Biochemical and genetic approaches for the characterization of Bdellovibrionaceae, unique predatory bacteria

Schwudke, Dominik

16 December 2003

Bdellovibrionaceae sind außergewöhnliche Bakterien, da sie als die kleinsten bekannten räuberischen Organismen gelten. Seit ihrer Entdeckung in Bodenproben im Jahr 1962 durch Stolp und Starr konnte eine weite Verbreitung in der Natur nachgewiesen werden. Besonderes Interesse erlangten Bdellovibrionaceae durch ihre Fähigkeit bakterielle Erreger wie Escherichia coli, Salmonella und Yersinia zu attackieren. Der bestuntersuchte Vertreter der Familie Bdellovibrionaceae ist Bdellovibrio bacteriovorus. Er durchläuft einen komplexen Lebenszyklus, der nur partiell verstanden ist. In der Attack-Phase werden durch einen noch nicht aufgeklärten Mechanismus potentielle Beutebakterien erkannt und der interzelluläre Kontakt hergestellt. Nachdem eine Pore in der Zellwand der ausschließlich Gram-negativen Beutebakterien erzeugt wurde, dringt B. bacteriovorus in den periplasmatischen Raum ein. Nach etwa 30 Minuten ist der Invasionsprozess abgeschlossen und man kann die Ausbildung sphärischer Bdelloblasten beobachten. Im Beutebakterium verdaut B. bacteriovorus makromolekulare Bestandteile des Wirtes und wächst zu einem langen spiralförmigen Stäbchen aus. Es setzt schließlich die Zellteilung ein bei der 5 bis 30 Tochterzellen in Abhängigkeit zur Größe des Beutebakteriums freiwerden. Mit der Reproduktion ist der parasitäre Lebenszyklus nach etwa 3 Stunden beendet. Die komplexe Regulation der Expression von Proteinen konnte für die einzelnen Wachstumsphasen durch ein- sowie zweidimensionale Gelelektrophorese nachgewiesen werden. In der Vergangenheit haben verschiedene Studien die Komplexität der Wechselwirkung mit den Beutebakterien belegt. Hierbei wurde, neben dem offensichtlichen Abbau makromolekularer Bestandteile der Beutebakterien, ein Recycling und Einbau von Membranbestandteilen wie Lipopolysacchariden (LPS) und Outer Membrane Proteine (OmP) in das Membransystem von B. bacteriovorus diskutiert. Die biologische Interpretation dieses Phänomens ist eine erhöhte Effizienz in der Reproduktion von B. bacteriovorus wenn es Bestandteile des Wirtsbakteriums wiederverwertet im Gegensatz zur Eigensynthese. Trotz der morphologischen Ähnlichkeit und des ungewöhnlichen Lebensstils wurde festgestellt, dass die Familie der Bdellovibrionaceae phylogenetisch sehr heterogen ist. Es werden zur Zeit zwei Gattungen unterschieden Bdellovibrio und Bacteriovorax. Aufgrund von 16S rRNA Untersuchungen konnten auch innerhalb der Gattungen eine Vielzahl von phylogenetisch distinkten Arten nachgewiesen werden. In der Literatur wird eine regulierende Wirkung auf pathogene Gram-negative Bakterien für aquatische Systeme durch Bdellovibrionaceae beschrieben. Weiterhin konnten sie bei verschiedenen Nutztieren im Verdauungstrakt mikrobiologisch nachgewiesen werden. Ein positiver Einfluss auf die Gesundheit der Tiere wurde bei Vorkommen von B. bacteriovorus festgestellt. Für eine Charakterisierung von Umweltisolaten werden in der vorliegenden Arbeit genetische Methoden vorgestellt. Hierfür wurden Hybridisierungsmethoden und PCR-methoden entwickelt, die es ermöglichen aus der Umwelt isolierte Bdellovibrionaceae phylogenetisch einzuordnen. Es konnte gezeigt werden, das sowohl B. bacteriovorus als auch Bacteriovorax stolpii im Verdauungstrakt von Nutztieren vorkommen. Es ist weiterhin gelungen eine PCR-methode für Kotproben zu entwickeln, die einen direkten Nachweis ermöglicht ohne mikrobiologische Anzucht. B. bacteriovorus ist ein Gram-negatives Bakterium, allein dieser Sachverhalt spiegelt die Schwierigkeit wider, wenn der enzymattische Abbau von Zellwandbestandteilen der Beutebakterien Ziel der Untersuchung ist, da auch die Beutebakterien Gram-negativ sind. Es ergibt sich aufgrund eines ähnlichen Zellwandaufbaus ein immenses analytisches Problem die makromolekularen Bestandteile von Wirtsbakterium und Jäger zu trennen. Um dem Lebensstil angepasst Modifikationen von B. bacteriovorus zu untersuchen, wurde in dieser Arbeit LPS, charakteristischer Bestandteil der Äußeren Membran, von Wildtypstamm B. bacteriovorus HD100 und seiner wirtsunabhängigen Mutante HI100 isoliert und das Lipid A strukturell aufgeklärt. Die Isolation gelang durch die Ausnutzung unterschiedlicher Fällungseigenschaften des LPS von B. bacteriovorus HD100 gegenüber des E. coli K-12 LPS aus dem Extraktionsmittel. Weiterhin konnte nachgewiesen werden, das B. bacteriovorus S-Form LPS besitzt. Die außergewöhnliche Struktur des Lipid A von B. bacteriovorus wurde im Detail mit massenspektrometrischen Methoden, ein- und zweidimensionalen NMR Methoden sowie mikrochemischer Methoden in Kombination mit der GC/MS charakterisiert. Der Fettsäureanker besteht aus a-D-ManpII-(1(R)4)-ß-D-GlcpN3NII-(1(R)6)-ß-D-GlcpN3NI-(1(R)1)-a-D-ManpI. Dies stellt eine neuartige Struktur dar, da an allen bisher bekannten Lipid A´s sich Brönstedtsäuren am hydrophilen Fettsäureanker befinden, die in physiologischer Lösung durch Protonenabgabe negative Ladungen tragen. Im Lipid A von B. bacteriovorus sind diese Substituenten durch den Neutralzucker Mannose ersetzt. Weiterhin wurden als Fettsäuren nur 3-Hydroxyfettsäuren nachgewiesen, wobei sich auf die 6 gebunden Fettsäuren etwa 1,5 Doppelbindungen verteilen. Dieses Lipid A zeigt eine wesentlich reduzierte endotoxische Aktivität im Vergleich zu E. coli Lipid A und weist als biophysikalische Besonderheit eine erhöhte Fluidität über einen weiten Temperaturbereich auf. Die vorgestellte 16S rRNA Analyse und die Strukturanalyse des Lipid A von B. bacteriovorus belegen seine besondere Stellung in der Welt der Bakterien. / Bdellovibrionaceae are extraordinary bacteria known as the smallest predatory organism so far. Since their discovery in soil samples by Stolp and Starr 1963 they have been detected in a wide range of other natural habitats. Bdellovibrionaceae became the focus of attention concerning their ability to attack pathogens like Escherichia coli, Salmonella and Yersinia. For Bdellovibrio bacteriovorus the most detailed studies are available. The up to now only partially understood lifecycle consists of several complex phases. In the attack phase B. bacteriovorus is motile possessing flagella and the preys are recognized by an unknown mechanism. After attachment on the cell wall within 15 to 30 minutes a pore is formed which is used as entrance to the periplasmatic space of the Gram-negative prey bacteria. The completion of the invasion process can be observed by the change of the prey s shape to spherical bdelloblasts. Inside of the prey B. bacteriovorus degrades macromolecular compounds and transforms into a long spirally shaped rod. At the end of the lifecycle the rod divides yielding 5 up to 30 daughter cells depending on the size of the prey bacteria. This reproduction phase is completed within 3 hours. The complex regulation of expression of a certain number of proteins was observed by one and two dimensional gelelectrophoresis. The complexity of the interaction between predator and prey were examined in several studies. Besides the obvious degradation of macromolecular compounds of the prey, reutilising of lipopolysaccharides (LPS) and Outer Membrane Proteins (OmP) into the membrane system of B. bacteriovorus was discussed. The biological interpretation of such behaviour was that it is more efficient for reproduction to recycle components of the prey than to perform de novo synthesis. Unexpectedly, despite the unique predatory lifecycle and common morphological features, Bdellovibrionaceae show a great phylogenetical diversity based on 16S rRNA analyses. Bdellovibrionaceae are divided into the three species Bdellovibrio bacteriovorus, Bacteriovorax stolpii, Bacteriovorax starrii and some strains yet to be assigned. In two studies Bdellovibrionaceae were found as part of regulation processes for decreasing the number of pathogenic Gram-negative bacteria in aquatic systems. Furthermore, B. bacteriovorus were found in the intestinal tract of several domestic animals showing a positive influence on the state of health. For the phylogenetic characterization of environmental isolates techniques were developed based on hybridisation methods and the PCR. In this work we detected B. bacteriovorus and B. stolpii strains in the gut of animals. Furthermore, a PCR method for direct detection of Bdellovibrionaceae in fecal samples was developed. B. bacteriovorus are Gram-negative bacteria. This fact complicates the study of the degradation of the prey s cell wall as it possesses the architecture of Gram-negative bacteria also. Furthermore, the search for important modifications of the cell wall of B. bacteriovorus concerning the predatory lifestyle becomes an analytical problem. In this study we isolated LPS of the wild type strain B. bacteriovorus HD100 and its host independent mutant strain HI100. For the isolation of pure B. bacteriovorus HD100 S-form LPS we took advantage of different precipitation properties in the extraction solvent of E. coli K-12 LPS and the predator s LPS. The structure of the lipid A was examined in detail by mass spectrometric methods, one- and two-dimensional NMR and chemical analytical techniques. The novel structure consists of backbone built of a-D-ManpII-(1(R)4)-ß-D-GlcpN3NII-(1(R)6)-ß-D-GlcpN3NI-(1(R)1)-a-D-ManpI. This is the first known natural lipid A without negatively charged substituents in physiological solution. The lipid A of B. bacteriovorus carries the neutral sugar mannose instead of Brönstedt acids. Furthermore, the lipid A exclusively consists of 3-hydroxy fatty acids with approximately 1.5 double bounds distributed on six bounded fatty acids. This lipid A shows a significant decreased endotoxic activity in comparison to E. coli lipid A and revealed increased fluidity over broad temperature range as further remarkable biophysical property. The 16S rRNA analysis and the structural analysis of the lipid A of B. bacteriovorus document the unique position in the world of bacteria.

Lipopolysaccharid

Massenspektrometrie

Bdellovibrionaceae

Phylogenetische Analyse

Mass spectrometry

Bdellovibrionaceae

Lipopolysaccharides (LPS)

Phylogenetic analysis

540 Chemie

30 Chemie

ddc:540

Endotoxin Peptide/Protein Interactions: Thermodynamic And Kinetic Analysis

Thomas, Celestine J

11 1900

Endotoxin or Lipopolysaccharide (LPS) is the invariant structural component of gram negative bacterial outer membranes and is the chief causative factor of Sepsis or endotoxic shock. Sepsis is a syndrome that has very high mortality rates even in this age of excellent therapeutics and critical patient care. The treatment for sepsis till date remains nonspecific and supportive due to lack of effective anti-endotoxic drugs. Sepsis is initiated when the circulating bacteria shed LPS from their cell envelopes. Shed LPS aggregates are recognized by LPS binding proteins and receptors, which activate the host's immune system. Uncontrolled and excessive stimulation of the host's immune system precipitates endotoxic shock which in advanced cases involving multiple system organ failure inevitably lead to patient's death. Many strategies have been tested out to combat this deadly affliction. One of the attractive clinical modalities in sepsis treatment is the use of peptides as LPS sequestering anti-endotoxic drugs. A classical peptide antibiotic of this class is Polymyxin B (PMB) a cyclic cationic acylated molecule, that recognizes LPS with a very high affinity. This thesis describes kinetics and thermodynamics of PMB-LPS interactions and applies these parameters over a framework of different models so as to gain insights into the structure-function relationships that govern the interactions of this peptide with endotoxin(s). Classical biophysical techniques like fluorescence, circular dichroism spectroscopy, stopped flow kinetics, titration calorirnetry (ITC) and the relatively new technique of Surface Plasmon Resonance (SPR) have been employed to dissect out the mechanism of the range of non-covalent forces that are involved in peptide-endotoxin recognition. Certain proteins that exhibit LPS binding activity have also been studied to gains insight about their mode of action. Implications of these studies for designing peptides that have better anti-endotoxic properties are also highlighted. The first chapter introduces and highlights the clinical features of sepsis. It also attempts to shed light on the LPS mediated signal transduction pathway that leads to endotoxic shock. This chapter also briefly explains the roles of many LPS receptors that are present in the human system and their specific roles in the signal transduction pathways. The second part of this chapter deals with the role of cationic peptides as anti-endotoxic drugs. Certain key functional aspects of these peptides, which impart in them, the desirable property of LPS recognition have also been discussed The second chapter describes the kinetic studies undertaken to unravel the exact mechanism of LPS-PMB interaction. The studies reveal that PMB recognizes LPS in a biphasic manner, with the second, unimolecular isomerization step of the reaction being the rate-limiting step. The initial reaction is shown to be influenced by the presence of salt in the reaction medium. The dissociation phase of this interaction also shows a biphasic pattern. These data allow us to speculate upon the exact mechanism by which PMB is able to recognize LPS. The studies also shed light on some structural aspects that govern and confer such high LPS binding activity to PMB. Based on these a model has been proposed to explain this recognition (C.J. Thomas et al, 1998). The second chapter discuses the mode of action of various PMB analogs. These analogs have been chosen in terms of their mode of action as well as their structural similarly to PMB. The affinities of these analogs to LPS and lipid A were quantified using the Surface plasmon resonance (SPR) method. SPR, a technique that relies on the quantification of change in mass during a binary binding process occurring between an immobilized entity and a flowing ligand, is a rapid and sensitive method to measure biologically relevant interactions. SPR studies provide us with the binding constants and thermodynamic parameters that allow evaluation of the affinities of these peptides towards LPS (C.J.Thomas and A.Surolia, 1999). The third chapter discusses a hitherto unknown mode by which PMB acts on a LPS lamellae. The results of this study wherein the binding affinities of PMB and its analogs were performed on monolayers and tethered liposomes, show that PMB is able to remove specifically LPS or lipid A from monolayers or bilayer assemblies such as tethered liposomes. The exact mode of action of PMB is deciphered in the light of these new studies, which allow us to posit on the observed efficacy of PMB in neutralizing the endotoxin as compared to peptides with nearly similar affinities for LPS (C.J Thomas et al 1999). In the fourth chapter a series of 23 residue peptides, based on the sequence corresponding to the anti-sense strand of magainin gene have been synthesized. Magainin an amphiphilic helical peptide obtained from frog skins plays a vital role in the innate immune defense mechanisms of these organisms. It also exhibits LPS binding activity that makes it an attractive target as an anti-endotoxic drug. Biochemical and biophysical characterization of these peptides reveal that they have the tendency to perturb both the inner and the outer membranes of E.coli. The peptides are amphiphilic and have helical structure in a membrane bound environment. Three of the peptides tested have high affinities for lipid A that approach the values shown by PMB. The kinetic parameters obtained by stopped flow and SPR studies in conjunction with the therrnodynamic parameters obtained using ITC studies allow us to highlight the key structural features that need to be exhibited by peptides that are designed to be LPS recognizers. The studies also project the fact that ionic forces play an important role in the initial recognition of LPS by these peptides. Fortification of the might of these ionic charges increases affinity for LPS where as the hydrophobic residues that interact at the next phase of binding are more amenable to disruptions in contiguity. These factors are discussed using the helical wheel diagram that shows the clear amphiphilicity displayed by these peptides. (C.J Thomas et al Manuscript under preparation, 2000) Chapter six discusses the mode of action of certain LPS binding proteins. Limulus anti endotoxic factor (LALF) plays a vital role in the innate immune based defense systems of the horseshoe crab. Galectin-3 is a metal ion independent, galactosc binding Icctin of human origin with unknown functions. Both these phylogcntically-unrclatcd proteins exhibit LPS/lipid A recognizing properties. ITC and SPR studies have been used to determine the binding constants displayed by these proteins for lipid A. LALF bind to lipid A with very high affinity than compared to Galectin-3 and is also able to take away selectively lipid A from both monolayers and tethered liposomes. Galectin-3 does not show this property of LALF, which might account for its lowered affinities. Also structurally LALF has amphiphilic nature that confers high lipid A binding activity, which is clearly lacking in Galectin-3. These studies in conjunction with the knowledge gained from the study of LPS-PMB interaction stress on the importance of amphiphilicity in LPS recognition. (C.J Thomas et al Manuscript under preparation, 2000). The final chapter is a general discussion that attempts to collate all these kinetic and thermodynamic observations in the pursuit of designing small easily manipulatable peptides that exhibit high LPS binding activity. These studies are aimed to act as rough guidelines to the design of LPS sequestering peptides that might have better therapeutic and pharmacokinetic properties. The appendix to the main body of work presented in thesis are two pieces of work pertaining to the elucidation the kinetics and mechanism of sugar lectin interactions, when sugars are presented as glycolipids in monolayers or bilaycrs liposomes. Mode of the presentation of sugars at cell-surfaces in the form of glycolipids as ligands influence their recognition by macromolecular receptors like lectins. Appendix 1 is a study of the mode of action of Ulex europeus I lectin binding to H-fucolipid containing tethered liposomes, by SPR. Fucosylated sugars are often used as key markers in histochemical analysis of malignant cancerous tissues. Ulex lectin plays a vital role as a marker for identification of these tissues. The kinetics and thermodynamic parameters that are obtained in this study throw some light on the mode of recognition of glycolipid receptor by Ulex europeus I lectin (C.J Thomas and A. Surolia 2000). Appendix 2 is a study, that attempts to quantify the initial kinetic parameters that correlate the recognition of glycolipid receptors with their inclination at the membrane surface and the influence of charge on them by soyabean agglutinin (SBA), Abrus agglutinin I and II. Studies on the soyabean agglutinin-globoside interaction highlights the divalent cation mediated reorientation of these receptors on their accessibility and recognition to the agglutinin. The divalent cations are speculated to orient the oligosaccharide head groups in a spatial geometry that allows a heightened kinetics of their interaction by SBA. These studies reveal that the reorganization of the binding pocket of a lectin can also have a profound influence on ihc rates of recognition of a glycospingolipid ligand by a lectin as exemplified by Abrus agglutinin II- GM1 interactions (C.J Thomas ct al, Manuscript under preparation).

Biochemistry

Gram negative Bacterial Infection

Bacterial Immunity

Lipopolysaccharides (LPS)

Polymyxin B (PMB)

Sepsis

LPS Receptors

Surface Plasmon Resonance (SPR)

Peptide Antibiotics

Anti-endotoxic Drugs

Endotoxic Shock

Endotoxin

Ulex Lectin

Agglutinin