Phytotoxic effects of <i>Morus</i> nigra aqueous extract on germination and seedling growth of Lactuca sativa

Vieira, Letícia Rodrigues; Silva, Eliane Regina da; Soares, Geraldo Luiz Gonçalves; Fior, Claudimar Sidnei; Ethur, Eduardo Miranda; Hoehne, Lucélia; Freitas, Elisete Maria de

doi:10.1590/2175-7860201869443

Abstract

Some exotic species threat the integrity of natural environments due to their invasive potential. They can affect other species by releasing secondary compounds in the soil. Morus nigra (Moraceae) is an invasive species of riparian forests in southern Brazil. The objective of this study was to verify if the aqueous extracts of fruit, fresh and dry leaves of M. nigra show phytotoxic effects on germination, seedling growth and membrane integrity of seedlings of Lactuca sativa. Extract concentrations of 0.1, 0.25, 0.5, 0.75, 1, 2.5, 5, 7.5 and 10% were tested. Germination rate and speed of germination were determined. Effects on initial growth were evaluated by measuring seedling root and shoot length, and membrane integrity was assessed by conductivity tests. Results showed the phytotoxicity of M. nigra aqueous extracts, causing significant inhibition on germination and seedling growth. The fruit extract was generally less phytotoxic than extracts from fresh and dry leaves. Moreover, the extracts induced changes in membrane integrity and caused morphological deformities in seedlings, such as necrotic roots and chlorotic plants. The high phytotoxicity of fruit, dry and fresh leaf extracts of M. nigra was evidenced, indicating the allelopathic potential of the species.

Key words:
allelopathy; invasive species; membrane integrity; phenolics

Resumo

Algumas espécies exóticas vêm ameaçando a integridade dos ecossistemas naturais pelo seu potencial invasor. Elas podem ser favorecidas pelo lançamento de compostos secundários no solo. Morus nigra (Moraceae) é uma espécie invasora de florestas ribeirinhas no sul do Brasil. O objetivo do estudo foi verificar se o extrato aquoso dos frutos e folhas frescas e secas apresentam efeitos fitotóxicos sobre a germinação, o crescimento e a integridade de membranas de plântulas de Lactuca sativa. Foram testadas as concentrações 0,1; 0,25; 0,5; 0,75; 1; 2,5; 5; 7,5 e 10%. A taxa e o índice de velocidade de germinação foram definidos. O crescimento inicial foi obtido com as medidas do comprimento de raiz e parte aérea. A integridade das membranas foi estimada através de medidas de condutividade. Os resultados evidenciaram os efeitos fitotóxicos dos extratos aquosos, causando a inibição significativa da germinação e no crescimento inicial das plântulas. Os efeitos fitotóxicos dos extratos das folhas frescas e secas foram superiores ao do fruto. Além disso, os extratos causaram alterações na estrutura das membranas e deformações morfológicas nas plântulas, como radículas necrosadas e plantas acloríticas. A alta fitotoxidez dos extratos M. nigra foi evidenciada, indicando o seu potencial alelopático.

Palavras-chave:
alelopatia; espécies invasoras; integridade de membrana; fenólicos

Introduction

Allelopathy consists in the interaction, either beneficial or harmful, among plants through the production of chemical compounds released in the environment (Rice 1984Rice EL (1984) Allelopathy. 2nd ed. Academic Press, London. 422p.). Considering this plant interaction, a donor plant is the one that produces and releases allelochemicals, and a target or recipient organism is the one that suffers allelochemicals' effects (Rivzi et al. 1999Rizvi SJH, Tahir M, Rizvi V, Kohli RK & Ansari A (1999) Allelopathic interactions in agroforestry systems. Critical Reviews in Plant Sciences 18: 773-796.). Allelochemicals can be released by tissue leaching, volatilization, root exudation and by decomposition of plant structures (Einhellig 1986Einhellig FA (1986) Mechanisms and modes of action of allelochemicals. In: Putman AR & Tang CH-S (eds.) The Science of Allelopathy. Wiley, Minneapolis. Pp. 171-188.; Rice 1984Rice EL (1984) Allelopathy. 2nd ed. Academic Press, London. 422p.; Weir et al. 2004Weir TL, Park SW & Vivanco JM (2004) Biochemical and physiological mechanisms mediated by allelochemicals. Current Opinion in Plant Biology 7: 472-479.). These allelochemicals can be responsible for several interactions among organisms (Gotllieb 1982Gotllieb OR (1982) Micromolecular, evolution, systematics and ecology: an essay into a novel botanical discipline. Springer-Verlag, Berlin. 171p.; Weidenhamer 1996Weidenhamer JD (1996) Distinguishing resource competition and chemical interference: overcoming the methodological impasse. Agronomy Journal 88: 866-875.).

Phytotoxins released in soil by exotic species can inhibit native species germination and development, contributing to invasion success of exotic ones. This can occur due to the lack of adaptation of native species to allelochemicals from exotic species (Bais et al. 2003Bais HP, Vepachedu R, Gilroy S, Callaway RM & Vivanco JM (2003) Allelopathy and exotic plant invasion: from molecules and genes to species interactions. Science 301: 1377-1380.). Consequently, when exotic species succeed to establish in different biogeographic regions, they can threat natural ecosystem integrity by changing plant communities' structure (Kennedy et al. 2002Kennedy TA, Naeem S, Howe KM, Knops JMH, Tilman D & Reich P (2002) Biodiversity as a barrier to ecological invasion. Nature 417: 636-638.).

Morus nigra L. (Moraceae) is an invasive exotic species in southern Brazil. It is a tree species 7-10 meters high, with simple leaves, long and slender petioles and which produces a great quantity of aggregate fruit (Chan et al. 2016Chan EW, Lye PY & Wong SK (2016) Phytochemistry, pharmacology, and clinical trials of Morus alba. Chinese Journal of Natural Medicines 14: 17-30.; Ercisli & Orhan 2007Ercisli S & Orhan E (2007) Chemical composition of while (Morus alba), red (Morus rubra) and black (Morus nigra) mulberry fruits. Food Chemistry 103: 1380-1384.) of the drupe type (Judd et al. 2009Judd WS, Campbell CS, Kellogg EA, Kellogg EA, Stevens PF & Donoghue MJ (2009) Plant systematics: a phylogenetic approach. 3rd ed. Sinauer, Sunderland. 612p.), constituting an infructescence. The fruit presents reddish color in the beginning of maturation and black when mature. Leaves and fruit accumulate in large quantities under the plant, as M. nigra is a deciduous species. The soil, in general, is bare due to the presence of only few individuals of other plant species (personal observation). The presence of few individuals under the species may indicate that leaf and mature fruit accumulated on soil could release secondary metabolites that cause allelopathic effects on other plants.

Therefore, it is relevant to comprehend whether allelopathy can be a mechanism associated to M. nigra invasion. The objective of the present study was to evaluate the phytotoxic effect of aqueous extracts of leaves and fruit of M. nigra on germination and seedling growth, using Lactuca sativa L. as the recipient species.

Material and Methods

Plant collection and extract preparation

Leaves and fruit of M. nigra were collected from individuals situated at the margins of two rivers (29º30'4"-29º29'55"S and 51º58'9"-51º57'32"W) in southern Brazil, which vegetation type is inserted in the Atlantic Forest biome. Fertile material from a specimen from each of the collection sites was inserted in the HVAT Herbarium of the Universidade do Vale do Taquari - Univates under registers 5,129 and 5,130. In order to obtain samples from the whole branch, leaves were collected from the base to the tip of branches. After collection, part of leaves were immediately manually macerated (fresh leaves), while the remaining leaves were kept in a drying oven at 40 ºC for 48 hours, and then also macerated (dry leaves). Mature fruit (with dark color) was collected.

Leaf extracts (fresh and dry) were obtained by the infusion of macerated leaves in deionized water (1:10 w:v), heated at 90 ºC. The fruit extract was obtained by trituration followed by filtration and storage in ultra-low-temperature freezers (-80 ºC) for 12 hours. Lyophilization of all extracts was carried out at -50 ºC with 760 mmHg of pressure. For germination and growth bioassays, concentrations of the three extracts were obtained by diluting the crude extract in distilled and autoclaved water, resulting in the following treatments: 0% (control); 0.1%; 0.25%; 0.5%; 0.75%; 1%; 2.5%; 5%; 7.5% and 10%.

Germination assays

Germination assays were conducted with L. sativa (var. Grand Rapids) as the recipient species. Each repetition comprised 25 L. sativa cypselae placed on filter paper in a Petri dish (9.0 mm), with 8 ml of each treatment. For each concentration of extract, four repetitions were established. Plates were kept in a growth room with 16 hours/light photoperiod and temperature of 25 ºC (± 2 ºC). These conditions were maintained by white fluorescent lamps (40 W), with average irradiance of 91 µmol.m².s^-1. The experimental design was completely randomized.

In total, six days were needed to finish the bioassay, with daily counting at each 12 hours. Germinated cypselae were considered those with root protrusion of 2 mm. Germination rate (GR) and speed of germination index (SGI) were determined for each group. Germination rate was calculated as the percentage of germinated seeds in the last counting. GSI value was calculated by the formula GSI = (G1 / N1) + (G2 / N2) +...+ (Gn / Nn), where: G1 = number of germinated seeds in the first counting; N1 = number of hours elapsed until the first counting; G2 = number of germinated seeds in the second counting; N2 = number of hours elapsed until the second counting; and n corresponds to the last counting (Maguire 1962Maguire JD (1962) Speed of germination: aid in selection and evaluation for seedling emergence and vigor. Crop Science 2: 176-177.).

Initial growth assays

Effects of the aqueous extracts on root and shoot growth were evaluated with L. sativa seedlings. For the pre-treatment period, the cypselae were kept in Petri dishes with filter paper and distilled water. After primary root growth and the emergence of cotyledonary leaves (36 h), seedlings were transferred to plates containing the treatments, in the same conditions of the germination assays. For each extract and its respective concentrations, four repetitions of 25 seedlings were set. After five days in a growth room, seedlings were photographed and the values of root and shoot length were obtained with the software Image J.

Establishment of pH controls

Changes in extract pH can affect germination and seedling growth, and thus, effects of extracts can be erroneously attributed to allelochemicals (Einhellig 1986Einhellig FA (1986) Mechanisms and modes of action of allelochemicals. In: Putman AR & Tang CH-S (eds.) The Science of Allelopathy. Wiley, Minneapolis. Pp. 171-188.). Effects of pH of M. nigra aqueous extracts were assessed on germination and growth of L. sativa. Water pH and pH of the highest concentration of each extract (10%) were measured with a pHmeter. Aqueous extracts showed pH values of 5.97 for fruit, 7.04 for fresh leaves, 6.89 for dry leaves, and water pH was 7.02. Controls were established in solutions of distilled water and HCl 1M to adjust pH to the same value of each extract. Effects of these pH controls on germination and seedling growth were tested and compared to control (water), as described above.

Membrane integrity evaluation

Effects of M. nigra aqueous extracts on membrane integrity were evaluated by measuring the electrolyte leakage of seedling membranes. At the end of the early growth experiments, seedlings (0.2 g) from each plate were placed in tubes with distilled water (10 mL). After 24 h, the initial electrical conductivity of the medium (EC1) was measured using a digital conductivity meter (METRHOM 856). Samples in the tubes were frozen for total releasing of cell electrolytes, unfrozen and, after 24 hours, the final electrical conductivity (EC2) was measured. In order to calculate the relative electrolyte leakage (REL), the formula REL(%) = E₁/(E₁+E₂)*100 was used.

Total phenolic content

Total phenolic content in the aqueous extracts was assessed by Folin-Ciocalteau colorimetric method (Singleton et al. 1999Singleton VL, Orthofer R & Lamuela-Raventos RM (1999) Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent. Methods in Enzymology 299: 152-178.). An aliquot of 100 µL from the extract sample was mixed with 7.0 mL of distilled water, followed by addition of 500 µL of Folin-Ciocalteau reagent. After five minutes, 1.5 mL of a solution of sodium carbonate and water (2:10) was added to the sample. The absorbance was measured after 120 minutes at 760 nm with a spectrophotometer (UV-VIS). For each extract concentration, samples were made in triplicate. Tannic acid was used as the reference phenolic, in nine concentrations ranging from 0.1 to 10 mg/mL (R² = 0.98). Results were expressed in mg tannic acid equivalent/mL of extract.

Statistical analysis

For all the experiments, the measured parameters for each recipient species (germination rate, speed of germination, shoot length, root length and electrolyte leakage) were compared between groups by univariate analysis of variance with randomization (PERMANOVA). When analysis of variance indicated significant differences between groups, contrast analyses were used for pairwise comparisons (Pillar & Orlóci 1996Pillar VP & Orlóci L (1996) On randomization testing in vegetation science: multifactor comparisons of relevé groups. Journal of Vegetation Science 7: 585-592.). Randomization tests are not based on assumptions of normality and homogeneity of variances (Anderson 2001Anderson M (2001) A new method for non-parametric multivariate analysis of variance. Austral Ecology 26: 32-46.). Tests were conducted with 10,000 bootstrap iterations, using Euclidean distance as the dissimilarity measure, and considering a significance level of p ≤ 0.05. Analyses were performed with Multiv software (Pillar 2009Pillar VD (2009) MULTIV, software for multivariate exploratory analysis, randomization testing and bootstrap resampling. Version Beta 2.6.8. Departamento de Ecologia, UFRGS, Porto Alegre. Available at <http://ecoqua.ecologia.ufrgs.br>. Access on 26 november 2015.
http://ecoqua.ecologia.ufrgs.br... ).

Results

Extracts of fruit, fresh and dry leaves of M. nigra caused inhibitory effects on L. sativa germination. All the three extracts significantly reduced the germination rate of the recipient species from 0.25% (Fig. 1a). Regarding the speed of germination, the extracts of fresh and dry leaves were inhibitory from 0.25%, while the fruit extract only affected this parameter from 2.5% (Fig. 1b). Total inhibition of germination rate and speed of germination of L. sativa was observed from 2.5%, 5% and 10% for the extracts of dry leaves, fruit and fresh leaves, respectively.

Figure 1
Effects of aqueous extracts of fruit, fresh and dry leaves of Morus nigra on (a.) germination rate and (b.) speed of germination of Lactuca sativa. Data are presented as mean + standard deviation, with n = 4. (*) Significantly different from control, according to PERMANOVA, at p ≤ 0.05.

The aqueous extracts of M. nigra negatively affected seedling growth of L. sativa, with a stronger effect on root length. Extracts of dry and fresh leaves of M. nigra inhibited root growth of the recipient species from 0.1%, and the fruit caused inhibition from 0.5% (Fig. 2a). Shoot growth was affected by extracts of fresh leaves, dry leaves and fruit from 0.25%, 0.5% and 7.5%, respectively (Fig. 2b). Some seedlings were so damaged that they were decomposing, breaking at the slightest handling and thus could not be measured, which occurred for extracts of dry (10%) and fresh leaves (from 5 to 10%). Fruit extract of M. nigra at 0.75% and 1% promoted L. sativa shoot growth. In addition, necrotic roots were observed for seedlings exposed to the extracts of fresh and dry leaves from 0.75% and to the fruit extract from 2.5%. Seedlings were chlorotic (whitish) from concentrations of 5%, 7.5% and 10% for extracts of fresh leaves, dry leaves and fruit, respectively.

Figure 2
Effects of aqueous extracts of fruit, fresh and dry leaves of Morus nigra on (a.) root length and (b.) shoot length of Lactuca sativa. Data are presented as mean + standard deviation, with n = 4. (*) Significantly different from control, according to PERMANOVA, at p ≤ 0.05.

The pH control of the extracts did not cause significant inhibition in germination rate and speed of germination, when compared to the control treatment (Tab. 1). The same result was observed in relation to root and shoot length, as the treatments with the same pH of the extracts did not differ in relation to control.

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Table 1
Effects of pH controls for aqueous extracts of fruit, fresh and dry leaves of Morus nigra on germination and seedling growth of Lactuca sativa . Controls were established in solutions of distilled water and HCl 1M in the same pH of the highest concentration of each extract (10%). Data are presented as mean + standard deviation, with n = 4. No treatment differed from the control (water), according to PERMANOVA, at p ≤ 0.05.

Integrity of seedling membranes was affected by the three extracts, and the highest electrolyte leakage was observed in seedlings submitted to the fruit aqueous extract (Fig. 3). Electrolyte leakage of seedlings exposed to the fruit extract was significantly higher than the control from 0.1%. Dry and fresh leaf extracts affected electrolyte leakage from 0.5% and 2.5%, respectively. However, evaluation of membrane integrity was not possible for concentrations from 5 to 10% of fresh and dry leaf extracts for the same reason of growth measurements (seedling decomposition).

Figure 3
Effects of aqueous extracts of fruit, fresh and dry leaves of Morus nigra L. on electrolyte leakage of membranes of Lactuca sativa L. seedlings. Data are presented as mean + standard deviation, with n = 4. (*) Significantly different from control, according to PERMANOVA, at p ≤ 0.05.

The aqueous extracts showed high phenolic content (Fig. 4), especially the fruit extract, which had the highest value at 10% (1.37 mg tannic acid equivalent/mL of extract). The aqueous extracts of dry and fresh leaves at 10% reached, respectively, 1.01 and 0.50 mg tannic acid equivalent/mL of extract.

Figure 4
Total phenolic content of aqueous extracts of fruit, fresh and dry leaves of Morus nigra, based in Folin- Ciocalteau method and using tannic acid as the standard phenolic compound. Data are presented as mean + standard deviation, with n = 3.

Discussion

The aqueous extracts of M. nigra inhibited germination and growth of L. sativa seedlings even in low concentrations, which evidences the high phytotoxicity of the extracts. Furthermore, the extracts caused morphological changes in seedlings (chlorotic seedlings and necrotic roots). All the extracts showed similar phytotoxicity regarding germination rate (inhibitory effects starting from 0.25%). The fruit extract was less phytotoxic on speed of germination, root and shoot growth and morphological alterations than the leaf extracts, but it was more phytotoxic on integrity of seedling membranes. Thus, although the fruit extract was in general less phytotoxic, this is not a rule for all parameters. This shows the importance of evaluating several parameters in phytotoxicity studies, which allows a better comprehension of variability in effects. Additionally, the fruit extract in low concentrations caused stimulatory effects on shoot growth of the recipient species. This may have occurred as low concentrations of allelochemicals can stimulate effects that high concentrations inhibit (Rice 1984Rice EL (1984) Allelopathy. 2nd ed. Academic Press, London. 422p.).

Extracts of fruit, dry and fresh leaves of M. nigra affected integrity of seedling membranes, which may have been related to the inhibition in seedling growth. Effects on membranes were so pronounced that at concentrations above 2.5% of fresh and dry leaf extracts, seedlings decomposed. Changes in integrity, fluidity and permeability of membranes can be initially caused by production and accumulation of reactive oxygen species (ROS), which can affect the membranes and result in DNA and protein damages, leading to cell death (Testa & Caldwell 1995Testa B & Caldwell J (1995) The metabolism of drugs and other xenobiotics. Academic Press, New York. 471p.; Qian et al. 2009Qian H, Xu X, Chen W, Jiang H, Jin Y, Liu W & Fu Z (2009) Allelochemical stress causes oxidative damage and inhibition of photosynthesis in Chlorella vulgans. Chemosphere 75: 368-375.). The overproduction of ROS has been considered one of the initial mechanisms of allelochemical effects on germination and seedling growth (Yu et al. 2003Yu JQ, Ye SF, Zhang MF & Hu WH (2003) Effects of root exudates, aqueous root extracts of cucumber (Cucumis sativus L.) and allelochemicals on photosynthesis and antioxidant enzymes in cucumber. Biochemical Systematics and Ecology 31: 129-139.). Moreover, the chlorotic appearance of L. sativa seedlings was observed when they were submitted to high concentrations of M. nigra extracts, indicating degradation of chlorophyll molecules or inhibition of their synthesis (Rice 1984Rice EL (1984) Allelopathy. 2nd ed. Academic Press, London. 422p.). Changes on chlorophyll content due to exposure to allelochemicals can interfere in photosynthesis, affecting plant development (Rice 1984Rice EL (1984) Allelopathy. 2nd ed. Academic Press, London. 422p.; Inderjit & Dakshini 1996Inderjit D & Dakshini KMM (1996) Allelopathic potential of Pluchea lanceolata (Asteraceae): comparative studies of cultivated fields. Weed Science 44: 393-396.; Chou 1999Chou CH (1999) Roles of allelopathy in plant biodiversity and sustainable agriculture. Critical Reviews in Plant Sciences 18: 609-636.). Thus, the effects of M. nigra extracts on germination and seedling growth may have been caused by ROS accumulation that caused membrane damages, and by chlorophyll reduction, consequently decreasing photosynthesis.

Changes in extract pH did not inhibit germination and seedling growth, indicating that the observed effects were due to allelochemicals. Total phenolic content was higher in the fruit extract than in the extracts of fresh and dry leaves. However, the fruit extract was not more phytotoxic than the leaf extracts, suggesting the existence of another class of compounds with phytotoxic action. Further studies are necessary in order to elucidate the chemical aspects of M. nigra phytotoxicity. Phytochemical studies of species from Morus genus indicate that their fruit show phenolic compounds with a wide biochemical activity (Pérez-Gregório et al. 2011Pérez-Gregorio MR, Regueiro J, Alonso-Gonzalez E, Pastrana-Castro LM, Simal-Gándara J (2011) Influence of alcoholic fermentation process on antioxidant activity and phenolic levels from mulberries (Morus nigra L.). Food Science and Technology 44: 1973-1801.; Toshio et al. 2005Toshio F, Kiyoshi K & Sumio T (2005) Antimicrobial activity of 2-arylbenzofurans from Morus species against methicillin-resistant Staphylococcus aureus. Fitoterapia 76: 708-711.; Wang et al. 2011Wang CP, Wang Y, Wang X, Zhang X, Ye JF, Hu LS & Kong LD (2011) Mulberroside A possesses potent uricosuric and nephroprotective effects in hyperuricemic mice. Planta Medica 77: 786-794.), which are found in greater quantities in M. nigra than in M. alba and M. rubra (Memon et al. 2010Memon AA, Memon N, Luthria DL, Muhammad IB & Pitafi AA (2010) Phenolic acids profiling and antioxidant potential of mulberry (Morus laevigata W, Morus nigra L, Morus alba L.) leaves and fruits grown in Pakistan. Polish Journal of Food and Nutrition Sciences 60: 25-32.; Ercisli & Orhan 2007Ercisli S & Orhan E (2007) Chemical composition of while (Morus alba), red (Morus rubra) and black (Morus nigra) mulberry fruits. Food Chemistry 103: 1380-1384.; Nakamura et al. 2003Nakamura Y, Watanabe S, Miyake N, Kohno H & Osawa T (2003) Dihydrochalcones: evaluation as novel radical scavenging antioxidants. Journal of Agricultural and Food Chemistry 51: 3309-3312.). Sývacý & Sökmen (2004)Sývacý A & Sökmen M (2004) Seasonal changes in antioxidant activity, total phenolic and anthocyanin constituent of the stems of two Morus species (Morus alba L. and Morus nigra L.). Plant Growth Regulation 44: 251-256. and Dugo et al. (2001)Dugo P, Mondello L, Errante G, Zappia G & Dugo G (2001) Identification of anthocyanins in berries by narrow-bore high-performance liquid chromatography with electrospray ionization detection. Journal of Agricultural and Food Chemistry 49: 3987-3992. recorded high content of total phenolics in phytochemical studies with M. alba and M. nigra branches in a certain seasonal period for both species. Moreover, some classes of phenolic compounds which are often found in decomposing plant material and widely distributed inside the plant (Kujala et al. 2000Kujala TS, Loponen JM, Klika KD & Pihlaja K (2000) Phenolics and betacyanins in red beetroot (Beta vulgaris) root: distribution and effect of cold storage on the content of total phenolics and three individual compounds. Journal of Agricultural and Food Chemistry 48: 5338-5342.) are known by their potential to inhibit seed germination (Rice 1984Rice EL (1984) Allelopathy. 2nd ed. Academic Press, London. 422p.). Thus, even if the phenolic compounds are probably associated to the phytotoxic effects of M. nigra, other classes of chemical substances are also possibly related to its phytotoxicity.

In spite of being an initial study, the high phytotoxicity of M. nigra extracts was observed herein. This suggests the possibility of associating allelopathy with the invasive potential of the species. Nevertheless, by the extraction process used for the aqueous extracts, the maceration may release compounds that would not be active in natural processes, such as leaf fall on soil and microorganism degradation (Inderjit & Dakshini 1996Inderjit D & Dakshini KMM (1996) Allelopathic potential of Pluchea lanceolata (Asteraceae): comparative studies of cultivated fields. Weed Science 44: 393-396.). Thereby, further studies must consider using plant tissues from intact leaves and fruit of M. nigra in order to better comprehend the potentiality of this species to release allelochemicals.

Even though the high phytotoxicity of M. nigra extracts has been observed, it is important to highlight that this study only shows that the species causes phytotoxic effects in laboratory conditions. The evidence of these effects on germination and growth of species that are sensitive to allelochemicals needs to be tested in natural conditions, and using soil. Moreover, it is relevant to comprehend the mechanisms of allelopathic action of the species in seasonal periods. The species can release its compounds through tissue lixiviation, with the leaf attached to the branch or during decomposition in the soil. Therefore, it is possible that M. nigra affects other species, mainly the native ones, increasing its propagation.

In conclusion, M. nigra fruit and leaf extracts are phytotoxic, affecting germination and initial growth of L. sativa, and also the integrity of seedling membranes. In general, the fruit extract was less phytotoxic than the fresh and dry leaf extracts. This indicates the allelopathic potential of the species, possibly through decomposition and lixiviation by rain of allelochemicals from leaf and fruit. However, field studies are still necessary to comprehend whether allelopathy is indeed involved in the invasiveness of M. nigra.

Acknowledgements

The authors thank Fundação de Amparo à Pesquisa do estado do Rio Grande do Sul (FAPERGS) for the financial support and the scholarship granted to the first author, and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for the PhD scholarship granted to E.R. Silva. The authors also thank all collaborators of the Plant Propagation Laboratory and the Chemistry Laboratory from Univates.

References

Anderson M (2001) A new method for non-parametric multivariate analysis of variance. Austral Ecology 26: 32-46.
Bais HP, Vepachedu R, Gilroy S, Callaway RM & Vivanco JM (2003) Allelopathy and exotic plant invasion: from molecules and genes to species interactions. Science 301: 1377-1380.
Chan EW, Lye PY & Wong SK (2016) Phytochemistry, pharmacology, and clinical trials of Morus alba Chinese Journal of Natural Medicines 14: 17-30.
Chou CH (1999) Roles of allelopathy in plant biodiversity and sustainable agriculture. Critical Reviews in Plant Sciences 18: 609-636.
Dugo P, Mondello L, Errante G, Zappia G & Dugo G (2001) Identification of anthocyanins in berries by narrow-bore high-performance liquid chromatography with electrospray ionization detection. Journal of Agricultural and Food Chemistry 49: 3987-3992.
Einhellig FA (1986) Mechanisms and modes of action of allelochemicals. In: Putman AR & Tang CH-S (eds.) The Science of Allelopathy. Wiley, Minneapolis. Pp. 171-188.
Ercisli S & Orhan E (2007) Chemical composition of while (Morus alba), red (Morus rubra) and black (Morus nigra) mulberry fruits. Food Chemistry 103: 1380-1384.
Gotllieb OR (1982) Micromolecular, evolution, systematics and ecology: an essay into a novel botanical discipline. Springer-Verlag, Berlin. 171p.
Inderjit D & Dakshini KMM (1996) Allelopathic potential of Pluchea lanceolata (Asteraceae): comparative studies of cultivated fields. Weed Science 44: 393-396.
Judd WS, Campbell CS, Kellogg EA, Kellogg EA, Stevens PF & Donoghue MJ (2009) Plant systematics: a phylogenetic approach. 3^rd ed. Sinauer, Sunderland. 612p.
Kennedy TA, Naeem S, Howe KM, Knops JMH, Tilman D & Reich P (2002) Biodiversity as a barrier to ecological invasion. Nature 417: 636-638.
Kujala TS, Loponen JM, Klika KD & Pihlaja K (2000) Phenolics and betacyanins in red beetroot (Beta vulgaris) root: distribution and effect of cold storage on the content of total phenolics and three individual compounds. Journal of Agricultural and Food Chemistry 48: 5338-5342.
Maguire JD (1962) Speed of germination: aid in selection and evaluation for seedling emergence and vigor. Crop Science 2: 176-177.
Memon AA, Memon N, Luthria DL, Muhammad IB & Pitafi AA (2010) Phenolic acids profiling and antioxidant potential of mulberry (Morus laevigata W, Morus nigra L, Morus alba L.) leaves and fruits grown in Pakistan. Polish Journal of Food and Nutrition Sciences 60: 25-32.
Nakamura Y, Watanabe S, Miyake N, Kohno H & Osawa T (2003) Dihydrochalcones: evaluation as novel radical scavenging antioxidants. Journal of Agricultural and Food Chemistry 51: 3309-3312.
Pérez-Gregorio MR, Regueiro J, Alonso-Gonzalez E, Pastrana-Castro LM, Simal-Gándara J (2011) Influence of alcoholic fermentation process on antioxidant activity and phenolic levels from mulberries (Morus nigra L.). Food Science and Technology 44: 1973-1801.
Pillar VP & Orlóci L (1996) On randomization testing in vegetation science: multifactor comparisons of relevé groups. Journal of Vegetation Science 7: 585-592.
Pillar VD (2009) MULTIV, software for multivariate exploratory analysis, randomization testing and bootstrap resampling. Version Beta 2.6.8. Departamento de Ecologia, UFRGS, Porto Alegre. Available at <http://ecoqua.ecologia.ufrgs.br>. Access on 26 november 2015.
» http://ecoqua.ecologia.ufrgs.br
Qian H, Xu X, Chen W, Jiang H, Jin Y, Liu W & Fu Z (2009) Allelochemical stress causes oxidative damage and inhibition of photosynthesis in Chlorella vulgans Chemosphere 75: 368-375.
Rice EL (1984) Allelopathy. 2^nd ed. Academic Press, London. 422p.
Rizvi SJH, Tahir M, Rizvi V, Kohli RK & Ansari A (1999) Allelopathic interactions in agroforestry systems. Critical Reviews in Plant Sciences 18: 773-796.
Singleton VL, Orthofer R & Lamuela-Raventos RM (1999) Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent. Methods in Enzymology 299: 152-178.
Sývacý A & Sökmen M (2004) Seasonal changes in antioxidant activity, total phenolic and anthocyanin constituent of the stems of two Morus species (Morus alba L. and Morus nigra L.). Plant Growth Regulation 44: 251-256.
Testa B & Caldwell J (1995) The metabolism of drugs and other xenobiotics. Academic Press, New York. 471p.
Toshio F, Kiyoshi K & Sumio T (2005) Antimicrobial activity of 2-arylbenzofurans from Morus species against methicillin-resistant Staphylococcus aureus. Fitoterapia 76: 708-711.
Wang CP, Wang Y, Wang X, Zhang X, Ye JF, Hu LS & Kong LD (2011) Mulberroside A possesses potent uricosuric and nephroprotective effects in hyperuricemic mice. Planta Medica 77: 786-794.
Weidenhamer JD (1996) Distinguishing resource competition and chemical interference: overcoming the methodological impasse. Agronomy Journal 88: 866-875.
Weir TL, Park SW & Vivanco JM (2004) Biochemical and physiological mechanisms mediated by allelochemicals. Current Opinion in Plant Biology 7: 472-479.
Yu JQ, Ye SF, Zhang MF & Hu WH (2003) Effects of root exudates, aqueous root extracts of cucumber (Cucumis sativus L.) and allelochemicals on photosynthesis and antioxidant enzymes in cucumber. Biochemical Systematics and Ecology 31: 129-139.

Edited by

Editor de área: Dr. Claudio Barbedo

Publication Dates

Publication in this collection
Oct-Dec 2018

History

Received
16 Jan 2017
Accepted
29 Sept 2017

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

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	Control	Fruit extract pH	Fresh leaf extract pH	Dry leaf extract pH
Germination rate (%)	99 ± 2	99 ± 2	100	99 ± 2
Speed of germination	1.4 ± 0.09	1.18 ± 0.13	1.22 ± 0.12	1.19 ± 0.11
Root length (cm)	2.90 ± 0.81	2.65 ± 0.32	3.10 ± 0.46	2.85 ± 0.45
Shoot length (cm)	0.64 ± 0.05	0.63 ± 0.06	0.66 ± 0.03	0.60 ± 0.01

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