ABSTRACT
Anthracnose fruit rot affecting field peppers (Capsicum annuum L.) has been reported in Ontario, Canada, leading to significant crop losses of up to 80% over the past three years. Ten symptomatic fruits per field, exhibiting one or more soft, sunken lesions covered with salmon-colored spore masses (Fig. S1), were collected from one and two Banana pepper fields in August 2022 and 2023, respectively, all located in southwestern Ontario. Small sections of diseased tissue (0.5 cm in length) from lesion edges underwent surface sterilization and plated on 2% potato dextrose agar (PDA, Difco) supplemented with kanamycin (50 mg liter-1), neomycin sulfate (12 mg liter-1) and streptomycin sulfate (100 mg liter-1), and incubated at 22°C for 7 days in the dark. Fifteen fungal colonies were isolated and purified using the hyphal tipping method. All fungal isolates showed a pale gray colony morphology with a faint salmon tint on PDA (Fig. S1). Conidia, produced on PDA after incubating the 15 isolates at 22°C for 17 days in the dark, were hyaline, aseptate, smooth-walled, cylindrical with obtuse ends (Fig. S1), and measured 9.4 to 15.0 × 2.7 to 4.8 µm (mean ± standard deviation of 145 conidia = 11.3 ± 1.2 µm × 3.7 ± 0.5 µm), the typical morphology of Colletotrichum species (Damm et al. 2012). Internal transcribed spacer (ITS), actin (ACT), chitin synthase 1 (CHS-1), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), glutamine synthetase (GS), histone H3 (HIS3) and beta-tubulin 2 (TUB2) gene regions of all isolates were amplified and sequenced with primers ITS1/ITS4, ACT-512F/ACT-783R, CHS-79F/CHS-345R, GDF1/GDR1, GSF1/GSR1, CYLH3F/CYLH3R and Bt2a/Bt2b and deposited in GenBank (Accession Nos. ITS: PP060584 to PP060596; ACT, CHS-1, GAPDH, GS, HIS3 and TUB2: PP085919 to PP086005), respectively. The sequences were 100% identical to Colletotrichum scovillei strains from different hosts and countries (ITS: PP079643; ACT: MN718468; CHS-1: MN718466, GAPDH: MN718465.1, HIS3: MT592502, TUB2: MK462971). The maximum likelihood-based phylogenetic analysis of ITS, ACT, CHS-1, GAPDH, GS, HIS3, and TUB2 concatenated sequences was conducted using IQ-TREE 2.2.2.7 (Minh et al. 2020). All isolates from this study were grouped with high bootstrap support values with the holotype C. scovillei CBS 126529 (Fig. S2). Living cultures of these isolates were deposited in the Canadian Collection of Fungal Cultures (DAOMC 252833 to 252847). Pathogenicity was tested by inoculating 4 Banana (cv. Jumbo Stuff) and 4 Bell (cv. Archimedes) pepper fruits with 10 µl droplet of a 1 × 105 conidia ml-1 suspension of each isolate onto a wound made with a sterile pipette tip. Eight control fruits were mock-inoculated with sterilized water. Nine days post-inoculation, necrotic lesions measuring 24.7 ± 0.3 mm on Bell and 27.9 ± 0.2 mm on Banana peppers were observed. Colletotrichum scovillei was re-isolated from all symptomatic fruits, and its species identity was confirmed through morphology, fulfilling Koch's postulates. Control fruits remained symptom-free, and no fungi were isolated from them. This is the first report of C. scovillei in Canada. Previously identified as a pathogen causing anthracnose on peppers in eastern Asia, the United States, Brazil, and Kosovo (Farr and Rossman 2024; Xhemali et al. 2023), its emergence in Ontario raises significant concerns for pepper crops. Additional research is essential to better understand the epidemiology of the disease and develop effective phytosanitary strategies for control.
ABSTRACT
Apricot trees (Prunus armeniaca L.) with cankers, gummosi and dieback symptoms were observed in a commercial orchard in Niagara-on-the-Lake, Ontario, Canada. In October 2018, up to 44.9% disease incidence (n = 318) was observed on 2-year-old 'Harostar™' trees grafted onto 'Haggith' rootstocks. Fungal colonies were consistently isolated and purified from small sections of wood collected from canker margins of symptomatic trunk and shoot tissue, as described by Ilyukhin et al. (2023). Purified mycelial isolates sharing similar morphological characteristics were categorized into five distinct morphotypes. One representative isolate from each morphotype was used to inoculate excised apricot shoots as described by Ilyukhin and Ellouze (2023). One morphotype displayed necrotic lesions on the shoots consistently yielded abundant white aerial mycelium that turned grey-brown on PDA after 7 days (Figure S1) and produced black pycnidia three weeks following incubtion at 22°C in the dark. Conidia were hyaline, one-celled, fusiform, with dimensions of 19.7 - 24.2 × 3.6 - 4.8 µm (average 22.1 × 4.3 µm, n = 30), the typical morphology of a Neofusicoccum sp. (Crous et al. 2006). Species identification was verified by extracting genomic DNA of the representative isolate M1-105, amplifying and sequencing the internal transcribed spacer (ITS), translation elongation factor 1-α (EF1-α) and ß-tubulin (TUB2) gene regions with primers ITS1/ITS4, EF1-728F/EF1-986R and Bt2a/Bt2b. Nucleotide sequences (GenBank Accession No. ITS: OK287034; EF1-α: OK346636; TUB2: OK346633) have 100%, 99.61% and 99.55% identity with Neofusicoccum ribis isolates from different hosts and countries (MT587514, DQ235142, OL455952, respectively). Randomized accelerated maximum likelihood analysis (Stamatakis et al. 2008), using ITS, EF1-α and TUB2 sequence data, clustered M1-105 with the highest bootstrap support values with the N. ribis ex-epitype CBS 115475 (Figure S2). A living culture of M1-105 was deposited in the Canadian Collection of Fungal Cultures (DAOMC 252247). Pathogenicity was verified using 5 potted healthy 1-year-old 'Haroblush™' apricot cultivar grafted onto 'Krymsk® 86' rootstocks. Trunks and shoots were inoculated in a shallow wound made by a scalpel with mycelial plugs from a 5-day-old culture of M1-105. Five control trees were inoculated with sterile plugs. Trees were put in an open-air area and watered as needed. Canker symptoms appeared 7 days after inoculation, and spread above and below the inoculation point. Fifteen days post-inoculation, the upper portion of inoculated shoots showed necrosis, gummosis and wilt (Fig. S1). Neofusicoccum ribis was re-isolated from all infected trees and species identity was confirmed by sequencing as described above. Controls remained symptom-free and no fungi were isolated from the wood. Therefore, Koch's postulates were completed. Neofusicoccum ribis was reported to cause branch dieback of olive trees in Spain (Romero et al. 2005) and pistachio in Italy (Corazza et al. 1986), stem blight and dieback of blueberry in Michigan (Heger et al. 2023) and Florida (Wright and Harmon 2010) and postharvest decay of apple fruit from cold storage in Pennsylvania (Jurick et al. 2013). To the best of our knowledge, this is the first report of N. ribis causing canker and shoot dieback of apricot trees in Canada and worldwide. This report reveals N. ribis as a potential threat, causing canker and dieback. Without proper management, it could lead to significant losses in apricot orchards and the stone fruit industry. This study paves the way for crucial research on N. ribis outbreaks and effective disease control.
ABSTRACT
A dieback of apple trees (Malus domestica (Suckow) Borkh.) associated with cankers was observed in commercial orchards in southwestern Ontario, Canada, in 2019. Fifteen 2 to 10-year-old symptomatic trees were collected from three orchards exhibiting up to 37% disease incidence. Small sections of diseased wood (1 cm long) were surface sterilized with 70% ethanol for 30 sec and 1% NaClO for 20 min, rinsed thrice in sterile water, placed on 2% PDA (Difco) amended with kanamycin (50 mg liter-1), and incubated at 22°C for 5 days in the dark (Ilyukhin et al. 2023). Fungal colonies that were consistently isolated were hyphal-tipped, transferred to individual PDA plates and incubated at 22°C for 7 days in the dark. Purified isolates with same characteristics were classed into morphotypes. One morphotype was initially white and turned dark olivaceous with dense aerial mycelium. Pycnidia were produced on pine needles on PDA (Fig. S2) after incubation at 22°C for 17 days in the dark. Conidia were brown, aseptate, ovoid, and measured 27.9 to 31.3 µm x 12.1 to 14.2 µm (mean ± S.D. of 15 conidia = 29.9 ± 0.9 µm × 13.2 ± 0.6 µm), the typical morphology of a Diplodia sp. (Phillips et al. 2012). Genomic DNA was extracted from a 7-day-old culture of a representative isolate M45-28, using the Plant/Fungi DNA Isolation Kit (Norgen Biotech, Canada). The internal transcribed spacer (ITS), translation elongation factor 1-α (EF1-α) and ß-tubulin gene regions were amplified and sequenced with primers ITS1/ITS4, EF1-728F/EF1-986R and Bt2a/Bt2b and deposited in GenBank with accession numbers MZ970605, MZ995430 and MZ995431, respectively. Based on the sequence, the fungus was identified as Diplodia intermedia A.J.L. Phillips et al. and matched isolates from different hosts and countries (ITS: 100%, MG220378; EF1-α: 100%, MG220385; ß-tubulin: 99.24%, MT592502). The maximum likelihood-based phylogenetic analysis of ITS, EF1-α and ß-tubulin concatenated sequences was performed using IQ-Tree 2.2.2.7 (Minh et al. 2020). M45-28 was clustered with high bootstrap support values with D. intermedia isolates from the Westerdijk Fungal Biodiversity Institute collection, including the ex-holotype (CBS 124462) (Fig. S1). A living culture of M45-28 was deposited in the Canadian Collection of Fungal Cultures (DAOMC 252253). Pathogenicity assay was conducted by inoculating mycelial plugs from a 7-day-old culture of M45-28 into wounds made on the trunk of 5 eight-month-old potted healthy 'Royal Gala' apple seedlings. Five control seedlings were inoculated with sterile plugs. Canker symptoms appeared 15 days after inoculation, spread around, up and down the main stem from the inoculation point, and by 7 weeks the upper portion of the seedling was dead (Fig. S2). Diplodia intermedia was re-isolated from all inoculated seedlings and species identity was confirmed by sequencing as described above, fulfilling Koch's postulates. Control seedlings remained symptomless and the fungus was not isolated from the wood. Diplodia intermedia was reported to cause cankers on apple in Uruguay (Delgado-Cerrone et al. 2016), wild apple (Malus sylvestris) in Portugal (Phillips et al. 2012), grapevines in France (Comont et al. 2016) and forest trees in Iran (Kazemzadeh Chakusary et al. 2019). To the best of our knowledge, this is the first report of D. intermedia causing canker and dieback diseases on apple trees in Canada. Further studies are required to better understand the epidemiology involved in the dynamic spread of the disease in order to recommend an adequate phytosanitary program for its control.
ABSTRACT
Three bacterial strains, 1AS11T, 1AS12 and 1AS13, members of the new symbiovar salignae and isolated from root nodules of Acacia saligna grown in Tunisia, were characterized using a polyphasic approach. All three strains were assigned to the Rhizobium leguminosarum complex on the basis of rrs gene analysis. Phylogenetic analysis based on 1734 nucleotides of four concatenated housekeeping genes (recA, atpD, glnII and gyrB) showed that the three strains were distinct from known rhizobia species of the R. leguminosarum complex and clustered as a separate clade within this complex. Phylogenomic analysis of 92 up-to-date bacterial core genes confirmed the unique clade. The digital DNA-DNA hybridization and blast-based average nucleotide identity values for the three strains and phylogenetically related Rhizobium species ranged from 35.9 to 60.0% and 87.16 to 94.58â%, which were lower than the 70 and 96% species delineation thresholds, respectively. The G+C contents of the strains were 60.82-60.92âmol% and the major fatty acids (>4â%) were summed feature 8 (57.81â%; C18â:â1 ω7c) and C18â:â1 ω7c 11-methyl (13.24%). Strains 1AS11T, 1AS12 and 1AS13 could also be differentiated from their closest described species (Rhizobium indicum, Rhizobium laguerreae and Rhizobium changzhiense) by phenotypic and physiological properties as well as fatty acid content. Based on the phylogenetic, genomic, physiological, genotypic and chemotaxonomic data presented in this study, strains 1AS11T, 1AS12 and 1AS13 represent a new species within the genus Rhizobium and we propose the name Rhizobium acaciae sp. nov. The type strain is 1AS11T (=DSM 113913T=ACCC 62388T).
Subject(s)
Acacia , Rhizobium , Acacia/genetics , Fatty Acids/chemistry , Phylogeny , Tunisia , Root Nodules, Plant/microbiology , Sequence Analysis, DNA , Base Composition , DNA, Bacterial/genetics , RNA, Ribosomal, 16S/genetics , Bacterial Typing Techniques , NucleotidesABSTRACT
A new species of Cytospora was isolated from cankered wood of Prunus spp. during a survey of orchards exhibiting symptoms of fruit tree decline syndrome in southern Ontario, Canada. We found isolates that are morphologically similar to species in the Cytosporaceae family, which is characterized by single or labyrinthine locules, filamentous conidiophores or clavate to elongate obovoid asci and allantoid, hyaline conidia. Multi-gene phylogenetic analysis of ITS, LSU, act and tef1- α showed that the isolates form a distinct clade, sister to Cytospora plurivora. Morphologically, our isolates showed differences in the length of conidia and culture characteristics compared to C. plurivora, suggesting the establishment of a new species. The species is described as Cytospora paraplurivora sp. nov. and placed in the family Cytosporaceae of Diaporthales. Additionally, we sequenced, assembled and characterized the genome of the representative isolate for this new species. The phylogenomic analysis confirms the species order and family level classification. C. paraplurivora sp. nov. has the potential to severely affect stone fruits production, causing cankers and dieback in stressed trees, and eventually leads to tree decline. Pathogenicity tests show that the species is pathogenic to Prunus persica var. persica.
Subject(s)
Ascomycota , Fruit , Ontario , Phylogeny , Ascomycota/genetics , Cultural Characteristics , Spores, Fungal , SyndromeABSTRACT
Acacia saligna is an invasive alien species that has the ability to establish symbiotic relationships with rhizobia. In the present study, genotypic and symbiotic diversity of native rhizobia associated with A. saligna in Tunisia were studied. A total of 100 bacterial strains were selected and three different ribotypes were identified based on rrs PCR-RFLP analysis. Sequence analyses of rrs and four housekeeping genes (recA, atpD, gyrB and glnII) assigned 30 isolates to four putative new lineages and a single strain to Sinorhizobium meliloti. Thirteen slow-growing isolates representing the most dominant IGS (intergenic spacer) profile clustered distinctly from known rhizobia species within Bradyrhizobium with the closest related species being Bradyrhizobium shewense and Bradyrhizobium niftali, which had 95.17% and 95.1% sequence identity, respectively. Two slow-growing isolates, 1AS28L and 5AS6L, had B. frederekii as their closest species with a sequence identity of 95.2%, an indication that these strains could constitute a new lineage. Strains 1AS14I, 1AS12I and 6AS6 clustered distinctly from known rhizobia species but within the Rhizobium leguminosarum complex (Rlc) with the most closely related species being Rhizobium indicum with 96.3% sequence identity. Similarly, the remaining 11 strains showed 96.9 % and 97.2% similarity values with R. changzhiense and R. indicum, respectively. Based on nodC and nodA phylogenies and cross inoculation tests, these 14 strains of Rlc species clearly diverged from strains of Sinorhizobium and Rlc symbiovars, and formed a new symbiovar for which the name sv. "salignae" is proposed. Bacterial strains isolated in this study that were taxonomically assigned to Bradyrhizobium harbored different symbiotic genes and the data suggested a new symbiovar, for which sv. "cyanophyllae" is proposed. Isolates formed effective nodules on A. saligna.
Subject(s)
Acacia , Bradyrhizobium , Rhizobium leguminosarum , Rhizobium , DNA, Bacterial/genetics , Phylogeny , RNA, Ribosomal, 16S/genetics , Rhizobium leguminosarum/genetics , Root Nodules, Plant/microbiology , Sequence Analysis, DNA , Symbiosis/genetics , TunisiaABSTRACT
Apple trees (Malus domestica L. Borkh.) exhibiting extensive and unknown tree fruit decline symptoms were observed in commercial orchards over the past 5 years in Ontario, Canada. The trees exhibited shoot dieback, attached wilted leaves and cankers on the main trunk. Trees with rapid development of cankers upward from the graft union developed extensive vascular discoloration that resulted in sudden collapse of the entire tree. In 2018-19, up to 42% mortality was observed on 2- to 8-year old apple trees. Nine symptomatic trees were collected from two orchards located in southwestern and one in southcentral Ontario. Samples (1 cm length) were collected from symptomatic trunk and shoot tissue, surface sterilized with 70% ethanol for 30 sec, followed by 1% NaClO for 20 min and three rinses in sterile water. The samples were air-dried and placed on a 2% potato dextrose agar (PDA, Difco) culture media supplemented with kanamycin (50 mg L-1). The PDA plates were incubated at 22°C for 5 days in the dark. All fungal colony-forming units that developed were hyphal-tip transferred to individual PDA plates and incubated at 22°C for 7 days in the dark. Purified mycelial isolates were classified into morphotypes prior to molecular identification. One morphotype showed white to olive-green colonies that developed on a moderately dense mycelial mat with aerial hyphae. Several solitary and globose black pycnidia that contained a single ostiole were produced on pine needles on PDA after incubation at 22°C for 14 days in the dark. Conidia were hyaline, fusiform, aseptate with an average size of 3.9 - 5.2 x 21.4 - 26.6 µm (N=50). Genomic DNA was extracted from 5-day old culture of a representative isolate, #M68-17, grown on PDA using the Plant/Fungi DNA Isolation Kit (Norgen Biotech Corp., Thorold, ON, Canada). The rDNA internal transcribed spacer (ITS), translation elongation factor 1- alpha gene (TEF-1α), and ß-tubulin gene (TUB2) were amplified using the primer pairs ITS1/ITS4 (White et al. 1990), EF1-728F/EF1-986R (Carbone and Kohn 1999), and Bt2a/Bt2b (O'Donnell et al. 1998), respectively, and sequenced. The nucleotide sequences obtained (GenBank # MZ926850, MZ934654, MZ934655) were 100.00% similar to those of Botyrosphaeria dothidea (Moug. ex Fr.) Ces. & De Not. isolates from other hosts in several countries in the NCBI database (MT111097, MT309401, MN515421, respectively). Randomized Accelerated Maximum Likelihood (RAxML) analysis using the three gene sequence data was completed (Stamatakis et al. 2008). The isolate #M68-17 was clustered with high bootstrap support values with the B. dothidea isolates from the fungal biodiversity centre (CBS) collection, including the ex-epitype (CBS 115476, CBS 110302) (Fig. 1). A living culture of the representative isolate, #M68-17, was deposited in the Canadian Collection of Fungal Cultures (DAOMC 252246). Pathogenicity tests were conducted in the lab on wood cuttings and in planta. Ten 20 cm apple cuttings and five potted one year old apple seedlings were surface sterilized, wounded and inoculated with 4 mm mycelium agar plug from a 5-day old culture of isolate #M68-17 and wrapped with Parafilm. Three control apple cuttings and seedlings were inoculated with PDA plugs and incubated in the same environment. Cuttings were placed inside a clear plastic container with moist paper towels and incubated at room temperature in the dark. Seedlings were placed in an open-air area between two greenhouses and watered as needed. Twelve days post-inoculation, the average length of the developed necrotic lesions on cuttings was 8.8 ± 0.4 cm. Necrotic and sunken canker symptoms appeared at 10 days, spread upward from the inoculation point and by 6 weeks the upper portion of the seedling was dead (Fig. 2). B. dothidea was isolated from all the inoculated cuttings and seedlings, thus fulfilling Koch's postulates. Control cuttings and seedlings showed no symptoms, and the fungus was not isolated from the wood. B. dothidea was reported as a pathogen causing cankers on a wide range of woody crop plants including apples, almonds, pistachios, hazelnut, walnut, olive and grapes in the United States, China, Uruguay, Spain, Tunisia and Turkey (Chebil et al. 2014; Delgado-Cerrone et al. 2016; Moral et al. 2019; Tang et al. 2012; Türkölmez et al. 2016). However, this is the first report of B. dothidea causing stem canker and death of young apple seedlings in Ontario, Canada. The findings suggest that B. dothidea has the potential to severely affect apple production in Ontario. Accurate identification of pathogen(s) associated with apple decline will support management of the disease.
ABSTRACT
Nodulated Pisum sativum plants showed the presence of native rhizobia in 16 out of 23 soil samples collected especially in northern and central Tunisia. A total of 130 bacterial strains were selected and three different ribotypes were revealed after PCR-RFLP analysis. Sequence analyses of rrs and four housekeeping genes (recA, atpD, dnaK and glnII) assigned 35 isolates to Rhizobium laguerreae, R. ruizarguesonis, Agrobacterium radiobacter, Ensifer meliloti and two putative genospecies. R. laguerreae was the most dominant species nodulating P. sativum with 63%. The isolates 21PS7 and 21PS15 were assigned to R. ruizarguesonis, and this is the first report of this species in Tunisia. Two putative new lineages were identified, since strains 25PS6, 10PS4 and 12PS15 clustered distinctly from known rhizobia species but within the R. leguminosarum complex (Rlc) with the most closely related species being R. indicum with 96.4% sequence identity. Similarly, strains 16PS2, 3PS9 and 3PS18 showed 97.4% and 97.6% similarity with R. sophorae and R. laguerreae, respectively. Based on 16S-23S intergenic spacer (IGS) fingerprinting, there was no clear association between the strains and their geographic locations. According to nodC and nodA phylogenies, strains of Rlc species and, interestingly, strain 8PS18 identified as E. meliloti, harbored the symbiotic genes of symbiovar viciae and clustered in two different clades showing heterogeneity within the symbiovar. All these strains nodulated and fixed nitrogen with pea plants. However, the strains belonging to A. radiobacter and the two remaining strains of E. meliloti were unable to nodulate P. sativum, suggesting that they were non-symbiotic strains. The results of this study further suggest that the Tunisian Rhizobium community is more diverse than previously reported.
Subject(s)
Phylogeny , Pisum sativum , Rhizobium , DNA, Bacterial/genetics , Genes, Bacterial , Pisum sativum/microbiology , RNA, Ribosomal, 16S/genetics , RNA, Ribosomal, 23S/genetics , Rhizobium/classification , Rhizobium/isolation & purification , Root Nodules, Plant/microbiology , Sequence Analysis, DNA , Symbiosis , TunisiaABSTRACT
Moldy core is a fungal disease of apple fruits that is characterized by mycelial growth in the seed locules and is sometimes accompanied by penetration of the immediate surrounding flesh. The disease can go undetected until the fruit is cut open, as no external symptoms appear on the fruit. Alternaria, Aspergillus, Cladosporium, Coniothyrium, Epicoccum, Phoma and Stemphylium are some of the common pathogens associated with moldy core (Serdani et al. 2002; Gao et al. 2013; McLeod 2014). The disease is more common in apple cultivars with an open calyx, where spores may initiate infections during the growing season or at the post-harvest storage stage (Spotts et al. 1988). In 2018, a shipment of 'Sweet Tango' apples from New Zealand to Scotian Gold Co-operative Ltd., Nova Scotia, Canada, was found to be affected by moldy core. Moderate to severe moldy core symptoms were observed when 10 apples were cut open (Figure S1). In comparison, 'Sweet Tango' apples grown in Nova Scotia showed no moldy core symptoms when 10 random fruits were cut open. Small pieces of the diseased fruit tissue from the core region were surface-disinfected for 1 min in 1% NaOCl, rinsed three times with sterilized water and placed onto potato dextrose agar (PDA) dishes. The PDA dishes were incubated in dark at 22 oC and single spore isolation was carried out to fresh PDA dishes. These isolate produced colonies of regular shape, tan black with prominent white gray margin and gray colour conidia (Figure S2 AB). The colonies turn dark black after 3 weeks of growth on PDA. Mycelia were septate and conidia were oval or obclavate or club-shaped with a tapering end with 4-6 longitudinal and transverse septa (Figure S2 C-D). The size of conidia ranges from 12.5-20 x 8.7-12.5 µM on 20 days old PDA dishes. Based on the size and shape of conidia and other morphological characteristics the isolated fungi were identical to Alternaria spp. (Simmons 2007). To assess the identity of the isolated pathogen species by multi-locus sequence analysis, genomic DNA was extracted from the pure cultures of two isolates (5.8 and 8) using the E.Z.N.A. SP Fungal DNA Kit (Omega Bio-Tek). The glyceraldehyde-3-phosphate dehydrogenase (GAPDH), major allergen (Alt a 1), OPA10-2, the internal transcribed spacer (ITS) region of ribosomal DNA and the translation elongation factor 1-α (TEF1-α) region from two Alternaria spp. isolates (5.8 and 8) were amplified and sequenced using primers gpd1/2 (Berbee et al. 1999), A21F/A21R (Gabriel 2015), OPA10-2/ OPA10-2L (Andrew et al. 2009), ITS1/ITS4 (White et al. 1990) and EF1-up /EF1-low (O'Donnell et al. 1998) respectively. The resulting sequences of both isolates were deposited in the NCBI GenBank (GAPDH; MW411052, MW411053, Alt a 1; MW411050, MW411051, OPA10-2; MW415762, MW415763, ITS; MK140445, MT225559, TEF1-α; MT305773 and MT305774 ). Sequences of GAPDH, Alt a 1, OPA-10-2, ITS and TEF1-α genes of both isolates were identical to each other and showed 100 %, 100 %, 99.21 %, 100% and 100% identity to A. arborescens S. (AY278810.1, AY563303.1, KP124712.1, KY965831.1, KY965831.1) respectively. Identity with reference strain CBS 102605 confirms that both of the isolated strains 5.8 and 8 are A. arborescens. The pathogenicity of the two A. arborescens isolates were confirmed by artificially inoculating healthy 'Sweet Tango' fruit by dispensing the conidial suspension directly on the seed locule. Briefly, surface-disinfected fruits were air-dried for 5 min and then peeled using a sterilized knife and cut transversally. Each half of the fruit was inoculated with 100 µl of conidial suspensions (â¼1 × 104 conidia/ml) in potato dextrose broth (PDB) and incubated at 22 °C in a humid chamber for 7-10 days, or until symptoms with visible mycelial growth were observed. The control fruits were treated with 100 µl of sterilized PDB. Both A. arborescens isolates produced visible moldy core symptoms on the inoculated 'Sweet Tango' fruits, whereas no symptoms were observed on the control fruits (Figure S1). The experiment was repeated three times with at least three replicates with similar results. A. arborescens was successfully re-isolated from the artificially-inoculated fruits to complete Koch's postulates. To our knowledge, this is the first report of Alternaria arborescens causing moldy core disease in 'Sweet Tango' apples from New Zealand. Acknowledgments We thank Eric Bevis for his help in sample preparation for DNA sequencing, Willy Renderos for pathogenicity assay. We also thank Joan Hebb (Scotian Gold Cooperative Ltd.,) for providing the apple sample for this study. This research was made possible through financial support from Agriculture and Agri-Food Canada. The authors(s) declare no conflict of interest. Literature Cited Andrew M., Peever T.L., Pryor B.M. An expanded multilocus phylogeny does not resolve species among the small-spored Alternaria species complex. 2009. Mycologia. 101:95-109. Berbee, M. L. et al. 1999. Cochliobolus phylogenetics and the origin of known, highly virulent pathogens, inferred from ITS and glyceraldehyde-3-phosphate dehydrogenase gene sequences Mycologia. 91:964. Gabriel, M.F. I. Postigo, A. Gutiérrez-Rodríguez, E. Suñén, C.T. Tomaz, J. Martínez 2015. Development of a PCR-based tool for detecting immunologically relevant Alt a 1 and Alt a 1 homologue coding sequences. Medical Mycology. 53 (6):636-642. Gao, L. L., Zhang, Q., Sun, X. Y., Jiang, L., Zhang, R., Sun, G. Y., Zha, Y. L., and Biggs, A. R. 2013. Etiology of moldy core, core browning, and core rot of Fuji apple in China. Plant Dis. 97:510-516. Kerry, O'Donnell, H.C. Kistler, E. Cigelnik, R.C. Ploetz. 1998. Multiple evolutionary origins of the fungus causing Panama disease of banana: concordant evidence from nuclear and mitochondrial gene genealogies. PNAS. 95: 2044-2049. McLeod, A. 2014. Moldy core and core rots. Pages 40-41 in: Compendium of Apple and Pear Diseases and Pests, 2nd ed. T. B. Sutton, H. S. Aldwinckle, A. M. Agnello, and J. F. Walgenbach, eds. American Phytopathological Society, St Paul, MN. Serdani, M., Kang, J. C., Peever, T. L., Andersen, B., and Crous, P. W. 2002. Characterization of Alternaria species groups associated with core rot of apples in South Africa. Mycol. Res. 106:561-569. Simmons, E. G. 2007. Alternaria: an identification manual. CBS Biodiversity Series. 6:780 pp. Spotts, R. A., Holmes, R. J., and Washington, W. S. 1988. Factors affecting wet core rot of apples. Australas. Plant Pathol. 17:53-57. White, T. J., Bruns, T., Lee, S., and Taylor, J. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. Pages 315-322 in: PCR Protocols: A Guide to Methods and Applications. M. A. Innis, D. H. Gelfand, J. J. Sninsky, and T. J. White, eds. San Diego, CA: Academic Press. Woudenberg, J. H. C., et al. 2015. Alternaria section Alternaria: Species, formae speciales or pathotypes. Stud. Mycol. 82:1-21.
ABSTRACT
We present the first worldwide study on the apple (Malus × domestica) fruit microbiome that examines questions regarding the composition and the assembly of microbial communities on and in apple fruit. Results revealed that the composition and structure of the fungal and bacterial communities associated with apple fruit vary and are highly dependent on geographical location. The study also confirmed that the spatial variation in the fungal and bacterial composition of different fruit tissues exists at a global level. Fungal diversity varied significantly in fruit harvested in different geographical locations and suggests a potential link between location and the type and rate of postharvest diseases that develop in each country. The global core microbiome of apple fruit was represented by several beneficial microbial taxa and accounted for a large fraction of the fruit microbial community. The study provides foundational information about the apple fruit microbiome that can be utilized for the development of novel approaches for the management of fruit quality and safety, as well as for reducing losses due to the establishment and proliferation of postharvest pathogens. It also lays the groundwork for studying the complex microbial interactions that occur on apple fruit surfaces.
Subject(s)
Malus , Microbiota , Bacteria/genetics , Fruit/microbiology , Fungi/genetics , Malus/microbiologyABSTRACT
Two Pseudomonas strains (H346-M and H346-S) were isolated from hazelnut trees showing symptoms of shoot dieback and necrosis. The draft genome sequences of H346-M and H346-S consist of 66 and 51 contigs, respectively, with total sizes of 5,693,988 and 5,889,925 bp and 4,885 and 5,045 protein-coding sequences, respectively.
ABSTRACT
Nodulation and genetic diversity of native rhizobia nodulating Lathyrus cicera plants grown in 24 cultivated and marginal soils collected from northern and central Tunisia were studied. L. cicera plants were nodulated and showed the presence of native rhizobia in 21 soils. A total of 196 bacterial strains were selected and three different ribotypes were revealed after PCR-RFLP analysis. The sequence analysis of the rrs and two housekeeping genes (recA and thrC) from 36 representative isolates identified Rhizobium laguerreae as the dominant (53%) rhizobia nodulating L. cicera. To the best of our knowledge, this is the first time that this species has been reported among wild populations of the rhizobia-nodulating Lathyrus genus. Twenty-five percent of the isolates were identified as R. leguminosarum and isolates LS11.5, LS11.7 and LS8.8 clustered with Ensifer meliloti. Interestingly, five isolates (LS20.3, LS18.3, LS19.10, LS1.2 and LS21.20) were segregated from R. laguerreae and clustered as a separate clade. These isolates possibly belong to new species. According to nodC and nodA phylogeny, strains of R. laguerreae and R. leguminosarum harbored the symbiotic genes of symbiovar viciae and clustered in three different clades showing heterogeneity within the symbiovar. Strains of E. meliloti harbored symbiotic genes of Clade V and induced inefficient nodules.
Subject(s)
Lathyrus/microbiology , Plant Root Nodulation/physiology , Rhizobium/genetics , Symbiosis/genetics , Biodiversity , Biomass , DNA, Bacterial/genetics , Genes, Bacterial/genetics , Genes, Essential/genetics , Genetic Variation , Genotype , Lathyrus/growth & development , Phylogeny , Plant Root Nodulation/genetics , Rhizobium/classification , Rhizobium/isolation & purification , Root Nodules, Plant/microbiology , Sequence Analysis, DNA , Soil Microbiology , TunisiaABSTRACT
Understanding the variation in how wheat genotypes shape their arbuscular mycorrhizal (AM) fungal communities in a prairie environment is foundational to breeding for enhanced AM fungi-wheat interactions. The AM fungal communities associated with 32 durum wheat genotypes were described by pyrosequencing of amplicons. The experiment was set up at two locations in the Canadian prairies. The intensively managed site was highly dominated by Funneliformis. Genotype influenced the AM fungal community in the rhizosphere soil, but there was no evidence of a differential genotype effect on the AM fungal community of durum wheat roots. The influence of durum wheat genotype on the AM fungal community of the soil was less important at the intensively managed site. Certain durum wheat genotypes, such as Strongfield, Plenty, and CDC Verona, were associated with high abundance of Paraglomus, and Dominikia was undetected in the rhizosphere of the recent cultivars Enterprise, Eurostar, Commander, and Brigade. Genetic variation in the association of durum wheat with AM fungi suggests the possibility of increasing the sustainability of cropping systems through the use of durum wheat genotypes that select highly effective AM fungal taxa residing in the agricultural soils of the Canadian prairies.
Subject(s)
Grassland , Mycorrhizae/classification , Plant Roots/microbiology , Rhizosphere , Soil Microbiology , Triticum/microbiology , Agriculture , Biodiversity , Canada , Genetic Variation , Genotype , Mycorrhizae/genetics , Triticum/geneticsABSTRACT
The selection of genotypes under high soil fertility may alter the effectiveness of mycorrhizal symbioses naturally forming between crop plants and the mycorrhizal fungi residing in cultivated fields. We tested the hypothesis that the mycorrhizal symbiosis of 5 landraces functions better than the mycorrhizal symbiosis of 27 cultivars of durum wheat that were bred after the development of the fertilizer industry. We examined the development of mycorrhiza and the response of these genotypes to mycorrhiza formation after 4 weeks of growth under high and low soil fertility levels in the greenhouse. The durum wheat genotypes were seeded in an established extraradical hyphal network of Rhizophagus irregularis and in a control soil free of mycorrhizal fungi. The percentage of root length colonized by mycorrhizal fungi was lower in landraces (21%) than in cultivars (27%; P = 0.04) and in the most recent releases (29%; P = 0.02), which were selected under high soil fertility levels. Plant growth response to mycorrhiza varied from -36% to +19%. Overall, durum wheat plant breeding in Canada has increased the mycorrhizal development in wheat grown at a low soil fertility level. However, breeding had inconsistent effects on mycorrhizal development and has led to the production of cultivars with patterns of regulation ranging from unimproved to inefficient.
Subject(s)
Mycorrhizae/physiology , Plant Breeding , Triticum/growth & development , Genotype , Plant Roots/microbiology , Symbiosis/physiology , Triticum/microbiologyABSTRACT
Soil fungi are a critical component of agroecosystems and provide ecological services that impact the production of food and bioproducts. Effective management of fungal resources is essential to optimize the productivity and sustainability of agricultural ecosystems. In this review, we (i) highlight the functional groups of fungi that play key roles in agricultural ecosystems, (ii) examine the influence of agronomic practices on these fungi, and (iii) propose ways to improve the management and contribution of soil fungi to annual cropping systems. Many of these key soil fungal organisms (i.e., arbuscular mycorrhizal fungi and fungal root endophytes) interact directly with plants and are determinants of the efficiency of agroecosystems. In turn, plants largely control rhizosphere fungi through the production of carbon and energy rich compounds and of bioactive phytochemicals, making them a powerful tool for the management of soil fungal diversity in agriculture. The use of crop rotations and selection of optimal plant genotypes can be used to improve soil biodiversity and promote beneficial soil fungi. In addition, other agronomic practices (e.g., no-till, microbial inoculants, and biochemical amendments) can be used to enhance the effect of beneficial fungi and increase the health and productivity of cultivated soils.
