Complete mitochondrial genome of the Verticillium-wilt causing plant pathogen Verticillium nonalfalfae

Verticillium nonalfalfae is a fungal plant pathogen that causes wilt disease by colonizing the vascular tissues of host plants. The disease induced by hop isolates of V. nonalfalfae manifests in two different forms, ranging from mild symptoms to complete plant dieback, caused by mild and lethal pathotypes, respectively. Pathogenicity variations between the causal strains have been attributed to differences in genomic sequences and perhaps also to differences in their mitochondrial genomes. We used data from our recent Illumina NGS-based project of genome sequencing V. nonalfalfae to study the mitochondrial genomes of its different strains. The aim of the research was to prepare a V. nonalfalfae reference mitochondrial genome and to determine its phylogenetic placement in the fungal kingdom. The resulting 26,139 bp circular DNA molecule contains a full complement of the 14 "standard" fungal mitochondrial protein-coding genes of the electron transport chain and ATP synthase subunits, together with a small rRNA subunit, a large rRNA subunit, which contains ribosomal protein S3 encoded within a type IA-intron and 26 tRNAs. Phylogenetic analysis of this mitochondrial genome placed it in the Verticillium spp. lineage in the Glomerellales group, which is also supported by previous phylogenetic studies based on nuclear markers. The clustering with the closely related Verticillium dahliae mitochondrial genome showed a very conserved synteny and a high sequence similarity. Two distinguishing mitochondrial genome features were also found—a potential long non-coding RNA (orf414) contained only in the Verticillium spp. of the fungal kingdom, and a specific fragment length polymorphism observed only in V. dahliae and V. nubilum of all the Verticillium spp., thus showing potential as a species specific biomarker.     

Application of RAPD-PCR for Virulence Type Analysis within Verticillium dahliae and V. longisporum

A collection of 24 isolates of Verticillium dahliae, 11 isolates of V. longisporum and one isolate of V. albo‐atrum originating from different host plants and geographical regions was tested for genetic variability by random amplified polymorphic DNA‐polymerase chain reaction (RAPD–PCR). Based on nine primers, the three Verticillium species could be clearly differentiated. Likewise, this analysis provided a distinct separation of vegetative compatibility groups (VCG) 2B, 4A and 4B of V. dahliae by specific DNA banding patterns. Additionally, V. longisporum was found to segregate into two subgroups with only 88% similarity. This molecular‐genetic approach was used for the analysis of randomly selected Verticillium isolates from a field with high intensity of oilseed rape cultivation (33% in crop rotation). RAPD‐PCR analysis revealed that 95 of 100 isolates tested belonged to V. longisporum and 5 to VCG 2B of V. dahliae. This study demonstrates an adaptation of Verticillium soil populations to a specific cropping history.     

Vibrio cholerae Serogroup O139: Isolation from Cholera Patients and Asymptomatic Household Family Members in Bangladesh between 2013 and 2014

Background

Cholera is endemic in Bangladesh, with outbreaks reported annually. Currently, the majority of epidemic cholera reported globally is El Tor biotype Vibrio cholerae isolates of the serogroup O1. However, in Bangladesh, outbreaks attributed to V. cholerae serogroup O139 isolates, which fall within the same phylogenetic lineage as the O1 serogroup isolates, were seen between 1992 and 1993 and in 2002 to 2005. Since then, V. cholerae serogroup O139 has only been sporadically isolated in Bangladesh and is now rarely isolated elsewhere.

Methods

Here, we present case histories of four cholera patients infected with V. cholerae serogroup O139 in 2013 and 2014 in Bangladesh. We comprehensively typed these isolates using conventional approaches, as well as by whole genome sequencing. Phenotypic typing and PCR confirmed all four isolates belonging to the O139 serogroup.

Findings

Whole genome sequencing revealed that three of the isolates were phylogenetically closely related to previously sequenced El Tor biotype, pandemic 7, toxigenic V. cholerae O139 isolates originating from Bangladesh and elsewhere. The fourth isolate was a non-toxigenic V. cholerae that, by conventional approaches, typed as O139 serogroup but was genetically divergent from previously sequenced pandemic 7 V. cholerae lineages belonging to the O139 or O1 serogroups.

Conclusion

These results suggest that previously observed lineages of V. cholerae O139 persist in Bangladesh and can cause clinical disease and that a novel disease-causing non-toxigenic O139 isolate also occurs.     

Characterization of a Novel Cotton Subtilase Gene GbSBT1 in Response to Extracellular Stimulations and Its Role in Verticillium Resistance

Verticillium wilt is a disastrous vascular disease in plants caused by Verticillium dahliae. Verticillium pathogens secrete various disease-causing effectors in cotton. This study identified a subtilase gene GbSBT1 from Gossypium babardense and investigated the roles against V. dahliae infection. GbSBT1 gene expression is responsive to V. dahliae defense signals, jasmonic acid, and ethylene treatments. Moreover, the GbSBT1 protein is mainly localized in the cell membrane and moves into the cytoplasm following jasmonic acid and ethylene treatments. Silencing GbSBT1 gene expression through virus-induced GbSBT1 gene silencing reduced the tolerance of Pima-90 (resistant genotype), but not facilitated the infection process of V. dahliae in Coker-312 (sensitive genotype). Moreover, the ectopically expressed GbSBT1 gene enhanced the resistance of Arabidopsis to Fusarium oxysporum and V. dahliae infection and activated the expression levels of defense-related genes. Furthermore, pull-down, yeast two-hybrid assay, and BiFC analysis revealed that GbSBT1 interacts with a prohibitin (PHB)-like protein expressed in V. dahliae pathogens during infection. In summary, GbSBT1 recognizes the effector PHB protein secreted from V. dahliae and is involved in Verticillium-induced resistance in cotton.     

First report of <Emphasis Type="Italic">Verticillium tricorpus</Emphasis> isolated from potato tubers in Japan

In 1998, Verticillium sp. (CE98Vt1 and CE98Vt2) were isolated from discolored vascular structures of potato tubers sold at a market in Chiba Prefecture. These isolates were identified as Verticillium tricorpus on the basis of cultural and morphological characteristics and PCR diagnosis. This observed vascular discoloration of the potato tuber was demonstrated in three cultivars (Touya, Toyoshiro, and Waseshiro) among eight cultivars by inoculation to seedlings. External and internal symptoms of these isolates were not distinct in potato plants. The virulence of these isolates to potato was very low as compared with Verticillium dahliae. These two isolates were not pathogenic to Chinese cabbage, eggplant, green pepper, larkspur, parsley, snapdragon, soybean, tobacco, and tomato. This is the first report of V. tricorpus from potato in Japan.     

Evaluation in Cameroon of a Novel,Simplified Methodology to Assist Molecular Microbiological Analysis of V. cholerae in Resource-Limited Settings

BackgroundVibrio cholerae is endemic in South Asia and Africa where outbreaks of cholera occur widely and are particularly associated with poverty and poor sanitation. Knowledge of the genetic diversity of toxigenic V. cholerae isolates, particularly in Africa, remains scarce. The constraints in improving this understanding is not only the lack of regular cholera disease surveillance, but also the lack of laboratory capabilities in endemic countries to preserve, store and ship isolates in a timely manner. We evaluated the use of simplified sample preservation methods for molecular characterization using multi-locus variable-number tandem-repeat analysis (MLVA) for differentiation of Vibrio cholerae genotypes.ConclusionsCollecting V. cholerae using simplified laboratory methods in remote and low-resource settings allows for subsequent advanced molecular characterization of V. cholerae O1. These simplified DNA preservation methods identify V. cholerae and make possible timely information regarding the genetic diversity of V. cholerae; our results set the stage for continued molecular epidemiological research to better understand the transmission and dissemination of V. cholerae in Africa and elsewhere worldwide.     

Advanced Microbial Taxonomy Combined with Genome-Based-Approaches Reveals that Vibrio astriarenae sp. nov., an Agarolytic Marine Bacterium,Forms a New Clade in Vibrionaceae

Advances in genomic microbial taxonomy have opened the way to create a more universal and transparent concept of species but is still in a transitional stage towards becoming a defining robust criteria for describing new microbial species with minimum features obtained using both genome and classical polyphasic taxonomies. Here we performed advanced microbial taxonomies combined with both genome-based and classical approaches for new agarolytic vibrio isolates to describe not only a novel Vibrio species but also a member of a new Vibrio clade. Two novel vibrio strains (Vibrio astriarenae sp. nov. C7^T and C20) showing agarolytic, halophilic and fermentative metabolic activity were isolated from a seawater sample collected in a coral reef in Okinawa. Intraspecific similarities of the isolates were identical in both sequences on the 16S rRNA and pyrH genes, but the closest relatives on the molecular phylogenetic trees on the basis of 16S rRNA and pyrH gene sequences were V. hangzhouensis JCM 15146^T (97.8% similarity) and V. agarivorans CECT 5085^T (97.3% similarity), respectively. Further multilocus sequence analysis (MLSA) on the basis of 8 protein coding genes (ftsZ, gapA, gyrB, mreB, pyrH, recA, rpoA, and topA) obtained by the genome sequences clearly showed the V. astriarenae strain C7^T and C20 formed a distinct new clade protruded next to V. agarivorans CECT 5085^T. The singleton V. agarivorans has never been included in previous MLSA of Vibrionaceae due to the lack of some gene sequences. Now the gene sequences are completed and analysis of 100 taxa in total provided a clear picture describing the association of V. agarivorans into pre-existing concatenated network tree and concluded its relationship to our vibrio strains. Experimental DNA-DNA hybridization (DDH) data showed that the strains C7^T and C20 were conspecific but were separated from all of the other Vibrio species related on the basis of both 16S rRNA and pyrH gene phylogenies (e.g., V. agarivorans CECT 5085^T, V. hangzhouensis JCM 15146^T V. maritimus LMG 25439^T, and V. variabilis LMG 25438^T). In silico DDH data also supported the genomic relationship. The strains C7^T also had less than 95% average amino acid identity (AAI) and average nucleotide identity (ANI) towards V. maritimus C210, V. variabilis C206, and V. mediterranei AK1^T, V. brasiliensis LMG 20546^T, V. orientalis ATCC 33934^T, and V. sinaloensis DSM 21326. The name Vibrio astriarenae sp. nov. is proposed with C7 as the type strains. Both V. agarivorans CECT 5058^T and V. astriarenae C7^T are members of the newest clade of Vibrionaceae named Agarivorans.     

Genetic diversity of Vicia faba L. and Pisum sativum L. nodulating rhizobia in the central Black Sea region of Turkey

In this study, we obtained a total of 60 rhizobial isolates from root nodules of Vicia faba L. (n = 30) and Pisum sativum L. (n = 30) grown in the Central Black Sea region of Turkey. The 16S rDNA PCR-RFLP analysis with enzymes CfoI, HinfI, NdeII and MspI revealed a single pattern. Moreover, nucleotide sequence phylogenies based on both the 16S rDNA and recA suggested that these isolates belonged to Rhizobium leguminosarum. Phylogenetic analysis showed that some of our V. faba L.-originated isolates were closely related, indicating molecular evidence for the selection of some special R. leguminosarum bv. viciae isolates by V. faba L., as suggested in previous studies. Network analysis based on recA sequences revealed a common evolutionary history for Turkish, European, North and South American, and Jordanian R. leguminosarum bv. viciae isolates. We isolated four haplotypes using nodA and nifH nucleotide sequence data, i.e. four types of sym plasmids. Two of these types were common to rhizobial isolates from both V. faba L. and P. sativum L., indicating that nodulation factors may not be the mechanism for selection of the special R. leguminosarum bv. viciae populations by V. faba L.     

Maintenance of Sex-Related Genes and the Co-Occurrence of Both Mating Types in Verticillium dahliae

Verticillium dahliae is a cosmopolitan, soilborne fungus that causes a significant wilt disease on a wide variety of plant hosts including economically important crops, ornamentals, and timber species. Clonal expansion through asexual reproduction plays a vital role in recurring plant epidemics caused by this pathogen. The recent discovery of recombination between clonal lineages and preliminary investigations of the meiotic gene inventory of V. dahliae suggest that cryptic sex appears to be rare in this species. Here we expanded on previous findings on the sexual nature of V. dahliae. Only 1% of isolates in a global collection of 1120 phytopathogenic V. dahliae isolates contained the MAT1-1 idiomorph, whereas 99% contained MAT1-2. Nine unique multilocus microsatellite types comprised isolates of both mating types, eight of which were collected from the same substrate at the same time. Orthologs of 88 previously characterized sex-related genes from fungal model systems in the Ascoymycota were identified in the genome of V. dahliae, out of 93 genes investigated. Results of RT-PCR experiments using both mating types revealed that 10 arbitrarily chosen sex-related genes, including MAT1-1-1 and MAT1-2-1, were constitutively expressed in V. dahliae cultures grown under laboratory conditions. Ratios of non-synonymous (amino-acid altering) to synonymous (silent) substitutions in V. dahliae MAT1-1-1 and MAT1-2-1 sequences were indistinguishable from the ratios observed in the MAT genes of sexual fungi in the Pezizomycotina. Patterns consistent with strong purifying selection were also observed in 18 other arbitrarily chosen V. dahliae sex-related genes, relative to the patterns in orthologs from fungi with known sexual stages. This study builds upon recent findings from other laboratories and mounts further evidence for an ancestral or cryptic sexual stage in V. dahliae.     

Molecular Characterization of the Host-Adapted Pathogen Verticillium longisporum on the Basis of a Group-I Intron Found in the Nuclear SSU-rRNA Gene

Verticillium wilt of oilseed rape is caused by the host-adapted pathogen Verticillium longisporum comb. nov. With one set of nuclear SSU-rRNA gene primers, a PCR amplification product of ca. 2.5 kb was generated from all isolates of V. longisporum tested (36 from Europe, Japan, and USA), with the exception of two recombinant isolates. On the contrary, all the other phytopathogenic and non-phytopathogenic species of Verticillium tested (18 species, 46 isolates), with the exception of one isolate of V. lecanii and two of Cordyceps sp., generated a product of ca. 1.65 kb. Sequence analysis of the SSU-rRNA gene of two typical isolates of V. longisporum (wild radish, Japan, and oilseed rape, Germany) revealed that this dimorphism was due to the presence of an identical 839-bp intron located in a highly conserved insertion position (nt 1165 of Saccharomyces cerevisiae). The intron sequence was classified as group-I intron on the basis of conserved sequence and secondary structural elements. Primers designed from the 839-bp intron sequence amplified only the V. longisporum. Phylogenetic analysis based on SSU-rDNA sequences showed that V. longisporum was closely related to the genera of other filamentous Ascomycetes with fruiting bodies. Received: 24 August 2000 / Accepted: 25 September 2000     

Investigations into the taxonomy of the mushroom pathogen <Emphasis Type="Italic">Verticillium fungicola</Emphasis> and its relatives based on sequence analysis of nitrate reductase and ITS regions

The full sequence of the nitrate reductase gene was obtained from a type isolate of Verticillium fungicola var. fungicola and used for phylogenetic analysis against other ascomycete fungi. Sequencing obtained 2749 bp of coding region, 668 bp of 5′ flanking sequence and 731 bp of 3′ flanking sequence. In silico analysis indicated that the coding region contains a single intron and translates into an 893 amino acid protein, with BLAST analysis identifying five conserved nitrate reductase domains within the protein. The 5′ flanking sequence contains numerous conserved sites putatively involved in binding nitrogen regulatory proteins, indicating that the regulation of the gene is likely to be subject to the same regulation as that of model fungi such as Aspergillus nidulans. The central portion of this gene was amplified and sequenced from a number of V. fungicola isolates and related fungi and the resulting phylogenies compared to those obtained from analysis of the rDNA internal transcribed spacer regions for these fungi. Both nitrate reductase and ITS analyses provide additional evidence that reinforces previous findings that suggest the mushroom pathogenic Verticillium species are more related to other chitinolytic fungi such as the insect pathogens Verticillium lecanii and Beauveria bassiana than to the plant pathogenic Verticillia.     

Transfer of fungal tolerance through interspecific somatic hybridisation between Solanum melongena and S. torvum

Tolerance to Verticillium wilt is found in a wild relative of eggplant, Solanum torvum. To transfer this tolerance to eggplant (S. melongena), protoplast fusions between eggplant and irradiated S. torvum protoplasts were performed. Putative hybrids were regenerated and evaluated for Verticillium tolerance and field value. A total of 12 plants were eventually selected to be incorporated into the breeding program, as they showed a high degree of Verticillium tolerance under field conditions combined with the morphological characters of eggplant, including normal seed set. DNA analysis showed one of these tolerant plants to have a changed pattern, with some changes corresponding to specific pattern characteristics of S. torvum. Received: 12 April 1998 / Revision received: 9 September 1998 / Accepted: 29 November 1998     

Characterisation of New Zealand Fusarium populations using a polyphasic approach differentiates the F. avenaceum/F. acuminatum/F. tricinctum species complex in cereal and grassland systems

The purpose of this study was to determine the diversity and prevalence of Fusarium species in a survey of cereal and grassland systems from the South Island of New Zealand by applying morphological and molecular techniques. Isolates were collected from soil, roots, and stems from 21 cereal and grassland sites. Ten Fusarium species were identified using morphological characters, including F. acuminatum, F. avenaceum, F. crookwellense, F. culmorum, F. equiseti, F. oxysporum, F. poae, F. pseudograminearum, F. sambucinum, and F. tricinctum. In general, their distribution was found to be unrelated to biogeographical location, although agricultural practice increased the overall diversity of Fusarium. Phylogenetic analyses were successfully used to identify morphologically similar isolates belonging to the F. avenaceum/F. acuminatum/F. tricinctum species complex and to resolve previously undetermined relationships amongst these species. Fifty-eight isolates classified as either F. avenaceum, F. acuminatum, or other closely related species as well as several well-characterised isolates from international culture collections were examined using DNA sequence data for β-tubulin (βTUB), translation elongation factor 1α (EF1α), and mitochondrial small subunit ribosomal RNA (mtSSU). Analyses of DNA sequence data from both βTUB and EF1α discriminated among isolates of F. avenaceum, F. acuminatum, and F. tricinctum and determined that these three distinct sequence groups formed a single clade. By contrast, mtSSU was unable to differentiate F. avenaceum from F. acuminatum and other closely related species believed to be F. tricinctum. Comparison of the EF1α sequences with the international FUSARIUM-ID database supported the identification of isolates in this study. As in other studies, F. avenaceum was found to be widespread in agricultural and native ecosystems. However, F. acuminatum in New Zealand was found only on non-wheat hosts. The reason for the absence of this wheat pathogen in cereal-based ecosystems in New Zealand remains unknown.     

Genetic and phenotypic analyses of Pythium isolates from reed suggest the occurrence of a new species,P. phragmiticola,and its involvement in the generation of a natural hybrid

A set of isolates closely related to the reed pathogen Pythium phragmitis was found among Pythium strains obtained from reed (Phragmites australis) soil and plant samples in Germany and Switzerland. These isolates consistently differed from P. phragmitis at 6, 6 and 3 nucleotide positions in the rDNA internal transcribed spacer region, the β-tubulin, and the cytochrome oxidase II gene, respectively. They are formally described here as Pythium phragmiticola sp. nov. An analysis of phenotypic traits like oospore size, growth and aggressiveness to reed showed that P. phragmiticola is almost indiscernible from P. phragmitis, as most features assessed overlapped considerably between species. Phylogenetic analyses provided evidence that P. phragmiticola is the second parent of a previously described Pythium hybrid involving P. phragmitis. The alloploid status of the hybrid, and the parents' reproductive separation was confirmed by molecular evidence and the high ratios of aborted oospores. In natural environments there obviously are two species closely associated with reed, P. phragmitis and P. phragmiticola which are homothallic, but can outcross, resulting in sterile, vegetatively propagated interspecific hybrids. Driving forces leading to the radiation of these two species are unknown, but might be connected with divergent parasitic adaptation to different host tissues or species.     

Isolation of Bartonella henselae and Two New Bartonella Subspecies,Bartonella koehlerae Subspecies boulouisii subsp. nov. and Bartonella koehlerae Subspecies bothieri subsp. nov. from Free-Ranging Californian Mountain Lions and Bobcats

Domestic cats are the natural reservoir of Bartonella henselae, B. clarridgeiae and B. koehlerae. To determine the role of wild felids in the epidemiology of Bartonella infections, blood was collected from 14 free-ranging California mountain lions (Puma concolor) and 19 bobcats (Lynx rufus). Bartonella spp. were isolated from four (29%) mountain lions and seven (37%) bobcats. These isolates were characterized using growth characteristics, biochemical reactions, molecular techniques, including PCR-RFLP of selected genes or interspacer region, pulsed-field gel electrophoresis (PFGE), partial sequencing of several genes, and DNA-DNA hybridization. Two isolates were identical to B. henselae genotype II. All other isolates were distinguished from B. henselae and B. koehlerae by PCR-RFLP of the gltA gene using endonucleases HhaI, TaqI and AciI, with the latter two discriminating between the mountain lion and the bobcat isolates. These two novel isolates displayed specific PFGE profiles distinct from B. henselae, B. koehlerae and B. clarridgeiae. Sequences of amplified gene fragments from the three mountain lion and six bobcat isolates were closely related to, but distinct from, B. henselae and B. koehlerae. Finally, DNA-DNA hybridization studies demonstrated that the mountain lion and bobcat strains are most closely related to B. koehlerae. We propose naming the mountain lion isolates B. koehlerae subsp. boulouisii subsp. nov. (type strain: L-42-94), and the bobcat isolates B. koehlerae subsp. bothieri subsp. nov. (type strain: L-17-96), and to emend B. koehlerae as B. koehlerae subsp. koehlerae. The mode of transmission and the zoonotic potential of these new Bartonella subspecies remain to be determined.     

Azospirillum himalayense sp. nov., a nifH bacterium isolated from Himalayan valley soil,India

Gram-negative, free-living bacterial strain ptl-3^T was isolated from Himalayan valley soil, India. Polyphasic taxonomy was performed including morphological characterization, fatty acid analysis, biochemical tests, 16S rRNA and nifH gene sequence analyses. 16S rRNA gene sequence analysis showed that the strain ptl-3^T belonged to the genus Azospirillum and was closely related to A. brasilense (98.7 % similarity) and A. rugosum (97 % similarity). 16S rRNA gene sequence similarity (96–95 %) was shown with other members of the genus Azospirillum. Major fatty acid 18:1ω7c was also similar to the genus Azospirillum. DNA–DNA relatedness value between strain ptl-3^T and A. brasilense was found to be 47 %. Various biochemical tests showed that the strain ptl-3^T differed from its closely related species A. brasilense. On the basis of phenotypic, chemotaxonomic and molecular genetics evidence, a bacterium with the type strain ptl-3^T is proposed as a novel species of the genus Azospirillum. The name of bacterial strain ptl-3^T has been proposed as Azospirillum himalayense sp. nov. The type strain of ptl-3^T (CCUG 58760^T, KCTC 23189^T) has been submitted to two culture collection centres. The accession numbers for 16S rRNA and nifH gene are GQ 284588 and GQ 249665. respectively.     

Differentiation among the Vibrio cholerae serotypes O1, O139, O141 and non-O1, non-O139, non-O141 using specific monoclonal antibodies with dot blotting

Seven different monoclonal antibodies (MAbs) specific to only Vibrio cholerae were produced using a combination of five representative serotypes of V. cholerae for immunization. The first three MAbs (VC-93, VC-82 and VC-223) were specific to the V. cholerae serogroup O1 with different avidity for the serotypes O1 Inaba and O1 Ogawa. The fourth and the fifth MAbs were specific to V. cholerae O139 (VC-812) or O141 (VC-191) serogroups, respectively. The sixth MAb (VC-26) bound to all three serogroups of V. cholerae. The seventh MAb (VC-63) bound to all twenty five isolates of V. cholerae used in this study. None of the seven MAbs showed cross-reactivity with other Vibrio spp. or closely-related V. cholerae species, V. mimicus or other gram-negative bacteria. The eighth MAbs (VC-201) specific to almost all Vibrio spp. was also obtained. In dot blotting, these MAbs can be used to detect a diluted pure culture of V. cholerae in solution with a sensitivity range of from 10⁵ to 10⁷ CFU ml^− 1. However, the detection capability could be improved equivalent to that of PCR technique after preincubation of samples in alkaline peptone water (APW). Thus, these MAbs constitute convenient immunological tools that can be used for simple, rapid and simultaneous direct detection and differentiation of the individual serotypes of V. cholerae in complex samples, such as food and infected animals, without the requirement for bacterial isolation or biochemical characterization.