GOOSEGRASS RESISTANT TO GLYPHOSATE IN BRAZIL

TAKANO, H.K.; OLIVEIRA JR., R.S.; CONSTANTIN, J.; BRAZ, G.B.P.; GHENO, E.A.

doi:10.1590/S0100-83582017350100013

ABSTRACT

Several cases of herbicide resistance in goosegrass have been confirmed worldwide. Reports of control failures after glyphosate application have been observed, especially in the Midwest region of Paraná State. The objective of this study was to evaluate the existence of goosegrass populations resistant to glyphosate. For this, 25 populations collected in two consecutive seasons (2013/2014 and 2014/2015) were sown and grown in greenhouse. Glyphosate dose-response curve experiments were performed using doses of 0, 60, 120, 240, 480, 960, 1,920, 3,840, 7,680 and 15,360 g a.e. ha^-1. The application stages were from two to three tillers (E1) for the populations of 2013/2014 and E1 and five to six tillers (E2) for the populations of 2014/2015. Furthermore, three of the populations supposedly considered resistant in these experiments (populations 7, 19 and 25) have had their F1 submitted to the herbicide dose-response test in order to verify whether the resistance was inheritable. With the results obtained in this study, it was concluded that the populations 19 and 25, from Campo Mourão and Luziânia (Midwest of Paraná) are the first confirmed cases of goosegrass resistant to glyphosate in Brazil (RF = 3.99 to 6.81), following all the criteria for confirmation of new weed resistance cases.

Keywords:
Eleusine indica; dose-response; application timming; resistance factor

RESUMO

Diversos casos de resistência de capim-pé-de-galinha têm sido reportados mundialmente. Relatos de falhas de controle pela aplicação de glyphosate têm sido cada vez mais frequentes, especialmente na região Centro-Oeste do Paraná. O objetivo deste trabalho foi avaliar a existência de populações de capim-pé-de-galinha resistentes ao glyphosate. Para isso, 25 populações coletadas em duas safras consecutivas (2013/2014 e 2014/2015) foram semeadas e cultivadas em casa de vegetação. Experimentos de curva de dose-resposta de glyphosate foram realizados utilizando-se as doses de 0, 60, 120, 240, 480, 960, 1.920, 3.840, 7.680 e 15.360 g e.a. ha-1. O estádio de aplicação foi de dois a três perfilhos (E1) para as populações de 2013/2014 e E1 e cinco a seis perfilhos (E2) para as populações de 2014/2015. Além disso, três das populações consideradas supostamente resistentes nesses experimentos (populações 7, 19 e 25) tiveram suas gerações F1 submetidas ao ensaio de dose-resposta do herbicida, visando verificar se a resistência era herdável. A partir dos resultados obtidos neste trabalho, conclui-se que as populações 19 e 25, oriundas de Campo Mourão e Luziânia (Centro-Oeste do Estado do Paraná), constituem o primeiro relato de capim pé-de-galinha resistente ao glyphosate no Brasil (RF = 3,99-6,81), atendendo a todos os critérios estabelecidos para confirmação de novos casos de resistência.

Palavras-chave:
Eleusine indica; dose-resposta; estádio de aplicação; fator de resistência

INTRODUCTION

The weed resistance to herbicides is one of the main challenges in agriculture worldwide, especially in recent years with the number of cases of species resistant to herbicides increasing substantially. There are currently 41 cases of weed resistant to herbicide in Brazil, of which seven species are resistant to glyphosate, as follows, Lolium perenne ssp. multiflorum, Conyza bonariensis, C. canadensis, C. sumatrensis, Digitaria insularis, Chloris elata and Amaranthus palmeri (Carvalho et al., 2011Carvalho L.B. et al. Detection of sourgrass (Digitaria insularis) biotypes resistant to glyphosate in Brazil. Weed Sci., 2011;59:171-6.; Heap, 2016Heap I. International survey of herbicide-resistant weeds. [acessado em: 27 abr 2016] Disponível em: Disponível em: http://www.weedscience.org .
http://www.weedscience.org... ).

For a population of a certain weed to be considered as a new case of resistance, it must meet the following criteria: 1. Survive and reproduce at a dose of herbicide normally lethal to the wild population; 2. Confirmation with results obtained through science-based protocols; 3. The resistance should be inheritable to subsequent generations; 4. The problem must have a practical impact on the field; 5. Botanical identification of the species of the weed in question (Heap, 2005Heap I. Criteria for confirmation of herbicide-resistant weeds - with specific emphasis on confirming low level resistance. [acessado em: 27 abr. 2005] Disponível em: Disponível em: http://Weedscience.Org/Documents/Resistancecriterion.Pdf .
http://Weedscience.Org/Documents/Resista... ; Cristoffoleti and Lopez-Ovejero, 2008).

The goosegrass is considered one of the most troublesome weeds, and is found in many regions of the world. It presents a fast growth, autogamy, C4 cycle and high seed production (over 120,000 plant^-1), which are spread by the wind (Kissmann and Groth, 1997Kissmann K.G., Groth D. Plantas infestantes e nocivas. 2ª. ed. São Paulo: BASF, 1997.; Mueller et al., 2011Mueller T.C. Glyphosate-resistant goosegrass (Eleusine indica) confirmed in Tennessee. Weed Sci . 2011;59:562-6.; Takano et al., 2016Takano H.K. et al. Growth, development and seed production of goosegrass. Planta Daninha . 2016;34:249-58..).

The first glyphosate resistance report on goosegrass occurred in orchards in Malaysia in 1997 (Lee and Ngim, 2000Lee L.J., Ngim J. A first report of glyphosate-resistant goosegrass (Eleusine indica (L) Gaertn) in Malaysia. Pest Manage Sci. 2000;56:336-9.). Thereafter, resistant populations were found in different continents around the world (Yuan et al., 2005Yuan C.I. et al. Glyphosate-resistant goosegrass in Taiwan: cloning of target enzyme (EPSPS) and molecular assay of field populations. Plant Prot Bull. 2005;47:251-61.; Kaundun et al, 2008Kaundun S.S. et al. Importance of the P106S target-site mutation in conferring resistance to glyphosate in a goosegrass (Eleusine indica) population from the Philippines. Weed Sci . 2008;56:637-46.; Mueller et al, 2011Mueller T.C. Glyphosate-resistant goosegrass (Eleusine indica) confirmed in Tennessee. Weed Sci . 2011;59:562-6.; Molin et al., 2013Molin W.T., Wright A.A., Nandula V.K. Glyphosate-Resistant Goosegrass from Mississippi. Agronomy. 2013;3:474-87.; Heap, 2016Heap I. International survey of herbicide-resistant weeds. [acessado em: 27 abr 2016] Disponível em: Disponível em: http://www.weedscience.org .
http://www.weedscience.org... ). In addition to the resistance to glyphosate, some populations of goosegrass may have resistance up to four mechanisms of action simultaneously (EPSPS, ACCase, Photosystem I and GS-GOGAT) (Jalaludin et al., 2014Jalaludin, A. et al. Multiple resistance across glufosinate, glyphosate, paraquat and ACCase-inhibiting herbicides in an Eleusine indica population. Weed Res. 2014;55:82-9.).

Although there are no goosegrass population resistant to glyphosate in Brazil, populations with low levels of resistance have been detected in Rio Grande do Sul (Vargas et al., 2013Vargas L. et al. Low level resistance of goosegrass (Eleusine indica) to glyphosate in Rio Grande do Sul-Brazil. Planta Daninha . 2013;31:677-86.). Even though it is important for the scientific community, this kind of resistance has low practical impact on the field, since the recommendation dose is normally lethal to these populations. However, several technicians and producers in the Midwest region of Paraná state have seen goosegrass plants surviving the application of glyphosate in their crops.

Considering this context, the objective of this study was to evaluate the existence of goosegrass populations resistant to glyphosate in Brazil.

MATERIAL AND METHODS

Goosegrass seeds were collected in harvests in 2013/2014 and 2014/2015 in areas with a history of glyphosate applications and grown in succession system soybean/corn, on which the soybean cultivation, in all cases, were cultivars resistant to glyphosate. In these areas, the collection was done in at least 20 random plants not controlled by the application of glyphosate in the soybean's post emergence, forming a bulk.

In the season 2013/2014, the collections were held in 13 locations in the states of Parana, Santa Catarina and Goiás. In the same period, a well known susceptible population was collected and used as a standard. Depending on the results obtained in the first year, in the season 2014/2015, the collection was carried out only in the state of Paraná, in 12 locations. Each location was considered a distinct population of goosegrass and the collection period was during the months of January and February in 2014 and 2015 (Table 1). Plants in reproductive stage and representative of each population were properly identified in the Herbarium of the State University of Maringá (HUEM).

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Table 1
Geographical coordinates of the different collection sites of Eleusine indica populations in seasons 2013/2014 and 2014/2015

To confirm the resistance in science-based protocol, three experiments were conducted. The experiment 1 was made for 14 populations from 2013/2014, the experiment 2 for 13 populations from 2014/2015, and the experiment 3, for the F1 generation of the populations 7, 19 and 25. All experiments were conducted in a completely randomized outlining. Experiments 1 and 3 were arranged in double factorial scheme, with the first factor composed of different populations and the second factor for 10 doses of glyphosate (0, 60, 120, 240, 480, 960, 1,920, 3,840, 7,680 and 15,360 g e.a. ha^-1). The experiment 2, on the other hand, was arranged in triple factorial scheme had it's the first factor composed of different populations, the second factor by the same 10 doses of glyphosate and the third factor of two stages of development.

In all experiments, the experimental units were composed by jars of 1 dm³, which were filled with soil up to the half presenting pH values in water of 5,9; 11,89 g dm^-3 of C; 720 g kg^-1 of sand; 20 g kg^-1 of silt and 260 g kg^-1 of clay. Above this layer of soil, the experimental units were filled with coconut fiber substrate, aiming to prevent the emergence of possible seeds of weeds present in the soil used.

Thirty seeds of each population were sown per pot and after the emergence a thinning was performed, keeping three seedlings per experimental unit. For the 2013/2014 populations, the stage of the plants at the time of the application was from two to three tillers per plant, with two to three leaves per tiller and 5-8 cm (E1). As for the 2014/2015 populations, in addition to E1, plants were also evaluated in 5-6 tiller stage and 15 cm. Surviving plants from populations 7, 19 and 25 were grown separately and their seeds were collected to form their F1 generations.

The applications were made by spraying pressurized CO₂, equipped with a 1.5 m long bar containing three spray tips AI 110.02 type (0.5 m between tips), with pressure of 2.5 kgf cm^-², providing an application volume equivalent to 200 L ha^-1. Applications were always held in the morning in suitable weather conditions.

The recommended registration dose of glyphosate to control goosegrass varies between 720 and 1,200 g e.a. ha^-1 in more than 80% of this herbicide's trademarks (Brazil, 2015), which is the range of doses normally used by most producers in the region. In addition, several literature studies report that the application of 840 g e.a. ha^-1 of glyphosate provides goosegrass control above 96% (Corbett et al., 2004Corbett J.L. et al. Weed efficacy evaluations of bromoxynil, glufosinate, glyphosate and pyrithiobac and sulfosate. Weed Technol . 2004;18:443-53.; Thomas et al., 2006Thomas W.E. et al. Glyphosate-resistant cotton (Gossypium hirsutum) response and weed management with trifloxysulfuron, glyphosate, prometryn and MSMA. Weed Technol . 2006;20:6-13.; Clewis et al., 2006Clewis S.B. et al. Weed management with S-metolachlor and glyphosate mixtures in glyphosate-resistant strip and conventional-tillage cotton (Gossypium hirsutum L.). Weed Technol. 2006;20:232-41.). Therefore, the average value recommendation was considered as a reference dose for setting the dose response curve (960 g ha^-1).

Was evaluated the control percentage (visual scale from 0 to 100%) at 28 DAA, where 0% represents no injury and 100% represents the plant's death. At the end of this period, we also determined the dry mass of the aerial part, by collecting the plant's aerial part which survived the application and subsequent drying in a greenhouse at 65 ^oC for 72 hours.

Data were submitted to analysis of variance and regression, adjusted to logistic nonlinear regression model proposed by Streibig (1988Streibig J.C. Herbicide bioassay. Weed Res . 1988;28:479-84.):

where: y is the percentage control or the dry mass of the aerial part; x is the dose of the herbicide (g e.a. ha^-1); and a, b and c are the equation's estimated parameters, in such a way that: a is the amplitude existent between the maximum and the minimum point of the variable; b is the dose which promotes a 50% response of the variable and c is the declivity of the curve around b.

One of the terms integrating the equation of the logistic model (b) is an estimate of C₅₀ or GR_50, which represent the herbicide dose required for control or reduction of the plant's dry mass by 50% (Christoffoleti 2002Christoffoleti P.J. Curvas de dose-resposta de populações resistente e suscetível de Bidens pilosa L. aos herbicidas inibidores da ALS. Sci Agric. 2002;59:513-9.). Although one of the logistic model parameters is an estimate of the value of C_50, it was also decided to perform its mathematical calculation by inverse equation, according to the discussion proposed by Carvalho et al. (2005Carvalho S.J.P. et al. Curvas de dose-resposta para avaliação do controle de fluxos de emergência de plantas daninhas pelo herbicida imazapic. Planta Daninha. 2005;23:535-42.).

In addition to the C₅₀ or GR₅₀ values, were also obtained the values of C₈₀ and GR₈₀, using the inverse equation. The estimate of these values is important from a practical point of view, since it is the dose required to achieve minimum levels of control considered acceptable in the field. Based on the values of C₅₀ and GR₅₀, we calculated the resistance factor (RF = C₅₀ or GR₅₀ from the supposedly resistant population/C₅₀ or GR₅₀ from the susceptible population) to the resistant populations. The resistance factor expresses the number of times on which the necessary dose to control 50% of the resistant population is superior to the dose that controls 50% of the susceptible population (Hall et al., 1998Hall L.M. et al. Resistance to acetolactate synthase inhibitors and quinclorac in a biotype of false clover (Gallium spurium). Weed Sci . 1998;46:390-6.).

RESULTS AND DISCUSSION

The goosegrass plants had their species identified as Eleusine indica (Linn.) Gaertn, Poaceae family (protocol number: HUEM 30031).

The analysis of data variance showed there were significance for the variation sources, as well as the interaction between populations and doses. There was a proper adjustment of the model to the control data and dry mass of the aerial part, setting a, b and c parameters of the log-logistic equation. The R² values were close to 1, indicating adequate model adjustment to the observed data. From the adjusted models, it was possible to calculate, to the control data and the dry mass of aerial part, the doses necessary to control 50% and 80% of each population tested.

For the variable control in the season 2013/2014, with the exception of population 8, all populations showed RF>1.0 (Table 2). However, in most of them, the glyphosate dosage necessary for the control or reduction of dry mass was 80% lower than the dose recommended for the control of the species. On the other hand, populations 5 and 7 presented C₈₀ of 1,217.73 and 1,443.01 g e.a. ha^-1 and GR₈₀ 1,102.74 and 1,248.20, respectively, which is greater than the average dose recommended for the species. In these cases where the recommended dose did not provide satisfactory control, the RF varied between 4.16 and 7.99. For the susceptible population, the dry mass of the aerial part was reduced by 80% with 172.18 g e.a. ha^-1 of glyphosate.

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Table 2
Estimated glyphosate doses for control and reduction of dry mass in the aerial part in 505 and 80% and their resistance factors for different populations of Eleusine indica on stage of two to three tillers (E1) (season 2013/2014)

In the season 2014/2015, for the first stage (E1), based on the results of C₅₀ and GR_50, all populations showed RF>1.0 (Table 3).The values of C₈₀ and GR₈₀ were higher than the recommended dose only for the populations 19 and 25. In the case of population 19, the value of GR₈₀ (1,653.49 g e.a. ha^-1) was higher than the highest recommended dose ever recorded for goosegrass control (1,620 g e.a. ha^-1).

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Table 3
Estimated doses of glyphosate for control and reduction of dry mass from the aerial part in 50% and 80% and their resistance factors for different populations of Eleusine indica for applications performed in stage of two to three tillers (E1) (season 2014/2015)

The results obtained for the 2015 population which received application in E2 stage showed lower susceptibility to glyphosate in all populations compared to the E1 stage (Table 4). Except for the populations 23 and 24, C₈₀ and GR₈₀ values of all populations were greater than 960 g e.a. ha^-1. This shows the importance of the stage of the plants at the time of the application, which may be collaborating with application failures observed in the field.

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Table 4
Estimated doses of glyphosate for control and reduction of dry mass from the aerial part in 50% and 80% and their resistance factors from different populations of Eleusine indica for applications carried out in stage of five to six tillers (E2) (season 2014/2015)

Glyphosate applications in goosegrass in early development stage (E1) usually imply more effective, because it is the moment of greatest susceptibility of these plants to herbicides (Ulguim et al., 2013Ulguim A.R. et al. Manejo de capim pé de galinha em lavouras de soja transgênica resistente ao glifosato. Pesq Agropec Bras. 2013;48:17-24.). One of the goosegrass characteristics is its rapid tillering capacity, as the stadium of 2-3 tillers and 5-6 tillers can be reached at nine and twenty-four days after its emergence (DAE) respectively (Takano et al., 2016Takano H.K. et al. Growth, development and seed production of goosegrass. Planta Daninha . 2016;34:249-58.). The rapid growth of this species suggests that, for operational reasons, applications in the field cannot always be carried out in suitable stadium for its control.

Nevertheless, all populations had higher C₅₀ or GR₅₀ than the susceptible population. Populations 17, 19 and 25 showed values of C₈₀ and GR₈₀ higher than the maximum recommended dose of glyphosate to control goosegrass, while the susceptible population was controlled at 80% with 478.18 g e.a. ha^-1 of glyphosate. The resistance factors in these three populations varied from 3.69 to 5.37.

The results obtained for the F1 generation of populations 7, 19, and 25 showed that the resistance was inherited only in populations from season 2014/2015 (19 and 25) (Table 5). In the case of the population 7 (season 2013/2014), the RF>1.0, however the values of C₈₀ and GR₈₀ were below the recommended dose (653.27 and 647.27 g e.a. ha^-1, respectively) not attending, to this population, the heritability criteria of the resistance. On the other hand, the values of these parameters were above 1,200 g e.a. ha^-1 for populations 19 and 25 and the resistance factors varied from 3.99 to 6.81, meeting these populations heritability criteria.

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Table 5
Estimated doses of glyphosate for control and reduction of dry mass from the aerial part in 50% and 80% and their resistance factors from different populations of Eleusine indica for applications carried out in stage of two to three tillers (E1)

The population of goosegrass in Rio Grande do Sul characterized as low-level resistant to glyphosate showed a resistance factor of 1.52 (Vargas et al., 2013Vargas L. et al. Low level resistance of goosegrass (Eleusine indica) to glyphosate in Rio Grande do Sul-Brazil. Planta Daninha . 2013;31:677-86.). As for the resistance factors obtained for the populations 19 and 25 in this study (RF = 3.99 to 6.81) are more similar to reports of goosegrass resistant to glyphosate in Tennessee, USA (RF = 3,1 to 7,4) (Mueller et al., 2011Mueller T.C. Glyphosate-resistant goosegrass (Eleusine indica) confirmed in Tennessee. Weed Sci . 2011;59:562-6.) and in Malaysia (RF = 8 to 12) (Lee and Ngim, 2000Lee L.J., Ngim J. A first report of glyphosate-resistant goosegrass (Eleusine indica (L) Gaertn) in Malaysia. Pest Manage Sci. 2000;56:336-9.).

The results obtained in this study show that populations 19 and 25 meet all the criteria set for the confirmation of a case of resistance by Heap (2005)Heap I. Criteria for confirmation of herbicide-resistant weeds - with specific emphasis on confirming low level resistance. [acessado em: 27 abr. 2005] Disponível em: Disponível em: http://Weedscience.Org/Documents/Resistancecriterion.Pdf .
http://Weedscience.Org/Documents/Resista... .Criterion 1: the plants from these populations have survived and reproduced after their exposure to a herbicide dose that was lethal to the susceptible population; Criterion 2: the resistance factors were higher than one (RF = 3,99 to 6,81) and the recommended dose to the species did not provide satisfactory control (C₈₀ e GR₈₀ > 1,200 g e.a. ha^-1); Criterion 3: the plants from the F1 generation of these populations were also considered resistant; Criterion 4: control flaws complaints are being observed on the field; Criterion 5: random plants of these populations were properly classified as Eleusine indica.

In this sense, complementary measures handling with herbicides should be designed to reduce the selection pressure, such as the association and the use of herbicides with different mechanisms of action (Shaner, 2000Shaner D.L. The impact of glyphosate tolerant crops on the use of other herbicides and on resistance management. Pest Manage Sci . 2000;56:320-6.; Johnson and Gibson, 2006Johnson W.G., Gibson K.D. Glyphosate resistant weeds and resistance management strategies: an Indiana grower perspective. Weed Technol . 2006;20:768-72.).Research papers show that ACCase inhibitors are one of the alternatives for goosegrass control (Ulguim et al., 2013Ulguim A.R. et al. Manejo de capim pé de galinha em lavouras de soja transgênica resistente ao glifosato. Pesq Agropec Bras. 2013;48:17-24.). However, it is important to remember that goosegrass resistance to this mechanism of action has been previously reported in Brazil (Vidal et al., 2006Vidal R.A. et al. Resistência de Eleusine indica aos inibidores de ACCase. Planta Daninha . 2006;24:163-71.), which shows that the continuous application of graminicides may not be effective in all situations. Alternatively, other mechanisms of action may exhibit effectiveness in controlling these populations, such as GS-GOGAT inhibitors, carotenoid synthesis inhibitors (Ulguim et al., 2013), cell division inhibitors, and photosystem I inhibitors (Molin et al., 2013Molin W.T., Wright A.A., Nandula V.K. Glyphosate-Resistant Goosegrass from Mississippi. Agronomy. 2013;3:474-87.).

The resistance mechanism to glyphosate in other countries' goosegrass involves replacement of a proline by serine or threonine at position 106 in the EPSPS gene (P106S or P106T) (Baerson et al., 2002Baerson S.R. et al. Glyphosate-resistant goosegrass. Identification of a mutation in the target enzyme 5-enolpyruvylshikimate-3-phosphate synthase. Plant Physiol. 2002; 129:1265-75.; Ng et al.2004Ng C.H. et al. Glyphosate resistance in Eleusine indica (L) Gaertn from different origins and polymerase chain reaction amplification of specific alleles. Austr J Agric Res. 2004;55:407-14.; Yu et al.2007Yu Q. et al. Glyphosate, paraquat and ACCase multiple herbicide resistance evolved in a Lolium rigidum biotype. Planta. 2007;225:499-513.; Kaundun et al, 2008Kaundun S.S. et al. Importance of the P106S target-site mutation in conferring resistance to glyphosate in a goosegrass (Eleusine indica) population from the Philippines. Weed Sci . 2008;56:637-46., 2011Kaundun S.S. et al. A novel P106L mutation in EPSPS and an unknown mechanism (s) act additively to confer resistance to glyphosate in a South African Lolium rigidum population. J Agric Food Chem. 2011;59:3227-33.), or the EPSPS gene amplification in resistant plants (Chen et al., 2015Chen J. et al. Mutations and amplification of EPSPS gene confer resistance to glyphosate in goosegrass (Eleusine indica). Planta. 2015;242:859-68.). Such single mutation confers intermediate levels of glyphosate resistance (RF = 2 to 4). However, double mutation at positions 106 (T102I and P106S) of the mutant population can confer higher levels of resistance (RF>10) (Yu et al., 2015Yu Q. et al. Evolution of a double amino acid substitution in the 5-enolpyruvylshikimate-3-phosphate synthase in Eleusine indica conferring high-level glyphosate resistance. Plant Physiol . 2015;167:1440-7.). Nevertheless, the mechanism that confers resistance in populations from Brazil is still unknown. Therefore, further studies to elucidate the mechanism that confers resistance, as well as the development of new alternative tools for the management of resistant populations are needed.

With the results obtained in this study, it is concluded that the populations 19 and 25, coming from Campo Mourão and Luziânia (Midwest of Paraná), are the first report of goosegrass resistant to glyphosate in Brazil (RF = 3.99 to 6.81), meeting all the criteria for confirmation of new cases of resistance.

REFERENCES

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Carvalho L.B. et al. Detection of sourgrass (Digitaria insularis) biotypes resistant to glyphosate in Brazil. Weed Sci., 2011;59:171-6.
Chen J. et al. Mutations and amplification of EPSPS gene confer resistance to glyphosate in goosegrass (Eleusine indica). Planta. 2015;242:859-68.
Clewis S.B. et al. Weed management with S-metolachlor and glyphosate mixtures in glyphosate-resistant strip and conventional-tillage cotton (Gossypium hirsutum L.). Weed Technol. 2006;20:232-41.
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» http://www.weedscience.org
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Johnson W.G., Gibson K.D. Glyphosate resistant weeds and resistance management strategies: an Indiana grower perspective. Weed Technol . 2006;20:768-72.
Kaundun S.S. et al. Importance of the P106S target-site mutation in conferring resistance to glyphosate in a goosegrass (Eleusine indica) population from the Philippines. Weed Sci . 2008;56:637-46.
Kaundun S.S. et al. A novel P106L mutation in EPSPS and an unknown mechanism (s) act additively to confer resistance to glyphosate in a South African Lolium rigidum population. J Agric Food Chem. 2011;59:3227-33.
Kissmann K.G., Groth D. Plantas infestantes e nocivas. 2ª. ed. São Paulo: BASF, 1997.
Lee L.J., Ngim J. A first report of glyphosate-resistant goosegrass (Eleusine indica (L) Gaertn) in Malaysia. Pest Manage Sci. 2000;56:336-9.
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Ng C.H. et al. Glyphosate resistance in Eleusine indica (L) Gaertn from different origins and polymerase chain reaction amplification of specific alleles. Austr J Agric Res. 2004;55:407-14.
Shaner D.L. The impact of glyphosate tolerant crops on the use of other herbicides and on resistance management. Pest Manage Sci . 2000;56:320-6.
Streibig J.C. Herbicide bioassay. Weed Res . 1988;28:479-84.
Takano H.K. et al. Growth, development and seed production of goosegrass. Planta Daninha . 2016;34:249-58.
Thomas W.E. et al. Glyphosate-resistant cotton (Gossypium hirsutum) response and weed management with trifloxysulfuron, glyphosate, prometryn and MSMA. Weed Technol . 2006;20:6-13.
Ulguim A.R. et al. Manejo de capim pé de galinha em lavouras de soja transgênica resistente ao glifosato. Pesq Agropec Bras. 2013;48:17-24.
Vargas L. et al. Low level resistance of goosegrass (Eleusine indica) to glyphosate in Rio Grande do Sul-Brazil. Planta Daninha . 2013;31:677-86.
Vidal R.A. et al. Resistência de Eleusine indica aos inibidores de ACCase. Planta Daninha . 2006;24:163-71.
Yuan C.I. et al. Glyphosate-resistant goosegrass in Taiwan: cloning of target enzyme (EPSPS) and molecular assay of field populations. Plant Prot Bull. 2005;47:251-61.
Yu Q. et al. Glyphosate, paraquat and ACCase multiple herbicide resistance evolved in a Lolium rigidum biotype. Planta. 2007;225:499-513.
Yu Q. et al. Evolution of a double amino acid substitution in the 5-enolpyruvylshikimate-3-phosphate synthase in Eleusine indica conferring high-level glyphosate resistance. Plant Physiol . 2015;167:1440-7.

Publication Dates

Publication in this collection
2017

History

Received
27 Apr 2016
Accepted
30 May 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Baerson S.R. et al. Glyphosate-resistant goosegrass. Identification of a mutation in the target enzyme 5-enolpyruvylshikimate-3-phosphate synthase. Plant Physiol. 2002; 129:1265-75.

[2] Carvalho S.J.P. et al. Curvas de dose-resposta para avaliação do controle de fluxos de emergência de plantas daninhas pelo herbicida imazapic. Planta Daninha. 2005;23:535-42.

[3] Carvalho L.B. et al. Detection of sourgrass (Digitaria insularis) biotypes resistant to glyphosate in Brazil. Weed Sci., 2011;59:171-6.

[4] Chen J. et al. Mutations and amplification of EPSPS gene confer resistance to glyphosate in goosegrass (Eleusine indica). Planta. 2015;242:859-68.

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[8] Christoffoleti P.J., López-Ovejero R.F. Resistência das plantas daninhas a herbicidas: definições, bases e situação no Brasil e no mundo. In: Christoffoleti P.J., editor. Aspectos de resistência de plantas daninhas a herbicidas. 3ª.ed. Piracicaba: HRAC-BR, 2008. p.3-30.

[9] Hall L.M. et al. Resistance to acetolactate synthase inhibitors and quinclorac in a biotype of false clover (Gallium spurium). Weed Sci . 1998;46:390-6.

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[12] Jalaludin, A. et al. Multiple resistance across glufosinate, glyphosate, paraquat and ACCase-inhibiting herbicides in an Eleusine indica population. Weed Res. 2014;55:82-9.

[13] Johnson W.G., Gibson K.D. Glyphosate resistant weeds and resistance management strategies: an Indiana grower perspective. Weed Technol . 2006;20:768-72.

[14] Kaundun S.S. et al. Importance of the P106S target-site mutation in conferring resistance to glyphosate in a goosegrass (Eleusine indica) population from the Philippines. Weed Sci . 2008;56:637-46.

[15] Kaundun S.S. et al. A novel P106L mutation in EPSPS and an unknown mechanism (s) act additively to confer resistance to glyphosate in a South African Lolium rigidum population. J Agric Food Chem. 2011;59:3227-33.

[16] Kissmann K.G., Groth D. Plantas infestantes e nocivas. 2ª. ed. São Paulo: BASF, 1997.

[17] Lee L.J., Ngim J. A first report of glyphosate-resistant goosegrass (Eleusine indica (L) Gaertn) in Malaysia. Pest Manage Sci. 2000;56:336-9.

[18] Brasil. Ministério da Agricultura, Pecuária e Abastecimento. AGROFIT. 2015. [acessado em: 10 abr. 2016]. Disponível em: Disponível em: http://www.agricultura.gov.br
» http://www.agricultura.gov.br

[19] Molin W.T., Wright A.A., Nandula V.K. Glyphosate-Resistant Goosegrass from Mississippi. Agronomy. 2013;3:474-87.

[20] Mueller T.C. Glyphosate-resistant goosegrass (Eleusine indica) confirmed in Tennessee. Weed Sci . 2011;59:562-6.

[21] Ng C.H. et al. Glyphosate resistance in Eleusine indica (L) Gaertn from different origins and polymerase chain reaction amplification of specific alleles. Austr J Agric Res. 2004;55:407-14.

[22] Shaner D.L. The impact of glyphosate tolerant crops on the use of other herbicides and on resistance management. Pest Manage Sci . 2000;56:320-6.

[23] Streibig J.C. Herbicide bioassay. Weed Res . 1988;28:479-84.

[24] Takano H.K. et al. Growth, development and seed production of goosegrass. Planta Daninha . 2016;34:249-58.

[25] Thomas W.E. et al. Glyphosate-resistant cotton (Gossypium hirsutum) response and weed management with trifloxysulfuron, glyphosate, prometryn and MSMA. Weed Technol . 2006;20:6-13.

[26] Ulguim A.R. et al. Manejo de capim pé de galinha em lavouras de soja transgênica resistente ao glifosato. Pesq Agropec Bras. 2013;48:17-24.

[27] Vargas L. et al. Low level resistance of goosegrass (Eleusine indica) to glyphosate in Rio Grande do Sul-Brazil. Planta Daninha . 2013;31:677-86.

[28] Vidal R.A. et al. Resistência de Eleusine indica aos inibidores de ACCase. Planta Daninha . 2006;24:163-71.

[29] Yuan C.I. et al. Glyphosate-resistant goosegrass in Taiwan: cloning of target enzyme (EPSPS) and molecular assay of field populations. Plant Prot Bull. 2005;47:251-61.

[30] Yu Q. et al. Glyphosate, paraquat and ACCase multiple herbicide resistance evolved in a Lolium rigidum biotype. Planta. 2007;225:499-513.

[31] Yu Q. et al. Evolution of a double amino acid substitution in the 5-enolpyruvylshikimate-3-phosphate synthase in Eleusine indica conferring high-level glyphosate resistance. Plant Physiol . 2015;167:1440-7.

Population	Season	Coordinates	City	State
Susceptible	2014	S 23^o 19'35'' W 52^o 00'05''	Mandaguaçu	PR
1	2014	S 24^o 27'24'' W 54^o 16'16''	Rondon	PR
2	2014	S 24^o 20'42'' W 53^o 24'57''	Jesuítas	PR
3	2014	S 23^o 51'10'' W 52^o 11'29''	Quinta do Sol	PR
4	2014	S 24^o 13'25'' W 52º 27'56''	Goioerê	PR
5	2014	S 24^o 20'34'' W 52^o 33'25''	Mamborê	PR
6	2014	S 23^o 19'11'' W 51^o 18'54''	Rolândia	PR
7	2014	S 24^o 46'32'' W 51^o 45'42''	Pitanga	PR
8	2014	S 18^o 46'37'' W 52^o 37'02''	Chapadao do Céu	GO
9	2014	S 26^o 23'22'' W 52^o 48'45''	São Lourenço do Oeste	SC
10	2014	S 24^o 12'59'' W 52^o 57'46''	Campo Mourão	PR
11	2014	S 24^o 18'39'' W 52^o 43'16''	Juranda	PR
12	2014	S 24^o 12'46'' W 52^o 48'32''	Boa Esperança	PR
13	2014	S 24^o 06'27'' W 52^o 51'25''	Campo Mourão	PR
14	2015	S 24^o 04'11'' W 52^o 52'51''	Moreira Sales	PR
15	2015	S 24^o 13'44'' W 52^o 50'53''	Goioerê	PR
16	2015	S 24^o 14'06'' W 52^o 52'22''	Boa Esperança	PR
17	2015	S 24^o 01'52'' W 52^o 49'27''	Janiópolis	PR
18	2015	S 24^o 02'27'' W 52^o 52'33''	Janiópolis	PR
19	2015	S 24^o 09'29'' W 52^o 29'04''	Campo Mourão	PR
20	2015	S 24^o 07'12'' W 53^o 13'37''	Mariluz	PR
21	2015	S 24^o 01'52'' W 52^o 49'07''	Janiópolis	PR
22	2015	S 24^o 02'42'' W 52^o 27'55''	Campo Mourão	PR
23	2015	S 24^o 08'19'' W 52^o 28'50''	Campo Mourão	PR
24	2015	S 24^o 13'51'' W 52^o 52'31''	Rancho Alegre	PR
25	2015	S 24^o 13'09'' W 52^o 18'05''	Luziânia	PR

Population	g e.a. ha ^-1
Population	C ₅₀	C ₈₀	RF ₅₀	GR ₅₀	GR ₈₀	RF ₅₀
Susceptible	100.45	150.78	-	100.97	172.18	-
1	194.94	284.24	1.94	152.39	353.92	1.51
2	278.15	389.06	2.77	110.99	235.05	1.10
3	154.12	212.92	1.53	99.74	216.45	0.99
4	162.26	249.62	1.62	133.23	322.51	1.32
5	604.72	1217.73	6.02	420.34	1102.74	4.16
6	117.08	164.61	1.17	61.05	118.89	0.60
7	802.43	1443.01	7.99	726.13	1248.20	7.19
8	88.32	140.71	0.88	59.62	122.28	0.59
9	248.35	393.99	2.47	225.16	348.26	2.23
10	276.01	402.30	2.75	81.31	260.33	0.81
11	105.11	142.72	1.05	61.59	114.68	0.61
12	313.98	479.52	3.12	167.25	375.21	1.66
13	179.71	258.01	1.79	103.38	168.22	1.02

Population	g e.a. ha ^-1
Population	C ₅₀	C ₈₀	RF ₅₀	GR ₅₀	GR ₈₀	RF ₅₀
Susceptible	113.26	204.39	-	101.14	240.22	-
14	299.43	504.80	2.64	178.45	387.66	1.76
15	273.31	419.75	2.41	155.58	341.76	1.54
16	397.20	797.43	3.51	298.28	609.01	2.95
17	367.13	629.17	3.24	444.80	688.38	4.40
18	363.66	650.49	3.21	305.72	519.79	3.02
19	503.49	1571.42	4.45	503.41	1653.49	4.98
20	320.95	620.41	2.83	277.55	873.90	2.74
21	239.14	444.47	2.11	137.88	310.16	1.36
22	267.72	428.39	2.56	249.82	495.75	2.47
23	289.94	554.91	2.36	313.94	708.92	3.10
24	320.63	594.91	2.83	107.54	222.77	1.06
25	536.54	1471.71	4.74	552.02	1524.49	5.46

Population	g e.a. ha ^-1
Population	C ₅₀	C ₈₀	RF ₅₀	GR ₅₀	GR ₈₀	RF ₅₀
Susceptible	190.31	478.18	-	120.67	298.42	-
14	546.29	1412.49	2.87	397.07	969.40	3.29
15	782.83	1734.77	4.11	259.56	1059.55	2.15
16	624.54	1727.47	3.28	219.76	1029.19	1.82
17	843.13	2137.20	4.43	444.80	1878.16	3.69
18	630.48	1508.86	3.31	469.14	1352.47	3.88
19	978.04	2451.96	5.14	648.21	1943.56	5.37
20	713.05	1873.06	3.75	397.84	1519.33	3.30
21	712.11	1796.25	3.74	466.63	1421.12	3.87
22	832.80	1900.60	3.72	401.87	1008.55	3.33
23	507.87	767.01	2.67	383.29	729.57	3.18
24	430.59	793.04	2.26	281.63	582.66	2.33
25	784.95	2575.59	4.12	511.20	1856.07	4.24

Population	E1: 2-3 tillers (g e.a. ha -1)
Population	C ₅₀	C ₈₀	RF ₅₀	GR ₅₀	GR ₈₀	RF ₅₀
Susceptible	113.26		-	100.14		-
7 - F1	419.68	653.27	3.71	397.78	647.27	3.97
19 - F1	573.76	1290.77	5.07	399.59	1407.04	3.99
25 - F1	554.65	1268.62	4.90	681.86	1554.95	6.81

Brasil

Brasil

GOOSEGRASS RESISTANT TO GLYPHOSATE IN BRAZIL

Capim-Pé-de-Galinha Resistente ao Glyphosate no Brasil

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

REFERENCES

Publication Dates

History