8 research outputs found
Isolation and characterization of Pythium spp. from South Dakota soils under commerial alfalfa production
Alfalfa is a significant crop in South Dakota that provides many different benefits for its growers. South Dakota plants the most acres of alfalfa in the United States. It is used as a protein-rich feed for livestock, a cover crop that protects against soil erosion, and a natural fertilizer because of its ability to fix nitrogen in the soil. However, alfalfa seedlings are susceptible to many diseases. Pythium root and seed rot is one disease known to have devastating effects on alfalfa field establishment and yield. Pythium species are oomycete pathogens that inhabit the soil and remain present and pathogenic as oospores. Pythium diseases of alfalfa cause reduced root systems, plant size, length, and growth rate. Pythium management is centered on fungicidal seed treatments. There have been recent reports of Pythium spp. infecting alfalfa across the world in places like Sudan and China, but current research in South Dakota is needed. In our research, we isolated Pythium spp. from Lake County South Dakota soils under commercial alfalfa production. We also characterized these isolates with a DNA sequencing analysis and evaluated the isolates for fungicide sensitivity. This summer, we will conduct a statewide Pythium disease survey and assess the collected isolates for fungicide sensitivity and pathogenicity towards various commercial lines of alfalfa. This research will provide growers with the information necessary to make educated decisions in order to increase yields and maximize their profits
Surveying for Ophidiomyces ophidiicola, the causal agent of Snake Fungal Disease in South Dakota.
For the past decade there has been an emerging disease plaguing wild snakes across the Eastern United States and Europe. In 2006, researchers started investigating the decline of Timber rattlesnake populations in New Hampshire. They discovered a fungal infection killing off the young to mid-juvenal snakes, thus know as Snake Fungal Disease or Ophidiomycosis. In 2011, San Deigo State University, identified the pathogen that causes infection, the fungus Ophidiomyces ophiodiicola. O. ophiodiicola has now affected 30 different snakes from six families within at least 20 different states since it’s discovery. This study pertains to determining the prevalence of Snake Fungal Disease within South Dakota.https://scholar.dsu.edu/research-symposium/1028/thumbnail.jp
Plant defensin antibacterial mode of action against Pseudomonas species
Background: Though many plant defensins exhibit antibacterial activity, little is known about their antibacterial mode of action (MOA). Antimicrobial peptides with a characterized MOA induce the expression of multiple bacterial outer membrane modifications, which are required for resistance to these membrane-targeting peptides. Mini-Tn5- lux mutant strains of Pseudomonas aeruginosa with Tn insertions disrupting outer membrane protective modifications were assessed for sensitivity against plant defensin peptides. These transcriptional lux reporter strains were also evaluated for lux gene expression in response to sublethal plant defensin exposure. Also, a plant pathogen, Pseudomonas syringae pv. syringae was modified through transposon mutagenesis to create mutants that are resistant to in vitro MtDef4 treatments.
Results: Plant defensins displayed specific and potent antibacterial activity against strains of P. aeruginosa. A defensin from Medicago truncatula, MtDef4, induced dose-dependent gene expression of the aminoarabinose modification of LPS and surface polycation spermidine production operons. The ability for MtDef4 to damage bacterial outer membranes was also verified visually through fluorescent microscopy. Another defensin from M. truncatula, MtDef5, failed to induce lux gene expression and limited outer membrane damage was detected with fluorescent microscopy. The transposon insertion site on MtDef4 resistant P. syringae pv. syringae mutants was sequenced, and modifications of ribosomal genes were identified to contribute to enhanced resistance to plant defensin treatments.
Conclusions: MtDef4 damages the outer membrane similar to polymyxin B, which stimulates antimicrobial peptide resistance mechanisms to plant defensins. MtDef5, appears to have a different antibacterial MOA. Additionally, the MtDef4 antibacterial mode of action may also involve inhibition of translation
Plant defensins inhibit growth of pathogens in the alfalfa crown rot disease complex
Poster presentation at the 2016 American Phytopathological Society Annual Meeting.Alfalfa crown rot is a disease complex that severely limits alfalfa stand density and productivity in all alfalfa-producing areas. Currently, there are no viable methods of control. Plant defensins are small cationic antimicrobial peptides with a conserved signature of cysteines. Defensins have a γ-core motif, a cluster of positively charged residues, which is essential for antimicrobial activity. The γ-core motifs of five synthetic defensins were tested for antimicrobial activity against the pathogens in the alfalfa crown rot disease complex. In a 96-well microplate, each well contained half strength potato dextrose broth, approximately 2000 spores, and concentrations of defensin peptide up to 30 μg/mL in a total volume of 100 μL. After 48 hours of incubation at 25 C in the dark, absorbance of the wells was measured at 595 nm on a microplate reader to quantify the inhibition of fungal growth. The amount of defensin needed to inhibit growth of pathogen strains by 50% (EC50) was calculated. The γ-core motif of MtDef4 was shown to be the most effective peptide with EC50 values of 5.3 μM against Phoma medicaginis and 6.9 μM against Fusarium oxysporum f.sp. medicaginis. In addition, MtDef4 had activity against Pseudomonas syringae pv. syringae and Xanthomonas alfalfae subsp. alfalfae but not the oomycete Aphanomyces euteiches in in vitro assays. These results indicate that transgenic expression of plant defensins in alfalfa has the potential to lead to improved crown rot resistance
Transgenic expression of Medicago truncatula PR10 and PR5 promoters in alfalfa shows pathogen induced up-regulation of transgene expression
Poster presentation at the 2016 North American Alfalfa Improvement Conference.Genetic modification of alfalfa for introduction of novel traits requires promoters for controlling gene expression. Promoters that are constitutively activated for expression of genes that enhance disease resistance pose a great energy load on the plant and exert a strong selective pressure on the pathogens. Promoters that are induced upon pathogen invasion are needed for engineering plants with disease resistance. Medicago truncatula promoter regions of pathogenesis-related (PR) genes, PR5 and PR10, were identified as being highly up-regulated during the initial stages of infection by root and foliar pathogens. These promoters were PCR amplified and cloned into plant transformation vectors ahead of the β-glucuronidase (gus) gene. Agrobacterium mediated transformation was used to create transgenic lines of alfalfa (cultivar Regen SY27x). The transgenic plants were stained for GUS activity. In uninoculated plants, GUS activity was primarily seen in the root vascular tissues. No activity was observed in uninoculated leaves. With fungal pathogen infection, staining was greatly enhanced and allowed for stain visualized in the leaves. Quantitative PCR assays were done to quantify pathogen-induced GUS expression, as well as expression of PR5 and PR10 in infected leaves. RNA was extracted from symptomatic infected leaves after inoculation and converted to cDNA. Using specific primers, transcript accumulation was compared between cDNA from mock inoculated and inoculated plant tissue. In plants with the PR10:GUS or PR5:GUS constructs, GUS transcripts accumulated 41- to 378-fold over the mock inoculated plants at 7 days after inoculation with Phoma medicaginis, depending on the plant line. GUS transcripts were also strongly up-regulated in response to Colletotrichum trifolii and Pseudomonas syringae pv. syringae. Consistently, the PR10 promoter had greater fold amplifications and greater activity than the PR5 promoter. In response to P. medicaginis, transcripts of the PR10 gene were up-regulated 31- to 221-fold at 7 days after inoculation and transcripts of the PR5 gene were up-regulated 44- to 60-fold. These experiments show that the M. truncatula PR10 promoter is functional in alfalfa for expression of transgenes and up-regulates genes after infection by a range of alfalfa pathogens
Antimicrobial Activity of Brassica rapa Nectar Lipid Transfer Protein
Poster presentation at the 2017 Mycological Society of America Annual Meeting.Antimicrobial peptides (AMPs) provide an ancient, innate immunity conserved in all multicellular organisms. In plants, there are several large families of AMPs defined by sequence similarity. The nonspecific lipid transfer protein (LTP) family is defined by a conserved signature of eight cysteines and has a compact structure with a lipid-binding hydrophobic cavity. The antimicrobial activity of LTPs varies greatly among plant species. An LTP from Brassica rapa (variety R-o-18) nectar was tested for antimicrobial activity. In a 96-well microplate, each well contained half strength potato dextrose broth, approximately 2000 spores, and concentrations of LTP peptide up to 300 μg/mL in a total volume of 100 μL. After 48 hours of incubation at 25 C in the dark, absorbance of the wells was measured at 595 nm on a microplate reader to quantify the inhibition of fungal growth. The amount of LTP needed to inhibit growth of pathogen strains by 50% (IC50) was calculated. This Brassica LTP was most effective against Trichoderma and Bipolaris oryzae with IC50 values of 0.78 μM and 1.71 μM, respectively. Additionally, both Colletotrichum trifolii and Alternaria solani had IC50 values of less than 4.0 μM. The activity of this Brassica LTP at such low biological values indicates that it is a potent defense protein. These results suggest that transgenic expression of antimicrobial LTPs has the potential to lead to improved broad-spectrum disease resistanc
Management Strategies and Distribution of Aphanomyces Root Rot of Alfalfa (Medicago sativa), a continuing threat to forage production in the United States
Alfalfa (Medicago sativa) is one of several legumes that is affected by Aphanomyces root rot (ARR) caused by Aphanomyces euteiches. Symptoms of ARR on alfalfa seedlings include a yellow-grey discolouration of roots, rotting and loss of lateral roots, stunted growth, chlorotic foliage and reduction of nitrogen-producing nodules on roots. Infection can also occur on adult plants leading to loss of lateral roots and nodules. At the seedling stage, ARR decreases alfalfa stand establishment, and field longevity is reduced when adult plants are infected. A. euteiches is an oomycete pathogen that has motile zoospores and thick-walled oospores that can survive for many years in soil. Two races are currently recognized by pathogenicity on differential alfalfa check cultivars. Most alfalfa cultivars contain race 1 resistance, but there is an increasing development of cultivars with resistance to race 2. Management strategies include planting resistant cultivars, avoiding planting in fields with poor drainage and rotating crops with nonhost plants