Abstract
In 2013–2018 on the leaves of Cornus mas L. small brownish spots with regular shape merging also to large necrotic lesions or present as extensive necrotic area from leaf petiole were observed. In 2016 on leaves of Cornus sanguinea L. dark red brownish spots of 4 mm in diameter with necrotic center, were observed. From samples with diseased tissue, fluorescent bacteria were isolated, showing a morphology similar to that of the genus Pseudomonas. The phenotypic characters using LOPAT tests [levan production from sucrose (L), presence of oxidase (O), pectolytic activity on potato (P), the presence of arginine dihydrolase (A), hypersensitivity reaction on tobacco (T)], allowed to classify the isolates to Pseudomonas syringae (LOPAT group Ia). The pathogenicity of isolates was proved on young leaves of Cornus mas and Cornus sanguinea, confirming the ability to infect the species. Detection of genes coding for the phytotoxins coronatine (cfl), syringomycin (syrB and syrD), and yersiniabactin (irp1) showed that none of strains from cornelian cherry nor red dogwood possessed cfl gene, but 5 out of 6 cornelian cherry strains contained the irpl gene. Only the strain 1439, isolated from red dogwood possessed the syrD and syrB genes. Sequence analysis of the 16S rRNA, and housekeeping genes gyrB and rpoB showed that strains from cornelian cherry are most closely related to the hazelnut pathogen Pseudomonas avellane, and that the strain from red dogwood could be identified as Pseudomonas syringae pv. syringae. Further research will determine the exact taxonomic position of the cornelian cherry strains.
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Introduction
In recent years, the growing of cornelian cherry dogwood (Cornus mas L., family Cornaceae) is becoming more and more popular. The plant is native to southern Europe and SW-Asia (Lannert 1981; Lawrence 1985, Mamedov and Craker 2004), but nowadays is also commonly grown in north-eastern Europe and Great Britain, Central Asia, and South America (rev in Mamedov and Craker 2004). Its popularity in Europe is undoubtedly linked to the value and the ‘advantages’ of the fruits both as fresh or used for preparation of juices, syrups, wine, and traditional products (Brindza et al. 2007; Tesevic et al. 2009; Rop et al. 2010). Moreover, cornelian cherry is a prospective source for phytomedicine, possessing interesting antimicrobial properties against fungal and bacterial pathogens, e.g. Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa and Candida albicans. Also, it is very popular in folk medicines, especially in China (Krzyściak et al. 2011; Kyriakopoulos and Dinda 2015; Dinda et al. 2016). Cornelian cherry till now has demonstrated longevity and adaptability, and is considered as a plant that is easy to grow due to its high resistance to drought, air pollution and low susceptibility to pests and diseases.
The few most common diseases attacking cornelian cherry are caused by a number of fungal pathogens: Discula destructive (dogwood anthracnose), Elsinoe corni (dogwood spot anthracnose), Septoria cornicola (septoria leaf spot), and Phyllactinia corni (powdery mildew) (Redlin 1991; https://www.cabi.org/isc/datasheet/20079; http://www4.ncsu.edu/~qyxiang/cornuspathology.html; Gauthier and Stolz 2017; Bacigálová et al. 2005; Li et al. 2009, Mmbaga et al. 2016). However, very little is known about bacterial diseases occurring on cornelian cherry. Hitherto, only one report was published about occurrence of a leaf blight caused by Pseudomonas syringae in Tennessee, USA (Mmbaga and Sheng 2000; Mmbaga and Nodu 2006). However, the identity of isolates obtained from diseased leaves classified as P. syringae was confirmed only by some phenotypic characters and fatty acid analysis.
In 2013, 2014 and 2018 on leaves of Cornus mas plants, delivered to our laboratory from nurseries, small, regular, brownish spots ca. 3 mm in diameter sometimes merging, to form large necrotic lesions, were observed. From the symptomatic tissue fluorescent bacteria were repeatedly isolated.
Cornus sanguinea L. known as common or red dogwood belongs to the same family as cornelian cherry. It is widely distributed in almost the entire European continent and west Asia. It can grow from lowlands up to 1500 m above sea level in the Alps e.g. Switzerland and Caucasus Mountains. As an ornamental plant it is used for fences, but also grows along riversides, and is often planted as an ornamental in cities and along roads (Liesebach and Götz 2008; Wadl et al. 2013). Red dogwood is affected by only a few fungal pathogens: Discula destructive (dogwood anthracnose), and sometimes Nectria spp., Phomopsis spp., Botryosphaeria spp., Tubercularia spp., Phytophthora spp. (dieback/canker) (https://www.eppo.int/QUARANTINE/Alert_List/fungi/DISCDE.htmhttp://extension.illinois.edu/hortanswers/plantdetail.cfm?PlantID=372&PlantTypeID=8). Hitherto, there was no report on the occurrence of bacterial diseases on this species. In 2016 on leaves of red dogwood (Cornus sanguinea L.) shrubs dark red, brownish spots with regular shape of 4–5 mm in diameter with necrotic center, were observed in Poland. Although, the symptoms were first taken for those caused by Discula destructive causing anthracnose, fluorescent bacteria were repeatedly isolated.
As mentioned above, Pseudomonas syringae, which was reported on cornelian cherry in the USA, is known as polyphagous, causing economically important diseases on many both annual and woody plants, including fruit trees, vegetables and ornamental plants (Bultreys and Kałużna 2010). From molecular studies it is known that the P. syringae complex comprises over 50 pathovars defined according to their pathogenic ability (Young 2010). This species is also divided into genomospecies determined by DNA:DNA hybridization (Gardan et al. 1999) and redefined into up to 13 so called phylogroups (PG) (Parkinson et al. 2011; Berge et al. 2014) based on Multi Locus Sequence Analysis (MLSA) largely corresponding to the genomospecies defined by DNA:DNA hybridization (Gardan et al. 1999).
The aim of present study was to characterize and determine the taxonomic and phylogenetic position of bacterial isolates causing necroses on leaves of cornelian cherry and red dogwood in Poland, based on phenotypic characteristics and molecular sequence analysis of 16S rRNA and the housekeeping genes rpoB and gyrB.
Materials and methods
Isolation of the bacteria and determination of their phenotypic characters
Samples of cornelian cherry (Cornus mas L.) leaves exhibiting small brownish spots, and/or large necrotic lesions were delivered to our laboratory from nurseries in the years 2013, 2014, and 2018 in Łódzkie and Kujawsko-pomorskie voivodeships in Poland (Fig. 1; Table 1). Leaf samples of red dogwood (Cornus sanguinea L.) shrubs with dark red, brownish spots with regular shape of 4 mm in diameter with necrotic center were also supplied from nurseries in 2016 from Łódzkie voivodeship, Poland (Fig. 2; Table 1).
From the border between healthy and diseased tissue, that was shortly disinfected with 70% ethanol, small pieces were cut out and macerated in sterile PBS buffer (0.27% Na2HPO4; 0.04% NaH2PO4; 0.8% NaCl). The macerate was plated onto King’s medium B (King et al. 1954) and incubated at 27 °C. After 48 h single, fluorescent, colonies were selected and purified on the same medium. The obtained isolates were subjected to the following tests: Gram reaction with 3% KOH (Suslow et al. 1982), and LOPAT tests [levan production from sucrose (L), presence of oxidase (O), pectolytic activity on potato (P), the presence of arginine dihydrolase (A), hypersensitivity reaction on tobacco (T)] were performed (Lelliott 1966). A culture of Pseudomonas syringae pv. syringae strain LMG 1247 was used as reference. For further analysis all isolates and the reference strain LMG 1247 were stored in a mixture of glycerol (20% v/v) and PBS and kept at −75 °C (Table 1).
Pathogenicity test
To determine the pathogenicity of all isolates the attached young leaves of two plants of Cornus mas and Cornus sanguinea were inoculated with a water suspension of each isolate separately and the reference strain LMG 1247T mentioned in Table 1 and at a concentration of 107cfu ml−1 was prepared from 48 h-old cultures grown on King’s B. The suspension was infiltrated into leaves by a hypodermic syringe. The plants with infiltrated leaves were covered with plastic bags for 48 h to maintain high humidity conditions and then were kept in a greenhouse at 18–22 °C. Leaves were also treated by the same way with sterile distilled water as the negative control. During two weeks appearance of lesion formation and development of disease symptoms were observed (Fig. 3a and b). From symptomatic tissue samples were taken for bacteria re-isolation. For confirmation of the identity of bacteria re-isolated with those used for inoculation phenotypic characters, and PCR reactions with primers Ps-for and Ps-rev were performed.
Molecular characterization and phylogenetic analysis
Isolation of bacterial DNA was performed by the method described by Aljanabi and Martinez (1997) with slight modifications described in Kałużna et al. (2012). To confirm that bacteria obtained from cornelian cherry and red dogwood belong to the genus Pseudomonas amplification of DNA with primers Ps-for and Ps-rev (Widmer et al. 1998) according to the reaction conditions as originally described was done. DNA of reference strain LMG 1247T was included for comparison.
Detection of genes coding for syringomycin, coronatine and yersiniabactin
Determination of the presence of genes coding for synthesis of the bacterial phytotoxins syringomycin, coronatine and the siderophore yersiniabactin was done by PCR with primers amplifying fragments of their genes: (i) syrB and syrD encoding synthesis of syringomycin with primers syrB1/syrB2 and syrD1/syrD2 as described by Sorensen et al. (1998) and Bultreys and Gheysen (1999), respectively, (ii) irp1 encoding synthesis of yersiniabactin with primers PSYE2/PSYE2R from Bultreys et al. (2006) and (iii) cfl encoding coronatine synthesis with primers cfl1/cfl2 described by Bereswill et al. (1994). The amplifications were conducted in a Biometra T3000 thermocycler (Biometra, Germany). The conditions of all PCR reactions, with slight modifications of annealing temperatures applied are indicated in Kałużna et al. (2010). Reference strains P. syringae pv. morsprunorum race 1 – LMG 2222, P. syringae pv. morsprunorum race 2 – CFBP 3800, P. syringae pv. syringae (Pss) – LMG 1247T) were included in all reactions. PCR products were separated in a 1.5% agarose gel in 0.5 x TBE buffer (0.045 M Tris – boric acid, 0.001 M EDTA, pH 8.0) (Sambrook et al. 1989) by comparison with the standard mass O’GeneRuler 100 bp DNA Ladder Plus (ThermoScientific, Lithuania) and electrophoresis run at 5–7 V/cm of gel. After staining with ethidium bromide solution (0.5 μg ml−1) the obtained amplification products were visualized under UV light.
Identification of isolates based on sequence analysis of 16S rRNA, gyrB and rpoB genes
All isolates obtained from cornelian cherry and the one isolate from red dogwood were identified by (partial) sequence analysis of 16S rRNA and the gyrB and rpoB housekeeping genes. For this purpose DNA was amplified with the primers fD1 and rp2 (Weisburg et al. 1991), primers gyrB-F and gyrB-R (Sawada et al. 1999) and primers LAPS and LAPS27 (Ait Tayeb et al. 2005), respectively, with PCR conditions as it was described in the above mentioned papers. The sequences obtained were assembled using the SeqMan Lasergene package (DNASTAR, Inc., Madison, WI) and sequences compared with those deposited in NCBI GenBank (http://www.ncbi.nlm.nih.gov) and in the database of the EzTaxon server (https://www.ezbiocloud.net/; Yoon et al. 2017). Maximum Likelihood phylogenetic trees including all species of the Pseudomonas genus (Fig. 3) and most closely related species (Figs. 4 and 5) were constructed with the MEGAX program (Kumar et al. 2018).
A dendrogram based on the sequence analysis of the partial 16S rRNA gene for all Pseudomonas spp. species was constructed using the General Time Reversible evolutionary model with gamma distribution and by assuming that a certain fraction of sites are evolutionarily invariable (G + I) (found as the best substitution model) (Nei and Kumar 2000), however, with closest relatives with Hasegawa-Kishino-Yano (HKY) gamma distributed with invariant sited (G + I) (found as the best substitution model) (Hasegawa et al. 1985). A dendrogram based on sequence analysis of gyrB for all Pseudomonas spp. species was constructed using the Tamura-Nei evolutionary model with gamma distribution (+G) (Tamura and Nei 1993). For rpoB genes the General Time Reversible evolutionary model with gamma distribution and by assuming that a certain fraction of sites are evolutionarily invariable (G + I) was used as it was found as the best substitution model (Nei and Kumar 2000). Dendrograms based on sequence analysis for cornelian cherry, red dogwood and the closest neighbor of other species for gyrB and rpoB genes were constructed using using the Tamura 3 parameter (found as the best substitution model) (Tamura 1992). The significance of the internal branches of all dendrograms was estimated with bootstrap values expressed as percentages of 500 replications. All 21 sequences of the 3 genes analyzed for 7 strains were deposited in the NCBI database, with the following accession numbers: (ii)16S rRNA gene: LS991856-LS991862, (ii) gyrB gene: LS991830-LS991836 and (iii) rpoB gene: LS991849-LS991855.
PCR with primers specific for P. avellanae
Based on the results obtained from the analysis of the 16S rRNA, gyrB and rpoB gene sequences (Figs. 4, 5 and 6, supplementary Fig. S1 and S2), an additional PCR using specific primers for P. avellanae (Pa): PAV 1 and PAV 22 (Scortichini and Marchesi 2001) and WA/WC (Loreti and Gallelli 2002) and P. s. pv. actinidiae (Psa) (Rees-George et al. 2010) were chosen for further identification of cornelian cherry isolates. The protocol and conditions described in original paper were used. PCR products were separated in a 1.5% agarose gel in 0.5 x TBE buffer (0.045 M Tris – boric acid, 0.001 M EDTA, pH 8.0) by comparison with the standard mass O’GeneRuler 100 bp DNA Ladder Plus (ThermoScientific, Lithuania) and electrophoresis run at 5–7 V/cm of gel. After staining with ethidium bromide solution (0.5 μg/ml) the obtained amplification products were visualized under UV light.
Results and discussion
Six fluorescent bacterial isolates were selected from those obtained from cornelian cherry and one isolate from red dogwood leaves with blight symptoms. Their colony morphology and strong blue fluorescence on King’s B medium was similar to the type strain of Pseudomonas syringae LMG 1247T. The affinity of isolates was confirmed by PCR with primers Ps-F and Ps-R – all gave product 967 bp characteristic for Pseudomonas genus.
The pathogenicity test showed that these isolates caused a different kind of necrosis (Fig. 3a and b). The first symptoms were observed after 24 h from inoculation only with strain LMG 1247T and isolate 1439 from red dogwood on both Cornus mas and Cornus sanguinea leaves. After next 48 h the symptoms caused by isolate 1439 on Cornus sanguinea significantly enlarged and dry necrotic areas were observed in the center of lesions (Fig. 3a), whereas the symptoms on Cornus mas leaves were not so expanded but also some similar dry areas could be noticed. Strain LMG 1247T caused only small necrotic spots on both host but they did not enlarge since their appearance. The symptoms on both hosts did not change over a period of 5–7 days after inoculation (Fig. 3a). All isolates from cornelian cherry caused first small brownish spots 72 h after inoculation on Cornus mas leaves and clear brown necrotic spots, often surrounded by a chlorotic halo, similar to those observed on natural conditions appeared after next 24 h (Fig. 3b). A little different spots were observed after inoculation of leaves with isolate 1299b (Fig. 3b). To fulfill Koch’s postulates, bacteria were re-isolated from leaves 8 days after the inoculations. Almost pure cultures were grown on the isolation plates. Colony morphology, other phenotypic characters i.e. LOPAT tests and PCRs done with primers for syrB, irp1, PAV 1/PAV 22 and WA/WC, confirmed that the re-isolates were the same as bacteria which were used for inoculation.
After a 2–4 days of incubation on King’s B medium at room temperature all six isolates from cornelian cherry produced a brown pigment which changed the color of entire medium to brown after next 48 h. This feature was already observed in our previous study with a Pseudomonas species isolated from blueberry (Vaccinium corymbosum) in Poland that is also very closely related to Pseudomonas avellanae (Kałużna et al. 2013). No information concerning production of a brown pigment was provided in the first report of leaf blight caused on Cornus mas L. from Tennessee, USA (Mmbaga and Sheng 2000). Moreover, it is not known if production of brown pigment on King’s B by the US cornelian cherry isolates was not noticed by the researchers or those isolates actually do not produce it. The results from phenotypic tests presented here showed that all seven selected isolates were Gram-negative, produced levan on NSA medium [Nutrient Agar (Difco), supplemented with 5% of sucrose], induced hypersensitivity reactions on tobacco leaves cv. ‘Samsun’, were negative for the oxidase, arginine dihydrolase and did not caused soft rot of potato slices. These features allowed to classify them to Pseudomonas syringae – the LOPAT group Ia as described by Lelliott et al. (1966). As mentioned above the isolates from Cornus mas L. produced brown pigment similarly to isolates originating from blueberry however, the blueberry differ, at least phenotypically, because they did not produce levan (Kałużna et al. 2013). It is know from our previous study and other authors that LOPAT tests although very useful, are apart from being rather labor-intensive and time-consuming (Little et al. 1998; Vicente et al. 2004; Kałużna et al. 2013). Moreover, those tests can give sometimes questionable results, and are not sufficient for definitive identification and classification. Therefore, a broader taxonomic study was performed, including molecular characterization and phylogenetic analyses for isolates from cornelian cherry. These test results confirmed that isolates were P. syringae and can be considered as a strains.
Detection of genes coding for coronatine, syringomycin, and yersiniabactin showed that the product of the expected size (650 bp) obtained by amplification of cfl gene encoding for coronatine was obtained only for Pss reference strain LMG 2222. The results of PCR with primers for the gene irp1 coding for yersiniabactin showed that this gene was present in almost all cornelian cherry strains, namely 1299a, 1342, 1343, 1557 and 1558 and in P. syringae pv. morsprunorum race 2 reference strain CFBP 3800. The syringomycin specific PCR product of 752 bp of the syrB gene and 1078 bp for the gene syrD was detected only in strain 1439 isolated from red dogwood and Pss reference strain LMG 1247. Based on these results strain 1439 isolated from red dogwood is identified as Pseudomonas syringae pv. syringae (Pss). The study of other authors indicated that syrD gene is most common in Pss strains (Abdellatif et al. 2017; Bultreys and Gheysen (1999). The presence of the genes for yersiniabactin production is widespread within the genus Pseudomonas and hitherto was found to be present in the pathovars antirrhini, apii, berberidis, delphinii, lachrymans, morsprunorum race 2, passiflorae, persicae, tomato, viburni, helianthi, tagetis and theae (Bultreys et al. 2006).
When sequences of the cornelian cherry strains were submitted to the database of the EzTaxon server (database updated in May 2018) it was found that they were most similar to Pseudomonas avellanae BPIC 631T isolated from Corylus avellana (common hazelnut) in 1976 in Greece (over 99% of similarity), the causal agent of bacterial canker and decline of hazelnut, Corylus avellana L. (Janse et al. 1996) which belongs also to group LOPAT Ia and does not possess the syrB gene (Lelliott et al. 1966; Scortichini et al. 2002). The strain 1439 from red dogwood was most closely related (100%) to Pseudomonas ficuserectae JCM 2400T isolated from Ficus erecta Thunb. in 1983 in Japan, (Goto 1983). Sequence similarity of cornelian cherry strains when compared to sequences available in NCBI database showed the closest similarity (99%) to Pseudomonas syringae pathovars tomato, avii and maculicola. In the NCBI database the strain 1439 from red dogwood was the most similar to Pseudomonas ficuserectae JCM 2402 isolated from Ficus erecta Thunb. in 1983 in Japan (Goto 1983) and P. s. pv. syringae Pss9097 isolated from Prunus avium in UK by Steve Roberts in 2010 and CFBP 2118 isolated from Prunus avium in France in 1979.
The dendrogram constructed on the analysis of gene sequence of the 16S rRNA including all type strains of Pseudomonas spp. (data not shown) showed that the all isolates from cornelian cherry revealed the highest similarity (formed separate cluster with low bootstrap value 32%) to Pseudomonas amygdali LMG 2123T isolated from Prunus dulcis in 1975 in Crete Greece, causing leaf blight on almond (Prunus amygdalus) trees, and again a close relation (formed separate cluster with low bootstrap value 32%) with Pseudomonas avellanae PD 2378T and Pseudomonas asturiensis LPPA 221T but not to type strain of P. s. pv. syringae (Pss), was found in separate distant cluster. The strain 1439 from red dogwood was found again to be the most related to Pseudomonas ficuserectae JCM 2400T. The dendrogram constructed based on the whole analyses with these closest relatives showed that the strains from cornelian cherry formed a separate cluster with high bootstrap value of 99% (Fig. 4).
The dendrogram constructed on sequence analysis of gyrB gene with all type strains of Pseudomonas spp. species (data not shown) indicated that cornelian cherry isolates were most similar to Pseudomonas avellanae CIP 105176T isolated from Corylus avellana in Greece in 1997, but formed separate cluster with bootstrap value 98%, again a close relation also to Pseudomonas cannabina CIP 106140T isolated from Cannabis sativa in Hongrie in 1957 (formed again separate cluster with bootstrap value 97%). The strain from red dogwood was closely related (formed separate cluster with bootstrap value 82%,) to P. syringae pv. syringae PDDCC 3023T and Pseudomonas congelans LMG 21466T isolated from Syringa vulgaris in UK in 1950 and from grasses, phyllosphere in Paulinenaue Brandenburg Germany, in 1994, respectively. The dendrogram constructed based on the analysis with the closest relatives showed that the strains from cornelian cherry formed a separated cluster with as closest relative P. avellanae CIP 105176T with a high bootstrap value of 98% (Fig. 5).
The dendrogram constructed on sequence analysis of rpoB gene with all type strains of Pseudomonas spp. species (data not shown) indicated that cornelian cherry isolates were the again most closely related to Pseudomonas avellanae CIP 105176T (but formed separate cluster with bootstrap value 100%), but also to Pseudomonas cannabina CIP 106140T and Pseudomonas coronafaciens LMG 13190T, so exactly the same results was obtained as for gyrB gene (Fig. 6). The strain from red dogwood was found in a cluster together with the type strain of P. syringae pv. syringae LMG 1247T, Pseudomonas congelans LMG 21466T, Pseudomonas cerasi 58T and Pseudomonas caricapapayae LMG 2152T, isolated from Syringa vulgaris in UK in 1950, from grasses, phyllosphere in Paulinenaue Brandenburg Germany, in 1994, Prunus cerasus in 2007 in Poland and from Carica papaya in Brasil, in 1966, respectively, so in to the P. syringae group (Anzai et al. 2000).
All the results from phylogeny analyses are in agreement with the study on genes coding of toxin production, i.e. cornelian cherry strains possessed irp1 gene for yersiniabactin production, as is known for P. avellanae strains which also produce yersiniabactin (Marcelletti and Scortichini 2015). The strain 1439 from red dogwood is highly similar to Pss in possessing syrD genes also characteristic for this pathovar.
Because based on the phylogeny, cornelian cherry strains showed their close relationship to P. avellanae a PCR with a primer pair PAV1 and PAV22 specific for P. avellane (Scortichini and Marchesi 2001) was additionally performed. These PCR results proved to be positive for all isolates from cornelian cherry. Similar results were obtained with Pseudomonas spp. strains isolated in Poland from blueberry. However, when the phylogenetic study was done on cornelian cherry and blueberry isolates based on all three genes i.e. 16S rRNA, gyrB and rpoB the cornelian cherry strains formed separate cluster from blueberry ones in 100% bootstrap value. It is known from literature that the primers specific for P. avellanae (Scortichini and Marchesi 2001) also amplify DNA of other taxa, namely P. s. pv. actinidiae and pv. theae (Pst) (Scortichini et al. 2002) and others i.e. selected strains of Pseudomonas fluorescens, P. marginalis, P. syringae pvs. Papulans, syringae, actinidiae and tomato (Rees-George 2010).Thus it is possible that also here such situation appear and exact identification awaits an in depth taxonomic study (Scortichini et al. 2002). Based on these results in the work on blueberry isolates, an additional dendrogram using sequences of strains belonging to pathovars of P. syringae was constructed which showed a closer similarity of these strains to P. s. pv. actinidiae causing bacterial canker disease of kiwifruit and pv. theae, the causal agent of bacterial shoot blight on tea plants, than to P. avellanae (Kałużna et al. 2013). Here, in this work, when the sequences of the rpoB gene of pathovars Psa and Pst were added to the sequence analysis of this gene from cornelian cherry, red dogwood and the closest neighbor of other species, the cornelian cherry strains were also more closely related to Psa and Pst than to P. avellanae (Supplementary Fig. S1). Based on this finding, PCR with primers specific to Psa with primers (Rees-George et al. 2010) showed that all the cornelian cherry strains gave a characteristic product 280 bp with primers PsaF1/R2. When additionally sequences of the rpoB gene of some blueberry strains were included, the cornelian cherry strains were more similar to P. avellanae (but separated from this species with high bootstrap value of 100%). In this final dendrogram blueberry strains grouped more with Psa (but also formed separate cluster form them with high bootstrap value of 98%) (Supplementary Fig. S2). The results of similarity of other taxa to P. avellanae were described already by Scortichini et al. (2013). The conducted genomic analyses on redefinition of P. avellanae using the average nucleotide identity (ANI) analysis and the tetranucleotide frequency correlation coefficients (TETRA) value methods demonstrated the existence of a well demarcated genomic cluster that includes strains classified as P. avellanae, P. syringae pv. theae, P. s. pv. actinidiae and one P. s. pv. morsprunorum strain, all belonging to P. avellanae sensu lato. Moreover, as stated by Scortichini and coworkers, some strains of P. s. pv. tomato and one P. s. pv. lachrymans strain, are also closely related to P. avellanae (Scortichini et al. 2013). Because the primer pair PAV1 and PAV22 proved not to be specific for Pa strains only, we have performed an additional PCR with primer set WA/WA, designed to the hrpW gene, which is specific for virulent Pa strains only (Loreti and Gallelli 2002). The results showed that specific product 350 bp was present in some cornelian cherry strains, namely 1299a, 1342, 1343, 1557 and 1558. Only 1299b strain was negative so the same as in case of PCR for irp1 coding for yersiniabactin. Strain 1299b also showed different symptoms in pathogenicity test. It is known from literature that bacterial populations, that have the hrp genes encoding for the harpin proteins are very virulent to hazelnut germplasm (Loreti et al. 2001). Moreover, as stated by authors, specific primer set WA/WC targeted to hrpW gene, enables the discrimination between P. avellanae and other pseudomonads associated with hazelnut decline (Loreti and Gallelli 2002; Scortichini et al. 2002). Therefore, it appears that cornelian cherry strains, except 1299b, possess a gene associated coding for high virulence.
When gyrB gene sequences, obtained in an earlier study (Kałużna et al. 2014) of causal agents of bacterial canker of stone fruit trees in Poland were compared with sequences of the same gene fragment of all available Pseudomonas type strains present in GenBank, the Polish strains did not form a monophyletic group, which is the basic criterion for classification into one species. Strains of P. syringae pv. morsprunorum race 2 were grouped with P. avellanae CIP 105176T (Kałużna et al. 2014).When sequences of all pathovars of P. syringae were added to the analysis the grouping of strains appeared even the more complex (data not shown). However, no Psa or Pst strains were found to be related to P. syringae pv. morsprunorum race 2.
As far as is known, this is the first report on the occurrence of a bacterial leaf blight on cornelian cherry (Cornus mas) in Poland. The causal agent is a Pseudomonas species, closely related to P. avellanae. Results till so far, however, do not allow definitive taxonomic placement and identification yet. Therefore, further taxonomic study using the polyphasic approach including phenotypic characterization, BIOLOG, genome sequencing, ANIb, GGDC, DNA–DNA hybridization, sequence analysis of 16S rDNA and more housekeeping genes – MLSA, determination of G + C content, FAME and others enabling definitive classification and determination of taxonomic position of these isolates and those of Vaccinium corymbosum (Kałużna et al. 2013) and the related pathovars (Scortichini et al. 2013; Kałużna et al. 2014) will be continued. This paper presents furthermore the first report on the occurrence of P. s. pv. syringae on red dogwood (Cornus sanguinea L.).
References
Ait Tayeb L, Ageron E, Grimont F, Grimont PAD (2005) Molecular phylogeny of the genus Pseudomonas based on rpoB sequences and application for the identification of isolates. Res Microbiol 156:763–773
Aljanabi SM, Martinez I (1997) Universal and rapid salt-extraction of high quality genomic DNA for PCR-based techniques. Nucleic Acids Res 25:4692–4693
Anzai Y, Kim H, Park JY, Wakabayashi H, Oyaizu H (2000) Phylogenetic affiliation of the pseudomonads based on 16S rRNA sequence. Int J Syst Evol Microbiol 50:1563–1589
Bacigálová K, Tóth D, Brindza J (2005) Powdery mildew Phyllactinia corni causing disease on Cornus mas (Cornaceae) – a new record for Slovakia. Plant Prot Sci 41:90–93
Bereswill S, Bugert P, Volksch B, Ullrich M, Bender CL, Geider K (1994) Identification and relatedness of coronatine-producing Pseudomonas syringae pathovars by PCR analysis and sequence determination of the amplification products. Appl Environ Microbiol 60:2924–2930
Berge O, Monteil CL, Bartoli C, Chandeysson C, Guilbaud C, Sands DC, Morris CE (2014) A user's guide to a data base of the diversity of Pseudomonas syringae and its application to classifying strains in this phylogenetic complex. PLoS One 9:e105547
Brindza P, Brindza J, Toth D, Klimenko SV, Grigorieva O (2007) Slovakian cornelian cherry (Cornus mas L.): potential for cultivation. Acta Hortic 760:433–437
Bultreys A, Kałużna M (2010) Bacterial cankers caused by Pseudomonas syringae on stone fruit species with special emphasis on the pathovars syringae and morsprunorum race 1 and race 2. J Plant Pathol 92:S21–S33
Bultreys A, Gheysen I, Hoffmann de E (2006) Yersiniabactin production by Pseudomonas syringae and Escherichia coli and description of a second yersiniabactin locus evolutionary group. Appl Environ Microbiol 72:3814–3825
Bultreys A, Gheysen I (1999) Biological and molecular detection of toxic lipodepsipeptide-producing Pseudomonas syringae strains and PCR identification in plants. Appl Environ Microbiol 65:1904–1909
Dinda B, Kyriakopoulos AM, Dinda S, Zoumpourlis V, Thomaidis NS., Velegraki A, Markopoulosg C, Dinda, M (2016) Cornus mas L.(cornelian cherry), an important European and Asian traditional food and medicine: ethnomedicine, phytochemistry and pharmacology for its commercial utilization in drug industry. J Ethnopharmacol 193:670–690
Gardan L, Shafik H, Belouin S, Broch R, Grimont F, Grimont PAD (1999) DNA relatedness among the pathovars of Pseudomonas syringae and description of Pseudomonas tremae sp. nov. and Pseudomonas cannabina sp. nov. (ex Sutic and Dowson 1959). Int J Syst Bacteriol 49:469–478
Gauthier NW, Stolz S (2017) Flowering dogwood diseases. http://plantpathology.ca.uky.edu/files/ppfs-or-w-06.pdf
Goto M (1983) Pseudomonas ficuserectae sp. nov., the causal agent of bacterial leaf spot of Ficus erecta Thunb. Int J Syst Evol Microbiol 33:546–550
Hasegawa M, Kishino H, Yano T (1985) Dating the human-ape split by a molecular clock of mitochondrial DNA. J Mol Evol 22:160–174
Janse JD, Rossi MP, Angelucci L, Scortichini M, Derks JHJ, Akkermans ADL, De Vrijer R, Psallidas PG (1996) Reclassification of Pseudomonas syringae pv. avellanae as Pseudomonas avellanae (sp. nov.), the bacterium causing canker of hazelnut (Corylus avellana L.). Syst Appl Microbiol 19:589–595
Kałużna M, Puławska J, Sobiczewski P (2010) The use of PCR melting profile for typing of Pseudomonas syringae isolates from stone fruit trees. Eur J Plant Pathol 126:437–443
Kałużna M, Janse JD, Young JM (2012) Detection and identification methods and new tests as used and developed in the framework of COST 873 for bacteria pathogenic to stone fruits and nuts Pseudomonas syringae pathovars. J Plant Pathol 94:117–126
Kałużna M, Puławska J, Meszka B (2013) A new bacterial disease on blueberry (Vaccinium Corymbosum) caused by Pseudomonas spp. J Plant Protec Res 53:32–36
Kałużna M, Puławska J, Sobiczewski P (2014) Biodiversity and phylogenetic position of bacteria causing bacterial canker of stone fruits trees in Poland. 11th EFPP Conference, Kraków, p 27
King EO, Raney MK, Ward DE (1954) Two simple media for the demonstration of pyocianin and fluorescin. J Lab Clin Med 44:301–307
Krzyściak P, Krośniak M, Gąstoł M, Ochońska D, Krzyściak W (2011) Antimicrobial activity of cornelian cherry (Cornus mas L.). Postępy Fitoterapii 4:227–231
Kumar S, Stecher G, Li M, Knyaz C, Tamura K (2018) MEGA X: molecular evolutionary genetics analysis across computing platforms. Mol Biol Evol 35:1547–1549
Kyriakopoulos AM, Dinda B (2015) Cornus mas (Linnaeus) novel devised medicinal preparations: bactericidal effect against Staphylococcus aureus and Pseudomonas aeruginosa. Molecules 20:11202–11218
Lannert E (1981) Edible and medicinal plants of Britain and northern Europe. Hamlyn Publishing Group, London
Lawrence E (ed) (1985) The illustrated book of trees and shrubs. Gallery Books, NewYork
Lelliott RA, Billing E, Hayward AC (1966) A determinative scheme for the fluorescent plant pathogenic pseudomonads. J Appl Bacteriol 29:470–489
Li Y, Mmbaga MT, Windham AS, Windham MT, Trigiano RN (2009) Powdery mildew of dogwoods: current status and future prospects. Plant Dis 93:1084–1092
Liesebach H, Götz B (2008) Low chloroplast DNA diversity in red dogwood (Cornus sanguinea L.). Silvae Genetica 57:291–300
Little EL, Bostock RM, Kirkpatrick BC (1998) Genetic characterization of Pseudomonas syringae pv. syringae strains from stone fruits in California. Appl Environ Microbiol 64:3818–3823
Loreti S, Gallelli A (2002) Rapid and specific detection of virulent Pseudomonas avellanae strains by PCR amplification. Eur J Plant Pathol 108:237–244
Loreti S, Sarrocco S, Gallelli A (2001) Identification of hrp gene, encoding harpin, in Pseudomonas avellanae (Psallidas) Janse et al. J Phytopathol 149:219–226
Mamedov N, Craker L (2004) Cornelian Cherry: A Prospective source for Phytomedicine, In Future For Medicinal And Aromatic Plants
Marcelletti S, Scortichini M (2015) Comparative genomic analyses of multiple Pseudomonas strains infecting Corylus avellana trees reveal the occurrence of two genetic clusters with both common and distinctive virulence and fitness traits. PLoS One 10(7):e0131112
Mmbaga MT, Mrema FA, Mackasmiel L, Rotich E (2016) Effect of bacteria isolates in powdery mildew control in flowering dogwoods (Cornus florida L.). Crop Prot 89:51–57
Mmbaga MT, Nodu EC (2006) Biology and control of bacterial leaf blight of Cornus mas. HortScience 41:721–724
Mmbaga MT, Sheng H (2000) First report of leaf blight caused by Pseudomonas syringae on Cornus mas. Plant Dis 84:200–200
Nei M, Kumar S (2000) Molecular evolution and Phylogenetics. Oxford University Press, New York
Parkinson N, Bryant R, Bew J, Elphinstone J (2011) Rapid phylogenetic identification of members of the Pseudomonas syringae species complex using the rpoD locus. Plant Pathol 60:338–344
Redlin SC (1991) Discula destructiva sp. nov., cause of dogwood anthracnose. Mycologia 83(5):633–642
Rees-George J, Vanneste JL, Cornish DA, Pushparajah IPS, Yu J, Templeton MD, Everett KR (2010) Detection of Pseudomonas syringae pv. actinidiae using polymerase chain reaction (PCR) primers based on the 16S–23S rDNA intertranscribed spacer region and comparison with PCR primers based on other gene regions. Plant Pathol 59:453–464
Rop O, Mlcek J, Kramarova D, Jurikova T (2010) Selected cultivars of cornelian cherry (Cornus mas L.) as a new food source for human nutrition. Afr J Biotechnol 9:1205–1210
Sambrook J, Fritsch EF, Maniatis T, (1989) Molecular cloning. A laboratory manual, 2nd edn. Cold Spring Harbor Laboratory Press, Cold Spring Harbor
Sawada H, Suzuki F, Matsuda I, Saitou N (1999) Phylogenetic analysis of Pseudomonas syringae pathovars suggests the horizontal gene transfer of argK and the evolutionary stability of hrp gene cluster. J Mol Evol 49:627–644
Scortichini M, Marcelletti S, Ferrante P, Firrao G (2013) A genomic redefinition of Pseudomonas avellanae species. PLoS One 8:e75794. https://doi.org/10.1371/journal.pone.0075794
Scortichini M, Marchesi U (2001) Sensitive and specific detection of Pseudomonas avellanae using primers based on 16S rRNA gene sequences. J Phytopathol 149:527–532
Scortichini M, Marchesi U, Rossi MP, Di Prospero P (2002) Bacteria associated with hazelnut (Corylus avellana L.) decline are of two groups: Pseudomonas avellanae and strains resembling P. syringae pv. syringae. Appl Environ Microbiol 68:476–484
Sorensen KN, Kim K-H, Takemoto JY (1998) PCR detection of cyclic lipodepsinonapeptide producing Pseudomonas syringae pv. syringae and similarity of strains. Appl Environ Microbiol 64:226–230
Suslow TV, Schrooth MN, Isaka M (1982) Application of a rapid method for gram differentiation of plant pathogenic and saprophytic bacteria without staining. Phytopathol 72:917–918
Tamura K (1992) Estimation of the number of nucleotide substitutions when there are strong transition-transversion and G + C-content biases. Mol Biol Evol 9:678–687
Tamura K, Nei M (1993) Estimation of the number of nucleotide substitutions in the control region of mitochondrial DNA in humans and chimpanzees. Mol Biol Evol 10:512–526
Tesevic V, Nikicevic N, Milosavljevic S, Bajic D, Vajs V, Vuckovic L, Vijisic I, Dordevic M, Stankovic M, Velickovic L (2009) Characterization of volatile compounds of ‘Drenja’, an alcoholicbeverage obtained from the fruits of cornelian cherry. J Serb Chem Soc 74:117–128
Vicente JG, Roberts SJ, Russell K, Alves JP (2004) Identification and discrimination of Pseudomonas syringae isolates from wild cherry in England. Eur J Plant Pathol 110:337–351
Wadl PA, Hatmaker EA, Fussi B, Scheffler BE, Trigiano RN (2013) Isolation and characterization of microsatellite loci for Cornus sanguinea (Cornaceae). Applications Plant Sci 1:1300012
Weisburg WG, Barns SM, Pellettier DA, Lane DJ (1991) 16S ribosomal DNA amplification for phylogenetic study. J Bacteriol 173:697–703
Widmer F, Seidler RJ, Gillevet PM, Watrud LS, Di Giovanni GD (1998) A highly selective PCR protocol for detecting 16S rRNA genes of the genus Pseudomonas (sensu stricto) in environmental samples. Appl Environ Microbiol 64:2545–2553
Yoon SH, Ha SM, Kwon S, Lim J, Kim Y, Seo H, Chun J (2017) Introducing EzBioCloud: a taxonomically united database of 16S rRNA and whole genome assemblies. Int J Syst Evol Microbiol 67:1613–1617
Young JM (2010) Taxonomy of Pseudomonas syringae. J Plant Pathol 92:5–14
Funding
The research work was carried out in the frame of statutory grant number 2.1.5.”New bacterial diseases of horticultural plants in Poland - identification, characterization and detection of their causal agents” funded by Ministry of Science and Higher Education.
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Kałużna, M. Characterization and phylogeny of the novel taxon of Pseudomonas spp., closely related to Pseudomonas avellanae as causal agent of a bacterial leaf blight of cornelian cherry (Cornus mas L.) and Pseudomonas syringae pv. syringae as a new bacterial pathogen of red dogwood (Cornus sanguinea L.). J Plant Pathol 101, 251–261 (2019). https://doi.org/10.1007/s42161-018-0189-5
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DOI: https://doi.org/10.1007/s42161-018-0189-5