Assessing the Exoproteome of Marine Bacteria, Lesson from a RTX-Toxin Abundantly Secreted by Phaeobacter Strain DSM 17395

Emie Durighello; Joseph Alexander Christie-Oleza; Jean Armengaud

doi:10.1371/journal.pone.0089691

Abstract

Bacteria from the Roseobacter clade are abundant in surface marine ecosystems as over 10% of bacterial cells in the open ocean and 20% in coastal waters belong to this group. In order to document how these marine bacteria interact with their environment, we analyzed the exoproteome of Phaeobacter strain DSM 17395. We grew the strain in marine medium, collected the exoproteome and catalogued its content with high-throughput nanoLC-MS/MS shotgun proteomics. The major component represented 60% of the total protein content but was refractory to either classical proteomic identification or proteogenomics. We de novo sequenced this abundant protein with high-resolution tandem mass spectra which turned out being the 53 kDa RTX-toxin ZP_02147451. It comprised a peptidase M10 serralysin domain. We explained its recalcitrance to trypsin proteolysis and proteomic identification by its unusual low number of basic residues. We found this is a conserved trait in RTX-toxins from Roseobacter strains which probably explains their persistence in the harsh conditions around bacteria. Comprehensive analysis of exoproteomes from environmental bacteria should take into account this proteolytic recalcitrance.

Citation: Durighello E, Christie-Oleza JA, Armengaud J (2014) Assessing the Exoproteome of Marine Bacteria, Lesson from a RTX-Toxin Abundantly Secreted by Phaeobacter Strain DSM 17395. PLoS ONE 9(2): e89691. https://doi.org/10.1371/journal.pone.0089691

Editor: Daniel Gillet, CEA (Atomic and Alternative Energies Commission), France

Received: December 4, 2013; Accepted: January 21, 2014; Published: February 24, 2014

Copyright: © 2014 Durighello et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: JA Christie-Oleza was supported by a fellowship from the Fundación Ramón Areces. The authors thank the Commissariat à l’Energie Atomique et aux Energies Alternatives for financial support. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

The extremely high diversity of marine microorganisms was shown ever since the first large metagenomic shotgun analysis carried out on total DNA extracted from filtered seawater samples collected from the Sargasso Sea near Bermuda [1]. Heterotrophic bacterioplankton communities in near-surface marine pelagic environments mostly comprise Alphaproteobacteria and Gammaproteobacteria, as well as Sphingobacteria and Flavobacteria (both belonging to the Bacteroidetes superphylum). As shown recently with environmental metagenomic data, prominent components belong to the SAR11, Roseobacter and SAR86 clades together with the OM60/NOR5 cluster [2]. The Roseobacter lineage is a phylogenetically coherent group of Alphaproteobacteria comprising up to 20% of marine microbial communities, especially in coastal and polar waters [3]. However, the Roseobacter clade is a physiologically heterogeneous group showing a high variety of lithoheterotrophic strategies. Despite a free-living lifestyle, Roseobacter strains are also found as planktonic or larger pluricellular symbionts [4].

Today, in-depth analysis of a microbial proteome relies on the use of high-resolution hybrid tandem mass spectrometers coupled to high-pressure liquid chromatography systems able to resolve complex peptide mixtures [5], [6]. A comprehensive list of proteins and their quantitation in several physiological conditions by such shotgun approaches are a rather straightforward method [7], [8]. Exoproteomes comprise the fraction of proteins secreted by cellular systems and proteins arising from cell lysis [9]. These are generally subjected to intense proteolytic activities and most components have a short half-life. Nevertheless, key components involved in nutrient imports, cell motility, signaling and interactions with other organisms should be refractory to proteolysis in order to be efficient. Analysis of bacterial secretomes is an important issue for the discovery of novel bioactive compounds and to determine how organisms interact within their environment. We have shown that microbial exoproteomes can be comprehensively analyzed by high throughput shotgun proteomics [10], [11]. The use of the most recent generation of hybrid tandem mass spectrometers revealed a high diversity of protein virulence factors in the pathogenic Bacillus cereus bacteria [11]. To date, only a few exoproteome analyses have been reported on environmental avirulent isolates [10], [12]. In this case, the data obtained helped elucidating the ecological distinctness among strains of the Roseobacter clade. Microbial exoproteomes are also insightful for understanding the molecular mechanisms of bacterial colonization of biotic or abiotic surfaces, i.e. bacterial adhesion and biofilm formation [13]. Their exploration gains ground with the current development of proteomic tools for environmental microbiology [14].

Phaeobacter gallaeciensis BS107 (previously Roseobacter gallaeciensis BS107) is the type species of the Phaeobacter genus [15]. This strain was obtained from larval cultures and collectors of the scallop Pecten maximus [16]. Other species of the genus have since been described: Phaeobacter inhibens, isolated from the German Wadden Sea [15], Phaeobacter daeponensis, isolated from a tidal flat of the Yellow Sea at Daepo Beach in Korea [17], and Phaeobacter arcticus, a psychrophilic species isolated from marine sediments of the Arctic Ocean [18]. Phaeobacter inhibens was in-depth characterized with proteomics and metabolomics approaches highlighting its versatile metabolism [19], [20], [21], [22]. The type species Phaeobacter strain DSM 17395 was shown to be able to produce a new tropolone derivative, tropodithietic acid, which exhibits strong antibiotic properties against marine bacteria of various taxa and marine algae [23], [24]. Additional studies led to the identification of nine new troponoid compounds belonging to the bacterial roseobacticide family [25]. More recently, it has been shown that Phaeobacter strain DSM 17395 switches its secreted molecule metabolism to the production of potent and selective algaecides in response to p-coumaric acid, an algal lignin breakdown product that is symptomatic of aging algae. This switch converts Phaeobacter strain DSM 17395 into an opportunistic pathogen of its algal host [26] and highlights the interest of the study of its secretome. The type strain Phaeobacter gallaeciensis BS107T has been deposited at public culture collections worldwide. Recently, it was shown that the Phaeobacter strain DSM 17395, previously annotated as Phaeobacter gallaeciensis BS107T, exhibits a much closer affiliation to Phaeobacter inhibens DSM 16374T and should thus be allocated to this species [27].

With the intention to further characterize the ecological distinctness of Roseobacters members and how they interact with their environment, we analyzed the secreted proteins of Phaeobacter strain DSM 17395. For this, we grew the strain in marine medium, collected the exoproteome and catalogued its protein content with high throughput nanoLC-MS/MS shotgun proteomics. Interestingly, the major protein in this exoproteome was recalcitrant to classical proteomic identification. Indeed it appears very abundant on SDS-PAGE migration but no protein was matching this band after proteomic analysis. A de novo sequencing strategy identified peptides of a RTX-like toxin which led to re-analyze proteomics data with no-enzyme specificity. This RTX-like toxin was then clearly identified. We found that this protein and its homologues exhibit unusually low content in basic residues. From these results, we proposed a general strategy to obtain more comprehensive exoproteome analyses of environmental bacteria.

Materials and Methods

P. gallaenciensis Growth and Exoproteome Preparation

Four flasks containing 40 mL of marine broth (Difco) were inoculated with Phaeobacter strain DSM 17395 cells previously grown on marine agar plates. The cultures were incubated at 30°C under 180 rpm agitation until mid-exponential phase growth (OD₆₀₀ = 0.6). Cultures were centrifuged at 3,000 g for 10 min at 20°C and supernatants were carefully filtered through two low protein-binding filters of 0.45 µm (Millex-Hv) and then 0.22 µm (Millex-GV) diameter pore (Millipore) in order to eliminate bacterial cells. Supernatants were frozen prior protein precipitation. Proteins from the supernatant were precipitated with tricholoroacetic acid as previously described [10]. The resulting protein pellets were dissolved into 90 µl of lithium dodecyl sulfate-β-mercaptoethanol protein gel sample buffer (Invitrogen), incubated at 99°C for 5 min and briefly centrifuged prior SDS-PAGE.

SDS-PAGE and Trypsin-in gel Proteolysis

A volume of 20 µl of the concentrated exoproteome of Phaeobacter strain DSM 17395 was deposited per well onto 10% Bis-Tris NuPAGE gels (Invitrogen). SDS-PAGE was carried out using 1X 3-(N-morpholino) propanesulfonic acid solution (Invitrogen) in a XCell SureLock Mini-cell (Invitrogen) under a constant voltage of 200 V. At first, a long migration was carried out in order to fully resolve the exoproteome according to its molecular weight. For the proteomic shotgun analysis, the entire exoproteome was allowed to enter the polyacrylamide gel in a short migration (3 mm). Both gels were stained with SimplyBlue SafeStain, a ready-to-use Coomassie G-250 stain (Invitrogen). SeeBlue Plus2 (Invitrogen) was used as a molecular weight marker. Densitometry analysis of the long-migrated SDS-PAGE gel was carried out with the molecular imager GS-800 calibrated densitometer (BioRad) and the Quantity One software (version 4.6.9, BioRad) in order to establish the relative abundance of the main protein band. Densitometric relative ratio was obtained by comparing the density signal of each band to the total signal of the whole gel lane. These measurements were done in triplicate. Polyacrylamide gel bands (equivalent in volume to 50 µl) were cut and processed for in-gel proteolysis with Trypsin Sequencing Grade (Roche) followed by the ProteaseMax protocol (Promega) as previously described [11].

NanoLC-MS/MS Analysis

Peptide digests were resolved on an UltiMate 3000 LC system (Dionex-LC Packings) as previously described [28] prior to MS/MS measurements done with a LTQ-Orbitrap XL (ThermoFisher). For the FT/IT procedure, parameters used for the tandem mass spectrometry measurements were those previously described [29]. During the FT/FT procedure, the LC gradient used was a 90 min gradient with aqueous solvent A (0.1% HCOOH) and solvent B (0.1% HCOOH/80% CH₃CN) developed as follows: 5–60% B in 90 min, 60–90% B in 1 min, 90% B during 10 min, 90–5% B in 1 min and 5% B during 19 min. The “full scan” mass spectrum was measured from m/z 300 to 1800 th and the charge states considered were +2 and +3. A scan cycle was started with a high resolution full scan (resolution = 30,000) with the Orbitrap analyzer, followed by a high resolution MS/MS scan of the secondary ions obtained after fragmentation, again with the Orbitrap analyzer but with a slightly lower resolution (resolution = 15,000). A 30 sec dynamic exclusion was set. The activation type used was CID with a standard normalized collision energy set at 35.

MS/MS Database MASCOT Search and Protein Quantification by Spectral Count

Peak lists were generated with the MASCOT DAEMON software (v2.3.2, Matrix Science) from the LC-MS/MS raw data using default parameters. The MASCOT 2.3.02 search engine (Matrix Science) was used to search all MS/MS spectra against a database corresponding to a complete list of annotated Coding Domain Sequences (CDS) from Phaeobacter strain DSM 17395 (NCBI RefSeq: NC_018290.1, NC_018291.1, NC_018288.1, and NC_018287.1). Bovine trypsin and the 22 most common keratin contaminants were included as a follow-up. Searches for peptides were first performed with the following parameters: mass tolerance of 5 ppm on the parent ion and 0.5 Da on the MS/MS (FT/IT procedure), static modifications of carboxamidomethylated Cys (+57.0215), and dynamic modification of oxidized Met (+15.9949). High-resolution MS/MS (FT/FT procedure) searches were performed with mass tolerance of 0.1 Da on the MS/MS. To process the data resulting from trypsin proteolysis, the maximum number of missed cleavage was set at 2. All peptide matches with a score above its peptidic identity threshold (set at p<0.01) with the ORF database and rank 1 were filtered with the IRMa 1.28.0 software [30]. A protein was only validated when at least two peptides had been assigned. In a second stage, we performed additional searches for both “semi-trypsin” and “no-enzyme” protease specificities. Protein abundance was evaluated in the shotgun analysis by MS/MS spectral counts as established by Liu and co-workers [31] and previously described [32]. Normalized Spectral count Abundance Factors (NSAF) was calculated as defined by Paoletti et al. [33].

De novo Assignment of MS/MS Spectra

Peak lists were submitted to Peaks Studio 5.3 software (Bioinformatics Solutions Inc). At first, a data refinement step was performed with a quality threshold set at 0.65. De novo sequencing was then carried out with the following parameters: a parent mass error tolerance of 5.0 ppm, a fragment mass error tolerance of 0.1 Da, cysteine carbamidomethylation (+57.02) as fixed modification, and methionine oxidation (+15.99) as variable modification. More stringent criteria were applied with a parent mass error tolerance of 2 ppm with high resolution mode for both MS and MS/MS. Successively, trypsin, semi-trypsin and no-enzyme were chosen as enzyme specificities. The list of assigned spectra obtained with MASCOT using Phaeobacter strain DSM 17395 CDS database was compared with Peaks Studio results for each samples. Precursor mass spectra annotated with the Peaks Studio software but not interpreted with the Mascot engine gave candidates for manual annotation. Results were then sorted by their Average of Local Confidence (ALC) in order to choose the best spectra to annotate.

Results and Discussion

The most Abundant Protein within the Exoproteome of Phaeobacter strain DSM 17395 is Recalcitrant to Standard Proteomic Identification

The resulting exoproteome of the marine bacterium Phaeobacter strain DSM 17395 when grown in Marine Broth was collected and resolved by SDS-PAGE. Remarkably, an abundant protein band migrating at a molecular weight of about 55 kDa was observed in the protein profile. This 55 kDa band accounts for 60 (±2) % of the total exoproteome as estimated by densitometry (Figure 1). With the objective of identifying most of the components of this exoproteome, we analyzed the sample with the previously developed shotgun procedure [10]. The whole exoproteome was excised from a short SDS-PAGE migration (3 mm) as a single small polyacrylamide band. After trypsinization, the peptide mixture was injected into a C18 reversed phase chromatography column coupled to a high resolution LTQ-Orbitrap XL hybrid mass spectrometer. The acquired tandem mass spectra were assigned with the Mascot software using as database the complete list of annotated CDS from Phaeobacter strain DSM 17395. The dataset comprised 2321 MS/MS spectra, from which 1112 could be assigned to specific peptides from Phaeobacter strain DSM 17395 (Table S1 in File S1). These spectra corresponded to 478 different peptides which validated the presence of 75 proteins with at least two different peptides (Table S2 in File S1). In terms of spectral counts, the first 15 proteins accounted for half of the total number of assigned spectra. The most detected proteins were an outer membrane porin (ZP_02147263), a flagellin-like protein (COG1344, ZP_02145485), a hemolysin-type calcium-binding protein (ZP_02144235), and the periplasmic phosphate-binding subunit of a phosphate ABC transporter (ZP_02143869) with 86, 55, 52, and 41 MS/MS spectra, respectively (Table S2 in File S1). Despite all these proteins were expected to be secreted, none was abundant enough (8% of total MS/MS spectra) as to be considered the highly secreted protein seen in Figure 1. Furthermore, their molecular weights (32, 28, 116, and 37 kDa, respectively) differ from that expected for this protein (≈55 kDa). Therefore, the shotgun results were in disagreement with the SDS-PAGE information and the abundant 55 kDa protein could not be identified. To solve this issue, we fully resolved the exoproteome onto a SDS-PAGE gel as shown in Figure 1 and analyzed by nanoLC-MS/MS the protein content of the 55 kDa polyacrylamide band. Although only one major polypeptide was expected to be present in this polyacrylamide band, we evidenced 48 proteins identified with at least 2 peptides. Table 1 reports the ten first proteins as ranked by their Mascot score (assigned MS/MS spectra and corresponding peptide characteristics are reported in Table S3 in File S1). Surprisingly we observed the protein GroEL Chaperonin (ZP_02145205) as the most detected protein with 61 MS/MS spectra although this protein is not expected to be secreted by bacteria. Another unexpected result was the presence in this polyacrylamide band of the 116 kDa protein ZP_02144235. Its tryptic sequence coverage showed that both the N- and C-termini were confirmed with proteomic-detected peptides, but the internal sequence was poorly covered (Table S3 in File S1). We presumed that this protein may be subjected to specific maturation such as a proteolytic cleavage. Again, none of the proteins shown in Table 1 were in sufficient abundance as to be considered the abundant protein seen in Figure 1. Whether the expected abundant 55 kDa protein was encoded on the genome but missed during the annotation stage was also investigated by a new Mascot search using a six-frame translation of the whole nucleic acid sequence, as previously described [34]. This proteogenomic approach remained unsuccessful with no considerable findings (Data not shown). Therefore, the abundantly secreted protein of Phaeobacter strain DSM 17395 remained unidentified with standard proteomic identification.

Download:

Figure 1. SDS-PAGE of the exoproteome of Phaeobacter strain DSM 17395.

Exoproteins were resolved by a long migration on a 10% SDS-PAGE and stained with SimplyBlue SafeStain (Invitrogen). Lane M: SeeBlue Plus2 molecular weight range marker (Invitrogen). Lane E1: Phaeobacter strain DSM 17395 exoproteome grown in Marine Broth (20 µg). Lane E2: Phaeobacter strain DSM 17395 exoproteome grown in Marine Broth (8 µg). The 55 kDa major component is indicated with an arrow.

https://doi.org/10.1371/journal.pone.0089691.g001

Download:

Table 1. List of the first ten proteins identified from the 55P. gallaeciensis DSM¹.

https://doi.org/10.1371/journal.pone.0089691.t001

De novo Sequencing with High Resolution Data Revealed the Identity of the Abundantly Secreted Protein

We carried out a search to manually assign spectra that had not been automatically assigned to a tryptic peptide comprised in the Phaeobacter strain DSM 17395 CDS database. For this de novo sequencing strategy, we reanalyzed the peptides from the 55 kDa protein band by nanoLC-MS/MS with a FT/FT procedure which enables getting higher resolution MS/MS spectra and better mass accuracy (15,000 in the orbitrap analyzer instead of the 3,000 previously done with the LTQ analyzer). From this new dataset acquisition, 246 MS/MS spectra were assigned directly with the Mascot software using the complete list of annotated CDSs from Phaeobacter strain DSM 17395 as a database. The same dataset was also searched with the de novo sequencing software Peaks Studio 5.3 identifying 258 new MS/MS spectra that had not been assigned by Mascot. We manually annotated these spectra checking all peptide sequence possibilities. Figure 2 shows the annotation of a representative MS/MS spectrum with a m/z ratio measured at 614.33826 amu corresponding to a di-charged peptide with a semi-tryptic sequence, DLVGDAGVNVLR. Peak assignment was confident with the detection of 10 monoprotonated b ions and 9 monoprotonated y ions, except that the second and eleventh residues could be either leucine or isoleucine. We could also assign the first residue with the detection of the y₁₁ diprotonated fragment ion. A total of five sequences could be confidently assigned because of MS/MS mass accuracy. The Blast analysis of each of these five tentative peptides revealed strict identities to the ZP_02147451 protein from Phaeobacter strain DSM 17395. Curiously, all five de novo sequenced peptides corresponded to semi-tryptic peptides. With these data in hands, we finally supposed that the abundant exoprotein was ZP_02147451, annotated as a hemolysin-type calcium binding protein (RTX-toxin). Its theoretical molecular weight, 52624 Da, matched the expected molecular weight estimated from the SDS-PAGE gel.

Download:

Figure 2. MS/MS spectrum of the semi-tryptic peptide [288–299] belonging to ZP_02147451.

The MS/MS spectrum was acquired with a FT/FT procedure with an LTQ-Orbitrap XL hybrid mass spectrometer. The peptide sequence is shown on the top with the collision-induced fragmentation pattern. The b and y ions are shown in blue and red, respectively. The y₁₁ di-charged ion is labeled in green.

https://doi.org/10.1371/journal.pone.0089691.g002

High Resolution Data Allowed a High Coverage of ZP_02147451 with Non-tryptic Peptides

To confirm the identity of the protein and because de novo sequencing of some MS/MS spectra had shown the presence of abundant non-tryptic peptides, we re-analyzed the FT/FT experimental data with the Mascot software using “no-enzyme” as the enzyme parameter. Table S4 in File S1 lists the resulting 228 MS/MS spectra assigned to 128 distinct peptides belonging to proteins of the Phaeobacter strain DSM 17395 bacterium. As expected, less MS/MS spectra are assigned with the no-enzyme search mode than with the trypsin search mode, due to the loss of discrimination introduced by the larger search space. This time the hemolysin-type calcium binding protein ZP_02147451 was clearly the most abundant protein identified accounting 67 MS/MS spectra assigned (30% of the spectral counts). A total of 36 distinct peptides were found for this protein and allowed 51% coverage of the whole sequence (Figure 3). According to this “no-enzyme” Mascot search, 24 peptides were semi-tryptic, 10 items do not arise from a specific cleavage, and only 1 is a tryptic peptide despite the trypsinization protocol applied. Peptides were evenly distributed along the protein sequence except the peptidase unit region spanning residues 240 to 279 (Figure 3). Table 2 shows the comparative list of proteins assigned in the two Mascot search modes (“trypsin” or “no-enzyme”). In order to compare results obtained in the two search modes we defined the Enzyme Unspecificity Factor (EUF) for each protein as the number of unique peptides in the no-enzyme MASCOT search divided by the number of unique peptides in the trypsin MASCOT search. As seen in the table, ZP_02147451 is the only protein having a higher number of unique peptides (18-fold more) when the “no-enzyme” condition is used. MASCOT search with the “no-enzyme” parameter does not change significantly the results of spectral counting when cellular proteome are analyzed as based on our previous data (Data not shown) from another Roseobacter, namely Roseobacter denitrificans [35].

Download:

Figure 3. ZP_02147451 sequence coverage with non-tryptic, semi-tryptic, and tryptic peptides.

The ZP_02147451 sequence is represented with its peptidase motif (residues 240 to 279) pointed out with purple stars. Peptides identified with the “no-enzyme” Mascot search are symbolized with a line underlining the sequence. Tryptic, semi-tryptic, and non-tryptic peptides are indicated in yellow, blue and red, respectively.

https://doi.org/10.1371/journal.pone.0089691.g003

Download:

Table 2. List of proteins identified in the 55/FT proteomic procedure¹.

https://doi.org/10.1371/journal.pone.0089691.t002

The Recalcitrance of ZP_02147451 is Caused by an Extreme Lack of Basic Residues in its Sequence

The ZP_02147451 protein is a RTX-toxin with 533 amino acids that contains only a few basic residues (three lysines and six arginines). These residues are trypsin targets for proteolysis and, therefore, this RTX-like protein will derive in extremely large peptides after digestion. Considering the length of the protein and the position of these basic residues, only three tryptic peptides could be considered as detectable by the LC-MS/MS procedure with the LTQ-Orbitrap XL hybrid mass spectrometer (m/z range from 300 to 1800 th). When reconsidering all the peptides detected of ZP_02147451, less than half of the cleavages occurred at the C-terminus of arginines (30%) and lysines (12%) in accordance to the trypsin activity. Nevertheless, a large number of cleavages (20%) also arose at the C-terminus of asparagine (N). Other residues like glutamic acid (8%) and aspartic acid (7%) were also frequently found at the C-terminus of the detected peptides (Figure S1). Thus, acidic residues frequently appeared at this position although trypsin could not explain such cleavages. Taken together, the low number of detectable tryptic peptides of the RTX-toxin ZP_02147451 is the reason why we observed other proteolytic derived peptides. These alternative proteolytic activities are usually rare and masked by the highly abundant tryptic peptides. Furthermore, in standard analysis these peptides would not be considered during the search.

We subjected the whole exoproteome of Phaeobacter strain DSM 17395 to a novel shotgun analysis with the FT/FT procedure in order to apply a de novo sequencing approach and evaluate alternative proteolysis patterns. The data were analyzed with MASCOT using a “no-enzyme” or “trypsin” parameter. Table 3 shows the comparative list of proteins assigned with at least five different peptides in the “no-enzyme” Mascot analysis mode. Interestingly, with “trypsin” as criterion for the Mascot search, ZP_02147451 was detected with only one unique peptide (2 spectral counts). The same protein was detected with 12 peptides when the “no-enzyme” parameter was used. ZP_02147451 was the only protein that exhibited such a large increase of detected peptides when the non-tryptic search mode was used (12-fold, Table 3). Noteworthy, we did not find any specific proteolytic pattern in the other proteins because of the small number of extra non-tryptic peptides detected during the analysis.

Download:

Table 3. List of proteins identified in whole exoproteome of Phaeobacter strain DSM 17395 using the FT/FT procedure¹.

https://doi.org/10.1371/journal.pone.0089691.t003

RTX-toxins Exhibit Unusually Low Content in Basic Residues

After identifying the RTX-like protein ZP_02147451 by de novo sequencing we further investigated the reason of its recalcitrance to our standard proteomic approach. Within the 533 residue protein we only found nine basic amino acids. Thus, it results refractory to standard trypsin-based proteomic approaches because of the large tryptic peptides generated. These cannot be analyzed properly by mass spectrometers operated in classical conditions. We checked whether this was a specific feature for this protein compared to the whole Phaeobacter strain DSM 17395 theoretical proteome. Figure 4 shows the comparison for all the proteins with length above 100 residues. Indeed, ZP_02147451 is by far unusual in terms of basic residue content, i.e. 1 basic residue every 59 residues while the mean value is every 11 residues within the whole theoretical proteome of Phaeobacter strain DSM 17395. Noteworthy, we detected that other RTX-toxins encoded on the Phaeobacter strain DSM 17395 genome are also unusually poor in basic residues. ZP_02146514, ZP_02146960, ZP_02146988, ZP_02146235, and ZP_02146693 are large RTX-toxin proteins (1725, 969, 296, 1112, and 937 amino acids respectively) which contain 1 basic residue every 30 residues in average (Figure 4). We wondered whether this characteristic is conserved among the other secreted proteins. Figure 4 shows that the other proteins detected in the exoproteome of Phaeobacter strain DSM 17395 do not exhibit such a specific trend, although most have a slightly lower RK content compared to the average. This trait is a common issue within the RTX-like proteins coded in Roseobacter members. The analysis of the 107 RTX-like proteins coded in 12 other sequenced Roseobacter strains revealed one basic residue every 27 amino acids (Data not shown). As an example, Roseobacter sp. MED193 exhibits two RTX-like proteins, ZP_01058551 and ZP_01057949, with an average tryptic peptide size of 80 and 73 residues, respectively. As a result, the secreted RTX-like proteins are generally refractory to trypsin digestion. We evidenced as illustrated in Figure 4 the presence in the exoproteome of a large protein with a low ratio KR/polypeptide length through the identification of three distinct peptides. This protein, ZP_02146938.1, is large (122 kDa) and annotated as the hypothetical protein RGBS107_08210. Its low content in basic residues and large molecular weight may suggest that it could also be a “RTX-toxin” far-related protein. Indeed, a Blast analysis confirmed such relationship.

Download:

Figure 4. Occurrence of basic residues in proteins from Phaeobacter strain DSM 17395.

The graph reports the ratio Lysine (K) and Arginine (R) residues per protein length of all the proteins with length above 100 residues encoded by Phaeobacter strain DSM 17395. Proteins are symbolized by a blue triangle. RTX-like proteins and the other exoproteins detected by tandem mass spectrometry are represented by red and yellow squares, respectively. The ZP_02143988.1 (a), ZP_02147451.1 (b), ZP_02144693.1 (c), ZP_02146960.1 (d), ZP_02144235.1 (e), and ZP_02146514.1 (f) RTX-toxins are indicated. Only the ZP_02143988.1 RTX-like protein has been detected by mass spectrometry.

https://doi.org/10.1371/journal.pone.0089691.g004

Concluding Remarks

Secreted proteins play an essential role in successful adaptation of bacteria to their environment. These exoproteins are crucial for nutrient import, motility, and biofilm formation. In some cases, they are used by pathogens to adhere to and degrade cell walls from their targets and to suppress defense responses from their hosts [36]. With the development of novel high-throughput proteomic strategies and the use of novel generation of hybrid tandem mass spectrometers, novel insights were recently obtained regarding the secretome from various marine Roseobacter strains in several physiological conditions [10], [12]. Here, we reported the analysis of the exoproteome of another Roseobacter member, namely Phaeobacter strain DSM 17395, which is known to produce potent and selective algaecides [25]. In this case, we found that the major secreted protein, representing 60% of the total exoproteome, was refractory to classical proteomic approach identification. This challenging issue made us changes our strategy and resort to de novo sequencing in order to identify the polypeptide. Interestingly, we found that the abundantly secreted protein was a RTX-like toxin, namely ZP_02147451, annotated as a hemolysin-type calcium-binding protein. This 533 amino acids polypeptide comprised a domain spanning from amino acids 239 to 279 and shared high similarities to the C-terminal peptidase M10 serralysin. Noteworthy, we did not find any specific proteolytic pattern for the other proteins because of the small number of extra non-tryptic peptides detected during the analysis. This indicates that no massive proteolysis occurred during exoproteome extraction as previously experienced [7], [12], [37]. As previously reported, the presence of highly secreted RTX-toxins seems to be a common issue in some Roseobacter strains [12]. In this sense, the main component of the exoproteome from Ruegeria pomeroyi DSS-3 was the PaxA RTX-toxin, observed whatever the culture condition experimentally tested. While some RTX-like proteins have been well characterized and considered as the main virulence factors in several well-known uropathogenic strains or different pathogenic Vibrio species [38] most of these toxin-like proteins remain uncharacterized in nonpathogenic environmental strains. This diverse group of RTX-like secreted proteins encoded in Roseobacter members is thought to have a potential effect on other members of the marine community in order to capture organic matter [39]. Interestingly, the secreted RTX-like proteins were depleted from the exoproteome of R. pomeroyi DSS-3 only in presence of a natural marine port community indicating a potential effect on its environment [7].

We concluded that the low content in basic residues detected in RTX-like proteins from Roseobacter strains could be linked to the function of these proteins rather than to the fact that they are secreted. Because these proteins encompass peptidase domains, their content in basic residues could be constrained to a low level for a higher resistance to the proteolysis of trypsin-like proteases or autoproteolysis as RTX-toxins may autoprocess [40], [41]. Because they are secreted to the marine environment in high amounts, at least ZP_02147451 from Phaeobacter strain DSM 17395 and PaxA from R. pomeroyi DSS-3, their function should be vital for bacteria from the Roseobacter clade. The present study shows that usual proteomic parameters for the interpretation of MS/MS data are misleading when exoproteomes are being analyzed. Here, trypsin-specific searches for MS/MS assignment did not identify correctly the ZP_02147451 RTX-toxin and led to false quantitative results regarding the main exoproteome components. Therefore, we propose for further exoproteome studies to analyze by tandem mass spectrometry the proteins cleaved with a combination of different proteases (e.g. trypsin, chymotrypsin or EndoGluC proteases) in order to not underestimate, or simply miss, abundantly secreted proteins of interest. As an example, here the experimental proteolysis of the 55 kDa band with chymotrypsin allowed the identification of the ZP_02147451 RTX-toxin with 701 MS/MS spectra assigned to the protein out of 817 MS/MS spectra recorded, i.e. 85% % (Table S5 in File S1). Proteolysis with endo glu-C led to the identification of the same protein with 662 assigned MS/MS spectra out of 747 MS/MS spectra recorded, i.e. 89 (Table S6 in File S1). In this paper we outlined a strategy that could be systematically used to identify secreted proteins in environmental environments. It would be worth re-analyzing previous exoproteome datasets to check whether the lack of identification of an intense protein was common to several of these studies. However, the lack of the corresponding raw data (SDS-PAGE and MS/MS datasets) prevented such analysis. While RTX-proteins are found numerous in marine bacteria with more than a thousand members, some have been found involved in virulence of uropathogenic E. coli revealing strong medical interest [42]. Our results point at the specific structural characteristics of these proteins as basic residues have been counter-selected during evolution.

Supporting Information

Figure S1.

Relative abundance of C-ter cleaved residues within the whole mass spectrometry-detected ZP_02147451 peptides.

https://doi.org/10.1371/journal.pone.0089691.s001

(TIF)

File S1.

Table S1, List of tryptic peptides identified in the whole exoproteome from Phaeobacter strain DSM 17395 using a standard shotgun procedure. Table S2, List of proteins identified in the whole exoproteome from Phaeobacter strain DSM 17395 using a standard shotgun procedure. Table S3, List of tryptic peptides identified in the 55 kDa SDS-PAGE band of the exoproteome from Phaeobacter strain DSM 17395 using a standard shotgun procedure. Table S4, List of peptides identified in the 55 kDa band of the exoproteome from Phaeobacter strain DSM 17395 using the FT/FT procedure and with "no-enzyme" as MASCOT search criteria. Table S5, List of peptides identified in the 55-kDa band of the exoproteome from Phaeobacter strain DSM 17395 after chymotrypsin digestion using the FT/FT procedure. Table S6, List of peptides identified in the 55-kDa band of the exoproteome from Phaeobacter strain DSM 17395 after endo-GluC digestion using the FT/FT procedure.

https://doi.org/10.1371/journal.pone.0089691.s002

(XLSX)

Author Contributions

Conceived and designed the experiments: ED JACO JA. Performed the experiments: ED JACO JA. Analyzed the data: ED JACO JA. Contributed reagents/materials/analysis tools: ED JACO JA. Wrote the paper: ED JACO JA.

References

1. Venter JC, Remington K, Heidelberg JF, Halpern AL, Rusch D, et al. (2004) Environmental genome shotgun sequencing of the Sargasso Sea. Science 304: 66–74.
- View Article
- Google Scholar
2. Giebel HA, Kalhoefer D, Lemke A, Thole S, Gahl-Janssen R, et al. (2011) Distribution of Roseobacter RCA and SAR11 lineages in the North Sea and characteristics of an abundant RCA isolate. ISME J 5: 8–19.
- View Article
- Google Scholar
3. Wagner-Dobler I, Biebl H (2006) Environmental biology of the marine Roseobacter lineage. Annu Rev Microbiol 60: 255–280.
- View Article
- Google Scholar
4. Geng H, Belas R (2010) Molecular mechanisms underlying roseobacter-phytoplankton symbioses. Curr Opin Biotechnol 21: 332–338.
- View Article
- Google Scholar
5. Armengaud J (2013) Microbiology and proteomics, getting the best of both worlds! Environ Microbiol. 15: 12–23.
- View Article
- Google Scholar
6. Armengaud J, Hartmann EM, Bland C (2013) Proteogenomics for environmental microbiology. Proteomics 13: 2731–42.
- View Article
- Google Scholar
7. Christie-Oleza JA, Fernandez B, Nogales B, Bosch R, Armengaud J (2012) Proteomic insights into the lifestyle of an environmentally relevant marine bacterium. ISME J 6: 124–135.
- View Article
- Google Scholar
8. Clair G, Armengaud J, Duport C (2012) Restricting fermentative potential by proteome remodeling: an adaptive strategy evidenced in Bacillus cereus. Mol Cell Proteomics 11: M111 013102.
9. Armengaud J, Christie-Oleza JA, Clair G, Malard V, Duport C (2012) Exoproteomics: exploring the world around biological systems. Expert Rev Proteomics 9: 561–575.
- View Article
- Google Scholar
10. Christie-Oleza JA, Armengaud J (2010) In-depth analysis of exoproteomes from marine bacteria by shotgun liquid chromatography-tandem mass spectrometry: the Ruegeria pomeroyi DSS-3 case-study. Mar Drugs 8: 2223–2239.
- View Article
- Google Scholar
11. Clair G, Roussi S, Armengaud J, Duport C (2010) Expanding the known repertoire of virulence factors produced by Bacillus cereus through early secretome profiling in three redox conditions. Mol Cell Proteomics 9: 1486–1498.
- View Article
- Google Scholar
12. Christie-Oleza JA, Pina-Villalonga JM, Bosch R, Nogales B, Armengaud J (2012) Comparative proteogenomics of twelve roseobacter exoproteomes reveals different adaptive strategies among these marine bacteria. Mol Cell Proteomics 11: M111 013110.
13. Chagnot C, Zorgani MA, Astruc T, Desvaux M (2013) Proteinaceous determinants of surface colonization in bacteria: bacterial adhesion and biofilm formation from a protein secretion perspective. Front Microbiol 4: 303.
- View Article
- Google Scholar
14. Wohlbrand L, Trautwein K, Rabus R (2013) Proteomic tools for environmental microbiology-a roadmap from sample preparation to protein identification and quantification. Proteomics 13: 2700–2730.
- View Article
- Google Scholar
15. Martens T, Heidorn T, Pukall R, Simon M, Tindall BJ, et al. (2006) Reclassification of Roseobacter gallaeciensis Ruiz-Ponte et al. 1998 as Phaeobacter gallaeciensis gen. nov., comb. nov., description of Phaeobacter inhibens sp. nov., reclassification of Ruegeria algicola (Lafay et al. 1995) Uchino et al. 1999 as Marinovum algicola gen. nov., comb. nov., and emended descriptions of the genera Roseobacter, Ruegeria and Leisingera. Int J Syst Evol Microbiol 56: 1293–1304.
- View Article
- Google Scholar
16. Ruiz-Ponte C, Cilia V, Lambert C, Nicolas JL (1998) Roseobacter gallaeciensis sp. nov., a new marine bacterium isolated from rearings and collectors of the scallop Pecten maximus. Int J Syst Bacteriol 48 Pt 2: 537–542.
- View Article
- Google Scholar
17. Yoon JH, Kang SJ, Lee SY, Oh TK (2007) Phaeobacter daeponensis sp. nov., isolated from a tidal flat of the Yellow Sea in Korea. Int J Syst Evol Microbiol 57: 856–861.
- View Article
- Google Scholar
18. Zhang DC, Li HR, Xin YH, Liu HC, Chi ZM, et al. (2008) Phaeobacter arcticus sp. nov., a psychrophilic bacterium isolated from the Arctic. Int J Syst Evol Microbiol 58: 1384–1387.
- View Article
- Google Scholar
19. Druppel K, Hensler M, Trautwein K, Kossmehl S, Wohlbrand L, et al. (2014) Pathways and substrate-specific regulation of amino acid degradation in Phaeobacter inhibens DSM 17395 (archetype of the marine Roseobacter clade). Environ Microbiol. 16: 218–38.
- View Article
- Google Scholar
20. Kossmehl S, Wohlbrand L, Druppel K, Feenders C, Blasius B, et al. (2013) Subcellular protein localization (cell envelope) in Phaeobacter inhibens DSM 17395. Proteomics 13: 2743–2760.
- View Article
- Google Scholar
21. Zech H, Hensler M, Kossmehl S, Druppel K, Wohlbrand L, et al. (2013) Dynamics of amino acid utilization in Phaeobacter inhibens DSM 17395. Proteomics 13: 2869–2885.
- View Article
- Google Scholar
22. Zech H, Hensler M, Kossmehl S, Druppel K, Wohlbrand L, et al. (2013) Adaptation of Phaeobacter inhibens DSM 17395 to growth with complex nutrients. Proteomics 13: 2851–2868.
- View Article
- Google Scholar
23. Berger M, Neumann A, Schulz S, Simon M, Brinkhoff T (2011) Tropodithietic acid production in Phaeobacter gallaeciensis is regulated by N-acyl homoserine lactone-mediated quorum sensing. J Bacteriol 193: 6576–6585.
- View Article
- Google Scholar
24. Brinkhoff T, Giebel HA, Simon M (2008) Diversity, ecology, and genomics of the Roseobacter clade: a short overview. Arch Microbiol 189: 531–539.
- View Article
- Google Scholar
25. Seyedsayamdost MR, Carr G, Kolter R, Clardy J (2011) Roseobacticides: small molecule modulators of an algal-bacterial symbiosis. J Am Chem Soc 133: 18343–18349.
- View Article
- Google Scholar
26. Seyedsayamdost MR, Case RJ, Kolter R, Clardy J (2011) The Jekyll-and-Hyde chemistry of Phaeobacter gallaeciensis. Nat Chem 3: 331–335.
- View Article
- Google Scholar
27. Buddruhs N, Pradella S, Goker M, Pauker O, Pukall R, et al. (2013) Molecular and phenotypic analyses reveal the non-identity of the Phaeobacter gallaeciensis type strain deposits CIP 105210T and DSM 17395. Int J Syst Evol Microbiol 63: 4340–4349.
- View Article
- Google Scholar
28. Dedieu A, Gaillard JC, Pourcher T, Darrouzet E, Armengaud J (2011) Revisiting iodination sites in thyroglobulin with an organ-oriented shotgun strategy. J Biol Chem 286: 259–269.
- View Article
- Google Scholar
29. de Groot A, Dulermo R, Ortet P, Blanchard L, Guerin P, et al. (2009) Alliance of proteomics and genomics to unravel the specificities of Sahara bacterium Deinococcus deserti. PLoS Genet 5: e1000434.
- View Article
- Google Scholar
30. Dupierris V, Masselon C, Court M, Kieffer-Jaquinod S, Bruley C (2009) A toolbox for validation of mass spectrometry peptides identification and generation of database: IRMa. Bioinformatics 25: 1980–1981.
- View Article
- Google Scholar
31. Liu H, Sadygov RG, Yates JR 3rd (2004) A model for random sampling and estimation of relative protein abundance in shotgun proteomics. Anal Chem 76: 4193–4201.
- View Article
- Google Scholar
32. Zivanovic Y, Armengaud J, Lagorce A, Leplat C, Guerin P, et al. (2009) Genome analysis and genome-wide proteomics of Thermococcus gammatolerans, the most radioresistant organism known amongst the Archaea. Genome Biol 10: R70.
- View Article
- Google Scholar
33. Paoletti AC, Parmely TJ, Tomomori-Sato C, Sato S, Zhu D, et al. (2006) Quantitative proteomic analysis of distinct mammalian Mediator complexes using normalized spectral abundance factors. Proc Natl Acad Sci U S A 103: 18928–18933.
- View Article
- Google Scholar
34. Baudet M, Ortet P, Gaillard JC, Fernandez B, Guerin P, et al. (2010) Proteomics-based refinement of Deinococcus deserti genome annotation reveals an unwonted use of non-canonical translation initiation codons. Mol Cell Proteomics 9: 415–426.
- View Article
- Google Scholar
35. Bland C, Bellanger L, Armengaud J (2014) Magnetic Immunoaffinity Enrichment for Selective Capture and MS/MS Analysis of N-Terminal-TMPP-Labeled Peptides. J Proteome Res. in press.
36. Preston GM, Studholme DJ, Caldelari I (2005) Profiling the secretomes of plant pathogenic Proteobacteria. FEMS Microbiol Rev 29: 331–360.
- View Article
- Google Scholar
37. Clair G, Lorphelin A, Armengaud J, Duport C (2013) OhrRA functions as a redox-responsive system controlling toxinogenesis in Bacillus cereus. J Proteomics 94: 527–539.
- View Article
- Google Scholar
38. Linhartova I, Bumba L, Masin J, Basler M, Osicka R, et al. (2010) RTX proteins: a highly diverse family secreted by a common mechanism. FEMS Microbiol Rev 34: 1076–1112.
- View Article
- Google Scholar
39. Moran MA, Belas R, Schell MA, Gonzalez JM, Sun F, et al. (2007) Ecological genomics of marine Roseobacters. Appl Environ Microbiol 73: 4559–4569.
- View Article
- Google Scholar
40. Satchell KJ (2011) Structure and function of MARTX toxins and other large repetitive RTX proteins. Annu Rev Microbiol 65: 71–90.
- View Article
- Google Scholar
41. Sheahan KL, Cordero CL, Satchell KJ (2007) Autoprocessing of the Vibrio cholerae RTX toxin by the cysteine protease domain. EMBO J 26: 2552–2561.
- View Article
- Google Scholar
42. Vigil PD, Alteri CJ, Mobley HL (2011) Identification of in vivo-induced antigens including an RTX family exoprotein required for uropathogenic Escherichia coli virulence. Infect Immun 79: 2335–2344.
- View Article
- Google Scholar

[ref1] 1. Venter JC, Remington K, Heidelberg JF, Halpern AL, Rusch D, et al. (2004) Environmental genome shotgun sequencing of the Sargasso Sea. Science 304: 66–74.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Giebel HA, Kalhoefer D, Lemke A, Thole S, Gahl-Janssen R, et al. (2011) Distribution of Roseobacter RCA and SAR11 lineages in the North Sea and characteristics of an abundant RCA isolate. ISME J 5: 8–19.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Wagner-Dobler I, Biebl H (2006) Environmental biology of the marine Roseobacter lineage. Annu Rev Microbiol 60: 255–280.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Geng H, Belas R (2010) Molecular mechanisms underlying roseobacter-phytoplankton symbioses. Curr Opin Biotechnol 21: 332–338.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Armengaud J (2013) Microbiology and proteomics, getting the best of both worlds! Environ Microbiol. 15: 12–23.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref6] 6. Armengaud J, Hartmann EM, Bland C (2013) Proteogenomics for environmental microbiology. Proteomics 13: 2731–42.
View Article
Google Scholar

[17] View Article

[18] Google Scholar

[ref7] 7. Christie-Oleza JA, Fernandez B, Nogales B, Bosch R, Armengaud J (2012) Proteomic insights into the lifestyle of an environmentally relevant marine bacterium. ISME J 6: 124–135.
View Article
Google Scholar

[20] View Article

[21] Google Scholar

[ref8] 8. Clair G, Armengaud J, Duport C (2012) Restricting fermentative potential by proteome remodeling: an adaptive strategy evidenced in Bacillus cereus. Mol Cell Proteomics 11: M111 013102.

[ref9] 9. Armengaud J, Christie-Oleza JA, Clair G, Malard V, Duport C (2012) Exoproteomics: exploring the world around biological systems. Expert Rev Proteomics 9: 561–575.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Christie-Oleza JA, Armengaud J (2010) In-depth analysis of exoproteomes from marine bacteria by shotgun liquid chromatography-tandem mass spectrometry: the Ruegeria pomeroyi DSS-3 case-study. Mar Drugs 8: 2223–2239.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Clair G, Roussi S, Armengaud J, Duport C (2010) Expanding the known repertoire of virulence factors produced by Bacillus cereus through early secretome profiling in three redox conditions. Mol Cell Proteomics 9: 1486–1498.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Christie-Oleza JA, Pina-Villalonga JM, Bosch R, Nogales B, Armengaud J (2012) Comparative proteogenomics of twelve roseobacter exoproteomes reveals different adaptive strategies among these marine bacteria. Mol Cell Proteomics 11: M111 013110.

[ref13] 13. Chagnot C, Zorgani MA, Astruc T, Desvaux M (2013) Proteinaceous determinants of surface colonization in bacteria: bacterial adhesion and biofilm formation from a protein secretion perspective. Front Microbiol 4: 303.
View Article
Google Scholar

[34] View Article

[35] Google Scholar

[ref14] 14. Wohlbrand L, Trautwein K, Rabus R (2013) Proteomic tools for environmental microbiology-a roadmap from sample preparation to protein identification and quantification. Proteomics 13: 2700–2730.
View Article
Google Scholar

[37] View Article

[38] Google Scholar

[ref15] 15. Martens T, Heidorn T, Pukall R, Simon M, Tindall BJ, et al. (2006) Reclassification of Roseobacter gallaeciensis Ruiz-Ponte et al. 1998 as Phaeobacter gallaeciensis gen. nov., comb. nov., description of Phaeobacter inhibens sp. nov., reclassification of Ruegeria algicola (Lafay et al. 1995) Uchino et al. 1999 as Marinovum algicola gen. nov., comb. nov., and emended descriptions of the genera Roseobacter, Ruegeria and Leisingera. Int J Syst Evol Microbiol 56: 1293–1304.
View Article
Google Scholar

[40] View Article

[41] Google Scholar

[ref16] 16. Ruiz-Ponte C, Cilia V, Lambert C, Nicolas JL (1998) Roseobacter gallaeciensis sp. nov., a new marine bacterium isolated from rearings and collectors of the scallop Pecten maximus. Int J Syst Bacteriol 48 Pt 2: 537–542.
View Article
Google Scholar

[43] View Article

[44] Google Scholar

[ref17] 17. Yoon JH, Kang SJ, Lee SY, Oh TK (2007) Phaeobacter daeponensis sp. nov., isolated from a tidal flat of the Yellow Sea in Korea. Int J Syst Evol Microbiol 57: 856–861.
View Article
Google Scholar

[46] View Article

[47] Google Scholar

[ref18] 18. Zhang DC, Li HR, Xin YH, Liu HC, Chi ZM, et al. (2008) Phaeobacter arcticus sp. nov., a psychrophilic bacterium isolated from the Arctic. Int J Syst Evol Microbiol 58: 1384–1387.
View Article
Google Scholar

[49] View Article

[50] Google Scholar

[ref19] 19. Druppel K, Hensler M, Trautwein K, Kossmehl S, Wohlbrand L, et al. (2014) Pathways and substrate-specific regulation of amino acid degradation in Phaeobacter inhibens DSM 17395 (archetype of the marine Roseobacter clade). Environ Microbiol. 16: 218–38.
View Article
Google Scholar

[52] View Article

[53] Google Scholar

[ref20] 20. Kossmehl S, Wohlbrand L, Druppel K, Feenders C, Blasius B, et al. (2013) Subcellular protein localization (cell envelope) in Phaeobacter inhibens DSM 17395. Proteomics 13: 2743–2760.
View Article
Google Scholar

[55] View Article

[56] Google Scholar

[ref21] 21. Zech H, Hensler M, Kossmehl S, Druppel K, Wohlbrand L, et al. (2013) Dynamics of amino acid utilization in Phaeobacter inhibens DSM 17395. Proteomics 13: 2869–2885.
View Article
Google Scholar

[58] View Article

[59] Google Scholar

[ref22] 22. Zech H, Hensler M, Kossmehl S, Druppel K, Wohlbrand L, et al. (2013) Adaptation of Phaeobacter inhibens DSM 17395 to growth with complex nutrients. Proteomics 13: 2851–2868.
View Article
Google Scholar

[61] View Article

[62] Google Scholar

[ref23] 23. Berger M, Neumann A, Schulz S, Simon M, Brinkhoff T (2011) Tropodithietic acid production in Phaeobacter gallaeciensis is regulated by N-acyl homoserine lactone-mediated quorum sensing. J Bacteriol 193: 6576–6585.
View Article
Google Scholar

[64] View Article

[65] Google Scholar

[ref24] 24. Brinkhoff T, Giebel HA, Simon M (2008) Diversity, ecology, and genomics of the Roseobacter clade: a short overview. Arch Microbiol 189: 531–539.
View Article
Google Scholar

[67] View Article

[68] Google Scholar

[ref25] 25. Seyedsayamdost MR, Carr G, Kolter R, Clardy J (2011) Roseobacticides: small molecule modulators of an algal-bacterial symbiosis. J Am Chem Soc 133: 18343–18349.
View Article
Google Scholar

[70] View Article

[71] Google Scholar

[ref26] 26. Seyedsayamdost MR, Case RJ, Kolter R, Clardy J (2011) The Jekyll-and-Hyde chemistry of Phaeobacter gallaeciensis. Nat Chem 3: 331–335.
View Article
Google Scholar

[73] View Article

[74] Google Scholar

[ref27] 27. Buddruhs N, Pradella S, Goker M, Pauker O, Pukall R, et al. (2013) Molecular and phenotypic analyses reveal the non-identity of the Phaeobacter gallaeciensis type strain deposits CIP 105210T and DSM 17395. Int J Syst Evol Microbiol 63: 4340–4349.
View Article
Google Scholar

[76] View Article

[77] Google Scholar

[ref28] 28. Dedieu A, Gaillard JC, Pourcher T, Darrouzet E, Armengaud J (2011) Revisiting iodination sites in thyroglobulin with an organ-oriented shotgun strategy. J Biol Chem 286: 259–269.
View Article
Google Scholar

[79] View Article

[80] Google Scholar

[ref29] 29. de Groot A, Dulermo R, Ortet P, Blanchard L, Guerin P, et al. (2009) Alliance of proteomics and genomics to unravel the specificities of Sahara bacterium Deinococcus deserti. PLoS Genet 5: e1000434.
View Article
Google Scholar

[82] View Article

[83] Google Scholar

[ref30] 30. Dupierris V, Masselon C, Court M, Kieffer-Jaquinod S, Bruley C (2009) A toolbox for validation of mass spectrometry peptides identification and generation of database: IRMa. Bioinformatics 25: 1980–1981.
View Article
Google Scholar

[85] View Article

[86] Google Scholar

[ref31] 31. Liu H, Sadygov RG, Yates JR 3rd (2004) A model for random sampling and estimation of relative protein abundance in shotgun proteomics. Anal Chem 76: 4193–4201.
View Article
Google Scholar

[88] View Article

[89] Google Scholar

[ref32] 32. Zivanovic Y, Armengaud J, Lagorce A, Leplat C, Guerin P, et al. (2009) Genome analysis and genome-wide proteomics of Thermococcus gammatolerans, the most radioresistant organism known amongst the Archaea. Genome Biol 10: R70.
View Article
Google Scholar

[91] View Article

[92] Google Scholar

[ref33] 33. Paoletti AC, Parmely TJ, Tomomori-Sato C, Sato S, Zhu D, et al. (2006) Quantitative proteomic analysis of distinct mammalian Mediator complexes using normalized spectral abundance factors. Proc Natl Acad Sci U S A 103: 18928–18933.
View Article
Google Scholar

[94] View Article

[95] Google Scholar

[ref34] 34. Baudet M, Ortet P, Gaillard JC, Fernandez B, Guerin P, et al. (2010) Proteomics-based refinement of Deinococcus deserti genome annotation reveals an unwonted use of non-canonical translation initiation codons. Mol Cell Proteomics 9: 415–426.
View Article
Google Scholar

[97] View Article

[98] Google Scholar

[ref35] 35. Bland C, Bellanger L, Armengaud J (2014) Magnetic Immunoaffinity Enrichment for Selective Capture and MS/MS Analysis of N-Terminal-TMPP-Labeled Peptides. J Proteome Res. in press.

[ref36] 36. Preston GM, Studholme DJ, Caldelari I (2005) Profiling the secretomes of plant pathogenic Proteobacteria. FEMS Microbiol Rev 29: 331–360.
View Article
Google Scholar

[101] View Article

[102] Google Scholar

[ref37] 37. Clair G, Lorphelin A, Armengaud J, Duport C (2013) OhrRA functions as a redox-responsive system controlling toxinogenesis in Bacillus cereus. J Proteomics 94: 527–539.
View Article
Google Scholar

[104] View Article

[105] Google Scholar

[ref38] 38. Linhartova I, Bumba L, Masin J, Basler M, Osicka R, et al. (2010) RTX proteins: a highly diverse family secreted by a common mechanism. FEMS Microbiol Rev 34: 1076–1112.
View Article
Google Scholar

[107] View Article

[108] Google Scholar

[ref39] 39. Moran MA, Belas R, Schell MA, Gonzalez JM, Sun F, et al. (2007) Ecological genomics of marine Roseobacters. Appl Environ Microbiol 73: 4559–4569.
View Article
Google Scholar

[110] View Article

[111] Google Scholar

[ref40] 40. Satchell KJ (2011) Structure and function of MARTX toxins and other large repetitive RTX proteins. Annu Rev Microbiol 65: 71–90.
View Article
Google Scholar

[113] View Article

[114] Google Scholar

[ref41] 41. Sheahan KL, Cordero CL, Satchell KJ (2007) Autoprocessing of the Vibrio cholerae RTX toxin by the cysteine protease domain. EMBO J 26: 2552–2561.
View Article
Google Scholar

[116] View Article

[117] Google Scholar

[ref42] 42. Vigil PD, Alteri CJ, Mobley HL (2011) Identification of in vivo-induced antigens including an RTX family exoprotein required for uropathogenic Escherichia coli virulence. Infect Immun 79: 2335–2344.
View Article
Google Scholar

[119] View Article

[120] Google Scholar

Figures

Abstract

Introduction

Materials and Methods

P. gallaenciensis Growth and Exoproteome Preparation

SDS-PAGE and Trypsin-in gel Proteolysis

NanoLC-MS/MS Analysis

MS/MS Database MASCOT Search and Protein Quantification by Spectral Count

De novo Assignment of MS/MS Spectra

Results and Discussion

The most Abundant Protein within the Exoproteome of Phaeobacter strain DSM 17395 is Recalcitrant to Standard Proteomic Identification

De novo Sequencing with High Resolution Data Revealed the Identity of the Abundantly Secreted Protein

High Resolution Data Allowed a High Coverage of ZP_02147451 with Non-tryptic Peptides

The Recalcitrance of ZP_02147451 is Caused by an Extreme Lack of Basic Residues in its Sequence

RTX-toxins Exhibit Unusually Low Content in Basic Residues

Concluding Remarks

Supporting Information

Figure S1.

File S1.

Author Contributions

References