The Complete Genome and Proteome of Laribacter hongkongensis Reveal Potential Mechanisms for Adaptations to Different Temperatures and Habitats

Laribacter hongkongensis is a newly discovered Gram-negative bacillus of the Neisseriaceae family associated with freshwater fish–borne gastroenteritis and traveler's diarrhea. The complete genome sequence of L. hongkongensis HLHK9, recovered from an immunocompetent patient with severe gastroenteritis, consists of a 3,169-kb chromosome with G+C content of 62.35%. Genome analysis reveals different mechanisms potentially important for its adaptation to diverse habitats of human and freshwater fish intestines and freshwater environments. The gene contents support its phenotypic properties and suggest that amino acids and fatty acids can be used as carbon sources. The extensive variety of transporters, including multidrug efflux and heavy metal transporters as well as genes involved in chemotaxis, may enable L. hongkongensis to survive in different environmental niches. Genes encoding urease, bile salts efflux pump, adhesin, catalase, superoxide dismutase, and other putative virulence factors—such as hemolysins, RTX toxins, patatin-like proteins, phospholipase A1, and collagenases—are present. Proteomes of L. hongkongensis HLHK9 cultured at 37°C (human body temperature) and 20°C (freshwater habitat temperature) showed differential gene expression, including two homologous copies of argB, argB-20, and argB-37, which encode two isoenzymes of N-acetyl-L-glutamate kinase (NAGK)—NAGK-20 and NAGK-37—in the arginine biosynthesis pathway. NAGK-20 showed higher expression at 20°C, whereas NAGK-37 showed higher expression at 37°C. NAGK-20 also had a lower optimal temperature for enzymatic activities and was inhibited by arginine probably as negative-feedback control. Similar duplicated copies of argB are also observed in bacteria from hot springs such as Thermus thermophilus, Deinococcus geothermalis, Deinococcus radiodurans, and Roseiflexus castenholzii, suggesting that similar mechanisms for temperature adaptation may be employed by other bacteria. Genome and proteome analysis of L. hongkongensis revealed novel mechanisms for adaptations to survival at different temperatures and habitats.


Introduction
Laribacter hongkongensis is a recently discovered, Gram-negative, facultative anaerobic, motile, seagull or S-shaped, asaccharolytic, urease-positive bacillus that belongs to the Neisseriaceae family of bproteobacteria [1]. It was first isolated from the blood and thoracic empyema of an alcoholic liver cirrhosis patient in Hong Kong [2]. In a prospective study, L. hongkongensis was shown to be associated with community acquired gastroenteritis and traveler's diarrhea [3,4]. L. hongkongensis is likely to be globally distributed, as travel histories from patients suggested its presence in at least four continents: Asia, Europe, Africa and Central America [4][5][6]. L. hongkongensis has been found in up to 60% of the intestines of commonly consumed freshwater fish, such as grass carp and bighead carp [4,7,8]. It has also been isolated from drinking water reservoirs in Hong Kong [9]. Pulsed-field gel electrophoresis and multilocus sequence typing showed that the fish and patient isolates fell into separate clusters, suggesting that some clones could be more virulent or adapted to human [8,10]. These data strongly suggest that this bacterium is a potential diarrheal pathogen that warrants further investigations.
Compared to other families such as Enterobacteriaceae, Vibrionaceae, Streptococcaceae, genomes of bacteria in the Neisseriaceae family have been relatively under-studied. Within this family, Neisseria meningitidis, Neisseria gonorrhoeae and Chromobacterium violaceum are the only species with completely sequenced genomes [11][12][13]. In view of its potential clinical importance, distinct phylogenetic position, interesting phenotypic characteristics and the availability of genetic manipulation systems [14][15][16][17], we sequenced and annotated the complete genome of a strain (HLHK9) of L. hongkongensis recovered from a 36-year old previously healthy Chinese patient with profuse diarrhea, vomiting and abdominal pain [4]. Proteomes of L. hongkongensis growing at 37uC (body temperature of human) and 20uC (average temperature of freshwater habitat in fall and winter) [9] were also compared.

General Features of the Genome
The complete genome of L. hongkongensis is a single circular chromosome of 3,169,329 bp with a G+C content of 62.35% ( Figure 1). In terms of genome size and number of predicted coding sequences (CDSs), rRNA operons and tRNA genes (Table 1), L. hongkongensis falls into a position intermediate between C. violaceum and the pathogenic Neisseria species. A similar intermediate status was also observed when the CDSs were classified into Cluster of Orthologous Groups (COG) functional categories, except for genes of RNA processing and modification (COG A), cell cycle control, mitosis and meiosis (COG D), replication, recombination and repair (COG L) and extracellular structures (COG W), of which all four bacteria have similar number of genes ( Figure 2). This is in line with the life cycles and growth requirements of the bacteria. C. violaceum is a highly versatile, facultative anaerobic, soil-and water-borne free-living bacterium and therefore requires the largest genome size and gene number. The pathogenic Neisseria species are strictly aerobic bacteria with human as the only host and therefore require the smallest genome size and gene number. L. hongkongensis is a facultative anaerobic bacterium that can survive in human, freshwater fish and 0-2% NaCl but not in marine fish or $3% NaCl and therefore requires an intermediate genome size and gene number.

General Metabolism
The L. hongkongensis genome lacks a complete set of enzymes for glycolysis, with orthologues of glucokinase, 6-phosphofructokinase and pyruvate kinase being absent (Table S1). This is compatible with its asaccharolytic phenotype and is consistent with other asaccharolytic bacteria, such as Campylobacter jejuni, Bordetella pertussis, Bordetella parapertussis and Bordetella bronchiseptica, in that glucokinase and 6-phosphofructokinase are also absent from their genomes [18,19]. On the other hand, the L. hongkongensis genome encodes the complete sets of enzymes for gluconeogenesis, the pentose phosphate pathway and the glyoxylate cycle (Table S1). Similar to C. jejuni, the L. hongkongensis genome encodes a number of extracellular proteases and amino acid transporters. These amino acids can be used as carbon source for the bacterium. The genome encodes enzymes for biosynthesis of the 21 genetically encoded amino acids and for biosynthesis and b-oxidation of saturated fatty acids (Tables S2 and S3). The L. hongkongensis genome encodes a variety of dehydrogenases (LHK_00527-00540, LHK_01219-01224, LHK_02418-02421, LHK_00801-00803, LHK_01861, LHK_02912-02913 and LHK_00934) that enable it to utilize a variety of substrates as electron donors, such as NADH, succinate, formate, proline, acyl-CoA and D-amino acids. The presence of three terminal cytochrome oxidases may allow L. hongkongensis to carry out respiration using oxygen as the electron acceptor under both aerobic conditions [type aa 3 oxidase (LHK_00169-00170, LHK_00173)] and conditions with reduced oxygen tension [type cbb 3 (LHK_00995-00996, LHK_00998) and type bd (LHK_02252-02253) oxidases]. The genome also encodes a number of reductases [fumarate reductase (LHK_02340-02342), nitrate reductase (LHK_02079-02085), dimethylsulfoxide (DMSO) reductase (LHK_02496-02498) and tetrathionate reductase (LHK_01476-01478)], which may help carry out respiration with alternative electron acceptors to oxygen (fumarate, nitrate, DMSO and tetrathionate) under anaerobic conditions. This is supported by the enhanced growth of L. hongkongensis under anaerobic conditions in the presence of nitrate (data not shown). Further studies are required to confirm if the bacterium can utilize other potential electron acceptors.

Transporters
There were 441 transport-related proteins (13.6% of all CDSs) in the L. hongkongensis genome, comprising an extensive variety of transporters, which may reflect its ability to adapt to the freshwater fish and human intestines, and freshwater environments. According to the Transporter Classification Database (TCDB) (http:// www.tcdb.org/), all seven major categories of transporters are present in L. hongkongensis. Primary active transporters (class 3 transporters) were the most abundant class of transporters, accounting for 43.3% (191 CDSs) of all annotated CDSs related to transport, among which 104 belong to the ATP-binding cassette (ABC) transporter superfamily and 41 were oxidoreduction-driven transporters. Electrochemical potential-driven transporters (class 2 transporters) were the second most abundant class of transporters, accounting for 27.9% (123 CDSs) of all annotated CDSs related to transport, most of which (117 CDSs) are various kinds of porters including major facilitator superfamily (MFS) (19 CDSs), resistance-nodulation-cell division (RND) superfamily (22 CDSs), amino acid-polyamine-organocation family (8 CDSs), dicarboxylate/amino acid:cation symporter (DAACS) family (5 CDSs) and monovalent cation:proton antiporter-2 family (3 CDSs), and various heavy metal transporters which may be involved in detoxification and resistance against environmental hazards. Three different types of class 2 transporters, belonging to the DAACS, tripartite ATP-independent periplasmic transporter and

Author Summary
Laribacter hongkongensis is a recently discovered bacterium associated with gastroenteritis and traveler's diarrhea. Freshwater fish is the reservoir of L. hongkongensis. In order to achieve a rapid understanding on the mechanisms by which the bacterium adapts to different habitats and its potential virulence factors, we sequenced the complete genome of L. hongkongensis, compared its gene contents with other bacteria, and compared its gene expression at 37uC (human body temperature) and 20uC (freshwater habitat temperature). We found that the gene contents of L. hongkongensis enable it to adapt to its diverse habitats of human and freshwater fish intestines and freshwater environments. Genes encoding proteins responsible for survival in the intestinal environments, adhesion to intestinal cells, evasion from host immune systems, and putative virulence factors similar to those observed in other pathogens are present. We also observed, in gene expression studies, that L. hongkongensis may be using different pathways for arginine synthesis regulated at different temperatures. Phylogenetic analysis suggested that such mechanisms for temperature adaptation may also be used in bacteria found in extreme temperatures.
C 4 -dicarboxylate uptake C family, are likely involved in the transport of malate, which can be used as the sole carbon source for L. hongkongensis in minimal medium [unpublished data]. The remaining class 2 transporters were ion-gradient-driven energizers belonging to the TonB family (6 CDSs). The third most abundant class of transporters was the channels and pores (class 1), with 39 CDSs including 12 a-type channels, 26 b-barrel porins. Among the 12 a-type channels, four were mechanosensitive channels and G+C content (10-kb window with 100-b step); circles 3 to 7, red, light purple, orange, aqua and teal bars show BLAST hits to Neisseria gonorrhoeae FA 1090, Neisseria gonorrhoeae MC58, Neisseria gonorrhoeae FAM18, Neisseria gonorrhoeae Z2491 and Chromobacterium violaceum ATCC 12472, respectively; circle 8, green arcs show location of eight putative prophages; circles 9 and 12, colors reflect Cluster of Orthologous Groups of coding sequences (CDSs). Maroon, translation, ribosomal structure and biogenesis; navy, transcription; purple, DNA replication, recombination and repair; light brown, cell division and chromosome partitioning; aqua, posttranslational modification, protein turnover, chaperones; teal, cell envelope biogenesis, outer membrane; blue, cell motility and secretion; orange, inorganic ion transport and metabolism; light purple, signal transduction mechanisms; olive, energy production and conversion; lime, carbohydrate transport and metabolism; green, amino acid transport and metabolism; fuchsia, nucleotide transport and metabolism; light pink, coenzyme metabolism; red, lipid metabolism; yellow, secondary metabolites biosynthesis, transport and catabolism; gray, general function prediction only; silver, function unknown; circles 10 and 11, dark blue, dark red and dark purple indicate CDSs, tRNA and rRNA on the 2 and + strands, respectively. doi:10.1371/journal.pgen.1000416.g001 which are important for mediating resistance to mechanophysical changes. The remaining transporters belong to four other classes, namely group translocators (class 4, 9 CDSs), transport electron carriers (class 5, 16 CDSs), accessory factors involved in transport (class 8, 9 CDSs) and incompletely characterized transport system (class 9, 54 CDSs). In line with their asaccharolytic nature, the genomes of L. hongkongensis and C. jejuni do not contain genes that encode a complete phosphotransferase system. The five families of multidrug efflux transporters, including MFS (6 CDSs), RND (8 CDSs), small multidrug resistance family (2 CDSs), multidrug and toxic compound extrusion family (2 CDSs) and ABC transporter superfamily (5 CDSs), were all present in L. hongkongensis, which may reflect its ability to withstand toxic substances in different habitats [20]. 20 CDSs were related to iron metabolism, including hemin transporters, ABC transporters of the metal type and ferrous iron, iron-storage proteins and the Fur protein responsible for iron uptake regulation. In contrast to C. violaceum which produces siderophores for iron acquisition, but similar to the pathogenic Neisseria species, proteins related to siderophore formation are not found in L. hongkongensis genome. In addition to a TonB-dependent siderophore receptor (LHK_00497), a set of genes (LHK_01190, LHK_01193, LHK_01427-1428) related to the transport of hemin were present, suggesting that L. hongkongensis is able to utilize exogenous siderophores or host proteins for iron acquisition, which may be important for survival in different environments and hosts.

Motility, Chemotaxis, and Signal Transduction
Except the first strain of L. hongkongensis isolated from the blood and empyema pus of a patient which represented a non-motile variant, all L. hongkongensis strains, whether from human diarrheal stool, fish intestine or environmental water, are motile with polar flagella. The ability to sense and respond to environmental signals is important for survival in changing ecological niches. A total of 47 CDSs are related to chemotaxis, of which 27 encode methyl-accepting chemotaxis proteins (MCPs) and 20 encode chemosensory transducer proteins. While most MCPs are scattered throughout the genome, the transducer proteins are mostly arranged in three gene clusters ( Figure  S1). At least 38 genes, in six gene clusters, are involved in the biosynthesis of flagella ( Figure S2).
Enteric bacteria use several quorum-sensing mechanisms, including the LuxR-I, LuxS/AI-2, and AI-3/epinephrine/norepinephrine systems, to recognize the host environment and communicate across species. Unlike the genomes of C. violaceum and the pathogenic Neisseria species which encode genes involved in LuxR-I and LuxS/AI-2 systems respectively, the L. hongkongensis genome does not encode genes of these 2 systems. Instead, the AI-3/epinephrine/norepinephrine system, which is involved in interkingdom cross-signaling and regulation of virulence gene transcription and motility, best characterized in enterohemorrhagic E. coli [21,22], is likely the predominant quorum-sensing mechanism used by L. hongkongensis. Several human enteric commensals or pathogens, including E. coli, Shigella, and Salmonella, produce AI-3 [23]. A two-component system, QseB/C, of which QseC is the sensor kinase and QseB the response regulator, has been found to be involved in sensing AI-3 from bacteria and epinephrine/ norepinephrine from host, and activation of the flagellar regulon transcription [21]. While the biosynthetic pathway of AI-3 has not been discovered, two sets of genes, LHK_00329/LHK_00328 and LHK_01812/LHK_01813, homologous to QseB/QseC were identified in the L. hongkongensis genome, suggesting that the bacterium may regulate its motility upon recognition of its host environment. The presence of two sets of QseB/QseC, one most similar to those of C. violaceum and the other most homologous to Azoarcus sp. strain BH72, is intriguing, as the latter is the only bacterium, with complete genome sequence available, that possesses two copies of such genes.

Pathogenic Factors
Before reaching the human intestine, L. hongkongensis has to pass through the highly acidic environment of the stomach. In the L.  hongkongensis genome, a cluster of genes, spanning a 12-kb region, related to acid resistance, is present. Similar to Helicobacter pylori, the L. hongkongensis genome contains a complete urease gene cluster (LHK_01035-LHK_01037, LHK_01040-LHK_01044), in line with the bacterium's urease activity. Phylogenetically, all 8 genes in the urease cassette are most closely related to the corresponding homologues in Brucella species (a-proteobacteria), Yersinia species (c-proteobacteria) and Photorhabdus luminescens (c-proteobacteria), instead of those in other members of b-proteobacteria, indicating that L. hongkongensis has probably acquired the genes through horizontal gene transfer after its evolution into a distinct species ( Figure S3). Upstream and downstream to the urease cassette, adi (LHK_01034) and hdeA (LHK_01046) were found respectively. Their activities will raise the cytoplasmic pH and prevents proteins in the periplasmic space from aggregation during acid shock respectively [24,25]. In addition to the acid resistance gene cluster, the L. hongkongensis genome contains two arc gene clusters [arcA (LHK_02729 and LHK_02734), arcB (LHK_02728 and LHK_02733), arcC (LHK_02727 and LHK_02732) and arcD (LHK_02730 and LHK_02731)] of the arginine deiminase pathway which converts L-arginine to carbon dioxide, ATP, and ammonia. The production of ammonia increases the pH of the local environment [26,27]. Similar to other pathogenic bacteria of the gastrointestinal tract, the genome of L. hongkongensis encodes genes for bile resistance. These include three complete copies of acrAB (LHK_01425-01426, LHK_02129-02130 and LHK_02929-02930), encoding the best studied efflux pump for bile salts, and two pairs of genes (LHK_01373-01374 and LHK_03132-03133) that encode putative efflux pumps homologous to that encoded by emrAB in E. coli [28]. Furthermore, five genes [tolQ (LHK_00053), tolR (LHK_03174), tolA (LHK_03173), tolB (LHK_03172) and pal (LHK_03171)] that encode the Tol proteins, important in maintaining the integrity of the outer membrane and for bile resistance, are also present [29].
In the L. hongkongensis genome, a putative adhesin (LHK_01901) for colonization of the intestinal mucosa, most closely related to the adhesins of diffusely adherent E. coli (DAEC) and enterotoxigenic E. coli (ETEC), encoded by aidA and tibA respectively, was observed ( Figure S4) [30,31]. aidA and tibA encode proteins of the autotransporter family, type V protein secretion system of Gramnegative bacteria. All the three domains (an N-terminal signal sequence, a passenger domain and a translocation domain) present in proteins of this family are found in the putative adhesin in L. hongkongensis.
Moreover, a putative heptosyltransferase (LHK_01902), with 52% amino acid identity to the TibC heptosyltransferase of ETEC, responsible for addition of heptose to the passenger domain, was present upstream to the putative adhesin gene in the L. hongkongensis genome ( Figure S4). In addition to host cell adhesion, the passenger domains of autotransporters may also confer various virulence functions, including autoaggregation, invasion, biofilm formation and cytotoxicity. The L. hongkongensis genome encodes a putative superoxide dismutase (LHK_01716) and catalases (LHK_01264, LHK_01300 and LHK_02436), which may play a role in resistance to superoxide radicals and hydrogen peroxide generated by neutrophils.

Adaptability to Different Environmental Temperatures
To better understand how L. hongkongensis adapts to human body and freshwater habitat temperatures at the molecular level, the types and quantities of proteins expressed in L. hongkongensis HLHK9 cultured at 37uC and 20uC were compared. Since initial 2D gel electrophoresis analysis of L. hongkongensis HLHK9 proteins under a broad range of pI and molecular weight conditions revealed that the majority of the proteins reside on the weakly acidic to neutral portion, with a minority on the weak basic portion, consistent with the median pI value of 6.63 calculated for all putative proteins in the genome of L. hongkongensis HLHK9, we therefore focused on IPG strips of pH 4-7 and 7-10. Comparison of the 2D gel electrophoresis patterns from L. hongkongensis HLHK9 cells grown at 20uC and 37uC revealed 12 differentially expressed protein spots, with 7 being more highly expressed at 20uC than at 37uC and 5 being more highly expressed at 37uC than at 20uC (Table 2, Figure 3). The identified proteins were involved in various functions (Table 2). Of note, spot 8 [N-acetyl-L-glutamate kinase (NAGK)-37, encoded by argB-37] was up-regulated at 37uC, whereas spot 1 (NAGK-20, encoded by argB-20), was upregulated at 20uC (Figures 3, 4A and 4B). These two homologous copies of argB encode two isoenzymes of NAGK [NAGK-20 (LHK_02829) and NAGK-37 (LHK_02337)], which catalyze the second step of the arginine biosynthesis pathway.
The transcription levels of argB-20 and argB-37 at 20uC and 37uC were quantified by real time RT-PCR. Results showed that the mRNA level of argB-20 at 20uC was significantly higher that at 37uC and the mRNA level of argB-37 at 37uC was significantly higher that at 20uC ( Figure 4C and 4D), suggesting that their expressions, similar to most other bacterial genes, were controlled at the transcription level. When argB-20 and argB-37 were cloned, expressed and the corresponding proteins NAGK-20 and NAGK-37 purified for enzyme assays, their highest enzymatic activities were observed at 37-45uC and 45-50uC respectively ( Figure 4E). Moreover, NAGK-20, but not NAGK-37, was inhibited by 0.25-10 mM of arginine ( Figure 4F).
L. hongkongensis probably regulates arginine biosynthesis at temperatures of different habitats using two pathways with two isoenzymes of NAGK. L. hongkongensis and wild type E. coli ATCC 25922, but not E. coli JW5553-1 (argB deletion mutant), grew in minimal medium without arginine, indicating that L. hongkongensis contains a functional arginine biosynthesis pathway. NAGK-20 is expressed at higher level at 20uC than 37uC, whereas NAGK-37 is expressed at higher level at 37uC than 20uC. Bacteria use either of two different pathways, linear and cyclic, for arginine biosynthesis. Similar to NAGK-20 of L. hongkongensis, NAGK of Pseudomonas aeruginosa and Thermotoga maritima, which employ the cyclic pathway, can be inhibited by arginine as the rate-limiting enzyme for negative feedback control [34][35][36][37]. On the other hand, similar to NAGK-37 of L. hongkongensis, NAGK of E. coli, which employs the linear pathway, is not inhibited by arginine [35,36]. We speculate that L. hongkongensis can use different pathways with the two NAGK isoenzymes with differential importance at different temperatures of different habitats. Phylogenetic analysis of NAGK-20 and NAGK-37 showed that they were more closely related to each other than to homologues in other bacteria ( Figure 5). The topology of the phylogenetic tree constructed using NAGK was similar to that constructed using 16S rRNA gene sequences (data not shown). This suggested that the evolution of argB genes in general paralleled the evolution of the corresponding bacteria, and argB gene duplication has probably occurred after the evolution of L. hongkongensis into a separate species. The requirement to adapt to different temperatures and habitats may have provided the driving force for subsequent evolution to 2 homologous proteins that serve in different environments. Notably, among all 465 bacterial species with complete genome sequences available, only Thermus thermophilus, Deinococcus geothermalis, Deinococcus radiodurans, Roseiflexus castenholzii and Roseiflexus sp. RS-1 possessed two copies of argB, whereas Anaeromyxobacter sp. Fw109-5 and Anaeromyxobacter dehalo-  genans 2CP-C possessed one copy of argB and another fused with argJ ( Figure 5). The clustering of argB in two separate groups in these bacteria suggests that argB gene duplication has probably occurred in their ancestor, before the divergence into separate species. The prevalence of T. thermophilus, Deinococcus species and Roseiflexus species in hot springs suggested that this novel mechanism of temperature adaptation may also be important for survival at different temperatures in other bacteria. Further experiments on differential expression of the two isoenzymes at different temperatures in these bacteria will verify our speculations.

Conclusion
Traditionally, complete genomes of bacteria with medical, biological, phylogenetic or industrial interests were sequenced only after profound phenotypic and genotypic characterization of the bacteria had been performed. With the advance in technology and bioinformatics tools, complete genome sequences of bacteria can be obtained with greater ease. In this study, we sequenced and analyzed the complete genome of L. hongkongensis, a newly discovered bacterium of emerging medical and phylogenetic interest, and performed differential proteomics and downstream characterization of important pathways. In addition, putative virulence factors and a putative novel mechanism of arginine biosynthesis regulation at different temperatures were discovered, further characterization of which will lead to better understanding of their contributions to the survival and virulence of L. hongkongensis, the Neisseriaceae family and other bacteria. A similar ''reverse genomics'' approach can be used for the study of other newly discovered important bacteria.

Sequencing and Assembly
The genome sequence of L. hongkongensis HLHK9 was determined with the whole-genome shotgun method. Three shotgun libraries were generated: one small-insert (2-4 kb) library and one medium-insert (5-6 kb) library in pcDNA2.1, and a largeinsert (35-45 kb) fosmid library in pCC2FOS. DNA sequencing was performed using dye-terminator chemistries on ABI3700 sequencers. Shotgun sequences were assembled with Phrap. Fosmid end sequences were mapped onto the assembly using BACCardI [38] for validation and support of gap closing. Sequences of all large repeat elements (rRNA operons and prophages) were confirmed by primer walking of fosmid clones.
The nucleotide sequence for the complete genome sequence of L. hongkongensis HLHK9 was submitted to Genbank under accession number CP001154.

Genome Annotation
Gene prediction was performed by Glimmer [39] version 3.02, and results post-processed using TICO [40] for improving predictions of translation initiation sites. Automated annotation of the finished sequence was performed by a modified version of AutoFACT [41], supplemented by analysis by InterProScan [42]. Manual curation of annotation results was done with support from the software tool GenDB [43]. In addition, annotation of membrane transport proteins was done by performing BLAST search of all predicted genes against the curated TCDB [44]. Ribosomal RNA genes were annotated using the online RNAmmer service [45]. Putative prophage sequences were identified using Prophage Finder [46]. Frameshift errors were predicted using ProFED [47]. CRISPRs (Clustered Regularly Interspaced Short Palindromic Repeats) were searched by using PILER-CR [48], CRISPRFinder [49] and CRT (CRISPR recognition tool) [50].

Proteomic Analysis by 2D Gel Electrophoresis
Single colony of L. hongkongensis HLHK9 was inoculated into brain heart infusion (BHI) medium for 16 h. The bacterial cultures were diluted 1:100 in BHI medium and growth was continued at 20uC for 20 h and 37uC for 6 h, respectively, with shaking to OD 600 of 0.6. After centrifugation at 6,5006g for 15 min, cells were lysed in a sample buffer containing 7 M urea, 2 M thiourea and 4% CHAPS. The crude cell homogenate was sonicated and centrifuged at 16,0006g for 20 min. Immobilized pH gradient (IPG) strips (Bio-Rad Laboratories) (17 cm) with pH 4-7 and 7-10 were hydrated overnight in rehydration buffer containing 7 M urea, 2 M thiourea, 4% CHAPS, 1% IPG buffer pH 4-7 (IPG strip of pH 4-7) and pH 6-11 (IPG strip of pH 7-10) (GE Healthcare) and 60 mM DTT with 60 mg of total protein. The first dimension, isoelectric focusing (IEF), was carried out in a Protean IEF cell electrophoresis unit (Bio-Rad Laboratories) for about 100,000 volt-hours. Protein separation in the second dimension was performed in 12% SDS-PAGE utilizing the Bio-Rad Protean II xi unit (Bio-Rad Laboratories). 2D gels were stained with silver and colloidal Coomassie blue G-250 respectively for qualitative and quantitative analysis, and scanned with ImageScanner (GE Healthcare). ImageMaster 2D Platinum 6.0 (GE Healthcare) was used for image analysis. For MALDI-TOF MS analysis, protein spots were manually excised from gels and subjected to in-situ digestion with trypsin, and peptides generated were analyzed using a 4800 Plus MALDI TOF/TOF Analyzer (Applied Biosystems). Proteins were identified by peptide mass fingerprinting using the MS-Fit software (http://prospector.ucsf. edu) and an in-house sequence database of L. hongkongensis HLHK9 proteins generated using the information obtained from the complete genome sequence and annotation. Only spots with at least two-fold difference in their spot volume between 20uC and 37uC and those uniquely detected at either temperature were subjected to protein identification by MALDI-TOF MS analysis. Three independent experiments for each growth condition were performed.
Essentiality of Arginine for Growth of L. hongkongensis HLHK9 L. hongkongensis HLHK9 cells were grown in minimal medium M63 [51] supplemented with 20 mM L-malate as carbon source and 19 mM potassium nitrate as nitrogen source, and 1 mM each of vitamin B1 and vitamin B12. The pH of all media was adjusted to 7.0 with KOH. Essentiality of arginine for growth of L. hongkongensis HLHK9 was determined by transferring the bacterial cells to the modified M63 medium with or without 100 mM of Larginine. Escherichia coli ATCC 25922 and JW5553-1 (argB deletion mutant) [52] were used as positive and negative controls respectively. All cultures were incubated at 37uC with shaking for 5 days. Growth in each medium was determined by measuring absorbance spectrophotometrically at OD 600 . The experiment was performed in duplicate.

Real-Time RT-PCR
mRNA levels of argB-20 and argB-37 in L. hongkongensis HLHK9 cells grown in 20uC and 37uC were compared. Total RNA was extracted from culture of L. hongkongensis HLHK9 (OD 600 of 0.6) grown in conditions described in proteomic analysis by using RNeasy kit (Qiagen) in combination with RNAprotect Bacteria Reagent (Qiagen) as described by the manufacturer. Genomic DNA was removed by DNase digestion using RNase-free DNase I (Roche). The total nucleic acid concentration and purity were estimated using A 260 /A 280 values measured by NanoDrop ND-1000 spectrophotometer (NanoDrop Technologies). Bacteria were harvested from three independent replicate cultures. cDNA was synthesized by RT using random hexamers and SuperScript III kit (Invitrogen) as described previously [53,54] (Table S4). Reactions were first incubated at 50uC for 2 min, followed by 95uC for 10 min in duplicate wells. Reactions were then thermal-cycled in 40 cycles of 95uC for 15 s and 60uC for 1 min. Absolute standard curve method was used for determination of transcript level for each gene. Standard curves were made by using serial dilutions from plasmids containing the target sequences with known quantities. Housekeeping gene RNA polymerase beta subunit, rpoB, was used as an internal control. Triplicate assays using RNAs extracted in three independent experiments confirmed that transcript levels of rpoB were not significantly different (P.0.05) at 20uC compared with 37uC (data not shown). The transcript levels of argB-20 and argB-37 were then normalized to that of rpoB. Triplicate assays using RNAs extracted in three independent experiments were performed for each target gene.

Phylogenetic Characterization
The phylogenetic relationships among NAGK-20 and NAGK-37 of L. hongkongensis HLHK9 and their homologues in other bacteria with complete genomes available were analyzed. Phylogenetic tree was constructed by the neighbor-joining method using Kimura's two-parameter correction with ClustalX 1.83. Three hundred and eleven positions were included in the analysis.
Cloning and Purification of (His) 6 -Tagged Recombinant NAGK Proteins of L. hongkongensis HLHK9 Cloning and purification of (His) 6 -tagged recombinant NAGK proteins of L. hongkongensis HLHK9 was performed according to our previous publications, with modifications [53,55]. To produce plasmids for protein purification, primers (59-GGAATTCCA-TATGCTGCTTGCAGACGCCC -39 and 59-GGAATTCCA-TATGTCAGGCTGCGCGGATCAT -39 for argB-20 and 59-GGAATTCCATATGGTTATTCAATCTGAAGT -39 and 59-GGAATTCCATATGTCAGAGCGTGGTACAGAT -39 for argB-37) were used to amplify the genes encoding NAGK-20 and NAGK-37, respectively, by PCR. The sequence coding for amino acid residues of the complete NAGK-20 and NAGK-37 was amplified and cloned, respectively, into the NdeI site of expression vector pET-28b(+) (Novagen) in frame and downstream of the series of six histidine residues. The two recombinant NAGK proteins were expressed and purified using the Ni 2+ -loaded HiTrap Chelating System according to the manufacturer's instructions (GE Healthcare).

Enzyme Assays
Purified NAGK-20 and NAGK-37 were assayed for N-acetyl-Lglutamate kinase activity using Haas and Leisinger's method [56], with modifications. The reaction mixtures contained 400 mM NH 2 OH?HCl, 400 mM Tris?HCl, 40 mM N-acetyl-L-glutamate, 20 mM MgCl 2 , 10 mM ATP and 2 mg of enzyme in a final volume of 1.0 ml at pH 7.0. After incubation at 25uC, 30uC, 37uC, 45uC, 50uC, 55uC or 60uC for 30 min, the reaction was terminated by adding 1.0 ml of a stop solution containing 5% (w/ v) FeCl 3 ?6H 2 O, 8% (w/v) trichloroacetic acid and 0.3 M HCl. The absorbance of the hydroxamate?Fe 3+ complex was measured with a spectrophotometer at A 540 [57]. Inhibition of the kinase activities of NAGK-20 and NAGK-37 were examined with and without 0.25, 0.5, 0.75, 1, 2.5, 5, 10, and 20 mM of L-arginine and incubated at 37uC for 30 min. One unit of N-acetyl-Lglutamate kinase is defined as the amount of enzyme required to catalyze the formation of 1 mmol of product per min under the assay conditions used. Each assay was performed in duplicate. Results were presented as means and standard deviations of three independent experiments. Figure S1 Physical map of the chemotaxis-related genes in L. hongkongensis. While the three gene clusters contain the transducer proteins and some of the methyl-accepting proteins (MCPs), most MCPs are scattered outside the clusters. Genes in orange are coding for chemotaxis transducer proteins; genes in green are coding for MCPs; genes in grey are coding for hypothetical proteins. The numbers refer to the coding sequences in the L. hongkongensis genome.