfs assemble further to form a “Z ring” at the center of prokaryotic cells. The Z ring generates a constriction force on the inner membrane, and also serves as a scaffold to recruit cell-wall remodeling proteins for complete cell division in vivo. FtsZ can be subdivided into 3 main functional regions: globular domain, C terminal (Ct) linker, and Ct peptide. The globular domain binds GTP to assembles the pfs. The extreme Ct peptide binds membrane proteins to allow cytoplasmic FtsZ to function at the inner membrane. The Ct linker connects the globular domain and Ct peptide. In the present studies, we used genetic and structural approaches to investigate the function of Escherichia coli (E. coli) FtsZ. We sought to examine three questions: (1) Are lateral bonds between pfs essential for the Z ring? (2) Can we improve direct visualization of FtsZ in vivo by engineering an FtsZ-FP fusion that can function as the sole source of FtsZ for cell division? (3) Is the divergent Ct linker of FtsZ an intrinsically disordered peptide (IDP)?</p><p> One model of the Z ring proposes that pfs associate via lateral bonds to form ribbons; however, lateral bonds are still only hypothetical. To explore potential lateral bonding sites, we probed the surface of E. coli FtsZ by inserting either small peptides or whole FPs. Of the four lateral surfaces on FtsZ pfs, we obtained inserts on the front and back surfaces that were functional for cell division. We concluded that these faces are not sites of essential interactions. Inserts at two sites, G124 and R174 located on the left and right surfaces, completely blocked function, and were identified as possible sites for essential lateral interactions. Another goal was to find a location within FtsZ that supported fusion of FP reporter proteins, while allowing the FtsZ-FP to function as the sole source of FtsZ. We discovered one internal site, G55-Q56, where several different FPs could be inserted without impairing function. These FtsZ-FPs may provide advances for imaging Z-ring structure by super-resolution techniques.</p><p> The Ct linker is the most divergent region of FtsZ in both sequence and length. In E. coli FtsZ the Ct linker is 50 amino acids (aa), but for other FtsZ it can be as short as 37 aa or as long as 250 aa. The Ct linker has been hypothesized to be an IDP. In the present study, circular dichroism confirmed that isolated Ct linkers of E. coli (50 aa) and C. crescentus (175 aa) are IDPs. Limited trypsin proteolysis followed by mass spectrometry (LC-MS/MS) confirmed Ct linkers of E. coli (50 aa) and B. subtilis (47 aa) as IDPs even when still attached to the globular domain. In addition, we made chimeras, swapping the E. coli Ct linker for other peptides and proteins. Most chimeras allowed for normal cell division in E. coli, suggesting that IDPs with a length of 43 to 95 aa are tolerated, sequence has little importance, and electrostatic charge is unimportant. Several chimeras were purified to confirm the effect they had on pf assembly. We concluded that the Ct linker functions as a flexible tether allowing for force to be transferred from the FtsZ pf to the membrane to constrict the septum for division.</p> / Dissertation

Biochemistry

Cellular biology

Microbiology

bacterial cell division

fluorescent protein

FtsZ

super-resolution

tubulin

Z ring

Détermination des fonctions des protéines FtsZ dans la division et la biogenèse des plastes de plantes supérieures par la caractérisation des mutants FtsZ d'Arabidopsis thaliana.

Karamoko, Mohamed

04 April 2008

La division des chloroplastes des cellules végétales fait intervener des protéines d'origine procaryotique et eucaryotique. Parmi les protéines d'origine procaryotique on trouve la protéine FtsZ, l'ancêtre de la tubiline. Alors que les bactéries n'utilisent qu'une protein FtsZ pour se diviser, les chloroplastes de plantes supérieures possedent deux familles de protéines FtsZ: FtsZ1 et FtsZ2. La caractérisation des mutants FtsZ d'Arabidopsis thaliana montre que les protéines FtsZ en plus d'être impliquées dans la division des plastes ont acquis de nouvelles fonctions au cours de l'évolution. La localization des protéines FtsZ avec les thylacoïdes au cours du développement suggère un rôle des protéines FtsZ dans la biogenèse des chloroplastes au cours du développement des feuilles. Le nombre et la taille des grains d'amidon dans les mutants d'Arabidopsis, ainsi que l'expression des protéines FtsZ au cours de la transition proplastes-amyloplastes dans les cellules BY2 de tabac, suggèrent une fonction de ces protéines dans le metabolisme du grain d'amidon.

[SDV:BV] Life Sciences/Vegetal Biology

Arabidopsis thaliana

chloroplastes

FtsZ

thylacoïdes

grain d'amidon

Developmental Control of Cell Division in <i>Streptomyces coelicolor</i>

Grantcharova, Nina

January 2006

<p>Cell division in the Gram-positive bacterium <i>Streptomyces coelicolor</i> starts with the assembly of the tubulin homologue FtsZ into a cytokinetic ring (the Z ring) at the site of septation. In stark contrast to the binary fission of most bacteria, the syncytial hyphal cells of <i>S. coelicolor</i> exploit two types of cell division with strikingly different outcomes depending on the developmental stage. </p><p>The main goal of this study has been to identify developmental mechanisms that modulate this differential performance of the basic cell division machinery.</p><p>By isolation and characterization of a non-sporulating <i>ftsZ</i> mutant, we demonstrated that the requirements for Z-ring formation differ between the two types of septation. The <i>ftsZ17</i>(Spo) mutation abolished septation without overtly affecting vegetative growth. This mutant was defective in the assembly of FtsZ into regularly spaced Z rings in sporogenic hyphae, suggesting that the assembly of Z rings is developmentally controlled during sporulation.</p><p>An FtsZ-EGFP translational fusion was constructed and used to visualize the progression of FtsZ ring assembly in vivo. This revealed that polymerization of FtsZ occurred throughout the sporogenic cell, with no evidence for pre-determined nucleation sites, and that the placement of multiple Z rings is a dynamic process and involves remodeling of spiral-shaped FtsZ intermediates into regularly spaced rings. </p><p>The dynamics of the multiple Z-rings assembly during sporulation was perturbed by the action of the protein CrgA, which is important for coordinating growth and cell division in sporogenic hyphae. CrgA was also found to affect the timing of <i>ftsZ</i> expression and the turnover of the FtsZ protein. </p><p><i>S. coelicolor</i> is the main genetic model of the streptomycetes, which are major industrial antibiotic producers. The control of cell division in these organisms differs from that of other bacteria like <i>Escherichia coli</i>. Thus, it is of fundamental importance to clarify how the streptomycetes reproduce themselves. </p>

Microbiology

FtsZ

cell division

Streptomyces

GFP

bacterial development

Mikrobiologi

Microbiology

Mikrobiologi

Developmental Control of Cell Division in Streptomyces coelicolor

Grantcharova, Nina

January 2006

Cell division in the Gram-positive bacterium Streptomyces coelicolor starts with the assembly of the tubulin homologue FtsZ into a cytokinetic ring (the Z ring) at the site of septation. In stark contrast to the binary fission of most bacteria, the syncytial hyphal cells of S. coelicolor exploit two types of cell division with strikingly different outcomes depending on the developmental stage. The main goal of this study has been to identify developmental mechanisms that modulate this differential performance of the basic cell division machinery. By isolation and characterization of a non-sporulating ftsZ mutant, we demonstrated that the requirements for Z-ring formation differ between the two types of septation. The ftsZ17(Spo) mutation abolished septation without overtly affecting vegetative growth. This mutant was defective in the assembly of FtsZ into regularly spaced Z rings in sporogenic hyphae, suggesting that the assembly of Z rings is developmentally controlled during sporulation. An FtsZ-EGFP translational fusion was constructed and used to visualize the progression of FtsZ ring assembly in vivo. This revealed that polymerization of FtsZ occurred throughout the sporogenic cell, with no evidence for pre-determined nucleation sites, and that the placement of multiple Z rings is a dynamic process and involves remodeling of spiral-shaped FtsZ intermediates into regularly spaced rings. The dynamics of the multiple Z-rings assembly during sporulation was perturbed by the action of the protein CrgA, which is important for coordinating growth and cell division in sporogenic hyphae. CrgA was also found to affect the timing of ftsZ expression and the turnover of the FtsZ protein. S. coelicolor is the main genetic model of the streptomycetes, which are major industrial antibiotic producers. The control of cell division in these organisms differs from that of other bacteria like Escherichia coli. Thus, it is of fundamental importance to clarify how the streptomycetes reproduce themselves.

Microbiology

FtsZ

cell division

Streptomyces

GFP

bacterial development

Mikrobiologi

Microbiology

Mikrobiologi

Transcriptional Analysis Of The Principal Cell Division Gene ftsZ Of Mycobacterium Tuberculosis And Mycobacterium Smegmatis

Roy, Sougata

06 1900

The success of Mycobacterium tuberculosis as a pathogen is due to its remarkable ability to: (i). adapt to and survive inside activated macrophages under nonproliferating condition, (ii). put up drug resistance and (iii). enter into hypoxia-induced dormancy and remain in nonproliferating condition, be resistant to drugs, and get reactivated into proliferation when favourable conditions arise. Thus, regulation of cell division (arrest and resumption) is an obligatory event that is critical to the pathogen for the establishment of successful infection, latency and reactivation process in human host. Therefore, in order to understand and combat the successful survival strategy of the bacterium inside the host macrophages or in granuloma, a basic knowledge of the regulation of cell division in tubercle bacillus is essential. Bacterial cytokinetic protein FtsZ (a tubulin homologue) is the key regulatory molecule for cell division and its intracellular level is critical for initiation of cell division in bacteria. Therefore, in order to understand the regulation cell division by expression and maintenance of ftsZ mRNA and protein, we initiated studies on the transcriptional regulation of ftsZ gene in the slow growing pathogen, M. tuberculosis, and in the fast-growing saprophyte M. smegmatis. Identification of regions containing ftsZMt promoter activity In order to identify promoter activity-containing regions of ftsZ gene of M. tuberculosis H37Rv (ftsZMt) in vivo, different regions upstream of ftsZMt namely, the ftsQ-ftsZ intergenic region, the ftsQ open reading frame (ORF), and different regions of ftsQ ORF, were cloned in a gfp reporter plasmid and analyzed for gfp expression in M. smegmatis mc2155 cells. Flow cytometric analysis of exponentially grown M. smegmatis mc2155 cells containing these transcription fusion constructs revealed GFP expression in the cells harbouring ftsQ-ftsZ intergenic region (172 bp), the entire ftsQ ORF (945 bp), and 5’ 467 bp and 3’ 217 bp regions of ftsQ ORF. RT-PCR analyses on RNA from M. smegmatis mc2155 cell transformants carrying the entire ftsQ ORF-ftsQ-ftsZ intergenic region containing construct, as well as on total RNA from M. tuberculosis confirmed that the regions identified indeed elicit promoter activity. RT-PCR analysis on M. tuberculosis RNA as well as semi-quantitative RT-PCR analyses of gfp transcripts driven by cloned MtftsZ promoter regions in M. smegmatis cells showed that about 70% of the total promoter activity comes from ftsQ ORF and there is co-transcription of ftsQ-ftsZ genes. Multiple transcripts code for ftsZMt Primer extension analysis, using primers annealing at different positions in the ftsQ-ftsZ chromosomal region, on RNA from M. tuberculosis as well as from M. smegmatis transformants containing 1.117 kb ftsZMtpromoter region in a promoter probe vector, identified origin of six different transcripts (T1-T6) for the gene. Among them, five transcripts (T1, T2, T3, T4, and T6) were detected in M. tuberculosis cells at exponential phase of growth. T5 could be detected only in M. smegmatis transformants containing 1.117 kb ftsZMt promoter upstream of mycgfp2+ reporter gene. Transcript T1 and T2 originate in the ftsQ-ftsZ intergenic region, while T3, T4, and T6 start in the ftsQ ORF. Analysis of sequence in the –10 and –35 regions of the corresponding promoters for the individual transcripts identified high GC content of the regions, which is characteristic of promoters of M. tuberculosis. All of the individual promoter sequences were independently cloned in a promoter probe vector and confirmed that they are true promoters, active in M. smegmatis cells, and that the T1-T6 transcripts were not products of RNA processing. Differential expression from the multiple ftsZMt promoters In order to study the activity and regulation of ftsZMt promoters in M. tuberculosis cells, which is a slow grower and also asymptomatically survives as dormant bacteria for decades in human granuloma, a stably genome-integrated plasmid was required where activity of the promoters can be studied by means of stable and enhanced gfp expression. For that purpose, an L5-mycobacteriophage attP (attachment site)-specific integration proficient promoter probe vector, which contains a stable gfp gene (mycgfp2+) whose codon has been optimized for mycobacterial expression, was generated. Using the vector, all the six promoter regions (P1-P6) were studied in M. smegmatis and M. tuberculosis cells. Flow cytometric and semi-quantitative RT-PCR analyses showed that promoter P5 is unable to elicit activity in M. tuberculosis cells, unlike in M. smegmatis transformants. Semi-quantitative RT-PCR analyses showed that expression of P3 is only 10-20% of the total promoter activity. Promoters P1, P2, P4 and P6 showed 50-80% activity of the total promoter activity and their activity were comparable in M. smegmatis and M. tuberculosis. The presence of multiple promoters reflects the requirement to maintain high basal level of, or to differentially regulate a critical level of, FtsZ expression during different pathogenic stages of tubercle bacilli. In order to investigate the role of multiple promoters, we verified the levels of expression of the five transcripts from the five ftsZ promoters in M. tuberculosis cells under conditions of growth inside mouse macrophage cell line and also under various stress conditions mimicking those that exist in the granuloma environment, like conditions of nonreplicating persistence, gradual nutrient depletion stress, oxidative stress, surface tension stress, acidic stress, heat shock, DNA damaging conditions and osmotic stress. For this purpose, individual promoter regions were cloned into a stably inheritable gfp reporter plasmid vector, and into an L5 mycobacteriophage attP (attachment site)-specific integration-proficient variant of the same vector, for the expression of the promoters from the chromosomal locus in M. smegmatis and M. tuberculosis cells. Quantitative primer extension analyses, semiquantitative RT-PCR analyses on RNA from M. tuberculosis cells grown under these different conditions, and quantitative GFP fluorescence analyses in these cells showed differential activation of the five promoters under different conditions of growth. Under hypoxic and nutrient-depleted stationary phase of growth, two new promoters, Tdor and Ts, in the ftsQ ORF were identified, and these promoters showed maximal activity only under those specific conditions of growth. None of the ftsZ promoters were found to be responsive to stringent response mediated by overexpression of M. tuberculosis RelA. None of the promoters were also found to be responsive of overexpression of heat-shock sigma factor SigH in M. tuberculosis, implicating new pathway of regulation of ftsZ promoters. Multiple promoters driving expression of ftsZ gene of M. smegmatis Similar studies, which were carried out on the identification, structural and functional characterization, regulation of the promoters of cell division gene ftsZ in the fast growing saprophyte M. smegmatis cells, showed the presence of four ftsZ promoters, three of which originates from the 249 bp ftsQ-ftsZ intergenic region and one from the ftsQ ORF. RT-PCR analysis showed that both ftsQ and ftsZ are co-transcribed. Cloning and expression analysis of the individual promoters mapped by primer extension in a GFP based reporter plasmid showed that all the four putative regions are true promoters. Quantitative primer extension on RNA from a synchronously grown culture identified P2 promoter to be responsive to either initiation of cell division or stress, although expression of P1, P3, and P4 did not vary with respect to synchronous division. Quantitative primer extension analysis and semi-quantitative RT-PCR analysis on the RNA from M. smegmatis cells showed that under various stress conditions, P2 activity goes down significantly. Under nutrient depleted stationary phase and hypoxic nonreplicating persistence stage-2, the levels of P2 and P3 activity could hardly be detected, whereas, expression from P1 and P4 goes down only in hypoxia. Level of total ftsZ mRNA remains almost the same under various stress conditions, although upon hypoxia and stationary phase the level goes down almost two fold. Thus, in fast growing M. smegmatis too, multiple ftsZ promoters are differentially regulated under various stress conditions and a critical level of ftsZ mRNA is maintained. Taken together, the study of ftsZ promoters of a slow-growing pathogenic mycobacterium and a fast growing non-pathogenic mycobacterium indicate that differential expression of the multiple promoters, along with conditional activation of stage specific promoters like Pdor or Ps, is one of the mechanisms through which the bacilli probably maintain required levels of FtsZ protein that are crucial for the cell survival, probably through cytoskeletal maintenance, and cell division.

Gene Transcription

Gene Regulation

Mycobacterium Tuberculosis

Mycobacterium Smegmatis

ftsZ

Cell Division Gene

Molecular Biology

Single-molecule Imaging of the Cell Division Ring in Escherichia coli Using the ALFA-tag / Enmolekyl-mikroskopi av delningsringen i Escherichia coli med användandet av ALFA-taggen

Westlund, Emma

January 2023

The use of super-resolution (SR) microscopy is an important tool for understanding the inside mechanisms of bacterial cells. However, for SR imaging, the labelling of the proteins of interest is a great challenge as flourescent proteins (FPs) are often too big to be directly fused to the target protein and traditional immunolabelling with antibodies creates too long separation between the fluorophore and the target protein. In an attempt to overcome this hurdle, the Escherichia coli (E. coli) cell division protein FtsZ is in this project fused to a nanotag (NT) that is subsequently labelled with a nanobody (NB). The ALFA-tag, a short amino acid peptide, is chromosomally fused to the target protein, creating a MG1655/FtsZ-ALFA strain where all FtsZ proteins have an ALFA-tag attached. Recognising the ALFA-tag is the NB αALFA (anti-ALFA) which is fused to a FP and expressed from a plasmid. The MG1655/FtsZ-ALFA strain is labelled using standard plasmid transformation which allows for live cell imaging of the division ring in E. coli. Both FPs sfGFP and mEos3.2 are used for labelling which means that the cells can be imaged in epifluorescence microscopy and single-molecule Photo-Activated Localisation Microscopy (PALM), and even single-molecule time lapses of the constricting FtsZ-ring is possible. This system is also applicable to other bacterial proteins. / Superupplösningsmikroskopi (SUM) är ett viktigt redskap för att förstå de inre processerna i en bakteriecell. Att på ett framgångsrikt sätt tagga målproteinerna har dock visat sig vara en utmaning för SUM. Att direkttagga målproteinerna med fluorescerande protein är oftast inte möjligt på grund av de fluorescerande proteinernas storlek och traditionell märkning med antikroppar skapar ett för stort avstånd mellan fluorofor och målprotein. För att överkomma detta problem taggas här celldelningsproteinet FtsZ iEscherichia coli (E. coli) med hjälp av nanotaggar (NT) och nanokroppar (NK). ALFA-taggen, en kort aminosyrapeptid, är kromosomt bunden till FtsZ i cellinjen MG1655/FtsZ-ALFA, så att varje FtsZ protein som produceras har en ALFA-tag bunden till sig. NK αALFA (anti-ALFA) känner igen och binder till ALFA-taggen när de kommer i kontakt. NK är bunden till ett fluorescerande protein och uttryckt från en plasmid vilket gör att MG1655/FtsZ-ALFA kan bli taggad med hjälp av vanlig plasmidtransformation. Denna metod möjliggör mikroskopi av divisionsringen i levande E. coli-celler. Två olika fluorescerande protein används, sfGFP och mEos3.2, vilket innebär att både epifluorensmikroskopi och fotoaktiverad lokaliseringsmikroskopi (PALM) kan användas. Dessutom är även intervallfotografering i enmolekylmikroskopi av divisionsringens konstriktion möjligt. Denna märkningsteknik är vidare applicerbar på andra bakteriella protein.

ALFA-tag

Escherichia coli

Divisome protein FtsZ

mEos3.2

Nanobodies

Nanotags

PALM

Plasmid transformation

sfGFP

Single-molecule Imaging

ALFA-tag

Escherichia coli

Divisomprotein FtsZ

mEos3.2

Nanokroppar

Nanotaggar

PALM

Plasmidtransformation

sfGFP

Enmolekyl-mikroskopi

Physical Sciences

Fysik

Influence Of FtsH Protease On The Medial FtsZ Ring In Escherichia Coli

Bhatt, Brijesh Narayan

08 1900

FtsH is an essential AAA family Zn++ metalloprotease of Escherichia coli, possessing ATPase-dependent chaperon activity and ATP-dependent protease activity. Heat shock transcription factor Sigma32, LpxC, SecY, and bacteriophage protein CII are some of the substrates of FtsH. Although FtsH is known to influence several cellular processes, the role of FtsH in bacterial cell division had not been identified. FtsZ is the principal cell division protein that marks the cell division site at mid-cell by forming a ring structure. Using a pair of ftsH-null and isogenic wild type strain of E. coli, earlier studies in the laboratory had demonstrated that proteolytic function of FtsH is required for the presence of FtsZ rings at mid-cell site. It was also shown that FtsZ is not a substrate for FtsH protease in vivo. In view of these observations, using a pair of ftsH-null and isogenic wild type strain of E. coli, experiments were carried out to find out the mechanism behind the requirement for FtsH protease for the presence of FtsZ ring at mid-cell site. Viability of the cells having ftsH-null status was maintained by a suppressor mutation at another locus, and was found to be comparable to that of isogenic wild type cells. Immunostaining for FtsZ showed that only 20% cells of ftsH-null strain of E. coli has FtsZ ring at mid-cell site, On the contrary, more than 90% cells of isogenic wild type cells had FtsZ ring at mid-cell site. Live cell imaging with FtsZ-GFP also showed similar results. Low fraction of ftsH-null cells having FtsZ ring was found to be independent of slow growth rate of the cells. Confocal microscopy revealed that ftsH-null cells lacked the normal helical spiral-type structure of FtsZ, unlike the intact FtsZ helices present in isogenic wild type cells. FtsZ protein levels in the membrane and cytoplasmic fractions of ftsH-null cells were found to be same as those in the isogenic wild type cells. Exogenous expression of wild type FtsH in ftsH-null cells could restore FtsZ ring status to normalcy, similar to that in the isogenic wild type cells. However, this restoration could not be accomplished by FtsH mutants, which were lacking in ATP binding, ATPase, or protease activities. FtsA anchors FtsZ to the membrane and a specific FtsZ/FtsA ratio is known to be critical for cell division. Further, FtsA and/or ZipA are required for the stabilisation of FtsZ ring at mid-cell site. The levels of FtsA were found to be lower by more than 2.5-fold in all the membrane and soluble fractions of ftsH-null cells. The levels of FtsA were found restored to normalcy upon complementation with exogenous expression of FtsH. Low levels of FtsA were not due to the slow growth of ftsH-null cells. Exogenous expression of FtsA or FtsA-GFP restored FtsZ in more than 90% of ftsH-null cells. Moreover, FtsA mutants, which are defective in the interaction with FtsZ, did not restore FtsZ rings to normalcy. The levels of ZipA were found to be same in ftsH-null and isogenic wild type cells. Expression of ZipA or ZipA-GFP could restore FtsZ rings to normalcy in ftsH-null cells. These data showed that low FtsA levels might be the reason for low percentage of cells having FtsZ ring in ftsH-null cells. It implied that ftsH-null cells might have been managing FtsZ ring stabilisation with ZipA, to facilitate septation. Real time RT-PCR showed that the levels of ftsA mRNA and those of all the other fts genes, except ftsZ, in the 16-gene dcw cluster, were found to be low in ftsH-null cells. Moreover, real time RT-PCR using specific primers designed for multiple promoters of ftsZ and for the RNaseE processing site, just upstream of ftsZ, showed that the levels of transcripts of the genes upstream to RNaseE site were significantly low and that the levels of ftsZ transcripts, which were downstream to RNaseE site, were unaffected. On the contrary, the levels of mRNAs of fts genes, such as ftsE, ftsX, ftsN, and zipA that were located at another part of the genome, were normal in ftsH-null cells. These observations suggested that the reason for the low levels of FtsA protein might be low levels of ftsA mRNA. In addition, the low levels of other fts mRNAs from the dcw cluster, and probably of the respective proteins, might contribute to the slow growth of ftsH-null cells. The ftsH null strains also showed less compact nucleoids and the nucleoids did not look bilobular. This data suggested that there may be some defect in the compaction of nucleoids in ftsH-null cells. On the contrary, isogenic wild type cells, when grown slow like the growth of ftsH-null cells, had no defect in nucleoid compaction and looked bilobular. The proper compaction of nucleoids could be restored only by wild type FtsH, but not by the protease mutant of FtsH. These observations suggest that proteolytic activity of FtsH might be required for the proper compaction of nucleoids, which in turn might have influence on the placement of FtsZ ring at mid-cell site. In parallel, different percentage of silver stained single-dimension SDS-PAGE showed conspicuous difference in the protein profiles of the membrane and soluble fractions of ftsH-null cells, in comparison to those of isogenic wild type cells. FtsZ co-immuno precipitation (CoIP) of total cell lysates of ftsH-null and isogenic wild type cells showed differential interaction of two proteins, the outer membrane protein A (OmpA) and a 50 kDa protein, between the two strains. The level of OmpA was 2.5-fold high in ftsH-null cells, in comparison to that in isogenic wild type cells. However, overexpression of ompA in isogenic wild type cells did not have any effect on FtsZ rings in isogenic wild type cells. Two-dimensional gel electrophoresis for membrane and soluble fractions of ftsH-null cells, in comparison with that of isogenic wild type cells, showed that several proteins in each fraction were either present or absent between these two strains. Most of these proteins were then identified using MALDI-TOF / LC –MS methods. Identification of these proteins, which were present differentially between ftsH-null and isogenic wild type cells, has revealed existence of many more hitherto unidentified potential substrates of FtsH and therefore cell processes, which FtsH may influence.

Bacterial Cell

Escherichia Coli

FtsH Protease

FtsZ Ring

Cell Division Genes

Bacterial Cell Septation

FtsA

E. coli

Biochemistry

A Comprehensive Model of the Structure and Function of the FtsZ Ring of Escherichia coli

Redfearn, James C.

21 April 2016

No description available.

Biochemistry

Cellular Biology

Microbiology

FtsZ

FtsA

Z-ring

reconstitution

binary fission

bacterial cell division

cell division

Escherichia coli

cytokinesis

divisome