‘Ca. Liberibacter asiaticus’ Proteins Orthologous with pSymA-Encoded Proteins of Sinorhizobium meliloti: Hypothetical Roles in Plant Host Interaction

L. David Kuykendall; Jonathan Y. Shao; John S. Hartung

doi:10.1371/journal.pone.0038725

Abstract

Sinorhizobium meliloti strain 1021, a nitrogen-fixing, root-nodulating bacterial microsymbiont of alfalfa, has a 3.5 Mbp circular chromosome and two megaplasmids including 1.3 Mbp pSymA carrying nonessential ‘accessory’ genes for nitrogen fixation (nif), nodulation and host specificity (nod). A related bacterium, psyllid-vectored ‘Ca. Liberibacter asiaticus,’ is an obligate phytopathogen with a reduced genome that was previously analyzed for genes orthologous to genes on the S. meliloti circular chromosome. In general, proteins encoded by pSymA genes are more similar in sequence alignment to those encoded by S. meliloti chromosomal orthologs than to orthologous proteins encoded by genes carried on the ‘Ca. Liberibacter asiaticus’ genome. Only two ‘Ca. Liberibacter asiaticus’ proteins were identified as having orthologous proteins encoded on pSymA but not also encoded on the chromosome of S. meliloti. These two orthologous gene pairs encode a Na⁺/K+ antiporter (shared with intracellular pathogens of the family Bartonellacea) and a Co++, Zn++ and Cd++ cation efflux protein that is shared with the phytopathogen Agrobacterium. Another shared protein, a redox-regulated K+ efflux pump may regulate cytoplasmic pH and homeostasis. The pSymA and ‘Ca. Liberibacter asiaticus’ orthologs of the latter protein are more highly similar in amino acid alignment compared with the alignment of the pSymA-encoded protein with its S. meliloti chromosomal homolog. About 182 pSymA encoded proteins have sequence similarity (≤E-10) with ‘Ca. Liberibacter asiaticus’ proteins, often present as multiple orthologs of single ‘Ca. Liberibacter asiaticus’ proteins. These proteins are involved with amino acid uptake, cell surface structure, chaperonins, electron transport, export of bioactive molecules, cellular homeostasis, regulation of gene expression, signal transduction and synthesis of amino acids and metabolic cofactors. The presence of multiple orthologs defies mutational analysis and is consistent with the hypothesis that these proteins may be of particular importance in host/microbe interaction and their duplication likely facilitates their ongoing evolution.

Citation: Kuykendall LD, Shao JY, Hartung JS (2012) ‘Ca. Liberibacter asiaticus’ Proteins Orthologous with pSymA-Encoded Proteins of Sinorhizobium meliloti: Hypothetical Roles in Plant Host Interaction. PLoS ONE 7(6): e38725. https://doi.org/10.1371/journal.pone.0038725

Editor: Paulo Lee Ho, Instituto Butantan, Brazil

Received: February 1, 2012; Accepted: May 14, 2012; Published: June 25, 2012

This is an open-access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication.

Funding: No current external funding sources for this study.

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

Introduction

Within the order Rhizobiales of the class alpha-Proteobacteria, Sinorhizobium meliloti is a member of a diverse bacterial family, Rhizobiaceae [1]–[3]. Other genera contained within the Rhizobiaceae and indeed the Rhizobium type genus [3] include Agrobacterium and Rhizobium [4]. A growing number of species of the family Rhizobiaceae and of the order Rhizobiales are becoming recognized based on 16 S RNA gene sequence data. Many species interact with plants and other eukaryotes to produce important agricultural, economic and/or environmental consequences. ‘Ca. Liberibacter asiaticus’ is recognized as the causal agent of huanglongbing (HLB), also known as citrus greening disease. This phytopathogen was introduced into the New World from Asia [5], [6], and is transmitted by the citrus psyllid, Diaphorina citri [7]. The full genomic sequence of ‘Ca. Liberibacter asiaticus’ was determined by deep sequencing of total DNA obtained from a single citrus psyllid which contained more than 10⁸ cells of ‘Ca. Liberibacter asiaticus.’ Phylogenetic analysis indicated that ‘Ca. Liberibacter asiaticus’ and S. meliloti are close bacterial relatives [2]. ‘Ca. Liberibacter asiaticus’ has a single small chromosome of 1.23 Mbps with 36.5% GC content compared to the chromosome of S. meliloti which is 3.65 Mbps and 62.7% GC [2], [8]. ‘Ca. Liberibacter asiaticus’ is not available in culture but can colonize intracellularly and move systemically in the phloem vessels of citrus trees [9], [10] following introduction by the citrus psyllid, D. citri. ‘Ca. Liberibacter asiaticus’ also systemically and intracellularly colonizes citrus psyllid salivary glands [11]. The genome of ‘Ca. Liberibacter asiaticus’ has many adaptations to facilitate an intracellular lifestyle in both plant and insect cells [2], [12].

S. meliloti 1021, free living in the soil, also lives in specialized root nodules in symbiosis with alfalfa, Medicago sativa L., where S. meliloti reduces atmospheric nitrogen and thereby confers plant nitrogen sufficiency. S. meliloti 1021 has a composite genome comprised of the chromosome and two megaplasmids, pSymA and pSymB, of 1.3 Mbps and 1.7 Mbps [8]. Megaplasmids pSymA and pSymB encode 1293 and 1570 protein-coding genes, respectively [8], [13].

Predicted gene products of all open-reading frames (ORFs) in the genome of ‘Ca. Liberibacter asiaticus’ were compared by protein BLAST against all of the predicted gene products encoded by chromosomal genes of S. meliloti 1021 [2]. However, predicted gene products of all ORFs encoded on the plant symbiosis-controlling S. meliloti megaplasmid pSymA had not been previously subjected to protein BLAST compared with the predicted gene products encoded in the ‘Ca. Liberibacter asiaticus’ genome. As an “accessory” genome component [14], pSymA may have originated from an ancestral plasmid and may have maintained individual and some small blocks of genes originally from host chromosomes. It has long been known that the pSymA megaplasmid of S. meliloti, in contrast to the circular chromosome or the other S. meliloti megaplasmid pSymB, specializes in carrying genes essential for establishing and maintaining intimate intracellular plant interactions with alfalfa. The megaplasmid pSymA itself is self-transmissible and upon transfer confers nodulation (nod), nitrogen fixation (nif) and other symbiotic abilities in related bacteria with a similar genetic background or complement of chromosomal genes [15]–[17]. The chromosome of the tumor-inducing bacterial phytopathogen Agrobacterium tumefaciens encodes characteristics practically identical to those of Rhizobium microsymbionts, and members of the species also maintain pTi as an accessory genomic component. When bacterial cells recruit or accept transfer of the Ti plasmid or pSymA, either tumor-inducing pathogenicity or nitrogen-fixing symbiotic ability, respectively, is conferred on the host bacterium. Agrobacterium and Rhizobium were combined into a single genus within the Rhizobiaceae largely for this reason and to reject taxonomy based largely on plant interactions determined by extrachromosomal elements, i.e., to avoid plasmid-based nomenclature [4].

As S. meliloti is a close phylogenetic relative of ‘Ca. Liberibacter asiaticus,’ it is likely that the two bacteria deploy a similar repertoire of mechanisms for avoiding defenses elicited in host plant cells by their invasion, or, in the case of beneficial root nodule bacteria, recruitment or “welcomed entry” [18]. The goal of the present study was to compare predicted gene products encoded by the genome of ‘Ca. Liberibacter asiaticus’ with those encoded by genes carried on the megaplasmid pSymA of S. meliloti strain 1021. The rationale for identifying protein products of ‘Ca. Liberibacter asiaticus’ genes orthologous to those encoded by genes on pSymA is simply that such genes and their protein products may play direct or indirect role(s) in establishing and maintaining an intimate intracellular interaction with eukaryotes. We have identified a number of such interesting protein products.

Results

Maintenance of Homeostasis

In general, proteins encoded by pSymA genes are more similar in sequence alignment to those encoded by S. meliloti chromosomal orthologs than to orthologous proteins encoded by genes carried on the ‘Ca. Liberibacter asiaticus’ genome. There are two very notable exceptions where orthologs are shared only by pSymA and ‘Ca. Liberibacter asiaticus’ and not with the chromosome of S. meliloti. YP_003064907, the predicted protein product of a ‘Ca. Liberibacter asiaticus’ gene, is orthologous to NP_435608.2 (E = 5e-71) encoded by pSymA yet lacks an orthologous protein encoded by the chromosome of S. meliloti (Table 1). SMART analysis predicts that YP_003064907, has a cation efflux domain (E = 1.3e-31) from residues 15 to 313 of the 313 amino acid protein. This predicted protein also has BLAST matches with cobalt, zinc and cadmium efflux proteins (COG3965) [19]. pSymA-encoded NP_436297.2 is orthologous to YP_003064775 (E = 3e-30) encoded on the chromosome of ‘Ca. Liberibacter asiaticus’, but neither has an ortholog encoded by the S. meliloti chromosome (Table 1). SMART analysis of ‘Ca. Liberibacter asiaticus’ YP_003064775, annotated as a nhaA gene, predicts a sodium/proton antiporter domain (E = 2.1e-113) at residues 4 to 379 of the 381 amino acid protein [20], [21]. These two protein pairs are the only two protein pairs uniquely shared by pSymA and ‘Ca. Liberibacter asiaticus’. A third orthologous protein pair comprised of NP_436118.1 (pSymA) and YP_003065337 (‘Ca. Liberibacter asiaticus’) is much more similar in amino acid sequence (E = 1e-134) than is NP_436118.1 and its ortholog encoded by the S. meliloti chromosome, NP_384912 (E = 1e-22). Bioinformatic analyses revealed that YP_003065337 is a potassium efflux protein. Control of intracellular pH is ascribed in its domain architecture. SMART analysis of YP_003065337 confidently predicts two domains as follows: an amino-terminal sodium/proton exchanger domain (E = 2.7e-72) from residues 4 to 394 and a non-overlapping TrkA domain (E = 8.3e-25) for redox regulation, from amino acids 451–566 of the 609 amino acid protein. ‘Ca. Liberibacter asiaticus’ YP_003065245, a potassium uptake protein, has E = 0 alignments with both pSymA (NP_436237.1) and S. meliloti chromosomal orthologs (Table 1). These proteins likely contribute to the maintainence of intracellular homeostasis through the regulation of pH and the control of mono- and divalent cation concentrations.

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Table 1. Proteins shared between the Sinorhizobium meliloti plasmid pSymA, and the ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti chromosomes and with roles in the maintenance of homeostasis or signal transduction.

https://doi.org/10.1371/journal.pone.0038725.t001

Signal Transduction

There are several orthologous proteins encoded by genes shared between pSymA and the ‘Ca. Liberibacter asiaticus’ and S. meliloti chromosomes that are predicted to function in sensing and signal transduction. For example, YP_003064826, a PAS/PAC sensor signal transduction kinase has a pSymA ortholog and a S. meliloti chromosomal ortholog. Several two-component response regulators or sensor histidine kinases are encoded both by genes on pSymA and the genome ‘Ca. Liberibacter asiaticus’, and include YP_003065306, which has a characteristic N-terminal CheY-like sensor and Trans_reg_C which are DNA-binding transcriptional activator/effector domains. YP_003064863, a two component sensor histidine kinase/response regulator hybrid protein, is a FixL-like oxygen-controlled histidine kinase homologous to several pSymA-encoded proteins (E = 3e-49 for the most similar ortholog) (Table 1).

ABC-cassette Type Amino Acid Transporters

ATP Binding Cassette type amino acid transporters comprise the largest class of genes shared by ‘Ca. Liberibacter asiaticus’, pSymA and the S. meliloti chromosome (Table 2). For most ABC-type transporter proteins encoded by ‘Ca. Liberibacter asiaticus’ genes there are multiple homologs on pSymA, dispersed over the megaplasmid (Table S1). YP_003064586 is an example of an ABC-type transporter protein from ‘Ca. Liberibacter asiaticus’. In addition to NP_435288.1 there are 10 more pSymA-encoded proteins homologous to YP_003064586 (E = 4e-67 up to 1e-14), and all are annotated as general amino acid transporters with an ATP binding site and other characteristics of an ABC type amino acid transporter. The corresponding genes are dispersed across the pSymA (Fig. 1A; Table 2).

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Figure 1. Distribution of genes on the S. meliloti pSymA megaplasmid that encode proteins orthologous to YP_003064586, annotated as an ABC-Type amino acid transporter in ‘Ca.

Liberibacter asiaticus’ (A), that encode proteins orthologous to YP_003064948, annotated as a 3-ketoacyl-(acyl carrier protein) reductase in ‘Ca. Liberibacter asiaticus’ (B) and that encode proteins orthologous to YP_003064695, annotated as a LysR type regulator of transcription in ‘Ca. Liberibacter asiaticus’ (C).

https://doi.org/10.1371/journal.pone.0038725.g001

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Table 2. Proteins shared between the Sinorhizobium meliloti plasmid pSymA, and the ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti chromosomes with roles in ABC-Type transport and the synthesis of amino acids and metabolic cofactors.

https://doi.org/10.1371/journal.pone.0038725.t002

YP_003064753 is a proline/glycine betaine ABC transporter protein with eight pSymA-encoded homologs (Table S1). YP_003064754, another proline/glycine betaine permease/ABC transporter permease protein, has two pSymA-encoded homologs. ‘Ca. Liberibacter asiaticus’ YP_003065117 and YP_003064552, both ATP-binding ABC-type transporter proteins, each have four homologs encoded by genes on pSymA. YP_003065525, a putative amino acid-binding periplasmic protein, is homologous to two pSymA-encoded predicted proteins. YP_003065526, an ABC-type amino acid transporter permease, has 7 homologs encoded by pSymA genes. These are examples of multiple, redundant shared homologs of ABC-type amino acid transport systems encoded by pSymA. ‘Ca. Liberibacter asiaticus’ YP_003064636 is an exception since this putative transmembrane ABC-type transporter permease has only one pSymA-encoded homolog, NP_435480.1 (Table 2). The multiplicity of ABC-type transporter homologs on pSymA presumably provides a repertoire of ABC transporters for S. meliloti, and is consistent with a high magnitude of importance for ABC transporter systems in S. meliloti. In contrast, ‘Ca. Liberibacter asiaticus’ lacks the general overall redundancy of ABC-type transporters present in S. meliloti.

Metabolic cofactors are also likely to be imported by ‘Ca. Liberibacter asiaticus’ and S. meliloti from the plant host. For example, essential vitamins are up taken by ABC-type transporters encoded by pSymA and the ‘Ca. Liberibacter asiaticus’ chromosome. YP_003064972, an ATP-binding component of an ABC transport complex for thiamine, has two homologs on both pSymA and the S. meliloti chromosome.

Synthesis of Metabolic Cofactors and Amino Acids

In addition to transporter proteins, there are a large number of genes shared between ‘Ca. Liberibacter asiaticus’, S. meliloti and pSymA that encode proteins involved in the synthesis of metabolic cofactors (Table 2). ‘Ca. Liberibacter asiaticus’ YP_003064901 encodes adenosylmethionine-8-amino-7-oxononanoate transaminase (E = 5e-35). The enzyme 8-amino-7-oxononanoate synthase (AONS), which is pyridoxal 5′-phosphate-dependent, catalyzes 8-amino-7-oxononanoate synthesis, needed for biosynthesis of biotin. ‘Ca. Liberibacter asiaticus’ YP_003064762 is a serine hydroxymethyltransferase (SHMT) that catalyzes production of L-serine and tetrahydrofolate with an exceptionally low E-value when compared with its pSymA ortholog NP_436409. YP_003065324 encodes formyltetrahydrofolate deformylase, active in glyoxylate and dicarboxylate metabolism. YP_003064946 is a 3-oxoacyl-(acyl carrier protein) synthase, presumably involved in fatty acid synthesis, orthologous to NodE, a pSymA-encoded protein NP_435712.1 (E = 4e-63). YP_003064948, annotated as a 3-ketoacyl-(acyl carrier protein) reductase, is a dehydrogenase involved in fatty acid biosynthesis (COG1028). Megaplasmid pSymA encodes 20 proteins similar to YP_003064948 (E = 8e-78 to E = 2e-11) (Fig. 1B; Table S1).

Genes on pSymA with orthologs on the ‘Ca. Liberibacter asiaticus’ and S. meliloti chromosomes also encode enzymes involved in the synthesis of amino acids (Table 2). The predicted protein products of ‘Ca. Liberibacter asiaticus’ YP_003064878 and pSymA NP_435501.1 (E = 3e-75) have domains expected of threonine synthase, ThrC, a member of the TrpB tryptophan synthase superfamily. YP_003064845 is an acetylornithine transaminase protein, part of the arginine metabolism and lysine biosynthesis pathways. ‘Ca. Liberibacter asiaticus’ YP_003064846 and its orthologs in S. meliloti, encoded by genes on pSymA and its chromosome, are predicted to be an ornithine carbamoyl transferase, involved in arginine metabolism. YP_003065195 and its S. meliloti homolog are succinyl diaminopimelate desuccinylase involved in lysine biosynthesis. However, NP_436258.1, a similar protein encoded by pSymA, is annotated as an acetylornithine deacetylase, an enzyme which catalyzes a step in arginine metabolism. Plant hosts of ‘Ca. Liberibacter asiaticus’ are presumed to supply some amino acids to the obligate phytopathogen since certain genes for the biosynthesis of several amino acids were not found in the comparison of the chromosomes of ‘Ca. Liberibacter asiaticus’ and S. meliloti [2].

Export of Bioactive Molecules

In addition to the proteins involved in the import or potential export of amino acids and metabolic cofactors, ‘Ca. Liberibacter asiaticus’ shares genes with pSymA and the S. meliloti chromosomes for several proteins used to export small bioactive molecules (Table 3). These include YP_003064686 an ABC-type transporter with excellent Blast alignments with chromosomal virulence gene (chvD) in Agrobacterium, Bartonella and Brucella [22].

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Table 3. Proteins shared between the Sinorhizobium meliloti plasmid pSymA, and the ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti chromosomes with roles in the export of bioactive molecules, as chaperonins and in the regulation of transcription and translation.

https://doi.org/10.1371/journal.pone.0038725.t003

The ‘Ca. Liberibacter asiaticus’ genome encodes two nodI homologs, likely involved in exporting lipid virulence factors. YP_003065157, an ATP-binding ABC-type transporter protein with a yhbG domain, is similar to pSymA nodI, a multidrug efflux-like protein that secretes lipids and lipopolysaccarides including cell wall and outer membrane or Nod factor components. Interestingly, pSymA encodes six homologs of YP_003065157, consistent with important roles for these proteins in the S. meliloti/alfalfa interaction. When ABC-type transporters of ‘Ca. Liberibacter asiaticus’ were blasted against the Transporter Classification Database (http://www.tcdb.org/), YP_003065330, annotated as an ABC-type transporter nucleotide binding/ATPase, was homologous with Q2G2M9 (4.00E-088), a putative multi-drug export ATP-binding/permease protein of Staphylococcus aureus,SAOUHSC_02003. Like YP_003065157, YP_003065330 aligns best with nodI NP_435718.1 (2.00E-021) encoded by pSymA.

‘Ca. Liberibacter asiaticus’ YP_003065113, orthologous to pSymA-encoded protein NP_435856.2 (E = 5e-33), a serine protease DO protease, has a PDZ-metalloprotease domain, a PDZ serine protease domain and a trypsin domain, all fused into a single multi-domain protease product. This protein, a probable virulence factor, is likely to protrude from ‘Ca. Liberibacter asiaticus’ into the host cell where it can presumably digest host proteins using zinc as a cofactor.

Chaperonins

Several chaperonin proteins are encoded by orthologous genes shared by ‘Ca. Liberibacter asiaticus’, pSymA and S. meliloti (Table 3). YP_003065051 is a DnaJ molecular chaperone protein with one orthologous protein encoded by pSymA, NP435305.2. Cold shock protein YP_003065326 has three similar proteins encoded by pSymA. YP_003065262 (GroEL) is orthologous with both pSymA NP_435641.1 (E = 0) and with pSymA NP_435310.1 (E = 1e-166). Co-chaperonin GroES YP_003065261 is orthologous with pSymA-encoded NP_535311.1 (E = 4e-22) and NP_435642.1 (E = 9e-21).

Regulation of Transcription and Translation

‘Ca. Liberibacter asiaticus’, pSymA and S. meliloti share several proteins that regulate transcription (Table 3). YP_003064695 is a member of the LysR family of transcription regulator proteins. Its importance for plant interaction is indicated by at least 14 LysR-like proteins encoded by and distributed across pSymA (E = 1e-21 to E = 1e-10) (Fig. 1C; Table S1). Other genes encoding transcriptional regulators are not as extensively duplicated on pSymA, consistent with LysR family transcription regulators being of unique importance in plant interaction in S. meliloti [23]. The ‘Ca. Liberibacter asiaticus’ genome, by contrast, encodes only YP_003064695, annotated as transcriptional regulator with a LysR region. YP_003065329, a putative sigma-54-dependent transcription regulator protein is similar to NP_435689 in pSymA annotated as NifA. NifA is a DNA-binding ATPase and CheY-like two-component sensor-based response regulator that is known to activate expression of genes involved in nitrogen metabolism. YP_003065196, encodes a transcription-activating MucR-like protein [24], with two orthologs on pSymA. MucR proteins regulate production of extracellular polysaccharides which could contribute to biofilm formation in phloem cells of citrus inhabited by ‘Ca. Liberibacter asiaticus.’ YP_003065365 and pSymA NP_436495 (E = 7e-49) are encoded by orthologous genes for a UvrD2 DNA helicase II, or superfamily I DNA and RNA helicase. ‘Ca. Liberibacter asiaticus’ YP_003065000 and pSymA orthologs NP_436130.1 and NP_436426.1 encodes a XerD recombinase/integrase. YP_003064676, a Tu translation elongation factor, is orthologous to pSymA-encoded NP_435253 (E = 7e-19) and to NP_435715.1 (E = 6e-18), and is involved in the synthesis of proteins. YP_003065391 encodes aspartyl/glutamyl-tRNA amidotransferase, an enzyme known to allow formation of correctly charged asparagine or glutamine tRNAs in organisms which lack either or both a asparaginyl-tRNA synthetases or a glutaminyl-tRNA synthetase.

Cell Surface

‘Ca. Liberibacter asiaticus’ and pSymA share several genes encoding proteins that contribute to a functional architecture of the cell surface (Table 4). A UDP-glucose-4-epimerase, YP_003064741 probably has a role interconverting monosaccarides needed for exopolysaccaride synthesis. Cyclic diguanylate controls biofilm formation [25]. YP_003064881, a putative prokaryotic sensory diguanylate cyclase/phosphodiesterase protein, has two orthologs on pSymA, NP_435318.2 (E = 1e-42) and NP_436089.2 (E = 7e-42). YP_003065366 encodes an OmpA/MotB-like protein similar with S. meliloti pSymA NP_435574.1 (E = 8e-14) and the S. meliloti chromosome NP_384380 (E = 2e-16). Pilus assembly gene clusters on pSymA have orthologs on the ‘Ca. Liberibacter asiaticus’ chromosome. Proteins YP_003065134 (NP_436096, E = 5e-50), YP_003065135 (NP_436097, E = 3e-49), YP_003065137 (NP_436098, E = 1e-178; NP_435955, E = 2e-35), YP_003065140 (NP_435332.2, E = 9e-45) and YP_003065141 (NP_436102.1, E = 3e-29) are all components of a pilus assembly for ‘Ca. Liberibacter asiaticus’. YP_003065138, a pilus-associated response regulator receiver protein, likely regulates production of pili based on signals received from the environment.

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Table 4. Proteins shared between the Sinorhizobium meliloti plasmid pSymA, and the ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti chromosomes with roles in the modification of cell surface structures.

https://doi.org/10.1371/journal.pone.0038725.t004

A transglycosylase, YP_003064721 in ‘Ca. Liberibacter’ asiaticus’ and pSymA-encoded NP_436359.1 (E = 3e-40), could produce cell wall degradation products. YP_003064721 signal peptide protein orthologous to pSymA NP_436359.1 and is a putative membrane-bound lytic murein transglycosylase (E = 3e-40).

YP_003065165, a penicillin-binding peptidoglycan synthase, is orthologous to NP_ 436481.1 (E = 0). A transmembrane protein that also binds penicillin, YP_003065516 is orthologous to pSymA NP_436482.1 (E = 1e-93). ‘Ca. Liberibacter asiaticus’ YP_003065356 (Table 1), a glucosamine-fructose-5-phosphate aminotransferase, needed for N-acetyl D-glucosamine synthesis, aligns with pSymA-encoded NP_435728.1 (E = 0).

Electron Transfer

An important conserved microsyntenous orthologous gene (MOG) cluster, occurs in the ‘Ca. Liberibacter asiaticus’ genome and in the genomes of four other members of the Rhizobiales that were analyzed previously [26]. This conserved MOG encodes thirteen subunits that comprise a “mitochondrial-like” Type I respiratory complex (Table 5). Genes encoding this respiratory complex are also found on pSymA, and orthologous proteins specified by ‘Ca. Liberibacter asiaticus’ chromosomal genes include the following: Chain A, NuoA2 NADH: ubiquinone oxidoreductase YP_003065265 and NP_436080.1 (E = 9e-14); Chain B, or NuoB2 YP_003065266 and NP_436079 (E = 6e-48); Chain C, or NuoC2 YP_003065267 and NP_436078.1 (E = 6e-33); Chain D, or NuoD2 YP_003065268 and NP_436077.1 (E = 1e-110); Chain E or NuoE2, YP_003065269 and NP_436076.1 (E = 4e-24) and Chain F or NuoF2 YP_003065271 and NP_436075.1 (E = 1e-104). Chains G, H and I/J or NuoG2, NuoH2, a multi-subunit ubiquinone oxidase have the following orthologs: YP_003065272 and NP_436074.1 (E = 2e-62); YP_003065273 and NP_436071.1 (E = 1e-51), YP_003065274 and NP_436072.1 (E = 1e-22), and YP_003065275 and NP_436087.2 (E = 8e-11). YP_003065278 is orthologous with pSym proteins NP_436085.1 and NP_436083.4 annotated as, respectively, a multidomain K/L oxidoreductase, a NADH ubiquinone oxidase (COG1009), or a multi-domain Na+/K+ antiporter, largely synonomous, involved in energy generation, cation efflux or intracellular pH control. ‘Ca. Liberibacter asiaticus’ YP_003065279 and pSymA NP_436082.1 (E = 2e- 92) are chain M of ubiquinone oxidoreductase. ‘Ca. Liberibacter asiaticus’ YP_003065280 and pSymA NP_436081.1 are chain N (E = 4e-57). Nearly all orthologous proteins shared between pSymA and S. meliloti chromsome have lower E-values aligned with each other than do orthologs shared between pSymA and the ‘Ca. Liberibacter asiaticus’ chromosome (Tables 1–4). However the amino acid sequence similarities between protein components of the respiratory complex I encoded by pSymA, and the ‘Ca. Liberibacter asiaticus’ genome and the S. meliloti chromosome are highly comparable with each other (Table 5). The organization of the genes in genomic regions encoding the NADH dehydrogenase complex is the same for S. meliloti and ‘Ca. Liberibacter asiaticus’ (Fig. 2). NuoG and NuoL are encoded by genes in the expected cluster on the S. meliloti chromosome. But the e-values obtained by pBlast of pSymA NuoG and NuoL vs S. meliloti are better for genes found elsewhere on the S. meliloti chromosome. The best match for pSymA NuoG (NP_43074) on the S. meliloti chromosome is a NAD-dependent formate dehydrogenase alpha subunit (NP_387115; E = 2e⁻⁹⁵). The NADH dehydrogenase subunit G (NP_385378; E = 8e⁻⁷⁷) is the second best result. This protein is transcribed and translated from a gene with the expected position in the NADH dehydrogenase MOG and aligns well with the ‘Ca. Liberibacter asiaticus’ NuoG (e = 0). A similar finding was obtained when pSymA NP_436085 encoding the NuoL subunit was used in a blast search of the chromosome of S. meliloti. The best matches were to proteins annotated as monovalent cation/H+ antiporter subunits located at different positions on the chromosome. NADH dehydrogenase subunit L (NP_385383; E = 7e⁻²⁵) encoded by the chromosome was significantly less well-aligned. As was seen for NuoG, this protein is transcribed from a gene with the expected position in the NADH dehydrogenase MOG and aligns well with the ‘Ca. Liberibacter asiaticus’ NuoL (e = 0). Thus these proteins likely function in the role of NuoL. The NADH dehydrogenase gene cluster on pSymA has a different arrangement of genes (Fig. 2). Genes encoding NuoA-NuoG in the center of the Nuo gene cluster are flanked on one side by genes encoding NuoJ – NuoN and by genes, transcribed from the opposite strand, that encode NuoH and NuoI on the other side.

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Figure 2. Diagram showing the organization of the genes encoding the components of the NADH dehydrogenase complex on pSymA, ‘Ca. Liberibacter asiaticus’ and S. meliloti.

https://doi.org/10.1371/journal.pone.0038725.g002

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Table 5. Proteins shared between the Sinorhizobium meliloti plasmid pSymA, and the ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti chromosomes with roles in electron transfer.

https://doi.org/10.1371/journal.pone.0038725.t005

Other proteins are encoded by genes shared by ‘Ca. Liberibacter asiaticus’, pSymA and the chromosome of S. meliloti, and have roles in energy generation. YP_003065437, is a probable electron transfer flavoprotein-quinone oxidoreductase or FixC. YP_003064703 is orthologous with both pSymA-borne NP_435265.2 and NP_435950.1, which are zinc-dependent NADPH quinone oxidoreductases, COG0604, and are important in energy production. YP_003064781 and YP_003064782, encoded by adjacent genes, are orthologs of NP_436008.1 and NP_436007.1 (E = 3e-73 and 2e- 77 respectively). Both genes have two adjacent ortholog pairs on both pSymA and the S. meliloti chromosome. YP_003065174 and NP_435375.1 (E = 3e-76) are annotated as energy yielding FAD-dependent dehydrogenases. YP_003065041 is coproporphyrinogen III oxidase and is orthologous to a pSymA-borne locus NP_435937.1. The protein has two domains; N-terminal Radical-SAM super family and a C-terminal HemN_C superfamily, which obtains electrons from a flavodoxin-like system regenerated by a nicotinamide cofactor-dependent flavodoxin [27]. ‘Ca. Liberibacter asiaticus’ YP_003064696 is a NADPH thioredoxin reductase orthologous to NP_436285.1.

Discussion

The premise for identifying protein products of ‘Ca. Liberibacter asiaticus’ orthologous to those encoded by genes on pSymA was an hypothesis that such genes and their protein products in all likelihood play direct or indirect role(s) in establishing and maintaining an intimate intracellular interaction with eukaryotes. ‘Ca. Liberibacter asiaticus’ has an obligatory requirement for a eukaryotic host, and there are multiple orthologs of these genes in Sinorhizobium meliloti. These factors preclude mutagenesis studies at the present time to test this hypothesis. In particular, we discovered that there are several orthologous genes in the ‘Ca. Liberibacter asiaticus’ genome and on pSymA that encode proteins with vital roles in maintaining intracellular homeostasis for mono- and divalent cations and pH. Genes encoding a Na⁺/H+ antiporter [20], [21] and a cation efflux antiporter protein that secretes excess metal ions Cd⁺⁺, Zn⁺⁺ or Co⁺⁺ in exchange for K⁺ and H⁺ [19], [28] were identified as orthologs shared exclusively by pSymA and ‘Ca. Liberibacter asiaticus,’ i.e., not found on the S. meliloti chromosome. In a previous study we compared the proteins encoded by the circular chromosomes of ‘Ca. Liberibacter asiaticus’ and four other members of the Rhizobiales. In that study the cation efflux antiporter (YP_003064907) was found to be uniquely shared between ‘Ca. Liberibacter asiaticus’ and phytopathogenic Agrobacterium tumefaciens C58 (NP_354015; 3E-84). The Na⁺/H⁺ antiporter (YP_003064775) shared between pSymA and ‘Ca. Liberibacter asiaticus’ is also shared with 10 species or strains of the Bartonellaceae (6E-60–4E-48), but not with the other members of the Rhizobiales studied [26]. This suggests that this protein is used to facilitate an intracellular lifestyle. In addition, another protein encoded by genes shared by pSymA and the ‘Ca. Liberibacter asiaticus’ and S. meliloti chromosomes, is a glutathione-gated potassium efflux protein that exchanges potassium for sodium and protons and thereby modulates cytoplasmic pH [29], [30]. This orthologous protein pair encoded by both pSymA and the ‘Ca. Liberibacter asiaticus’ genome align with an e-value that is 110 orders of magnitude lower than the alignment of the orthologous proteins encoded by pSymA and the S. meliloti chromosome. Thus, the maintenance of intracellular pH and ion homeostasis are likely critical functions of proteins encoded by genes shared uniquely by ‘Ca. Liberibacter asiaticus’ and pSymA (but not the S. meliloti chromosome). Other ‘Ca. Liberibacter asiaticus’ genes with orthologs on pSymA likely encode proteins with either direct or indirect nutritional or energy roles in establishing and maintaining an intimate intracellular interaction with eukaryotic hosts.

We identified 86 ‘Ca. Liberibacter asiaticus’ genes with 182 probable orthologs on pSymA and the S. meliloti chromosome. Most of the orthologous proteins encoded by pSymA and the S. meliloti chromosome produced alignments with substantially more significant E-values than orthologous proteins encoded by ‘Ca. Liberibacter asiaticus’ and pSymA. Individual genes encoded by the reduced genome of ‘Ca. Liberibacter asiaticus’ may have many orthologs or paralogs carried by the pSymA megaplasmid besides additional similar genes on the chromosome of S. meliloti. An example is YP_003064948, a 3-ketoacyl-(acyl-carrier-protein) reductase with 20 similar proteins encoded by pSymA. Thus, numerous physiological and niche adaptations conferred upon S. meliloti by pSymA may not be available to ‘Ca. Liberibacter asiaticus.’ However, in a reduced genome such as that of ‘Ca. Liberibacter asiaticus’, genes that are retained may function with relaxed substrate specificity [31], [32], compensating for the lack of multiple homologs in the ‘Ca. Liberibacter asiaticus’ genome. The multiplicity of pSymA orthologs complicates any mutagenesis strategy to definitively establish their roles in S. meliloti.

Protein products not constitutively expressed may be considered as candidates for being involved with niche specialization or pathogenesis; S. meliloti has conditionally expressed genes that are especially important for nitrogen fixation and nodulation symbiosis. YP_003064695 is a putative regulator of transcription by ‘Ca. Liberibacter asiaticus’, with 14 related proteins in pSymA, many of which are annotated as LysR transcriptional regulatory proteins. Despite considerable conservation both structurally and functionally, LysR-type transcriptional regulators regulate a diverse set of genes, including those involved in virulence, metabolism, quorum sensing and motility [33], [34]. In S. meliloti, LysR proteins function in exquisite control of a sequence of events leading to root colonization, initiation of nodulation and subsequent differentiation of nodules containing S. meliloti [23]. Fatty acid products of the 3-ketoacyl-(acyl-carrier-protein) reductase orthologs are also used to complete the structure of nodulation factors. This may be why the extensive collection of LysR regulatory elements and 3-ketoacyl-(acyl-carrier-protein) reductases encoded on pSymA are not found on the ‘Ca. Liberibacter asiaticus’ chromosome. Thus, ‘Ca. Liberibacter asiaticus’ may have much less capability for finely nuanced control of the expression of genes, consistent with its obligatory intracellular lifestyle. Parasitism of citrus by ‘Ca. Liberibacter asiaticus’ follows direct injection of the pathogen into the host and results in systemic invasion of phloem tissues throughout the host [9], [10], and differentiated nodules are not produced.

Genes with orthologs on both pSymA and the chromosome of S. meliloti are largely specialized for symbiosis and nitrogen metabolism in S. meliloti and include 48 ABC-type transporter genes. The genome of ‘Ca. Liberibacter asiaticus’ encodes only 11 ABC-type transporter proteins that are orthologous to pSymA-encoded proteins, compared with a total of about 40 ABC-type transporters encoded by the chromosome [2]. These transporters likely serve to import sugars, amino acids and precursors and purines and pyrimidines into ‘Ca. Liberibacter asiaticus’ from the host. The genome of ‘Ca. Liberibacter asiaticus’ is known to be deficient in genes used in the biosynthetic pathways of these compounds [2], [12].

ABC-type transporters may also be used to export small molecules by ‘Ca. Liberibacter asiaticus’. YP_003064989 is an ABC-type transporter protein encoded by ‘Ca. Liberibacter asiaticus’ that likely functions to export glucans for osmoprotection. A class of proteins that confer multiple drug resistance, are called ‘RND’ for Resistance, Nodulation and Division [35]. RND-type proteins confer drug resistance based on rapid efflux of drugs from the bacterial cell. YP_003065157, is an ATP-binding ABC-type transporter protein with a yhbG domain, and is orthologous to pSymA NodI, a protein that is required for nodulation of alfalfa by S. meliloti. NodI-like proteins secrete lipids and lipopolysaccarides such as cell wall, outer membrane or Nod factor components needed to stimulate the differentiation of nodules by the host. Very interestingly pSymA encodes six homologs of YP_003065157. Orthologs of ABC-type transporters encoded by ‘Ca. Liberibacter asiaticus’ were identified with the “Transporter Classification Database” (http://www.tcdb.org/). YP_003065330, annotated as an ABC-type transporter with nucleotide binding and ATPase domains was homologous to Q2G2M9 (4.00E-88), annotated as a putative multi-drug export ATP-binding/permease protein, Staphylococcus aureus SAOUHSC_02003. YP_003065330 aligns best with nodI NP_435718.1 (2.00E-021) encoded by pSymA. Thus these proteins at the least share similar structural motifs.

Genes encoding type IV pili may have evolved from structures used for DNA transfer but it is now known that virulence proteins may be secreted by components of a type IV pili [36]. Genes encoding type IV pili are shared between ‘Ca. Liberibacter asiaticus’, S. meliloti, and pSymA. Effectors directly involved with the establishment of ‘Ca. Liberibacter asiaticus’ as an intracellular pathogen living within the phloem cells of citrus, may be transferred from the bacterium to its host by type IV secretion involving pilus assembly proteins. If pili are produced by ‘Ca. Liberibacter asiaticus’, they may also have roles in twitching motility and biofilm formation as in Xylella fastidiosa [37].

Why is the entire S. meliloti chromosomal respiratory complex I gene set duplicated on pSymA? Plants respond to bacterial pathogens by producing a sustained oxidative burst leading to apoptosis. The respiratory complex protein NuoG can also be used by Mycobacterium tuberculosis to pump protons out of the cell to neutralize such superoxide radicals [38]. This may explain the duplication of the genes encoding the respiratory complex on pSymA and provide an additional role for NuoG in the ‘Ca. Liberibacter asiaticus’/citrus interaction. Homeostasis with respect to sodium is also of critical importance to both S. meliloti and ‘Ca. Liberibacter asiaticus’ as discussed above, and in addition to pumping protons out of the cell to create the proton motive force needed for the synthesis of ATP, respiratory complex I of at least some Gram negative bacteria can also transport sodium ions out of the cells [39]. Besides an obvious potential gene dosage effect, redundant copies carried on an extrachromosomal element provide a palette for gene evolution. However in spite of the potential for diversification of these genes afforded to pSymA, substantial diversification is not apparent since the E-values for the orthologs encoded by pSymA, ‘Ca. Liberibacter asiaticus’ and S. meliloti are very similar.

Most ‘Ca. Liberibacter asiaticus’ protein products that align significantly with proteins encoded by pSymA also align significantly with predicted protein products encoded by the S. meliloti chromosome. Thus, although present as single copies for the most part in ‘Ca. Liberibacter asiaticus’, these genes are present in multiple copies per replicon in the free-living microsymbiont. The presence of multiple orthologs in pSymA of ‘Ca. Liberibacter asiaticus’ proteins such as the amino acid transporter YP_003064586, the fatty acid dehydrogenase YP_003064948 and the LysR transcriptional regulator YP_003064695, suggests that their products are of particular importance in host/microbe interactions, and are likely to be examples of a single protein acquiring multiple functions in an organism with a reduced genome [32]. ‘Ca. Liberibacter asiaticus’ very notably also has two or three genes shared with pSymA but not the S. meliloti chromosome. These genes are predicted to produce proteins that generate a proton gradient with ATP-producing potential, maintain sodium and potassium homeostasis, prevent over accumulation of divalent metal cations and maintain intracellular pH. Thus the maintenance of intracellular homeostasis is potentially a vital requirement for successful colonization of citrus and psyllids by ‘Ca. Liberibacter asiaticus’. In an obligate pathogen, cellular vitality and pathogenesis are tied together.

Materials and Methods

The genome of ‘Ca. Liberibacter asiaticus’ was compared with both the circular chromosome and megaplasmids, especially pSymA, of S. meliloti. To identify orthologous proteins, predicted amino acid sequences (‘Ca. Liberibacter asiaticus’ strain psy62, RefSeq NC_012985; Sinorhizobium meliloti strain 1021 RefSeq NC_003047, and pSymA RefSeq NC_003037) were downloaded from NCBI. Using default BLAST parameters, each predicted amino acid sequence from the ORFs identified on pSymA of the S. meliloti 1021 genome was BLASTed against the predicted amino acid sequences of the ORFs on the chromosomes of ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti strain 1021. Perl scripts and Excel spreadsheets were created to identify hits between genomes with low, negative e-values and to extract annotations from Genbank. In addition, amino acid similarity and length of the blast hit was extracted from each top hit from the BLAST output. First, a general analysis was done extracting predicted protein products having BLAST alignment values of e -10 or lower. Similar or homologous proteins were also identified manually where possible to be consistent with the annotations from the authors of each respective genome. That is, annotations of ORFs were extracted from NCBI annotations of the genome of ‘Ca. Liberibacter asiaticus’ and megaplasmid pSymA of Sinorhizobium meliloti strain 1021, respectively. Thus, the matching homolog might not have the best e-value or match with the top hit as many proteins share the same domain structure or amino acid similarity, but are functionally quite different. Similarly, for proteins of interest that were unique to each genome, proteins were sorted for positive e-values, signifying that an orthologous protein was not encoded in a respective genome. Orthologous genes from the ‘Ca. Liberibacter asiaticus chromosome, the S. meliloti chromosome and megaplasmid pSymA were mapped on linear representations of the respective genophores opened at their origins of replication.

Supporting Information

Table S1.

Proteins shared between the Sinorhizobium meliloti plasmid pSymA, and the ‘Ca. Liberibacter asiaticus’ and Sinorhizobium meliloti chromosomes. The protein IDs and annotations used by NCBI and the e-values of pairwise comparisons are provided.

https://doi.org/10.1371/journal.pone.0038725.s001

(XLSX)

Acknowledgments

We acknowledge the technical assistance of Ms. Lauren Conway, Ms. Felicia Davenport and Ms. Larissa Higginbotham.

Author Contributions

Conceived and designed the experiments: LDK JYS JSH. Performed the experiments: LDK JYS JSH. Analyzed the data: LDK JYS JSH. Contributed reagents/materials/analysis tools: JYS. Wrote the paper: LDK JYS JSH.

Reference

1. Kuykendall LD (2005) Order Rhizobiales, Type Family Rhizobiaceae Genus Rhizobium. In: Brenner , Krieg , Staley , Garrity , editors. pp 324–361.
2. Duan Y, Zhou L, Hall DG, Li W, Doddapaneni H, et al. (2009) Complete genome sequence of citrus huanglongbing bacterium, ‘Candidatus Liberibacter asiaticus’ obtained through metagenomics. Molecular Plant-Microbe Interactions 22: 1011–1020.
- View Article
- Google Scholar
3. Kuykendall LD (2006) List of new names and new combinations previously effectively, but not validly, published. Validation List no. 107. International Journal of Systematic and Evolutionary Microbiology 56: 1–6.
- View Article
- Google Scholar
4. Young JM, Kuykendall LD, Martinez-Romero E, Kerr A, Sawada H (2001) A revision of Rhizobium Frank 1889, with an emended description of the genus, and the inclusion of all species of Agrobacterium Conn 1942 and Allorhizobium undicola de Lajudie, et al. 1998 as new combinations: Rhizobium radiobacter, R. rhizogenes, R. rubi, R. undicola and R. vitis. Int J Syst and Evol Microbiol 51: 89–103.
- View Article
- Google Scholar
5. Coletta-Filho HD, Targon MLPN, Takita MA, Negri JDD, Pompeu J, et al. (2004) First report of the causal agent of Huanglongbing (‘Candidatus Liberibacter asiaticus’) in Brazil. Plant Disease 88: 1382.
- View Article
- Google Scholar
6. Gottwald TR (2010) Current epidemiological understanding of citrus huanglongbing. Annual Review of Phytopathology 48: 119–139.
- View Article
- Google Scholar
7. Salibe AA, Cortez RE (1966) Studies on the leaf mottling disease of citrus in the Philippines. FAO Plant Protection Bulletin 14: 141–144.
- View Article
- Google Scholar
8. Galibert F, Finan TM, Long SR, Puhler A, Abola P, et al. (2001) The composite genome of the legume symbiont Sinorhizobium meliloti. Science 293: 668–672.
- View Article
- Google Scholar
9. Tatineni S, Shankar Sagaram U, Gowda S, Robertson CJ, Dawson WO, et al. (2008) In planta distribution of ‘Candidatus Liberibacter asiaticus’ as revealed by polymerase chain reaction (PCR) and real-time PCR. Phytopathology 98: 592–599.
- View Article
- Google Scholar
10. Li W, Levy L, Hartung JS (2009) Quantitative distribution of ‘Candidatus Liberibacter asiaticus’ in citrus plants with citrus huanglongbing. Phytopathology 99: 139–144.
- View Article
- Google Scholar
11. Ammar E-D, Shatters RG Jr, Hall DG (2011) Localization of Candidatus Liberibacter asiaticus, Associated with Citrus Huanglongbing Disease, in its Psyllid Vector using Fluorescence in situ hybridization. J Phytopathology.
- View Article
- Google Scholar
12. Hartung JS, Shao J, Kuykendall LD (2011) Comparison of the ‘Ca. Liberibacter asiaticus’ genome adapted for an intracellular lifestyle with other members of the Rhizobiales. PLoS One 6: e23289.
- View Article
- Google Scholar
13. Barnett MJ, Fisher RF, Jones T, Komp C, Abola AP, et al. (2001) Nucleotide sequence and predicted functions of the entire Sinorhizobium meliloti pSymA megaplasmid. PNAS 98: 9883–9888.
- View Article
- Google Scholar
14. Slater SC, Goldman BS, Goodner B, Setubal JC, Farrand SK, et al. (2009) Genome Sequences of Three Agrobacterium Biovars Help Elucidate the Evolution of Multichromosome Genomes in Bacteria. J Bacteriology 191: 2501–2511.
- View Article
- Google Scholar
15. Rogel MA, Hernandez-Lucas I, Kuykendall LD, Balkwill DL, Martinez-Romero E (2001) Nitrogen-fixing nodules with Ensifer adhaerens harboring Rhizobium tropici symbiotic plasmids. Appl Environ Microbiol 67: 3264–3268.
- View Article
- Google Scholar
16. Jones KM, Kobayashi H, Davies BW, Taga ME, Walker GC (2007) How rhizobial symbionts invade plants: the Sinorhizobium-Medicago model. Nat Rev Microbiol 5: 619–633.
- View Article
- Google Scholar
17. Rosenblueth M, Martínez-Romero E (2006) Bacterial endophytes and their interactions with hosts. Molecular Plant-Microbe Interactions 19: 827–837.
- View Article
- Google Scholar
18. Soto MJ, Sanjuan J, Olivares J (2006) Rhizobia and plant-pathogenic bacteria: common infection weapons. Microbiology 152: 3167–3174.
- View Article
- Google Scholar
19. Goldberg M, Pribylt T, Juhnke S, Nies DH (1999) Energetics and topology of CzcA, a cation/proton antiporter of the resistance-nodulation-cell division protein family. J Biol Chemistry 274: 26065–26070.
- View Article
- Google Scholar
20. Taglicht D, Padan E, Schuldiner S (1991) Overproduction and purification of a functional Na⁺/H⁺ antiporter coded by nhaA (ant) from Escherichia coli. J Biol Chemistry 266: 11289–11294.
- View Article
- Google Scholar
21. Williams KA (2000) Three-dimensional structure of the ion-coupled transport protein NhaA. Nature 403: 112–115.
- View Article
- Google Scholar
22. Goodner B, Hinkle G, Gattung S, Miller N, Blanchard M, et al. (2001) Agrobacterium tumefaciens C58: Genome sequence of theplant pathogen and biotechnology agent. Science 294: 2323–2328.
- View Article
- Google Scholar
23. Swanson JA, Mulligan JT, Long SR (1993) Regulation of SyrM and NodD3 in Rhizobium meliloti. Genetics 134: 435–444.
- View Article
- Google Scholar
24. Mueller K, Gonzalez JE (2011) Complex regulation of symbiotic functions is coordinated by MucR and quorum sensing in Sinorhizobium meliloti. J Bacteriol 193: 485–496.
- View Article
- Google Scholar
25. Tischler AD, Camilli A (2005) Cyclic diguanylate regulates Vibrio chloerae virulence. Infection and Immunity 73.
26. Kuykendall LD, Shao J, Hartung JS (2012) Conservation of Gene Order and Content in the Circular Chromosomes of ‘Candidatus Liberibacter asiaticus’ and Other Rhizobiales. PLos One 7: e34673.
- View Article
- Google Scholar
27. Layer G, Verfurth K, Mahlitz E, Jahn D (2002) Oxygen-independent coproporphyrinogen-III oxidase HemN from Escherichia coli. J Biol Chem 277: 34136–34142.
- View Article
- Google Scholar
28. Guffanti AA, Wei Y, Rood SV, Krulwich TA (2002) An antiport mechanism for a member of the cation diffusion facilitator family: divalent cations efflux in exchange for K⁺ and H⁺. Molecular Microbiology 45: 145–153.
- View Article
- Google Scholar
29. Ness LS, Booth IR (1999) Different foci for the regulation of the activity of the KefB and KefC glutathione-gated K⁺ efflux systems. J Biol Chemistry 274: 9524–9530.
- View Article
- Google Scholar
30. Roosild TP, Castronovo S, Healy J, Miller S, Pliotas C, Rasmussen T, Bartlett W, Conway SJ, Booth IR (2010) Mechanism of ligand-gated potassium efflux in bacterial pathogens. PNAS USA 107: 19784–19789.
- View Article
- Google Scholar
31. Cordwell SJ, Basseal DJ, Pollack JD, Humphery-Smith I (1997) Malate/lactate dehydrogenase in mollicutes: evidence for a multienzyme protein. Gene 197: 113–120.
- View Article
- Google Scholar
32. Pollack JD, Myers MA, Dandekar T, Herrmann R (2002) Suspected Utility of Enzymes with Multiple Activities in the Small Genome Mycoplasma Species: The Replacement of the Missing “Household” Nucleoside Diphosphate Kinase Gene and Activity by Glycolytic Kinases. OMICS 6: 247–258.
- View Article
- Google Scholar
33. Kovacikova G, Skorupski K (1999) A Vibrio cholerae LysR homologue, AphB, cooperates with AphA at the tcpPH promoter to activate expression of the ToxR virulence cascade. J Bacteriology 181: 4250–4256.
- View Article
- Google Scholar
34. Harris SJ, Shih Y-L, Bentley SD, Salmond GPC (1998) The hexA gene of Erwinia carotovora encodes a LysR homologue and regulates motility and the expression of multiple virulence determinants. Molecular Microbiology 28: 705–707.
- View Article
- Google Scholar
35. Blair JMA, Piddock LJV (2009) Structure, function and inhibition of RND efflux pumps in gram-negative bacteria: an update. Current Opinion in Microbiology 12: 512–519.
- View Article
- Google Scholar
36. Rego AT, Chandran V, Waksman G (2010) Two-step and one-step secretion mechanisms in Gram-negative bacteria: contrasting the Type IV secretion system and the chaperone usher pathway of pilus biogenesis. Biochem J 425: 475–488.
- View Article
- Google Scholar
37. Li Y, Hao G, Galvani CD, Meng Y, Fuente Ldl, et al. (2007) Type I and type IV pili of Xylella fastidiosa affect twitching motility, biofilm formation and cell-cell aggregation. Microbiology 153: 719–726.
- View Article
- Google Scholar
38. Velmurugan K, Chen B, Miller JL, Azogue S, Gurses S, et al. (2007) Mycobacterium tuberculosis nuoG is a virulence gene that inhibits apoptosis in infected host cells. PLos Pathogens 3: e110.
- View Article
- Google Scholar
39. Friedrich T, Scheide D (2000) The respiratory complex I of bacteria, archaea and eukarya and its module common with membrane-bound multisubunit hydrogenases. FEBS Letters 479: 1–5.
- View Article
- Google Scholar

[ref1] 1. Kuykendall LD (2005) Order Rhizobiales, Type Family Rhizobiaceae Genus Rhizobium. In: Brenner , Krieg , Staley , Garrity , editors. pp 324–361.

[ref2] 2. Duan Y, Zhou L, Hall DG, Li W, Doddapaneni H, et al. (2009) Complete genome sequence of citrus huanglongbing bacterium, ‘Candidatus Liberibacter asiaticus’ obtained through metagenomics. Molecular Plant-Microbe Interactions 22: 1011–1020.
View Article
Google Scholar

[3] View Article

[4] Google Scholar

[ref3] 3. Kuykendall LD (2006) List of new names and new combinations previously effectively, but not validly, published. Validation List no. 107. International Journal of Systematic and Evolutionary Microbiology 56: 1–6.
View Article
Google Scholar

[6] View Article

[7] Google Scholar

[ref4] 4. Young JM, Kuykendall LD, Martinez-Romero E, Kerr A, Sawada H (2001) A revision of Rhizobium Frank 1889, with an emended description of the genus, and the inclusion of all species of Agrobacterium Conn 1942 and Allorhizobium undicola de Lajudie, et al. 1998 as new combinations: Rhizobium radiobacter, R. rhizogenes, R. rubi, R. undicola and R. vitis. Int J Syst and Evol Microbiol 51: 89–103.
View Article
Google Scholar

[9] View Article

[10] Google Scholar

[ref5] 5. Coletta-Filho HD, Targon MLPN, Takita MA, Negri JDD, Pompeu J, et al. (2004) First report of the causal agent of Huanglongbing (‘Candidatus Liberibacter asiaticus’) in Brazil. Plant Disease 88: 1382.
View Article
Google Scholar

[12] View Article

[13] Google Scholar

[ref6] 6. Gottwald TR (2010) Current epidemiological understanding of citrus huanglongbing. Annual Review of Phytopathology 48: 119–139.
View Article
Google Scholar

[15] View Article

[16] Google Scholar

[ref7] 7. Salibe AA, Cortez RE (1966) Studies on the leaf mottling disease of citrus in the Philippines. FAO Plant Protection Bulletin 14: 141–144.
View Article
Google Scholar

[18] View Article

[19] Google Scholar

[ref8] 8. Galibert F, Finan TM, Long SR, Puhler A, Abola P, et al. (2001) The composite genome of the legume symbiont Sinorhizobium meliloti. Science 293: 668–672.
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Tatineni S, Shankar Sagaram U, Gowda S, Robertson CJ, Dawson WO, et al. (2008) In planta distribution of ‘Candidatus Liberibacter asiaticus’ as revealed by polymerase chain reaction (PCR) and real-time PCR. Phytopathology 98: 592–599.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Li W, Levy L, Hartung JS (2009) Quantitative distribution of ‘Candidatus Liberibacter asiaticus’ in citrus plants with citrus huanglongbing. Phytopathology 99: 139–144.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Ammar E-D, Shatters RG Jr, Hall DG (2011) Localization of Candidatus Liberibacter asiaticus, Associated with Citrus Huanglongbing Disease, in its Psyllid Vector using Fluorescence in situ hybridization. J Phytopathology.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Hartung JS, Shao J, Kuykendall LD (2011) Comparison of the ‘Ca. Liberibacter asiaticus’ genome adapted for an intracellular lifestyle with other members of the Rhizobiales. PLoS One 6: e23289.
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Barnett MJ, Fisher RF, Jones T, Komp C, Abola AP, et al. (2001) Nucleotide sequence and predicted functions of the entire Sinorhizobium meliloti pSymA megaplasmid. PNAS 98: 9883–9888.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Slater SC, Goldman BS, Goodner B, Setubal JC, Farrand SK, et al. (2009) Genome Sequences of Three Agrobacterium Biovars Help Elucidate the Evolution of Multichromosome Genomes in Bacteria. J Bacteriology 191: 2501–2511.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Rogel MA, Hernandez-Lucas I, Kuykendall LD, Balkwill DL, Martinez-Romero E (2001) Nitrogen-fixing nodules with Ensifer adhaerens harboring Rhizobium tropici symbiotic plasmids. Appl Environ Microbiol 67: 3264–3268.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Jones KM, Kobayashi H, Davies BW, Taga ME, Walker GC (2007) How rhizobial symbionts invade plants: the Sinorhizobium-Medicago model. Nat Rev Microbiol 5: 619–633.
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Rosenblueth M, Martínez-Romero E (2006) Bacterial endophytes and their interactions with hosts. Molecular Plant-Microbe Interactions 19: 827–837.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Soto MJ, Sanjuan J, Olivares J (2006) Rhizobia and plant-pathogenic bacteria: common infection weapons. Microbiology 152: 3167–3174.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Goldberg M, Pribylt T, Juhnke S, Nies DH (1999) Energetics and topology of CzcA, a cation/proton antiporter of the resistance-nodulation-cell division protein family. J Biol Chemistry 274: 26065–26070.
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref20] 20. Taglicht D, Padan E, Schuldiner S (1991) Overproduction and purification of a functional Na⁺/H⁺ antiporter coded by nhaA (ant) from Escherichia coli. J Biol Chemistry 266: 11289–11294.
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref21] 21. Williams KA (2000) Three-dimensional structure of the ion-coupled transport protein NhaA. Nature 403: 112–115.
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref22] 22. Goodner B, Hinkle G, Gattung S, Miller N, Blanchard M, et al. (2001) Agrobacterium tumefaciens C58: Genome sequence of theplant pathogen and biotechnology agent. Science 294: 2323–2328.
View Article
Google Scholar

[63] View Article

[64] Google Scholar

[ref23] 23. Swanson JA, Mulligan JT, Long SR (1993) Regulation of SyrM and NodD3 in Rhizobium meliloti. Genetics 134: 435–444.
View Article
Google Scholar

[66] View Article

[67] Google Scholar

[ref24] 24. Mueller K, Gonzalez JE (2011) Complex regulation of symbiotic functions is coordinated by MucR and quorum sensing in Sinorhizobium meliloti. J Bacteriol 193: 485–496.
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref25] 25. Tischler AD, Camilli A (2005) Cyclic diguanylate regulates Vibrio chloerae virulence. Infection and Immunity 73.

[ref26] 26. Kuykendall LD, Shao J, Hartung JS (2012) Conservation of Gene Order and Content in the Circular Chromosomes of ‘Candidatus Liberibacter asiaticus’ and Other Rhizobiales. PLos One 7: e34673.
View Article
Google Scholar

[73] View Article

[74] Google Scholar

[ref27] 27. Layer G, Verfurth K, Mahlitz E, Jahn D (2002) Oxygen-independent coproporphyrinogen-III oxidase HemN from Escherichia coli. J Biol Chem 277: 34136–34142.
View Article
Google Scholar

[76] View Article

[77] Google Scholar

[ref28] 28. Guffanti AA, Wei Y, Rood SV, Krulwich TA (2002) An antiport mechanism for a member of the cation diffusion facilitator family: divalent cations efflux in exchange for K⁺ and H⁺. Molecular Microbiology 45: 145–153.
View Article
Google Scholar

[79] View Article

[80] Google Scholar

[ref29] 29. Ness LS, Booth IR (1999) Different foci for the regulation of the activity of the KefB and KefC glutathione-gated K⁺ efflux systems. J Biol Chemistry 274: 9524–9530.
View Article
Google Scholar

[82] View Article

[83] Google Scholar

[ref30] 30. Roosild TP, Castronovo S, Healy J, Miller S, Pliotas C, Rasmussen T, Bartlett W, Conway SJ, Booth IR (2010) Mechanism of ligand-gated potassium efflux in bacterial pathogens. PNAS USA 107: 19784–19789.
View Article
Google Scholar

[85] View Article

[86] Google Scholar

[ref31] 31. Cordwell SJ, Basseal DJ, Pollack JD, Humphery-Smith I (1997) Malate/lactate dehydrogenase in mollicutes: evidence for a multienzyme protein. Gene 197: 113–120.
View Article
Google Scholar

[88] View Article

[89] Google Scholar

[ref32] 32. Pollack JD, Myers MA, Dandekar T, Herrmann R (2002) Suspected Utility of Enzymes with Multiple Activities in the Small Genome Mycoplasma Species: The Replacement of the Missing “Household” Nucleoside Diphosphate Kinase Gene and Activity by Glycolytic Kinases. OMICS 6: 247–258.
View Article
Google Scholar

[91] View Article

[92] Google Scholar

[ref33] 33. Kovacikova G, Skorupski K (1999) A Vibrio cholerae LysR homologue, AphB, cooperates with AphA at the tcpPH promoter to activate expression of the ToxR virulence cascade. J Bacteriology 181: 4250–4256.
View Article
Google Scholar

[94] View Article

[95] Google Scholar

[ref34] 34. Harris SJ, Shih Y-L, Bentley SD, Salmond GPC (1998) The hexA gene of Erwinia carotovora encodes a LysR homologue and regulates motility and the expression of multiple virulence determinants. Molecular Microbiology 28: 705–707.
View Article
Google Scholar

[97] View Article

[98] Google Scholar

[ref35] 35. Blair JMA, Piddock LJV (2009) Structure, function and inhibition of RND efflux pumps in gram-negative bacteria: an update. Current Opinion in Microbiology 12: 512–519.
View Article
Google Scholar

[100] View Article

[101] Google Scholar

[ref36] 36. Rego AT, Chandran V, Waksman G (2010) Two-step and one-step secretion mechanisms in Gram-negative bacteria: contrasting the Type IV secretion system and the chaperone usher pathway of pilus biogenesis. Biochem J 425: 475–488.
View Article
Google Scholar

[103] View Article

[104] Google Scholar

[ref37] 37. Li Y, Hao G, Galvani CD, Meng Y, Fuente Ldl, et al. (2007) Type I and type IV pili of Xylella fastidiosa affect twitching motility, biofilm formation and cell-cell aggregation. Microbiology 153: 719–726.
View Article
Google Scholar

[106] View Article

[107] Google Scholar

[ref38] 38. Velmurugan K, Chen B, Miller JL, Azogue S, Gurses S, et al. (2007) Mycobacterium tuberculosis nuoG is a virulence gene that inhibits apoptosis in infected host cells. PLos Pathogens 3: e110.
View Article
Google Scholar

[109] View Article

[110] Google Scholar

[ref39] 39. Friedrich T, Scheide D (2000) The respiratory complex I of bacteria, archaea and eukarya and its module common with membrane-bound multisubunit hydrogenases. FEBS Letters 479: 1–5.
View Article
Google Scholar

[112] View Article

[113] Google Scholar

Figures

Abstract

Introduction

Results

Maintenance of Homeostasis

Signal Transduction

ABC-cassette Type Amino Acid Transporters

Synthesis of Metabolic Cofactors and Amino Acids

Export of Bioactive Molecules

Chaperonins

Regulation of Transcription and Translation

Cell Surface

Electron Transfer

Discussion

Materials and Methods

Supporting Information

Table S1.

Acknowledgments

Author Contributions

Reference