Oligomerisation, localisation and interaction of the sensor histidine kinases DcuS and CitA in Escherichia coli

The two-component system DcuSR of Escherichia coli regulates gene expression of anaerobic fumarate respiration and aerobic C4-dicarboxylate uptake. C4-dicarboxylates and citrate are perceived by the periplasmic domain of the membrane-integral sensor histidine kinase DcuS. The signal is transduced across the membrane by phosphorylation of DcuS and of the response regulator DcuR, resulting in activation of DcuR and transcription of the target genes.rnIn this work, the oligomerisation of full-length DcuS was studied in vivo and in vitro. DcuS was genetically fused to derivatives of the green fluorescent protein (GFP), enabling fluorescence resonance energy transfer (FRET) measurements to detect protein-protein interactions in vivo. FRET measurements were also performed with purified His6-DcuS after labelling with fluorescent dyes and reconstitution into liposomes to study oligomerisation of DcuS in vitro. In vitro and in vivo fluorescence resonance energy transfer showed the presence of oligomeric DcuS in the membrane, which was independent of the presence of effector. Chemical crosslinking experiments allowed clear-cut evaluation of the oligomeric state of DcuS. The results showed that detergent-solubilised His6-DcuS was mainly monomeric and demonstrated the presence of tetrameric DcuS in proteoliposomes and in bacterial membranes.rnThe sensor histidine kinase CitA is part of the two-component system CitAB of E. coli, which is structurally related to DcuSR. CitAB regulates gene expression of citrate fermentation in response to external citrate. The sensor kinases DcuS and CitA were fused with an enhanced variant of the yellow fluorescent protein (YFP) and expressed in E. coli under the control of an arabinose-inducible promoter. The subcellular localisation of DcuS-YFP and CitA-YFP within the cell membrane was studied by means of confocal laser fluorescence microscopy. Both fusion proteins were found to accumulate at the cell poles. The polar accumulation was slightly increased in the presence of the stimulus fumarate or citrate, respectively, but independent of the expression level of the fusion proteins. Cell fractionation demonstrated that polar accumulation was not related to inclusion bodies formation. The degree of polar localisation of DcuS-YFP was similar to that of the well-characterised methyl-accepting chemotaxis proteins (MCPs), but independent of their presence. To enable further investigations on the function of the polar localisation of DcuS under physiological conditions, the sensor kinase was genetically fused to the flavin-based fluorescent protein Bs2 which shows fluorescence under aerobic and anaerobic conditions. The resulting dcuS-bs2 gene fusion was inserted into the chromosome of various E. coli strains.rnFurthermore, a protein-protein interaction between the related sensor histidine kinases DcuS and CitA, regulating common metabolic pathways, was detected via expression studies under anaerobic conditions in the presence of citrate and by in vivo FRET measurements.

Ricerca di Escherichia coli produttori di verocitotossine e definizione di obiettivi di performance nella produzione primaria di alimenti di origine animale

La presenza di Escherichia coli produttori di verocitotossine (VTEC o STEC) rappresenta una tra le più importanti cause di malattia alimentare attualmente presenti in Europa. La sua presenza negli allevamenti di animali destinati alla produzione di alimenti rappresenta un importante rischio per la salute del consumatore. In conseguenza di comuni contaminazioni che si realizzano nel corso della macellazione, della mungitura i VTEC possono essere presenti nelle carni e nel latte e rappresentano un grave rischio se la preparazione per il consumo o i processi di lavorazione non comportano trattamenti in grado d’inattivarli (es. carni crude o poco cotte, latte non pastorizzato, formaggi freschi a latte crudo). La contaminazione dei campi coltivati conseguente alla dispersione di letame o attraverso acque contaminate può veicolare questi stipiti che sono normalmente albergati nell’intestino di ruminanti (domestici e selvatici) e anche prodotti vegetali consumati crudi, succhi e perfino sementi sono stati implicati in gravi episodi di malattia con gravi manifestazioni enteriche e complicazioni in grado di causare quadri patologici gravi e anche la morte. Stipiti di VTEC patogeni ingeriti con gli alimenti possono causare sintomi gastroenterici, con diarrea acquosa o emorragica (nel 50% dei casi), crampi addominali, febbre lieve e in una percentuale più bassa nausea e vomito. In alcuni casi (circa 5-10%) l’infezione gastroenterica si complica con manifestazioni tossiemiche caratterizzate da Sindrome Emolitico Uremica (SEU o HUS) con anemia emolitica, insufficienza renale grave e coinvolgimento neurologico o con una porpora trombotica trombocitopenica. Il tasso di mortalità dei pazienti che presentano l’infezione da E. coli è inferiore all’1%. I dati forniti dall’ECDC sulle infezioni alimentari nel periodo 2006-2010 hanno evidenziato un trend in leggero aumento del numero di infezioni a partire dal 2007. L’obiettivo degli studi condotti è quello di valutare la prevalenza ed il comportamento dei VTEC per una analisi del rischio più approfondita.

The C-4-Dicarboxylate carriers DcuB and DctA of Escherichia coli: function as cosensors and topology

Das fakultativ anaerobe Enterobakterium Escherichia coli nutzt C4-Dicarboxylate sowohl unter aeroben als auch anaeroben Bedingungen als Kohlenstoff- und Energiequelle. Die Aufnahme der C4-Dicarboxylaten und die Energiekonservierung mittels Fumaratatmung wird durch das Zweikomponentensystem DcuSR reguliert. Die Sensorhistidinkinase DcuS und der nachgeschaltete Responseregulator DcuR aktivieren bei Verfügbarkeit von C4-Dicarboxylaten die Expression der Gene für den Succinat Transporter DctA, den anaeroben Fumarat/Succinat Antiporter DcuB, die Fumarase B sowie die Fumaratreduktase FrdABCD. Die Transportproteine DctA und DcuB wiederum regulieren die Expression der DcuSR-abhängigen Gene negativ. Fehlen von DctA oder DcuB resultiert bereits ohne Effektor in einer maximalen Expression von dctA bzw. dcuB. Durch gerichtete und ungerichtete Mutagenese wurde gezeigt, dass die Transportfunktion des Carriers DcuB unabhängig von seiner regulatorischen Funktion ist. DcuB kann daher als Cosensor des DcuSR Systems angesehen werden.rnUnter Verwendung von Reportergenfusionen von C-terminal verkürzten Konstrukten von DcuB mit der Alkalischen Phosphatase und der β-Galactosidase wurde die Topologie des Multitransmembranproteins DcuB bestimmt. Zusätzlich wurde die Zugänglichkeit bestimmter Aminosäurereste durch chemische Modifikation mit membran-durchlässigen und membran-undurchlässigen Thiolreagenzien untersucht. Die erhaltenen Ergebnisse deuten auf die Existenz eines tief in die Membran reichenden, hydrophilen Kanal hin, welcher zum Periplasma hin geöffnet ist. Mit Hilfe der Topologie-Studien, des Hydropathie-Blots und der Sekundärstruktur-Vorhersage wurde ein Modell des Carriers erstellt. DcuB besitzt kurze, periplasmatisch liegende Proteinenden, die durch 12 Transmembranhelices und zwei große hydrophile Schleifen jeweils zwischen TM VII/VIII und TM XI/XII verbunden sind. Die regulatorisch relevanten Reste K353, T396 und D398 befinden sich innerhalb von TM XI sowie auf der angrenzenden cytoplasmatischen Schleife XI-XII. Unter Berücksichtigung der strukturellen und funktionellen Aspekte wurde ein Regulationsmodell erstellt, welches die gemeinsam durch DcuB und DcuS kontrollierte C4-Dicarboxylat-abhängige Genexpression darstellt. rnDer Effekt von DctA und DcuSR auf die Expression einer dctA´-´lacZ Reportergenfusion und auf die aerobe C4-Dicarboxylat-Aufnahme wurde untersucht. In-vivo FRET-Messungen weisen auf eine direkte Wechselwirkung zwischen dem Carrier DctA und dem Sensor DcuS hin. Dieses Ergebnis stützt die Theorie der Regulation von DcuS durch C4-Dicarboxylate und durch die Cosensoren DctA bzw. DcuB mittels direkter Protein-Protein Interaktion.rn

The oxygen sensors FNR from Escherichia coli and NreABC from Staphylococcus carnosus

Im Laufe der Evolution entwickelte sich eine Reihe von Sauerstoff-Sensorsystemen in Bakterien, um die Genexpression der Sauerstoffverfügbarkeit anzupassen. Der Sauerstoffsensor FNR aus Escherichia coli bindet unter anaeroben Bedingungen ein [4Fe4S]2+ Zentrum. Unter Sauerstoffeinfluß zerfällt aktives [4Fe4S]2+FNR zu inaktivem [2Fe2S]2+FNR und weiter zu ebenfalls inaktivem apoFNR. In der vorliegenden Arbeit wurde der Zustand von FNR in vivo in aeroben und anaeroben Zellen von Escherichia coli aufgeklärt. Durch Alkylierung der Cysteine in FNR und anschließender Analyse im Massenspektrometer konnte gezeigt werden, das FNR in aeroben Zellen hauptsächlich in der apo-Form vorliegt. Nach ca. 6 Minuten war in lebenden E. coli Zellen die Umwandlung von [4Fe4S]2+ FNR zu apoFNR abgeschlossen.rnrnIn dem gram positiven Bakterium Staphylococcus carnosus aktiviert das NreBC System unter anaeroben Wachstumsbedingungen die Gene der Nitratatmung. NreB ist eine cytoplasmatische Sensorhistidinkinase, die ein sauerstofflabiles [4Fe4S]2+ Zentrum über eine PAS-Domäne bindet. Das [4Fe4S]2+ Zentrum wird von vier Cysteinen gebunden. Der Responsregulator NreC steuert nach Aktivierung durch NreB die Transkription der Zielgene. In der vorliegenden Arbeit wurde NreB mit Hilfe von Cysteinmarkierungen in vivo charakterisiert. Durch die Änderung der Cystein-Zugänglichkeit für Thiolreagenzien nach Sauerstoffzugabe konnte eine Halbwertszeit von ca. 3 Minuten für das [4Fe4S]2+ Zentrum in vivo bestimmt werden. In anaeroben Bakterien stellt [4Fe4S]2+NreB die Hauptform von NreB dar, während in aeroben Bakterien hauptsächlich apoNreB vorkommt. Dieses Ergebnis konnte durch Massenspektroskopie bestätigt werden. Weiterhin konnte gezeigt werden das NreA mit NreB und NreC wechselwirkt und Bestandteil des NreABC Drei-Komponentensystems ist. rn

Analisi della resa di purificazione di componenti della dna polimerasi III di escherichia coli

Nella seguente tesi sono stati affrontati differenti protocolli di purificazione di componenti della DNA polimerasi III di Escherichia coli, previamente sovraespressi nel microrganismo. A distanza di oltre 20 anni dall’identificazione della DNA polimerasi III quale enzima responsabile della replicazione del genoma di E. coli, sono stati fatti progressi riguardo la sua conoscenza. Tuttavia molti sono gli aspetti rimasti incogniti riguardo al meccanismo d’azione dell’enzima, così come il ruolo svolto dalle sue subunità e parte della loro struttura. Al fine di migliorare la comprensione di questo enzima, è necessario insistere sulla diffrattometria di raggi X, per la quale è indispensabile l’isolamento di cristalli delle proteine. Si intuisce la necessità di sviluppare metodi appropriati che consentano di ottenere una resa il più possibile elevata dei suoi componenti. Una metodica generale per la sovraespressione del core catalitico e della singola subunità α, deputata all’attività polimerasica a carico di entrambi i filamenti di DNA, era già stata perfezionata presso il laboratorio ospitante. Con il presente lavoro sono stati sperimentati alcuni procedimenti, volti ad aumentare la resa di purificazione, adottando differenti soluzioni. In primo luogo, si è cercato di recuperare le proteine contenute nel flow through eluito da una colonna cromatografica Q-Sepharose, alla quale non erano riuscite a legarsi durante il primo stadio di purificazione. Inoltre, sono stati sperimentati metodi alternativi di lisi cellulare di estrazione delle proteine. In sintesi, il contenuto della tesi potrebbe agevolare la valutazione di diverse strategie per incrementare la resa di purificazione della subunità α e del core polimerasico della DNA Polimerasi III di E. coli.

PAS c als signaltransduzierende Domäne des Sensorproteins DcuS von Escherichia coli

Bakterien besitzen membranintegrierte Sensoren für die Reaktion auf verändernde Umweltbedingungen.rnViele der Sensoren sind Zweikomponenten-Systeme bestehend aus einer Sensorhistidinkinase und einem Responseregulator der die zellulare Antwort auslöst. DcuS, der C4-Dicarboxylat-Sensor von DcuS ist eine membranintegrierte Histidin-Kinase. DcuS ist ein Multidomänen-Protein mit einer sensorischen periplasmatischen PASP (Per-Arnt-Sim) Domäne, zwei Transmembranhelices, eine cytoplasmatische PASC-Domäne und eine C-terminale Kinase-Domäne. PAS-Domänen sind ubiquitäre Signalmodule die in allen Reichen des Lebens zu finden sind. PAS-Domänen detektieren eine Vielfalt von Reizen wie Licht, Sauerstoff, Redoxpotential und verschiedene kleine Moleküle so wie die Modulation von Protein-Protein Interaktionen. PAS-Domänen sind strukturell homolog und besitzen eine charakteristische α/β-Faltung. Eine große Anzahl der sensorischen PAS-Domänen wurden identifiziert, aber viele der PAS-Domänen besitzen keinen apparenten Cofaktor und die Funktion ist unbekannt.rnEine Kombination aus gerichteter und ungerichteter Mutagenese, Protein-Protein-Interaktionsstudien und Festkörper-NMR (ssNMR) Experimente mit strukturellem Modelling wurde zur Untersuchung der Struktur und Funktion der cytoplasmatischen PAS-Domäne des membranintegrierten Sensors DcuS verwendet. Die Experimente zeigen, dass PASC eine wichtige Rolle in die Signaltransduktion von PASP zur C-terminalen Histidin-Kinase von DcuS spielt.rn

Caratterizzazione dell'attivita pirofosfatasica associata al dominio php della DNA Polimerasi III di Escherichia coli

Il presente lavoro si incentra sulla parziale caratterizzazione del sito attivo del dominio PHP della subunità alpha, componente fondamentale dell'Oloenzima polimerasi III di E. coli. E' stato messo in luce il coinvolgimento di questo dominio nel meccanismo di idrolisi del pirofosfato generato dalla reazione polimerasica, valutando inoltre il grado di associazione tra queste due attività.

Structural and kinetic characterization of DNA polymerases I and III from Escherichia coli

DNA elongation is performed by Pol III α subunit in E. coli, stimulated by the association with ε and θ subunits. These three subunits define the DNA Pol III catalytic core. There is controversy about the DNA Pol III assembly for the simultaneous control of lagging and leading strands replication, since some Authors propose a dimeric model with two cores, whereas others have assembled in vitro a trimeric DNA Pol III with a third catalytic core, which increases the efficiency of DNA replication. Moreover, the function of the PHP domain, located at the N-terminus of α subunit, is still unknown. Previous studies hypothesized a possible pyrophosphatase activity, not confirmed yet. The present Thesis highlights by the first time the production in vivo of a trimeric E. coli DNA Pol III by co-expressing α, τ, ε and θ subunits. This trimeric complex has been enzymatically characterized and a molecular model has been proposed, with 2 α subunits sustaining the lagging-strand replication whereas the third core replicates the leading strand. In addition, the pyrophosphatase activity of the PHP domain has been confirmed. This activity involves, at least, the H12 and the D19 residues, whereas the D201 regulates phosphate release. On the other hand, an artificial polymerase (HoLaMa), designed by deleting the exonuclease domain of Klenow Fragment, has been expressed, purified and characterized for a better understanding of bacterial polymerases mechanism. The absence of exonuclease domain impaired enzyme processivity, since this domain is involved in DNA binding. Finally, Klenow enzyme, HoLaMa, α subunit and DNA Pol III αεθ have been characterized at the single-molecule level by FRET analysis, combining ALEX and TIRF microscopy. Fluorescently-labeled DNA molecules were immobilized, and changes in FRET efficiency enabled us to study polymerase binding and DNA polymerization.

Bioverkapselung lebender Bakterien (Escherichia coli) mit Poly-(Silicat) nach Transformation mit dem Silicatein-alpha-Gen

Die Bioverkapselung ist eine faszinierende Methode, um biologische Materialien einschließlich Zellen in Siliziumdioxid, Metalloxiden oder hybriden Sol-Gel-Polymeren zu immobilisieren. Bisher wurde nur die Sol-Gel-Vorläufertechnologie genutzt, um Bakterien- oder Hefezellen in Siliziumdioxid zu immobilisieren. Hierfür wurden verschiedene Reagenzien als wässrige Vorläufer getestet, um poly(Silicate) auf Biomolekülen (Bhatia et al., 2000) oder Zellen (Liu und Chen 1999; Coradin und Livage, 2007) zu bilden. Einer der erfolgreichsten bisherigen Methoden verwendet eine Mischung aus Silicaten und kolloidalem Silica. Diese initialen Vorläufer werden durch die Zugabe von Salzsäure neutralisiert, was die Gelbildung fortschreiten lässt und die Verkapselung von Bakterien in einem Silica-Netzwerk zur Folge hat (Nassif et al., 2003). Mit der Entdeckung von Silicatein, einem Enzym, das aus Demospongien isoliert wurde und die Bildung von poly(Silicat) katalysiert, wurde es möglich, poly(Silicat) unter physiologischen Bedingungen zu synthetisieren. Silicatein wurde rekombinant in E. coli hergestellt und ist in der Lage, bei Raumtemperatur, neutralem pH-Wert und in wässrigen Puffersystemen aus Siliziumalkoxiden poly(Silicat) zu bilden (Krasko et al., 2000; Müller et al., 2007b; Zhou et al., 1999). In vivo katalysiert Silicatein die Synthese der Silicathülle der Schwamm-Spiculae (Skelettelemente; Müller et al., 2005b; Müller et al., 2007a; Müller et al., 2007b; Schröder et al., 2007a). Dieses Biosilica wurde in Form von Silica-Nanospheren mit Durchmessern zwischen 100 nm und 250 nm organisiert vorgefunden (Pisera 2003; Tahir et al., 2005). Mit dieser Arbeit konnte gezeigt werden, dass Escherichia coli erfolgreich mit dem Silicatein-Gen transformiert werden kann. Das Level der Proteinexpression kann in Anwesenheit von Isopropyl-β-D-thiogalaktopyranosid (IPTG) effizient erhöht werden, indem man die Bakterienzellen gleichzeitig mit Kieselsäure inkubiert. Dieser Effekt konnte sowohl auf Ebene der Synthese des rekombinanten Proteins durch Western Blot als auch durch Immunfluoreszenzmikroskopie nachgewiesen werden. Das heterolog produzierte Silicatein besitzt enzymatische Aktivität und kann die Polymerisation von Kieselsäure katalysieren. Dies konnte sowohl durch Färbung mit Rhodamin123, als auch durch Reaktion der nicht polymerisierten, freien Kieselsäure mit dem ß-Silicomolybdato-Farbsystem (Silicomolybdänblau) nachgewiesen werden. Elektronenmikroskopische Untersuchungen zeigten, dass nur die silicateinexprimierenden Bakterien während des Wachstums in Anwesenheit von Kieselsäure eine viskose Hülle um Zelle herum bilden. Ebenfalls konnte gezeigt werden, dass Silicatein-α aus Suberites domuncula nach Transformation in E. coli an die Zelloberfläche dieser Zellen transportiert wurde und dort seine enzymatische Funktion beibehielt. Die Silicathülle wurde mittels Raster-Elektronenmikroskopie (REM) analysiert. Die Bakterien, die Silicatein exprimierten und poly(Silicat) an ihrer Oberfläche synthetisierten, zeigten die gleichen Wachstumsraten wie die Bakterien, die das Gen nicht enthielten. Schlussfolgernd lässt sich sagen, dass die silicateinvermittelte Verkapselung von Bakterien mit poly(Silicat) die Bandbreite der Anwendung von Bakterien für die Produktion von rekombinanten Proteinen verbessern, erweitern und optimieren könnte.

Escherichia coli variants in periprosthetic joint infection: diagnostic challenges with sessile bacteria and sonication

The diagnostic yield of prosthetic joint-associated infection is hampered by the phenotypic change of bacteria into a sessile and resistant form, also called biofilm. With sonication, adherent bacteria can be dislodged from the prosthesis. Species identification may be difficult because of their variations in phenotypic appearance and biochemical reaction. We have studied the phenotypic, genotypic, and biochemical properties of Escherichia coli variants isolated from a periprosthetic joint infection. The strains were collected from synovial fluid, periprosthetic tissue, and fluid from the explanted and sonicated prosthesis. Isolates from synovial fluid revealed a normal phenotype, whereas a few variants from periprosthetic tissue and all isolates from sonication fluid showed different morphological features (including small-colony variants). All isolates from sonication fluid were beta-galactosidase negative and nonmotile; most were indole negative. Because of further variations in biochemical properties, species identification was false or not possible in 50% of the isolates included in this study. In contrast to normal phenotypes, variants were resistant to aminoglycosides. Typing of the isolates using pulsed-field gel electrophoresis yielded nonidentical banding patterns, but all strains were assigned to the same clonal origin when compared with 207 unrelated E. coli isolates. The bacteria were repeatedly passaged on culture media and reanalyzed. Thereafter, most variants reverted to normal phenotype and regained their motility and certain biochemical properties. In addition, some variants displayed aminoglycoside susceptibility after reversion. Sonication of an explanted prosthesis allows insight into the lifestyle of bacteria in biofilms. Since sonication fluid also reveals dislodged sessile forms, species identification of such variants may be misleading.

Crystallization of Escherichia coli Catabolite Gene Activator Protein with its DNA Binding Site: The use of Modular DNA

To obtain crystals of the Escherichia coli catabolite gene activator protein (CAP) complexed with its DNA-binding site, we have searched for crystallization conditions with 26 different DNA segments ≥28 base-pairs in length that explore a variety of nucleotide sequences, lengths, and extended 5′ or 3′ termini. In addition to utilizing uninterrupted asymmetric lac site sequences, we devised a novel approach of synthesizing half-sites that allowed us to efficiently generate symmetric DNA segments with a wide variety of extended termini and lengths in the large size range (≥28 bp) required by this protein. We report three crystal forms that are suitable for X-ray analysis, one of which (crystal form III) gives measurable diffraction amplitudes to 3 Å resolution. Additives such as calcium, n-octyl-β-d-glucopyranoside and spermine produce modest improvements in the quality of diffraction from crystal form III. Adequate stabilization of crystal form III is unexpectedly complex, requiring a greater than tenfold reduction in the salt concentration followed by addition of 2-methyl-2,4-pentanediol and then an increase in the concentration of polyethylene glycol.

The copper-inducible ComR (YcfQ) repressor regulates expression of ComC (YcfR), which affects copper permeability of the outer membrane of Escherichia coli

The pathway of copper entry into Escherichia coli is still unknown. In an attempt to shed light on this process, a lux-based biosensor was utilized to monitor intracellular copper levels in situ. From a transposon-mutagenized library, strains were selected in which copper entry into cells was reduced, apparent as clones with reduced luminescence when grown in the presence of copper (low-glowers). One low-glower had a transposon insertion in the comR gene, which encodes a TetR-like transcriptional regulator. The mutant strain could be complemented by the comR gene on a plasmid, restoring luminescence to wild-type levels. ComR did not regulate its own expression, but was required for copper-induction of the neighboring, divergently transcribed comC gene, as shown by real-time quantitative PCR and with a promoter-lux fusion. The purified ComR regulator bound to the promoter region of the comC gene in vitro and was released by copper. By membrane fractionation, ComC was shown to be localized in the outer membrane. When grown in the presence of copper, ∆comC cells had higher periplasmic and cytoplasmic copper levels, compared to the wild-type, as assessed by the activation of the periplasmic CusRS sensor and the cytoplasmic CueR sensor, respectively. Thus, ComC is an outer membrane protein which lowers the permeability of the outer membrane to copper. The expression of ComC is controlled by ComR, a novel, TetR-like copper-responsive repressor.

Structure and function of the glucose PTS transporter from Escherichia coli

The glucose transporter IICB of the Escherichia coli phosphotransferase system (PTS) consists of a polytopic membrane domain (IIC) responsible for substrate transport and a hydrophilic C-terminal domain (IIB) responsible for substrate phosphorylation. We have overexpressed and purified a triple mutant of IIC (mut-IIC), which had recently been shown to be suitable for crystallization purposes. Mut-IIC was homodimeric as determined by blue native-PAGE and gel-filtration, and had an eyeglasses-like structure as shown by negative-stain transmission electron microscopy (TEM) and single particle analysis. Glucose binding and transport by mut-IIC, mut-IICB and wildtype-IICB were compared with scintillation proximity and in vivo transport assays. Binding was reduced and transport was impaired by the triple mutation. The scintillation proximity assay allowed determination of substrate binding, affinity and specificity of wildtype-IICB by a direct method. 2D crystallization of mut-IIC yielded highly-ordered tubular crystals and made possible the calculation of a projection structure at 12Å resolution by negative-stain TEM. Immunogold labeling TEM revealed the sidedness of the tubular crystals, and high-resolution atomic force microscopy the surface structure of mut-IIC. This work presents the structure of a glucose PTS transporter at the highest resolution achieved so far and sets the basis for future structural studies.

Nitroreductase (GlNR1) increases susceptibility of Giardia lamblia and Escherichia coli to nitro drugs

OBJECTIVES: The protozoan parasite Giardia lamblia causes the intestinal disease giardiasis, which may lead to acute and chronic diarrhoea in humans and various animal species. For treatment of this disease, several drugs such as the benzimidazole albendazole, the nitroimidazole metronidazole and the nitrothiazolide nitazoxanide are currently in use. Previously, a G. lamblia nitroreductase 1 (GlNR1) was identified as a nitazoxanide-binding protein. The aim of the present project was to elucidate the role of this enzyme in the mode of action of the nitro drugs nitazoxanide and metronidazole. METHODS: Recombinant GlNR1 was overexpressed in both G. lamblia and Escherichia coli (strain BL21). The susceptibility of the transfected bacterial and giardial cell lines to nitazoxanide and metronidazole was analysed. RESULTS: G. lamblia trophozoites overexpressing GlNR1 had a higher susceptibility to both nitro drugs. E. coli were fully resistant to nitazoxanide under both aerobic and semi-aerobic growth conditions. When grown semi-aerobically, bacteria overexpressing GlNR1 became susceptible to nitazoxanide. CONCLUSIONS: These findings suggest that GlNR1 activates nitro drugs via reduction yielding a cytotoxic product.