Skip to main content

ORIGINAL RESEARCH article

Front. Microbiol., 09 February 2018
Sec. Microbial Physiology and Metabolism

Membrane Topology and Heme Binding of the Histidine Kinases HrrS and ChrS in Corynebacterium glutamicum

  • Institute of Bio- and Geosciences, IBG-1: Biotechnology, Forschungszentrum Jülich, Jülich, Germany

The HrrSA and the ChrSA two-component systems play a central role in the coordination of heme homeostasis in the Gram-positive soil bacterium Corynebacterium glutamicum and the prominent pathogen Corynebacterium diphtheriae, both members of the Corynebacteriaceae. In this study, we have performed a comparative analysis of the membrane topology and heme-binding characteristics of the histidine kinases HrrS and ChrS of C. glutamicum. While the cytoplasmic catalytic domains are highly conserved between HrrS and ChrS, the N-terminal sensing parts share only minor sequence similarity. PhoA and LacZ fusions of the N-terminal sensor domains of HrrS and ChrS revealed that both proteins are embedded into the cytoplasmic membrane via six α-helices. Although the overall membrane topology appeared to be conserved, target gene profiling indicated a higher sensitivity of the ChrS system to low heme levels (< 1 μM). In vitro, solubilized and purified full-length proteins bound heme in a 1:1 stoichiometry per monomer. Alanine-scanning of conserved amino acid residues in the N-terminal sensor domain revealed three aromatic residues (Y112, F115, and F118), which apparently contribute to heme binding of HrrS. Exchange of either one or all three residues resulted in an almost abolished heme binding of HrrS in vitro. In contrast, ChrS mutants only displayed a red shift of the soret band from 406 to 418 nm suggesting an altered set of ligands in the triple mutant. In line with target gene profiling, these in vitro studies suggest distinct differences in the heme-protein interface of HrrS and ChrS. Since the membrane topology mapping displayed no extensive loop regions and alanine-scanning revealed potential heme-binding residues in α-helix number four, we propose an intramembrane sensing mechanism for both proteins. Overall, we present a first comparative analysis of the ChrS and HrrS kinases functioning as transient heme sensors in the Corynebacteriaceae.

Introduction

Heme represents a ubiquitous cofactor of proteins and plays a vital role in a variety of cellular processes, including electron transport, oxygen transport, or oxidative stress responses (Poulos, 2007). Ferriprotoporphyrin IX (heme) is also the predominant form of iron in vertebrates and is consequently also exploited as an important iron source for – not only – pathogenic bacteria (Andrews, 2008; Cornelis et al., 2011). Elevated heme levels, however, cause toxicity by so far not satisfactorily settled mechanisms (Anzaldi and Skaar, 2010). Thus, the intracellular heme pool is typically tightly balanced by a complex and integrative regulatory network.

In bacteria, two-component systems (TCS) represent a ubiquitous principle used by the cells to sense and respond to a variety of different stimuli (Mascher et al., 2006). A prototypical TCS consists of a membrane bound histidine kinase (HK) with a unique sensing domain and a conserved, catalytically active kinase core and a cytoplasmic response regulator (RR) which can be phosphorylated and activated by the HK (Zschiedrich et al., 2016). In response to the stimulus, the HK is autophosphorylated at a conserved histidine residue. The following phosphoryl transfer to the RR typically leads to the activation of this protein, which then drives cellular adaptation, for example, by controlling target gene expression (Stock et al., 2000; Laub and Goulian, 2007).

In the Gram-positive soil bacterium Corynebacterium glutamicum, two paralogous TCS, HrrSA and ChrSA, have been reported to play a central role in the control of heme homeostasis (Frunzke et al., 2011; Bott and Brocker, 2012; Heyer et al., 2012). While the HrrSA system is crucial for utilization of heme as an alternative iron source by activating the expression of the heme oxygenase (hmuO) under iron limiting conditions (Frunzke et al., 2011), the TCS ChrSA is required to cope with elevated heme levels by activating the expression of a putative heme exporter hrtBA (Heyer et al., 2012). Significant cross-phosphorylation between these two systems has been demonstrated in previous studies (Hentschel et al., 2014) reflecting the striking similarity of the HisKA_3 domains of the sensor kinases HrrS and ChrS [pfam07730, ∼40% sequence identity (Finn et al., 2010)]. In contrast, the N-terminal, membrane anchored signal perception domains of the sensor kinases share a low sequence identity of only 8.5% (Supplementary Figure S1). Nevertheless, previous studies provided evidence that heme is perceived as a stimulus by both kinases (Frunzke et al., 2011; Heyer et al., 2012).

In nature, the predominant types of heme are heme b and heme c. While heme c is mostly found covalently bound to proteins, heme b is often non-covalently bound (Bowman and Bren, 2008; Brewitz et al., 2017). According to a bioinformatical analysis of 125 different heme-binding proteins, the top five residues with high frequencies in close proximity to the binding pocket are cysteine, histidine, phenylalanine, methionine, and tyrosine (Li et al., 2011). Overall, 31 different structural folds were reported for the protein–heme interaction, hinting to a very diverse mode of interaction between proteins and heme as ligand (Li et al., 2011).

In the ChrS homolog of Corynebacterium diphtheriae, a single tyrosine residue (Y61) was speculated to be involved in heme binding (Ito et al., 2009; Bibb and Schmitt, 2010). A further example of a heme-responsive TCS is the heme sensor system (HssRS), which has been studied in Staphylococcus aureus and Bacillus anthracis (Stauff and Skaar, 2009a,b). In this case, several amino acids were speculated to be involved in heme binding. However, the periplasmic loop domain of HssS represents a significant difference to HrrS and ChrS in Corynebacteria. In contrast to ChrS, heme binding and membrane topology of HrrS has not been studied so far.

Here, we performed a comparative sequence and biochemical analysis of the transmembrane domain of C. glutamicum HrrS and ChrS. Our data suggested that regardless of the low sequence identity of the sensor domain, both kinases are embedded into the cytoplasmic membrane via six α-helices. In vitro analysis of purified full-length proteins revealed that HrrS and ChrS bind heme in a 1:1 stoichiometry per monomer. Furthermore, three conserved aromatic residues (Y112, F115, and F118) were identified, which are of crucial importance for heme binding of HrrS. Conclusively, we provide insights into the organization of the sensor domain of these two closely related HKs and present a model for an intramembrane heme interface for signal perception.

Materials and Methods

Bacterial Strains and Growth Conditions

Corynebacterium glutamicum ATCC 13032 was used as wild type strain (Kalinowski et al., 2003) (Supplementary Table S1). For reporter studies, a BHI pre-culture (brain heart infusion, Difco BHI, BD, Heidelberg, Germany) was inoculated with cells from a fresh agar plate and incubated for 8–10 h at 30°C. Subsequently, cells were transferred into a CGXII (Keilhauer et al., 1993) preculture containing 2% (w/v) glucose and 0 μM FeSO4. These conditions have been optimized to achieve iron starvation. Protocatechuic acid (PCA) was present in the pre-culture, allowing the uptake of trace amounts of iron. After overnight growth, a CGXII main culture (containing hemin as iron source) was inoculated to an OD600 of 1. If necessary, 25 μg/ml kanamycin or 10 μg/ml chloramphenicol was added.

Escherichia coli was cultivated in Lysogeny Broth (LB) medium at 37 or 20°C for protein production. If necessary, 50 μg/ml kanamycin or 34 μg/ml chloramphenicol was added.

Cloning Techniques and Recombinant DNA Work

Routine molecular biology methods were performed according to standard protocols (Sambrook and Russell, 2001). Chromosomal DNA of C. glutamicum ATCC 13032 was used as template for PCR amplification of DNA fragments was and prepared as described earlier (Eikmanns et al., 1994). DNA sequencing and synthesis of oligonucleotides was performed by Eurofins Genomics (Ebersberg, Germany).

For the construction of expression plasmids (Supplementary Table S1), DNA fragments were amplified with oligonucleotides given in Supplementary Table S2 and assembled into a vector backbone either by Gibson et al. (2009) or via standard restriction digestion and ligation. For the phoA/lacZ assays, pT7-5-phoA and pT7-5-lacZ were used as vector backbones. Both plasmids were kindly donated by the laboratories of G. Unden (Bauer et al., 2011).

Wild type and mutant versions of hrrS and chrS were expressed from the pkW3 plasmid backbone. The mutations were introduced via “QuikChange Lightning” site directed mutagenesis according to the supplier’s manual (Agilent Technologies, Santa Clara, United States). The origin plasmid was digested with DpnI (digestion of methylated DNA) and the mutant plasmid was transferred into E. coli TOP-10. The introduced mutations were confirmed by sequencing.

Alkaline Phosphatase and β-Galactosidase Assays

For both, the alkaline phosphatase (PhoA) and the β-galactosidase (LacZ) assay, E. coli TG-1 was transformed with truncated hrrS or chrS versions fused to either phoA or lacZ in the pT7-5 vector and grown overnight in LB medium containing kanamycin (50 μg/ml). The overnight culture was diluted 1:50 in fresh medium and grown for 1.5 h (∼OD600 = 0.1). Subsequently, expression of the phoA/lacZ fusions was induced with 1 mM IPTG for 1 h. The activities of PhoA and LacZ fusions were measured as described as follows: for the PhoA assay, 100 μl of the E. coli cells were harvested and resuspended in 300 μl of 1 mM Tris–HCl (pH = 8.0). Cells were permeabilized by the addition of 25 μl 0.1 % (w/v) SDS and 25 μl chloroform to allow both substrates (p-nitrophenyl phosphate and 2-nitrophenyl β-D-galactopyranoside) to enter the cells. Samples were incubated for 20 min at room temperature (Manoil, 1991). Subsequently, 200 μl of the upper phase was transferred to a microtiter plate and the reaction was started by the addition of 25 μl of a 5 mg/ml p-nitrophenyl phosphate solution (in 1 mM Tris–HCl, 5 mM MgCl2, pH 8.0). For background measurement and normalization, Abs600 and Abs500 were measured immediately. The plates were incubated at 28°C for up to 2 h and the yellow color change was determined by measuring the Abs420.

For LacZ, the protocol was derived from a protocol published by Miller (1992): 100 μl of the E. coli culture was harvested and resuspended in 300 μl buffer Z (60 mM Na2HPO4⋅12H2O, 40 mM NaH2PO4⋅H2O, 1 mM MgSO4⋅7H2O, 10 mM KCl, and 100 mM freshly added DTT).

The cells were permeabilized and transferred to a microtiter plate. The reactions were started by addition of 25 μl of a 5 mg/ml 2-nitrophenyl β-D-galactopyranoside solution (in 100 mM K2HPO4, pH = 7.0). Measurements were performed as described for PhoA above. Miller units for both enzymes were calculated according to Supplementary Formula S1.

Reporter Assays

For fluorescent reporter assays a 20 ml pre-culture of CGXII minimal medium containing 2% (w/v) glucose was inoculated from a 5 ml BHI culture of C. glutamicum carrying the reporter plasmid (e.g., pJC1_PhmuO-eyfp or pJC1_PhrtBA-eyfp) (Hentschel et al., 2014) and expressing a hrrS or chrS mutant gene (fused to the flag-gene) from the plasmid pKW3 under control of the native promotor. To cause iron starvation, no additional iron source was added to the CGXII medium (PCA was present in the pre-culture, allowing the uptake of trace amounts of iron). The cells were incubated overnight at 30°C in a rotary shaker and grew to an OD600 of ∼10–20. Reporter assays in microtitre scale were performed in the BioLector system (m2p-labs GmbH, Aachen, Germany). Therefore, 750 μl CGXII medium containing 2% (w/v) glucose and 2.5 μM hemin were inoculated from the second pre-culture with iron-starved cells to an OD600 of 1 and cultivated in 48-well Flowerplates® (m2p-labs GmbH, Aachen, Germany) at 30°C, 95% humidity, 1200 r.p.m. For the hemin stock solution, hemin (Sigma–Aldrich, Munich, Germany) was dissolved in 20 mM NaOH to a concentration of 2.5 mM and diluted in water to 250 μM. Biomass production of the growing cells was determined as the backscattered light intensity of sent light with a wavelength of 620 nm (signal gain factor of 12). For the measurement of eYFP fluorescence, the chromophore was excited at 510 nm and emission was measured at 532 nm (signal gain factor of 50). The specific fluorescence corresponds to the total eYFP fluorescence signal in relation to the backscatter signal and is given in arbitraty units (a.u.) (Kensy et al., 2009).

Overproduction and Purification of Full-Length Histidine Kinases

For the overproduction of HrrS-CStrep and ChrS-CStrep, E. coli BL21(DE3) was either transformed with the vectors pET24b-hrrS-Cstrep, pET24b-chrS-Cstrep or a mutated version and cultivated in 500 ml LB medium at 37°C and 100 rpm. At an OD600 of ∼0.7, expression was induced by the addition of 0.5 mM IPTG. After 12–16 h at 20°C, cells were harvested by centrifugation (4000 × g at 4°C, 10 min). The cell pellet was stored at -20°C. For protein purification, the cell pellet was resuspended in buffer W (100 mM Tris–HCl, pH = 8.0, 250 mM NaCl), containing “complete” protease inhibitor cocktail (Roche, Germany). Cells were disrupted by passing a French pressure cell (SLM Ainco, Spectronic Instruments, Rochester, NY, United States) three times at 207 MPa. The cell debris was removed by centrifugation (6900 × g, 4°C, 20 min), followed by an ultracentrifugation of the cell-free extract for 1 h (150,000 × g, 4°C). Pellets containing the membrane fraction were resuspended in 3 ml buffer W containing protease inhibitor. For solubilization of HrrS-CStrep and ChrS-CStrep, the membrane fraction was incubated with 1% n-Dodecyl-β-D-Maltoside (DDM) (Biomol, Germany) at 25°C on a rotary shaker for 1 h. After a second ultracentrifugation step (0.5 h, 150,000 × g, 4°C), solubilized HrrS-CStrep and ChrS-CStrep present in the supernatant were purified by strep-tactin affinity chromatography (1 ml column volume, CV). Equilibration was performed with 15 CV buffer W containing 0.03% DDM. After washing with 15 CV of buffer W containing 0.03% DDM, CStrep-proteins were eluted with 5 CV of buffer W containing 0.03% DDM and 15 mM desthiobiotin. Fractions containing the desired Strep-tagged proteins were pooled, and the buffer was exchanged against HEPES-buffer (20 mM HEPES, pH 7.5, 20 mM KCl, 20 mM MgCl2, 200 mM NaCl) using a PD10 desalting column (GE Healthcare, Munich, Germany). The purified proteins were kept at 4°C and immediately used for heme-binding studies. Purity of protein samples was analyzed on a 12% SDS-polyacrylamide gel, which was afterward stained with Coomassie brilliant blue (G250, VWR Chemicals, Pennsylvania, United States). The protein concentration was determined using the extinction coefficients [𝜀(HrrS) = 35535, 𝜀(ChrS) = 51575] with a nano-spectrophotometer at 280 nm. In our elution fractions, the DDM interfered with other assays such as Bradford protein assay or Pierce BCA Protein Assay (Thermo Fisher, Waltham, United States).

Western Blot Analysis

The production of HrrS and ChrS flag-tag variants was verified by western blot analysis. C. glutamicum ΔhrrS ΔchrS strains expressing a hrrS or chrS mutant gene (fused to the flag-gene) from the plasmid pKW3 under control of the native promotor were cultivated as described in the Section “Bacterial strains and growth conditions.” After 12 h, the cells were harvested and disrupted by passing a French pressure cell. Subsequently, 20 μg of protein extract were resuspended in SDS sample buffer (124 mM Tris–HCl, pH = 6.8, 20% (v/v) glycerol, 4.6% (w/v) SDS, 1.4 M β-mercaptoethanol, 0.01% (w/v) bromophenol blue) and the proteins separated by SDS-gel electrophoresis (12% separating gel, Bio-Rad Laboratories, Inc., United States). The gel was electroblotted via a Transblot Semi-Dry Transfer Cell (Bio-Rad Laboratories, Inc., United States) to a nitrocellulose membrane (Amersham® Hybond-ECL Membranes, GE Healthcare, Germany) in Towbin-Blotpuffer (25 mM Tris, 192 mM Glycin, 20 % (v/v) Methanol). Transfer was carried out for 45 min (15 V). The membrane was blocked for 1 h in TBST (20 mM Tris–HCl pH = 7.5, 500 mM NaCl, 0.05 % (v/v) Tween 20) with 5 % (w/v) skim milk powder and subsequently washed in TBST and for the specific detection of FLAG-tagged proteins. Membranes were incubated for 1 h in ANTI-FLAG®-antibody (produced in mouse, 5 μg/ml, Sigma–Aldrich, Munich, Germany). After washing in TBST (3×) the membrane was incubated in a 1:10000 dilution of peroxidase-coupled anti-mouse secondary antibody for 1 h (GE Healthcare, Germany). For the detection of peroxidase activity, the “Amersham ECL-Select Western Blotting Detection” regent was used (GE Healthcare, Germany) and analyzed with the LAS-3000 mini (Fuji Photo Film Co., Tokyo, Japan).

Heme-Binding Assays with Purified Protein

To assess the heme binding of purified kinases, we proceeded as following: after cell disruption and removal of cell debris by centrifugation, the cleared lysate of E. coli, overproducing HrrS or ChrS, was incubated with 50 μM hemin for 1 h at 4°C prior to ultracentrifugation of the cell-free extract for 1 h (150,000 × g, 4°C). Subsequently, the proteins were purified as described above. The purified protein was then analyzed via UV-visual spectroscopy: The absorption from 280 to 600 nm was determined using the UV/Visible double beam spectrophotometer UV-1601 PC (Shimadzu, Kyoto, Japan). For in vitro binding assays, purified protein (no pre-incubation with hemin) was added to buffer containing hemin concentrations from 0.5 to 36 μM and incubated for 5 min at room temperature. Subsequently, the absorption from 280 to 600 nm was determined. The samples were then referenced to respective hemin concentrations in buffer without protein.

In Vitro Phosphorylation Assays

The autophosphorylation of both full-length HKs was determined as follows: immediately after purification, both kinases were incubated with 0.25 μM[γ-33P]-ATP (10 mCi/ml; PerkinElmer, United States) mixed with 80 μM non-radioactive ATP. The mixture was incubated for up to 30 min and at different time points 7 μl aliquots were removed, mixed with an equal volume of 2 × SDS loading buffer (124 mM Tris–HCl, pH = 6.8, 20 % (v/v) glycerol, 4.6 % (w/v) SDS, 1.4 M β-mercaptoethanol, 0.01 % (w/v) bromophenol blue) and kept on ice. Without prior heating, the samples were subjected to an SDS–PAGE (12% separating gel, Bio-Rad Laboratories, Inc., United States). Dried, gels were exposed on storage phosphor imaging films (Fuji Photo Film Co., Tokyo, Japan) and analyzed with a Typhoon Trio Scanner (GE Healthcare, Germany) after 24 h.

Results

Transmembrane Organization of HrrS and ChrS Is Highly Conserved

The HrrSA and ChrSA systems represent two homologous TCS involved in heme-responsive gene regulation in C. glutamicum. Whereas the cytoplasmic domains of the HrrS and ChrS kinases show a high sequence identity (39.4% in the HisKA_3 domains), the N-terminal sensor domains share only minor conservation at the sequence level (8.5%, Supplementary Figure S1). In order to unravel mechanistic differences or similarities in signal perception, we analyzed the transmembrane topology of both N-terminal sensor domains. For this purpose, we used online prediction tools in combination with an experimental approach based on PhoA/LacZ fusions. For the prediction of membrane spanning α-helices different analysis tools were applied, including TopPredII (Claros and von Heijne, 1994), TMPred (Hofman and Stoffel, 1993), Hmmtop (Tusnady and Simon, 2001), Minnou polyview (Porollo et al., 2004), CBS TMHMM (Krogh et al., 2001), DAS (Cserzo et al., 1997) Mpex (Snider et al., 2009), TOPCONS (Tsirigos et al., 2015), and Phobius (Kall et al., 2007).

As indicated in Supplementary Table S3, five out of nine programs suggested five transmembrane helices (TMHs) for ChrS, whereas three tools predicted six TMHs. The outcome of this analysis was even more diverse in the case of HrrS, where predictions ranged from 3 to 7 TMHs for the HrrS sensor domain – highlighting the importance of experimental verification.

For each kinase gene, hrrS and chrS, several truncated versions were fused to the phoA and lacZ genes at their 3′-end, encoding the alkaline phosphatase (PhoA) or the β-galactosidase (LacZ), respectively (Figure 1A). By expressing these fusion genes in E. coli TG-1, C-terminally truncated forms of HrrS and ChrS were obtained, that are linked to intact PhoA or LacZ enzymes. While PhoA displays high enzymatic activity if located in the periplasm, LacZ is only active if the enzymatic part of the protein is accessible in the cytosol (Manoil, 1991). Positions of the fusion constructs were distributed over the N-terminal sensor domain while focusing on residues close to predicted TMHs. Remarkably, this analysis revealed that both kinases, HrrS (Figures 1B,D) and ChrS (Figures 1C,E), are embedded into the cytoplasmic membrane via six TMHs. Thus, despite their minor sequence similarity, HrrS and ChrS share a conserved membrane topology. Referring to the results of the topology prediction tools, only TOPCONS (Tsirigos et al., 2015) and HMMTOP (Tusnady and Simon, 2001) were in line with our experimental data for both HrrS and ChrS.

FIGURE 1
www.frontiersin.org

FIGURE 1. Experimental analysis of HrrS and ChrS membrane topology. (A) Sequence alignment of the N-terminal sensor domain of C. glutamicum HrrS and ChrS. A total of 20 truncated versions of HrrS or ChrS fused to the alkaline phosphatase (PhoA) or the β-galactosidase (LacZ) at the indicated amino acids positions were produced in E. coli TG-1 (A). Based on the results indicated in (B–E) fusion residues are marked in red (inside) or green (outside). (B)+(D): Enzymatic activities of 20 PhoA (up) and LacZ (down) fusions of HrrS and ChrS (given in miller units). The enzymatic activity of all fusion proteins was measured as described in the Section “Materials and Methods.” Data represent average values of three independent biological replicates. (C)+(E): Log10 of the PhoA-activity/LacZ-activity ratios. The graph outlines the membrane topology of the histidine kinases (HKs) HrrS and ChrS: a ratio of > ∼0.5 indicates an extracellular and < ∼-0.5 a cytoplasmic localization.

Target Gene Profiling Revealed a Higher Sensitivity of ChrS toward Heme in Comparison to HrrS

As a next step in the comparative analysis of HrrS and ChrS, we performed a profiling of target gene activation in response to heme as a stimulus. To avoid cross-phosphorylation between the systems and to focus on pathway activation mediated by only one of the two HKs, the deletion strains ΔchrS and ΔhrrS were transformed with the respective target gene reporter constructs (pJC1_PhmuO-eyfp and pJC1_PhrtBA-eyfp, respectively) (Hentschel et al., 2014). In the case of HrrS, the respective target promoter PhmuO already revealed a high background output caused by the iron limiting conditions leading to DtxR derepression (Wennerhold and Bott, 2006) (Figure 2, full spectra in Supplementary Figure S2). Heme-dependent activation via HrrS was only observed for heme concentrations above 4 μM resulting in a 1.5- to 1.7-fold induction (± 0.08/± 0.13) of the reporter (Figure 2A). In contrast to that the ChrS target gene reporter PhrtBA-eyfp (heme detoxification) showed almost no background activity and displayed a sensitive induction profile already at low (< 1.5 uM) heme concentrations, with a fold change of about 8 in the lower micromolar range (± 2.2, 0.2–1.5 μM) (Figure 2B). These findings are in agreement with previous data (Hentschel et al., 2014), suggesting a very sensitive response of the ChrSA system toward low heme levels, in contrast to the HrrSA system which facilitates heme utilization as an iron source, but only under iron limiting conditions (Figures 2C,D). Taken together, these results confirmed the heme-responsive activation of the HKs, but also provided evidence for differences in signal perception and ligand-binding affinity.

FIGURE 2
www.frontiersin.org

FIGURE 2. HrrS and ChrS target promoter profiling in response to heme. The C. glutamicum mutant strains ΔchrS or ΔhrrS were transformed with the target gene reporter pJC1_PhmuO-eyfp or pJC1_PhrtBA-eyfp, respectively. Cells were cultivated in a microbioreactor system (Biolector) in CGXII minimal medium with 2% (w/v) glucose containing 0–6 μM hemin. The maxima of the specific fluorescence after 7 h (PhmuO, A and C) or 3 h (PhrtBA, B and D) are shown. The specific fluorescence of mutant strains displaying background reporter levels was subtracted from the measurement (ΔhrrSA for PhmuO-eyfp and ΔchrSA for PhrtBA-eyfp). The reporter output over the time course of the experiment is shown in Supplementary Figure S2.

HrrS and ChrS Are Heme-Binding Proteins

In the following, we performed in vitro studies to test whether both kinases bind heme via their N-terminal sensor domain. Therefore, both proteins were purified from E. coli BL21 (DE3) by the means of an N-terminal Streptactin tag (see the section “Materials and Methods”). Subsequently, 10 μM of solubilized and purified protein was mixed with different concentrations of hemin and analyzed by ultraviolet-visible spectroscopy (UV-Vis). Resulting spectra with the characteristic soret-peak at 406–420 nm were referenced against a buffer control, containing only the DDM micelles, in the absence of protein. The maximum values of the characteristic soret-peaks of heme/protein interaction at 420 nm are shown in Figure 3.

FIGURE 3
www.frontiersin.org

FIGURE 3. UV-Vis analysis of the heme-binding properties of HrrS and ChrS. For hemin-binding assays, different amounts of hemin were titrated to 10 μM purified HrrS or ChrS to a final concentration of 0, 2, 4, 8, 16, and 32 μM. The mixture was incubated for 5 min at RT and then analyzed by UV-visual spectroscopy. The resulting absorption was referenced against the absorption of buffer containing only DDM micelles but no protein. The graph shows the maxima of the soret peaks at 420 nm.

In our assay, both HrrS and ChrS showed heme-binding properties and the absorbance ΔAbs420 saturated slightly above 8 μM suggesting that both kinases bind heme in a 1:1 ratio (see full spectra in Supplementary Figure S3). These data, thus, emphasize that ChrS and HrrS contain a single heme-binding site per monomer.

Identification of Putative Heme-Binding Residues by Alanine Scanning of HrrS

Subsequently, we aimed at the identification of amino acid residues potentially involved in heme binding. Therefore, several conserved residues in the transmembrane domain of HrrS were exchanged against alanine to disrupt the heme-protein interface. The chosen amino acid residues are conserved among HrrS orthologs of several Corynebacteriaceae species (Supplementary Figure S4) and located within the N-terminal sensor domain of the kinase. Proper synthesis of most resulting proteins in C. glutamicum was confirmed by western blot analysis (Figure 4B). The heme-responsive activation of HrrS was monitored by using the PhmuO-eyfp target gene reporter described earlier (Hentschel et al., 2014).

FIGURE 4
www.frontiersin.org

FIGURE 4. Alanine scanning of the N-terminal transmembrane domain of HrrS revealed putative heme-binding residues.(A) The C. glutamicum mutant strain ΔhrrSΔchrS was transformed with the target gene reporter pECXC99E_PhmuO-eyfp and the pkW3 plasmid either containing wild type hrrS under its native promoter (wt) or 1 of 15 hrrS variants, encoding the HK with a single amino acid exchange. All proteins contained a C-terminal FLAG tag fusion for western blot analysis. Cells were cultivated in a microbioreactor system (Biolector) in CGXII minimal medium with 2% (w/v) glucose containing 2.5 μM hemin. The specific fluorescence after 8 h is shown. Highlights three aromatic residues inside of helix 4 which were further investigated in following experiments. ∗∗Activation of the target gene reporter by the triple mutant HrrSY 112A-F115A-F118A. (B) Western blot of HrrS variants (20 μg raw protein extract) using an anti-FLAG® primary monoclonal ANTI-FLAG M2 antibody (5 μg/ml) and a peroxidase coupled anti-mouse secondary antibody.

Proteins were produced in a C. glutamicum ΔhrrSΔchrS mutant strain to avoid cross-activation by the respective non-cognate kinase (Hentschel et al., 2014). The C. glutamicum ΔhrrSΔchrS strain was transformed with the reporter plasmid pECXC99E_PhmuO-eyfp (chloramphenicol resistance) and complemented with pKW3 (kanamycin resistance) carrying either wild type hrrS under the control of its own promoter (PhrrS-hrrS) or one of the 15 hrrS single residue exchange variants. Whereas the empty vector control only displayed background levels of fluorescence, a significant reporter output could be restored by complementation with wild type hrrS (Figure 4A, full spectra shown in Supplementary Figure S5).

With this approach several residues were identified, that, upon exchange against alanine, led to a significantly reduced reporter output [up to 66 % reduction (Y112) compared to wild type HrrS]. Particularly interesting is a cluster of four aromatic amino acids inside or in close proximity of α-helix 4: W100-Y112-F115-F118. Indeed, previous studies revealed that tyrosine and phenylalanine residues are prime candidates for heme-interaction (Li et al., 2011). However, the tryptophan W100 appeared to be of structural importance for HrrS. This residue is located in the middle of α-helix three and purification of this variant led to a highly unstable and aggregated eluate, while HrrS-wt or other variants were purified as stable protein. Furthermore, HrrSW100A and HrrST97A show slightly reduced protein amounts in our western blot analysis (Figure 4B). Consequently, we concentrated on the triple residue, intermembrane motive Y112-F115-F118 (marked as in Figure 4). Exchange of the residue Y112 to alanine (HrrSY112A) resulted in reduced proteins levels (data not shown), and thus, HrrSY112F was used for further analysis (Figure 4B). In comparison with the single mutants, a simultaneous exchange of all three conserved residues (Y112-F115-F118), however, led to no further decrease in target promoter activation (Figure 4, marked as ∗∗). We speculate that even after complete loss of signal perception, HrrS will still exhibit background kinase activity resulting in the activation of hmuO transcription.

Based on the finding for HrrS, we also investigated the second kinase, ChrS, in an analogous experiment. However, here, the plasmid-based overexpression of chrS variants was hampered by the fact that ChrS appeared to exhibit a very strong phosphatase activity resulting in weak target promoter activation (pJC1_PhrtBA-eyfp) upon overproduction. Even for an expression of chrS on the same plasmid (pJC1_PhrtBA-eyfp_PchrS-chrS), only minor activities could be measured for the reporter (Supplementary Figure S6). Nevertheless, again the exchange of the three residues Y87, F90, and F94 resulted in a significantly lower reporter output. These residues are conserved in the sensor domains of HrrS and ChrS in C. glutamicum. However, because of the very low reporter output, the findings for ChrS must be viewed critically.

HrrSY 112A-F115A-F118A Shows Impaired Heme-Binding Properties

In the following, the role of the three aromatic amino acids, as putative heme-binding residues in HrrS, was further investigated in in vitro hemin-binding assays. For this purpose, wild type protein as well as the triple mutant HrrSY 112A-F115A-F118A were overproduced in E. coli BL21 and subsequently solubilized and purified as described in the Section “Materials and Methods.” Upon analysis of 12 μM of both proteins (no addition of heme) via UV-vis spectroscopy (280–600 nm) and normalization to the protein absorption (Abs280), HrrS consistently showed a soret band at 406 nm which was lacking for the triple mutant (Figure 5). This peak corresponds to small amounts of heme co-purified from the E. coli extracts. Remarkably, this peak was not observed for the HrrSY 112A-F115A-F118A triple mutant protein providing first evidence that heme binding of HrrS was impaired by the exchange of these residues (Figure 5). Also for the single HrrS mutants (HrrSY 112A, HrrSF115A, and HrrSF118A), ChrS, and the ChrSY 87A-F90A-F94A variant, no co-purification was observed either (Supplementary Figure S7).

FIGURE 5
www.frontiersin.org

FIGURE 5. Heme co-purifies together with wild type HrrS (solid line) but not with the triple mutant HrrSY 112A-F115A-F118A (dotted line). HrrS (solid line) and HrrSY 112A-F115A-F118A (dotted line) were purified from E. coli (BL21) cells as described in the Section “Materials and Methods.” The cells were grown for 16 h, expressing the kinases. No additional heme/hemin was added to the medium or lysate. The purified protein (12 μM) was conducted to UV-vis spectroscopy in a range from 280 to 600 nm. Both spectra were normalized to the absorption of the proteins (at 280 nm) and background absorption of buffer with micelles was subtracted from both spectra. An arrow indicates a small soret peak at 406 nm in the spectrum of wild type HrrS (solid line) which is not observable in the triple mutant (dotted line). The box shows a zoom into the peak area.

However, only a small fraction of the purified HrrS appeared to be in the heme-bound state. To enhance this effect, 50 μM hemin was added to the cleared E. coli lysate prior to protein purification. The lysate was incubated for 1 h at 4°C and subsequently, purification was carried out as described above. After this reconstitution, a significantly increased peak was observed for wild type HrrS after the purification, and now, even the single mutants or the triple mutant HrrSY 112A-F115A-F118A were co-purified with small amounts of heme/hemin (Figure 6). In contrast to the wild type protein, however, the binding was strongly reduced. Similar to the alanine scanning, no clear difference between the single (Figure 6A) and the triple mutants (Figure 6B) was noticeable, suggesting that all three residues are equally important for the formation of the heme-protein interface. In vitro autophosphorylation of HrrS and the triple mutant HrrSY 112A-F115A-F118A indicated that both proteins are correctly folded and enzymatically active (Supplementary Figure S8).

FIGURE 6
www.frontiersin.org

FIGURE 6. Heme-binding studies with single- and triple mutants of HrrS and ChrS. For all samples, 50 μM hemin was added to the cleared E. coli BL21 (DE3) lysate of cells overproducing either HrrS, one of the three HrrS single mutants (A) or the HrrS triple mutant (B). Additionally, ChrS and ChrSY 87A-F90A-F94A were analyzed in an analog experiment (C). After incubation of the lysate with 50 μM hemin for 1 h, ultracentrifugation, solubilization, and purification were carried out as described in the Section “Materials and Methods.” Purified protein samples (12 μM) were conducted to UV-vis spectroscopy and the resulting spectra were normalized to the absorption of the proteins at 280 nm. Background absorption of buffer with DDM micelles was subtracted.

Analogous experiments were performed for ChrS and the triple mutant ChrSY 87A-F90A-F94A. Both proteins were not purified with bound heme from E. coli membranes (Supplementary Figure S7). However, upon addition of hemin to the cleared lysate prior to purification a significant soret band at 406 nm emerged for ChrS demonstrating the ability of this protein to bind heme in vitro (Figure 6C). Interestingly, for ChrSY 87A-F90A-F94A, the peak volume was not reduced but showed a significant red shift from 406 to 418 nm. Thus, heme binding of ChrSY 87A-F90A-F94A is somehow affected but obviously, the heme-protein interface differs from HrrS where exchange of the same conserved triplet (HrrSY 112A-F115A-F118A) almost abolished heme binding in the homologous HK.

Discussion

Bacterial heme homeostasis relies on complex regulatory networks integrating iron- and heme availability to harmonize intracellular processes involved in heme degradation (e.g., HmuO), export (HrtBA), biosynthesis, and heme-containing proteins (Andrews et al., 2003; Yasmin et al., 2011). The Gram-positive soil bacterium C. glutamicum, remarkably, invests 2 out of 13 TCS for the maintenance of heme homeostasis (Frunzke et al., 2011; Bott and Brocker, 2012; Heyer et al., 2012). Information on iron availability is integrated into the network via the global iron-dependent regulator DtxR, which represses both the hmuO gene as well as hrrA encoding the RR of the HrrSA “heme utilization system” (Wennerhold and Bott, 2006). This overall network topology is conserved between the non-pathogenic soil bacterium C. glutamicum and the prominent pathogen C. diphtheriae highlighting that heme regulatory processes are not restricted to pathogens of vertebrates but represent a significant fitness trait of many bacterial species in the battle for iron.

In this study, we demonstrated that the two HKs of the TCS, HrrSA, and ChrSA, bind heme in a 1:1 stoichiometry per HK monomer. This is in agreement with previous studies reporting the activation of HrrSA and ChrSA target gene expression (e.g., hmuO and hrtBA, respectively) in response to heme availability (Bibb et al., 2007; Bibb and Schmitt, 2010; Frunzke et al., 2011; Heyer et al., 2012; Hentschel et al., 2014; Burgos and Schmitt, 2016).

For both kinases, heme binding occurs at an N-terminal sensing domain which is embedded in the cytoplasmic membrane via six TMHs connected by only small loop regions (Figure 7A). Although our studies revealed a similar membrane topology, the sequence conservation of the sensor domain is rather minor (8.5% sequence identity). This is in line with the finding that heme recognition differs between the systems. Whereas exchange of three conserved aromatic residues (tyrosine 112 and the phenylalanine residues 115 and 118) almost abolished heme binding of HrrS, exchange of these amino acids in the sensor domain of ChrS only resulted in a red shift of the soret band toward an absorption maximum at 418 nm. Differences in heme perception are also reflected by the profiling assay demonstrating a much more sensitive response of the ChrS kinase to heme as a stimulus (Figure 2). The central iron atom of heme can either be bound in a penta- or hexa-coordinated manner (Brewitz et al., 2017). The position of the soret band of heme-binding proteins is significantly influenced by the chemical nature of the amino acid ligands (Vickery et al., 1976). Because of this, one can speculate that an altered set of ligands with different chemical properties participates in heme binding of the triple mutant ChrSY 87A-F90A-F94A, resulting in a red shift of the soret band. This set of alternative ligands seems not to be present in HrrS, however. Based on these findings, we cannot exclude that the triplet of conserved aromatic residues is involved in ChrS heme binding as well.

FIGURE 7
www.frontiersin.org

FIGURE 7. Topology model of the N-terminal transmembrane domain of the two HKs HrrS and ChrS. (A) Sequence alignment of the N-terminal parts of HrrS and ChrS was generated using ClustalW, and the transmembrane helices indicated are based on predictions and in agreement with our PhoA/LacZ-Screening. (B,C) Scheme of the topology of HrrS and ChrS. Circles represent single amino acids, red indicates high LacZ-activity of the fusion protein (intracellular localization), and green high PhoA activity (extracellular localization). The three putative heme-binding residues of HrrS, Y112, F115, and F118, are indicated as dark green circles in helix number four (B).

Sequence analysis of ChrS/HrrS paralogs revealed that the three aromatic residues are highly conserved in different Corynebacteriaceae species (Supplementary Figure S3). In their recent study, Li et al. (2011) analyzed the top five amino acids with high frequencies in heme-binding pockets and concluded that cysteine, histidine, methionine as well as tyrosine and phenylalanine are the most prominent residues in such interaction centers. Attributed to the chemical versatility of the heme molecule, different heme-protein interactions are possible (Brewitz et al., 2017). Whereas amino acids may act as axial ligands of the central iron atom via sulfur, nitrogen or oxygen donor atoms (cysteine, histidine, lysine, and tyrosine, respectively), π-stacking interactions via aromatic residues (phenylalanine, tyrosine, or tryptophan) may also contribute to the heme interface. For HrrS, we identified three aromatic residues (Y112, F115, and F118), which upon exchange, led to a reduced reporter output in response to heme. Remarkably, an exchange of Y112 to phenylalanine (lacking the hydroxyl group of tyrosine) led to a drastically reduced heme binding (Figures 5, 6). We therefore speculate that the tyrosine 112 may act as an axial ligand of the central iron atom. Also in NEAT (NEAr Transporter) proteins, several well-studied cases confirmed single tyrosine residues coordinating the central metal ion of the heme molecule (Grigg et al., 2007; Sharp et al., 2007; Villareal et al., 2008).

While Y112 is concluded to be crucial for the interaction with the iron atom, the phenylalanine residues F115 and F118 might be important for the interface through aromatic stacking interactions with the porphyrin ring of heme (Schneider et al., 2007; Smith et al., 2010; Li et al., 2011). Interestingly, a single proline residue (P116) is located between the two phenylalanine residues and is, together with the YFF motif, conserved between HrrS and ChrS (Figure 6A). This amino acid might be involved in shaping the heme interface by kinking the α-helix number four (von Heijne, 1991) thereby creating a heme-binding pocket consisting of the three residues Y112-F115-Y118 (Figure 7B). This effect has been demonstrated for the cysteine-proline (CP) dipeptide motif representing a prominent heme-regulatory motif (Lathrop and Timko, 1993).

In C. diphtheriae, the ChrS membrane topology was predicted using the two tools TMpred and DAS and experimentally analyzed via six PhoA/LacZ fusions (Bibb and Schmitt, 2010). Comparable to HrrS and ChrS in C. glutamicum, six TMHs were postulated (Figures 7B,C). In this study, alanine scanning of the N-terminus of this homologous protein revealed several kinase mutants with inability to activate the target operon hrtBA. A conserved tyrosine residue in TMH number two (Y61) was postulated as a prime candidate for heme binding (Bibb and Schmitt, 2010). This amino acid Y61 in ChrS (C. diphtheriae) corresponds to Y74 in HrrS (C. glutamicum, see Supplementary Figure S3). However, in our study the exchange of this residue to alanine had no significant effect (Figure 4). In contrast, the exchange of phenylalanine residue 114 to alanine in C. diphtheriae ChrS (TMH number four) led to a 40% decreased PhrtBA activity. Interestingly, this residue is conserved between most Corynebacteriaceae and as supporting evidence phenylalanine F118 is part of our postulated Y112-F115-F118 heme-protein interface in HrrS, suggesting a conserved function and mode of interaction.

As a further heme-responsive TCS, Stauff and Skaar (2009a,b) characterized the conserved HssRS of Staphylococcus aureus and Bacillus anthracis and predicted an N-terminal periplasmic sensing domain flanked by two transmembrane helices. Their findings indicate that the mode of signal perception of HssS (S. aureus and B. anthracis) vastly differs from HrrS/ChrS from Corynebacterium species. Exchange of several residues in the extracellular part of B. antracis HssS did not lead to the identification of the heme-binding site, but the fact, that the sensing domain is flanked by two helices led to the prediction, that this protein detects a signal located either in the periplasm or within the membrane itself, similar to HrrS (Stauff and Skaar, 2009a). As in our study, the exchange of residues likely not involved in heme binding (such as arginine or lysine) showed reduced phenotype complementation and led to the speculation that this domain might be more involved in signal transduction than previously expected.

In summary, this study provides evidence for a direct sensing of heme via the N-terminal sensor domain of the HKs ChrS and HrrS in C. glutamicum. Although the particular binding pocket may differ between the proteins, they represent two further examples of proteins involved in transient heme-sensing of bacteria. Considering the versatile composition of heme–protein interfaces in nature, the molecular and structural analysis of heme proteins provides an important basis for the prediction of novel domains potentially involved in heme sensing.

Author Contributions

MK, ED, and JF conceived the study; MK, ED, and CG performed the experiments; MK and ED analyzed the data; and MK and JF wrote the manuscript.

Funding

The authors acknowledge financial support by the Deutsche Forschungsgemeinschaft (FR 2759/4-1) and by the Helmholtz Association (W2/W3-096).

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

We thank Jacqueline Fuchs and Simon Lemm for their help with the cloning of several constructs.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fmicb.2018.00183/full#supplementary-material

References

Andrews, N. C. (2008). Forging a field: the golden age of iron biology. Blood 112, 219–230. doi: 10.1182/blood-2007-12-077388

PubMed Abstract | CrossRef Full Text | Google Scholar

Andrews, S. C., Robinson, A. K., and Rodriguez-Quinones, F. (2003). Bacterial iron homeostasis. FEMS Microbiol. Rev. 27, 215–237. doi: 10.1016/S0168-6445(03)00055-X

CrossRef Full Text | Google Scholar

Anzaldi, L. L., and Skaar, E. P. (2010). Overcoming the heme paradox: heme toxicity and tolerance in bacterial pathogens. Infect. Immun. 78, 4977–4989. doi: 10.1128/IAI.00613-10

PubMed Abstract | CrossRef Full Text | Google Scholar

Bauer, J., Fritsch, M. J., Palmer, T., and Unden, G. (2011). Topology and accessibility of the transmembrane helices and the sensory site in the bifunctional transporter DcuB of Escherichia coli. Biochemistry 50, 5925–5938. doi: 10.1021/bi1019995

PubMed Abstract | CrossRef Full Text | Google Scholar

Bibb, L. A., Kunkle, C. A., and Schmitt, M. P. (2007). The ChrA-ChrS and HrrA-HrrS signal transduction systems are required for activation of the hmuO promoter and repression of the hemA promoter in Corynebacterium diphtheriae. Infect. Immun. 75, 2421–2431. doi: 10.1128/IAI.01821-06

PubMed Abstract | CrossRef Full Text | Google Scholar

Bibb, L. A., and Schmitt, M. P. (2010). The ABC transporter HrtAB confers resistance to hemin toxicity and is regulated in a hemin-dependent manner by the ChrAS two-component system in Corynebacterium diphtheriae. J. Bacteriol. 192, 4606–4617. doi: 10.1128/JB.00525-10

PubMed Abstract | CrossRef Full Text | Google Scholar

Bott, M., and Brocker, M. (2012). Two-component signal transduction in Corynebacterium glutamicum and other corynebacteria: on the way towards stimuli and targets. Appl. Microbiol. Biotechnol. 94, 1131–1150. doi: 10.1007/s00253-012-4060-x

PubMed Abstract | CrossRef Full Text | Google Scholar

Bowman, S. E., and Bren, K. L. (2008). The chemistry and biochemistry of heme c: functional bases for covalent attachment. Nat. Prod. Rep. 25, 1118–1130. doi: 10.1039/b717196j

PubMed Abstract | CrossRef Full Text | Google Scholar

Brewitz, H. H., Hagelueken, G., and Imhof, D. (2017). Structural and functional diversity of transient heme binding to bacterial proteins. Biochim. Biophys. Acta 1861, 683–697. doi: 10.1016/j.bbagen.2016.12.021

PubMed Abstract | CrossRef Full Text | Google Scholar

Burgos, J. M., and Schmitt, M. P. (2016). The ChrSA and HrrSA two-component systems are required for transcriptional regulation of the hemA promoter in Corynebacterium diphtheriae. J. Bacteriol. 198, 2419–2430. doi: 10.1128/JB.00339-16

PubMed Abstract | CrossRef Full Text | Google Scholar

Claros, M. G., and von Heijne, G. (1994). TopPred II: an improved software for membrane protein structure predictions. Comput. Appl. Biosci. 10, 685–686. doi: 10.1093/bioinformatics/10.6.685

PubMed Abstract | CrossRef Full Text | Google Scholar

Cornelis, P., Wei, Q., Andrews, S. C., and Vinckx, T. (2011). Iron homeostasis and management of oxidative stress response in bacteria. Metallomics 3, 540–549. doi: 10.1039/c1mt00022e

PubMed Abstract | CrossRef Full Text | Google Scholar

Cserzo, M., Wallin, E., Simon, I., von Heijne, G., and Elofsson, A. (1997). Prediction of transmembrane alpha-helices in prokaryotic membrane proteins: the dense alignment surface method. Protein Eng. 10, 673–676. doi: 10.1093/protein/10.6.673

PubMed Abstract | CrossRef Full Text | Google Scholar

Eikmanns, B. J., Thum-Schmitz, N., Eggeling, L., Ludtke, K. U., and Sahm, H. (1994). Nucleotide sequence, expression and transcriptional analysis of the Corynebacterium glutamicum gltA gene encoding citrate synthase. Microbiology 140(Pt 8), 1817–1828. doi: 10.1099/13500872-140-8-1817

PubMed Abstract | CrossRef Full Text | Google Scholar

Finn, R. D., Mistry, J., Tate, J., Coggill, P., Heger, A., Pollington, J. E., et al. (2010). The Pfam protein families database. Nucleic Acids Res. 38, D211–D222. doi: 10.1093/nar/gkp985

PubMed Abstract | CrossRef Full Text | Google Scholar

Frunzke, J., Gätgens, C., Brocker, M., and Bott, M. (2011). Control of heme homeostasis in Corynebacterium glutamicum by the two-component system HrrSA. J. Bacteriol. 193, 1212–1221. doi: 10.1128/JB.01130-10

PubMed Abstract | CrossRef Full Text | Google Scholar

Gibson, D. G., Young, L., Chuang, R. Y., Venter, J. C., Hutchison, C. A. III, and Smith, H. O. (2009). Enzymatic assembly of DNA molecules up to several hundred kilobases. Nat. Methods 6, 343–345. doi: 10.1038/nmeth.1318

PubMed Abstract | CrossRef Full Text | Google Scholar

Grigg, J. C., Vermeiren, C. L., Heinrichs, D. E., and Murphy, M. E. (2007). Haem recognition by a Staphylococcus aureus NEAT domain. Mol. Microbiol. 63, 139–149. doi: 10.1111/j.1365-2958.2006.05502.x

PubMed Abstract | CrossRef Full Text | Google Scholar

Hentschel, E., Mack, C., Gätgens, C., Bott, M., Brocker, M., and Frunzke, J. (2014). Phosphatase activity of the histidine kinases ensures pathway specificity of the ChrSA and HrrSA two-component systems in Corynebacterium glutamicum. Mol. Microbiol. 92, 1326–1342. doi: 10.1111/mmi.12633

PubMed Abstract | CrossRef Full Text | Google Scholar

Heyer, A., Gätgens, C., Hentschel, E., Kalinowski, J., Bott, M., and Frunzke, J. (2012). The two-component system ChrSA is crucial for haem tolerance and interferes with HrrSA in haem-dependent gene regulation in Corynebacterium glutamicum. Microbiology 158, 3020–3031. doi: 10.1099/mic.0.062638-0

PubMed Abstract | CrossRef Full Text | Google Scholar

Hofman, K., and Stoffel, W. (1993). A database of membrane spanning proteins segments. J. Biol. Chem. 374:166.

Google Scholar

Ito, Y., Nakagawa, S., Komagata, A., Ikeda-Saito, M., Shiro, Y., and Nakamura, H. (2009). Heme-dependent autophosphorylation of a heme sensor kinase, ChrS, from Corynebacterium diphtheriae reconstituted in proteoliposomes. FEBS Lett. 583, 2244–2248. doi: 10.1016/j.febslet.2009.06.001

PubMed Abstract | CrossRef Full Text | Google Scholar

Kalinowski, J., Bathe, B., Bartels, D., Bischoff, N., Bott, M., Burkovski, A., et al. (2003). The complete Corynebacterium glutamicum ATCC 13032 genome sequence and its impact on the production of L-aspartate-derived amino acids and vitamins. J. Biotechnol. 104, 5–25. doi: 10.1016/S0168-1656(03)00154-8

PubMed Abstract | CrossRef Full Text | Google Scholar

Kall, L., Krogh, A., and Sonnhammer, E. L. (2007). Advantages of combined transmembrane topology and signal peptide prediction–the Phobius web server. Nucleic Acids Res. 35, W429–W432. doi: 10.1093/nar/gkm256

PubMed Abstract | CrossRef Full Text | Google Scholar

Keilhauer, C., Eggeling, L., and Sahm, H. (1993). Isoleucine synthesis in Corynebacterium glutamicum: molecular analysis of the ilvB-ilvN-ilvC operon. J. Bacteriol. 175, 5595–5603. doi: 10.1128/jb.175.17.5595-5603.1993

PubMed Abstract | CrossRef Full Text | Google Scholar

Kensy, F., Zang, E., Faulhammer, C., Tan, R. K., and Buchs, J. (2009). Validation of a high-throughput fermentation system based on online monitoring of biomass and fluorescence in continuously shaken microtiter plates. Microb. Cell Fact. 8:31. doi: 10.1186/1475-2859-8-31

PubMed Abstract | CrossRef Full Text | Google Scholar

Krogh, A., Larsson, B., von Heijne, G., and Sonnhammer, E. L. (2001). Predicting transmembrane protein topology with a hidden Markov model: application to complete genomes. J. Mol. Biol. 305, 567–580. doi: 10.1006/jmbi.2000.4315

PubMed Abstract | CrossRef Full Text | Google Scholar

Lathrop, J. T., and Timko, M. P. (1993). Regulation by heme of mitochondrial protein transport through a conserved amino acid motif. Science 259, 522–525. doi: 10.1126/science.8424176

CrossRef Full Text | Google Scholar

Laub, M. T., and Goulian, M. (2007). Specificity in two-component signal transduction pathways. Annu. Rev. Genet. 41, 121–145. doi: 10.1146/annurev.genet.41.042007.170548

CrossRef Full Text | Google Scholar

Li, T., Bonkovsky, H. L., and Guo, J.-T. (2011). Structural analysis of heme proteins: implications for design and prediction. BMC Struct. Biol. 11:13. doi: 10.1186/1472-6807-11-13

PubMed Abstract | CrossRef Full Text | Google Scholar

Manoil, C. (1991). Analysis of membrane protein topology using alkaline phosphatase and beta-galactosidase gene fusions. Methods Cell Biol. 34, 61–75. doi: 10.1016/S0091-679X(08)61676-3

CrossRef Full Text | Google Scholar

Mascher, T., Helmann, J. D., and Unden, G. (2006). Stimulus perception in bacterial signal-transducing histidine kinases. Microbiol. Mol. Biol. Rev. 70, 910–938. doi: 10.1128/MMBR.00020-06

PubMed Abstract | CrossRef Full Text | Google Scholar

Miller, J. H. (1992). A Short Course in Bacterial Genetics: A Laboratory Manual and Handbook for Escherichia coli and Related Bacteria. Plainview, NY: Cold Spring Harbor Laboratory Press.

Google Scholar

Porollo, A. A., Adamczak, R., and Meller, J. (2004). POLYVIEW: a flexible visualization tool for structural and functional annotations of proteins. Bioinformatics 20, 2460–2462. doi: 10.1093/bioinformatics/bth248

PubMed Abstract | CrossRef Full Text | Google Scholar

Poulos, T. L. (2007). The Janus nature of heme. Nat. Prod. Rep. 24, 504–510. doi: 10.1039/b604195g

PubMed Abstract | CrossRef Full Text | Google Scholar

Sambrook, J., and Russell, D. W. (2001). Molecular Cloning: A Laboratory Manual, 3rd Edn. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory Press.

Google Scholar

Schneider, S., Marles-Wright, J., Sharp, K. H., and Paoli, M. (2007). Diversity and conservation of interactions for binding heme in b-type heme proteins. Nat. Prod. Rep. 24, 621–630. doi: 10.1039/b604186h

PubMed Abstract | CrossRef Full Text | Google Scholar

Sharp, K. H., Schneider, S., Cockayne, A., and Paoli, M. (2007). Crystal structure of the heme-IsdC complex, the central conduit of the Isd iron/heme uptake system in Staphylococcus aureus. J. Biol. Chem. 282, 10625–10631. doi: 10.1074/jbc.M700234200

PubMed Abstract | CrossRef Full Text | Google Scholar

Smith, L. J., Kahraman, A., and Thornton, J. M. (2010). Heme proteins–diversity in structural characteristics, function, and folding. Proteins 78, 2349–2368. doi: 10.1002/prot.22747

PubMed Abstract | CrossRef Full Text | Google Scholar

Snider, C., Jayasinghe, S., Hristova, K., and White, S. H. (2009). MPEx: a tool for exploring membrane proteins. Protein Sci. 18, 2624–2628. doi: 10.1002/pro.256

PubMed Abstract | CrossRef Full Text | Google Scholar

Stauff, D. L., and Skaar, E. P. (2009a). Bacillus anthracis HssRS signalling to HrtAB regulates haem resistance during infection. Mol. Microbiol. 72, 763–778. doi: 10.1111/j.1365-2958.2009.06684.x

PubMed Abstract | CrossRef Full Text | Google Scholar

Stauff, D. L., and Skaar, E. P. (2009b). The heme sensor system of Staphylococcus aureus. Contrib. Microbiol. 16, 120–135. doi: 10.1159/000219376

PubMed Abstract | CrossRef Full Text | Google Scholar

Stock, A. M., Robinson, V. L., and Goudreau, P. N. (2000). Two-component signal transduction. Annu. Rev. Biochem. 69, 183–215. doi: 10.1146/annurev.biochem.69.1.183

CrossRef Full Text | Google Scholar

Tsirigos, K. D., Peters, C., Shu, N., Kall, L., and Elofsson, A. (2015). The TOPCONS web server for consensus prediction of membrane protein topology and signal peptides. Nucleic Acids Res. 43, W401–W407. doi: 10.1093/nar/gkv485

PubMed Abstract | CrossRef Full Text | Google Scholar

Tusnady, G. E., and Simon, I. (2001). The HMMTOP transmembrane topology prediction server. Bioinformatics 17, 849–850. doi: 10.1093/bioinformatics/17.9.849

CrossRef Full Text | Google Scholar

Vickery, L., Nozawa, T., and Sauer, K. (1976). Magnetic circular dichroism studies of myoglobin complexes. Correlations with heme spin state and axial ligation. J. Am. Chem. Soc. 98, 343–350. doi: 10.1021/ja00418a005

PubMed Abstract | CrossRef Full Text | Google Scholar

Villareal, V. A., Pilpa, R. M., Robson, S. A., Fadeev, E. A., and Clubb, R. T. (2008). The IsdC protein from Staphylococcus aureus uses a flexible binding pocket to capture heme. J. Biol. Chem. 283, 31591–31600. doi: 10.1074/jbc.M801126200

PubMed Abstract | CrossRef Full Text | Google Scholar

von Heijne, G. (1991). Proline kinks in transmembrane alpha-helices. J. Mol. Biol. 218, 499–503. doi: 10.1016/0022-2836(91)90695-3

CrossRef Full Text | Google Scholar

Wennerhold, J., and Bott, M. (2006). The DtxR regulon of Corynebacterium glutamicum. J. Bacteriol. 188, 2907–2918. doi: 10.1128/JB.188.8.2907-2918.2006

PubMed Abstract | CrossRef Full Text | Google Scholar

Yasmin, S., Andrews, S. C., Moore, G. R., and Le Brun, N. E. (2011). A new role for heme, facilitating release of iron from the bacterioferritin iron biomineral. J. Biol. Chem. 286, 3473–3483. doi: 10.1074/jbc.M110.175034

PubMed Abstract | CrossRef Full Text | Google Scholar

Zschiedrich, C. P., Keidel, V., and Szurmant, H. (2016). Molecular mechanisms of two-component signal transduction. J. Mol. Biol. 428, 3752–3775. doi: 10.1016/j.jmb.2016.08.003

PubMed Abstract | CrossRef Full Text | Google Scholar

Keywords: Corynebacterium glutamicum, two-component systems, heme, heme-binding protein, transient heme sensing, ChrSA, HrrSA

Citation: Keppel M, Davoudi E, Gätgens C and Frunzke J (2018) Membrane Topology and Heme Binding of the Histidine Kinases HrrS and ChrS in Corynebacterium glutamicum. Front. Microbiol. 9:183. doi: 10.3389/fmicb.2018.00183

Received: 11 December 2017; Accepted: 26 January 2018;
Published: 09 February 2018.

Edited by:

Marc Bramkamp, Ludwig-Maximilians-Universität München, Germany

Reviewed by:

Iain Sutcliffe, Northumbria University, United Kingdom
Angela Wilks, University of Maryland, Baltimore, United States

Copyright © 2018 Keppel, Davoudi, Gätgens and Frunzke. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Julia Frunzke, j.frunzke@fz-juelich.de

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.