African Journal of
Agricultural Research

  • Abbreviation: Afr. J. Agric. Res.
  • Language: English
  • ISSN: 1991-637X
  • DOI: 10.5897/AJAR
  • Start Year: 2006
  • Published Articles: 6884

Full Length Research Paper

Coffee straw used as mulch for germination and strength of crops and spontaneous species seedlings

Elisa Maria Campos Minassa
  • Elisa Maria Campos Minassa
  • Laboratory of Plant Science, Universidade Estadual do Norte Fluminense Darcy Ribeiro. End.: Av. Alberto Lamego, 2000 - Parque Califórnia, Campos dos Goitacazes, Rio de Janeiro, Brazil.
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Silvério Paiva Freitas
  • Silvério Paiva Freitas
  • Laboratory of Plant Science, Universidade Estadual do Norte Fluminense Darcy Ribeiro. End.: Av. Alberto Lamego, 2000 - Parque Califórnia, Campos dos Goitacazes, Rio de Janeiro, Brazil.
  • Google Scholar
Diego Corona Baitelle
  • Diego Corona Baitelle
  • Department of Plant Science, Universidade Estadual do Norte Fluminense Darcy Ribeiro. End.: Av. Alberto Lamego, 2000 - Parque Califórnia, Campos dos Goitacazes- RJ, Rio de Janeiro, Brazil.
  • Google Scholar
Silvio de Jesus Freitas
  • Silvio de Jesus Freitas
  • Department of Plant Science, Universidade Estadual do Norte Fluminense Darcy Ribeiro. End.: Av. Alberto Lamego, 2000 - Parque Califórnia, Campos dos Goitacazes- RJ, Rio de Janeiro, Brazil.
  • Google Scholar
Ismael Lourenço de Jesus Freitas
  • Ismael Lourenço de Jesus Freitas
  • Fundação de Apoio à Escola Técnica (FAETEC), Rua Clarimundo de Melo, 847 - Quintino Bocaiuva, Rio de Janeiro - RJ, 21311-280, Brazil.
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Luiz Melo de Souza
  • Luiz Melo de Souza
  • Fundação de Apoio à Escola Técnica (FAETEC), Rua Clarimundo de Melo, 847 - Quintino Bocaiuva, Rio de Janeiro - RJ, 21311-280, Brazil.
  • Google Scholar


  •  Received: 25 September 2017
  •  Accepted: 20 October 2017
  •  Published: 07 December 2017

 ABSTRACT

The objective of this study was to evaluate the allelopathic effect of using conilon and arabica coffee straw as mulch on the emergence and development of three crops (Lactuca sativa, Cucumis sativu, Solanum lycopersicum) and three natural plants (Eupatorium maximilianii, Amaranthus hybridus and Bidens pilosa). The experiment was carried out in a greenhouse in a completely randomized design, with six repetitions. The treatments were arranged in a 3×6 factorial scheme, with three treatments of soil cover: Control (uncovered), conilon coffee straw and arabica coffee straw and six plant species.  Conilon coffee straw harmed the emergence of C. sativus, L. sativa and E. maximilianii; it reduced the emergence speed of the studied species, except for S. lycopersicum and A. hybridus; it reduced both fresh and dried C. sativus masses. Arabica coffee straw only compromised the emergence of E. maximilianii; it reduced the emergence speed of L. sativa, E. maximilianii, and A. hybridus; and it increased both fresh and dry masses of C. sativus seedlings. It is possible to conclude that conilon coffee straw can be used as mulch in S. lycopersicum crops, in the management of the weed E. maximilianii, and also to delay the emergence of B. pilosa. Arabica coffee can be used in C. sativus, S. lycopersicum and L. sativa crops in the control of E. maximilianii and to slow down the emergence of A. hybridus.

Key words: Cucumis sativus, Lactuca sativa, Solanum lycopersicum L., Eupatorium maximilianii Schrad, Amaranthus hybridus L, Bidens pilosa L.


 INTRODUCTION

Brazil is the largest producer and exporter and the second largest consumer of coffee in the world, with a production of about 55 million benefited bags in 2016 (ICO, 2017). During the fruit processing, a large volume of residues is produced, especially coffee straw (outer skin + parchment), which is often incorrectly discarded, resulting in damage to the environment (Magalhães et al., 2008).
 
In agriculture, the importance of the application of straw mulch has been tested as useful tool to improve soil quality and to reduce soil erosion. Especially, coffee straw, that is widely used as a composition of organic substrates for seedling production (Godoy et al., 2008; Coelho et al., 2016; Cerdà et al., 2017). It can also be used as mulch, both for crop nutrition, since this residue is an excellent organic matter, potassium and nitrogen source (Costa et al., 2007), as well as for managing natural plants, because of its negative effect on some natural plants due to its allelopathic potential.
 
Allelopathy is a common phenomenon in plant communities, in which certain plants or plant residues release allelochemicals substances that interfere with the development of nearby plants (Zhang et al., 2011). The allelochemicals can act in pre and post-emergence stages and in the soil seedbank (Han et al., 2008), which is an important factor in the control of certain undesired species, thus obtaining more productive crop systems (Goldfarb et al., 2009).
 
Caffeine and phenols found in coffee are secondary metabolites that act as allelochemicals in several plant species (Lima et al., 2007). It is known that conilon coffee has higher caffeine and polyphenols content than arabica coffee does (Ribeiro et al., 2014). This fact indicates that the straw of each one of these species of coffee may present different allelopathic responses that might interfere positively or negatively in the plants present therein, including the main crop (Rizzardi et al., 2008; Tesio et al., 2011; Campiglia et al., 2012).
 
In spite of presenting a great allelopathic potential over invasive plants and of being a source of nutrition for several crops, there are still few studies in literature that correlate the use of coffee straw as mulch in cultivation and weeds management. May et al. (2011) reported that coffee skin can also be tested for the creation of natural herbicides less aggressive to the environment, and show the great importance of studies that seek new options for the usage of coffee straw.
 
In this research the crop species tested are among the most cultivated in Brazil. Besides being highly sensitive to allelopathic substances, they are widely used as bioindicator plants for bioassays. The natural plants tested are the most present in cultivated areas, and they compete for the production factors with the cultivated species, causing reduction of productivity and product quality (Lorenzi, 2008).
 
The objective of this study was to evaluate the effect of mulches (conilon and arabica coffee straws) on the germination and development of three crops (Lactuca sativa, Cucumis sativus and Solanum lycopersicum) and three weeds (Eupatorium maximilianii, Amaranthus hybridus and Bidens pilosa).


 MATERIALS AND METHODS

The experiment was carried out at the weed and medicinal plants sector of the Center of Agricultural Sciences and Technology of the Universidade Estadual do Norte Fluminense Darcy Ribeiro, located in the city of Campos de Goytacazes-RJ, at latitude of 21°19'23" S and longitude of 41°19'41" W. According to the classification of Köeppen, the climate is tropical, hot and humid with rainy summers, dry winters, and average altitude of 11 m.
 
A completely randomized design of six repetitions was used. The treatments were arranged in a 3×6 factorial scheme, with three treatments of soil cover: Control (uncovered), conilon coffee straw (Coffea canephora) and arabica coffee straw (Coffea arabica); and six plant species (Lactuca sativa, Cucumis sativus, Solanum lycopersicum, Eupatorium maximilianii, Amaranthus hybridus and Bidens pilosa).
 
Conilon coffee straw was obtained from the production and processing of grains of plants from the variety G35 cultivated in the municipality of Muqui, Espírito Santo, at latitude: 20º57'06" S, and longitude: 41º20'45" W and altitude, 250 m. The arabica coffee straw was obtained from the production, pulping and processing of grains of Catuaí Vermelho IAC 81 cultivar, cultivated in the city of Venda Nova do Imigrante, Espírito Santo, Brazil at Latitude: 20º20'23" S, longitude: 41º08'05" W and altitude 63 m.
 
The seeds of L. sativa, C. sativus and S. lycopersicum were acquired in the local commerce. They present fast germination and high sensitivity to allelopathy. The seeds of E. maximilianii, A. hybridus and B. pilosa were purchased from Cosmos Agrícola Produção e Serviços Rurais Ltda (Agrocosmos), a company specialized in the control of prepared seeds, located in the city of Engenheiro Coelho, São Paulo.
 
The seeds were sown in polyethylene trays (25 cm × 40 cm) in an 18 cm long line and 5 cm between the rows. Different number of seeds was used for each specie, in order to allow adequate densities of germination and plant growth. 18 seeds of L. sativa, 8 of C. sativus, 12 of S. lycopersicum and black pickle and 20 of E. maximilianii and A. hybridus to the depth of 1 cm was used.
 
The substrate used was 150 mL of sand that had received irrigation for five days before planting, in order to leach possible compounds present in the material. Subsequently, the substrate was covered, between rows, with 150 mL of dry coffee skin per 90 cm2 of area, except the control, which remained uncovered. The treatments were irrigated daily to maintain the moisture content of the soil close to the field capacity.
 
The allelopathic activity was evaluated by the following tests:
 
1. Percentage of emergence (PE): Determined by the count of the number of seedlings emerged in the last emergence assessment, according to the species, on the seventh day after installation of the test for L. sativa; on the eighth day for C. sativus; on the fourteenth day for S. lycopersicum, A. hybridus and B. pilosa; and on the twenty-fifth day for E. maximilianii. The results were expressed as percentage of emerged seeds (Brazil, 2009).
 
2. Emergence speed index (ESI): The count of emerged seedlings was performed daily, from first seedling emergence to the last one according to each species, and subsequent conversion to the index proposed by Maguire (1962). Fresh matter (FM) and dry matter (DM) of the seedlings: At the end of the total emergence test, the seedlings were removed from the trays, washed in running water, taken to the laboratory, where they were weighed to establish the amount of fresh matter. Then the seedlings were placed in a forced air convection oven at 40°C for 72 h. The weighing were realized on a precision scale, with the results expressed in milligrams per seedling (mg plant-1).
 
The data were submitted to Liliefors test for normality of variance and Cochran and Barttlet test for homogeneity. In these tests, the need to transform the PE and ESI variables by the arcsine of the square root (x / 100) and the FM and DM by the square root (x + 1) was identified. The variance analysis and mean separation were done by the Tukey test at 5% probability level. The software SAEG 9.0 was always used.


 RESULTS AND DISCUSSION

The variance analysis indicated a significant interaction effect (P<0.05) between the type of mulch and the species studied for all variables analyzed, as shown in Table 1. 
 
 
Among the evaluated species, L. sativa and C. sativus were the ones that presented the highest percentage of emergence both in the control (without mulch) and in the covered with arabica coffee straw treatments. However, the straw from conilon coffee reduced the emergence of L. sativa to 28.70% (a reduction of 60.19% in relation to the control), as shown in Table 2.
 
 
It was verified that conilon coffee straw affected the ESI of the studied species, except for S. lycopersicum and A. hybridus. However, this mulch increased the ESI of C. sativus and B. pilosa. Arabica coffee straw reduced L. sativa ESI (Table 2), but there was no effect on the ESI of the other studied species.
 
In relation to spontaneous species, E. maximilianii was the only one that had the emergence of the seedlings influenced by the mulches, in which the conilon coffee straw was reduced by 85.33% and the arabica coffee straw was reduced by 46.67%. This fact indicates that E. maximilianii is highly sensitive to this type of soil cover, and that the use of coffee straw (especially that of conilon coffee) may be a viable alternative in the control of this invader plant.
 
Arabica coffee straw can be used as mulch for the cultivation of C. sativus and S. lycopersicum without causing damage to the emergence of the seedlings. However, conilon coffee straw harmed the emergence of C. sativus (14.58% reduction) and L. sativa (60.19% reduction), indicating that it should not be used in the cultivation of these crops.
 
The ESI for the C. sativus was higher in the presence of arabica coffee mulch (5.50) in comparison to the conilon coffee (3.29). This result indicates that conilon coffee straw interferes negatively with C. sativus, and reveals that arabic coffee straw can benefit the culture of this crop, since it does not harm its emergence and increases its ESI.
 
Although the Arabic coffee straw positively influenced the percentage of emergence of L. sativa seedlings, there was a negative effect on ESI, indicating that this coffee straw may present a negative allelopathic effect on this specie. Moreira et al. (2016) observed that L. sativa plants have their growth considerably inhibited when cultivated in soil obtained close to the coffee root, due to the release of allelochemicals, which corroborates the data of this study.
 
E. maximilianii and B. pilosa have shown an ESI reduction when conilon coffee straw was used as mulch. These results suggest that this cover can be used to reduce the emergence speed of these species.
 
In addition to the reduction of the emergence and ESI caused by conilon coffee straw in C. sativus seedlings, radicular anomalies were observed, such as size reduction, thickening and necrosis, evident symptoms of the allelopathic effect of the mulch (Ferreira and Áquila, 2000). It is known that the conilon coffee has a higher content of caffeine, soluble solids and polyphenols than the arabica coffee does (Ribeiro et al., 2014). This fact may explain the great negative influence of conilon straw on the emergence and ESI for most species studied, since caffeine and phenols are the main secondary metabolites of coffee that act as allelochemicals (Lima et al., 2007) .
 
However, similar symptoms of the negative allelopathic effect were also observed by May et al. (2011) when studying the effect of arabica coffee straw extract on the development of C. sativus. It is believed that this effect occurred due to the mode of use, in which the extract may have presented higher concentration of allelochemicals than the straw used as mulch, which usually presents a slower release of its allelochemicals.
 
Regarding the fresh mass, an increase in the fresh matter of the C. sativus seedlings was observed when arabica coffee straw was used as mulch, in comparison to the control. However, the conilon coffee straw reduced the fresh mass of the C. sativus and of the S. lycopersicum and there was no effect on the S. lycopersicum, in relation to the control (Table 3).
 
 
 
It can be observed that the seedlings of S. lycopersicum and C. sativus suffered a negative influence of the conilon coffee straw mulch, with 53.66 and 73.39% fresh mass reduction, respectively. The arabica coffee straw influenced only the C. sativus, increasing its fresh mass by 34.37% in relation to the control.
 
It was found that the conilon coffee straw provided a reduction of 39.81% in the dry mass of C. sativus seedlings, whereas the arabica coffee straw provided a 31.71% increase in the dry mass of its seedlings in relation to the control. The other evaluated species behaved indifferently in relation to this variable, which indicates that, although the mulches affect the germination and emergence of these species, they do not influence the development of the seedlings.
 
Caffeic acid (3,4-dihydroxycinnamic acid) present in coffee straw can alter root activity by inhibiting the absorption of phosphate and potassium by depolarization of root membranes (Barkosky et al., 2000). This fact may explain the lower amount of fresh and dry mass of the S. lycopersicum and C. sativus seedlings, when conilon coffee straw was used as mulch.
 
Barkosky et al. (2000), when evaluating the allelopathic effects of caffeic acid in Euphorbia escola, verified that the exposure of the plant to caffeic acid for 30 days reduced the leaf area, the leaf mass, root mass, root length, above-ground length and total plant weight, when compared to the control. This result corroborates with those found in this work, since conilon coffee straw probably has a higher concentration of caffeic acid than arabica coffee straw does, thus reducing the dry mass of the C. sativus seedlings.


 CONCLUSION

Conilon coffee straw, as mulch, can be used in S. lycopersicum crops cultivation, in the control of the weed E. maximilianii, and also to delay the emergence of B. pilosa. Arabica coffee straw can be used as mulch in C. sativus and S. lycopersicum crops cultivation, in the control of the weed E. maximilianii and in the reduction of the emergence speed of A. hybridus.


 CONFLICT OF INTERESTS

The authors have not declared any conflict of interests.



 REFERENCES

Barkosky RR, Einhellig FA, Butler JL (2000). Caffeic acid-induced changes in plant–water relationships and photosynthesis in leaf y spurge Euphorbiae sula. J. Chem. Ecol. 26(9):2095-2110.
Crossref

 

Brazil (2009). Ministério da Agricultura, Pecuária e Abastecimento. Regras para análise de sementes. Brasilia, Secretaria Nacional de Defesa Ambiental 399p.

 
 

Campiglia E, Radicetti E, Mancinelli R (2012). Weed negative control strategies and yield response in a pepper crop (Capsicum annuum L.) mulched with hairy vetch (Vicia villosa Roth.) and oat (Avena sativa L.) residues. Crop Prot. 33(1):65-73.
Crossref

 
 

Cerdà A, Rodrigo-Comino J, Giménez Morera A, Keesstra SD (2017). An economic, perception and biophysical approach to the use of oat straw as mulch in Mediterranean rainfed agriculture land. Ecol. Eng. 108:162-171.
Crossref

 
 

Coelho GF, GonÇalves Jr AC, Nóvoa-Mu-oz JC, Fernández-Calvi-o D, Arias-Estévez M, Fernández-Sanjurjo MJ, Álvarez-Rodríguez E, Nú-ez-Delgado A (2016). Competitive and non-competitive cadmium, copper and lead sorption/desorption on wheat straw affecting sustainability in vineyards. J. Clean. Prod. 139:1496-1503.
Crossref

 
 

Costa RSC, Leônidas FC, Rodrigues VGS, Santos JCF (2007). In: EMBRAPA RONDÔNIA: Consórcio Brasileiro de Pesquisa e Desenvolvimento do café. Available at: 

View

 
 

Ferreira AG, Aquila ME (2000). Alelopatia: uma área emergente da ecofisiologia. Rev. Bras. de Fisiologia Veg. 12(1):175-204.

 
 

Godoy WI, Farinacio D, Funguetto RF, Borsatti F, Scarioti A, Soligo E, Sbardelotto G (2008). Production of broccolis seedlings in different alternatives substrates. Hortic. Bras. 26(2):3878-3882.

 
 

Goldfarb M, Pimentel LW, Pimentel NW (2009). Alelopatia: relações nos agroecossistemas. Tecnologia e Ciências Agropecuárias, João Pessoa 3(1):23-28.

 
 

Han CM, Pan KW, Wu N, Wang JC, Li W (2008). Allelopathic effect of ginger on seed germination and seedling growth of soybean and chive. Sci. Hortic. 116(1):330-336.
Crossref

 
 

International Coffee Organization (ICO) (2017). Trade Statistics Tables. London, United Kingdom - 2017. Available at: 

View.

 
 

Lima JD, Moraes WS, Mendonça JC, Nomura ES (2007). Resíduos da agroindústria de chá preto como substrato para produção de mudas de hortaliças. Ciênc. Rural 37(1):1609-1613.
Crossref

 
 

Lorenzi H (2008). Plantas Daninhas do Brasil: terrestres, aquáticas, parasitas e tóxicas. In: Lorenzi, H. editor geral Harri Lorenzi. 4ª ed. Nova Odessa. Instituto Platarum. pp. 21-32

 
 

Magalhães EA, Silva JS, Silva JN, Filho DO, Dorneles SML, Martin S, Dutra L (2008). Casca de café associada à lenha como combustível para aquecimento indireto do ar de secagem. Rev. Bras. de Armazenagem 10(1):66-72.

 
 

May D, Rocha L, Oliveira CMR, Maranho LT (2011). Efeito de extratos de casca de café (Coffea arabica L.) na germinação e crescimento de Cucumis sativus (Cucumis sativus L.). Rev. Bras. de Biociências 9:180- 186.

 
 

Moreira MHO, Almeida GRR, da Cunha LT, Queiroz RL (2016). Interações alelopáticas sobre o desenvolvimento de Lactuca sativa (Lactuca sativa, L. cv. Vanda) cultivada em solo cafeeiro. Revista da UIIPS 4(4):16.

 
 

Ribeiro BB, Mendonça LMVL, Assis GA, Mendonça JMA, Malta MR, Montanari FF (2014). Avaliação química e sensorial de blends de Coffea canephora Pierre e Coffea arabica L. Coffee Sci. 9(2):178-186.

 
 

Rizzardi MA, Neves R, Johann LB (2008). Potencial alelopático da cultura da canola (Brassica napus L. var. oleifera) na supressão de Bidens pilosa (Bidens sp.) e soja. Rev. Bras. de Agrociência, Pelotas 14(2):239-248.

 
 

Tesio F, Wenston LA, Ferrero A (2011). Allelo chemicals identified from Jerusalem artichoke (Helianthus tuberosus L.) residues and their potential inhibitory activity in the field and laboratory. Sci. Hortic. 129:361-368.
Crossref

 
 

Zhang S, Zhu W, Wang B, Tang J, Chen X (2011). Secondary metabolites from the invasive Solidago canadensis L. accumulation in soil and contribution to inhibition of soil pathogen Pythium ultimum. Appl. Soil Ecol. 48:280-286.
Crossref

 

 




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