Interference of volunteer corn in growth and chlorophyll fluorescence of bean

Aguiar, Adalin Cezar Moraes de; Silva, Diecson Ruy Orsolin da; Basso, Claudir José; Soriani, Hilda Hildebrand; Novello, Bruna Dal’Pizol; Muraro, Dionei Schmidt

doi:10.1590/0034-737X201966030007

ABSTRACT

Corn kernels or seeds that remain after harvest can germinate and become a troublesome volunteer plant where bean crops are grown. The objective of this study was to evaluate the effect of time of emergence of volunteer corn on growth parameters, photosynthetic pigments and chlorophyll fluorescence in bean plants, competition for soil and light and light resources. The study was conducted in completely randomised experimental design, in 2×2×2+2 factorial scheme with four replications, involving two bean cultivars in competition with volunteer corn, emerging seven days before and simultaneously with beans, besides the partitioning of the competition by soil and light, just light and two controls without competition. We measured the levels of chlorophyll a, b, total and carotenoids, parameters related to chlorophyll fluorescence and bean growth variables. Volunteer corn was more competitive when it emerged seven days before the beans. When competition was established by light resource, there was a reduction in photosynthetic pigments and morphological variables of the bean plants. When competition by soil and light resources occurred, there was a reduction not only in photosynthetic pigments and morphological characteristics, but also in the chlorophyll fluorescence variables. There were significant correlations between the growth variables of the bean plants and chlorophyll fluorescence, which makes it an important analytical tool for quantifying the stress caused by weeds.

Keywords:
Phaseolus vulgaris; photosynthetic pigments; emerging time; competition; solar radiation; soil

INTRODUCTION

Beans (Phaseolus vulgaris) are one of the most important food crops in Brazil. In order for bean plants to express their maximum yield potential, it is necessary to control limiting factors, among which competition imposed by weeds stands out (Cury et al., 2013Cury JP, Santos JB, Silva EB, Braga RR, Carvalho FP, Valadão Silva D & Byrro ECM (2013) Eficiência nutricional de cultivares de feijão em competição com plantas daninhas. Planta daninha, 31:79-88. ). Beans have become an option after cropping with corn in the Southern region of Brazil. However, corn kernels or seeds that remain after harvest can germinate and become a troublesome volunteer plant where bean crops are grown. Volunteer corn growing in bean crops can cause yield losses that amount to approximately 20% for each volunteer corn plant per square meter (Sbatella et al., 2016Sbatella GM, Kniss AR, Omondi EC & Wilson RG (2016) Volunteer corn (Zea mays) interference in dry edible bean (Phaseolus vulgaris). Weed Technology, 30:937-942.).

Volunteer corn has a capacity to germinate at different times in the bean crop, and its time of emergence may alter the competition between it and the crop. Weeds that emerge early show good growth and have an increased effect on yield losses of crops by acquiring advantage to resources of the environment and have a high relative growth rate (Agostinetto et al., 2004Agostinetto D, Fleck NG Rizzardi MA & Balbinot JR AA (2004) Perdas de rendimento de grãos na cultura de arroz irrigado em função da população de plantas e da época relativa de emergência de arroz-vermelho ou de seu genótipo simulador de infestação de arroz-vermelho. Planta Daninha, 22:175-183.). However, weeds that emerge after crops usually cause a low level of interference with crop yield (Vandevender et al., 1997Vandevender KW, Costello TA & Smith RJ (1997) Model of rice (Oryza sativa) yield reduction as a function of weed interference. Weed Science , 45:218-224.).

Although the competition is integrated, studies that isolate the factors involved in competition improve understanding of the mechanisms of competition (McPhee & Aarssen, 2001Mcphee CS & Aarssen LW (2001) The separation of above and below-ground competition in plants. A review and critique of methodology. . Plant Ecology, 152:119-136.). For example, changes in the red and far-red ratio of light, a response to light stress which can cause alterations in the root system and leaf area, directly affecting the water and nutrients supply (Ballaré, 2014Ballaré CL (2014) Light regulation of plant defense. Annual Review of Plant Biology , 65:335-363.).

Abiotic factors, such as water and nutrient depletion, and changes in light quality and quantity are reflected in the photosynthetic capacity of plants (Afifi & Swanton, 2012Afifi M & Swanton C (2012) Early physiological mechanisms of weed competition. Weed Science, 60:542-551. ). In this case, the content of photosynthetic pigments is an important indicator of the photochemical capacity of plants (Dai et al., 2017Dai L, Song X, He B, Valverde BE & Qiang S (2017) Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Management Science, 73:1410-1420.), because chlorophyll a favors the absorption of long-wave light, chlorophyll b works for short-wave light, and carotenoids absorb light of other wave lengths as well as being endogenous antioxidants and protecting chlorophyll from photodynamic damage (Brody, 2002Brody SS (2002) Fluorescence lifetime, yield, energy transfer and spectrum in photosynthesis,1950-1960. Photosynthesis Research, 73:127-132.). In view of this, changes in photosynthesis-related parameters may be good indicators of competitive damage in plants (Dai et al., 2017Dai L, Song X, He B, Valverde BE & Qiang S (2017) Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Management Science, 73:1410-1420.).

The use of fluorescence parameters allows the evaluation of the effect of several biotic and abiotic stresses, such as water deficit (Silva et al., 2015Silva FG, Dutra WF, Dutra AF, Oliveira IM, Filgueiras L & Melo AS (2015) Trocas gasosas e fluorescência da clorofila em plantas de berinjela sob lâminas de irrigação. Revista brasileira de engenharia agrícola e ambiental , 19:946-952.), salinity (Yan et al., 2012Yan H, Hu X & Li F (2012) Leaf photosynthesis, chlorophyll fluorescence, ion content and free amino acids inCaragana korshinskiiKom exposed to NaCl stress. Acta Physiologiae Plantarum, 34:2285-2295.), light (Schock et al., 2014Schock AA, Ramm A, Martinazzo EG, Silva DM & Bacarin MA (2014) Crescimento e fotossíntese de plantas de pinhão-manso cultivadas em diferentes condições de luminosidade. Revista brasileira de engenharia agrícola e ambiental, 18:03-09.), temperature (Perboni et al., 2015Perboni AT, Martinazzo EG, Silva DM & Bacarin MA (2015) Baixas temperaturas sobre a fluorescência da clorofila a em plantas de diferentes híbridos de canola. Ciência Rural, 45:215-222.), insect damage (Huang et al., 2013Huang J, Huang J, Zhang PJ, Zhang J, Lu YB, Huang F & Li MJ (2013) Chlorophyll content and chlorophyll fluorescence in tomato leaves infested with an invasive Mealybug, Phenacoccus solenopsis (Hemiptera: Pseudococcidae). Environmental Entomology, 42:973-979.), diseases (Costa et al., 2009Costa AC, Oliveira LBD, Carmo MGFD & Pimentel C (2009) Avaliação visual e do potencial fotossintético para quantificação da ferrugem do milheto pérola e correlações com a produção. Tropical Plant Pathology, 34:313-321.) and heavy metals (Ferreira et al., 2015Ferreira PAA, Ceretta CA, Soriani HH, Tiecher TL, Sousa Soares CRF, Rossato LV, Nicoloso FT, Brunetto G, Paranhos JT & Cornejo P (2015) Rhizophagus clarusand phosphate alter the physiological responses ofCrotalaria junceacultivated in soil with a high Cu level. Applied Soil Ecology, 91:37-47.). However, measurement of chlorophyll fluorescence to indicate damage caused by weed competition has not been reported in the literature.

Therefore, the objective of this study was to evaluate the effect of time of emergence of volunteer corn on growth parameters, photosynthetic pigments and chlorophyll fluorescence in bean cultivars competing for soil and light and light resources.

MATERIAL AND METHODS

A greenhouse experiment was conducted during the months of November and December, 2016. The experimental design was completely randomized, in a three-factor factorial treatment arrangement with four replications. The factors consisted of two bean cultivars: IPR Gralha and Fepagro Triunfo; two volunteer corn emergence times: 7 days before and 0 days after bean emergence; two competition conditions: soil and light and just light competition. Controls without volunteer corn were used for each competition condition. The cultivars used were IPR Gralha with cycle of 93 days, and Fepagro Triunfo with cycle of 75 days. Volunteer corn F2 was used as a surrogate plant competitor. The experimental units consisted of 6.0 L plastic pots with 18.5 cm diameter, filled with substrate.

The soil and light competition treatment were obtained establishing one bean plant in the center of the pot and four volunteer corn plants equidistantly surrounding the bean plant. In the light competition treatment, four plastics cups (0.5 L) were buried equidistantly around the circumference of each pot, and the volunteer corn plants were grown on theses cups. Volunteer corn was sowed both seven days before and at the time of bean sowing, to establish the emergence time of volunteer corn in relation to bean. Similar procedure was performed for the control treatments (i.e. absence of volunteer corn). Irrigation management was performed daily according to the need of the crop.

Bean leaf discs were collected at 28 DAE (days after emergence) to determine the content of photosynthetic pigments (chlorophyll a, b, total (a + b) and carotenoids) by the extractable method. The samples were macerated with 5 mL of 80% (v / v) acetone and transferred to beakers adjusting the volume to 8 mL and then centrifuged at 4000 rpm for 3 minutes. The supernatant was transferred to test tubes and the volume was completed with 8 ml of 80% (v / v) acetone. The levels of chlorophyll a, b, total (a + b) and total carotenoids were obtained from the absorbance of the supernatant of the solution obtained by spectrophotometry at 645, 663 and 480 nm (Lichtenthaler, 1987Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. In: Packer L & Douce R (Eds.) Methods in enzimology. New York, London, Academic Press. p.350-381.) and the results expressed as mg g^-1 of fresh dough.

Chlorophyll fluorescence parameters were measured using a pulse amplitude modulated fluorometer at 30 DAE (JUNIOR-PAM, Walz, Effeltrich, Germany). The measurement was performed early in the morning in the central leaflet of the third trifoliate leaf of the bean plants, which were adapted to dark conditions for 30 minutes using foil sheets. The minimum fluorescence level in the dark adaptation state (F0) was measured using a modulated pulse (<0.05 μmol m^-2 s^-1 for 1.8 μs). The maximum fluorescence in this state (Fm) was measured after the application of a pulse of actinic light saturation of 10,000 μmol m^-2 s ^-1 for 0.6 s.

Using the fluorescence parameters, determined in both light and dark states, the following variables were calculated: the effective quantum efficiency of PSII (Y (II)) calculated by the equation Y(II) = (Fm'- F') / Fm', where Fm' and F' correspond to Fm and F₀ after the second pulse of saturated light (Genty et al., 1989Genty B, Briantais JM & Baker NR (1989) The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. Biochim Biophys Acta, 990:87-92.), and non-photochemical extinction (NPQ) (NPQ = (Fm / Fm ') - 1), which is linearly related to heat dissipation (Maxwell & Johnson, 2000Maxwell K & Johnson GN (2000) Chorophyll fluorescence - a practical guide. Journal of Experimental Botany , 51:659-668.).

The maximum rate of electron transport (ETR) was evaluated through light curves (ETR versus photosynthetically active radiation, PAR), where each sample was subjected to nine radiation levels (0, 125, 190, 285, 420, 625, 820, 1150 and 1500 μmol photons m^-2 s^-1) for 10 seconds and the curve points adjusted by the ETR = ETR_max [1-e ^-kQ], where k is an adjustment constant and Q is the intensity of light (Rascher et al., 2000Rascher U, Liebig M & Lüttge U (2000) Evaluation of instant lightresponse curves of chlorophyll fluorescence parameters obtained with a portable chlorophyll fluorometer on site in the field. Plant, Cell E Environment, 23:1397-1405.).

The electron transport rate was calculated according to the equation: ETR = PAR x 0.84 x 0.5 x Y(II), being PAR the applied radiation, the value 0.84 corresponding to the proportion of photons absorbed by the photosynthetic pigments, the value 0.5 corresponding to the proportion of photons absorbed by PSII in relation to the total of photons absorbed by the photosynthetic pigments and Y(II) the effective quantum yield of PSII (Edwards & Baker, 1993Edwards GE & Baker NR (1993) Can CO2assimilation in maize leaves be predicted accurately from chlorophyll fluorescence analysis?. Photosynthesis Research , 37:89-102.), being an estimate for the PSII-absorbed photon flux density.

Plant height (H), stem diameter (D) and root length (RL) was determined at 32 DAE. Plant height was measured from the base of plant to the extended tip of the last leaf. The stem diameter was measured with a caliperat 1 cm from the plant base. The root length was washed and measured from the base to the last root. After these measurements, the shoot and root were packed on paper bags and dried at 60ºC for 72 h to determine dry weight of the bean plants (DW).

The Lilliefors test was used to test for assumption of normality, and no transformation was required. Data were subjected to ANOVA by F test (p<0.05). The cultivar, emergence times of volunteer corn and competition conditions factors were compared by the Tukey test (p<0.05). The Pearson correlation matrix was also elaborated among the growth, photosynthetic pigments and Chlorophyll fluorescence parameters.

RESULTS AND DISCUSSION

Regarding competition for soil and light, there was a reduction in height of bean plants when beans were grown with volunteer corn that had emerged early compared to when beans and corn emerged simultaneously or compared to the controls (Table 1). In contrast, when in light competition, the plant height presented no change at any competition condition. With early emergence, volunteer corn had 39% higher dry biomass compared to corn which simultaneously emerged with bean plants (data not shown); thus, indicating that bean plants were suppressed in height only when volunteer corn emerged seven days earlier. The lower growth in bean height suggests that competition for soil resources occurred at higher intensities, as well as in the competition between soybean and Raphanus sativus reported by Fleck et al. (2006Fleck NG, Bianchi MA, Rizzardi MA & Agostinetto D (2006) Interferência deRaphanus sativussobre cultivares de soja durante a fase vegetativa de desenvolvimento da cultura. Planta Daninha , 24:425-434.).

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Table 1:
Plant height (H), stem diameter (D) and root length (RL) and height/root length ratio of bean cultivars (IPR Gralha and Fepagro Triunfo) as a function of the emergence time of volunteer corn plants competing for soil and light and light resources

A similar reduction was observed in stem diameter and root length in soil and light competition with volunteer corn. The early emergence of volunteer corn caused a 34% reduction in stem diameter and 51% reduction in root length, while simultaneous emergence caused 18 and 26% reduction in stem diameter and root length, respectively, compared to the control without competition (Table 1). However, with light competition, the emergence time had a similar effect on root length, reducing it by approximately 20%; nevertheless, the stem diameter was reduced only when volunteer corn emerged early (15%). In relation to the two cultivars, a longer root length was observed with the cultivar Gralha compared to Triunfo when there was light competition.

The presence of volunteer corn increased the height/root length ratio of the bean compared to the control plots, but only when competing for soil and light resources (Table 1). The plants are able to perceive the presence of weeds in their early stages and redirect the flow of photoassimilates according to the quality of light radiation intercepted by the seedlings (Vidal & Merotto Jr., 2010Vidal RA & Merotto Jr A (2010) Inicialismo. In: Vidal R (Ed.) Interação negativa entre plantas: inicialismo, alelopatia e competição. Porto Alegre: Evangraf. p. 33-49.), directing the biggest allocation of photoassimilates to the shoot part of the bean plant when in competition. This occurrence can be seen in wheat in the presence of ryegrass and turnip competitors, which also showed an increase in the relation height/root length ratio (Lamego et al., 2015Lamego FP, Reinehr M, Cutti L, Aguiar ACM, Rigon CAG & Pagliarini IB (2015) Alterações morfológicas de plântulas de trigo, azevém e nabo quando em competição nos estádios iniciais de crescimento. Planta Daninha , 33:13-22.).

The reduction at plant dry weight varies according to the availability of environmental resources to plants that are growing in coexistence (Rizzardi et al., 2004Rizzardi MA, Roman ES, Borowski DZ & Marcon R (2004) Interferência de populações deEuphorbia heterophyllaeIpomoea ramosissimaisoladas ou em misturas sobre a cultura de soja. Planta Daninha , 22:29-34. ). The interference of volunteer corn at plant dry weight was more pronounced with soil and light competition, which was reduced by 75 and 51% when corn emerged seven days before beans and simultaneously with beans, respectively, compared to the control without competition (Table 2). Regarding the cultivars, greater plant dry weight occurred with Gralha compared to Triunfo, but only with competition for light resources. Bean cultivars competing with Bidens pilosa, Cenchrus echinatus, Euphorbia heterophylla and Commelina benghalensis showed a reduction in dry biomass of 38, 51, 50 and 61%, respectively (Cury et al., 2011Cury JP, Santos JB, Valadão Silva D, Carvalho FP, Braga RR, Byrro ECM & Ferreira EA (2011) Produção e partição de Biomassa seca de cultivares de feijão em competição com plantas daninhas. Planta Daninha , 29:149-158.).

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Table 2:
Dry weight of bean plants (DW) of bean cultivars (IPR Gralha and Fepagro Triunfo) as a function of the emergence time of volunteer corn plants competing for soil and light and light resources

Competition with volunteer corn plants, regardless of the time of emergence, reduced bean chlorophyll a, b and a + b, being more pronounced with soil and light competition (Table 3). A greater amount of chlorophyll a, b and a + b was produced by Triunfo leaves compared to Gralha.

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Table 3:
Chlorophyll content a, b and a + b (mg g^-1 fresh biomass) of leaves of bean cultivars (IPR Gralha and Fepagro Triunfo) as a function of the emergence time of volunteer corn plants competing for soil and light and light resources

Reduction in chlorophyll content of leaves is indicative of biotic or abiotic stresses that modify light absorption and photochemical efficiency, reducing CO₂ assimilation and causing physiological changes in photosynthetic activity (Baker & Rosenqvist, 2004Baker NR & Rosenqvist E (2004) Applications of chlorophyll fluorescence can improve crop production strategies: an examination of future possibilities. Journal of Experimental Botany, 55:1607-1621.). When competing plants grow in the same location, competition for environmental resources may affect the chlorophyll content of the plants (Amaral et al., 2015Amaral CL, Pavan GB, Souza MC, Martins JVF & Alves PLDCA (2015) Relações de interferência entre plantas daninhas e a cultura do grão-de-bico. Bioscience Journal, 31: 37-46.). In soybean plants competing with weeds at different densities, the reduction in chlorophyll content is more accentuated when soybean plants are exposed to a high density of competitors, and this reduction may be related to the lower availability of nitrogen in the soil as a result of competition (Saberalia & Mohammadi, 2015Saberalia SF & Mohammadi K (2015) Organic amendments application downweight the negative effects of weed competition on the soybean yield. Ecological Engineering, 82:451-458.).

There was an interaction between bean cultivars and the emergence time of volunteer corn plants in terms of the carotenoid content of leaves of the bean plants (Table 4). When the corn emerged seven days before the beans, the Triunfo cultivar had 25% higher carotenoid content than the Gralha cultivar, in total competition, while in competition for light the Triunfo cultivar was superior by 17% (Table 4). The carotenoids are important antioxidants that protect chlorophyll from photodynamic damage, consisting of an important factor related to greater stress tolerance in plants (Brody, 2002Brody SS (2002) Fluorescence lifetime, yield, energy transfer and spectrum in photosynthesis,1950-1960. Photosynthesis Research, 73:127-132.).

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Table 4:
Carotenoid content (mg g^-1 fresh biomass) of leaves of bean cultivars (IPR Gralha and Fepagro Triunfo) as a function of the emergence time of volunteer corn plants competing for soil and light and light resources

When competition was established by light, there was no correlation between the photosynthetic pigments bean growth variables (Supplementary Material 1). In contrast, when there was competition for soil and light resources, chlorophyll a and a + b showed positive correlations with stem diameter, root length and dry weight (Supplementary Material 2), thus showing that the reduction in photosynthetic pigments that occurs with competition is related to changes in stem diameter, root length and dry weight of bean plants.

Regarding competition for soil and light, the initial chlorophyll fluorescence (F₀) in bean leaves was higher when there was competition with volunteer corn plants that had emerged early, followed by simultaneous emergence of beans and corn, and the control (Figure 1). The F₀ values represent the light emitted by the excited chlorophyll a molecule, before the energy is dissipated to the PSII reaction centre (Mathis & Paillotin, 1981Mathis P & Paillotin G (1981) Primary processes of photosynthesis. In: Hatch MD & Boardman NK (Eds.) The biochemistry of plants. New York, London, Academic Press , p 97-161.). Therefore, F₀ increases as a result of stress in the environment, causing structural alterations in the photosynthetic pigments of PSII.

Figure 1:
Initial fluorescence (F₀) of leaves of bean plants in competition for soil and light and only light with volunteer corn plants, emerged seven days before (7 DBE) and simultaneously (0 DBE). Lowercase letters compare between emergence time of volunteer corn plants or bean cultivars, by the Tukey test (p <0.05).

When there was competition for light, F0 did not change between the conditions of competition. The comparison of the cultivars showed that Triunfo presented lower value of F0 in relation to the cultivar Gralha (Figure 1). There was also less loss of transfer of excitation energy from the antenna complex to the reaction centers when competing for soil and light resources.

The values of F₀ increase if the PSII reaction center is compromised, or if the transfer of excitation energy from the antenna complex to the reaction centers is impaired (Bolhàr-Nordenkampf et al., 1989Bolhàr-Nordenkampf HR, Long SP, Baker NR, Oquist G, Schreiber U & Lechner EG (1989) Chlorophyll fluorescence as probe of the photosynthetic competence of leaves in the field. A review of current instrument :. Functional Ecology, 03:497-514.), such as in low pigment content. Similar to this, it was shown that F₀ correlated negatively with chlorophyll a and a + b levels and growth parameters DC, CR and BST with soil and light competition (Supplementary Material 2). This result indicates that reductions in chlorophyll content and plant growth parameters are linked to the increase in F₀, due to structural damage in the photosynthetic pigments of PSII and its efficiency in transferring the absorbed energy.

As for competition for soil and light resources, the maximum fluorescence (Fm) for bean leaves was higher when in competition with early emerging volunteer corn, compared to simultaneous emergence and absence of competition (Figure 2). In the case of light competition only, there was no variation in Fm in bean leaves between the emergence times of corn compared to the control plots (Figure 2).

Figure 2:
Maximum fluorescence (Fm) and effective quantum yield of PSII (Y II) of leaves of bean plants in competition for soil and light and only light with volunteer corn plants, emerged seven days before (7 DBE) and simultaneously (0 DBE). Lowercase letters compare between emergence time of volunteer corn plants or bean cultivars, by the Tukey test (p <0.05)

Stress caused by competition can result in damage to photosynthetic tissues, resulting in alteration in non-photochemical extinction processes which modify the Fm. In many situations of stress, the increase in non-photochemical extinction can be accompanied by photo-inactivation of the PSII reaction centers which then dissipate the excitation energy as heat instead of as photochemistry (i.e. electron transfer between photosystems), shown by the increase in Fm (Baker, 2008Baker B (2008) Chlorophyll Fluorescence: A Probe of Photosynthesis In Vivo. Annual Review of Plant Biology, 59:89-113.). Photo-inactivation can lead to oxidation, which in turn promotes damage and loss of PSII reaction centers (Aro et al., 1993Aro EM, Virgin I & Andersson B (1993) Photoinhibition of photosystem II. Inactivation, protein damage and turnover. Biochimica et Biophysica Acta, 1143:113-134.).

As with F₀, the Fm value correlated negatively with the growth parameters of plant height, stem diameter, root length, dry weight and content of chlorophyll a, a+b and carotenoids (Supplementary Material 2). Increased stress in the photosynthetic tissues caused by competition may have reduced the growth and mass accumulation of bean plants, however, this was only seen with soil and light competition (Supplementary Material 2).

The effective quantum efficiency of PSII (YII) and the electron transport rate (ETR) presented the same pattern, displaying a linear correlation (0.99). Likewise, both YII and ETR were reduced in bean plants when volunteer corn plants emerged early. However, regarding competition for soil and light resources, there were no differences compared to the control when volunteer corn and bean plants emerged simultaneously (Figure 2, Figure 3). These changes were not apparent when there was only competition for light resources. Similar results were reported by Lassouane & Lutts (2016Lassouane N & Lutts FAS (2016) Drought inhibits early seedling establishment of Parkinsonia aculeata L. under low light intensity: a physiological approach. Plant Growth Regulation, 80:115-126.), who showed that, under low light intensity, the photosynthetic apparatus of P. aculeata was not damaged by water stress.

Figure 3:
Electron transport rate (ETR) and non-photochemical extinction (NPQ) of leaves of bean plants in competition for soil and light and only light with volunteer corn plants, emerged seven days before (7 DBE) and simultaneously (0 DBE). Lowercase letters compare between emergence time of volunteer corn plants or bean cultivars, by the Tukey test (p <0.05)

Reductions in ETR observed with competition for soil and light resources when corn plants emerged early may result from the degradation of chlorophylls, which reduces the efficiency of collection by the antenna complex, as indicated by the value of F₀ and also the reduction in the efficiency of the YII.

There are few studies in the literature that demonstrate the relationship between chlorophyll fluorescence and weed interference in crops. However, the stresses observed in this relationship may be similar to those reported by Korres et al. (2017Korres NE, Norsworthy JK, FitzSimons T, Roberts TL & Oosterhuis DM (2017) Differential Response of Palmer Amaranth (Amaranthus palmeri) Gender to Abiotic Stress. Weed Science, 65:213-227.), who found that the ETR was reduced under nutritional and light stress in Amaranthus palmeri, which can be linked to photo-inhibition or caused by limited NADP or ATP for the Calvin cycle and/or reduced carboxylation capacity. Therefore, the stress caused by weed interference can be predicted by the use of chlorophyll fluorescence in plants.

ETR and YII showed positive correlation with the growth parameters of plant height, stem diameter, root length and dry weight when there was competition for soil and light resources, and with stem diameter when the competition was for light only (Supplementary Material 2). On the other hand, ETR and YII showed no correlation with photosynthetic pigments in any competition conditions.

The non-photochemical extinction (NPQ) of the bean plants increased when there was soil and light competition with early emerging volunteer corn, the emergence being anticipated in relation to the control; however, when competition was established by light NPQ was not altered (Figure 3).

NPQ is related to heat dissipation. NPQ's main collaborator is called the extinction of the high energy state and is considered essential to protecting the leaf from light-induced damage (Horton et al., 1996Horton P, Ruban AV & Walters RG (1996) Regulation of light harvesting in green plants. Annual Review Plant Physiology, Plant Molecular Biology, 47:655-684.). In a competitive environment, a high NPQ in the bean plants probably indicates that these plants display a greater dissipation of light energy absorbed in the form of thermal energy insteadof using it for the production of chemical energy in the form of ATP and NADPH (Zanandrea et al., 2006Zanandrea I, de Lima Nassi F, Turchetto AC, Braga EJB, Peters JA & Bacarin MA (2006) Efeito da salinidade sob parâmetros de fluorescência em phaseolus vulgaris. Revista Brasileira de Agrociência, 12:157-161), reducing the Calvin cycle and, consequently, plant growth. This result corroborates findings for growth parameters, as can be seen by the negative correlation between NPQ and plant growth parameters, such as stem diameter, root length and dry weight (Supplementary Material 2).

The alteration in NPQ is related to the stress suffered by the plant. Increases in saline stress, water stress and luminous stress in plants have been proved to increase the NPQ, indicating that some excess of excitation energy was dissipated thermally as a result of the stress (Lassouane & Lutts, 2016Lassouane N & Lutts FAS (2016) Drought inhibits early seedling establishment of Parkinsonia aculeata L. under low light intensity: a physiological approach. Plant Growth Regulation, 80:115-126.; Yan et al., 2012Yan H, Hu X & Li F (2012) Leaf photosynthesis, chlorophyll fluorescence, ion content and free amino acids inCaragana korshinskiiKom exposed to NaCl stress. Acta Physiologiae Plantarum, 34:2285-2295.).

Regarding competition for light, correlation between growth parameters, photosynthetic pigments and chlorophyll fluorescence was low and mostly non-significant (Supplementary Material 1). However, when there was competition for soil and light resources, there was a moderate positive correlation (from 0.4 to 0.6) between growth parameters and photosynthetic pigments and a moderate to strong correlation (from 0.4 to 0.6 and 0.7 to 1) between growth parameters and chlorophyll fluorescence, being negative for F₀, Fm and NPQ and positive for YII and ETR (Supplementary Material 2). Among the photosynthetic pigments and chlorophyll fluorescence, the correlations range from weak to moderate (from 0.4 to 0.6), being negative for F₀ and Chl a and Chl a + b, negative for Fm and Chl a, a + b and carotenoids and negative for NPQ and carotenoids.

Chlorophyll fluorescence is a fast and non-destructive parameter that correlates directly with growth variables of plants grown under conditions of competition; therefore, it may serve as an important analytical tool to demonstrate stress caused by weed interference.

CONCLUSION

Volunteer corn plants interfere negatively with bean plants, being more competitive when emerging before the bean plants.

Competition with volunteer corn plants for soil and light resources causes great stress on growth, photosynthetic pigments and chlorophyll fluorescence parameters in bean plants. The competition for light resources causes a reduction in growth and photosynthetic pigments in bean plants.

There is a significant correlation between growth variables and chlorophyll fluorescence in bean plants, which makes it an important analytical tool that can be used to demonstrate stress caused by weed interference.

ACKNOWLEDGEMENTS

The present work was carried out with the support of the Coordination of Improvement of Higher Education Personnel - Brazil (CAPES) - Financing Code 001.

REFERENCES

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Aro EM, Virgin I & Andersson B (1993) Photoinhibition of photosystem II. Inactivation, protein damage and turnover. Biochimica et Biophysica Acta, 1143:113-134.
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Baker NR & Rosenqvist E (2004) Applications of chlorophyll fluorescence can improve crop production strategies: an examination of future possibilities. Journal of Experimental Botany, 55:1607-1621.
Ballaré CL (2014) Light regulation of plant defense. Annual Review of Plant Biology , 65:335-363.
Bolhàr-Nordenkampf HR, Long SP, Baker NR, Oquist G, Schreiber U & Lechner EG (1989) Chlorophyll fluorescence as probe of the photosynthetic competence of leaves in the field. A review of current instrument :. Functional Ecology, 03:497-514.
Brody SS (2002) Fluorescence lifetime, yield, energy transfer and spectrum in photosynthesis,1950-1960. Photosynthesis Research, 73:127-132.
Costa AC, Oliveira LBD, Carmo MGFD & Pimentel C (2009) Avaliação visual e do potencial fotossintético para quantificação da ferrugem do milheto pérola e correlações com a produção. Tropical Plant Pathology, 34:313-321.
Cury JP, Santos JB, Valadão Silva D, Carvalho FP, Braga RR, Byrro ECM & Ferreira EA (2011) Produção e partição de Biomassa seca de cultivares de feijão em competição com plantas daninhas. Planta Daninha , 29:149-158.
Cury JP, Santos JB, Silva EB, Braga RR, Carvalho FP, Valadão Silva D & Byrro ECM (2013) Eficiência nutricional de cultivares de feijão em competição com plantas daninhas. Planta daninha, 31:79-88.
Dai L, Song X, He B, Valverde BE & Qiang S (2017) Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Management Science, 73:1410-1420.
Edwards GE & Baker NR (1993) Can CO₂assimilation in maize leaves be predicted accurately from chlorophyll fluorescence analysis?. Photosynthesis Research , 37:89-102.
Ferreira PAA, Ceretta CA, Soriani HH, Tiecher TL, Sousa Soares CRF, Rossato LV, Nicoloso FT, Brunetto G, Paranhos JT & Cornejo P (2015) Rhizophagus clarusand phosphate alter the physiological responses ofCrotalaria junceacultivated in soil with a high Cu level. Applied Soil Ecology, 91:37-47.
Fleck NG, Bianchi MA, Rizzardi MA & Agostinetto D (2006) Interferência deRaphanus sativussobre cultivares de soja durante a fase vegetativa de desenvolvimento da cultura. Planta Daninha , 24:425-434.
Genty B, Briantais JM & Baker NR (1989) The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. Biochim Biophys Acta, 990:87-92.
Horton P, Ruban AV & Walters RG (1996) Regulation of light harvesting in green plants. Annual Review Plant Physiology, Plant Molecular Biology, 47:655-684.
Huang J, Huang J, Zhang PJ, Zhang J, Lu YB, Huang F & Li MJ (2013) Chlorophyll content and chlorophyll fluorescence in tomato leaves infested with an invasive Mealybug, Phenacoccus solenopsis (Hemiptera: Pseudococcidae). Environmental Entomology, 42:973-979.
Korres NE, Norsworthy JK, FitzSimons T, Roberts TL & Oosterhuis DM (2017) Differential Response of Palmer Amaranth (Amaranthus palmeri) Gender to Abiotic Stress. Weed Science, 65:213-227.
Lamego FP, Reinehr M, Cutti L, Aguiar ACM, Rigon CAG & Pagliarini IB (2015) Alterações morfológicas de plântulas de trigo, azevém e nabo quando em competição nos estádios iniciais de crescimento. Planta Daninha , 33:13-22.
Lassouane N & Lutts FAS (2016) Drought inhibits early seedling establishment of Parkinsonia aculeata L. under low light intensity: a physiological approach. Plant Growth Regulation, 80:115-126.
Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. In: Packer L & Douce R (Eds.) Methods in enzimology. New York, London, Academic Press. p.350-381.
Mathis P & Paillotin G (1981) Primary processes of photosynthesis. In: Hatch MD & Boardman NK (Eds.) The biochemistry of plants. New York, London, Academic Press , p 97-161.
Maxwell K & Johnson GN (2000) Chorophyll fluorescence - a practical guide. Journal of Experimental Botany , 51:659-668.
Mcphee CS & Aarssen LW (2001) The separation of above and below-ground competition in plants. A review and critique of methodology. . Plant Ecology, 152:119-136.
Perboni AT, Martinazzo EG, Silva DM & Bacarin MA (2015) Baixas temperaturas sobre a fluorescência da clorofila a em plantas de diferentes híbridos de canola. Ciência Rural, 45:215-222.
Rascher U, Liebig M & Lüttge U (2000) Evaluation of instant lightresponse curves of chlorophyll fluorescence parameters obtained with a portable chlorophyll fluorometer on site in the field. Plant, Cell E Environment, 23:1397-1405.
Rizzardi MA, Roman ES, Borowski DZ & Marcon R (2004) Interferência de populações deEuphorbia heterophyllaeIpomoea ramosissimaisoladas ou em misturas sobre a cultura de soja. Planta Daninha , 22:29-34.
Saberalia SF & Mohammadi K (2015) Organic amendments application downweight the negative effects of weed competition on the soybean yield. Ecological Engineering, 82:451-458.
Sbatella GM, Kniss AR, Omondi EC & Wilson RG (2016) Volunteer corn (Zea mays) interference in dry edible bean (Phaseolus vulgaris). Weed Technology, 30:937-942.
Schock AA, Ramm A, Martinazzo EG, Silva DM & Bacarin MA (2014) Crescimento e fotossíntese de plantas de pinhão-manso cultivadas em diferentes condições de luminosidade. Revista brasileira de engenharia agrícola e ambiental, 18:03-09.
Silva FG, Dutra WF, Dutra AF, Oliveira IM, Filgueiras L & Melo AS (2015) Trocas gasosas e fluorescência da clorofila em plantas de berinjela sob lâminas de irrigação. Revista brasileira de engenharia agrícola e ambiental , 19:946-952.
Vandevender KW, Costello TA & Smith RJ (1997) Model of rice (Oryza sativa) yield reduction as a function of weed interference. Weed Science , 45:218-224.
Vidal RA & Merotto Jr A (2010) Inicialismo. In: Vidal R (Ed.) Interação negativa entre plantas: inicialismo, alelopatia e competição. Porto Alegre: Evangraf. p. 33-49.
Yan H, Hu X & Li F (2012) Leaf photosynthesis, chlorophyll fluorescence, ion content and free amino acids inCaragana korshinskiiKom exposed to NaCl stress. Acta Physiologiae Plantarum, 34:2285-2295.
Zanandrea I, de Lima Nassi F, Turchetto AC, Braga EJB, Peters JA & Bacarin MA (2006) Efeito da salinidade sob parâmetros de fluorescência em phaseolus vulgaris Revista Brasileira de Agrociência, 12:157-161

Publication Dates

Publication in this collection
12 Aug 2019
Date of issue
May-Jun 2019

History

Received
02 Apr 2019
Accepted
16 July 2019

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

[1] Afifi M & Swanton C (2012) Early physiological mechanisms of weed competition. Weed Science, 60:542-551.

[2] Agostinetto D, Fleck NG Rizzardi MA & Balbinot JR AA (2004) Perdas de rendimento de grãos na cultura de arroz irrigado em função da população de plantas e da época relativa de emergência de arroz-vermelho ou de seu genótipo simulador de infestação de arroz-vermelho. Planta Daninha, 22:175-183.

[3] Amaral CL, Pavan GB, Souza MC, Martins JVF & Alves PLDCA (2015) Relações de interferência entre plantas daninhas e a cultura do grão-de-bico. Bioscience Journal, 31: 37-46.

[4] Aro EM, Virgin I & Andersson B (1993) Photoinhibition of photosystem II. Inactivation, protein damage and turnover. Biochimica et Biophysica Acta, 1143:113-134.

[5] Baker B (2008) Chlorophyll Fluorescence: A Probe of Photosynthesis In Vivo. Annual Review of Plant Biology, 59:89-113.

[6] Baker NR & Rosenqvist E (2004) Applications of chlorophyll fluorescence can improve crop production strategies: an examination of future possibilities. Journal of Experimental Botany, 55:1607-1621.

[7] Ballaré CL (2014) Light regulation of plant defense. Annual Review of Plant Biology , 65:335-363.

[8] Bolhàr-Nordenkampf HR, Long SP, Baker NR, Oquist G, Schreiber U & Lechner EG (1989) Chlorophyll fluorescence as probe of the photosynthetic competence of leaves in the field. A review of current instrument :. Functional Ecology, 03:497-514.

[9] Brody SS (2002) Fluorescence lifetime, yield, energy transfer and spectrum in photosynthesis,1950-1960. Photosynthesis Research, 73:127-132.

[10] Costa AC, Oliveira LBD, Carmo MGFD & Pimentel C (2009) Avaliação visual e do potencial fotossintético para quantificação da ferrugem do milheto pérola e correlações com a produção. Tropical Plant Pathology, 34:313-321.

[11] Cury JP, Santos JB, Valadão Silva D, Carvalho FP, Braga RR, Byrro ECM & Ferreira EA (2011) Produção e partição de Biomassa seca de cultivares de feijão em competição com plantas daninhas. Planta Daninha , 29:149-158.

[12] Cury JP, Santos JB, Silva EB, Braga RR, Carvalho FP, Valadão Silva D & Byrro ECM (2013) Eficiência nutricional de cultivares de feijão em competição com plantas daninhas. Planta daninha, 31:79-88.

[13] Dai L, Song X, He B, Valverde BE & Qiang S (2017) Enhanced photosynthesis endows seedling growth vigour contributing to the competitive dominance of weedy rice over cultivated rice. Pest Management Science, 73:1410-1420.

[14] Edwards GE & Baker NR (1993) Can CO₂assimilation in maize leaves be predicted accurately from chlorophyll fluorescence analysis?. Photosynthesis Research , 37:89-102.

[15] Ferreira PAA, Ceretta CA, Soriani HH, Tiecher TL, Sousa Soares CRF, Rossato LV, Nicoloso FT, Brunetto G, Paranhos JT & Cornejo P (2015) Rhizophagus clarusand phosphate alter the physiological responses ofCrotalaria junceacultivated in soil with a high Cu level. Applied Soil Ecology, 91:37-47.

[16] Fleck NG, Bianchi MA, Rizzardi MA & Agostinetto D (2006) Interferência deRaphanus sativussobre cultivares de soja durante a fase vegetativa de desenvolvimento da cultura. Planta Daninha , 24:425-434.

[17] Genty B, Briantais JM & Baker NR (1989) The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. Biochim Biophys Acta, 990:87-92.

[18] Horton P, Ruban AV & Walters RG (1996) Regulation of light harvesting in green plants. Annual Review Plant Physiology, Plant Molecular Biology, 47:655-684.

[19] Huang J, Huang J, Zhang PJ, Zhang J, Lu YB, Huang F & Li MJ (2013) Chlorophyll content and chlorophyll fluorescence in tomato leaves infested with an invasive Mealybug, Phenacoccus solenopsis (Hemiptera: Pseudococcidae). Environmental Entomology, 42:973-979.

[20] Korres NE, Norsworthy JK, FitzSimons T, Roberts TL & Oosterhuis DM (2017) Differential Response of Palmer Amaranth (Amaranthus palmeri) Gender to Abiotic Stress. Weed Science, 65:213-227.

[21] Lamego FP, Reinehr M, Cutti L, Aguiar ACM, Rigon CAG & Pagliarini IB (2015) Alterações morfológicas de plântulas de trigo, azevém e nabo quando em competição nos estádios iniciais de crescimento. Planta Daninha , 33:13-22.

[22] Lassouane N & Lutts FAS (2016) Drought inhibits early seedling establishment of Parkinsonia aculeata L. under low light intensity: a physiological approach. Plant Growth Regulation, 80:115-126.

[23] Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. In: Packer L & Douce R (Eds.) Methods in enzimology. New York, London, Academic Press. p.350-381.

[24] Mathis P & Paillotin G (1981) Primary processes of photosynthesis. In: Hatch MD & Boardman NK (Eds.) The biochemistry of plants. New York, London, Academic Press , p 97-161.

[25] Maxwell K & Johnson GN (2000) Chorophyll fluorescence - a practical guide. Journal of Experimental Botany , 51:659-668.

[26] Mcphee CS & Aarssen LW (2001) The separation of above and below-ground competition in plants. A review and critique of methodology. . Plant Ecology, 152:119-136.

[27] Perboni AT, Martinazzo EG, Silva DM & Bacarin MA (2015) Baixas temperaturas sobre a fluorescência da clorofila a em plantas de diferentes híbridos de canola. Ciência Rural, 45:215-222.

[28] Rascher U, Liebig M & Lüttge U (2000) Evaluation of instant lightresponse curves of chlorophyll fluorescence parameters obtained with a portable chlorophyll fluorometer on site in the field. Plant, Cell E Environment, 23:1397-1405.

[29] Rizzardi MA, Roman ES, Borowski DZ & Marcon R (2004) Interferência de populações deEuphorbia heterophyllaeIpomoea ramosissimaisoladas ou em misturas sobre a cultura de soja. Planta Daninha , 22:29-34.

[30] Saberalia SF & Mohammadi K (2015) Organic amendments application downweight the negative effects of weed competition on the soybean yield. Ecological Engineering, 82:451-458.

[31] Sbatella GM, Kniss AR, Omondi EC & Wilson RG (2016) Volunteer corn (Zea mays) interference in dry edible bean (Phaseolus vulgaris). Weed Technology, 30:937-942.

[32] Schock AA, Ramm A, Martinazzo EG, Silva DM & Bacarin MA (2014) Crescimento e fotossíntese de plantas de pinhão-manso cultivadas em diferentes condições de luminosidade. Revista brasileira de engenharia agrícola e ambiental, 18:03-09.

[33] Silva FG, Dutra WF, Dutra AF, Oliveira IM, Filgueiras L & Melo AS (2015) Trocas gasosas e fluorescência da clorofila em plantas de berinjela sob lâminas de irrigação. Revista brasileira de engenharia agrícola e ambiental , 19:946-952.

[34] Vandevender KW, Costello TA & Smith RJ (1997) Model of rice (Oryza sativa) yield reduction as a function of weed interference. Weed Science , 45:218-224.

[35] Vidal RA & Merotto Jr A (2010) Inicialismo. In: Vidal R (Ed.) Interação negativa entre plantas: inicialismo, alelopatia e competição. Porto Alegre: Evangraf. p. 33-49.

[36] Yan H, Hu X & Li F (2012) Leaf photosynthesis, chlorophyll fluorescence, ion content and free amino acids inCaragana korshinskiiKom exposed to NaCl stress. Acta Physiologiae Plantarum, 34:2285-2295.

[37] Zanandrea I, de Lima Nassi F, Turchetto AC, Braga EJB, Peters JA & Bacarin MA (2006) Efeito da salinidade sob parâmetros de fluorescência em phaseolus vulgaris Revista Brasileira de Agrociência, 12:157-161

Emergence time/ cultivar	Competing for soil and light	Competing for light
Emergence time/ cultivar	H (cm)
7 DBE²	42.8 (±2.36)⁴b¹	48.6(±3.43) a
0 DBE	49.8 (±3.50) a	50.5 (±2.85) a
Control	49.7 (±2.05) a	48.2(±2.82) a
CV(%)³	7.3	6.2
Emergence time	D (mm)
7 DBE	4.29 (±0.38) c	5.31 (±0.15) b
0 DBE	5.32 (±0,61) b	6.07 (±0.42) a
Control	6.49 (±0.26) a	6.20 (±0.33) a
CV (%)	8.5	5.2
Emergence time	RL (cm)
7 DBE	29.9 (±3.45) c	43.5 (5±.37) b
0 DBE	37.7 (±3.55) b	45.3 (±6.66) b
Control	50.9 (±6.98) a	56.3 (±8.56) a
CV (%)	15.1	14.3
Cultivar	RL (cm)
Triunfo	39.6 (±7.88) a	43.3 (±6.79) b
Gralha	39.4 (±11.3) a	51.7 (±7.01) a
CV(%)	15.1	14.3
Emergence time	PH/RL
7 DBE	1.45 (±0.19) a	1.12 (±0.18) a
0 DBE	1.33 (±0.10) a	1.14 (±0.25) a
Control	0.99 (±0.10) b	0.94 (±0.20) a
CV (%)	10.9	18.8

Emergence time/ cultivar	Competing for soil and light	Competing for light
Emergence time/ cultivar	DW (g)
7 DBE²	3.73 (±0.69)⁴ c¹	9.06 (±1.00) b
0 DBE	7.32 (±0.68) b	11.6 (±1.20) a
Control	14.8 (±2.26) a	11.8 (±1.28) a
CV (%)³	18.2	16.4
Cultivar	DW (g)
Triunfo	8.41 (±3.87) a	9.98 (±1.30) b
Gralha	8.80 (±4.15) a	11.7 (±0.89) a
CV(%)	18.2	16.4

Emergence time/ cultivar	Competing for soil and light	Competing for light
Emergence time/ cultivar	Chlorophyll a
7 DBE²	1.29 (±0.13)⁴ b¹	1.41 (±0.07) b
0 DBE	1.36 (±0.09) b	1.40 (±0.05) b
Control	1.54 (±0.06) a	1.53 (±0.09) a
CV (%)³	3.6	3.2
Cultivar	Chlorophyll a
Triunfo	1.45 (±0.09) a	1.49 (±0.08) a
Gralha	1.35 (±0.10) b	1.41 (±0.08) b
CV(%)	3.6	3.2
Emergence time	Chlorophyll b
7 DBE	0.76 (±0.04) b	0.76 (±0.02) b
0 DBE	0.77 (±0.04) b	0.76 (±0.03) b
Control	0.80 (±0.01) a	0.81 (±0.03) a
CV (%)	4.2	3.4
Cultivar	Chlorophyll b
Triunfo	0.79 (±0.03) a	0.79 (±0.04) a
Gralha	0.75 (±0.03) b	0.77 (±0.03) a
CV(%)	3.6	3.4
Emergence time	Chlorophyll a+b
7 DBE	2.05 (±0.16) b	2.18 (±0.09) b
0 DBE	2.13 (±0.13) b	2.17 (±0.05) b
Control	2.34 (±0.06) a	2.33 (±0.10) a
CV (%)	4.6	3.0
Cultivar	Chlorophyll a+b
Triunfo	2.24 (±0.12) a	2.28 (±0.09) a
Gralha	2.11 (±0.11) b	2.18 (±0.08) b
CV(%)	4.6	3.0

Emergence time	Competing for soil and light		Competing for light
Emergence time	Triunfo	Gralha	Triunfo	Gralha
7 DBE²	0.20 (±0.02)⁴ aA¹	0.15 (±0.03) bB	0.23 (±0.09) aA	0.19 (±0.02) aA
0 DBE	0.21 (±0.01) aA	0.21 (±0.02) aA	0.25 (±0.05) aA	0.19 (±0.02) aB
Control	0.21 (±0.02) aA	0.22 (±0.02) aA	0.24 (±0.09) aA	0.23 (±0.05) aA
CV(%)³	12.7		19.0

Brazil

Brazil

Interference of volunteer corn in growth and chlorophyll fluorescence of bean1 1 This work is part of the master's dissertation of the first author.

ABSTRACT

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History

Interference of volunteer corn in growth and chlorophyll fluorescence of bean¹ 1 This work is part of the master's dissertation of the first author.