Transfer of Xanthomonas campestris pv. arecae and X. campestris pv. musacearum to X. vasicola (Vauterin) as X. vasicola pv. arecae comb. nov. and X. vasicola pv. musacearum comb. nov. and Description of X. vasicola pv. vasculorum pv. nov

We present an amended description of the bacterial species Xanthomonas vasicola to include the causative agent of banana Xanthomonas wilt, as well as strains that cause disease on Areca palm, Tripsacum grass, sugarcane, and maize. Genome-sequence data reveal that these strains all share more than 98% average nucleotide with each other and with the type strain. Our analyses and proposals should help to resolve the taxonomic confusion that surrounds some of these pathogens and help to prevent future use of invalid names. The aim of this letter is to resolve the taxonomy of several bacterial lineages that phylogenetically fall within the species Xanthomonas vasicolaVauterin et al. 1995. These lineages include an economically important pathogen of banana and enset (X. campestris pv.musacearumYirgou andBradbury 1968), a pathogen of Areca palm (X. campestris pv. arecae Rao andMohan 1970) and closely related bacteria isolated from Tripsacum grass. Also within scope is a subset of X. campestris pv. vasculorum (Cobb 1894) Dye 1978 from sugarcane and maize. Finally, it includes strains from maize assigned to a taxon with an invalid name, [X. campestris pv. zeae]. In this manuscript, pathovar names that have no standing in nomenclature are presented with square brackets ([]) as is standard (Bull et al. 2012). There is confusion surrounding the taxonomy of some of these lineages, not least around the previous splitting of Xanthomonas campestris pv. vasculorum into two new taxa: X. axonopodis pv. vasculorum and [X. vasicola pv. vasculorum] (Vauterin et al. 1995). The latter name currently has no standing in the nomenclature, yet has nevertheless been widely adopted. Our first objective is to formally transfer these lineages into the species X. vasicola. A second objective is to formally propose X. vasicola pv. vasculorum according to the International Standards for Naming Pathovars of Phytopathogenic Bacteria (Young et al. 2001), which hereafter we call the Standards. Our description of this pathovar corresponds to the previous proposal (Vauterin et al. 1995) but also incorporates [X. campestris pv. zeae] and agrees closely with the adopted usage of this name by the community. Despite a previous proposal (Vauterin et al. 1995), the name [X. vasicola pv. vasculorum] was excluded from theNames of Plant Pathogenic Bacteria (Young et al. 1996) due to the lack of a pathotypewith an adherent description for the pathovar. Therefore, the name [X. vasicola pv. vasculorum] currently has no standing in the nomenclature and needs to be proposed as a pv. nov. Only a subset of X. campestris pv. vasculorum strains fall withinX. vasicola (while others fall withinX. axonopodis, including the pathotype strain). Therefore, the problem cannot be solved by transferring X. campestris pv. vasculorum into X. vasicola as a comb. nov. because no name-bearing strain is being transferred into X. vasicola. Corresponding author: D. J. Studholme; d.j.studholme@exeter.ac.uk Funding: This work was supported by the European Cooperation in Science and Technology (COST) Action CA16107 EuroXanth. *The e-Xtra logo stands for “electronic extra” and indicates that one supplementary figure is published online. The author(s) declare no conflict of interest. Copyright © 2020 The Author(s). This is an open access article distributed under the CC BY 4.0 International license. Vol. 110, No. 6, 202

The aim of this letter is to resolve the taxonomy of several bacterial lineages that phylogenetically fall within the species Xanthomonas vasicola Vauterin et al. 1995. These lineages include an economically important pathogen of banana and enset (X. campestris pv. musacearum Yirgou and Bradbury 1968), a pathogen of Areca palm (X. campestris pv. arecae Rao and Mohan 1970) and closely related bacteria isolated from Tripsacum grass. Also within scope is a subset of X. campestris pv. vasculorum (Cobb 1894) Dye 1978 from sugarcane and maize. Finally, it includes strains from maize assigned to a taxon with an invalid name, [X. campestris pv. zeae]. In this manuscript, pathovar names that have no standing in nomenclature are presented with square brackets ([]) as is standard (Bull et al. 2012).
There is confusion surrounding the taxonomy of some of these lineages, not least around the previous splitting of Xanthomonas campestris pv. vasculorum into two new taxa: X. axonopodis pv. vasculorum and [X. vasicola pv. vasculorum] (Vauterin et al. 1995). The latter name currently has no standing in the nomenclature, yet has nevertheless been widely adopted. Our first objective is to formally transfer these lineages into the species X. vasicola. A second objective is to formally propose X. vasicola pv. vasculorum according to the International Standards for Naming Pathovars of Phytopathogenic Bacteria (Young et al. 2001), which hereafter we call the Standards. Our description of this pathovar corresponds to the previous proposal (Vauterin et al. 1995) but also incorporates [X. campestris pv. zeae] and agrees closely with the adopted usage of this name by the community. Despite a previous proposal (Vauterin et al. 1995), the name [X. vasicola pv. vasculorum] was excluded from the Names of Plant Pathogenic Bacteria (Young et al. 1996) due to the lack of a pathotype with an adherent description for the pathovar. Therefore, the name [X. vasicola pv. vasculorum] currently has no standing in the nomenclature and needs to be proposed as a pv. nov. Only a subset of X. campestris pv. vasculorum strains fall within X. vasicola (while others fall within X. axonopodis, including the pathotype strain). Therefore, the problem cannot be solved by transferring X. campestris pv. vasculorum into X. vasicola as a comb. nov. because no name-bearing strain is being transferred into X. vasicola.
Members of the genus Xanthomonas, within the gamma-Proteobacteria, collectively cause disease on more than 400 plant species (Hayward 1993), though some members are apparently nonpathogenic (Garita-Cambronero et al. 2016;Vauterin et al. 1996;Vicente et al. 2017) and some have been isolated from clinical samples such as skin microbiota (Seité et al. 2017). Historically, taxonomy of Xanthomonas was tied to the host of isolation (Starr 1981;Wernham 1948), with the genus being split into large numbers of species, each defined by this single phenotypic feature (Dye 1962). Subsequently, most of the species were transferred (i.e., "lumped") into a single species, X. campestris, and designated as nomenspecies because the organisms could not be distinguished from one another by phenotypic and physiological tests (Dye and Lelliott 1974;Lapage et al. 1992). As a temporary solution, and to help to maintain a connection with the historical and plantpathological literature, these nomenspecies were designated as pathovars within X. campestris, each defined by host range or disease syndrome (Dye et al. 1980). More recently, DNA sequence comparisons and biochemical approaches revealed that in X. campestris, pathovar designation does not always correlate with phylogeny (Parkinson et al. , 2009Rodriguez-R et al. 2012). There have been heroic advances to improve the taxonomy of the genus as a whole (Rademaker et al. 2005;Vauterin et al. 1990Vauterin et al. , 1995Vauterin et al. , 2000 and of individual taxa (Constantin et al. 2016;da Gama et al. 2018;Jones et al. 2004;Timilsina et al. 2019;Trébaol et al. 2000), based on phenotypic, chemotaxonomic, and genotypic analyses. But in a number of taxa there remain unresolved issues.
The bacterial pathogen X. campestris pv. musacearum (Yirgou and Bradbury 1968) Dye 1978 presents a major threat to cultivation of banana and enset crops in central and eastern Africa, where it causes banana Xanthomonas wilt (BXW) and enset Xanthomonas wilt (EXW). Originally described as X. musacearum (Yirgou and Bradbury 1968), this pathogen was first isolated in Ethiopia from enset and banana in the 1960s and early 1970s, respectively Bradbury 1968, 1974). Symptoms consistent with EXW were reported for Ethiopia as early as the 1930s (Castellani 1939). However, only in the 21st century did the disease establish in the banana-growing areas of Burundi, Democratic Republic of Congo, Kenya, Rwanda, Tanzania, and Uganda (Biruma et al. 2007;Carter et al. 2010;Ndungo et al. 2006;Reeder et al. 2007;Tushemereirwe et al. 2004). In this region around the Great Lakes of eastern and central Africa, BXW disease severely challenges the livelihoods and food security of millions (Blomme et al. 2013(Blomme et al. , 2017Biruma et al. 2007;Nakato et al. 2018;Shimwela et al. 2016;Tinzaara et al. 2016). There is confusion in the literature about the taxonomy of this pathogen, with some authors adopting the invalid name [X. vasicola pv. musacearum]. The use of this name was motivated by studies suggesting a close relationship between X. campestris pv. musacearum (Yirgou and Bradbury 1968) Dye 1978b and X. vasicola pv. holcicola (Elliott 1930) Vauterin et al. 1995 based on fatty acid methyl ester (FAME) analysis, genomic fingerprinting using rep-PCR and partial nucleotide sequencing of the gyrB gene Parkinson et al. 2009). In this letter, we formally propose the name X. vasicola pv. musacearum as a comb. nov., according to the Standards for naming pathovars (Young et al. 2001).
The background to this splitting of X. campestris pv. vasculorum is that taxonomic studies revealed phenotypic and genomic differences among X. campestris pv. vasculorum strains, despite their shared host ranges (Destéfano et al. 2003;Dookun et al. 2000;Péros et al. 1994;Stead 1989;Vauterin et al. 1992Vauterin et al. , 1995. Vauterin and colleagues distinguish type-A strains from type-B by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of proteins, gas chromatography of fatty acid methyl esters and DNA-DNA hybridization (Yang et al. 1993). Type-A and type-B strains can also be distinguished by PCR-restriction fragment length polymorphism analysis (Destéfano et al. 2003 The names X. vasicola and X. vasicola pv. holcicola are listed in the Comprehensive List of Names of Plant Pathogenic Bacteria Young et al. 1996). However, as pointed out in Bergey's Manual (Brenner and Staley 2005), the name [X. vasicola pv. vasculorum] (Vauterin et al. 1995) was excluded from the Names of Plant Pathogenic Bacteria 1864 _ 1995 (Young et al. 1996) on the grounds that it was defective in terms of the Standards (Young et al. 2001). Specifically, it lacked a modern description differentiating it from other pathovars (Young et al. 2004) and lacked designation of a pathotype strain (Young et al. 1996). This is understandable given that Vauterin and colleagues were primarily concerned with species-level reclassification of the genus rather than focusing on individual pathovars. Although the name [X. vasicola pv. vasculorum] (Vauterin et al. 1995) is invalid, this name has come to be understood by the community to represent a meaningful biological grouping; that is, a set of X. campestris pv. vasculorum strains that are biochemically and phylogenetically similar to X. vasicola and pathogenically distinct. Therefore, we propose a formal description of X. vasicola pv. vasculorum pv. nov. that adheres to the Standards (Young et al. 2001), to harmonize the formal nomenclature with that which is in common use.
Adoption of competing classifications and invalid names has led to the potentially confusing use of three different valid species names (X. campestris, X. axonopodis, and X. vasicola) to describe this group of bacteria in the literature.  Wasukira et al. 2014). Type-B strains NCPPB 1326, NCPPB 702, and NCPPB 206 were erroneously described as X. axonopodis pv. vasculorum (Lewis Ivey et al. 2010) though they are clearly members of X. vasicola. We acknowledge that our taxonomic proposals will likely not eliminate mistakes such as these.
A further source of confusion is the status of strains isolated from maize for which some authors use the invalid name [X. campestris pv. zeae] (Coutinho and Wallis 1991;Qhobela et al. 1990). A useful nomenclature for this group has become more pressing since the recent outbreak of leaf streak on corn in the United States, caused by bacteria very closely related to strains previously described as [X. campestris pv. zeae]. One of these strains, NCPPB 4614 (=SAM119), was suggested to be the eventual pathotype strain of X. vasicola pv. vasculorum though no formal proposal and description was made (Korus et al. 2017;Lang et al. 2017). We concur with the previous suggestion ) that strains classified to [X. vasicola pv. vasculorum] and [X. campestris pv. zeae] (Vauterin et al. 1995) are insufficiently distinct to warrant separate pathovars and therefore strains previously named [X. campestris pv. zeae] are assigned into the newly described X. vasicola pv. vasculorum pv. nov.
Draft or complete sequence assemblies are now available for more than a thousand Xanthomonas genomes, including those of type strains for most species and pathotypes for most pathovars. Genomic sequences can offer some advantages for phylogeny and taxonomy, such as generally applicable threshold values for species delineation (Glaeser and Kämpfer 2015;Meier-Kolthoff et al. 2013Richter and Rosselló-Móra 2009). We calculated pairwise average nucleotide identity (ANI) between representative Xanthomonas strains, including all available species type strains and relevant pathotype strains and tabulated these in Figure 1.
The high ANI levels ( Fig. 1) clearly delineate a species that includes the type strain of X. vasicola (i.e., NCPPB 2417). It has been proposed that the boundary of a prokaryotic species can be delimited by 95 to 96% ANI (Richter and Rosselló-Móra 2009). By this criterion, X. campestris pv. arecae, X. campestris pv. musacearum, and [X. vasicola pv. zeae] clearly fall within X. vasicola and outside X. campestris. The next-nearest species to X. vasicola is X. oryzae; ANI between the respective type strains of these two species is 91.7%.
Despite the usefulness of ANI for delimiting species boundaries, it does not include any model of molecular evolution and thus is unsuited for phylogenetic reconstruction. Therefore, we used  Lang et al. 2017;Potnis et al. 2011;Sanko et al. 2018;Studholme et al. 2010;Vicente et al. 2017;Wasukira et al. 2014Wasukira et al. , 2012. Type strains are indicated by T. Pathotype strains that are not also type strains are indicated by PT. Strain NCPPB 4614 (=SAM119) was previously proposed as a member of [X. campestris pv. zeae] and also as the pathotype for [X. vasicola pv. vasculorum] and is indicated with an asterisk.
RaxML via the RealPhy pipeline (Bertels et al. 2014;Stamatakis et al. 2005) to elucidate phylogenetic relationships, using a maximum-likelihood method based on genome-wide sequencing data. This approach has the additional advantage of being based on sequence reads rather than on genome assemblies, where the latter may be of variable quality and completeness (Bertels et al. 2014). Figure 2 depicts the phylogeny of X. vasicola based on RealPhy analysis of genome-wide sequence data. Pathovars X. vasicola pv. holcicola and X. campestris pv. musacearum are monophyletic, comprising well supported clades within the X. vasicola species. A third well supported clade includes the four Xanthomonas strains originating from the grass Tripsacum laxum. A fourth clade consists of mostly X. campestris pv. vasculorum strains isolated from sugarcane but also includes X. campestris pv. vasculorum strain NCPPB 206 isolated from maize and several strains from maize attributed previously named [X. campestris pv. zeae]. The sequenced strains of [X. campestris pv. zeae] from corn (Coutinho and Wallis 1991;Lang et al. 2017;Qhobela et al. 1990;Sanko et al. 2018) are monophyletic and fall within the clade containing type-B strains of X. campestris pv. vasculorum (Fig. 2). The single sequenced strain of X. campestris pv. arecae is the pathotype and it falls immediately adjacent to the X. vasicola clade containing strains from corn and X. campestris pv. vasculorum type-B strains (Fig. 2).
Strain NCPPB 206 of X. campestris pv. vasculorum was isolated from maize, in contrast to most strains of this pathovar being isolated from sugarcane. On the basis of phylogenetic analysis of DNA sequence, this strain clearly falls within X. vasicola (Wasukira et al. 2014) and has the fatty-acid type characteristic of X. vasicola (Dookun et al. 2000). However, it is phylogenetically distinct from the strains of [X. campestris pv. zeae], as illustrated in Figures 1 and  2. This indicates that natural infection of maize by X. vasicola is not restricted to strains of [X. campestris pv. zeae].
Overall, our molecular sequence analyses strongly point to the existence of a phylogenetically coherent species, X. vasicola Vauterin 1995, that includes strains previously assigned to X. campestris pathovars musacearum and arecae, some strains of X. campestris pv. vasculorum, and strains collected from corn and Tripsacum laxum grass that have not been previously assigned to species nor pathovar. Here we propose that the pathovar X. vasicola pv. vasculorum pv. nov. includes strains formerly classified as X. campestris pv. vasculorum but distinguishable from X. axonopodis pv. vasculorum (Cobb) Vauterin, Hoste, Kersters & Swings by protein SDS-PAGE, FAME analysis, and DNA hybridization (Vauterin et al. 1992(Vauterin et al. , 1995Yang et al. 1993). Our analyses also support the transfer of X. campestris pv. arecae (Rao and Mohan 1970) Dye 1978 to X. vasicola. Although only a single genome of this pathovar has been sequenced, fortunately that genome belongs to the pathotype strain of the pathovar Rao and Mohan 1970).
Our results are consistent with previous evidence for similarity between X. campestris pv. musacearum and strains of X. vasicola, based on FAME, genomic fingerprinting with rep-PCR, and gyrB sequencing Parkinson et al. 2007). The formal species description for X. vasicola Vauterin 1995 states that this species can be clearly distinguished by its FAME profiles (Vauterin et al. 1995). Pathogenicity studies demonstrated phenotypic distinctiveness of X. campestris pv. musacearum (Yirgou and Bradbury 1968) Dye 1978 on banana; X. campestris pv. musacearum produces severe disease on this host, whereas X. vasicola pv. holcicola NCPPB 2417 and X. campestris pv. vasculorum NCPPB 702 (which belongs to X. vasicola) induced no symptoms ). The species description (Vauterin et al. 1995) also states that X. vasicola is characterized by metabolic activity on the carbon substrates D-psicose and L-glutamic acid, and by a lack of metabolic activity on a range of carbon substrates (further detailed in the emended description). We are not aware that these metabolic activities have been tested for X. campestris pv. arecae, X. campestris pv. musacearum, and [X. campestris pv. zeae]; it is possible that the species description may need to be amended to Fig. 2. Maximum-likelihood phylogenetic tree based on genomic sequencing reads. The maximum likelihood tree was generated using RealPhy (Bertels et al. 2014) and RaxML (Stamatakis et al. 2005). Bootstrap values are expressed as percentages of 500 trials. Type and pathotype strains are indicated by T and PT, respectively. Whole-genome shotgun sequence reads were obtained from the Sequence Read Archive (Leinonen et al. 2011) via BioProjects PRJNA73853, PRJNA163305, PRJNA163307, PRJNA31213, PRJNA374510, PRJNA374557, PRJNA439013, PRJNA439327, PRJNA439328, PRJNA439329, and PRJNA449864 Sanko et al. 2018;Wasukira et al. 2014Wasukira et al. , 2012. The cartoon images denote typical host plants from which each clade of bacteria have been typically isolated. Xanthomonas vasicola pv. holcicola strain NCPPB 989 was isolated from velvet grass (Holcus sp.), while strains NCPPB 1060, NCPPB 1241, and NCPPB 2417 were isolated from sorghum (Sorghum vulgare). Strains of X. campestris pv. musacearum were isolated from banana (Musa spp.) except for NCPPB 2005, which was isolated from enset (Ensete ventricosum). Strains of X. campestris pv. zeae were isolated from maize (Zea mays), as was X. campestris pv. vasculorum NCPPB 206. The remaining X. campestris pv. vasculorum strains were isolated from sugarcane (Saccharum spp.). The pathotype strain of X. campestris pv. arecae, namely NCPPB 2649, was isolated from betel palm (Areca catechu).
accommodate any deviation from this definition among the repositioned pathovars.
Overall, it seems that the species X. vasicola (including X. vasicola pv. holcicola, X. campestris pv. vasculorum type-B strains, [X. campestris pv. zeae] strains, X. campestris pv. arecae, and some strains isolated from T. laxum) is almost exclusively associated with monocot plants of the families Palmae and Gramineae. In this respect, it is similar to its closest sibling species X. oryzae, whose host range is limited to Gramineae (Bradbury 1986). The exception is a report of leaf blight and dieback in Eucalyptus caused by X. vasicola (Coutinho et al. 2015), remarkable given the phylogenetic distance between this dicot plant and the usual monocot hosts of X. vasicola; the infected South African plantation was in an area where sugarcane is grown. Vauterin et al. (1995) designated the pathotype strain of X. vasicola pv. holcicola (LMG 736, NCPPB 2417, ICMP 3103, andCFBP 2543) as the type strain of X. vasicola, although they did not use the pathovar epithet for the specific epithet of the species as is most appropriate to indicate this relationship. The natural host range of X. vasicola pv. holcicola includes the cereal crops millet and sorghum on which it causes bacterial leaf streak (Table 2) as well as wild grass belonging to the genus Holcus. The host range of the strains that Vauterin et al. (1995) called [X. vasicola pv. vasculorum] is less well defined because in most of the relevant pre-1995 literature it is impossible to distinguish between type-A and type-B of X. campestris pv. vasculorum and therefore between X. axonopodis pv. vasculorum and strains belonging to X. vasicola. However, X. campestris pv. vasculorum type-B strains (that is, members of X. vasicola) have been isolated from sugarcane and maize and shown to infect these hosts on artificial inoculation (Karamura et al. 2015;Vauterin et al. 1995).
In conclusion, analysis of available genome sequence data, combined with published pathogenicity and biochemical data, strongly supports the transfer of the X. campestris pathovars musacearum and arecae to the species X. vasicola as, respectively, (i) X. vasicola pv. musacearum comb. nov. with NCPPB 2005 as the pathotype strain (being the type strain of X. musacearum Yirgou & Bradbury and pathotype strain of X. campestris pv. musacearum) and (ii) X. vasicola pv. arecae comb. nov. with NCPPB 2649 as the pathotype strain (being the type strain of X. arecae Rao & Mohan and pathotype strain of X. campestris pv. arecae). Strains NCPPB 206, NCPPB 702, NCPPB 795, NCPPB 890, NCPPB 895, NCPPB 1326, NCPPB 1381, and NCPPB 4614 form a phylogenetically and phenotypically coherent group with a distinctive host range causing symptoms on maize and sugarcane but not on banana Karamura et al. 2015) that falls within X. vasicola pv. vasculorum pv. nov. The strains isolated from T. laxum are also clearly within the phylogenetic bounds of X. vasicola and form a distinct clade but cannot be assigned to any pathovar. The previous proposal of [X. vasicola pv. vasculorum] was invalid due in part to the lack of a designated pathotype strain (Vauterin et al. 1995). We designate NCPPB 4614 as the pathotype strain for this pathovar, following the previous suggestion by Lang et al. (2017). This strain was previously proposed as the pathotype of [X. vasicola pv. vasculorum] ) and causes disease symptoms on maize and sugarcane  but not on banana None Areca catechu (Bradbury 1986;Kumar 1993Kumar , 1983 Cocos nucifera, Saccharum sp. (Bradbury 1986 Tripsacum laxum (Mulder 1961), Vetiveria zizanoides (Kumar 1983(Kumar , 1993 Not known ( Supplementary Fig. S1). Furthermore, given that strains from corn formerly described by the invalid name [X. campestris pv. zeae] are members of X. vasicola and have host ranges that cannot be distinguished from the pathotype strain of X. vasicola pv. vasculorum pv. nov., we propose that these strains are members of this pathovar. Phylogenetic data support this as the corn strains represent a subclade within strains of X. campestris pv. vasculorum that fall within the emended X. vasicola.
EMENDED DESCRIPTION OF X. VASICOLA VAUTERIN ET AL. 1995 The characteristics are as described for the genus and the species (Vauterin et al. 1995) extended with phylogenetic data from this study. The species can be clearly distinguished from other xanthomonads by multilocus sequence analysis (MLSA) and whole genome sequence analysis with members having more than 98% ANI with the type strain. SDS-PAGE protein and FAME profiles have been shown to be distinguishing for some pathovars Vauterin et al. 1992;Yang et al. 1993) by the presence of metabolic activity on the carbon substrates D-psicose and Lglutamic acid, and by a lack of metabolic activity on the carbon substrates N-acetyl-D-galactosamine, L-arabinose, a-D-lactose, Dmelibiose, P-methyl-D-glucoside, L-rhamnose, D-sorbitol, formic add, D-galactonic acid lactone, D-galacturonic acid, D-gluconic acid, D-glucuronic acid, p-hydroxyphenylacetic acid, a-ketovaleric acid, quinic acid, glucuronamide, L-asparagine, L-histidine, Lphenylalanine, urocanic acid, inosine, uridine, thymidine, DL-aglycerol phosphate, glucose 1-phosphate, and glucose 6-phosphate. The G+C content is between 63.1 and 63.6 mol% as calculated from whole-genome sequence data. The type strain is X. vasicola pv. holcicola LMG 736 (= CFBP 2543 = ICMP 3103 = NCPPB 2417).
X. vasicola pv. vasculorum pv. nov. Description as for the species and this pathovar is distinguished on the basis of phytopathogenic specialization and includes the strains of the former taxon X. campestris pv. vasculorum type B and pathogens from corn. The pathovar is identified to species and distinguished from other pathovars by its gyrB gene sequence (Parkinson et al. 2009) and genome-wide sequence analysis. It is not known whether the strains being transferred to this taxon conform to the species description for metabolic activity. According to previously published work Coutinho et al. 2015;Hayward 1962;Karamura et al. 2015), the natural host range includes Saccharum spp., Zea mays, and Eucalyptus grandis and does not cause symptoms on banana.
Pathotype strain: NCPPB 4614 (= CFBP 8549 = SAM119). Description as for the species and this pathovar is distinguished on the basis of phytopathogenic specialization. The pathovar is identified to species and distinguished from other pathovars by its gyrB gene sequence (Parkinson et al. 2009) and by genome-wide sequence analysis. According to Bradbury (1986), the natural host range includes Areca catechu (areca nut). Bradbury (1986) reports the artificial host range to include Cocos nucifera (coconut). Needle prick into sugar cane produced limited streaks, but the bacteria did multiply to some extent and could be reisolated. Disease: leaf stripe. Long, narrow water-soaked lesions, becoming dark brown or black with age. It is not known if the strains being transferred to this taxon conform to the species description for metabolic activity.
X. vasicola pv. musacearum (Yirgou & Bradbury) Dye 1978 comb. nov. =X. campestris pv. musacearum (Yirgou & Bradbury) Dye 1978. Description as for the species and this pathovar is identified to species and distinguished on the basis of phytopathogenic specialization and is distinct from other pathovars by its gyrB gene sequence (Parkinson et al. 2009) and genome-wide sequence analysis. Gelatin slowly liquefied, starch not hydrolyzed. Growth quite rapid and very mucoid when cultured on yeastpeptone-sucrose agar based media for 48 h at 28°C. According to Bradbury (1986), the natural hosts include Ensete ventricosum (enset) and Musa spp. (banana). Additional hosts by inoculation: Saccharum sp. (sugarcane) and Zea mays (maize) and disease is exhibited as a bacterial wilt where leaves wilt and wither; yellowish bacterial masses are found in vascular tissue and parenchyma. It is not known if the strains being transferred to this taxon conform to the species description for metabolic activity.