Abstract
Vibrio anguillarum 531A, isolated from a diseased fish in the Atlantic Ocean, is a mixture composed of about 95 and 5% of highly pigmented cells (strain 531Ad) and cells with normal levels of pigmentation (strain 531Ac), respectively. Analysis of the V. anguillarum 531Ad DNA region encompassing genes involved in the tyrosine metabolism showed a 410-bp duplication within the hmgA gene that results in a frameshift and early termination of translation of the homogentisate 1,2-dioxygenase. We hypothesized that this mutation results in accumulation of homogentisate that is oxidized and polymerized to produce pyomelanin. Introduction in E. coli of recombinant clones carrying the V. anguillarum hppD (4-hydroxyphenylpyruvate-dioxygenase), and a mutated hmgA produced brown colored colonies. Complementation with a recombinant clone harboring hmgA restored the original color to the colonies confirming that in the absence of homogentisate 1,2-dioxygenase the intermediary in tyrosine catabolism homogentisate accumulates and undergoes nonenzymatic oxidation and polymerization resulting in high amounts of the brown pigment. Whole-genome sequence analysis showed that V. anguillarum 531 Ac and 531Ad differ in the hmgA gene mutation and 23 mutations, most of which locate to intergenic regions and insertion sequences.
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Introduction
Vibrio anguillarum is the causative agent of vibriosis, a devastating disease characterized by terminal hemorrhagic septicemia that affects numerous fresh and salt-water fish species1,2. Among the hosts that V. anguillarum infects are species of enormous economic importance such as salmon, turbot, rainbow trout, sea bass, sea bream, cod, eel, and ayu1. Although never recognized as a human pathogen, one case of fatal infection in an immunocompromised patient has been documented3. Studies on the molecular mechanisms of pathogenicity in this bacterium led to the identification of various virulence factors1,4,5 such as motility6,7,8,9, adhesion9, the lipopolysaccharide1, outer membrane proteins1, DNase, protease, and hemolysin activities4,10,11,12,13, as well as efficient iron uptake systems14,15,16,17. V. anguillarum also possesses quorum sensing systems involved in regulation of expression of virulence factors18,19. The pJM1-type plasmid-mediated anguibactin iron-uptake system is one of the best characterized virulence factors present in numerous serotype O1 V. anguillarum strains14,15,20,21. It consists of the low-molecular-weight siderophore anguibactin and a receptor complex that facilitates transport of ferric-anguibactin across the membranes22,23. The vast majority of the pJM1-type plasmids include genes that code for enzymes that participate in the synthesis of anguibactin, outer membrane and periplasmic components of the ferric-anguibactin receptor complex, and regulatory elements24,25,26,27. Studies on V. anguillarum 531A, a strain isolated from a diseased fish on the Atlantic coast, showed that it carries a pJM1-like plasmid, pJHC1, and can grow in the presence of higher concentrations of iron chelators when compared to other strains like the well-studied strain 77528,29. Another unique and intriguing property of V. anguillarum 531A is that it secretes very high amounts of a brown pigment. We aimed to understand the genetics and biochemistry of this property. In this work, we report that V.anguillarum 531A is a mix of two variants, one of them producing dark brown colonies due to production of an ochronotic-like pigment that is correlated with a DNA duplication that disrupts the hmgA gene. The lack of a functional homogentisate 1,2-dioxygenase leads to accumulation of homogentisate in the tyrosine degradation pathway. Numerous reports described bacteria that produce the ochronotic pigment pyomelanin when homogentisate accumulates and undergoes oxidation and polymerization30,31,32,33,34,35,36,37,38.
Results
V. anguillarum 531A, a strain isolated from diseased Oncorhynchus kisutch in the Atlantic Ocean, carries the pJM1-type plasmid pJHC1 and produces higher levels of anguibactin than the strain 77528,29,39. While performing assays to characterize V. anguillarum 531A, we noticed that, unlike 775 and all other V. anguillarum strains in our collection, it produces a dark brown pigment (Fig. 1A). Another observation was that upon plating, the isolate produced two kinds of colonies, about 95% of them were dark and the rest with the usual clear color (Fig. 1B). A representative of each of the colonies was isolated, and the new strains were named 531Ad (dark) and 531Ac (clear). These strains conserved their pigmentation characteristics when they were subsequently cultured in TSBS or TSAS (Fig. 1A).
To determine if V. anguillarum 531Ac and 531Ad were two independent strains or one derives from the other we did whole-genome sequencing. The draft sequences of strains 531AC and 531AD had a total of 2,039,599 and 2.204.992 high-quality paired-end reads, respectively; 99.9% of the reads were mapped, resulting in mean nucleotide coverage of 30X for both genomes. The corrected reads showed an average length of 128 (531Ac) and 123 (531Ad) bp and there were 119 (531Ac) and 124 (531Ad) contigs larger than 500 bp. The draft genomes have an N50 contig size of 96,636 (531Ac) and 100,331 (531Ad) bp with a maximum contig length of 347,928 (531Ac) and 321,926 (531Ad). The GC content (%) of the genomes was determined as 44.3%, a value consistent with previous measurements using other V. anguillarum strains40. The genomic differences between both strains were evaluated by performing genome comparisons. Two-way average nucleotide identity (ANI) calculation and the tetra nucleotide correlation analysis among both isolates showed a 99,9% value and a score 1.0, respectively. Also, tetra nucleotide correlation against all the database of JSpeciesWS, showed the highest score against V. anguillarum 775. These results strongly suggest that V. anguillarum 531Ac and 531Ad could be considered to be the essentially same strain with a small number of nucleotide differences. To validate these results, a core-genome phylogeny of V. anguillarum 531Ac and 531Ad and V. anguillarum genomes from GenBank. The core-genome contains 1538 genes and the pan-genome contains 13,038 genes. The phylogenetic relation among the V. anguillarum 531Ac and 531Ad genomes as determined by core-genome phylogeny analysis showed that the pairwise distance is 0.000344655 substitution per 100 bp, which indicates the presence of a few SNPs between both isolates (Supplementary Fig. S1 and Table S1). Mutation prediction among both isolates showed that besides the duplication of of the hmgA gene described below, there are 23 mutations among the V. anguillarum 531 Ac and 531Ad genomes. While most mutations were found within intergenic regions and insertion sequence (ISVa5 and ISVa2) (Supplementary Table S2), one of them occurred within the TyrP (tyrosine-specific transport protein) coding sequence. This mutation resulted in a Q349P amino acid change (Supplementary Table S2) within the transmembrane domain. However, prediction of transmembrane helices using the TMHMM software showed that the mutation does not induce significant structural differences. As a consequence, it is most probable that the one amino acid difference does not affect tyrosine uptake. Future research will permit to confirm this observation. A final confirmation of the identity between V. anguillarum 531Ac and 531Ad was carried out by restriction analysis of their plasmid content. V. anguillarum strains usually harbor pJM1-type plasmids whose DNA sequences slightly differ14,28,41,42. Therefore, identical restriction digestion patterns of both pJM1-type plasmids would be a strong indication that one of the strains derives from the other. The plasmid originally isolated from V. anguillarum 531A was called pJHC1, then the plasmids isolated from the variants 531Ac and 531Ad were called pJHC1c and pJHC1d. Figure 2A shows a comparison of the products of BamHI restriction digestion of pJHC1c and pJHC1d, as well as the prototype plasmid pJM1. This figure shows that both strains, 531Ac and 531Ad, shared the same signature pJM1-type plasmid, the BamHI fragments 4 and 7 showed identical molecular size in pJHC1c and pJHC1d, and were larger than those from pJM1. The correspondence between the fragments was confirmed by PCR using as primers oligonucleotides at the edges of the BamHI fragments 4 and 7 based on the pJM1 nucleotide sequence (Fig. 2B). These results agree with the genomic analyses and indicates that both variants have a common origin.
Production of the ochronotic type pigment pyomelanin is caused by the accumulation of homogentisate formed by the action of 4-hydroxyphenylpyruvate dioxygenase, coded for by the hppD gene, on 4-hydroxyphenylpyruvic acid in the tyrosine metabolic pathway (Fig. 3)33,34,43,44. Accumulation of homogentisate can occur when homogentisate 1,2-dioxygenase, the enzyme encoded by hmgA that metabolizes this compound to 4-maleylacetoacetate, is not present (Fig. 3). The homogentisate is oxidized and polymerized to produce pyomelanin30,34. Figure 3 shows the tyrosine metabolic pathway underscoring the steps relevant to formation of pyomelanin. To determine if this pathway is responsible for the hyperproduction of the brown pigment in V. anguillarum 531Ad, we cloned the chromosome I region encompassing the hppD and hmgA genes from strains 531Ac and 531Ad. Introduction of the recombinant clones pP531Ac and pP531Ad into E. coli resulted in clear and dark colonies, respectively (Fig. 3). Inspection of the nucleotide sequences of both regions cloned showed that there was a 410-bp tandem repeat within the nucleotide sequence of the V. anguillarum 531Ad hmgA gene (hmgA*) that results in a frameshift and truncation of the product of translation. This modification leaves 156 out of a total of 375 amino acids in the complete protein (Fig. 3 and Supplementary Fig. S2). To confirm that the lack of a functional homogentisate 1,2-dioxygenase was responsible for the high production of pigment, the region cloned in pP531Ac was used as template to generate a DNA fragment that includes the complete hppD and only a portion of the hmgA gene. This fragment was used to generate the recombinant clone pP531AcΔhmgA (Fig. 3 and Supplementary Fig. S2). As expected, E. coli cells carrying this recombinant plasmid produced highly pigmented colonies (Fig. 3). Next, a recombinant clone harboring the hmgA gene under the control of the T7 promoter was generated inserting the appropriate DNA segment from strain 531Ac into pACYC177, a vector compatible with pCR-Blunt II-TOPO. This plasmid, pPhmgA531Ac, was introduced into E. coli BL21(DE3) already harboring pP531AcΔhmgA, which produces brown colonies (Fig. 4). The transformant strain, E. coli BL21(DE3) (pP531AcΔhmgA, pPhmgA531Ac), produced clear colonies further confirming that lack of a functional hmgA gene is a direct cause of production of the brown pigment (Fig. 4). The experiments described in this paragraph led us to conclude that V. anguillarum 531Ad produces high amounts of pyomelanin due to the lack of a functional homogentisate 1,2-dioxygenase. Inspection of all 60 complete V. anguillarum genomes in GenBank indicated that all of them include a gene coding for a full homogentisate 1,2-dioxygenase. Therefore, 531Ad is the only V. anguillarum strain described to date that harbors a disrupted hmgA gene.
It had been observed that V. anguillarum 531A can grow at higher concentrations of iron chelators when compared to V. anguillarum 775 due to higher production of anguibactin28,29. Since V. anguillarum 531A is a mix of two variants, 531Ac and 531Ad, it is possible that only one of them possesses the ability to grow at higher concentrations of iron chelators. The minimal inhibitory concentrations of EDDHA for both variants were 20 μM while the value for strain 775 was 10 μM. This result indicated that the presence or absence of an intact copy of the hmgA gene does not impact the iron proficiency of V. anguillarum in the experimental conditions.
Coculturing assays were used to compare the fitness of strains 531Ad and 531Ac to determine if the ability to produce high amounts of pyomelanin in high quantities was advantageous when growing in TSBS culture medium. A 1:1 mixture of the strains was cultured, and the relative frequencies were determined every 20 generations. Up to 60 generations, the ratio 531Ad/531Ac was approximately 1 indicating that both strains were equally fit when growing in TSBS.
Since a recent report described a variant of the Aeromonas salmonicida 4-hydroxyphenylpyruvate dioxygenase that is thermolabile due to the amino acids S18, P103, and L119, which in thermostable variants are mostly T18, Q103, and P11937, we identified these important amino acids within the V. anguillarum version of the enzyme. A comparison of both sequences showed that except for a short stretch at the N-terminus, the amino acid sequences shared 76% identity and 85% similarity (Fig. 5). Furthermore, the amino acids at the key positions for thermolability in the V. anguillarum enzyme were T, Q, and P as it is the case of those that are thermostable (Fig. 5).
Discussion
The production of the ochronotic pigment pyomelanin has been reported in numerous organisms including humans, where the accumulation of homogentisate produces the syndrome known as ochronosis or alkaptonuria45,46. Numerous bacteria have been identified as producers of a pyomelanin-type pigment, which occurs through the metabolic pathway of tyrosine degradation. Homogentisate is produced by the action of 4-hydroxyphenylpyruvate dioxygenase on 4-hydroxyphenylpyruvic acid. When this metabolite accumulates, it undergoes oxidation and polymerization producing the brown pigment pyomelanin. This process has been identified as the cause behind the production of the pigment in several bacteria such as V. anguillarum33, V. cholerae38, A. salmonicida37, Legionella pneumophila31, Shewanella colwelliana32, Burkholderia cepacia35, B. cenocepacia36, Streptomyces avermitilis34, Ralstonia solanacearum30. Previous studies identified VanT and RpoS as positive regulators of pyomelanin production by enhancing expression of 4-hydroxyphenylpyruvate dioxygenase in V. anguillarum cultures entering stationary phase33,44. However, based on the published information33,44, these levels of pigment production must be much lower than those observed in strain 531Ad, in which the lack of homogentisate 1,2-dioxygenase activity leads to accumulation of the pyomelanin precursor and production of unusually high amounts of the pigment. The results obtained by searching the GenBank database indicating that all sequenced V. anguillarum strains show a complete hmgA gene confirms that the mechanism of production of pyomelanin in strain 531Ad is, to our best knowledge, exceptional among this species. A search for this characteristic, i.e., higher pigmentation, in other bacteria showed that a subset of Burkholderia cepacia strains includes a deficient hmgA gene. In this case, rather than the truncation, the variant of the hmgA gene codes for a protein that has an amino acid substitution that is detrimental for enzymatic activity35.
Since we did not know the basis of the appearance of two variants in the sample kept at −80 °C in the laboratory collection, a battery of experiments was carried out to determine of both V. anguillarum 531Ac and 531Ad have a common origin and also if there is a fitness difference in regular laboratory growth conditions. Whole-genome sequencing and plasmid restriction enzyme digestion analyses showed that both variants are essentially the same strain with the exception of the hmgA gene and other minor mutations. Furthermore, comparison of their iron uptake proficiency also failed to show any difference. Of course, it is possible that the production of pyomelanin is advantageous in particular conditions not tested in this work. For example, it was recently found in comparisons of different Klebsiella pneumoniae strains, which showed that a dominant Klebsiella pneumoniae strain in the host does not show enhanced fitness in the mixed growth assay47. Several studies found pyomelanin functions that could enhance fitness in bacteria. Examples of these functions are protection against oxidative stress30,36,48 or enhancement of bacterial virulence35,38. A V. cholerae mutant obtained by mini-Tn5 insertion within hmgA overproduced pyomelanin, expressed more toxin-coregulated pilus and cholera toxin, and showed enhanced colonization of intestines in an infant mice model of infection38. On the other hand, other reports show a reduction in virulence of bacteria that develop the capability to produce the pigment49. The information available seems to indicate that high production of pyomelanin is correlated with pleiotropic changes that may differ among bacteria. Future experiments will clarify our understanding of the possible role of pyomelanin in high quantities in the physiology and virulence of V. anguillarum.
Methods
Bacterial strains, plasmids, primers, and media
The relevant characteristics of bacterial strains and plasmids used in this work are described in Table 1. V. anguillarum 531A was isolated from a diseased fish in the coast of Maine28,29,39. V. anguillarum 775 is a prototype serotype O1 strain; it was used for comparison of growth under iron deficiency conditions and as a source of plasmid pJM122. Escherichia coli TOP10 (Life Technologies) and BL21(DE3)50 were used as hosts of recombinant clones. Plasmids pCR-Blunt II-TOPO (Life Technologies) and pACYC17751 were used as cloning vehicles. V. anguillarum strains were cultured at 25 °C in Trypticase soy broth with the addition of 1% (w/v) NaCl (TSBS), and for cultures in solid medium the medium was supplemented with 2% agar (TSAS)42. E. coli strains were cultured at 37 °C in LB broth or LB agar (2%). Oligonucleotides to be used as primers or for DNA sequencing were purchased from Integrated DNA Technologies or Bio-Synthesis Inc.
General procedures
Plasmid DNA isolation and PCR reactions were carried out using the QIAspin miniprep (QIAGEN) and the Invitrogen Platinum SuperFi PCR Master Mix (ThermoFisher Scientific) kits, respectively. Primers used to amplify DNA fragments are listed in Table 2. Restriction endonuclease and T4 DNA ligase treatments were performed according to the supplier’s recommendations (New England Biolabs). Transformation of competent E. coli strains was carried out as described by the supplier (Life Technologies). Briefly, 50 μl of the competent cells suspension were thawed on ice before adding the DNA sample. The cells were then incubated for 30 minutes on ice, followed by a heat shock at 42 °C for 30 seconds. Then 250 μl of LB broth were added, and the cells were incubated for 1 hour at 37 °C with shaking. The cells were then plated on LB agar containing 1 mg/ml ampicillin. Amino acid sequence comparisons were carried out using the BLAST tool at the National Center for Biotechnology information52.
Determination of minimal inhibitory concentration (MIC) of ethylenediamine di(o-hydroxyphenyl) acetic acid (EDDHA)
MIC of the synthetic iron chelator of the iron chelator EDDHA was assessed culturing the strains in M9 minimal medium containing incremental EDDHA concentrations up to 40 μM22,28.
Fitness assays
Fitness of V. anguillarum strains 531Ac and 531Ad were compared coculturing a 1:1 mixture of the strains and determining their ratio every 20 generations as described previously53,54.
Pigment production
V. anguillarum strains were inoculated in TSBS or plated on solid media and cultured at 25 °C for 36 h. E. coli strains were plated on LB agar and incubated for 36 h at 37 °C. The production of pigment was readily visible.
Genome sequencing and bioinformatic analysis
Genomic DNA was extracted using the Master Pure DNA purification kit following the manufacturer’s instructions (Epicentre, Madison, WI, USA). Libraries were generated using the Illumina Nextera kit (Illumina Inc., San Diego, CA) as described by Baym et al.55, and sequenced with the Illumina NextSeq500 equipment at the Microbial Genome Sequencing Center (Pittsburgh, PA). De novo assembly was performed with SPADES assembler, version 3.3.156. The annotation was performed using the RAST server57 and the predictions were confirmed using the BLAST software52. The quality of the sequences and assembly were evaluated using FASTQC software (https://www.bioinformatics.babraham.ac.uk/projects/fastqc/) and the QUAST software58, respectively. The Average Nucleotide Identity and pairwise tetra nucleotide correlation were performed using JSpeciesWS online service59. The mutation prediction between both isolates was performed using breseq60. The core genome prediction was carried out using the Roary software61 including seventy V. anguillarum genomes from GenBank. The core-genome phylogeny was performed using RaxML62 and substitution model was predicted with JModelTest263. The default Bootstrap test was used to evaluate branch supports. The tree representation was done using FigTree (https://github.com/rambaut/figtree/). The transmembrane domain prediction was done using the TMHMM software (http://www.cbs.dtu.dk/services/TMHMM/).
Data Availability
Published accession numbers of sequences used in this study are included in the article. The nucleotide sequences of specific regions from strains 531Ac and 531Ad have been provided GenBank accession numbers MK791314 and MK791315. Whole genome sequences of V. anguillarum 531Ac and 531Ad provided GenBank accession numbers VSLE00000000 and VSLF00000000, respectively. Bacterial strains are available upon request.
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Acknowledgements
This work was supported by Public Health Service grants 2R15AI047115 (M.E.T.) from the National Institute of Allergy and Infectious Diseases, National Institutes of Health, SC3GM125556 (M.S.R.) from the National Institute of General Medical Sciences, National Institutes of Health, and California State University Fullerton.
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M.E.T. conceived the study, designed, and carried out the early experiments. M.E.T., M.S.R., J.F. and V.B. designed experiments. V.B., J.F., B.F., J.S., K.L.Q., K.P., E.F., A.R., K.V., F.C., A.J.F., K.B., J.Z., V.L., K.D., G.T. and K.R. performed experiments. M.E.T. wrote the first draft of the manuscript, all other authors contributed to editing.
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Batallones, V., Fernandez, J., Farthing, B. et al. Disruption of hmgA by DNA Duplication is Responsible for Hyperpigmentation in a Vibrio anguillarum Strain. Sci Rep 9, 14589 (2019). https://doi.org/10.1038/s41598-019-51126-8
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DOI: https://doi.org/10.1038/s41598-019-51126-8
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