Comparative Genomics Analysis of Plasmid pPV989-94 from a Clinical Isolate of <i>Pantoea vagans</i> PV989

Xu, Lei; Yin, Min; Zhu, Tingyuan; Liu, Yabo; Ying, Yuanyuan; Lu, Junwan; Lin, Chaoqing; Ying, Jianchao; Xu, Teng; Ni, Liyan; Bao, Qiyu; Lu, Shunfei

doi:https://doi.org/10.1155/2018/1242819

International Journal of Genomics

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Abstract Introduction Results and Discussion Conclusion Materials and Methods Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2018 | Article ID 1242819 | https://doi.org/10.1155/2018/1242819

Comparative Genomics Analysis of Plasmid pPV989-94 from a Clinical Isolate of Pantoea vagans PV989

Lei Xu,¹Min Yin,¹Tingyuan Zhu,¹Yabo Liu,¹Yuanyuan Ying,¹Junwan Lu,²Chaoqing Lin,³Jianchao Ying,¹Teng Xu,¹Liyan Ni,³Qiyu Bao,¹and Shunfei Lu²

Academic Editor: Graziano Pesole

Received03 Nov 2017

Accepted25 Mar 2018

Published10 May 2018

Abstract

Pantoea vagans, a gram-negative bacterium from the genus Pantoea and family Enterobacteriaceae, is present in various natural environments and considered to be plant endophytes. We isolated the Pantoea vagans PV989 strain from the clinic and sequenced its whole genome. Besides a chromosome DNA molecule, it also harboured three large plasmids. A comparative genomics analysis was performed for the smallest plasmid, pPV989-94. It can be divided into four regions, including three conservative regions related to replication (R1), transfer conjugation (R2), and transfer leading (R3), and one variable region (R4). Further analysis showed that pPV989-94 is most similar to plasmids LA637P2 and pEA68 of Erwinia amylovora strains isolated from fruit trees. These three plasmids share three conservative regions (R1, R2, and R3). Interestingly, a fragment (R4) in R4, mediated by phage integrase and phage integrase family site-specific recombinase and encoding 9 genes related to glycometabolism, resistance, and DNA repair, was unique in pPV989-94. Homologues of R4 were found in other plasmids or chromosomes, suggesting that horizontal gene transfer (HGT) occurred among different bacteria of various species or genera. The acquired functional genes may play important roles in the adaptation of bacteria to different hosts or environmental conditions.

1. Introduction

The genus Pantoea includes approximately 20 phenotypically similar yellow-pigmented and rod-shaped species in plants, humans, and the natural environment [1]. It is closely related to the Erwinia and Tatumella genera, which are grouped as sisters [2]. For classification and identification of Pantoea species, the four housekeeping genes, gyrB, rpoB, atpD, and infB, are reliable genetic markers [3]. Pantoea vagans belongs to the genus Pantoea and is separated from Pantoea agglomerans based on borderline DNA-DNA relatedness, 16S rRNA, multilocus sequence analysis (MLSA), and several biochemical characteristics [3]. A portion of Pantoea vagans strains have been isolated and screened from natural resources such as a Malaysian waterfall and French soil and sea water. In addition, the bacterium 848_PVAG has been isolated from a patient in the intensive care unit of a tertiary care hospital [4], while the majority of strains are epiphytes attached to a broad range of plants. The typical strain of Pantoea vagans is strain C9-1 from Michigan apples. It has been registered as BlightBan C9-1 (NuFarm Americas, Burr Ridge, IL) and works as causal biocontrol for fire blight disease in pome fruit caused by the enterobacterium Erwinia amylovora [5, 6].

Canonically horizontal gene transfer (HGT) is dependent on mobile genetic elements (MGEs) that include plasmids, transposons, bacteriophages, genomic islands, and integrative conjugative elements (ICEs). Some MGEs such as phage integrases may be inserted in strategic locations and serve to mobilize certain genes [7]. Phage integrases are classified into two evolutionarily and mechanistically different families of site-specific recombinases, the tyrosine recombinases and the serine recombinases, which are differentiated by the amino acid residue that forms a covalent protein-DNA linkage in the reaction intermediate [8]. The bacterial attachment site attB and phage attachment site attP are recognized by phage integrases during integration and the excision reaction, and the mobile genetic element emerges as integrated prophages flanked by two hybrid sites, attL and attR [9]. The site-specificity and efficiency of phage integrases are essential for the HGT of genetic information and the control of gene expression.

To date, 22 species from the genus Pantoea have been sequenced, of which 7 Pantoea species have complete genomes. Genome sequencing showed that two strains of Pantoea agglomerans and one strain of Pantoea vagans harbored three plasmids, whereas one strain of Pantoea rwandensis was free of plasmids. In this study, we isolated a clinical strain designated Pantoea vagans PV989. We sequenced the complete genome of the strain and analyzed the structural components of the plasmid pPV989-94. In addition, we also performed extensive comparative analysis among the plasmid pPV989-94 and its close relatives to explore their origin, evolution, and distribution.

2. Results and Discussion

2.1. Identification and Characterization of Pantoea vagans PV989

Pantoea vagans PV989 was isolated from the blood of a high-risk newborn infant girl with bacteremia at the Central Hospital of Lishui City, China. We used single molecule real time (SMRT) technology to determine the complete genome sequence of Pantoea vagans PV989. The whole genome comparative analysis combined with 16S ribosomal RNA gene homology analysis showed that the most closely related species were two Pantoea vagans strains (P. vagans C9-1, CP002206 and P. vagans LJ15, KM40861), and the most similar genome belongs to Pantoea vagans C9-1. It has been reported that the multilocus sequence analysis (MLSA) of housekeeping genes is a useful approach for rapid classification and identification of Pantoea strains with high phenotypic similarity and is more reliable than 16S rRNA sequences [10]. Four housekeeping genes, namely, gyrB, rpoB, atpD, and infB, from the Pantoea vagans PV989 genome were further evaluated and showed optimum matching to those in P. vagans C9-1 (identity 100%, 99%, 99%, and 99%, resp.). We finally grouped the strain into the species Pantoea vagans and named it Pantoea vagans PV989.

2.2. General Features of the Genome of Pantoea vagans PV989

The genome of Pantoea vagans PV989 consists of a chromosome and three large plasmids. The chromosome is 4,071,006 bp in length and encodes 3648 ORFs. The largest plasmid, named pPV989-508, is 507,680 bp in length and harbors 492 ORFs. The second largest plasmid, pPV989-167, is 166,637 bp in size and carries 152 ORFs, and the smallest plasmid, pPV989-94, is 93,831 bp in length and has 101 ORFs (Table 1). Based on the sequence structures and the functions of its ORFs, plasmid pPV989-94 can be roughly divided into four parts (Figure 1). The first region (R1, 7 ORFs from ORF41 to ORF48) relates to plasmid replication and consists of repA, copB, yedk, and nuc and 3 unknown ORFs. The second region (R2, 42 ORFs from ORF49 to ORF113), next to R1, is mainly composed of three operons (3 trb, 18 tra, and 11 pil genes) related to conjugal transfer, the genes excA, ymoA, ppg1, and nuc, lipoprotein, and five ORFs whose functions are unknown. The third region (R3, 38 ORFs, from ORF114 to ORF19) is defined as the transfer leading region and includes ORFs for the mobilization system (mobA, mobB, and mobC) and plasmid SOS inhibition (psiA, psiB). The fourth region (R4, 14 ORFs from ORF20 to ORF40) mainly contains a mobile genetic element. It includes a fragment (named R4) inserted into the umuC gene, which is characterized by a phage integrase (ORF38) and a phage integrase family site-specific recombinase (ORF37) and encodes 9 genes from different origins with various functions.

Figure 1

The circular map of plasmid pPV989-94. (1) The circle on the outside shows positions in bp. (2) The four regions (replication, R1; transfer conjugation, R2; transfer leading, R3; and the variable region, R4) in the circle are in blue, green, purple, and pink, respectively. Arrows display ORFs on the lagging strand (outwards) or leading strand (inwards), with ORFs involved in replication in blue, conjugation in light yellow, pilus formation in light green, transfer leading in light purple, MGEs in pink, and others in blue-green. (3) The G + C content with values more than 50% are directed outward; otherwise, inward; (4) GC skew (G − C/G + C) with the positive values directed outward are in green, and the negative values directed inward are in purple.

2.3. Structural Analysis of Plasmid pPV989-94

To explore the origin of the pPV989-94 plasmid, two plasmids with the highest sequence similarities with pPV989-94 were identified. Both are plasmids from Erwinia amylovora strains (LA637P2, HG793099.1, a 78 kb plasmid from Erwinia amylovora LA637 and pEA68, and HG813238.1, a 68 kb plasmid from Erwinia amylovora 692). Comparative genomics analysis showed that they had 46.8 kb in common, including the R1, R2, and R3 regions in pPV989-94 (Figure 2). They all harbor homologous genes including 3 trbs and 18 tras encoding a type IV F conjugative transfer system, 11 pils encoding a type IV pilus system, mobABC encoding a mobilization protein, and umuCD for DNA error-prone repair. Plasmid pPV989-94 is approximately 12 kb larger than LA637P2, which mainly consists of the R4 region, and 22 kb larger than pEA68, which covers part of the R3 and R4 regions. Alignments of the three plasmids reveal synteny over long stretches of the plasmid genome. Despite the high similarity of the backbone of the plasmids, the origins of the host bacteria are totally different. The pPV989-94 plasmid carried by the strain P. vagans PV989 is a clinical isolate from southern China, while pEA68 and LA637P2 harbored by Erwinia amylovora strains are isolated from two continents, the former from Sorbus in Poland with fire blight symptoms and the latter from apple orchards in Mexico [11, 12].

In addition, each of the plasmids possesses its own variable regions. A toxin-antitoxin system (vagCD), an atypical plasmid stabilization system (stbAB) and several transposases (tnps) are present in pEA68. An IncFIIa-type repA system in pEA68 shows low identity with IncFII repA in LA637P2 or pPV989-94. IncF plasmids are subject to the host restriction of the Enterobacteriaceae family and possess strong intracellular adaptation [13]. Genes encoding various small proteins and hypothetical proteins are divergent in all three plasmids. Moreover, the phage integrase-mediated fragment (R4) inserted into umuC is exclusively in pPV989-94. The integration confers a level of specialization and contributes to interstrain genetic variability and genome diversity.

2.4. Comparative Genomics Analysis of the Mobile Genetic Element in R4

The variable regions make the plasmids different in size and genomic structure. Fragment R4 in pPV989-94 encodes 11 genes that span from the phage integrase (ORF38) to PQQ-dependent catabolism-associated beta-propeller protein (HET-E-1, ORF22) in R4 and is 10.7 kb in length (Figure 2). All of the homologous genes of fragment R4 were found in eight bacterial chromosomes or plasmids, including the chromosomes of Pantoea vagans C9-1 (CP002206.1), Pantoea ananatis PA13 (CP003085.1), Pantoea ananatis LMG 5342 (HE617160.1), and Pantoea ananatis AJ13355 (AP012032.2) as well as plasmid unnamed1 from Pantoea agglomerans FDAARGOS_160 (CP014126.1), plasmid pEB102 from Erwinia billingiae Eb661 (FP236826.1), plasmid pEM65 from Erwinia amylovora (JQ292796.1), and plasmid EaACW_pEI70 from Erwinia amylovora CW56400 (CP002951.1) (Table 2 and Figure 3(a)). These bacteria were mainly isolated from plants such as rice or clinical patient wounds polluted by plant materials from several countries (Table 2).

(a)

(b)

Interestingly, among eight R4 fragments, the sequences in the plasmids pEM65 (E. amylovora), EaACW_pEI70 (E. amylovora), pEB102 (E. billingiae), and unnamed1 (P. agglomerans) are almost identical, with at least 99% identity to each other at the nucleic acid (NA) level. Similarly, the sequence from the P. vagans C9-1 chromosome also has 99% NA identity with the sequences from those four plasmids. For the chromosome sequences of R4 homologous regions from P. ananatis PA13, P. ananatis LMG 5342, and P. ananatis AJ13355, the NA identities are more than 98%. Surprisingly, the R4 sequence in plasmid pPV989-94 was closer to those on the P. ananatis LMG 5342 and P. ananatis PA13 chromosomes than it was to that on the P. ananatis AJ13355 chromosome and was least similar to those on the P. vagans C9-1 chromosome and the four plasmids (pEM65, EaACW_pEI70, pEB102, and unnamed1). These results suggest that the R4 homologous fragments are distributed in the Pantoea and Erwinia genera and that the HGT of this fragment occurred between chromosomes and plasmids in different species or genera.

Unexpectedly, homeotic partial R4 fragments were also found (Figure 3(b)). In the chromosome of AJ13355, besides one entire R4 homologous fragment, two copies of partial R4 fragments of three genes (HET-E-1, mae1, and ung) were also present in the chromosome. Structural analysis showed that both copies were mediated by IS110 family transposases (tnpAs) with 14 bp perfect inverted repeats (IR1) lying upstream of tnpAs and downstream of ungs, which are typical transposons. Moreover, each gene of the two transposons shows a high degree of similarity with that in the whole R4 fragments of AJ13355 and pPV989-94. Furthermore, a partial R4 fragment encoding the genes crcB, gpmA, eno, uspA, and ppaC mediated by an IS911 family transposase appears in Plautia stali symbiont DNA (AP012551.1), which is the symbiotic bacterium of the stink bug Plautia stali. There are two 11 bp perfect inverted repeats flanking tnpA and ppaC (IR2). However, other partial fragments (CP019706.1, CP010326.1, and CP009871.1) only containing phage integrases and recombinases have also been identified, indicating that the entire R4 has been further fragmented by MGEs to spread among strains of the different species or genera.

2.5. Functional Analysis of the Genes in the R4 Fragment

There were 9 ORFs predicted in the R4 fragment other than the phage integrase and the site-specific recombinase genes. The functional annotations revealed that they were related to glycometabolism (gloA, gpmA, eno, ppaC, mae1, and HET-E-1), resistance (crcB, uspA) and DNA repair (ung).

2.5.1. Glycometabolism-Associated Genes and Their Functions

gloA encodes glyoxalase I, an (R)-S-lactoylglutathione methylglyoxal lyase (isomerizing) activated by Zn(II) or Ni(II) ions, and is 411 bp (136 amino acids) in length. It has been identified in bacteria, fungi, protists, plants, and animals but not in the protozoans Entamoeba histolytica, Giardia lamblia, and Trypanosoma brucei [14]. Catalysis of the glyoxalase I is the first step of the typical glyoxalase pathway wherein glyoxalase I catalyzes toxic methylglyoxal (MG) and generates innocuous S-D-lactoylglutathione, which then enters the mitochondria from the cytosol with glutathione (GSH) [15]. MG is a noxious electrophilic product of dihydroxyacetone phosphate (DHAP), which is one of the two products of the breakdown of fructose 1,6-bisphosphate in the glycolysis metabolic pathway. The GSH-dependent glyoxalase system suppresses α-oxoaldehyde-mediated glycation, helps maintain low intracellular reactive MG concentrations, and protects cells from irreversible damage in glycation [16]. It plays an irreplaceable role in antiglycation defense and protects bacteria from poisonous MG for survival.

gpmA and eno encode phosphoglycerate mutase and enolase, respectively, which have been known to participate in substrate level phosphorylation as glycolytic enzymes in carbon metabolism. The sequence of enolase is highly conserved from archaebacteria to mammals [17]. It has been found on the cell surfaces or in the culture supernatant of bacteria [18]. The gpmA and eno genes in the E. amylovora ACW56400 plasmid pEI70 have been reported to increase growth rates in minimal medium with sucrose, thus improving competence and increasing pathogen aggressiveness [19].

ppaC encodes inorganic pyrophosphatase (PPase) with the DHHA2 domain (IPR004097) and pyrophosphatase activity (GO: 0016462). It is well known that PPase can irreversibly hydrolyze one molecule of inorganic pyrophosphate (PPi) that comes from the processes of photophosphorylation, oxidative phosphorylation, and glycolysis into two inorganic phosphates (Pi). It is a highly exergonic reaction driving biosynthetic reactions, such as NA synthesis and lipid synthesis and degradation.

Enolase and PPase are highly sensitive to fluoride, and most organisms have equipment such as phosphoryl-transfer enzymes either to sequester or to export fluoride [20, 21]. Fluoride ions present at millimolar concentrations in bacterial culture media inhibit cell growth. The crcB-encoded CrcB protein is a “double-barreled” anion membrane channel and functions as a fluoride ion transporter that selectively exports many toxic fluoride ions [22]. The expression of the CrcB protein is controlled by fluoride-sensing messenger RNAs named fluoride riboswitches. The CrcB protein augments the activity of CspE to increase camphor resistance beyond the action of crcB alone, which protects the chromosome from decondensation by camphor [23]. It seems that CrcB significantly reduces fluoride concentration and chromosome decondensation to alleviate toxicity and hazards in the environment.

2.5.2. Resistance-Associated Genes and Their Functions

Universal stress protein A (UspA) expressed monocistronically in living systems is an autophosphorylating serine and threonine phosphoprotein and acts as a phosphate donor when it utilizes GTP or ATP [24]. Except for ppGpp, the uspA promoter is affected by the activities of the glycolytic/gluconeogenic pathways and is induced before the carbon source is depleted from the medium to generate adaptation to energy deficiency. The superinduction of uspA is elicited by the accumulation of fructose-6-phosphate (F-6-P), whereas a decrease in F-6-P has the opposite effect [25]. Furthermore, UspA is important in the defense against stress conditions, such as low oxygen, extreme temperatures, pH changes, nutrient starvation, oxidative stress, and DNA damaging agents, for avoiding cellular growth arrest [26].

The C4-dicarboxylate transporter is encoded by mae1, which contains the tellurite resistance protein TehA/malic acid transport protein domain (IPR011552) of the voltage-dependent anion channel family. TehA was identified as a transmembrane protein from Escherichia coli that was resistant to tellurite, tetraphenylarsonium Cl, ethidium bromide, crystal violet, and proflavin [27], and the malic acid transport phenotype increases L-malic acid uptake by competing against stearic dicarboxylic acids in Schizosaccharomyces pombe [28].

HET-E-1 was associated with the PQQ-dependent catabolism-associated beta-propeller protein (HET-E-1) containing alterable repeats of the YVTN family beta-propeller. The members of this family are often involved in pyrroloquinoline quinone-dependent (PQQ-dependent) alcohol catabolism. The functions of PQQ alcohol dehydrogenase are redundant for adaptation to changing environments. Thus, the PQQ-dependent oxidation system plays a significant role in efficient growth with various volatile alcohols [29].

2.5.3. DNA Repair-Associated Genes and Their Functions

Uracil-DNA glycosylase (UNG) has the isogenous domain uracil-DNA glycosylase family 4 (IPR005122 and IPR005273), which hydrolyzes the N-glycosidic bond of deoxyuridine in DNA to initiate DNA repair after lesioning in viruses, bacteria, archaea, yeast, mice, and humans. The structure of UNG is a specific uracil-binding pocket located in a DNA-binding groove that binds to DNA with appreciable affinity [30]. UNG is a monofunctional glycosylase and removes the uracil that results from spontaneous deamination of cytosine or the incorporation of dUMP specifically during DNA synthesis [31]. UNGs are classified into six families by their substrate specificity, and the IV UNG family interacts with one of the heterotrimeric proliferating cell nuclear antigen (PCNA) subunits, PCNA3, in Sulfolobus solfataricus [31]. UNGs were successively discovered in the hyperthermophilic bacterium Termotoga maritima as well as in archaea and only acts on double-stranded DNA containing U : G mispairs and single-stranded DNA containing U : A base pairs or U bases [32]. The base excision function of UNG maintains genetic stability and genomic integrity, particularly after UV radiation or exposure to environmental mutagens.

3. Conclusion

Pantoea vagans PV989 is a clinical isolate, and it harbors three large plasmids. Comparative genomics analysis demonstrated that two plasmids, LA637P2 and pEA68, from Erwinia amylovora strains isolated from fruit trees in Europe and North America, respectively, showed the highest sequence similarity with the smallest plasmid pPV989-94 in P. vagans PV989. The three plasmids shared the conservative backbone sequences consisting of the genes relating to replication, the type-IV F conjugative transfer system, and transfer leading. However, plasmid pPV989-94 contained a variable region that was a mobile genetic element mediated by the phage integrase and site-specific recombinase, and the region carried genes related to glycometabolism, resistance, and DNA repair. The acquired functional foreign genes guarantee the bacterium’s ability to adapt to environments, including the human body, and certainly pose a threat to human health.

4. Materials and Methods

4.1. Bacterial Strain and Plasmids

The host strain P. vagans PV989 that contains three plasmids was isolated from the Central Hospital of Lishui City, China. Species identification was conducted using a bioMérieux VITEK® 2 Compact instrument. Further verification was performed using homologous comparisons of seven 16S rRNA gene sequences, the whole genome sequence, and housekeeping genes with bacteria of the same genera in the NCBI database through blastn and blastp [33]. Seven 16S rRNA sequences were found by the online tool RNAmmer (http://www.cbs.dtu.dk/services/RNAmmer/) [34]. The plasmid pPV989-94 is the smallest of the three plasmids of P. vagans PV989.

4.2. Sequencing, Assembly, and Bioinformatics Analysis

The whole genome DNA of P. vagans PV989-9 was extracted by the alkaline lysis method [35]. The draft genome sequence of P. vagans PV989 was obtained using a PacBio RS instrument and was then assembled by Canu v1.2 [36]. Two FASTQ sequence files were generated using the Illumina HiSeq 2500 platform to control the assembly quality and to correct possible misidentified bases. Single nucleotide polymorphism (SNP) calling was performed by bwa0.7.13, samtools1.3, and GenomeAnalysisTK2.3.9 [37, 38]. Potential open reading frames (ORFs) were predicted using Glimmer3.02 with default parameters [39]. The annotations of ORFs were determined by using tblastx compared with the NCBI nonredundant protein database [33]. The comparisons of nucleotide sequences and amino acid sequences were performed by blastn and blastp, respectively [33]. The map of the plasmid with GC content and GC skew was drawn with the online CGView Server (http://stothard.afns.ualberta.ca/cgview_server/) and local GView 1.7 with visual interface [40]. The plasmid and chromosome genome sequences used in this study were downloaded from the NCBI database (http://www.ncbi.nlm.nih.gov). Family classification and domain prediction of the MGEs were verified by comparison with the InterPro database [41]. Other bioinformatics tools were written using Perl and BioPerl (http://www.perl.org/).

4.3. Accession Number

The complete nucleotide sequences of the chromosome and plasmids have been submitted to a NCBI database and the accession numbers of the chromosome, pPV989-508, pPV989-167, and pPV989-94 are CP028349.1, CP028350.1, CP028351.1, and CP028352.1, respectively.

Conflicts of Interest

The authors declare that they have no conflict of interest.

Acknowledgments

This work was supported by the National Natural Science Foundation of China (81501808, 81501780, and 81401702), the Science and Technology Foundation of Zhejiang Province, China (2015C33196), and the Natural Science Foundation of Zhejiang Province, China (LQ17H190001).

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Copyright © 2018 Lei Xu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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