Your search keyword '"R. T. Lartey"' showing total 8 results

1. Direct Polymerase Chain Reaction-Based Detection of Cercospora beticola in Field Soils

Author

Andrew W. Lenssen, R. T. Lartey, Thecan Caesar-TonThat, S. L. Hanson, J. L. Eckhoff, and Robert G. Evans

Subjects

biology, fungi, food and beverages, Plant Science, Fungi imperfecti, Amplicon, biology.organism_classification, Cercospora beticola, complex mixtures, Microbiology, Conidium, law.invention, chemistry.chemical_compound, Horticulture, Cercospora, chemistry, law, Sugar beet, Agronomy and Crop Science, Polymerase chain reaction, DNA

Abstract

Cercospora beticola, the causal agent of Cercospora leaf spot of sugar beet, survives as pseudostromata in infected sugar beet residues in the soil. Under optimal conditions, overwintering propagules germinate and produce conidia that are dispersed as primary inoculum to initiate infection in sugar beet. We developed a polymerase chain reaction (PCR) technique for rapid detection of C. beticola in field soils. Total DNA was first isolated from soil amended with C. beticola culture using the PowerSoil DNA Kit. The purified DNA was subjected to PCR in Extract-N-Amp PCR mix with CBACTIN primers over 35 cycles. The amplified products were resolved and compared by electrophoresis in 1% agarose gels. The PCR fragment size of C. beticola from the amended field soil correlated in size with the amplicon from control C. beticola culture DNA extract. Additionally, sample soils were collected from sugar beet fields near Sidney, MT and Foxholm, ND. Total DNA was extracted from the samples and subjected to PCR and resolved as previously described. The amplicons were purified from the gels and subjected to BigDye Terminator Cycle sequencing. All sequences from field soils samples, C. beticola-amended field soil, and pure culture were compared by alignment with a C. beticola actin gene sequence from GenBank. The result of the alignment confirmed the amplicons as products from C. beticola. Rapid screening for the presence of C. beticola in the soil by PCR will improve research capabilities in biological control, disease forecasting, and management of this very important sugar beet pathogen.

Published

2010

2. Safflower: A New Host of Cercospora beticola

Author

R. T. Lartey, N. I. Sol, W.L. Shelver, Thecan Caesar-TonThat, A. J. Caesar, and J.W. Bergman

Subjects

biology, Spots, Inoculation, fungi, food and beverages, Plant Science, Fungi imperfecti, biology.organism_classification, Cercospora beticola, Spore, Horticulture, Cercospora, Botany, Leaf spot, Sugar beet, Agronomy and Crop Science

Abstract

Safflower is an oilseed crop adapted to the small-grain production areas of the western Great Plains, including the Northern Plains Area (NPA). In the NPA, safflower production is being evaluated for potential rotation with sugar beet. Safflower is susceptible to Cercospora carthami, whereas sugar beet is susceptible to C. beticola C. carthami has not been observed on safflower in the NPA but C. beticola is ubiquitous on sugar beet. Observation of unusual leaf spots on irrigated safflower cv. Centennial at Sidney, MT prompted this investigation of safflower as a potential alternate host of C. beticola. Safflower plants were inoculated with four isolates of C. beticola (C1, C2, Sid1, and Sid2) and incubated in growth chambers; leaf spot symptoms appeared between 3 and 4 weeks later. Polymerase chain reaction (PCR) amplification of extracts from lesion leaf tissue with C. beticola-specific primers produced fragments comparable with amplified fragments from purified cultures of control C. beticola. PCR assay of cultures of single spores from diseased safflower leaf lesions also produced fragments comparable with fragments from C. beticola cultures. Antibody that was raised from isolate C2 also bound to antigens from the single-spore cultures of the four C. beticola isolates. Inoculum from single-spore cultures from infected safflower also infected sugar beet and produced typical Cercospora leaf spot symptoms. Assay of these leaf lesions by PCR resulted in amplification of target fragments with the C. beticola-specific primers. Our results demonstrate that safflower is a new host of C. beticola.

Published

2005

3. Isolate-specific synergy in disease symptoms between cauliflower mosaic and turnip vein-clearing viruses

Author

Ulrich Melcher, S. D. Hartson, R. T. Lartey, C. D. Taylor, R. Pennington, G. Hii, A. Williams, and D. Lewis

Subjects

Recombination, Genetic, Caulimovirus, biology, Virulence, viruses, fungi, Brassica napus, Tobamovirus, food and beverages, General Medicine, biology.organism_classification, Virology, Virus, Plant Leaves, Gene interaction, Species Specificity, Cauliflower mosaic virus, Caulimoviridae, Gene, Plant Diseases

Abstract

Simultaneous infection of a plant by two viruses can cause more severe disease than is caused by infection with either virus alone. Such synergy may be due to effects on the replication of one virus by the second virus or to other causes. The tobamovirus turnip vein-clearing virus (TVCV), itself causing almost imperceptible symptoms in infected turnips, exacerbated symptoms of infection of turnip by the Cabbage S isolate of the caulimovirus cauliflower mosaic virus (CaMV). The synergy in symptom production was most evident in a reduced size of leaves, providing an objective measure of synergy. In contrast, synergy did not occur when the CM4-184 isolate of CaMV was used in combination with TVCV. Both isolates of CaMV increased the level of TVCV accumulated in leaves. TVCV did not increase the level of the Cabbage S CaMV isolate. The use of Cabbage S-CM4-184 chimeras revealed that a region critical for isolate synergy in stunting was within the coat protein gene and/or the 5' one third of the reverse transcriptase gene. We conclude that the disease symptom synergy between TVCV and Cabbage S CaMV is not caused by altered levels of accumulation of the viruses, but instead reflects subtle genetic interactions mapping to the ORF IV-ORF V region of CaMV DNA.

Published

2002

4. First Report of Rhizoctonia spp. Causing a Root Rot of the Invasive Rangeland Weed Lepidium draba in North America

Author

J. Gaskin, A. J. Caesar, R. T. Lartey, and Thecan Caesar-TonThat

Subjects

biology, Weevil, Biological pest control, food and beverages, Introduced species, Plant Science, Rhizoctonia, biology.organism_classification, Lepidium, Draba, Botany, Root rot, Weed, Agronomy and Crop Science

Abstract

The exotic, invasive perennial rangeland weed Lepidium draba spreads rapidly and reduces native species diversity. The extensive root system of L. draba constitutes 76% of its biomass (4). Thus, searches have been done for biocontrol agents that target root tissue or that may interact with a weevil, Ceutorhynchus assimilis, that causes galls in the crown area of L. draba. An association of Rhizoctonia spp. with root tissue of plants galled by the weevil has been documented in Europe (3). The possible presence of soilborne pathogens similar to those found in the native range has been the subject of L. draba surveys in the United States. One such survey in 2008 detected a few plants with reddened and chlorotic foliage in a stand near Shepherd, MT. Such symptoms typically indicate the occurrence of soilborne diseases on L. draba in the native range of the weed (2). The site had shown a gradual increase in the range of detectable pathogens beginning with foliar pathogens in 1997. In 2010, at the Shepherd site, L. draba plants with similar (but more severe) symptoms to those seen in 2008 were noted in a different area of the stand. Excavation of the roots in both years revealed brown, sunken crown and root cankers. Pieces of root tissue were excised from the lesions and plated on acidified PDA and Ko and Hora medium. A non-sporulating fungus was isolated from three plants. Colonies of the isolates on PDA were typical of known Rhizoctonia spp. The 2010 isolates were determined to be multinucleate using DAPI and were paired with 14 tester (including subgroups) isolates of AG-1 to AG-4 on water agar. Anastomosis was observed between the multinucleate isolates and the AG-2-1 tester isolate. Sequence analysis of ITS of the rDNA of a multinucleate isolate (GenBank KJ545577) indicated 99% similarity with an accession of R. solani AG 2-1 (AB547381). The 2008 isolates were binucleate. A binucleate isolate, KJ545578, had 100% similarity with an isolate of Rhizoctonia spp. AG-A (AY927356). Pathogenicity tests consisted of planting 6-week-old seedlings of L. draba, one per pot, in ten 85-cm-diameter pots of pasteurized soil mix infested with Rhizoctonia-colonized barley grain that had been dried and milled. An inoculum level of ~8 CFU/g (1) of air-dried soil was established by most probable number calculations from fourfold dilutions of infested soil. Controls were the same number of plants in pasteurized potting mix. Results were recorded after 3 months in a greenhouse at 20–25°C. The test was repeated. Typically, R. solani caused mortality of six to eight plants, from which it was re-isolated, whereas binuclate isolates caused stunting and lower dry weight of L. draba. Control plants remained asymptomatic. This is the first report of R. solani and binucleate Rhizoctonia spp. on L. draba in North America. References: (1) A. J. Caesar et al. Plant Dis. 93:1350, 2009. (2) A. J. Caesar et al. Biol. Control 52:140, 2010. (3) A. J. Caesar et al. Plant Dis. 96:145, 2011. (4) R. F. Miller et al. Agronomy J. 86:487, 1994.

Published

2014

5. Limitations to tobacco mosaic virus infection of turnip

Author

T. C. Voss, Y. Zhang, R. T. Lartey, Ulrich Melcher, and S. D. Hartson

Subjects

Transcription, Genetic, viruses, Nicotiana tabacum, Recombinant Fusion Proteins, Restriction Mapping, Brassica, Biology, Virus, Viral Proteins, Species Specificity, Virology, Complementary DNA, Tobacco, Tobacco mosaic virus, Movement protein, Gene, DNA Primers, Reverse Transcriptase Polymerase Chain Reaction, fungi, Tobamovirus, food and beverages, General Medicine, biology.organism_classification, Plant Leaves, Plant Viral Movement Proteins, Tobacco Mosaic Virus, Plants, Toxic, RNA, Viral, Solanaceae, Plasmids

Abstract

Turnip vein-clearing virus (TVCV) and tobacco mosaic virus (TMV) represent subgroups of tobamoviruses infecting cruciferous and solanaceous plants, respectively. To identify adaptations that may have been necessary in the evolution of the TVCV subgroup from a TMV-like ancestor, the infection of turnip plants by TMV and by chimeras between TMV and TVCV was explored. TMV accumulated at spatially limited sites on inoculated turnip leaves as determined by leaf skeleton hybridization. A plasmid DNA containing a complete TVCV cDNA, when transcribed in vitro, produced RNA that was infectious to tobacco and turnip plants. TVCV-TMV chimeric genomes with junctions within coding regions were not infectious to tobacco, though the movement protein (MP) chimera was infectious to tobacco with a TMV MP transgene. Reciprocal chimeras with junctions between genes were infectious to tobacco. TVCV with a TMV MP gene infected turnips. The other tested chimeras were not detected in non-inoculated leaves, but were found in the inoculated leaves. Thus, the TMV MP is not responsible for the limitation of TMV spread in turnips.

Published

1999

6. First Report of Pilidium concavum Causing Root Lesions of Meadow Hawkweed in France

Author

R. T. Lartey, A. J. Caesar, and Thecan Caesar-TonThat

Subjects

geography, Hieracium, Chlorosis, geography.geographical_feature_category, biology, fungi, Biological pest control, food and beverages, Introduced species, Plant Science, biology.organism_classification, Pasture, Invasive species, Botany, Meadow hawkweed, Weed, Agronomy and Crop Science

Abstract

Hieracium caespitosum (meadow hawkweed) is an exotic invasive weed belonging to a complex of hawkweed species infesting nearly 500,000 hectares of pasture and wildlands in North America, primarily in the Pacific Northwest (1). Economic losses can be up to $222 per hectare (2). Despite prolonged effort, no promising insects have been found as agents of biological control of H. caespitosum. This has led to a greater emphasis on seeking plant pathogens such as rusts and smuts as potential biological control agents. Searches for plant pathogens have included Europe, which contains a portion of the native range of the weed. In the small stands of H. caespitosum that occur in northern France, plants were found with chlorosis and significant stunting. Typically, 10 to 30% of plants in affected stands exhibited such symptoms. Excavation and examination of roots revealed discrete necrotic lesions along the length of roots and decayed root tips, roughly resembling symptoms of corky root. Ten roots with these symptoms were thoroughly washed, cut into ~0.25- to 0.5-cm-long pieces and plated on potato dextrose agar (PDA) and acidified PDA. On these media, colonies were light-salmon-beige, woolly, zonate, with older mycelium sparser with the dense occurrence of dark, hemispherical conidiomata. The conidiomata exuded pink spore masses. The spores were hyaline and falcate with acute apices, 6.2 × 1.6 μm (n = 200). These traits match published descriptions of Pilidium concavum, described as a pathogen of numerous plants usually causing leaf spots and stem necrosis (3). To corroborate this identification, the internal transcribed spacer region of rDNA was amplified by PCR using primers ITS1 and ITS4 and sequenced. BLAST analysis of the 575-bp fragment (GenBank Accession No. JX047867) showed 100% homology with the sequences of six isolates of P. concavum in GenBank, including Accession No. AY487094. To confirm pathogenicity, five each of 30-day-old H. caespitosum plants were either sprayed with, or their roots soaked for 1 hr in a 1 × 106 per ml suspension of conidia prepared from 10-day-old cultures of the fungus grown on V8 agar. An equal number of control plants were either sprayed with sterile distilled water (SDW) or their roots were soaked for an hour in SDW. To plant soaked roots, a hole was made in the pre-moistened pasteurized potting mix in each pot and inoculum or SDW was poured around them before they were covered with soil. The experiments were repeated twice. Following leaf inoculations, plants were covered with a plastic bag and placed in the greenhouse in partial shade at 20 to 25°C for 72 to 96 h. Sprayed plants were then uncovered and assessed for the appearance of lesions over the next 7 to 10 days. No foliar symptoms occurred. Plants inoculated by soaking roots showed chlorosis and stunting by 4 months post-inoculation. P. concavum was isolated from root lesions on all inoculated, symptomatic plants, confirming Koch's postulates. Although reported to cause root deterioration of strawberry (4), to our knowledge, this the first report of a root disease of H. caespitosum caused by P. concavum. References: (1) C. A. Duncan et al. Weed Technol. 18:1411, 2004. (2) L. Frid. Economic Impacts of Invasive Plants in BC Final Project Report. British Columbia: Invasive Plant Council, 2009. (3) J. A. von Arx. Plant Pathogenic Fungi. J. Cramer, 1987. (4) J. L. Maas. Compendium of Strawberry Diseases. The American Phytopathological Society, St. Paul, MN, 1998.

Published

2012

7. First Report of a Root and Crown Disease of the Invasive Weed Lepidium draba Caused by Phoma macrostoma

Author

A. J. Caesar, R. T. Lartey, and Thecan Caesar-TonThat

Subjects

Chlorosis, biology, Brassica, food and beverages, Plant Science, biology.organism_classification, Lepidium, food.food, Conidium, food, Draba, Botany, Potato dextrose agar, Broccoli raab, Weed, Agronomy and Crop Science

Abstract

The exotic rangeland perennial Lepidium draba occurs as a noxious weed in 22 states, mostly in the western United States. Because chemical control measures against this invasive perennial, a member of the Brassicaceae, have not achieved adequate results, biological control is being pursued. While inventories of arthropods that feed on L. draba have been established, little is known of soilborne pathogens for possible use as biological control agents. To address this deficiency, we have surveyed for diseases of L. draba in the United States and Eurasia to identify and test potential biocontrol agents. In intensive surveys for soilborne diseases in a single infestation that is >20 years old in a cattle pasture in south-central Montana, several chlorotic, stunted plants were noted. Roots of chlorotic plants that exhibited elongated fissures from which other soilborne fungi were isolated also had numerous prominent pycnidia embedded in the crown tissue above the lesions. Examination with a dissecting microscope revealed large ostioles made evident by the wide concave inversions in the short necks of the pycnidia. Culture of root tissue on potato dextrose agar resulted in whitish, becoming pale gray colonies, with a dull peach-to-reddish tinge at the margins, with abundant single pycnidia. Conidia in vitro were mainly unicellular, variable shape, subglobose to ellipsoidal, with several guttules averaging 6 × 2.5 μm. These morphological traits are characteristic of Phoma macrostoma, which is regarded as a weak or wound pathogen. The internal transcribed spacer region of rDNA was amplified using primers ITS1 and ITS4 and sequenced. BLAST analysis of the 575-bp fragment showed a 100% homology with the sequence of an isolate of P. macrostoma that has been investigated extensively for commercialization as a biological control agent of various agricultural weeds (1), including wild mustard (GenBank No. DQ474091). The nucleotide sequence has been assigned GenBank No. HM755951. Pathogenicity tests consisted of making four 1.4-mm-diameter holes in five NaOCl (0.1%)-sterilized root sections of L. draba and pipetting ~50 to 100 μl of a 106 CFU/ml conidial suspension into the incisions, incubating the inoculated roots at 20 to 25°C overnight and planting the root sections, one per pot, in an artificial greenhouse potting mix and placing the pots in the greenhouse at 20 to 25°C. Controls were five root sections that were treated similarly except that sterile water was injected. The experiment was repeated. After 10 days, shoots that grew from inoculated roots were chlorotic and shorter than those produced from control roots. P. macrostoma was isolated from tissue of inoculated roots that became blackened distal to the inoculation points. To examine the host range of P. macrostoma on other brassica species, crowns of 2-week-old seedlings of radish, broccoli, cauliflower, broccoli raab, turnip, kohlrabi, cabbage, Chinese cabbage, mustard greens, and canola were injected with 0.5 ml of a 106 CFU/ml conidial suspension. Plants were grown in the greenhouse at 20 to 25°C for 4 weeks after inoculation and examined for symptoms. The experiment was repeated twice. Blackened root tissue with slight chlorosis occurred only on roots of radish and crowns of broccoli, from which P. macrostoma was reisolated. To our knowledge, this the first report of a disease of L. draba caused by P. macrostoma. Reference: (1) K. L. Bailey et al. U.S. Patent Application Serial No. 60/294,475, Filed May 20, 2001.

Published

2012

8. First Report of a Root and Crown Disease Caused by Rhizoctonia solani on Centaurea stoebe in Russia

Author

R. T. Lartey, A. J. Caesar, and Thecan Caesar-TonThat

Subjects

Fusarium, Perennial plant, fungi, Biological pest control, food and beverages, Sowing, Plant Science, Biology, biology.organism_classification, Rhizoctonia solani, Horticulture, Botany, Potato dextrose agar, Weed, Agronomy and Crop Science, Centaurea stoebe

Abstract

Spotted knapweed (SKW), Centaurea stoebe L., is a nonindigenous species that is invasive over large areas in the United States, especially in the west. It has been estimated that infestations of SKW cause $42 million in direct and indirect economic losses annually (2), and the weed could potentially invade 13.6 million ha of rangeland in Montana alone. Extensive efforts toward the control of SKW have included the release of 12 insects for biological control, four of which attack the crowns and roots of this short-lived perennial. To focus efforts to select potential soilborne pathogens, which could be applied in combination with insects, we conducted a survey for plant pathogens in the native range of SKW associated with damage caused by any root-attacking insects. Stunted and chlorotic SKW plants, which were colonized by larvae of Cyphocleonus spp., were found in June 1994 near the Novomar'evskaya Botanical Sanctuary (45°08′49.87″N, 41°51′02.05″E) in the Caucasus Region of Russia. A nonsporulating multinucleate fungus was isolated from the lower stem, crown, and upper root tissue of one such plant. Colonies growing on potato dextrose agar and Ko and Hora media were examined microscopically and identified as Rhizoctonia solani by the occurrence of robust, thick-walled, golden hyphae with right-angled branching and constrictions at the branch points. The anastomosis grouping of the one isolate was determined to be AG 2-2 IIIB after pairing it on water agar with 11 AG tester isolates representing all subgroups of AG 1 to AG 5. The hyphal diameter at the obvious point of anastomosis was reduced and cell death of adjacent cells was observed. In 2007, pathogenicity was determined by planting 12-week-old seedlings of SKW, one per pot, into 20 15-cm-diameter pots of a steamed greenhouse soil mix composed of sphagnum peat, sand, and Bozeman silt loam (1:1:1, vol/vol), pH 6.6, infested with R. solani-colonized barley grain that had been dried and milled. An inoculum level of 8 CFU/g of air-dried soil was determined by most probable number calculations from fourfold dilutions of infested soil. Controls were planted into noninfested soil. In both greenhouse tests, the isolate caused either mortality or a 93% mean fresh weight reduction of surviving plants, relative to the controls, after 8 months. R. solani was reisolated from necrotic root and crown tissue of dead and stunted plants but not from the controls. To our knowledge, this is the first report of R. solani occurring on SKW in Europe. The characterization and pathogenicity of Fusarium spp. isolated from insect-colonized roots of SKW in Europe was reported previously (1). References: (1) A. J. Caesar et al. BioControl 47:217. (2) S. A. Hirsch and J. A. Leitch, North Dakota Agricultural Economics Report No. 355. NDSU, Fargo. 1996.

Published

2009