Agronomy and Crop Science

The aim of this work was to assess the effects of a combined inoculum of a rhizobacterium and an arbuscular mycorrhizal (AM) fungus on plant responses to phytoplasma infection, and on phytoplasma multiplication and viability in Chrysanthemum carinatum plants infected by chrysanthemum yellows phytoplasma (CY). Combined inoculation with Glomus mosseae BEG12 and Pseudomonas putida S1Pf1Rif resulted in some resistance to phytoplasma infection (about 30%), delayed symptom expression in nonresistant plants, improved growth of the aerial part of the infected plants (+68·1%), and altered root morphology (root tip number: +49·9%; branching degree: +82·8%). Combined inoculation with the two beneficial microorganisms did not alter CY multiplication and viability. In inoculated and infected plants, phytoplasma morphology was typical of senescent cells. A more active and efficient root system in double‐inoculated plants probably mediated the effects of the two rhizospheric microorganisms in the infected plants. The practical application of rhizospheric microorganisms for mitigating phytoplasma damage, following evaluation under field conditions, represents an additional tool for the integrated management of phytoplasmosis.

Winter oilseed rape (Brassica napus L.) is widely grown in Poland to produce vegetable oil for industrial processing of human and animal feed. In recent years, according to European Union directives on the use of biofuels (Directive 2003/30/EC), the area under oilseed rape cultivation in Poland has dramatically increased to 810,000 ha in 2009 and is still increasing. Morphological deformations of winter oilseed rape indicative of phytoplasma infection have been observed sporadically in Poland since 2000 (3). Plants exhibiting floral virescence, phyllody, as well as auxiliary bud proliferation, reduced leaves, and malformation of siliques were identified during surveys of research fields in Wielkopolska during May and June of 2009 and 2010. To confirm phytoplasma infection of these plants, inflorescence and leaf tissues were collected from nine diseased and three symptomless plants from three different field locations with 1 to 16% disease incidence. Total DNA was extracted from each plant tissue sample with a modified cetyltrimethylammoniumbromide method (2). Samples were analyzed for phytoplasma DNA with a nested PCR assay employing phytoplasma universal rRNA operon primer pair P1/P7 followed by R16F2n/R16R2, using previously described conditions (1). PCR products of 1.8 and 1.2 kb were obtained from all diseased plants only following PCRs with P1/P7 and nested primer pair R16F2n/R16R2, respectively. PCR products were not obtained from symptomless plants. Eight 1.2-kb amplicons were sequenced (GenBank Accession Nos. JN193475 to JN193482). Comparative analysis of the R16F2n/R16R2 rDNA sequences confirmed the phytoplasma origin of the rDNA sequences that shared 100 to 99% identity with Maize bushy stunt phytoplasma (GenBank Accession No. HQ530152), Alfalfa stunt phytoplasma (GenBank Accession No. GU289675), Primula green yellows phytoplasma (GenBank Accession No. HM590623), and other aster yellows group phytoplasmas. A 1.8-kb amplicon of isolate designated RzW14 was sequenced (GenBank Accession No. HM561990) and had 99% identity with Aster yellow group phytoplasmas from Lithuania (GenBank Accession Nos.GU223208 and AY744071). A virtual restriction fragment length polymorphism analysis of the 16S rDNA sequences from the R16F2n/R16R2 amplicons was performed with iPhyClassifier (4). Restriction profile comparisons identified all aster yellows group phytoplasmas as subgroup 16SrI-B strains. To our knowledge, this is the first report of a ‘Candidatus Phytoplasma asteris’-related strain infecting oilseed rape in Poland. References: (1) I. M. Lee et al. Int. J. Syst. Bacteriol. 48:1153, 1998. (2) A. C. Padovan et al. Aust. J. Grape Wine Res. 1:25, 1995. (3) M. Starzycki and E. Starzycka. Oilseed Crops 21:399, 2000. (4) Y. Zhao et al. Int. J. Syst. Evol. Microbiol. 59:2582, 2009.

‘Candidatus Liberibacter africanus’ is associated with citrus greening (huanglongbing [HLB]) in South Africa. Various unpublished reports have suggested that the related bacterium ‘Ca. L. asiaticus’ associated with HLB in citrus might be seed transmissible based on real-time PCR results. Seed transmission poses a risk of long distance disease spread, especially with the dissemination of rootstock seed. Therefore, it was essential to determine whether ‘Ca. L. africanus’ is seed transmitted in citrus. Fruit from 26 ‘Ca. L. africanus’-infected branches of six citrus cultivars showing greening symptoms were collected and the seed was harvested. Cultivars included were Minneola tangelo (Citrus reticulata × C. paradisi); sweet oranges (C. sinensis) Premier midseason, Clanor midseason, and Olinda Valencia; Eureka lemon (C. limon) and Troyer citrange (Poncirus trifoliata × C. sinensis) rootstock variety. Branches bearing each fruit were collected and confirmed to contain ‘Ca. L. africanus’ by real-time PCR testing using Taqman probe HLBp and HLBaf and HLBr primers as described by Li et al. (3). The seed of each sample was sorted into five categories ranging from healthy looking to totally aborted based on their appearance before planting. Germination was done in seed trays under vector-free conditions at 24 to 28°C. Thereafter the seedlings were planted in small, plastic bags and monitored for greening-like symptoms or other abnormalities for up to 2 years. A slow-release, balanced fertilizer was applied and supplemented with micro-nutrient sprays for plant maintenance. Plants showing abnormal symptoms were potted into larger pots and closely monitored. These samples and a number of other seedlings showing growth abnormalities were tested for ‘Ca. L. africanus' by real-time PCR as described above. In total, 1,570 seedlings were obtained. Some abnormal symptoms such as small chlorotic leaves, interveinal chlorosis, yellow veins, and stunting were seen in some seedlings. Most symptoms resembled deficiencies, and no blotchy mottle typical of ‘Ca. L. africanus’ infection was noted on any of the seedlings. Abnormal seedlings arose from normal and abortive seed. One hundred and eighteen of these seedlings (8 Minneola tangelo; 24 Premier midseason, 42 Clanor midseason, 33 Olinda Valencia, and 11 Troyer citrange seedlings) were individually tested using real-time PCR for ‘Ca. L. africanus’ detection. These seedlings had germinated from essentially healthy-looking seed (category 1) to seeds with severe abnormalities (category 5) and 33, 24, 23, 30, and 8 seedlings, respectively, were tested from each of the five seed categories. No samples tested positive with real-time PCR based on a positive/negative threshold Cq value of 35. Buds of some seedlings that yielded the lowest Cq values above 35 were grafted onto healthy ‘Madam vinous’ sweet orange (C. sinensis) seedlings and monitored for symptom development for 3 months. No symptoms developed and all these indicators also tested negative for ‘Ca. L. africanus’, indicating the absence of a transmissible agent. Just as other researchers (1,2) have recently indicated a lack of evidence for seed transmission of ‘Ca. L. asiaticus’, no seed transmission of ‘Ca. L. africanus’ could be demonstrated in this experiment either. References: (1) U. Albrecht and K. D. Bowman. HortScience 44:1967, 2009. (2) J. S. Hartung et al. Plant Dis. 94:1200, 2010. (3) W. Li et al. J. Microbiol. Methods 66:104, 2006.

In January 2011, tomato (Solanum lycopersicum) plants exhibiting stunting, yellow mosaic, short, chlorotic leaves, aborted flowers, and reduced-size fruits, symptoms similar to those exhibited by plants infected by ‘Candidatus Liberibacter solanacearum’ (2), were observed in approximately 5% of tomato plants in greenhouses in Jocotitlan in the State of Mexico, Mexico. Occasional plant recovery was also observed. Tomato plants in this facility were previously shown to be infected by Mexican papita viroid (MPVd), Pepino mosaic virus (PepMV), and aster yellows phytoplasma. Eight symptomatic leaf samples (designated MX11-01 to MX11-08) were collected and screened against selected tomato viruses and pospiviroids by reverse transcription (RT)-PCR using purified plant RNA or for ‘Ca. L. solanacearum’ by PCR using purified plant DNA. As expected, both PepMV and MPVd were detected in these samples. However, two ‘Ca. L. solanacearum’-specific PCR products (1,168 and 669 bp) were also amplified in two samples (MX11-02 and MX11-05) using primers OA2 (2) and OI2c (1) or CL514F/CL514R (3), respectively. Each ‘Ca. L. solanacearum’-specific PCR product was gel purified with Geneclean (Q-Biogene, Carlsbad, CA) and cloned into pCR2.1 using TOPO TA cloning kit (Invitrogen, Carlsbad, CA) and sequenced (Functional Biosciences, Madison, WI). Sequences of 16S rRNA (1,168 bp) in both isolates (GenBank Accession Nos. JF811596 and JF811597) were identical. However, the 669-bp 50S rRNA sequences in these two isolates (GenBank Accession Nos. JF811598 and JF811599) contained two single nucleotide polymorphism (SNP) mutations. BLASTn searches showed that both 16S rRNA and 50S gene sequences in MX11-05 were identical to the ‘Ca. L. solanacearum’ previously identified on potato in Chihuahua (GenBank Accession Nos. FJ829811 and FJ829812) and Saltillo (GenBank Accession Nos. FJ498806 or FJ498807) in eastern Mexico. These ‘Ca. L. solanacearum’ isolates were recently classified as the “b” haplotype (4). Alignment analysis of the ‘Ca. L. solanacearum' 16S rRNA sequences also revealed the conserved SNP mutations (g.212T > G and g.581T > C) in MX11-02 and MX11-05 as previously identified for other “b” haplotype isolates (4). ‘Ca. L. solanacearum’ was first identified in greenhouse tomatoes in 2008 in New Zealand (2). It has also been identified in greenhouse and field tomatoes in the United States. ‘Ca. L. solanacearum’ was previously reported to infect field tomatoes in Sinaloa, Mexico (3), which was recently considered as the “a” haplotype (4). To our knowledge, this is the first report of ‘Ca. L. solanacearum’ naturally infecting tomatoes in Jocotitlan in the State of Mexico, Mexico. The greenhouse tomato ‘Ca. L. solanacearum’ may be transmitted from infected solanaceous plants by potato psyllids (Bactericera cockerelli), which were observed in this facility. References: (1) S. Jagoueix et al. Int. J. Syst. Bacteriol. 44:379, 1994. (2) L. W. Liefting et al. Plant Dis. 93:208, 2009. (3) J. E. Munyaneza et al. Plant Dis. 93:1076, 2009 (4) W. R. Nelson et al. Eur. J. Plant Pathol. 130:5, 2011.