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2. Physiological Response of Cape Gooseberry Seedlings to Two Organic Additives and Their Mixture under Inoculation with Fusarium oxysporum f. sp. physali.

Author

Chaves-Gomez, Jose Luis, Cotes-Prado, Alba Marina, Gomez-Caro, Sandra, and Restrepo-Díaz, Hermann

Subjects
*FUSARIUM oxysporum, *CAPE gooseberry, *PLANT physiology, *RICE hulls, *SEEDLINGS, *VASCULAR plants
Abstract

Vascular wilt caused by Fusarium oxysporum f. sp. physali is the most limiting disease in cape gooseberry crops. The use of natural products such as organic additives is a promising alternative for management of this disease. The present study sought to evaluate the physiological response of cape gooseberry plants infected with this pathogen and treated with the organic additives chitosan, burned rice husks, or their mixture. The test was conducted under greenhouse conditions and soil was inoculated with F. oxysporum f. sp. physali strain Map5. Chitosan was applied to seeds and seedlin gS,at the time of transplantation, whereas burned rice husk was incorporated into the soil in a 1:3 ratio. Plants inoculated and not inoculated with the pathogen were used as controls. The following variables were evaluated: area under the disease progress curve (AUDPC), leaf water potential, stomatal conductance gS, leaf area (LA), dry matter accumulation, photosynthetic pigment contents, proline synthesis, and lipid peroxidation estimation [malondialdehyde (MDA)]. The results showed that cape gooseberry plants with vascular wilt and treated with chitosan had higher gS, leaf water potential, LA, dry matter accumulation, and proline content values. In addition, the levels of vascular wilt severity decreased in comparison with pathogen-inoculated controls. The results suggest that chitosan applications on cape gooseberry plants may be considered as an alternative in the integrated management of the disease in producing areas, because they can mitigate the negative effect of the pathogen on plant physiology. [ABSTRACT FROM AUTHOR]

Published
2020
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4. Interactions between Bacillus amyloliquefaciens Bs006, Fusarium oxysporum Map5 and Cape gooseberry (Physalis peruviana)

Author

Moreno Velandia, Carlos Andrés, Cotes Prado, Alba Marina, Hoyos Carvajal, Lilliana María, Corporación Colombiana de Investigación Agropecuaria (Corpoica), and Biological control of agricultural pests

Subjects
Patología vegetal, Uchuva, Antibiosis, Fusariosis - Control, 632 - Lesiones, enfermedades, plagas vegetales [630 - Agricultura y tecnologías relacionadas], Pests - Biological control, Lipopéptidos, Fusarium oxysporum, Fusarium - control, Bacillus amyloliquefaciens, Biological control, Antibiosis, Plant diseases, Cape gooseberry, Control biológico de plagas, Cyclic lipopeptides
Abstract

ilustraciones, fotografías, gráficas, tablas Fusarium oxysporum (FOX) is one of the most difficult plant pathogens to control leading to important economic losses in several crops owing to Fusarium-wilt disease. Biological control through beneficial rhizobacteria has high potential to reduce the devastating effects caused by FOX. Bacillus amyloliquefaciens strain Bs006 has potential as plant growth promoter and biocontrol agent against cape gooseberry wilt disease. Although plant growth promoting phenomenon had been consistent in previous experiments, the biocontrol activity by Bs006 was variable, suggesting that biotic and abiotic factors in the rhizosphere affect the efficacy of Bs006. Thus, the main goal of this doctoral research was contribute to knowledge of Bs006-FOX-cape gooseberry-environment interactions. Results show that Bs006 synthesizes cyclic lipopeptides (CLPs) from the iturin, fengycin and surfactin families. However, incubation temperature and culture media affect the production of CLPs. Experimental evidence indicated that iturins have fungistatic effect on FOX, while fengycins have fungicidal effect in a concentration dependent manner. In gnotobiotic cultures, it was determined that Bs006 colonizes the cape gooseberry root surface, forming a biofilm and utilizes root exudates as a nutritional source. In this system, it was found that Bs006 synthesizes compounds of the three families listed above and is associated with the inhibition of FOX growth. In vivo studies indicated that biocontrol activity of Bs006 against Fusarium-wilt is influenced by the concentrations of the pathogenic inoculum, Bs006 inoculum and CLPs. These results have provided a framework in which to evaluate the optimal combination of Bs006 cells and supernatant/semi-purified extract or pure CLPs in future studies. Since the production of CLPs by Bs006 is lower in the rhizosphere than in artificial media and that propagules of FOX can be tolerant to CLP action, additional research is needed to design integrated management programs of this disease. These programs should include the development of a biopesticide based on Bs006 and information about compatibility between rhizobacteria, fungicides and another biological control agents. Fusarium oxysporum (FOX) es uno de los fitopatógenos más difíciles de controlar, provocando altas pérdidas agrícolas debido a la enfermedad marchitamiento vascular. El control biológico con rizobacterias promotoras del crecimiento vegetal (PGPR) presenta alto potencial para reducir los devastadores efectos de FOX. Particularmente Bacillus amyloliquefaciens cepa Bs006 ha mostrado alto potencial como promotor de crecimiento vegetal y como biocontrolador del marchitamiento vascular de la uchuva. Aunque el fenómeno de promoción del crecimiento vegetal había sido consistente previamente, la eficacia Bs006 contra la enfermedad fue variable, suponiendo que factores bióticos o abióticos de la rizósfera afectan su actividad biocontroladora. En este contexto, el objetivo de la investigación doctoral fue contribuir al conocimiento de las interacciones entre Bs006, FOX, uchuva y el ambiente. Los estudios in vivo indicaron que la actividad biocontroladora de Bs006 contra el marchitamiento vascular está influenciado por la concentración de inóculo del patógeno, la dosis de Bs006 y la concentración de lipopéptidos cíclicos (CLPs) de las familias iturinas, fengicinas y surfactinas. La evidencia experimental indicó que las iturinas tienen un efecto fungistático contra FOX, mientras que las fengicinas presentan un efecto fungicida, en una forma dependiente de la concentración. A través de un modelo gnotobiótico se determinó que Bs006 coloniza la superficie de la raíz de uchuva, formando una biopelícula; sintetizó compuestos de las tres clases de CLPs y desde la raíz inhibió el crecimiento de FOX. Adicionalmente, la temperatura de incubación y el medio de crecimiento afectaron la producción de CLPs por Bs006. Globalmente, los resultados de la presente investigación sugieren realizar estudios adicionales para encontrar una óptima combinación entre células de Bs006 y sobrenadante de su cultivo/extracto semi-purificado o una proporción de CLPs puros que no sea contraproducente para la planta. Teniendo en cuenta que en la rizósfera la producción de CLPs por la rizobacteria es mucho más baja que en un medio artificial y dada la tolerancia de FOX a los CLPs, son necesarias nuevas investigaciones para diseñar planes de manejo integrado de la enfermedad, que incluyan la alternativa de control biológico con B. amyloliquefaciens Bs006. (Texto tomado de la fuente). Incluye anexos Doctorado Doctor en Ciencias Agrarias Fitopatología Ciencias Agronómicas

Published
2017

5. Physiological Response of Cape Gooseberry Seedlings to Three Biological Control Agents Under Fusarium oxysporum f. sp. physali Infection.

Author

Chaves-Gómez JL, Chavez-Arias CC, Cotes Prado AM, Gómez-Caro S, and Restrepo-Díaz H

Subjects
Biological Control Agents, Humans, Plant Diseases, Seedlings, Fusarium, Infections, Physalis
Abstract

Cape gooseberry ( Physalis peruviana ) fruit has gained recognition owing to its nutritional value and versatility to be consumed processed or as a fresh product. These characteristics have made it an important product in both national and international markets. One of the main limitations for this crop is Fusarium wilt caused by the fungus Fusarium oxysporum f. sp. physalis , for which biological control is emerging as an alternative to conventional management with chemical synthesis products. However, information on the effect that biological control agents have on the growth and development of plants is scarce. In this research, the physiological response of cape gooseberry plants (stomatal conductance, leaf water potential, growth parameters, total chlorophyll, carotenoid, and proline and malondialdehyde contents) to the treatment with three potential biocontrol agents (BCAs) Trichoderma koningiopsis , Trichoderma virens , and Bacillus velezensis was determined. The study was conducted under greenhouse conditions; F. oxysporum was inoculated in the soil, and BCAs were soil drenched in the germination and transplanting stages. Plants inoculated with the pathogen and plants without inoculation were used as controls. It was found that the plants inoculated and treated with T. virens showed the lowest disease levels (area under the disease progress curve of 48.5 and disease severity index of 2.1). Additionally, they showed a lower water potential (-0.317 Mpa), a greater leaf area (694.7 cm 2 ), and a higher stomatal conductance (110.3 mmol m -2 s -1 ) compared with the control. Consequently, it can be concluded that T. virens can be a good candidate for the management of Fusarium wilt in the cape gooseberry crop.

Published
2020
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6. Plant odor analysis of potato: response of guatemalan moth to above- and belowground potato volatiles.

Author

Karlsson MF, Birgersson G, Cotes Prado AM, Bosa F, Bengtsson M, and Witzgall P

Subjects
Animals, Female, Male, Monoterpenes analysis, Monoterpenes pharmacology, Moths physiology, Oviposition drug effects, Phenylacetates, Pheromones, Plant Tubers chemistry, Sesquiterpenes analysis, Sesquiterpenes pharmacology, Moths drug effects, Odorants analysis, Solanum tuberosum chemistry
Abstract

The Guatemalan moth Tecia solanivora is an invasive pest of potato in Central and South America. The larvae infest potato tubers in the field as well as in storage facilities. The headspace of potato foliage and potato tubers was studied with regard to volatiles that mediate host-finding and oviposition in the Guatemalan moth. Foliage of three phenological stages, from sprouting to tuberization and flowering, released more than 30 sesquiterpenes. The main compounds were beta-caryophyllene, germacrene-D-4-ol, germacrene-D, kunzeaol, and (E,E)-alpha-farnesene. Sesquiterpenes accounted for >90% of the headspace of green plants, whereas fresh potato tubers emitted only trace amounts of a few sesquiterpenes. Screening of headspace collections with antennae of Guatemalan moth females showed a strong response to several sesquiterpenes and monoterpenes that were emitted from foliage only. In addition, antennae responded to methyl phenylacetate, a floral fragrance that was released in large amounts from flowering plants and that was also present in tuber headspace. Female and male moths were attracted to methyl phenylacetate; this compound may accordingly contribute to female attraction to tuber-bearing potato plants in the field as well as to potato tubers in storage. Oviposition tests showed that females lay eggs near mature flowering plants. Eggs were laid in soil close to the plant and not on potato stems and foliage, which may be due to avoidance of terpenoid compounds released from green plant parts at close range. The results support the concept that potato volatiles mediate host-finding and oviposition behavior and that these compounds may become useful tools for management of the Guatemalan moth.

Published
2009
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