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Bacterial functional membrane microdomains (FMMs) are membrane platforms that resemble lipid rafts of eukaryotic cells in certain functional and structural aspects. Lipid rafts are nanometer-sized, dynamic clusters of proteins and lipids in eukaryotic cell membranes that serve as signaling hubs and assembling platforms. Yet, studying these structures can often be hampered by the complexity of a eukaryotic cell. Thus, the analogous structures of prokaryotes are an attractive model to study molecular traits of this type of membrane organization.
Similar to eukaryotic lipid rafts, the bacterial FMMs are comprised of polyisoprenoid lipids, scaffold proteins and a distinct set of membrane proteins, involved in signaling or secretion. Investigating bacterial FMMs not only contributes to the understanding of the physiological importance of FMMs in bacteria, but also helps to elucidate general principles of rafts beyond prokaryotes.
In this work, a bacterial model organism was used to investigate effects of synthetic overproduction of the raft scaffolding proteins on bacterial physiology. This overexpression causes an unusual stabilization of the FMM-harbored protease FtsH and therefore the proteolytic targets of FtsH are not correctly regulated. Developmental defects and aberrances in shape are the consequence, which in turn negatively affects cell physiology. These findings may be adapted to better understand lipid raft processes in humans, where flotillin upregulation is detected along with development of neurological diseases.
Moreover, it was aimed at understanding the FMM-proteome of the human pathogen Staphylococcus aureus. An in-depth quantitative mass-spectrometry analysis reveals adaption of the protein cargo during different conditions, while maintaining a distinct set of core FMM proteins. As a case study, the assembly of the type VII secretion system was shown to be dependent on FMM integrity and more specifically on the activity of the FMM-scaffold flotillin. This secretion system is important for the virulence of this pathogen and its secretion efficiency can be targeted by small molecules that inhibit flotillin activity. This opens new venues for non-conventional antimicrobial compounds to treat staphylococcal infections.
In der vorgelegten Promotionsarbeit wurden die typischen bakteriellen MSSA bzw. MRSA Hautinfektionen einer dermatologischen Klinik mit dem Einzugsgebiet Nordbayern auf krankheitsrelevante Faktoren von PVL untersucht.
Interessanterweise fand sich bei der Präsenz von PVL keine Korrelation mit Methicillinresistenz oder Krankheitsschwere. Weder atopische Diathese noch Rauchen oder Körpergewicht scheinen das Auftreten des Pathogenitätsfaktors zu begünstigen. Allerdings traten die PVL positiven S. aureus Hautinfektionen bevorzugt bei jüngeren und weiblichen Patienten auf. Bei den untersuchten Hauterkrankungen zeigten S. aureus Stämme eine ausgeprägte Vielfalt. Es konnte kein spezieller epidemiologischer Stamm identifiziert werden.
Die Ergebnisse dieser Studie sind jedoch nur eingeschränkt auf ein großes Kollektiv projizierbar, da der Untersuchungszeitraum insgesamt nur 7 Jahre betrug und sich das Patientenkollektiv auf das Einzugsgebiet des Klinikums beschränkte.
Staphylococcus aureus is a versatile human pathogen that normally develops acute or chronic infections. The broad range of diseases caused by this bacterium facilitates the escape from the host's immune response as well as from target-specific antimicrobial therapies. Nevertheless, the underlying cellular and molecular mechanisms that enable S. aureus to cause these disparate types of infections are largely unknown. In this work, we depicted a novel genetic program involved in the development of cell-fate decision, which promotes the differentiation of the staphylococcal cells into two genetically identical but differently heritable cell lines capable of defining the course of an infection, by simultaneously progressing to (i) a biofilm-associated chronic infection or (ii) a disperse acute bacteremia. Here, S. aureus growing in architecturally complex multicellular communities harbored different cell types that followed an exclusive developmental plan, resulting in a clonal heterogeneous population. We found that these cell types are physiologically specialized and that, this specialization impacts the collective behavior within the multicellular aggregates. Whereas one cell line that we named BRcells, promotes biofilm formation that engenders chronic infections, the second cell line, which we termed DRcells is planktonic and synthetizes virulence factors, such as toxins that can drive acute bacteremia. We identified that the positive feedback loop present in Agr quorum sensing system of S. aureus acts a bimodal switch able to antagonistically control the divergence of these two physiologically distinct, heritable cell lines. Also, we found that this bimodal switch was triggered in response to environmental signals particularly extracellular Mg2+, affecting the size of the subpopulations in specific colonization environments. Specifically, Mg2+-enriched environments enhanced the binding of this cation to the staphylococcal teichoic acids, increasing the rigidity of the cell wall and triggering a genetic program involving the alternative sigma factor σB that downregulated the Agr bimodal switch, favoring the enrichment of the BRcells type. Therefore, colonization environments with different Mg2+ content favored different outcomes in the bimodal system, defining distinct ratio in the BRcells/DRcells subpopulations and the S. aureus outcome in our in vitro model of development of multicellular aggregates and, the infection outcome in an in vivo mice infection model. In this prime human pathogen cell-fate decision-making generates a conserved pattern of heritable, physiological heterogeneity that actively contributes to determine the course of an infection through the emergence and spatio-temporal dynamics of distinct and specialized cell types. In conclusion, this work demonstrates that cell differentiation in pathogenic bacteria is a fundamental phenomenon and its understanding, is central to understand nosocomial infections and to designing new anti-infective strategies
Staphylococcus aureus ist ein grampositives Bakterium, welches häufig als kommensaler Besiedler auf der Nasen- und Rachenschleimhaut von Säugetieren vorkommt. Darüber hinaus besitzt dieser fakultativ pathogene Mikroorganismus die Fähigkeit schwer zu behandelnde Krankenhausinfektionen auszulösen. Aufgrund der weiten Verbreitung von Antibiotikaresistenzen und dem Mangel an effektiven Therapien, verursachen S. aureus Infektionen jährlich enorme Kosten für das Gesundheitssystem. S. aureus wird meist von der Nase zum primären Infektionsort übertragen, wodurch zunächst sehr häufig Wund- und Weichteilinfektionen hervor gerufen werden. Von diesem primären Infektionsort ausgehend, kann der Erreger tiefer liegende Gewebsschichten infizieren oder sich über den Blutstrom im gesamten Organismus ausbreiten. Das Spektrum an Krankheitsbildern reicht von leichten Abszessen der Haut bis zu schweren, lebensbedrohlichen Erkrankungen wie Pneumonien und akuter Sepsis.
Für die erfolgreiche Kolonisierung und Infektion des Wirtes exprimiert S. aureus eine Vielzahl unterschiedlicher Virulenzfaktoren. Die wohl größte Gruppe an Virulenzfaktoren umfasst die Proteine, die an der Immunevasion und der Umgehung von verschiedenen Abwehrstrategien des Immunsystems beteiligt sind. Das bisherige Wissen über die Interaktion von S. aureus mit dem Immunsystem des Wirtes und die zugrunde liegenden Pathogenitätsmechanismen ist bisher limitiert.
Um neue Erkenntnisse über die Interaktion von Wirt und Pathogen zu erlangen, wurden im Rahmen dieser Arbeit bislang unbekannte sekretierte und Oberflächen-assoziierte Proteine von S. aureus funktionell charakterisiert. Die Funktion der ausgewählten Proteine wurde in vitro hinsichtlich Einfluss auf Komponenten des Immunsystems, Adhäsion an Wirtsfaktoren und Invasion in eukaryotische Zellen untersucht.
Mit Hilfe der vorangegangenen in-vitro-Charakterisierung der putativen Virulenzfaktoren, konnte für die cytoplasmatische Adenylosuccinat-Synthase PurA eine neuartige Funktion identifiziert werden. PurA ist bekannt als essentielles Enzym der de novo Purin-Synthese. In dieser Arbeit wurde nun gezeigt, dass PurA zudem an der Immunevasion beteiligt ist. Durch die Bindung des humanen Faktor H des Komplementsystems schützt PurA S. aureus vor der lytischen Aktivität des Komplementsystems und verhindert die Opsonisierung des Pathogens. Basierend auf diesen Ergebnissen wurde PurA detailliert charakterisiert. In Bindungsstudien mit rekombinantem Faktor H und PurA wurde eine direkte Interaktion beider Proteine nachgewiesen, wobei Faktor H mit dem N-terminalen Bereich von PurA interagiert. Weiterhin konnte PurA durch Immunfluoreszenz und FACS-Analysen auf der Zelloberfläche nachgewiesen werden, wo es wahrscheinlich mit der Zellwand assoziiert vorliegt. Dort rekrutiert es Faktor H an die bakterielle Oberfläche und verhindert das Fortschreiten der Komplement-Kaskade und damit die Lyse des Pathogens. Aufgrund der Multifunktionalität zählt PurA somit zur Gruppe der Moonlighting Proteine.
Des Weiteren wurde die Rolle von PurA im Infektionsgeschehen in zwei unabhängigen Tiermodellen untersucht. In beiden Modellen wurde ein signifikant reduziertes Virulenzpotential der ΔpurA-Mutante beobachtet. Zukünftig soll geklärt werden, ob die verminderte Virulenz in der fehlenden Komplementevasion oder im Defekt in der Purin-Synthese begründet ist. Aufgrund der sehr starken Attenuation in allen untersuchten Infektionsmodellen sollte PurA als potentielles Target für eine Therapie von S. aureus Infektionen weiter charakterisiert werden. Im Ergebnis dieser Arbeit wurde demnach mit PurA ein neues Moonlighting Protein identifiziert, das als Inhibitor des Komplementsystems wesentlich zur Immunevasion von S. aureus beiträgt.
Für das bessere Verständnis der humoralen S. aureus-spezifischen Immunantwort, Unterschieden in der Antikörperantwort und der gebildeten Antikörperspezifitäten wurde weiterhin das während der Kolonisierung und Infektion gebildete S. aureus-spezifische Antikörperprofil untersucht. Dazu wurden Plasmen von humanen nasalen Trägern und Nicht-Trägern sowie murine Seren von infizierten Tieren untersucht. Insbesondere wurde das Pathogen-spezifische Antikörperprofil in unterschiedlichen Infektionsmodellen mit Hilfe eines Proteinarrays analysiert, der im Rahmen dieser Arbeit in einer Kooperation mit der Firma Alere Technologies (Jena, Deutschland) und universitären Forschergruppen der Universitäten Greifswald, Münster und Jena mitentwickelt wurde. Die Antikörperprofile von intramuskulär und intravenös infizierten Tieren resultierten in jeweils spezifischen Antikörperprofilen. Diese Ergebnisse deuten auf einen Zusammenhang zwischen der Art der Infektion und der gebildeten Antikörperspezifitäten hin. Wahrscheinlich beruht dies auf einer gewebespezifischen Genexpression als Anpassung an die individuellen Bedürfnisse im Wirtsorganismus. Das ausgebildete Antikörperprofil gibt somit einen Einblick in das Expressionsmuster von Virulenzfaktoren von S. aureus unter in vivo Bedingungen und trägt damit zum Verständnis der komplexen Interaktion von Pathogen und Wirt bei. Diese Untersuchungen ergänzen zudem die bisherigen Kenntnisse über die Anpassung der humoralen Immunantwort an eine asymptomatische Kolonisierung im Gegensatz zu einer akuten Infektion durch S. aureus. Darüber hinaus können die gewonnenen Ergebnisse für diagnostische Zwecke und zur Identifikation von neuen Zielstrukturen für eine Vakzin-Entwicklung genutzt werden.
Staphylococcus aureus asymptomatically colonises one third of the healthy human population, finding its niche in the nose and on skin. Apart from being a commensal, it is also an important opportunistic human pathogen capable of destructing tissue, invading host cells and killing them from within. This eventually contributes to severe hospital- and community-acquired infections. Methicillin-resistant Staphylococcus aureus (MRSA), resistant to commonly used antibiotics are protected when residing within the host cell.
This doctoral thesis is focused on the investigation of staphylococcal factors governing intracellular virulence and subsequent host cell death. To initiate an unbiased approach to conduct this study, complex S. aureus mutant pools were generated using transposon insertional mutagenesis. Genome-wide infection screens were performed using these S. aureus transposon mutant pools in vitro and in vivo, followed by analysis using Transposon insertion site deep sequencing (Tn-seq) technology.
Amongst several other factors, this study identified a novel regulatory system in S. aureus that controls pathogen-induced host cytotoxicity and intra-host survival. The primary components of this system are an AraC-family transcription regulator called Repressor of surface proteins (Rsp) and a virulence associated non-coding RNA, SSR42. Mutants within rsp exhibit enhanced intra-host survival in human epithelial cells and delayed host cytotoxicity. Global gene-expression profiling by RNA-seq demonstrated that Rsp controls the expression of SSR42, several cytotoxins and other bacterial factors directed against the host immune system. Rsp enhances S. aureus toxin response when triggered by hydrogen peroxide, an antimicrobial substance employed by neutrophils to destroy pathogens. Absence of rsp reduces S. aureus-induced neutrophil damage and early lethality during mouse pneumonia, but still permits blood stream infection. Intriguingly, S. aureus lacking rsp exhibited enhanced survival in human macrophages, which hints towards a Trojan horse-like phenomenon and could facilitate dissemination within the host.
Hence, Rsp emerged as a global regulator of bacterial virulence, which has an impact on disease progression with prolonged intra-cellular survival, delayed-lethality but allows disseminated manifestation of disease. Moreover, this study exemplifies the use of genome-wide approaches as useful resources for identifying bacterial factors and deduction of its pathogenesis.
Biofilm formation by Staphylococcus aureus represents a problem in both the medical field and the food industry, because the biofilm structure provides protection to embedded cells and it strongly attaches to surfaces. This circumstance is leading to many research programs seeking new alternatives to control biofilm formation by this pathogen. In this study we show that a potent inhibition of biofilm mass production can be achieved in community-associated methicillin-resistant S. aureus (CA-MRSA) and methicillin-sensitive strains using plant compounds, such as individual constituents (ICs) of essential oils (carvacrol, citral, and (+)-limonene). The Crystal Violet staining technique was used to evaluate biofilm mass formation during 40 h of incubation. Carvacrol is the most effective IC, abrogating biofilm formation in all strains tested, while CA-MRSA was the most sensitive phenotype to any of the ICs tested. Inhibition of planktonic cells by ICs during initial growth stages could partially explain the inhibition of biofilm formation. Overall, our results show the potential of EOs to prevent biofilm formation, especially in strains that exhibit resistance to other antimicrobials. As these compounds are food additives generally recognized as safe, their anti-biofilm properties may lead to important new applications, such as sanitizers, in the food industry or in clinical settings.
Identification of human host cell factors involved in \(Staphylococcus\) \(aureus\) 6850 infection
(2015)
Staphylococcus aureus is both a human commensal and a pathogen. 20%-30% of all individuals are permanently or occasionally carriers of S. aureus without any symptoms. In contrast to this, S. aureus can cause life-threatening diseases e.g. endocarditis, osteomyelitis or sepsis. Here, the increase in antibiotic resistances makes it more and more difficult to treat these infections and hence the number of fatalities rises constantly. Since the pharmaceutical industry has no fundamentally new antibiotics in their pipeline, it is essential to better understand the interplay between S. aureus and the human host cell in order to find new, innovative treatment options.
In this study, a RNA interference based whole genome pool screen was performed to identify human proteins, which play a role during S. aureus infections. Since 1,600 invasion and 2,271 cell death linked factors were enriched at least 2 fold, the big challenge was to filter out the important ones. Here, a STRING pathway analysis proved to be the best option. Subsequently, the identified hits were validated with the help of inhibitors and a second, individualised small interfering RNA-based screen.
In the course of this work two important steps were identified, that are critical for host cell death: the first is bacterial invasion, the second phagosomal escape. The second step is obligatory for intracellular bacterial replication and subsequent host cell death. Invasion in turn is determining for all following events. Accordingly, the effect of the identified factors towards these two crucial steps was determined. Under screening conditions, escape was indirectly measured via intracellular replication. Three inhibitors (JNKII, Methyl-beta-cyclodeytrin, 9-Phenantrol) could be identified for the invasion process. In addition, siRNAs targeted against 16 different genes (including CAPN2, CAPN4 and PIK3CG), could significantly reduce bacterial invasion. Seven siRNAs (FPR2, CAPN4, JUN, LYN, HRAS, AKT1, ITGAM) were able to inhibit intracellular replication significantly. Further studies showed that the IP3 receptor inhibitor 2-APB, the calpain inhibitor calpeptin and the proteasome inhibitor MG-132 are able to prevent phagosomal escape and as a consequence intracellular replication and host cell death.
In this context the role of calpains, calcium, the proteasome and the mitochondrial membrane potential was further investigated in cell culture. Here, an antagonistic behaviour of calpain 1 and 2 during bacterial invasion was observed. Intracellular calcium signalling plays a major role, since its inhibition protects host cells from death. Beside this, the loss of mitochondrial membrane potential is characteristic for S. aureus infection but not responsible for host cell death. The reduction of membrane potential can be significantly diminished by the inhibition of the mitochondrial Na+/Ca2+ exchanger.
All together, this work shows that human host cells massively contribute to different steps in S. aureus infection rather than being simply killed by bacterial pore-forming toxins. Various individual host cell factors were identified, which contribute either to invasion or to phagosomal escape and therefore to S. aureus induced cytotoxicity. Finally, several inhibitors of S. aureus infection were identified. One of them, 2-APB, was already tested in a sepsis mouse model and reduced bacterial load of kidneys.
Thus, this study shows valuable evidence for novel treatment options against S. aureus infections, based on the manipulation of host cell signalling cascades.
The Staphylococcus aureus two component system (TCS) sae governs expression of numerous virulence factors, including Eap (extracellular adherence protein), which in turn among other functions also mediates invasion of host cells. The sae TCS is encoded by the saePQRS operon, with saeS coding for the sensor histidine kinase (SaeS) and saeR encoding the response regulator (SaeR). The saeRS system is preceded by two additional open reading frames (ORFs), saeP and saeQ, which are predicted to encode a lipoprotein (SaeP) and a membrane protein (SaeQ), respectively. Earlier, we have shown that SDS-containing subinhibitory concentrations of biocides (Perform®) and SDS alone activate sae transcription and increase cellular invasiveness in S. aureus strain Newman. The effect is associated with an amino acid exchange in the N-terminus of SaeS (L18P), specific to strain Newman.
In this work, the role of whether the two additional genes, saePQ coding for the accessory proteins SaeP and SaeQ, respectively, are involved in SDS-mediated saeRS was investigated. It could demonstrated that the lack of the SaeP protein resulted in an increased saeRS transcription without SDS stress in both SaeSL/P variants, while the SDS effect was less pronounced on sae and eap expression compared to the Newman wildtype, suggesting that the SaeP protein represses the sae system. Also, SDS-mediated inductions of sae and eap transcription along with enhanced invasion were found to be dependent on presence of the SaeSP variant in Newman wildtype. On the other hand, the study also shows that the saePQ region of the sae operon is required for fully functional two-component system saeRS under normal growth conditions, but it is not involved in SDS-mediated activation of the saeS signaling and sae-target class I gene, eap.
In the second approach, the study investigates whether SDS-induced sae expression and host cell invasion is common among S. aureus strains not carrying the (L18P) point mutation. To demonstrate this strain Newman, its isogenic saeS mutants, and various S. aureus isolates were analysed for sae, eap expression and cellular invasiveness. Among the strains tested, SDS exposure resulted only in an increase of sae transcription, Eap production and cellular invasiveness in strain Newman wild type and MRSA strain ST239-635/93R, the latter without an increase in Eap. Interestingly, the epidemic community-associated MRSA strain, USA300 LAC showed a biphasic response in sae transcription at different growth stages, which, however, was not accompanied by increased invasiveness. All other clinical isolates investigated displayed a decrease of the parameters tested. While in strain Newman the SDS effect was due to the saeSP allele, this was not the case in strain ST239-635/93R and the biphasic USA300 strains. Also, increased invasiveness of ST239-635/93R was found to be independent of Eap production. Furthermore, to investigate the global effect of SDS on sae target gene expression, strain Newman wild-type and Newman ∆sae were treated with SDS and analyzed for their transcription profiles of sae target genes using microarray assays. We could show that subinhibitory concentrations of SDS upregulate and downregulate gene expression of several signaling pathways involved in biosynthetic, metabolic pathways as well as virulence, host cell adherence, stress reponse and many hypothetical proteins.
In summary, the study sheds light on the role of the upstream region saePQ in SDS-mediated saeRS and eap expression during S. aureus SDS stress. Most importantly, the study also shows that subinhibitory SDS concentrations have pronounced strain-dependent effects on sae transcription and subsequent host cell invasion in S. aureus, with the latter likely to be mediated in some strains by other factors than the known invasin Eap and FnBP proteins. Moreover, there seems to exist more than the saeSP-mediated mechanism for SDS-induced sae transcription in clinical S. aureus isolates. These results help to further understand and clarify virulence and pathogenesis mechanisms and their regulation in S. aureus.
Staphylococcus aureus is a prevalent commensal bacterium which represents one of the leading causes in health care-associated bacterial infections worldwide and can cause a variety of different diseases ranging from simple abscesses to severe and life threatening infections including pneumonia, osteomyelitis and sepsis.
In recent times multi-resistant strains have emerged, causing severe problems in nosocomial as well as community-acquired (CA) infection settings, especially in the United States (USA). Therefore S. aureus has been termed as a superbug by the WHO, underlining the severe health risk originating from it. Today, infections in the USA are dominated by S. aureus genotypes which are classified as USA300 and USA400, respectively. Strains of genotype USA300 are responsible for about 70% of the CA infections.
The molecular mechanisms which render S. aureus such an effective pathogen are still not understood in its entirety. For decades S. aureus was thought to be a strictly extracellular pathogen relying on pore-forming toxins like α-hemolysin to damage human cells and tissue. Only recently it has been shown that S. aureus can enter non-professional phagocytes, using adhesins like the fibronectin-binding proteins which mediate an endocytotic uptake into the host cells. The bacteria are consequently localized to endosomes, where the degradation of enclosed bacterial cells through phagosome maturation would eventually occur.
S. aureus can avoid degradation, and translocate to the cellular cytoplasm, where it can replicate. The ability to cause this so-called phagosomal escape has mainly been attributed to a family of amphiphilic peptides called phenol soluble modulins (PSMs), but as studies have shown, they are not sufficient.
In this work I used a transposon mutant library in combination with automated fluorescence microscopy to screen for genes involved in the phagosomal escape process and intracellular survival of S. aureus. I thereby identified a number of genes, including a non-ribosomal peptide synthetase (NRPS). The NRPS, encoded by the genes ausA and ausB, produces two types of small peptides, phevalin and tyrvalin. Mutations in the ausAB genes lead to a drastic decrease in phagosomal escape rates in epithelial cells, which were readily restored by genetic complementation in trans as well as by supplementation of synthetic phevalin. In leukocytes, phevalin interferes with calcium fluxes and activation of neutrophils and promotes cytotoxicity of intracellular bacteria in both, macrophages and neutrophils. Further ausAB is involved in survival and virulence of the bacterium during mouse lung pneumoniae.
The here presented data demonstrates the contribution of the bacterial cyclic dipeptide phevalin to S. aureus virulence and suggests, that phevalin directly acts on a host cell target to promote cytotoxicity of intracellular bacteria.
The present work illustrates the structural and biochemical characterization of two diverse proteins, BadI and MenD from Rhodopseudomonas palustris and Staphylococcus aureus, respectively.
BadI or 2-ketocyclohexanecarboxyl-CoA is one of the key enzymes involved in the anaerobic degradation of aromatic compounds. The degradation of aromatic compounds is a vital process for the maintenance of the biogeochemical carbon cycle and bioremediation of xenobiotic compounds, which if present at higher concentrations can cause potential hazards to humans. Due to the relatively inert nature of aromatic compounds, enzymes catalyzing their degradation are of special interest for industrial applications. BadI is one of the key enzymes involved in the anaerobic degradation of aromatic compounds into an aliphatic moiety.
The major focus of this study was to provide mechanistic insights into the reaction catalyzed by BadI. BadI belongs to the crotonase superfamily and shares high sequence homology with the family members of MenB or dihydroxynaphthoate synthase. BadI is known to catalyze the cleavage of the cyclic ring of 2-ketocyclohexane carboxyl-CoA by hydrolyzing the C-C bond leading to the formation of the aliphatic compound pimelyl CoA. On the other hand MenB catalyzes the condensation reaction of o-succinylbenzoyl-CoA to dihydroxylnaphthoyl-CoA. A comprehensive amino acid sequence analysis between BadI and MenB showed that the active site residues of MenB from Mycobacterium tuberculosis (mtMenB) are conserved in BadI from Rhodopseudomonas palustris. MenB is involved in the menaquinone biosynthesis pathway and is a potential drug target against Mycobacterium tuberculosis as it has no known human homologs. Due to the high homology between MenB and BadI and the inability to obtain MenB-inhibitor complex structures we extended our interest to BadI to explore a potential substitute model for mtMenB as a drug target.
In addition, BadI possesses some unique mechanistic characteristics. As mentioned before, it hydrolyzes the substrate via a retro Dieckmann’s reaction contrasting its closest homolog MenB that catalyzes a ring closing reaction through a Dieckmann’s reaction. Nevertheless the active site residues in both enzymes seem to be highly conserved. We therefore decided to pursue the structural characterization of BadI to shed light on the similarities and differences between BadI and MenB and thereby provide some insights how they accomplish the contrasting reactions described above.
We determined the first structures of BadI, in its apo and a substrate mimic bound form. The crystal structures revealed that the overall fold of BadI is similar to other crotonase superfamily members. However, there is no indication of domain swapping in BadI as observed for MenB. The absence of domain swapping is quite remarkable because the domain swapped C-terminal helical domain in MenB provides a tyrosine that is imperative for catalysis and is also conserved in the BadI sequence. Comparison of the active sites revealed that the C-terminus of BadI folds onto its core in such a way that the conserved tyrosine is located in the same position as in MenB and can form interactions with the ligand molecule. The structure of BadI also confirms the role of a serine and an aspartate in ligand interaction, thus validating that the conserved active site triad participates in the enzymatic reaction. The structures also reveal a noteworthy movement of the active site aspartate that adopts two major conformations. Structural studies further illuminated close proximity of the active site serine to a water and chlorine molecule and to the carbon atom at which the carbonyl group of the true substrate would reside. Biochemical characterization of BadI using enzyme kinetics validated that the suggested active site residues are involved in substrate interaction. However, the role of these residues is very distinct, with the serine assuming a major role. Thus, the present work ascertain the participation of putative active site residues and demonstrates that the active site residues of BadI adopt very distinctive roles compared to their closest homolog MenB.
The MenD protein also referred to as SEPHCHC (2-succinyl-5-enolpyruvyl-6- hydroxy-3-cyclohexene-1-carboxylic acid) synthase is one of the enzymes involved in menaquinone biosynthesis in Staphylococcous aureus. Though S. aureus is usually considered as a commensal it can act as a remarkable pathogen when it crosses the epithelium, causing a wide spectrum of disorders ranging from skin infection to life threatening diseases. Small colony variants (SCVs), a slow growing, small sized subpopulation of the bacteria has been associated with persistent, recurrent and antibiotic resistant infections. These variants show autotrophy for thiamine, menaquinone or hemin. Menaquinone is an essential component in the electron transport pathway in gram-positive organisms. Therefore, enzymes partaking in this pathway are attractive drug targets against pathogens such as Mycobacterium tuberculosis and Bacillus subtilis. MenD, an enzyme catalyzing the first irreversible step in the menaquinone biosynthetic pathway has been implicated in the SCV phenotype of S. aureus. In the present work we explored biochemical and structural properties of this important enzyme.
Our structural analysis revealed that despite its low sequence identity of 28%, the overall fold of staphylococcal MenD (saMenD) is similar to Escherichia coli MenD (ecMenD) albeit with some significant disparities. Major structural differences can be observed near the active site region of the protein and are profound in the C-terminal helix and a loop near the active site. The loop contains critical residues for cofactor binding and is well ordered only in the ecMenD-ThDP structure, while in the apo and substrate bound structures of ecMenD the loop is primarily disordered. In our saMenD structure the loop is for the first time completely ordered in the apo form and displays a novel conformation of the cofactor-binding loop. The loop adopts an unusual open conformation and the conserved residues, which are responsible for cofactor binding are located too far away to form a productive complex with the cofactor in this conformation. Additionally, biochemical studies in conjugation with the structural data aided in the identification of the substrate-binding pocket and delineated residues contributing to its binding and catalysis. Thus the present work successfully divulged the unique biochemical and structural characteristics of saMenD.