Browsing by Subject "Escherichia coli"

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Adaptation of model organisms and environmental bacilli to glyphosate gives insight to species-specific peculiarities of the shikimate pathway
(2024) Schwedt, Inge; Commichau, Fabian M.
Glyphosate (GS), the active ingredient of the popular herbicide Roundup, inhibits the 5-enolpyruvyl shikimate-3-phosphate (EPSP) synthase of the shikimate pathway, which is present in archaea, bacteria, Apicomplexa, algae, fungi, and plants. In these organisms, the shikimate pathway is essential for de novo synthesis of aromatic amino acids, folates, quinones and other metabolites. Therefore, the GS-dependent inhibition of the EPSP synthase results in cell death. Previously, it has been observed that isolates of the soil bacteria Burkholderia anthina and Burkholderia cenocepacia are resistant to high amounts of GS. In the framework of this PhD thesis, it could be demonstrated that B. anthina isolates are not intrinsically resistant to GS. However, B. anthina rapidly adapts to the herbicide at the genome level and the characterization of GS-resistant suppressor mutants led to the discovery of a novel GS resistance mechanism. In B. anthina, the acquisition of loss-of-function mutations in the ppsR gene increases GS resistance. The ppsR gene encodes a regulator of the phosphoenolpyruvate (PEP) synthetase PpsA. In the absence of a functional PpsR protein, the bacteria synthesize more PEP, which competes with GS for binding in the active site of the EPSP synthase, increasing GS resistance. The EPSP synthase in B. anthina probably does not allow changes in the amino acid sequence as it is the case in other organisms. Indeed, the Gram-negative model organism Escherichia coli evolves GS resistance by the acquisition of mutations that either reduce the sensitivity of the EPSP synthase or increase the cellular concentration of the enzyme. Unlike E. coli, the EPSP synthase is also critical for the viability of Gram-positive model bacterium Bacillus subtilis. This observation is surprising because the enzyme belongs to the class of GS-insensitive EPSP synthases. In fact, the EPSP synthase is essential for growth of B. subtilis. The determination of the nutritional requirements allowing the growth of B. subtilis and E. coli mutants lacking EPSP synthase activity revealed that the demand for shikimate pathway intermediates is higher in the former organism. This finding explains why laboratory as well as environmental Bacilli exclusively adapt to GS by the mutational inactivation of glutamate transporter genes. Here, it was also shown that a B. subtilis mutant lacking EPSP synthase activity grows in minimal medium only when additional mutations accumulate in genes involved in the regulation of aerobic/anaerobic metabolism and central carbon metabolism. The characterization of these additional mutants will help to elucidate the peculiarities of the shikimate pathway in B. subtilis. Moreover, the mutants could be useful to identify the aromatic amino acid transporters that still await their discovery.
Advancing 2D fluorescence online monitoring in microtiter plates by separating scattered light and fluorescence measurement, using a tunable emission monochromator
(2023) Berg, Christoph; Busch, Selma; Alawiyah, Muthia Dewi; Finger, Maurice; Ihling, Nina; Paquet-Durand, Olivier; Hitzmann, Bernd; Büchs, Jochen
Online fluorescence monitoring has become a key technology in modern bioprocess development, as it provides in‐depth process knowledge at comparably low costs. In particular, the technology is widely established for high‐throughput microbioreactor cultivation systems, due to its noninvasive character. For microtiter plates, previously also multi‐wavelength 2D fluorescence monitoring was developed. To overcome an observed limitation of fluorescence sensitivity, this study presents a modified spectroscopic setup, including a tunable emission monochromator. The new optical component enables the separation of the scattered and fluorescent light measurements, which allows for the adjustment of integration times of the charge‐coupled device detector. The resulting increased fluorescence sensitivity positively affected the performance of principal component analysis for spectral data of Escherichia coli batch cultivation experiments with varying sorbitol concentration supplementation. In direct comparison with spectral data recorded at short integration times, more biologically consistent signal dynamics were calculated. Furthermore, during partial least square regression for E. coli cultivation experiments with varying glucose concentrations, improved modeling performance was observed. Especially, for the growth‐uncoupled acetate concentration, a considerable improvement of the root‐mean‐square error from 0.25 to 0.17 g/L was achieved. In conclusion, the modified setup represents another important step in advancing 2D fluorescence monitoring in microtiter plates.
Characterization of function and regulation of the subtilase cytotoxin and Shiga toxin of pathogenic Escherichia coli
(2021) Heinisch, Laura; Schmidt, Herbert
Food-borne diseases caused by enterohemorrhagic Escherichia coli (EHEC) constitute a great threat to human health worldwide. Pathogenicity of EHEC strongly depends on the ability to produce virulence factors such as amongst others bacterial toxins. One of these toxins are the so-called Shiga toxins (Stx), which is why EHEC are assigned to the group of Shiga toxin-producing Escherichia coli (STEC). Stx belong to the family of AB5 protein toxins consisting of two subunits. One of them, the StxA-subunit causes depurination of the 28S rRNA in eukaryotic ribosomes by exhibiting N-glycosidase activity subsequently leading to inhibition of the protein biosynthesis followed by apoptosis of the host cell. The second one is the homopentameric B-subunit, which mediates binding to the host cell surface via the receptor glycolipid globotriaosylceramide (Gb3). Besides Stx, the subtilase cytotoxin (SubAB) has been described in STEC in recent years. SubAB, also assigned to the family of AB5 toxins, generates its cytotoxic activity via cleavage of the endoplasmic chaperone binding immunoglobulin protein (BiP) by its A-subunit. This cleavage leads to an unfolded protein response, resulting in apoptosis of the host cell. The B-subunit forms a ring-like homopentameric structure which is responsible for the binding to the receptor N-glycolylneuraminic acid (Neu5Gc) and other O-glycans. Although the mode of cytotoxicity of AB5 toxins have been studied extensively, some mechanisms remain unsolved. The scope of this thesis was to analyze further the mode of action of AB5 toxins and the gene regulation of stx and subAB. Both publications included in this thesis combine the characterization of the cytotoxic activity of AB5 toxins, the regulation of their genes, their subunits, and the combination of subunits of Stx and SubAB. In the first publication the regulation of gene expression of AB5 toxins was investigated in more detail. In this study, the gene expression of subAB1 was analyzed with a luciferase reporter gene assay and by quantitative real-time polymerase chain reaction. To unravel the regulatory mechanisms, both the laboratory E. coli strain DH5α and the STEC O113:H21 strain TS18/08 were used. Expression of subAB1 and promoter activity was studied using standard cultivation methods. Moreover, this work shed light on the impact of the global regulatory proteins host factor of bacteriophage Qβ (Hfq) and histone-like nucleoid structuring protein (H-NS) on subAB1 gene expression. Therefore, isogenic deletion mutants of hfq and hns gene were generated in the respective strains. Afterwards, plasmid-based complementation was conducted to verify that the observed effects were due to the deletion. Analysis of subAB1 promoter activity revealed impact of both Hfq and H-NS during different growth phases in both strains. In addition, the influence of both regulatory proteins on the expression toxin genes in STEC strain TS18/08 was investigated. This study did not only focus on the expression of stx2a and subAB1, but also the gene expression of the gene of the cytolethal distending toxin V (cdtV) was analyzed. Interestingly, all three toxin genes studied were upregulated in the deletion mutants of Δhfq and Δhns. Those results demonstrate the impact of global regulatory proteins on AB5 toxin gene expression and show that all three toxin genes investigated are integrated into the same regulatory network. In the second publication, the mode of action of AB5 toxins on the example of Stx2a was analyzed in more detail. The paradigm of AB5 toxin was known as the receptor binding B-subunit which mediates uptake of the enzymatic A-subunit and the subsequent cytotoxic activity. Previous studies have questioned this paradigm by showing cytotoxic effects of the SubA-subunit in absence of its corresponding B-subunit. This work analyzed whether this cytotoxic effect of the A-subunit is not only true for SubAB, but also for Stx. Thus, seperate recombinant expression of StxA2a subunits and subsequent His tag-based purification was performed. Both StxA2a-His and StxB2a-His were analyzed on cytotoxicity separately or in combination with the other subunit. Strikingly, cytotoxic effects of the StxA2a-His was observed in the absence of its corresponding B-subunit cell-type independently on HeLa, Vero B4, and HCT-116 cells. Studies on the B-subunit revealed no cytotoxicity on all cell lines. Additionally, combinations of different A- and B-subunits of Stx2a and SubAB1 proteins were analyzed. The hybrid combination showed that the cytotoxic effect of StxA2a-His on HeLa and HCT-116 cells could be reduced in the presence of the SubB1-His. Contrary, the cytotoxic effects of SubA1- His were unaltered in combination with StxB2a-His. Those results give the assumption that the Stx2aA-subunit binds to a target cell receptor blocked by SubB1-His. Additional experiments on the binding capacity of the Stx2a-subunits to Gb3 revealed that while StxB2a-His was able to bind to the receptor, no binding of the recombinant A-subunit was observed. The results indicate a cytotoxic effect of StxA2a on different cell types in absence of its corresponding B-subunit, which is designated as “single-A” effect in this work. The role of this effect in STEC pathogenicity, the uptake mechanism and subsequent transport inside the host cells of StxA-subunit need to be further analyzed in the future.
Functional and structural studies of a C-terminally extended YidC
(2015) Seitl, Ines; Kuhn, Andreas
Members of the YidC/Oxa1/Alb3 protein family catalyze the insertion of integral membrane proteins into the lipid bilayer of the bacterial plasma membrane (YidC), the inner mitochondrial membrane (Oxa1), and the chloroplast thylakoid membrane (Alb3) (Saller et al., 2012; Dalbey et al., 2014). The insertase homologs are comprised of a conserved core region of 5 transmembrane domains, but are provided with additionally flanking N- and C-terminal regions of variable lengths and functions. The Gram-negative YidC is characterized by an additional N-terminal domain, while Gram-positive bacteria, mitochondria and plastids developed C-terminally extended insertase-domains. These domains are involved e.g. in direct interaction with ribosomes and facilitate a functional overlap with the co-translational SRP-targeting pathway. An extended C-terminal highly positively charged tail region was also found in the YidC homologs of the Gram-negative marine bacteria Rhodopirellula baltica and Oceanicaulis alexandrii, but not in Escherichia coli. The primary subject of this work was to characterize and analyze in detail the C-terminally extended YidC chimera, composed of the E. coli YidC and the C-terminally extended domains of the marine YidC homologs. Biochemical binding assays with the purified YidC proteins and isolated, vacant E. coli 70S ribosomes showed that the C-tails mediate specific binding to ribosomes independently of the translational state of the ribosome. Furthermore, a ribosome-bound insertase complex was visualized by cryo-electron microscopy. The enhanced affinity of the C-terminally extended YidC was used to isolate stable complexes with stalled ribosomes, carrying a nascent polypeptide chain of a YidC substrate protein (MscL). The cryo-EM structure of a YidC-ribosome nascent chain complex (RNC) was solved to a 8,6 Å resolution and allowed the visualization of the nascent chain from the peptidyl transferase center through the ribosomal exit tunnel into the YidC density. The structure revealed the helix H59 of the 23S rRNA and the two ribosomal proteins L24 and L29 as the major contacts sites of YidC at the ribosomal tunnel exit. Pull down assays confirmed a significantly interaction of the C-terminal ribosome binding domain and the ribosomal protein L29, while L24 seems to be a universal contact site for the YidC-insertase core domain. Strikingly, the cryo-EM structure clearly showed a single monomer of YidC bound to the translating ribosome. This suggests that monomeric YidC might be the minimal functional unit for YidC-dependent, co-translational insertion of inner membrane proteins. In addition to the in vitro tests, a possible role of the C-terminal YidC extensions in co-translational protein targeting was tested in vivo in E. coli. For that purpose the targeting and localization of the SRP-dependent YidC-substrate protein MscL (Facey et al., 2007) was investigated as a GFP fusion protein via fluorescence microscopy. In addition, the proper membrane insertion of MscL was analyzed in radioactive pulse chase experiments via AMS gel shift assays, either in the absence of a functional SRP or SRP receptor (FtsY). Both in vivo assays clearly showed that the C-terminal ribosome binding domain of the R. baltica YidC homolog can partially substitute for the SRP receptor function in E. coli, while the cytosolic signal recognition particle is still required for correct insertion of the MscL protein. Therefore, a new co-translational targeting and insertion model of YidC-only substrates was proposed. This works also highlights evolutionary aspects of the accessory YidC domains and indicates that the C-terminal extended tail of YidC in the planctomycete group may be an ancestral remnant of a primordial translocation system operating without a typical SRP receptor. The second part focuses on the interaction of the signal recognition particle with SRP signal sequences. Isolated mutant signal sequence peptides were used to determine the specificity of SRP recognition in proteins. The interaction studies were established in an in vitro system and binding affinities of purified SRP to the isolated signal sequence peptides were determined via microscale thermophoresis (MST). A short sequence of 27 amino acid residues at the very N-terminal tail of the large cytoplasmic domain of KdpD was identified as a SRP signal sequence. Furthermore, a direct influence of the amino acid composition in the signal peptide on its SRP binding affinity in vitro was demonstrated. This confirms a low influence of an altered charge in the N-terminal region while mutations in the hydrophobic core region causes significantly reduced binding affinities to SRP. Taken together, this study contributes to the understanding of the molecular mechanisms of co-translational membrane protein biogenesis in bacteria.
Funktion und Dynamik eines gemeinsamen Insertionskomplexes der Sec-Translokase und YidC-Insertase in der bakteriellen Membran
(2020) Steudle, Anja; Kuhn, Andreas
YidC/Oxa1/Alb3-insertases and the Sec-translocase are conserved across all three kingdoms of life and constitute the most important pathway for integral proteins into cell membranes and membranes of eukaryotic organelles. The insertion of membrane proteins into the inner membrane of Gram-negative bacteria occurs mainly via the SecYEG-translocase and the YidC-insertase acting independently or in cooperation. For the cooperative insertion a close contact between SecY and YidC is assumed. Previous interaction-studies and a recently solved low-resolution structure of the so-called holo-translocon (14 Å) indicate a contact between the lateral gate of SecY and the hydrophobic substrate slide of YidC. Which specific domains of YidC and SecY thereby interact directly with each other was unknown so far. The aim of this study was to describe the contact between SecY and YidC in more detail. A high affinity for the interaction of the two proteins in detergent and in DOPC-proteoliposomes was determined via FRET measurements with fluorescently labeled SecY and YidC. For the stoichiometric ratio of the SecY/YidC-interaction a factor of one was calculated. To identify the specific contacts between SecY and YidC in vivo disulphide cross-linking experiments were performed. Direct interactions between the transmembrane domain (TM) 3 and TM8 of the SecY lateral gate and TM3 and TM5 of the hydrophobic slide of YidC were found, respectively. Furthermore, a YidC mutant with five serine substitutions, which was unable to rescue a YidC depletion strain, was investigated. Even though the serine positions are located in the middle and the periplasmic half of the hydrophobic slide of YidC and four of the positions are identical with substrate contact sites, no inhibition of insertion for the YidC-dependent substrates M13 procoat and Pf3 coat by the 5S mutant compared to the wildtype YidC was observed. For the YidC-only pathway a minimum of hydrophobicity seems to be required sufficient to allow the insertion of these substrates. In vitro FRET measurements showed an impaired interaction between SecY and the YidC 5S mutant and confirmed once again an involvement of the hydrophobic slide in the SecY/YidC-contact. Based on the cross-linking contacts and the results of the FRET measurements a possible model of the SecY/YidC-contact was established, which shows the SecY lateral gate vis-à-vis of the hydrophobic slide and the hydrophilic groove between TM3 and TM5 of YidC generating a combined SecY/YidC-cavity. Taken together, the present study provides further evidence that the lateral gate of the Sec-translocase directly interacts with the hydrophobic slide of YidC. In a further project, a SecY-YidC fusion protein was cloned to ensure the two proteins are in close proximity, the correct orientation and proper stoichiometry after reconstitution into proteoliposomes. For a collaboration with the ETH Zürich, proteoliposomes hosting the fusion protein, SecYEG, YidC or SecYEG and YidC together were prepared by myself in Hohenheim. The stepwise insertion of the Sec/YidC-dependent substrate LacY into these proteoliposomes was observed by a collaborating group of the ETH Zürich using AFM–based single-molecule force spectroscopy. The insertion of LacY was observed for the different cases but for the fusion protein and SecYEG combined with YidC the insertion process is dominated by the Sec-translocase, whereas YidC probably only has a supporting function in the folding of the protein.
Funktionelle Untersuchung der Sensorkinase KdpD von Escherichia coli mit Hilfe verschiedener KdpD-Deletionsmutanten
(2007) Rothenbücher, Marina; Kuhn, Andreas
The high affinity K+ transport system KdpFABC is one of several uptake systems that accumulate K+ in Escherichia coli. Expression of the kdpFABC operon is under control of the regulatory proteins KdpD and KdpE, which constitute a typical sensor kinase/response regulator system. KdpD is an integral protein of the cytoplasmic membrane. The N-terminal domain, the 4 helices and 200 amino acids of the cytoplasmic C-terminal domain are accredited to be involved in the signal input function. Surprisingly, a mutant (KdpD-C) lacking the N-terminal domain, helix 1 and 2 is a functional K+ sensor, which is able to detect the changes in K+ concentration in the medium. To investigate which parts of the KdpD protein are essential for signal transduction, various truncated KdpD variants were constructed and analyzed. The results show that the fragment C499-894, which contains only the cytoplasmic C-terminal domain of KdpD, is able to recognise the increase in K+ concentration in medium and reduce the level of activity. This mini sensor is also able to discriminate between Li+, Rb+ and K+ ions like the wild-type KdpD. A plasmid coding for this mini sensor allows a kdpD deletion strain to grow under K+-limited conditions in medium. Presumably, the signal perceived by KdpD is in the periplasm, but how is the signal transmitted to the cytoplasmic domain of KdpD that controls activity? Perhaps KdpD is not the direct sensor, an additional component in the membrane might sense the signal and communicate with KdpD. Further research with sodium carbonate extraction to determine the membrane localisation of C499-894 showed the protein mainly found in the supernatant, suggesting C499-894 is a soluble protein, although C499-894 could be attached to the membrane to come in contact with an unknown membrane protein. Looking for the unknown component two protein candidates were found by co-purification, the cytochrome oxidase A (CyoA) and the glucosamine-6-phosphate synthase (GlmS). To find an interaction between these proteins and KdpD more research has to be done.
Die Insertion des „minor coat“ Proteins G3P des Bakteriophagen M13 in die innere E. coli Membran benötigt die Insertase YidC und die Translokase SecYEG.
(2021) Kleinbeck, Farina; Kuhn, Andreas
The membrane of every cell forms a spacial limitation for this smallest unit of a life form. Such a very simple unicellular life form is also the Gram-negative bacterium Escherichia coli (E. coli) and is therefore a valid model organism for a living cell. Due to the inner membrane the cellular components are held together in close proximity and are separated from the extracellular environment. Most substrates cannot pass the lipid bilayer, which forms the membrane, so an import and export system had to be developed to accomplish this. For these import and export systems, very complex, polytopic transmembrane protein complexes are needed. Examples are ion channels, ion pumps or large complexes through which energy production, secretion of toxins and the transfer of nutrients are catalysed. Moreover, proteins with functions in the periplasm or outer membrane must also travel from their site of synthesis in the cytoplasm to their destination. For these different processes proteins must be inserted into or translocated across the inner membrane. Of the total proteome in prokaryotes approximately 25 to 30% is either inserted into or secreted across the inner membrane. This work identified several components required for the insertion of the "minor coat" protein G3P of M13 bacteriophage. This protein is important for the assembly of the phage particle that occurs in the inner membrane. The outermost C-terminus of G3P is anchored in the inner membrane via a single transmembrane domain, while the bulk of the approximately 42 kDa protein is located in the periplasm. Using an N-terminal cleavable signal peptide, the major portion of G3P is translocated into the periplasm via SecYEG with the help of SecA and the membrane potential. Targeting, on the other hand, could not be clearly assigned to one of the known post- or co-translational pathways. Although contact via disulfide crosslink studies to Ffh, the protein component of the ribonucleoprotein SRP, was observed via stalled ribosome nascent chains (RNCs), insertion into the membrane in vivo was independent of Ffh. Even when the interaction between SecY and FtsY, the receptor for SRP at the membrane, was impaired, G3P was inserted via SecYEG. Although the chaperone SecB was able to bind to G3P in vitro, G3P inserted independently of SecB in vivo. For membrane incorporation of G3P, it was shown that YidC is required in vivo in addition to SecYEG. Disulphide crosslink studies demonstrated that G3P first contacts the plug domain TM2b and lateral gate (TM2a and TM7) via the signal peptide of G3P, and finally the C-terminal transmembrane domain of G3P contacts YidC via TM3 and TM5 of the hydrophilic slide. Based on these contact sites, a possible insertion model was confirmed, with SecY and YidC mediating defined steps in the insertion process, providing new insights into this largely unknown process.
The low mutational flexibility of the EPSP synthase in Bacillus subtilis is due to a higher demand for shikimate pathway intermediates
(2023) Schwedt, Inge; Schöne, Kerstin; Eckert, Maike; Pizzinato, Manon; Winkler, Laura; Knotkova, Barbora; Richts, Björn; Hau, Jann-Louis; Steuber, Julia; Mireles, Raul; Noda‐Garcia, Lianet; Fritz, Günter; Mittelstädt, Carolin; Hertel, Robert; Commichau, Fabian M.
Glyphosate (GS) inhibits the 5-enolpyruvyl-shikimate-3-phosphate (EPSP) synthase that is required for aromatic amino acid, folate and quinone biosynthesis in Bacillus subtilis and Escherichia coli. The inhibition of the EPSP synthase by GS depletes the cell of these metabolites, resulting in cell death. Here, we show that like the laboratory B. subtilis strains also environmental and undomesticated isolates adapt to GS by reducing herbicide uptake. Although B. subtilis possesses a GS-insensitive EPSP synthase, the enzyme is strongly inhibited by GS in the native environment. Moreover, the B. subtilis EPSP synthase mutant was only viable in rich medium containing menaquinone, indicating that the bacteria require a catalytically efficient EPSP synthase under nutrient-poor conditions. The dependency of B. subtilis on the EPSP synthase probably limits its evolvability. In contrast, E. coli rapidly acquires GS resistance by target modification. However, the evolution of a GS-resistant EPSP synthase under non-selective growth conditions indicates that GS resistance causes fitness costs. Therefore, in both model organisms, the proper function of the EPSP synthase is critical for the cellular viability. This study also revealed that the uptake systems for folate precursors, phenylalanine and tyrosine need to be identified and characterized in B. subtilis.
Molekulare Dynamik der YidC-Membraninsertase aus Escherichia coli
(2011) Imhof, Nora; Kuhn, Andreas
The membrane insertase YidC of the Gram-negative bacterium E. coli enables the insertion of proteins into the cytoplasmic membrane. YidC itself is localized in the cytoplasmic membrane and spans the membrane six times with its N- and C-termini localized in the cytoplasm. These six transmembrane segments are connected by three periplasmic loops (P1, P2 and P3) and two cytoplasmic loops (C1 and C2). It is known that the binding of the YidC-dependent protein Pf3 coat induces conformational changes in the tertiary structure of YidC. This molecular dynamic of YidC was examined in detail with steady-state and time-resolved fluorescence spectroscopy. Therefore, three tryptophan mutants of YidC with one tryptophan residue each, at position 354 in the first periplasmic domain P1, at position 454 in the second periplasmic region and at position 508 near the third periplasmic region, respectively, were used. Additionally, a double tryptophan mutant was used which contained two tryptophan residues at position 332/334 of the domain P1. These tryptophan residues were used as intrinsic fluorophores. First, it was shown that the tryptophan mutants of YidC complemented the growth defect of the E. coli YidC-depletion strain JS7131. Additionally, the mutants were able to insert the strictly YidC-dependent PClep protein into the cytoplasmic membrane of the depletion strain. Thus, the functionality of the tryptophan mutants of YidC was ensured. Purified tryptophan mutants of YidC were reconstituted into liposomes and titrated with Pf3W0 coat, a tryptophan free mutant of Pf3 coat protein allowing spectroscopic studies of each periplasmic region (P1, P2 and P3) before and after binding of Pf3W0 coat protein. Analysis of the emission spectra and the fluorescence lifetimes of detergent solubilized as well as of the reconstituted YidC tryptophan mutants before binding of Pf3W0 coat revealed that the tryptophan residue of each single tryptophan mutant (YidCW354, YidCW454 and YidCW508) was localized at the membrane/water interface. These results are consistent with the proposed membrane topology of YidC. The tryptophan residues of the double tryptophan mutant of YidC (YidC2W) showed fluorescence properties consistent with their localization in a partially exposed alpha-helical segment of the P1 domain. Analysis of the emission spectra and the fluorescence lifetimes provided additional evidence that binding of Pf3W0 coat induced conformational changes of all periplasmic regions (P1, P2 and P3) within YidC. Measurements of fluorescence anisotropy showed that the conformational changes affected motions within all three periplasmic regions of the YidC tryptophan mutants, whereas the periplasmic domain P1 with the tryptophan residues W332/W334 and the third periplasmic domain P3 with the tryptophan residue W508 were affected most significantly.
The bacterial membrane insertase YidC : in vivo studies of substrate binding and membrane insertion
(2015) Klenner, Christian Daniel; Kuhn, Andreas
YidC of Escherichia coli belongs to the evolutionarily conserved proteins of the Oxa1/YidC/Alb3 insertase family. The transmembrane regions of the core domain, comprising of TM2-6, are the most conserved parts among the homologs and are crucial for the function as a membrane insertase. This is particularly true for the TM2, TM3 and TM5 (KUHN et al., 2003; KIEFER & KUHN, 2007). In bacteria, YidC acts as an independently working membrane insertase and, as well, in cooperation with the Sec translocon for the biogenesis of various membrane proteins. YidC is required for the biogenesis of respiratory complexes, ATP synthase and for example the mechanosensitive channel protein MscL. Also, the coat proteins of filamentous phage Pf3 and M13 require YidC for membrane insertion. The best studied substrate is the Pf3 coat protein of phage Pf3 infecting Pseudomonas aeruginosa – i.e. a small protein of 44 amino acids in length. In the context of this thesis, the YidC-dependent biogenesis of Pf3 coat was analyzed to gain better insight into the entire insertion process. In doing so, a set of more than 100 single cysteine mutants in distinct domains of YidC and Pf3 coat were generated. To study the insertion of Pf3 coat under physiological conditions, an in vivo cross-linking assay was established for capturing YidC-Pf3 interactions within a short period of time after the onset of synthesis (1 minute) using 35S-Met pulse-labelling methods. YidC binds inserting Pf3 coat protein in distinct regions of the highly conserved TM domains involving four of the six TM helices. It was verified that TM3 is indispensable for the function of YidC since four contacting residues were found in this TM helix. A helical wheel projection of substrate binding helices reveals the localization of the contacting residues of each TM segment on one helical face. This implies a helix arrangement of the transmembrane core domain which enables binding of inserting substrate proteins and interactions with transmembrane domains over the entire membrane-spanning part of YidC. The serial mutation of nine from twelve contacting residues, which are strongly hydrophobic in most cases, to serines impaired the function of YidC, whereas the single mutations had no effect. Additionally, the insertion process of translocation deficient Pf3 coat mutants was analyzed for intermediate states of the insertion process. It has been shown that the insertion deficient Pf3 coat mutants are inhibited at a late step of membrane insertion, i.e. forming the YidC contacts in the periplasmic leaflet. Based on this work, further studies confirmed that the identified substrate contacting regions of YidC play a key role in YidC-mediated insertion. The mechanosensitive channel protein MscL, M13 procoat, nascent Foc and the polytopic membrane protein LacY contact YidC at exactly the same positions (NEUGEBAUER et al., 2012; SPANN & KUHN, unpublished results; WICKLES et al., 2014; ZHU et al., 2013b).
The function of E. coli YidC for the membrane insertion of the M13 procoat protein
(2018) Spann, Dirk; Kuhn, Andreas
The YidC/Oxa1/Alb3 family consists of insertase homologues that facilitate the insertion and folding of membrane proteins. YidC is located in the inner membrane of bacterial cells. Oxa1 is found in the inner membrane of mitochondria and Alb3 facilitates the insertion of membrane proteins in the thylakoid membranes of chloroplasts (Wang and Dalbey 2011, Hennon et al. 2015). An archaeal homologue was found in M. jannaschii showing that this insertase family is present in all domains of life (Dalbey and Kuhn 2015). The insertase family shares a structural feature that is conserved among all discovered members. This is a hydrophilic groove that is open towards the cytoplasm and the membrane core with a hydrophobic slide formed by transmembrane domain (TM) 3 and TM5. YidC functions on its own but also cooperates with the Sec translocon to facilitate the insertion of large membrane proteins. One protein that is membrane-inserted by YidC but is Sec-independent is the major coat protein of the M13 bacteriophage. The main objectives of this work are the analysis of the insertion mechanism of M13 procoat, the major capsid protein of the M13 bacteriophage, via the YidC-only pathway and the oligomeric state of the active YidC. The analysis of interactions between YidC and M13 procoat was performed via radioactive disulfide crosslinking mainly using copper phenanthroline as oxidizing agent. M13 procoat contacts YidC extensively in TM3 and TM5. The observed contacts suggest that the M13 procoat substrate “slides” along TM3 and TM5 of the insertase. Additional crosslinking experiments with the hydrophilic groove and the C1 loop of YidC were also performed to test their importance during the insertion process. A contact was found in the C1 loop that indicates a role in the insertion process, which is consistent with the proposed insertion model from Kumazaki et al. (2014a). Parallel to the radioactive disulfide crosslinking, a protocol using DTNB (Bis(3-carboxy-4-nitrophenyl) disulfide, Ellman’s reagent) as the oxidizing reagent and Western blot for detection was established. This method reliably promoted the formation of crosslinking products in vivo between YidC and M13 procoat over several hours and many, but not all, mapped at the same sites as in the radioactive approach. In addition, this protocol was used to purify small amounts of a YidC-substrate complex for biochemical analysis, which could also be applied to other substrates in the future. The oligomeric state of YidC was investigated by an artificial dimer of the insertase (dYidC) that was constructed by connecting two monomers together with a short linker. This dimer can complement YidC-depleted E. coli MK6S cells and facilitates the insertion of M13 procoat in vivo. For further analysis of the dYidC three functionally defective YidC mutants, T362A (Wickles et al. 2014), delta-C1 (Chen et al. 2014) and the 5S YidC mutant, were tested for their complementation and insertion capability. All three mutants were not able to complement under YidC depletion conditions. These mutants were then cloned in either one or both protomers of the dYidC. Complementation and insertion assays with these dYidC constructs show that in general one active protomer suffices to uphold cell viability and to facilitate the insertion of M13 procoat. Binding studies using cysteine mutants of the dYidC and M13 procoat for disulfide crosslinking with DTNB demonstrated that each protomer individually binds one substrate molecule. In summary, these experiments strongly support a monomer as the active state of the insertase for YidC-only substrates. Taken together, this study contributes to the understanding of the insertion of proteins into the inner bacterial cell membrane.
Untersuchungen zur spezifischen Genexpression von enterohämorrhagischen Escherichia coli (EHEC) in der Lebensmittelmatrix
(2012) Kroj, Andrea; Schmidt, Herbert
Ground beef as a high risk food is known to be an cause of human infection with Shiga toxin-producing E. coli (STEC). The pathogens infect humans by the ingestion of undercooked ground meat and cause severe diseases like hemorrhagic colitis or the life-threatening hemolytic uremic syndrome. E. coli O157:H7 strain EDL933 as a representative of enterohemorrhagic E. coli (EHEC), a subgroup of STEC, was analysed for in vivo induced genes in ground beef with the help of the in vivo expression technology. It could be demonstrated that the promoter selection vector pKK232-8, which contains a promoterless chloramphenicol resistance gene, is not a suitable vector for a study of gene expression in this matrix. The detection of in vivo expressed genes using the alcohol-soluble and bacteriostatic antibiotic was not possible. Therefore, the promoter selection vector pAK-1 was developed. The new vector system was based on a water-soluble and bactericidal kanamycin resistance gene for selection. In the present study, the vector was established and used for analysis of the gene expression in ground meat. 20 in vivo induced genes that were expressed during growth in ground meat under elevated temperature conditions at 42°C could be detected. Eight genes were associated with energy and nucleotide metabolism, macromolecule synthesis, transport and stress response of the cell. The major part of 12 genes was attributed to a putative or unknown function. Predominantly, identified genes could not be associated with virulence or stress response of the cell. The results of this study, using the in vivo expression technology, showed that genes which are expressed under specific conditions in ground meat could be detected with the help of the chosen method. A first insight into the gene expression of strain EDL933 in ground beef could be acquired. During further investigations a comparison of the fitness of 23 E. coli strains belonging to serogroups O26, O103 and O157 was realized. The isolates originating from foods, patients with HUS and animals were compared in ground beef. The determined differences showed strain-specificity and temperature-specificty. The fitness of the strains varied dependent on the chosen temperatures at 15, 20 and 37 degrees. The analysis of the strains based on ten virulence factors showed that the observed differences could not be attributed to the presence or the number of virulence genes. A correlation between the fitness and the production of a bacteriocin could not be found.