Relative Competitiveness Between Cultivated and Weedy Rice under Full and Low Light

SCHAEDLER, C.E.; LUBIAN, W.; LIMA, P.C.; CHIAPINOTTO, D.M.

doi:10.1590/S0100-83582020380100039

ABSTRACT:

Cultivated and weedy rice biotypes exhibit morphophysiological variations under low light, affecting competition between plants. The aim of this study was to assess relative competitiveness between cultivated and weedy rice under full and low light. Three experiments were conducted in a greenhouse, using a completely randomized design with four repetitions. The treatments in the experiment I were arranged in additive series while in the experiments II and III treatments were arranged in replacement series. Experiments II and III were carried out concomitantly to assess coexistence between the rice cultivar and weedy rice. The treatments consisted of different plants proportions: 100:0 (cultivated rice monoculture), 75:25, 50:50, 25:75 and 0:100 (weedy rice monoculture), keeping the total plant population obtained in experiment I (240 plants m-2) constant. Experiment II was conducted with full solar radiation and III under 50% light. The variables analyzed were shoot dry weight and plant height, 35 days after emergence (DAE). Competition among plants was evaluated via graphs and by interpreting competition indices. Concerning shoot dry weight, mutual losses were recorded between competitors, whereas equal competition for resources was observed for plant height. Weedy rice was more competitive than cultivated rice regardless of the light environment assessed, indicating the need for integrated methods to control this weed.

Keywords:
intraspecific competition; Oryza sativa; low light

RESUMO:

Em condições de baixa luminosidade, biótipos de arroz daninho e arroz cultivado apresentam variação morfofisiológica, tendo implicações na competição entre plantas. O objetivo desse trabalho foi avaliar a competitividade relativa entre arroz cultivado e arroz daninho, em ambiente sob plena radiação e sob redução de luminosidade. Foram conduzidos três experimentos, em ambiente protegido, utilizando delineamento experimental completamente casualizado, com quatro repetições. Os tratamentos do experimento I foram arranjados em série aditiva e nos experimentos II e III em série de substituição. Os experimentos II e III foram conduzidos concomitantemente, avaliando a convivência do cultivar de arroz com o arroz daninho. Os tratamentos foram constituídos por proporções de plantas: 100:0 (monocultivo de arroz cultivado); 75:25; 50:50; 25:75 e 0:100 (monocultivo de arroz daninho), mantendo-se constante a população total de plantas (240 plantas m-2) obtido no experimento I. O experimento II foi conduzido com plena radiação solar e o III sob redução de 50% de luminosidade. As variáveis analisadas foram: matéria seca da parte aérea e estatura de plantas, aos 35 dias após a emergência. A análise da competição entre plantas foi realizada por aplicação de diagramas e interpretações dos índices de competitividade. Para a variável matéria seca da parte aérea ocorreu prejuízo mútuo entre os competidores, já para estatura das plantas houve equivalência na competição pelos recursos do meio. Independente do ambiente avaliado, o arroz daninho apresenta habilidade competitiva superior ao arroz cultivado, indicando a necessidade de métodos integrados para o manejo dessa espécie daninha.

Palavras-chave:
competição intraespecífica; Oryza sativa; baixa luminosidade

INTRODUCTION

Competition between weeds and cultivated plants is one of the main causes of yield losses in agricultural crops. In this respect, weedy rice is considered one of the main weeds in irrigated rice crops. By competing with this crop for minerals, water, and light (Zhang et al., 2014Zhang Z, Dai W, Song X, Qiang S. A model of the relationship between weedy rice seed-bank dynamics and rice-crop infestation and damage in Jiangsu Province, China. Pest Manag Sci. 2014;70(5):716-24.), weedy rice can cause yield losses of up to 90% and compromise grain quality. Weedy rice belongs to the same taxon (species) of the cultivated rice (Oryza sativa L.), characterizing intraspecific competition (Roush et al., 1989Roush ML, Radosevich SR, Wagner RG, Maxwell BD, Petersen TD. A comparison of methods for measuring effects of density and proportion in plant competition experiments. Weed Sci. 1989;37(2):268-75.).

In irrigated rice, nutrients and sunlight quickly become the most limiting resources (Burgos et al., 2006Burgos NR, Norman RJ, Gealy DR, Black H. Competitive N uptake between rice and weedy rice. Field Crops Res. 2006;99:96-105.). Distinct morphophysiological traits such as vigor, high tiller production and height give weedy rice a competitive advantage (Abraham and Jose, 2014Abraham CT, Jose N. Weedy rice invasion in rice fields of India and management options. J Crop Weed. 2014;10:365-74.). These characteristics are responsible for larger leaf area and higher photosynthetic capacity (Dai et al., 2016Dai L, Song X, He B, Valverde BE, Qiang S. Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Manag Sci. 2016;73(7):1410-20.), enabling plants to better compete for solar radiation (Streck et al., 2008aStreck NA, Michelon S, Kruse ND, Bosco LC, Lago I, Marcolin E, et al. Comparação de parâmetros de crescimento e de desenvolvimento de dois biótipos de arroz vermelho com genótipos de arroz irrigado. Bragantia. 2008a;67(2):349-60.).

The availability of global solar radiation is one of the factors that most interferes in the yield potential of rice, exhibiting a linear relation with yield (Steinmetz et al., 2013Steinmetz S, Deibler AN, Silva JB. Estimativa da produtividade de arroz irrigado em função da radiação solar global e da temperatura mínima do ar. Cienc Rural. 2013;43:206-11.). Sunlight regulates the physiological and biophysical processes of plants (Yang et al., 2013Yang X, Asseng S, Wong MTF, Yu Q, Li J, Liu E. Quantifying the interactive impacts of global dimming and warming on wheat yield and water use in China. Agric For Meteorol. 2013;182-183:342-51.); it is vital to photosynthesis and acts as an environmental signaler, altering plant metabolism and growth (Jiao et al., 2007Jiao Y, Lau OS, Deng XW. Light-regulated transcriptional networks in higher plants. Nature Rev Genet. 2007;8(3):217-30.) and potentially influencing competition between plants (Liu et al., 2009Liu JG, Mahoney KJ, Sikkema PH, Swanton CJ. The importance of light quality in crop-weed competition. Weed Res. 2009;49:217-24.).

Low light levels can occur in rice-producing areas worldwide due to shading by the canopy (Aumonde et al., 2013Aumonde TZ, Pedó T, Martinazzo EG, Moraes DM, Villela FA, Lopes NF. Análise de crescimento e partição de assimilados em plantas de Maria-pretinha submetidas a níveis de sombreamento. Planta Daninha. 2013;31(1):99-108.), the presence of neighboring plants (Concenço et al., 2008Concenço G, Ferreira EA, Silva AA, Ferreira FA, Galon L, Reis MR, et al. Fotossíntese de biótipos de azevém sob condição de competição. Planta Daninha. 2008;26(3):595-600.; Schaedler et al., 2009Schaedler CE, Fleck NG, Ferreira FB, Lazaroto CA, Rizzardi MA. Características morfológicas em plantas de cultivares de aveia como indicadoras do potencial competitivo com plantas daninhas. Cienc Rural. 2009;39(5):1313-9.) or cloud cover (Singh, 2000Singh S. Growth, yield and biochemical response of rice genotypes to low light and hight temperature-humidy stress. Oryza. 2000;37:35-8.). Another related factor is the El Niño Southern Oscillation (ENSO), a large-scale phenomenon that affects the weather and climate at different locations across the world, including southern Brazil (Streck et al., 2009Streck NA, Buriol GA, Heldwein AB, Gabriel LF, Paula GM. Associação da variabilidade da precipitação pluvial em Santa Maria com a Oscilação Decadal do Pacífico. Pesq Agropec Bras. 2009;44(12):1553-61.), the country’s largest rice-producing region (SOSBAI, 2014Sociedade Sul-Brasileira de Arroz Irrigado - SOSBAI. Arroz irrigado: recomendações técnicas da pesquisa para o Sul do Brasil. Santa Maria: 2014.). one of the consequences One of the consequences of the warm phase anomalies of ENSO is reduced solar radiation due to more frequent rainfall, particularly from November to January (Streck et al., 2008bStreck NA, Rosa HT, Walter LC, Bosco LC, Lago I, Heldwein AB. O fenômeno El Niño oscilação sul e a variabilidade interanual da evaporação do tanque Classe A e da umidade relativa do ar em Santa Maria, RS. Cienc Rural. 2008b;38(5):1452-5.), critical period in the rice growth cycle.

Studying light quality is a new approach to understand the biology of competition between plants and can be used to develop weed management technologies (Merotto Jr. et al., 2009Merotto Jr A, Fischer AJ, Vidal RA. Perspectives for using light quality knowledge as an advanced ecophysiological weed management tool. Planta Daninha. 2009;27(2):407-19.), replacement series being the most valuable method for evaluating this interaction (Swanton et al., 2015Swanton CJ, Nkoa R, Blackshaw RE. Experimental methods for crop-weed competition studies. Weed Sci. 2015;63:2-11.). Research has found no difference in growth between weedy and cultivated rice under low light conditions (Venske et al., 2013Venske E, Schaedler CE, Peil da Rosa M, Borges CT, Avila LA, Zimmer PD. Initial development of red and cultivated rice in response to light and air temperature. J Seed Sci. 2013;35(4):510-8.). Our hypothesis is that competitive ability between weedy and cultivated rice changes under low light. The aim of this study was to assess relative competitiveness between cultivated and weedy rice in natural (full solar radiation) and low light environments.

MATERIAL AND METHODS

Three experiments were conducted between 2013 and 2014, in a greenhouse located at 29o09’22.4"S and 56o33’11.9"W, using a completely randomized design with four repetitions. The experimental units were 8 L (0.05 m2 surface) plastic pots filled with sieved soil classified as haplic plinthosol (Embrapa, 2013Empresa Brasileira de Pesquisa Agropecuária - Embrapa. Sistema brasileiro de classificação de solos. Brasília, DF: Embrapa; 2013.), with the following chemical composition: pH = 4.8; CECpH7.0 = 15.6 cmolc dm-3; OM = 1.7%; clay content = 21%; phosphorus (P) = 6.8 mg dm-3; and potassium (K) = 48 mg dm-3.

Experiment I was conducted in additive series. Monocultures of irrigated (IRGA 424) and weedy rice (biotype 32B) were assessed to determine the plant population (m-2) at which shoot dry weight (SDW) becomes independent of the population - reciprocal yield law (Radosevich et al., 2007Radosevich RS, Holt JS, Ghersa CM. Ecology of weeds and invasive plants: relationship to agriculture and natural resource management. New York: Wiley; 2007.). The populations analyzed were 2, 4, 8, 16, 32 and 64 plants pot-1, corresponding to 40, 80, 160, 320, 640 and 1,280 plants m-2, respectively. At 35 days after emergence (DAE), the plants were cut at ground level and dried in an oven at 65 oC until constant weight, when SDW was determined (g per plant). Constant SDW was obtained with a population of 240 plants m-2 (equivalent to 12 plants pot-1) for the IRGA 424 cultivar and biotype 32B (data not showed).

Experiments II and III were carried out concomitantly, in a replacement series design, to assess the coexistence of the rice cultivar and weed. The treatments consisted of different plants proportion: 100:0 (cultivated rice monoculture), 75:25, 50:50, 25:75 and 0:100 (weedy rice monoculture), keeping the total plant population obtained in experiment I (240 plants m-2) constant. Experiment II was conducted under full solar radiation and experiment III at an average of 50% light reduction, measured using a radiometer (Li-cor, Inc. LI-185B), with a polypropylene screen attached to the experimental units. Daily readings were taken (9 a.m.) of the environmental temperature and the soil underneath the polypropylene screen and at full solar radiation; an average difference of approximately 1.22 and 2.38 oC was observed for the environmental and soil temperatures, respectively. When the plants displayed three leaves, a constant water depth of 3 cm was maintained in the experimental units.

Plants can already detect light quality in the seedling stage, signaling that competition will occur and altering their characteristics (Vidal and Merotto Jr., 2010Vidal AR, Merotto Jr A. Inicialismo. In: Vidal R, editor. Interação negativa entre plantas: inicialismo, alelopatia e competição. Porto Alegre: Evangraf; 2010. p.33-49.). As such, SDW and plant height (PH) were determined at 35 DAE, considered enough time to evaluate relative competitiveness. Plant height was measured from ground level to the tip of the leaf blade of the last fully developed leaf (12 plants per repetition); SDW was determined as described in experiment I. Based on these data, graphical analysis was used to assess relative yield (RY = species mixture mean/monoculture mean) and total relative yield (TRY = RYc + RYw), with the respective plant proportions, where RYc = relative yield of cultivated rice and RYw = relative yield of weedy rice.

The graphs were interpreted based on the following: RY = 1 (straight line), when both species are equally capable of interfering with each other; RY < 1 (concave line), when antagonism occurs in the growth of one or both competitors; RY > 1 (convex line), when there is synergism in the growth of one or both competitors. TRY = 1 (straight line), when there is competition for the same resource; TRY > 1 (convex line), when there is no competition; TRY < 1 (concave line), when mutual loss occurs (Cousens, 1991Cousens R. Aspects of the design and interpretation of competition (interference) experiments. Weed Technol. 1991;5(3):664-73.; Radosevich et al., 2007Radosevich RS, Holt JS, Ghersa CM. Ecology of weeds and invasive plants: relationship to agriculture and natural resource management. New York: Wiley; 2007.).

The relative competition intensity index (RCI = RYc/ RYw), relative clustering coefficient (K = RYc/ [1-RYc] or RYw/ [1-RYw]) and competitive ability (C = RYc - RYw) were calculated in line with Cousens and O’neill (1993Cousens R, O’Neill M. Density dependence of replacement series experiments. Oikos. 1993;66(2):347-52.) using a 50:50 species proportion, and indicating which genotype is the most competitive (Cousens, 1991). The RCI index expresses the relative growth of the rice cultivar (c) in relation to weedy rice (w); K denotes the relative dominance of the cultivar (c) over the weed (d); and C indicates which genotype is the most competitive. Cultivated rice (c) is more competitive than weedy rice (w) when RCI > 1, Kc > Kw and C > 0; and the inverse is true if RCI < 1, Kc < Kw and C < 0 (Hoffman and Buhler, 2002Hoffman ML, Buhler DD. Utilizing Sorghum as functional model of crop-weed competition. I. Establishing a competitive hierarchy. Weed Sci. 2002;50:466-72.).

In statistical analysis of relative yield, the differences in RY values (RYD) at proportions of 25%, 50% and 75% in relation to the values on the hypothetical straight line of the respective proportion. The t-test was used to analyze the differences in RYD, TRY, RCI, K and C (Roush et al., 1989Roush ML, Radosevich SR, Wagner RG, Maxwell BD, Petersen TD. A comparison of methods for measuring effects of density and proportion in plant competition experiments. Weed Sci. 1989;37(2):268-75.; Hoffman and Buhler, 2002Hoffman ML, Buhler DD. Utilizing Sorghum as functional model of crop-weed competition. I. Establishing a competitive hierarchy. Weed Sci. 2002;50:466-72.). The null hypothesis used to test RYD and C was that the means were equal to zero (H0 = 0); for TRY and RCI, that the means were equal to 1(H0 = 1); and for K, that the differences between mean Kc and mean Kw were equal to zero (H0 = 0).

The criterion used to differentiate between the RY and TRY curves and competitive ability indices was the presence of differences for at least two plants proportions (Bianchi et al., 2006Bianchi MA, Fleck NG, Lamego FP. Proporção entre plantas de soja e plantas competidoras e as relações de interferência mútua. Cienc Rural. 2006;36(5):1380-7.). The PH and SDW results for each plant proportion, expressed as mean values per plant, were submitted to analysis of variance and treatments means compared to controls using Dunnett’s test (p≤0.05).

RESULTS AND DISCUSSION

Graphic analysis of the replacement experiments (II - full solar radiation and III - 50% light reduction) for shoot dry weight (SDW) showed a significant difference for at least two plant proportions. The data obtained for this variable produced a concave line for relative yield (RY) and total relative yield (TRY) for both the irrigated rice cultivar (IRGA 424) and weedy rice biotype (32B), considering both environments assessed (Figure 1A, B). For plant height (PH), RY and TRY were equal to 1 (straight line) in both environments, with no difference among the plant proportions studied and hypothetical relative yield (Figure 1C, D).

Figure 1
Relative yield (RY) and total relative yield (TRY) for shoot dry weight (SDW) and plant height (PH) under natural light (A and C) and 50% light (B and D) for the irrigated rice cultivar (IRGA 424) and weedy rice biotype (32B).

For SDW in the low light environment, relative yield differences (RYD) were recorded for all competitor proportions; however, under natural light, differences were only observed for competitors at equal or lower proportions (50:50 or 25:75). For PH no differences were found between IRGA 424 and 32B proportions in either of the environments studied (Table 1).

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Table 1
Relative yield differences (RYD) and total relative yield (TRY) for proportions of cultivated rice plants (IRGA 424) associated with weedy rice (biotype 32B) for the variables shoot dry weight (g per plant) and height (cm) under full solar radiation (natural) and 50% light (low light). 29o09’22.4"S; 56o33’11.9"W, 2013-2014

Joint analysis of the RY and TRY graphs concerning to shoot dry weight (SDW) indicated antagonism, that is, mutual losses occurred for both the rice cultivar and weedy rice biotype when in competition, regardless of the environment assessed. The results obtained for plant height (PH) demonstrate that each competitor has the same ability to interfere with the other since they compete for the same available resources in the environment (Swanton et al., 2015Swanton CJ, Nkoa R, Blackshaw RE. Experimental methods for crop-weed competition studies. Weed Sci. 2015;63:2-11.). Since they belong to the same species and exploit the same ecological niche, rice genotypes compete for the same resources in time and/or space (Fleck et al., 2008Fleck NG, Agostinetto D, Galon L, Schaedler CE. Competitividade relativa entre cultivares de arroz irrigado e biótipo de arroz-vermelho. Planta Daninha. 2008;26(1):101-11.; Rubim et al., 2014Rubim RS, Langaro AC, Mariani F, Agostinetto D, Berto RM. Habilidade competitiva relativa de arroz irrigado com arroz-vermelho suscetível ou resistente ao herbicida imazapyr + imazapic. Arq Inst Biol. 2014;81(2):173-9.).

One competitor may use the available environmental resources more efficiently than the other; in this respect, the competition indices for SDW under natural light indicate that weedy rice was superior to cultivated rice, exhibiting higher relative competition intensity (RCI) and competitive ability (C) coefficients. For PH under low light, weedy rice obtained a higher RCI and relative dominance (K) when compared to cultivated rice (Table 2). These indices indicate greater competitive ability for weedy compared relation to cultivated rice, regardless of the environment assessed.

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Table 2
Competition indices between the rice cultivar (IRGA 424) and weedy rice (biotype 32B), expressed by the relative competition intensity (RCI), relative clustering coefficient (K; Kc = cultivated rice, Kw = weedy rice) and competitive ability (C), calculated at a 50:50 plant proportion, under full solar radiation (natural) and 50% light (low light). 29o09’22.4"S; 56o33’11.9"W, 2013-2014

Absolute data for SDW and HT, expressed as means per plant, corroborated the results obtained for RYD and TRY. They also indicated, under natural light, 13.2 and 38.6% higher SDW and PH, respectively, for the weedy rice monoculture in comparison to the cultivated rice. Under low light, these values were 13.6 and 29.4% (Table 3), that is, regardless of the light environments assessed, weedy rice shows distinct morphological traits that provide a competitive advantage over cultivated rice (Abraham and Jose, 2014Abraham CT, Jose N. Weedy rice invasion in rice fields of India and management options. J Crop Weed. 2014;10:365-74.).

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Table 3
Shoot dry weight (SDW) and height (HT) of the rice cultivar (IRGA 424) and weedy rice biotype (32B) in a replacement series experiment at 35 days after emergence (DAE). 29o09’22.4"S; 56o33’11.9"W, 2013-2014

Due to its greater vigor, height and larger number of tillers, weedy rice has better competitive ability than cultivated rice in a natural environment (Burgos et al., 2006Burgos NR, Norman RJ, Gealy DR, Black H. Competitive N uptake between rice and weedy rice. Field Crops Res. 2006;99:96-105.). However, under low light, plants invest a greater proportion of photoassimilates in increasing leaf area in order to optimize light capture (Gobbi et al., 2011Gobbi KF, Garcia R, Ventrella MC, Garcez Neto AF, Rocha GC. Área foliar específica e anatomia foliar quantitativa do capim-braquiária e do amendoim-forrageiro submetidos a sombreamento. Rev Bras Zootec. 2011;40(7):1436-44.). Changes in height due to light quality allow the formation of a canopy (Concenço et al., 2008Concenço G, Ferreira EA, Silva AA, Ferreira FA, Galon L, Reis MR, et al. Fotossíntese de biótipos de azevém sob condição de competição. Planta Daninha. 2008;26(3):595-600.; Schaedler, 2009Schaedler CE, Fleck NG, Ferreira FB, Lazaroto CA, Rizzardi MA. Características morfológicas em plantas de cultivares de aveia como indicadoras do potencial competitivo com plantas daninhas. Cienc Rural. 2009;39(5):1313-9.), which may result in lower biomass production.

In cereal grains such as rice, low light causes etiolation and a decline in the number of tillers, directly reducing dry matter (Vidal and Merotto Jr., 2010Vidal AR, Merotto Jr A. Inicialismo. In: Vidal R, editor. Interação negativa entre plantas: inicialismo, alelopatia e competição. Porto Alegre: Evangraf; 2010. p.33-49.). Plants are capable of acclimation, whereby they adjust to environmental changes and maintain adequate levels of performance. Under low light, cell components are adjusted to improve light absorption efficiency (Gomes and Juneau, 2017Gomes MP, Juneau P. Temperature and light modulation of herbicide toxicity on Algal and Cyanobacterial physiology. Front Environ Sci. 2017;5:1-17.). Its high concentrations of chlorophyll a and b suggest that weedy rice generally has higher photosynthetic capacity than cultivated rice (Dai et al., 2016Dai L, Song X, He B, Valverde BE, Qiang S. Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Manag Sci. 2016;73(7):1410-20.), thus justifying its greater competitive ability under restricted light.

Additionally, weedy rice populations exhibit different morphological and phenological characteristics (Shivrain et al., 2010Shivrain VK, Burgos NR, Agrama HA, Lawton Rauh A, Lu B, Sales MA, et al. Genetic diversity of weedy red rice (Oryza sativa) in Arkansas, USA. Weed Res. 2010;50(4):289-302.), making it difficult to establish a competition pattern. Rubim et al. (2014Rubim RS, Langaro AC, Mariani F, Agostinetto D, Berto RM. Habilidade competitiva relativa de arroz irrigado com arroz-vermelho suscetível ou resistente ao herbicida imazapyr + imazapic. Arq Inst Biol. 2014;81(2):173-9.) assessed competition between the Puitá INTA CL rice cultivar and weedy rice biotypes and found equal competitive ability between the plants. Conversely, findings more frequently indicate superior competitive ability in weedy when compared to cultivated rice (Fleck et al., 2008Fleck NG, Agostinetto D, Galon L, Schaedler CE. Competitividade relativa entre cultivares de arroz irrigado e biótipo de arroz-vermelho. Planta Daninha. 2008;26(1):101-11.; Dai et al., 2014Dai L, Dai W, Song X, Lu B, Qiang S. A comparative study of competitiveness between different genotypes of weedy rice (Oryza sativa) and cultivated rice. Pest Manag Sci. 2014;70(1):113-22.), corroborating the results obtained here. Competitive advantage by one species denotes a greater capacity to assimilate the resources of the ecological niche, resulting in superior growth and development and greater losses for the competitor (Agostinetto et al., 2013Agostinetto D, Fontana LC, Vargas L, Markus C, Oliveira E. Habilidade competitiva relativa de milhã em convivência com arroz irrigado e soja. Pesq Agropec Bras. 2013;48(10):1315-322.).

Regardless of the environment assessed (full solar radiation or low light), weedy rice showed greater competitive ability than cultivated rice. This rejects the hypothesis that competitive ability between weedy and cultivated rice changes under restricted solar radiation. Crop management strategies such as shading weedy rice with cultivated rice and using rice cultivars with superior vigor may be insufficient to control this weed, requiring other integrated methods to control the species in irrigated rice crops. However, field studies are needed to confirm this hypothesis.

REFERENCES

Abraham CT, Jose N. Weedy rice invasion in rice fields of India and management options. J Crop Weed. 2014;10:365-74.
Agostinetto D, Fontana LC, Vargas L, Markus C, Oliveira E. Habilidade competitiva relativa de milhã em convivência com arroz irrigado e soja. Pesq Agropec Bras. 2013;48(10):1315-322.
Aumonde TZ, Pedó T, Martinazzo EG, Moraes DM, Villela FA, Lopes NF. Análise de crescimento e partição de assimilados em plantas de Maria-pretinha submetidas a níveis de sombreamento. Planta Daninha. 2013;31(1):99-108.
Bianchi MA, Fleck NG, Lamego FP. Proporção entre plantas de soja e plantas competidoras e as relações de interferência mútua. Cienc Rural. 2006;36(5):1380-7.
Burgos NR, Norman RJ, Gealy DR, Black H. Competitive N uptake between rice and weedy rice. Field Crops Res. 2006;99:96-105.
Concenço G, Ferreira EA, Silva AA, Ferreira FA, Galon L, Reis MR, et al. Fotossíntese de biótipos de azevém sob condição de competição. Planta Daninha. 2008;26(3):595-600.
Cousens R. Aspects of the design and interpretation of competition (interference) experiments. Weed Technol. 1991;5(3):664-73.
Cousens R, O’Neill M. Density dependence of replacement series experiments. Oikos. 1993;66(2):347-52.
Dai L, Dai W, Song X, Lu B, Qiang S. A comparative study of competitiveness between different genotypes of weedy rice (Oryza sativa) and cultivated rice. Pest Manag Sci. 2014;70(1):113-22.
Dai L, Song X, He B, Valverde BE, Qiang S. Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Manag Sci. 2016;73(7):1410-20.
Empresa Brasileira de Pesquisa Agropecuária - Embrapa. Sistema brasileiro de classificação de solos. Brasília, DF: Embrapa; 2013.
Fleck NG, Agostinetto D, Galon L, Schaedler CE. Competitividade relativa entre cultivares de arroz irrigado e biótipo de arroz-vermelho. Planta Daninha. 2008;26(1):101-11.
Gobbi KF, Garcia R, Ventrella MC, Garcez Neto AF, Rocha GC. Área foliar específica e anatomia foliar quantitativa do capim-braquiária e do amendoim-forrageiro submetidos a sombreamento. Rev Bras Zootec. 2011;40(7):1436-44.
Gomes MP, Juneau P. Temperature and light modulation of herbicide toxicity on Algal and Cyanobacterial physiology. Front Environ Sci. 2017;5:1-17.
Hoffman ML, Buhler DD. Utilizing Sorghum as functional model of crop-weed competition. I. Establishing a competitive hierarchy. Weed Sci. 2002;50:466-72.
Jiao Y, Lau OS, Deng XW. Light-regulated transcriptional networks in higher plants. Nature Rev Genet. 2007;8(3):217-30.
Liu JG, Mahoney KJ, Sikkema PH, Swanton CJ. The importance of light quality in crop-weed competition. Weed Res. 2009;49:217-24.
Merotto Jr A, Fischer AJ, Vidal RA. Perspectives for using light quality knowledge as an advanced ecophysiological weed management tool. Planta Daninha. 2009;27(2):407-19.
Radosevich RS, Holt JS, Ghersa CM. Ecology of weeds and invasive plants: relationship to agriculture and natural resource management. New York: Wiley; 2007.
Roush ML, Radosevich SR, Wagner RG, Maxwell BD, Petersen TD. A comparison of methods for measuring effects of density and proportion in plant competition experiments. Weed Sci. 1989;37(2):268-75.
Rubim RS, Langaro AC, Mariani F, Agostinetto D, Berto RM. Habilidade competitiva relativa de arroz irrigado com arroz-vermelho suscetível ou resistente ao herbicida imazapyr + imazapic. Arq Inst Biol. 2014;81(2):173-9.
Schaedler CE, Fleck NG, Ferreira FB, Lazaroto CA, Rizzardi MA. Características morfológicas em plantas de cultivares de aveia como indicadoras do potencial competitivo com plantas daninhas. Cienc Rural. 2009;39(5):1313-9.
Shivrain VK, Burgos NR, Agrama HA, Lawton Rauh A, Lu B, Sales MA, et al. Genetic diversity of weedy red rice (Oryza sativa) in Arkansas, USA. Weed Res. 2010;50(4):289-302.
Singh S. Growth, yield and biochemical response of rice genotypes to low light and hight temperature-humidy stress. Oryza. 2000;37:35-8.
Sociedade Sul-Brasileira de Arroz Irrigado - SOSBAI. Arroz irrigado: recomendações técnicas da pesquisa para o Sul do Brasil. Santa Maria: 2014.
Steinmetz S, Deibler AN, Silva JB. Estimativa da produtividade de arroz irrigado em função da radiação solar global e da temperatura mínima do ar. Cienc Rural. 2013;43:206-11.
Streck NA, Michelon S, Kruse ND, Bosco LC, Lago I, Marcolin E, et al. Comparação de parâmetros de crescimento e de desenvolvimento de dois biótipos de arroz vermelho com genótipos de arroz irrigado. Bragantia. 2008a;67(2):349-60.
Streck NA, Rosa HT, Walter LC, Bosco LC, Lago I, Heldwein AB. O fenômeno El Niño oscilação sul e a variabilidade interanual da evaporação do tanque Classe A e da umidade relativa do ar em Santa Maria, RS. Cienc Rural. 2008b;38(5):1452-5.
Streck NA, Buriol GA, Heldwein AB, Gabriel LF, Paula GM. Associação da variabilidade da precipitação pluvial em Santa Maria com a Oscilação Decadal do Pacífico. Pesq Agropec Bras. 2009;44(12):1553-61.
Swanton CJ, Nkoa R, Blackshaw RE. Experimental methods for crop-weed competition studies. Weed Sci. 2015;63:2-11.
Venske E, Schaedler CE, Peil da Rosa M, Borges CT, Avila LA, Zimmer PD. Initial development of red and cultivated rice in response to light and air temperature. J Seed Sci. 2013;35(4):510-8.
Vidal AR, Merotto Jr A. Inicialismo. In: Vidal R, editor. Interação negativa entre plantas: inicialismo, alelopatia e competição. Porto Alegre: Evangraf; 2010. p.33-49.
Yang X, Asseng S, Wong MTF, Yu Q, Li J, Liu E. Quantifying the interactive impacts of global dimming and warming on wheat yield and water use in China. Agric For Meteorol. 2013;182-183:342-51.
Zhang Z, Dai W, Song X, Qiang S. A model of the relationship between weedy rice seed-bank dynamics and rice-crop infestation and damage in Jiangsu Province, China. Pest Manag Sci. 2014;70(5):716-24.

Publication Dates

Publication in this collection
15 June 2020
Date of issue
2020

History

Received
27 Dec 2017
Accepted
21 June 2018

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

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[28] Streck NA, Rosa HT, Walter LC, Bosco LC, Lago I, Heldwein AB. O fenômeno El Niño oscilação sul e a variabilidade interanual da evaporação do tanque Classe A e da umidade relativa do ar em Santa Maria, RS. Cienc Rural. 2008b;38(5):1452-5.

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[33] Yang X, Asseng S, Wong MTF, Yu Q, Li J, Liu E. Quantifying the interactive impacts of global dimming and warming on wheat yield and water use in China. Agric For Meteorol. 2013;182-183:342-51.

[34] Zhang Z, Dai W, Song X, Qiang S. A model of the relationship between weedy rice seed-bank dynamics and rice-crop infestation and damage in Jiangsu Province, China. Pest Manag Sci. 2014;70(5):716-24.

Environment		Plant proportions Rc⁽¹⁾:Rw⁽²⁾ (%)
Environment		75:25	50:50	25:75
Shoot Dry Weight (g per plant)
Natural	TRY	0.64 (± 0.09)*	0.56 (± 0.06)*	0.74 (± 0.08)*
	RYD Cultivated rice	- 0.22 (± 0.09)^ns	- 0.27 (± 0.02)*	- 0.13 (± 0.02)*
	RYD Weedy rice	- 0.14 (± 0.01)*	- 0.18 (± 0.04)*	- 0.13 (± 0.08)^ns
Low light	TRY	0.60 (± 0.03)*	0.53 (± 0.03)*	0.59 (± 0.02)*
	RYD Cultivated rice	- 0.23 (± 0.03)*	- 0.21 (± 0.03)*	- 0.15 (± 0.02)*
	RYD Weedy rice	- 0.16 (± 0.01)*	- 0.25 (± 0.01)*	- 0.26 (± 0.02)*
Height (cm)
Natural	TRY	0.97 (± 0.02)^ns	1.02 (± 0.04)^ns	1.01 (± 0.01)^ns
	RYD Cultivated rice	- 0.03 (± 0.02)^ns	0.03 (± 0.05)^ns	0.01 (± 0.00)^ns
	RYD Weedy rice	- 0.00 (± 0.01)^ns	- 0.01 (± 0.01)^ns	0.00 (± 0.01)^ns
Low light	TRY	0.98 (± 0.05)^ns	1.04 (± 0.04)^ns	1.05 (± 0.04)^ns
	RYD Cultivated rice	- 0.01 (± 0.02)^ns	- 0.02 (± 0.02)^ns	- 0.00 (± 0.01)^ns
	RYD Weedy rice	- 0.01 (± 0.03)^ns	0.06 (± 0.02)^ns	0.05 (± 0.03)^ns

Environment	RCI	Kc	Kw	C
Shoot Dry Weight
Full solar radiation	0.72 (± 0.50)*	0.30 (± 0.03)^ns	0.49 (± 0.09)^ns	- 0.09 (± 0.03)*
Low light	1.18 (± 0.16)^ns	0.41 (±0.05)^ns	0.33 (± 0.02)^ns	0.04 (± 0.03)^ns
Height
Full solar radiation	1.08 (± 0.09)^ns	1.23 (± 0.30)^ns	0.97 (± 0.08)^ns	0.04 (± 0.05)*
Low light	0.87 (± 0.03)*	0.95 (± 0.08)*	1.27 (± 0.10)*	- 0.07 (± 0.02)*

Environment		Plant proportion (%)
Environment		100:0 (Ct)	75:25	50:50	25:75	0:100 (Ct)	CV (%)
		Shoot Dry Weight (g per plant)
Full solar radiation	Cultivated rice	3.36	2.36^ns	1.55*	1.58*	-	29.85
Full solar radiation	Weedy rice	-	1.77*	2.51*	3.20^ns	3.87	20.44
Low light	Cultivated rice	2.67	1.84*	1.52*	1.09*	-	15.21
Low light	Weedy rice	-	1.07*	1.52*	2.02*	3.09	9.92
		Height (cm)
Full solar radiation	Cultivated rice	25.01	24.03^ns	26.03^ns	25.65^ns	-	9.92	10.79
Full solar radiation	Weedy rice	-	40.56^ns	40.07^ns	40.78^ns	40.71	3.71
Low light	Cultivated rice	33.69	33.16^ns	32.62^ns	33.09^ns	-	6.78
Low light	Weedy rice	-	46.37^ns	55.16^ns	53.07^ns	47.75	19.54

Brasil

Brasil

Relative Competitiveness Between Cultivated and Weedy Rice under Full and Low Light

Competitividade Relativa entre Arroz Cultivado e Arroz Daninho em Ambiente sob Plena Radiação e sob Redução de Luminosidade

ABSTRACT:

RESUMO:

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

REFERENCES

Publication Dates

History