Bioherbicidal action of Phoma dimorpha fermented broth on seeds and plants of Senna obtusifolia 1

Chaves Neto, José Roberto; Mazutti, Marcio Antonio; Zabot, Giovani Leone; Tres, Marcus Vinícius

doi:10.1590/1983-40632020v5056894

ABSTRACT

The weed Senna obtusifolia causes severe damages to pasture areas in Brazil, due to its high production and seed spread. This study aimed to evaluate the bioherbicidal action of Phoma dimorpha fermented broth in the pre-emergence and post-emergence of S. obtusifolia. The experimental design was completely randomized, with two treatments, one with and other without the application of the fermented broth. The bioherbicidal effects were measured in bioassays of pre-emergence (germination percentage), detached leaves (phytotoxicity) and post-emergence (phytotoxicity, plant height and fresh plant mass). The application of the fermented broth provided a pre-emergence bioherbicidal action, inhibiting the seed germination in 100 %. In detached leaves, it caused leaf necrosis and death on the ninth day after the application. In the post-emergence, this application caused moderate symptoms, such as leaf spots and reduction in the weed plant size. It was concluded that the P. dimorpha fermented broth has a potential herbicidal action and, therefore, represents an alternative in the development of bioproducts for a sustainable weed control in pastures.

KEYWORDS:
Senna obtusifolia; biological control; phytotoxicity; weed

RESUMO

A planta daninha Senna obtusifolia causa severos danos em áreas de pastagens no Brasil, devido à sua elevada produção e disseminação de sementes. Objetivou-se avaliar a ação bioherbicida do caldo fermentado de Phoma dimorpha na pré-emergência e pós-emergência de S. obtusifolia. O delineamento experimental utilizado foi inteiramente casualizado, com dois tratamentos, um com e outro sem aplicação do caldo fermentado. Os efeitos bioherbicidas foram mensurados em bioensaios de pré-emergência (porcentagem de germinação), folhas destacadas (fitotoxicidade) e pós-emergência (fitotoxicidade, altura de planta e massa fresca de planta). A aplicação do caldo fermentado proporcionou ação bioherbicida em pré-emergência, inibindo em 100 % a germinação das sementes. Em folhas destacadas, ocasionou necrose e morte das folhas no nono dia após a aplicação. Na pós-emergência, essa aplicação ocasionou sintomas moderados, como manchas nas folhas e redução no tamanho da planta daninha. Conclui-se que o caldo fermentado de P. dimorpha possui ação herbicida potencial e, por isso, representa uma alternativa no desenvolvimento de bioprodutos para o controle sustentável de plantas daninhas em pastagens.

PALAVRAS-CHAVE:
Fedegoso; controle biológico; fitotoxidade; planta daninha

INTRODUCTION

The increasing weed infestation in growing areas may be responsible for significant reductions in crop yields. Several studies confirm the toxic potential and greater competitive power of weeds over cultivated plants, which have generated not only losses in the quality of agricultural products, but also in yield (28-68 % in large crops such as soybean and cotton), thus generating high economic losses (Pisula & Meiners 2010PISULA, N. L.; MEINERS, S. J. Relative allelopathic potential of invasive plant species in a young disturbed woodland. Journal of the Torrey Botanical Society, v. 137, n. 1, p. 81-87, 2010. , Suriyagoda et al. 2014SURIYAGODA, L.; COSTA, W. A. J. M.; LAMBERS, H. Growth and phosphorus nutrition of rice when inorganic fertiliser application is partly replaced by straw under varying moisture availability in sandy and clay soils. Plant Soil, v. 384, n. 1-2, p. 53-68, 2014. , Bajwa et al. 2016BAJWA, A. A.; SADIA, S.; ALI, H. H.; JABRAN, K.; PEERZADA, A. M.; CHAUHAN, B. S. Biology and management of two important Conyza weeds: a global review. Environmental Science and Pollution Research, v. 23, n. 24, p. 24694-24710, 2016. ).

The weed species most frequently found in pastures, orchards, annual and perennial plants in Brazil, and also in other countries, is Senna obtusifolia (L.) H. S. Irwin & Barneby, popularly known in Brazil as “fedegoso”, due to its characteristic bad odor, and also known as “bush-pasture”, due to the damage it causes to pastures. Native of the American continent, it is classified as a bushy and woody plant, with approximately 70-160 cm of height (Lorenzi 2002LORENZI, H. Plantas daninhas do Brasil: terrestres e aquáticas, parasitas e tóxicas. 4. ed. Nova Odessa: Instituto Plantarum de Estudos da Flora, 2002.).

Its potential as a weed is associated with its high seed production, as when the pods reach maturity, they spread their germinating seeds at the beginning of the rainy season. They are able to germinate and bloom over a wide temperature range (18-36 ºC); therefore, the seeds are the main way of propagation. In addition to these problematic characteristics, its competitive ability and toxicity to domestic animals cause problems in agricultural and pasture areas (Walker & Oliver 2008WALKER, E. R.; OLIVER, L. R. Translocation and absorption of glyphosate in flowering sicklepod (Senna obtusifolia). Weed Science , v. 56, n. 3, p. 338-343, 2008., Peres et al. 2010PERES, M. T. L. P.; CÂNDIDO, A. C. S.; BONILLA, M. B.; FACCENDA, O.; HESS, S. C. Phytotoxic potential of Senna occidentalis and Senna obtusifolia. Acta Scientiarum. Biological Sciences, v. 32, n. 3, p. 305-309, 2010. ).

Weed plant control is reached by cultural, mechanical, chemical or biological activities. In the last five decades, the use of chemical herbicides is the main measure of weed control systems (Jabran et al. 2015JABRAN, K.; MAHAJAN, G.; SARDANA, V.; CHAUHAN, B. S. Allelopathy for weed control in agricultural systems. Crop Protection , v. 72, n. 1, p. 57-65, 2015. ). Despite the widespread use and effectiveness of herbicides in the weed control, in recent years, weeds with multiple resistance to the action of certain chemical molecules have occurred (Jabran et al. 2015JABRAN, K.; MAHAJAN, G.; SARDANA, V.; CHAUHAN, B. S. Allelopathy for weed control in agricultural systems. Crop Protection , v. 72, n. 1, p. 57-65, 2015. , Meuller-Steover et al. 2016MEULLER-STEOVER, D.; NYBROE, O.; BARAIBAR, B.; LODDO, D.; EIZENBERG, H.; FRENCH, K.; SØNDERSKOV, M.; NEVE, P.; PELTZER, D. A.; MACZEY, N.; CHRISTENSEN, S. Contribution of the seed microbiome to weed management. Weed Research, v. 56, n. 5, p. 335-339, 2016. ).

Because of the difficult control of certain weed species, as well as the potential negative impacts of chemicals on the environment and human health, alternative methods are being developed, which are environmentally safe and biodegradable in nature, in order to reduce the use of synthetic herbicides (Bajwa et al. 2016BAJWA, A. A.; SADIA, S.; ALI, H. H.; JABRAN, K.; PEERZADA, A. M.; CHAUHAN, B. S. Biology and management of two important Conyza weeds: a global review. Environmental Science and Pollution Research, v. 23, n. 24, p. 24694-24710, 2016. ). The biological control is an alternative for the substitution of agrochemicals, favoring the reduction of their use and minimizing the damages caused to the environment (Schwan-Estrada et al. 2000SCHWAN-ESTRADA, K. R. F.; STANGARLIN, J. R.; CRUZ, E. E. S. Uso de extratos vegetais no controle de fungos fitopatogênicos. Floresta, v. 30, n. 1-2, p. 129-137, 2000.).

Biologically active secondary metabolites coming from fermented media of microorganisms are used in the agricultural environment for biological control. These offer several benefits, such as a greater specificity to the target plant, rapid degradation and reduction in the use of synthetic herbicides, being considered economically and environmentally viable (Baque et al. 2012BAQUE, M. A.; MOH, S. H.; LEE, E. J.; ZHONG, J. J.; PAEK, K. Y. Production of biomass and useful compounds from adventitious roots of high-value added medicinal plants using bioreactor. Biotechnology Advances, v. 30, n. 6, p. 1255-1267, 2012. , Cordeau et al. 2016CORDEAU, S.; TRIOLET, M.; WAYMAN, S.; STEINBERG, C.; GUILLEMINA, J-P. Bioherbicides: dead in the water?: a review of the existing products for integrated weed management. Crop Protection, v. 87, n. 1, p. 44-49, 2016.). Among the sources of secondary metabolites, fungi are the most studied microorganism producers, since several species of endophytic fungi are considered a potential source of natural products, being an important source for the selection of agents of interest to the biological control (Baque et al. 2012BAQUE, M. A.; MOH, S. H.; LEE, E. J.; ZHONG, J. J.; PAEK, K. Y. Production of biomass and useful compounds from adventitious roots of high-value added medicinal plants using bioreactor. Biotechnology Advances, v. 30, n. 6, p. 1255-1267, 2012. ).

The Phoma fungi are a source of secondary metabolites with high biological activity, as some species secrete secondary metabolites, which may be used for the manufacturing of products with bio-biocidal activity, as well as others, aimed at the biological control of phytopathogenic fungi and insects (Wijeratne et al. 2013WIJERATNE, E. M. K.; HE, H.; FRANZBLAU, S. G.; HOFFMAN, A. M.; GUNATILAKA, A. A. L. Phomapyrrolidones A-C, antitubercular alkaloids from the endophytic fungus Phoma sp. NRRL 46751. Journal of Natural Products, v. 76, n. 10, p. 1860-1865, 2013. ). Several studies have shown that fungi of this genus produce a large variety of secondary metabolites with biological potential and they may be used for the formulation of bioproducts aimed at the agricultural environment (Hubbard et al. 2014HUBBARD, M.; HYNES, R. K.; ERLANDSON, M.; BAILEY, K. L. The biochemistry behind biopesticide efficacy. Sustainable Chemical Processes, v. 2, n. 18, p. 1-8, 2014. , Brun et al. 2016BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016. , Todero et al. 2018bTODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b. ).

This study aimed to evaluate the bioherbicidal action of a fermented broth produced from Phoma dimorpha fungus in the pre-emergence and post-emergence of S. obtusifolia.

MATERIAL AND METHODS

The bioassays were conducted at the Universidade Federal de Santa Maria (UFMS), in Santa Maria, Rio Grande do Sul state, Brazil, under laboratory (pre-emergence and detached leaf) and greenhouse (post-emergence) conditions, from May to July 2018. The microorganism used to obtain the fermented broth was a P. dimorpha (NRRL 43879) fungus strain originated from the collection of the Biotec Factory laboratory (UFMS).

The S. obtusifolia seeds used to perform the bioassays were collected in a pasture area located in Cuité de Mamanguape, Paraíba state, Brazil (06º55’15.4”S and 35º17’12.8”W).

The fungus strain was maintained in Petri dishes containing BDA medium at 8 ºC, and subcultured every 15 days. For the fermentation process, Petri dishes containing the active growing fungus were kept in a bacteriological oven for 7 days, at 28 ºC, from which 2 mycelium disks of 6 mm were removed and transferred to Erlenmeyer flasks with 130 mL of a liquid medium containing potato extract (200 g L^-1), dextrose (20 g L^-1), peptone (10 g L^-1), yeast extract (7.5 g L^-1), ammonium sulfate [(NH₄)₂SO₄; 2 g L^-1], ferrous sulfate (FeSO₄.7H₂O; 1g L^-1) and magnesium sulfate (MgSO₄; 0.5 g L^-1 and MnSO₄.H₂O; 1g L^-1) (Zhang et al. 2012ZHANG, L.; WANG, S-Q.; LI, X-J.; ZHANG, A-L.; ZHANG, Q.; GAO, J-M. New insight into the stereochemistry of botryosphaeridione from a Phoma endophyte. Journal of Molecular Structure, v. 1016, n. 1, p. 72-75, 2012.), previously sterilized by autoclaving at 121 ºC, for 30 min. The flasks were maintained at 28 ºC, under agitation of 120 rpm, for 10 days (Innova 44R, New Brunswick) (Klaic et al. 2017KLAIC, R.; SALLET, D.; FOLETTO, E. L.; JACQUES, R. J. S.; GUEDES, J. V. C.; KUHN, R. C.; MAZUTTI, M. A. Optimization of solid-state fermentation for bioherbicide production by Phoma sp. Brazilian Journal of Chemical Engineering, v. 34, n. 2, p. 377-384, 2017. ). After this period, the cells were separated from the fermented broth through a filter paper with 14 µm pores in vacuum filtration with a Büchner funnel. The cell free fermented broth was stored in a freezer at -20 ºC, for 15 days. Then, three different bioassays were performed in order to verify the bioherbicidal action of the P. dimorpha fermented broth in pre-emergence, detached leaves and post-emergence of S. obtusifolia.

In pre-emergence, the bioherbicidal action of the P. dimorpha fermented broth was evaluated through a germination test, with the seeds being initialy submitted to the overcoming mechanical scarification dormancy method (Bortolini et al. 2011BORTOLINI, M. F.; KOEHLER, H. S.; ZUFFELLATO-RIBAS, K. C.; MALAVASI, M. M.; FORTES, A. M. T. Superação de dormência em sementes de Gleditschia amorphoides Taub. Ciência Rural, v. 41, n. 5, p. 823-827, 2011. ).

The germination test was carried out in a completely randomized design, with two treatments (with and without application of the fermented broth) and eight replicates of 25 seeds. For this, sheets of filter paper (Germitest^®) moistened with 4 mL of the different treatments were used. Then, the boxes were conditioned in a BOD germination chamber at 25 ºC, with photoperiod of 12/12 h of light/darkness. The evaluations were carried out daily until reaching stabilization, counting the number of seeds that germinated, having as a criterion the protrusion of the minimum radicle of 2 mm in length (Brasil 2009BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. Regras para análise de sementes. Brasília, DF: MAPA/ACS, 2009.).

Another bioassay in a completely randomized design, with the same two treatments (without and with application of the fermented broth), was used to assess the bioherbicidal action in the leaf. Four replications of one leaf each were used. With this aim, S. obtusifolia leaves with 15 days of growth were collected. These leaves were arranged in gerbox boxes previously disinfected with 70 % ethanol and lined with two sheets of filter paper. Then, 3 mL of the fermented broth were applied and, for the control treatment, the same volume of distilled water was applied with the use of an automatic pipette on cotton wrapped in the leaf petiole. The gerbox boxes were conditioned in a BOD incubator chamber with temperature of 25 ºC and photoperiod of 12/12 h of light/darkness. The evaluations were carried out on the 3rd, 6th and 9th day after the application (Pedras & Ahiahonu 2004PEDRAS, M. S.; AHIAHONU, P. W. Phytotoxin production and phytoalexin elicitation by the phytopathogenic fungus Sclerotinia sclerotiorum. Journal of Chemical Ecology, v. 30, n. 11, p. 2163-2179, 2004., Todero et al. 2018bTODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b. ) for the analysis of the appearance of symptoms, according to the scale presented in Table 1.

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Table 1
Scale for evaluation of the phytotoxicity percentage in detached leaves and plants, developed based on the concepts applied to the toxicity assessments¹ 1 Source: SBCPD (1995). .

In post-emergence, the assay to evaluate the bioherbicidal action of the P. dimorpha fermented broth on the weed was carried out in a greenhouse. The S. obtusifolia culture was used for the subsequent application and evaluation of the treatments. The same two treatments were assigned completely randomized to ten replications each. Each experimental unit was composed of a polyethylene vessel with volume of 180 mL, filled with Macplant^® commercial substrate. Initially, three seeds were sown in each vessel, and after the emergence of the seedlings, thinning was performed and only one plant was maintained per vessel, which was cultivated until the end of the experiment.

The application of the fermented broth was carried out at approximately 15 days after the emergence of the plants. For the application, a costal/manual, CO₂-pressurized sprayer and 300 L ha^-1 of syrup volume (Brun et al. 2016BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016. ), was used. Phytotoxicity evaluations were performed at 15 days after the treatment (Todero et al. 2018bTODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b. ) and the leaf damage to plants was estimated visually, based on the scale presented in Table 1. Then, the plant height (mm) and fresh plant mass (g) were also measured. Based on the plant height data, the growth reduction (%) of the treatment with application of the raw fungus fermented broth was calculated in relation to the control treatment (without fermented broth application).

The data were submitted to the normality and homogeneity errors tests, and then to the F-test of Anova, and the treatment means were compared by the Tukey test, adopting a significance level of 5 %. For this, the Sisvar software (Ferreira 2014FERREIRA, D. F. Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência & Agrotecnologia, v. 38, n. 2, p. 109-112, 2014. ) was used.

RESULTS AND DISCUSSION

A bioherbicidal action of the P. dimorpha fermented broth on the germination percentage of S. obtusifolia seeds was observed (Table 2). The application of the fermented broth presented a complete inhibition of the germination, with effectiveness in the order of 100 % (Table 2 and Figure 1).

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Table 2
Mean germination percentage of Senna obtusifolia seeds resulting in normal seedlings after to the application of Phoma dimorpha fermented broth.

Figure 1
Phytotoxic test on seeds of Senna obtusifolia submitted to the application of Phoma dimorpha fermented broth. A) Control treatment (without fermented broth); B) seedling of the control treatment; C) treatment with application of the fermented broth; D) detail of the seed when the fermented broth was applied.

The seed germination inhibition observed in this study characterizes that the fungus fermented broth presents a bioherbicidal action and potential for the development of bioherbicides in the agricultural environment. Researches focused on weed biological control by application of secondary metabolites from fungi of the Phoma genus were also conducted by Cimmino et al. (2013)CIMMINO, A.; ANDOLFI, A.; ZONNO, M. C.; AVOLIO, F.; BERESTETSKIY, A.; VURRO, M.; EVIDENTE, A. Chenopodolin: a phytotoxic unrearranged ent-pimaradiene diterpene produced by Phoma chenopodicola, a fungal pathogen for chenopodium album biocontrol. Journal of Natural Products, v. 76, n. 7, p. 1291-1297, 2013., Hubbard et al. (2014)HUBBARD, M.; HYNES, R. K.; ERLANDSON, M.; BAILEY, K. L. The biochemistry behind biopesticide efficacy. Sustainable Chemical Processes, v. 2, n. 18, p. 1-8, 2014. , Evidente et al. (2015)EVIDENTE, M.; CIMMINO, A.; ZONNO, M. C.; MASI, M.; BERESTETSKYI, A.; SANTORO, E.; SUPERCHI, E.; VURRO, M.; EVIDENTE, A. Phytotoxins produced by Phoma chenopodiicola, a fungal pathogen of Chenopodium album. Phytochemistry, v. 117, n. 1, p. 482-488, 2015. and Todero et al. (2018b)TODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b. . These authors characterized phytotoxic effects in pre-emergence (germination reduction) and post-emergence (spots, chlorosis, deformations and collapse of leaves, besides necrosis in plants) of several weed species.

Similar results were reported by Brun et al. (2016)BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016. , when evaluating the herbicide potential of raw fermented broth from Phoma sp. submerged in bioreactor on the seed germination of Cucumis sativus and Sorghum bicolor. They found that the application of this fermented broth caused a reduction in the germination, with percentages of 100 % and 84 % of inhibition, respectively. These authors suggest that a compound named Pyrrolo [1,2-a] pyrazine-1,4-dione, hexahydro-3- (2-methylpropyl), found as a major compound in the chemical characterization of fermented extracts, has a herbicidal effect.

Todero et al. (2018a)TODERO, I.; CONFORTIN, T. C.; SOARES, J. F.; BRUN, T.; LUFT, L.; RABUSKE, J. E.; KUHN, R. C.; TRES, M. V.; ZABOT, G. L.; MAZUTTI, M. A. Concentration of metabolites from Phoma sp. using microfiltration membrane for increasing bioherbicidal activity. Environmental Technology, v. 22, n. 1, p. 1-9, 2018a. , when evaluating the effectiveness of the bioherbicidal activity of Phoma sp. fermented broth concentrated by membrane from submerged fermentation, found that a 30 % concentrate in the pre-emergence of Bidens pilosa and Amaranthus retroflexus seeds reached an inhibition of 100 % in all the dilutions used. These results are in agreement with those found in the present research, confirming the bioherbicidal action of the fermented broth produced by representatives of this fungus genus.

The percentage of phytotoxicity, as a function of the application of P. dimropha fermented broth, on leaves of S. obtusifolia is shown in Table 3. In the detached leaves of S. obtusifolia, there was yellowing (40 % of phytotoxicity) since the first evaluation (72 h after the application), intensifying up to the last evaluation, performed at 9 days after the application of the raw fermented broth, when there were severe lesions with yellowing and marked necrosis, characterizing 90 % of phytotoxicity (Table 3 and Figure 2).

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Table 3
Phytotoxicity on leaves of Senna obtusifolia at 3, 6 and 9 days after the application (DAP) of Phoma dimorpha fermented broth.

Figure 2
Phytotoxic effects on leaves of Senna obtusifolia after 3, 6 and 9 days after the application (DAP) of Phoma dimorpha fermented broth (T1: control treatment without the fermented broth; T2: treatment with the fermented broth).

Brun et al. (2016)BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016. and Todero et al. (2018a)TODERO, I.; CONFORTIN, T. C.; SOARES, J. F.; BRUN, T.; LUFT, L.; RABUSKE, J. E.; KUHN, R. C.; TRES, M. V.; ZABOT, G. L.; MAZUTTI, M. A. Concentration of metabolites from Phoma sp. using microfiltration membrane for increasing bioherbicidal activity. Environmental Technology, v. 22, n. 1, p. 1-9, 2018a. reported similar phytotoxicity percentages, when evaluating the phytotoxic effect of Phoma sp. raw fermented broth on leaves of C. sativus. Yellowing and necrosis occurred on detached leaves of this species after 72 h of application (30 % of phytotoxicity), leading to the total leaf death in the last evaluation (80 % of phytotoxicity).

Similar results were also described by Graupner et al. (2003)GRAUPNER, P. R.; CARR, A.; CLANCY, E.; GILBERT, J.; BAILEY, K. L.; DERBY, J. A.; GERWICK, B. C. The macrocidins: novel cyclic tetramic acids with herbicidal activity produced by Phoma macrostoma. Journal of Natural Products , v. 66, n. 12, p. 1558-1561, 2003. , Vikrant et al. (2006)VIKRANT, P.; VERMA, K. K.; RAJAK, R. C.; PANDEY, A. K. Characterization of a phytotoxin from Phoma herbarum for management of Parthenium hysterophorus L. Journal of Phytopathology, v. 154, n. 1, p. 461-468, 2006. and Bailey et al. (2011a)BAILEY, K. L.; PITT, W. M.; LEGGETT, F.; SHEEDY, C.; DERBY, J. Determining the infection process of Phoma macrostoma that leads to bioherbicidal activity on broadleaved weeds. Biological Control , v. 59, n. 2, p. 268-276, 2011a., when evaluating the application effectiveness of raw fermented broth of different Phoma species obtained by submerged fermentation on leaves of Cirsium arvense and Parthenium hysterophorus (white losna) plants. They observed a fast yellowing and chlorosis, evolving for leaf necrosis and death, as well as growth reduction.

The application of P. dimropha fermented broth resulted in leaf necrosis (30 % of phytotoxicity) of S. obtusifolia plants at 15 days after the application (Table 4 and Figure 3). According to Mello et al. (2003)MELLO, S. C. M.; TEIXEIRA, E. A.; BORGES NETO, C. R. Fungos e seus metabólitos no controle da tiririca. Brasília, DF: Embrapa Recursos Genéticos e Biotecnologia, 2003. (Documentos, 104)., substances which are present in fermented fungi may cause symptoms such as chlorosis, wilt, waterlogging and alteration in plant growth.

According to Bailey et al. (2011b)BAILEY, K. L.; PITT, W. M.; FALK, S.; DERBY, J . The effects of Phoma macrostoma on nontarget plant and target weed species. Biological Control, v. 58, n. 1, p. 379-386, 2011b., the macrocidin A and Z compounds produced by the Phoma macrostoma fungus have as their mode of action the inhibition of the carotenoid biosynthesis, inducing chlorosis, bleaching and eventual necrosis in susceptible plants. These authors observed that compounds applications produce symptoms of photodegradation in broadleaf weeds such as Cirsium arvense, Taraxacum officinale and Stellaria media.

Similar results were found by Cimmino et al. (2013)CIMMINO, A.; ANDOLFI, A.; ZONNO, M. C.; AVOLIO, F.; BERESTETSKIY, A.; VURRO, M.; EVIDENTE, A. Chenopodolin: a phytotoxic unrearranged ent-pimaradiene diterpene produced by Phoma chenopodicola, a fungal pathogen for chenopodium album biocontrol. Journal of Natural Products, v. 76, n. 7, p. 1291-1297, 2013., who evaluated the isolated potential of the chenopodoline metabolite produced by the P. chenopodicola fungus in leaves of Cirsium arvense and Setaria viridis. They reported symptoms such as necrosis, wilt and foliar tissue degradation. Todero et al. (2018a)TODERO, I.; CONFORTIN, T. C.; SOARES, J. F.; BRUN, T.; LUFT, L.; RABUSKE, J. E.; KUHN, R. C.; TRES, M. V.; ZABOT, G. L.; MAZUTTI, M. A. Concentration of metabolites from Phoma sp. using microfiltration membrane for increasing bioherbicidal activity. Environmental Technology, v. 22, n. 1, p. 1-9, 2018a. reported that the application of fermented Phoma sp. in post-emergence of C. sativus plants caused yellowing at 7 days after the application, evolving up to the occurrence of wilting and necrotic lesions. In addition, these authors observed alterations in plant growth.

Figure 3
Phytotoxic effect on Senna obtusifolia plants at 15 days after the application of Phoma dimorpha fermented broth (T1: control treatment without the fermented broth; T2: treatment with the fermented broth).

A significant difference (p < 0.05) was observed for plant height with the application of the P. dimorpha fermented broth on S. obtusifolia plants, resulting in a lower height (Table 4). Similar results were observed by Klaic et al. (2017)KLAIC, R.; SALLET, D.; FOLETTO, E. L.; JACQUES, R. J. S.; GUEDES, J. V. C.; KUHN, R. C.; MAZUTTI, M. A. Optimization of solid-state fermentation for bioherbicide production by Phoma sp. Brazilian Journal of Chemical Engineering, v. 34, n. 2, p. 377-384, 2017. , who found a reduction of 30 % in the plant height of the bioindicator C. sativus, when submitted to the same fermented broth.

Thumbnail

Table 4
Means¹ 1 Means with distinct letters are statistically different by the Tukey test at 5 % of probability. MSD: minimum significant difference; CV: coefficient of variation. of plant phytotoxicity, plant height, growth reduction and fresh mass of Senna obtusifolia plants at 15 days after the application of Phoma dimorpha fermented broth.

The influence of the P. dimorpha fermented broth on the plant height of S. obtusifolia was confirmed by the reduction in the growth percentage (Table 4). Hence, it was possible to conclude that the application of this fermented broth causes a significant growth reduction in plants of S. obtusifolia. Similar results were found by Todero et al. (2018b)TODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b. , when evaluating formulations with secondary metabolites from submerged Phoma sp. with herbicidal action against the weed species Bidens pilosa, Amaranthus retroflexus and Conyza canadensis. These authors observed a reduction of 31 % in plant height. According to Gronwald et al. (2002)GRONWALD, J. W.; PLAISANCE, K. L.; IDE, D. A.; WYSE, D. L. Assessment of Pseudomonas syringae pv. tagetis as a biocontrol agent for Canada thistle. Weed Science, v. 50, n. 3, p. 397-404, 2002., the weed growth reduction is a factor to determine the bioherbicide potential.

The fresh mass of S. obtusifolia plants was also reduced with the application of the P. dimorpha fermented broth (Table 4). This reduction, as a function of the fermented broth, was also observed by Brun et al. (2016)BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016. on C. sativus plants at 7 days after the application of Phoma sp. Similarly, Klaic et al. (2017)KLAIC, R.; SALLET, D.; FOLETTO, E. L.; JACQUES, R. J. S.; GUEDES, J. V. C.; KUHN, R. C.; MAZUTTI, M. A. Optimization of solid-state fermentation for bioherbicide production by Phoma sp. Brazilian Journal of Chemical Engineering, v. 34, n. 2, p. 377-384, 2017. , after optimizing the solid state fermentation process for the production of the bioherbicide through Phoma sp. secondary metabolites, also observed its phytotoxicity on C. sativus plants, with a reduction of 20 % in the fresh mass, in comparison to the control treatment.

CONCLUSION

The application of Phoma dimorpha fermented broth provides a pre-emergence bioherbicidal action on Senna obtusifolia. This treatment inhibited the seed germination in 100 %. On detached leaves, it caused leaf necrosis and death at the ninth day after the application. In the post-emergence, the application caused leaf spots, as well as reduced the size and fresh mass of this weed. Thus, the P. dimorpha fermented broth has proved to be an alternative for the development of weed management bioproducts, with a view of reducing the use of the synthetic herbicides and preventing pollution in pasture ecosystems.

REFERENCES

BAILEY, K. L.; PITT, W. M.; FALK, S.; DERBY, J . The effects of Phoma macrostoma on nontarget plant and target weed species. Biological Control, v. 58, n. 1, p. 379-386, 2011b.
BAILEY, K. L.; PITT, W. M.; LEGGETT, F.; SHEEDY, C.; DERBY, J. Determining the infection process of Phoma macrostoma that leads to bioherbicidal activity on broadleaved weeds. Biological Control , v. 59, n. 2, p. 268-276, 2011a.
BAJWA, A. A.; SADIA, S.; ALI, H. H.; JABRAN, K.; PEERZADA, A. M.; CHAUHAN, B. S. Biology and management of two important Conyza weeds: a global review. Environmental Science and Pollution Research, v. 23, n. 24, p. 24694-24710, 2016.
BAQUE, M. A.; MOH, S. H.; LEE, E. J.; ZHONG, J. J.; PAEK, K. Y. Production of biomass and useful compounds from adventitious roots of high-value added medicinal plants using bioreactor. Biotechnology Advances, v. 30, n. 6, p. 1255-1267, 2012.
BORTOLINI, M. F.; KOEHLER, H. S.; ZUFFELLATO-RIBAS, K. C.; MALAVASI, M. M.; FORTES, A. M. T. Superação de dormência em sementes de Gleditschia amorphoides Taub. Ciência Rural, v. 41, n. 5, p. 823-827, 2011.
BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. Regras para análise de sementes Brasília, DF: MAPA/ACS, 2009.
BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016.
CIMMINO, A.; ANDOLFI, A.; ZONNO, M. C.; AVOLIO, F.; BERESTETSKIY, A.; VURRO, M.; EVIDENTE, A. Chenopodolin: a phytotoxic unrearranged ent-pimaradiene diterpene produced by Phoma chenopodicola, a fungal pathogen for chenopodium album biocontrol. Journal of Natural Products, v. 76, n. 7, p. 1291-1297, 2013.
CORDEAU, S.; TRIOLET, M.; WAYMAN, S.; STEINBERG, C.; GUILLEMINA, J-P. Bioherbicides: dead in the water?: a review of the existing products for integrated weed management. Crop Protection, v. 87, n. 1, p. 44-49, 2016.
EVIDENTE, M.; CIMMINO, A.; ZONNO, M. C.; MASI, M.; BERESTETSKYI, A.; SANTORO, E.; SUPERCHI, E.; VURRO, M.; EVIDENTE, A. Phytotoxins produced by Phoma chenopodiicola, a fungal pathogen of Chenopodium album. Phytochemistry, v. 117, n. 1, p. 482-488, 2015.
FERREIRA, D. F. Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência & Agrotecnologia, v. 38, n. 2, p. 109-112, 2014.
GRAUPNER, P. R.; CARR, A.; CLANCY, E.; GILBERT, J.; BAILEY, K. L.; DERBY, J. A.; GERWICK, B. C. The macrocidins: novel cyclic tetramic acids with herbicidal activity produced by Phoma macrostoma. Journal of Natural Products , v. 66, n. 12, p. 1558-1561, 2003.
GRONWALD, J. W.; PLAISANCE, K. L.; IDE, D. A.; WYSE, D. L. Assessment of Pseudomonas syringae pv. tagetis as a biocontrol agent for Canada thistle. Weed Science, v. 50, n. 3, p. 397-404, 2002.
HUBBARD, M.; HYNES, R. K.; ERLANDSON, M.; BAILEY, K. L. The biochemistry behind biopesticide efficacy. Sustainable Chemical Processes, v. 2, n. 18, p. 1-8, 2014.
JABRAN, K.; MAHAJAN, G.; SARDANA, V.; CHAUHAN, B. S. Allelopathy for weed control in agricultural systems. Crop Protection , v. 72, n. 1, p. 57-65, 2015.
KLAIC, R.; SALLET, D.; FOLETTO, E. L.; JACQUES, R. J. S.; GUEDES, J. V. C.; KUHN, R. C.; MAZUTTI, M. A. Optimization of solid-state fermentation for bioherbicide production by Phoma sp. Brazilian Journal of Chemical Engineering, v. 34, n. 2, p. 377-384, 2017.
LORENZI, H. Plantas daninhas do Brasil: terrestres e aquáticas, parasitas e tóxicas. 4. ed. Nova Odessa: Instituto Plantarum de Estudos da Flora, 2002.
MELLO, S. C. M.; TEIXEIRA, E. A.; BORGES NETO, C. R. Fungos e seus metabólitos no controle da tiririca Brasília, DF: Embrapa Recursos Genéticos e Biotecnologia, 2003. (Documentos, 104).
MEULLER-STEOVER, D.; NYBROE, O.; BARAIBAR, B.; LODDO, D.; EIZENBERG, H.; FRENCH, K.; SØNDERSKOV, M.; NEVE, P.; PELTZER, D. A.; MACZEY, N.; CHRISTENSEN, S. Contribution of the seed microbiome to weed management. Weed Research, v. 56, n. 5, p. 335-339, 2016.
PEDRAS, M. S.; AHIAHONU, P. W. Phytotoxin production and phytoalexin elicitation by the phytopathogenic fungus Sclerotinia sclerotiorum. Journal of Chemical Ecology, v. 30, n. 11, p. 2163-2179, 2004.
PERES, M. T. L. P.; CÂNDIDO, A. C. S.; BONILLA, M. B.; FACCENDA, O.; HESS, S. C. Phytotoxic potential of Senna occidentalis and Senna obtusifolia. Acta Scientiarum. Biological Sciences, v. 32, n. 3, p. 305-309, 2010.
PISULA, N. L.; MEINERS, S. J. Relative allelopathic potential of invasive plant species in a young disturbed woodland. Journal of the Torrey Botanical Society, v. 137, n. 1, p. 81-87, 2010.
SCHWAN-ESTRADA, K. R. F.; STANGARLIN, J. R.; CRUZ, E. E. S. Uso de extratos vegetais no controle de fungos fitopatogênicos. Floresta, v. 30, n. 1-2, p. 129-137, 2000.
SOCIEDADE BRASILEIRA DA CIÊNCIA DAS PLANTAS DANINHAS (SBCPD). Procedimentos para instalação, avaliação e análise de experimentos com herbicidas Londrina: SBCPD, 1995.
SURIYAGODA, L.; COSTA, W. A. J. M.; LAMBERS, H. Growth and phosphorus nutrition of rice when inorganic fertiliser application is partly replaced by straw under varying moisture availability in sandy and clay soils. Plant Soil, v. 384, n. 1-2, p. 53-68, 2014.
TODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b.
TODERO, I.; CONFORTIN, T. C.; SOARES, J. F.; BRUN, T.; LUFT, L.; RABUSKE, J. E.; KUHN, R. C.; TRES, M. V.; ZABOT, G. L.; MAZUTTI, M. A. Concentration of metabolites from Phoma sp. using microfiltration membrane for increasing bioherbicidal activity. Environmental Technology, v. 22, n. 1, p. 1-9, 2018a.
VIKRANT, P.; VERMA, K. K.; RAJAK, R. C.; PANDEY, A. K. Characterization of a phytotoxin from Phoma herbarum for management of Parthenium hysterophorus L. Journal of Phytopathology, v. 154, n. 1, p. 461-468, 2006.
WALKER, E. R.; OLIVER, L. R. Translocation and absorption of glyphosate in flowering sicklepod (Senna obtusifolia). Weed Science , v. 56, n. 3, p. 338-343, 2008.
WIJERATNE, E. M. K.; HE, H.; FRANZBLAU, S. G.; HOFFMAN, A. M.; GUNATILAKA, A. A. L. Phomapyrrolidones A-C, antitubercular alkaloids from the endophytic fungus Phoma sp. NRRL 46751. Journal of Natural Products, v. 76, n. 10, p. 1860-1865, 2013.
ZHANG, L.; WANG, S-Q.; LI, X-J.; ZHANG, A-L.; ZHANG, Q.; GAO, J-M. New insight into the stereochemistry of botryosphaeridione from a Phoma endophyte. Journal of Molecular Structure, v. 1016, n. 1, p. 72-75, 2012.

Publication Dates

Publication in this collection
03 Apr 2020
Date of issue
2020

History

Received
29 Jan 2019
Accepted
28 May 2019
Published
01 Nov 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited

[1] BAILEY, K. L.; PITT, W. M.; FALK, S.; DERBY, J . The effects of Phoma macrostoma on nontarget plant and target weed species. Biological Control, v. 58, n. 1, p. 379-386, 2011b.

[2] BAILEY, K. L.; PITT, W. M.; LEGGETT, F.; SHEEDY, C.; DERBY, J. Determining the infection process of Phoma macrostoma that leads to bioherbicidal activity on broadleaved weeds. Biological Control , v. 59, n. 2, p. 268-276, 2011a.

[3] BAJWA, A. A.; SADIA, S.; ALI, H. H.; JABRAN, K.; PEERZADA, A. M.; CHAUHAN, B. S. Biology and management of two important Conyza weeds: a global review. Environmental Science and Pollution Research, v. 23, n. 24, p. 24694-24710, 2016.

[4] BAQUE, M. A.; MOH, S. H.; LEE, E. J.; ZHONG, J. J.; PAEK, K. Y. Production of biomass and useful compounds from adventitious roots of high-value added medicinal plants using bioreactor. Biotechnology Advances, v. 30, n. 6, p. 1255-1267, 2012.

[5] BORTOLINI, M. F.; KOEHLER, H. S.; ZUFFELLATO-RIBAS, K. C.; MALAVASI, M. M.; FORTES, A. M. T. Superação de dormência em sementes de Gleditschia amorphoides Taub. Ciência Rural, v. 41, n. 5, p. 823-827, 2011.

[6] BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. Regras para análise de sementes Brasília, DF: MAPA/ACS, 2009.

[7] BRUN, T.; RABUSKE, J. E.; TODERO, I.; ALMEIDA, T. C.; JUNIOR, J. J. D.; ARIOTTI, G.; CONFORTIN, T. C.; ARNEMANN, J. A.; KUHN, R. C.; GUEDES, J. V. C.; MAZUTTI, M. A. Production of bioherbicide by Phoma sp. in a stirred-tank bioreactor. 3 Biotech, v. 6, n. 2, p. 230-239, 2016.

[8] CIMMINO, A.; ANDOLFI, A.; ZONNO, M. C.; AVOLIO, F.; BERESTETSKIY, A.; VURRO, M.; EVIDENTE, A. Chenopodolin: a phytotoxic unrearranged ent-pimaradiene diterpene produced by Phoma chenopodicola, a fungal pathogen for chenopodium album biocontrol. Journal of Natural Products, v. 76, n. 7, p. 1291-1297, 2013.

[9] CORDEAU, S.; TRIOLET, M.; WAYMAN, S.; STEINBERG, C.; GUILLEMINA, J-P. Bioherbicides: dead in the water?: a review of the existing products for integrated weed management. Crop Protection, v. 87, n. 1, p. 44-49, 2016.

[10] EVIDENTE, M.; CIMMINO, A.; ZONNO, M. C.; MASI, M.; BERESTETSKYI, A.; SANTORO, E.; SUPERCHI, E.; VURRO, M.; EVIDENTE, A. Phytotoxins produced by Phoma chenopodiicola, a fungal pathogen of Chenopodium album. Phytochemistry, v. 117, n. 1, p. 482-488, 2015.

[11] FERREIRA, D. F. Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência & Agrotecnologia, v. 38, n. 2, p. 109-112, 2014.

[12] GRAUPNER, P. R.; CARR, A.; CLANCY, E.; GILBERT, J.; BAILEY, K. L.; DERBY, J. A.; GERWICK, B. C. The macrocidins: novel cyclic tetramic acids with herbicidal activity produced by Phoma macrostoma. Journal of Natural Products , v. 66, n. 12, p. 1558-1561, 2003.

[13] GRONWALD, J. W.; PLAISANCE, K. L.; IDE, D. A.; WYSE, D. L. Assessment of Pseudomonas syringae pv. tagetis as a biocontrol agent for Canada thistle. Weed Science, v. 50, n. 3, p. 397-404, 2002.

[14] HUBBARD, M.; HYNES, R. K.; ERLANDSON, M.; BAILEY, K. L. The biochemistry behind biopesticide efficacy. Sustainable Chemical Processes, v. 2, n. 18, p. 1-8, 2014.

[15] JABRAN, K.; MAHAJAN, G.; SARDANA, V.; CHAUHAN, B. S. Allelopathy for weed control in agricultural systems. Crop Protection , v. 72, n. 1, p. 57-65, 2015.

[16] KLAIC, R.; SALLET, D.; FOLETTO, E. L.; JACQUES, R. J. S.; GUEDES, J. V. C.; KUHN, R. C.; MAZUTTI, M. A. Optimization of solid-state fermentation for bioherbicide production by Phoma sp. Brazilian Journal of Chemical Engineering, v. 34, n. 2, p. 377-384, 2017.

[17] LORENZI, H. Plantas daninhas do Brasil: terrestres e aquáticas, parasitas e tóxicas. 4. ed. Nova Odessa: Instituto Plantarum de Estudos da Flora, 2002.

[18] MELLO, S. C. M.; TEIXEIRA, E. A.; BORGES NETO, C. R. Fungos e seus metabólitos no controle da tiririca Brasília, DF: Embrapa Recursos Genéticos e Biotecnologia, 2003. (Documentos, 104).

[19] MEULLER-STEOVER, D.; NYBROE, O.; BARAIBAR, B.; LODDO, D.; EIZENBERG, H.; FRENCH, K.; SØNDERSKOV, M.; NEVE, P.; PELTZER, D. A.; MACZEY, N.; CHRISTENSEN, S. Contribution of the seed microbiome to weed management. Weed Research, v. 56, n. 5, p. 335-339, 2016.

[20] PEDRAS, M. S.; AHIAHONU, P. W. Phytotoxin production and phytoalexin elicitation by the phytopathogenic fungus Sclerotinia sclerotiorum. Journal of Chemical Ecology, v. 30, n. 11, p. 2163-2179, 2004.

[21] PERES, M. T. L. P.; CÂNDIDO, A. C. S.; BONILLA, M. B.; FACCENDA, O.; HESS, S. C. Phytotoxic potential of Senna occidentalis and Senna obtusifolia. Acta Scientiarum. Biological Sciences, v. 32, n. 3, p. 305-309, 2010.

[22] PISULA, N. L.; MEINERS, S. J. Relative allelopathic potential of invasive plant species in a young disturbed woodland. Journal of the Torrey Botanical Society, v. 137, n. 1, p. 81-87, 2010.

[23] SCHWAN-ESTRADA, K. R. F.; STANGARLIN, J. R.; CRUZ, E. E. S. Uso de extratos vegetais no controle de fungos fitopatogênicos. Floresta, v. 30, n. 1-2, p. 129-137, 2000.

[24] SOCIEDADE BRASILEIRA DA CIÊNCIA DAS PLANTAS DANINHAS (SBCPD). Procedimentos para instalação, avaliação e análise de experimentos com herbicidas Londrina: SBCPD, 1995.

[25] SURIYAGODA, L.; COSTA, W. A. J. M.; LAMBERS, H. Growth and phosphorus nutrition of rice when inorganic fertiliser application is partly replaced by straw under varying moisture availability in sandy and clay soils. Plant Soil, v. 384, n. 1-2, p. 53-68, 2014.

[26] TODERO, I.; CONFORTIN, T. C.; LUFT, L.; BRUN, T.; UGALDE, G. A.; ALMEITA, T. C.; ARNEMANN, J. A.; ZABOT, G. L.; MAZUTTI, M. A. Formulation of a bioherbicide with metabolites from Phoma sp. Scientia Horticulturae, v. 241, n. 1, p. 285-292, 2018b.

[27] TODERO, I.; CONFORTIN, T. C.; SOARES, J. F.; BRUN, T.; LUFT, L.; RABUSKE, J. E.; KUHN, R. C.; TRES, M. V.; ZABOT, G. L.; MAZUTTI, M. A. Concentration of metabolites from Phoma sp. using microfiltration membrane for increasing bioherbicidal activity. Environmental Technology, v. 22, n. 1, p. 1-9, 2018a.

[28] VIKRANT, P.; VERMA, K. K.; RAJAK, R. C.; PANDEY, A. K. Characterization of a phytotoxin from Phoma herbarum for management of Parthenium hysterophorus L. Journal of Phytopathology, v. 154, n. 1, p. 461-468, 2006.

[29] WALKER, E. R.; OLIVER, L. R. Translocation and absorption of glyphosate in flowering sicklepod (Senna obtusifolia). Weed Science , v. 56, n. 3, p. 338-343, 2008.

[30] WIJERATNE, E. M. K.; HE, H.; FRANZBLAU, S. G.; HOFFMAN, A. M.; GUNATILAKA, A. A. L. Phomapyrrolidones A-C, antitubercular alkaloids from the endophytic fungus Phoma sp. NRRL 46751. Journal of Natural Products, v. 76, n. 10, p. 1860-1865, 2013.

[31] ZHANG, L.; WANG, S-Q.; LI, X-J.; ZHANG, A-L.; ZHANG, Q.; GAO, J-M. New insight into the stereochemistry of botryosphaeridione from a Phoma endophyte. Journal of Molecular Structure, v. 1016, n. 1, p. 72-75, 2012.

Damage (%)	Description of the main categories
0-20	No injury or effect
20-40	Slight injury and/or growth reduction with rapid recovery
40-60	Moderate injury and/or growth reduction with slow or definitive recovery
60-80	Severe injury and/or reduction of non-recoverable growth and/or reduction of the stand
80-100	Complete destruction or just a few live plants

Treatment	Germination (%)¹ 1 Means with distinct letters are statistically different by the Tukey test at 5 % of probability. MSD: minimum significant difference; CV: coefficient of variation.
Control (without fermented broth)	99.00 ± 1.51 a
With fermented broth	0.00 ± 0.00 b
MSD	1.15
CV (%)	2.16

Treatment	Phytotoxicity (%)¹ 1 Means with distinct letters are statistically different by the Tukey test at 5 % of probability. MSD: minimum significant difference; CV: coefficient of variation.
Treatment	3 DAP	6 DAP	9 DAP
Control (without fermented broth)	0.00 ± 0.00 b	0.00 ± 0.00 b	0.00 ± 0.00 b
With fermented broth	40.00 ± 8.16 a	70.00 ± 8.16 a	90.00 ± 8.16 a
MSD	9.99	9.99	9.99
CV (%)	28.87	16.50	12.83

Treatment	Phytotoxicity (%)	Plant height (cm)	Growth reduction (%)	Fresh mass (g)
Control (without broth)	0.00 ± 0.00 b	8.43 ± 0.76 a	0.00 ± 0.00 b	1.97 ± 0.45 a
With fermented broth	30.00 ± 4.08 a	6.93 ± 0.70 b	20.80 ± 2.07 a	1.20 ± 0.14 b
MSD	2.71	0.69	8.48	0.31
CV (%)	19.25	10.06	26.68	21.15

Brasil

Brasil

Bioherbicidal action of Phoma dimorpha fermented broth on seeds and plants of Senna obtusifolia ¹

Ação bioherbicida de caldo fermentado de Phoma dimorpha em sementes e plantas de Senna obtusifolia

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History