Mi SciELO
Servicios personalizadosServicios Personalizados
Articulo
texto en 
Español (pdf)
Articulo en XML
Referencias del artículo
Enviar articulo por emailIndicadores
-
Citado por SciELO
Links relacionados
-
Similares en
SciELO
Compartir
Permalink
Cultivos Tropicales
versión On-line ISSN 1819-4087
cultrop vol.40 no.4 La Habana oct.-dic. 2019 Epub 01-Dic-2019
Bibliographic review
Generalities of the cultivation of chickpea and biological alternative for the control of the Marchitez
1Unidad Científico Tecnológica de Base "Los Palacios". Km 1½ carretera La Francia, Los Palacios, Pinar del Río, Cuba. CP 22900
2Empresa Agroindustrial de Granos (EAIG) "Los Palacios". Calle 26 e/ 19 y 21 Los Palacios, Pinar del Río, Cuba. CP 22900
3Centro Nacional de Sanidad Agropecuaria (CENSA), carretera de Jamaica y Autopista Nacional. Apartado 10, San José de las Lajas, Mayabeque, Cuba
The chickpea (Cicer arietinum L.), is one of the main sources of human and animal food and is placed on the list of the most cultivated legumes in the world, after soybeans (Glycine max), beans (Vicia faba), beans (Phaseolus vulgaris) and peas or pea (Pisum sativum). Among the biotic factors that limit a high production of chickpea, are the diseases produced by different pathogenic microorganisms of the soil. The Withering or Fusariosis, the causative agent Fusarium spp., Is the most important disease of the chickpea crop, it negatively affects the components of the yield and grain quality. This disease occurs ascending and descending according to the species, sick plants abort their flowers and the few grains that manage to form are of smaller caliber. To control this disease, agro-technical, chemical and biological estrategies are used, the latter being very effective from the economic, social and environmental point of view. The biological fight with products based on Trichoderma strains has had a favorable acceptance, and generalized in Cuban agriculture, for showing several mechanisms of action with direct and indirect effects in the reduction of phytopathogenic microorganisms. In this sense, the Wilt is a disease of difficult control, so knowing about the biology of the pathogen and its interaction with the host are important aspects to establish a more efficient control.
Key words: Cicer arietinum L; Trichoderma; legumes; microorganisms; fusariosis
INTRODUCTION
Origin of the chickpea. Background of the culture. Use and importance
Chickpea is native to the southern Caucasus region and northern Persia, mainly the territory currently occupied by Iran 1. From there it spread to Europe, especially the Mediterranean region, and Africa, mainly Ethiopia, which was its secondary diversification center 2.
Different authors cite the existence of 40 spp. of chickpea preferentially located in the Middle East, Turkey, Israel and Central Asia 3. Of these a single species is cultivated, C. arietinum 4. The Spanish colonizers introduced it in Latin America, successfully implanting in California, Mexico and in dry climate regions throughout the Americas 5.
Chickpea is an improver of soil structure and fertility thanks to the symbiotic fixation of atmospheric nitrogen, which can exceed 70 kg ha-1. In rotation with cereals it makes possible the breaking of the biological cycle of pathogens whose habitat is the soil such as: Sclerotium rolfsii Sacc, Rhizoctonia solani Künh and Macrophomina phaseolina [Tassi] Goidanich 6,7.
World production and trade
The world trade of chickpeas is around 1,100,000 tons, but it records large fluctuations between crop cycles. In the last 12 years the rate of increase of chickpea production in the world was 1.4 %. The main chickpea producing countries are: India, which participates with 68.5 % of the world total, is followed by Australia and thirdly Pakistan. Other countries of importance in production are Turkey, Myanmar, and in the Americas, Mexico and Canada 8. The main exporters are Spain, Jordan and Bangladesh 9).
Taxonomic classification and botanical characteristics of the chickpea culture
According to Mateo-Box J M, cited by Del Moral 10; the taxonomic location of the chickpea crop is:
Class: Angiospermae
Subclass: Dicotyledoneae
Order: Leguminosae
Family: Fabaceae
Genre: Cicer
Species: Cicer arietinum L.
This legume develops like a small shrub, an annual, diploid plant, with a chromosomal number of 2n = 16, with the presence of pubescences throughout the plant, glandular and non-glandular hairs. The roots are strong and the root system is deep, reaches 2 m deep, but the largest proportion is up to 60 cm. The stems are branched flexible or straight, erect or creeping crawlers and can reach up to 1 m tall. The leaves are pseudoimparipinate. Floral clusters usually have a flower, rarely two. The flowers are typically papilliated. The pods are pubescent, pointed and swollen, reaching up to 3 cm in length, which can contain up to three seeds. The seeds have shapes that vary between globular and bilobular, some being almost spherical, of various colors that can range from black to ivory white. The reproduction system is fundamentally autogamy; placing the level of autogamy around 1 % 11,12.
Edafoclimatic requirements
Chickpea is a legume well adapted to dry and cool weather. It is generally grown in the winter of tropical regions and in the spring and summer of temperate regions. Among the optimal conditions for cultivation are: temperatures between 21-29 °C during the day and 18-26 °C at night, average annual rainfall of 600 to 1000 mm. Hail, excessive rainfall and heat damage the crop. The development of cold-resistant cultivars allowed to change the sowing season in temperate zones towards winter, with cycles from sowing to 180-day harvest. The low relative humidity is optimal for seed set. Chickpea behaves like a neutral day plant, however, physiological studies characterize it as a quantitative long day plant, although it blooms in all photoperiods 13.
Factors that influence in the production of chickpea
Numerous factors, both abiotic and biotic, can limit chickpea production. Among the first are climatic factors, such as temperature, which can affect germination, plant growth and physiological processes related to plant development. Another factor is the soils. The crop prefers siliceous-clay or silt-clay soils, which do not contain aerated plaster. Chickpea is sensitive to salinity, both soil and irrigation water. The ideal pH for its development is between 6 and 9 14.
Among the limiting biotic factors for chickpea production, there are diseases caused by different soil-borne microorganisms 15. Therefore, 115 pathogens affecting chickpea were reported, including fungi, virus bacteria, phytoplasms and nematodes 16. From these, only a few cause economic damage, which become limiting production in some areas 17. It is reported that most fungal diseases of the crop can be controlled with fungicides, but their use is sometimes not economical, hence appropriate phytotechnical measures and resistant cultivars are used as more profitable measures 18.
The crop of chickpea in cuba
Chickpea productions in Cuba until the 1990s were of little consideration, and although they have increased, they do not meet national demand, so it was necessary to make imports, mostly from Mexico, Canada and Spain 11,12.
In Cuba, the crop develops in the dry winter period. When temperatures are high and there is a water deficit, the period of vegetative growth is reduced, causing early maturity, with considerable damage to grain production and their size. Temperatures above 30 °C accelerate the fall of flowers, limit symbiotic fixation and accelerate senescence of the crop. The optimum temperatures for seed germination are between 20 and 30 °C, seedlings emerging between 5 and 8 days after sowing. Irrigation improves nodulation and increases yield and number of pods 14. The yield is favored by low rainfall during maturation, since high volumes of water during this period can cause losses of pods, since it favors the attack of fungal diseases, which affect the yield 19.
The sowing period runs from November 15 to December 30. In the case of short-cycle cultivars (100 days), in some locations with low rainfall or in years of late rains, it can last until January 15. The crop is demanding with the humidity in the stages of germination, pre-flowering, flowering and filling of the pods 11.
The wilt in the chickpea crop
The most important diseases in chickpea cultivation in Cuba and the world are those caused by soil fungi 20. Among these are: Fusarium spp., S. rolfsii, R. solani, M. phaseolina, the most important being Fusarium spp. for the damages it produces and the frequency with which it occurs 6. The disease appears mainly in clay soils or with drainage problems, a condition that favors the development of these pathologies 21.
In the world, this disease was named according to the symptomatology produced by the pathogen species; Yellowness and Vascular Wilt, caused by F. oxysporum f. sp. Ciceri22; Black root rot or dry rot, caused by Fusarium solani (Martius) 23. In the investigations carried out in Cuba, on the identification of these species, the name of ascending Wilt was given to the symptoms caused by F. oxysporum and descending Marchitez, to the symptomatology caused by F. solani12.
SYMPTOMATOLOGY
Infected plants have necrotic roots and brown spots on the neck. Inside the affected roots there are reddish brown colorations along the vascular system, an injury that extends from the root to the neck and to the area on the neck 21. The fungus obstructs the transfer of the sage through the vessels and destroys the roots 24.
The aerial symptoms correspond to a gradual development of chlorosis in the foliage, growth arrest and lack of vigor. Sick plants abort their flowers and the few grains that form are smaller. Plants affected early in their development end up dying and those that are attacked later tend to mature early. These symptoms appear randomly, forming irregular circles around those that were first affected or in entire areas when it comes to poorly drained soils.
Causal organism
Fusariosis in chickpea is caused by several species of Fusarium23. This fungus is located in the:
Fungi kingdom
Phylum: Ascomycota
Class: Sordariomycetes
Order: Hypocreales
Family: Nectriaceae;
Genus: Fusarium
Species: Fusarium spp.
Some researchers have reported in this crop the following Fusarium species: F. oxysporum, F. solani and F. redolens25.
In Cuba there is little information on the diseases that affect this crop, however, Fusarium species that affect chickpea have been characterized, in the productions obtained in the provinces of Havana City and Havana, identified as Fusarium oxysporum Schlechtend. Fr.f. sp. Ciceri (Padwik) Matuo & K. Sato and Fusarium solani (Martius) Appel & Wollenweber emend. Snyder & Hansen 26. Fusarium oxysporum f. sp. Ciceri is a fungus whose habitat is the soil, an obligate necrotroph, pathogenically specialized in species of the Cicer genus, which infects their vascular system and can be transmitted by infected seeds 27. However, F. oxysporum can asymptomatically invade roots of other plants, both leguminous and non-leguminous 22, where it survives, in the absence of its cultivated host. In addition, like the causative agents of other vascular fusariosis, it has the ability to survive inactively in the soil in the form of clamidospores for 6 years 27-30. The germination of these is stimulated by the exudates of the roots of numerous plants, including non-host species 31.
On the other hand, F. solani remains saprophytic in the soil, on the residues of infected plants. In this way, the fungus can develop in the rhizosphere of susceptible plants, before invading their roots. The dissemination of spores and mycelium occurs with the transfer of infected and / or entrained water 32.
Soil compaction favors the invasion process and the development of symptoms. The persistence of this pathogen in the soil is very long and can last several years, so once it has been established in the soil, it becomes necessary to adopt very long rotations of 5-6 years 23.
Development of the disease
These fungi are transmitted by conidia and clamidospores, through irrigation water or contaminated soil. These can live in crop residues or decomposing organic matter, forming part of the community of organisms in most of the soils dedicated to horticultural crops. Also, they can spread through contaminated seeds, settling in soil free of the pathogen. They colonize the roots taking advantage of some stress condition of the plant and/or the presence of wounds in roots. The pathogen when it enters the root, grows, multiplies and causes rot that covers the entire root.
Control measures for the causant pathogen of the chickpea´s wilt
Among the measures used for the control of Fusarium in chickpea are: agrotechnical measures (use of chickpea cultivars with a certain degree of resistance to disease, adjustment of planting dates, biofumigation, use of high planting beds, rotation of crops), chemical (fungicide seed treatments) and biological (use of biological control agents as isolates of the genus Trichoderma). The best control measures are preventive, since there is no curative control that is effective and economically profitable 33.
Trichoderma as a biological control agent
Trichoderma species are characterized as saprophytic fungi and are widely distributed in different types of soils, especially those that contain organic matter or decaying plant wastes. They cover a group of filamentous fungi, facultative anaerobes, of more than 100 species 34.
The taxonomic location of this fungus is 35:
Fungi kingdom
Division: Mycota
Subdivision: Eumycota
Class: Hyphomycetes
Order: Moniliales
Family: Moniliaceae
Genus: Trichoderma
Species: Trichoderma spp.
The genus Trichoderma in its vegetative state presents mycelium at the beginning of white, which turn dark green or yellowish, with dense sporulation 36. The mycelium is mostly thin, and seen under a microscope it is fine, the conidiophores are branched and look like a small tree. They are presented as compacted tufts that form rings with a system of irregular branches in a pyramidal manner. These end up in phialides where asexual or conidia spores are formed, of great importance for taxonomic identification at the species level and to ensure fungus generations during a large part of the vegetative period of plants 36. They are haploid and their wall is composed of chitin and glucans 37. In conidiophores, they can occur on phyloids that emerge directly from the mycelium. It produces unicellular clamidospores. These structures are of vital importance for the survival of the fungus in the soil under adverse conditions 37.
The relationship between the temperature and the development of Trichoderma, depends on the species and the isolation itself, although in general this varies between 25 and 30 ºC (38). However, at 30 °C, the antagonistic activity of this species is almost nil (38). All of which constitute evidence that the optimum temperature for growth does not necessarily coincide with that of its antagonistic activity, and that there is a close relationship between isolation, antagonism and temperature 39.
The most commonly used species as biological control agents until a few years ago were Trichoderma virens (Miller, Giddens & Foster) Arx, T. viride and fundamentally T. harzianum, which is an antagonist of phytopathogenic fungi and virus vector fungi 40,41. Currently several species of the genus, and among them T. asperellum42, are used in the management of diseases caused by phytopathogenic fungi in various crops of economic importance (rice, beans, tomatoes, among others), with positive results on some pathogens from the soil (R. solani and S. rolfsii), in farmhouses and in the countryside 43-45.
Trichoderma action mechanisms as a biological control agent
Trichoderma presents different mechanisms of action, with direct and indirect effects. Among the main ones are competition for space and nutrients, mycoparasitism and antibiosis, which have a direct action against the phytopathogenic fungus 39-46. In addition, others are reported, whose bioregulatory action is indirectly, such as the induction of physiological and biochemical defense mechanisms, related to the activation in the plant of compounds related to resistance (Resistance Induction) 37, toxin detoxification excreted by pathogens and the deactivation of these enzymes during the infection process; the solubilization of nutritional elements, which in their original form are not accessible to plants. They have the capacity, in addition to creating a favorable environment for radical development, which increases the plant's tolerance to stresses 37-39.
Direct action mechanism
Competition by space or by nutrients
Competition is defined as the unequal behavior of two or more organisms in the same requirement, which reduces the amount of nutrients and / or space available to others. Hence, an essential factor in competition is the limitation of an element 47.
The high versatility in the use of substrates by Trichoderma species, allows you to rapidly colonize the medium and prevent the proliferation of other microorganisms in the same habitat. It has a capacity to mobilize and take nutrients from the soil superior to that of other organisms, based fundamentally on the ability to obtain ATP from the metabolism of different sugars or numerous polymers, present at different concentrations in environments where fungi develop. One of the explanations in this regard is due to the presence of the high affinity glucose transporter (Gtt1) in T. harzianum (CECT 2413), which enables it to obtain energy from hydrolyzed polymers and the rapid transport of sugar to the interior of the cells, when glucose concentrations are very low 48.
Antibiosis
Antibiosis takes place through interactions that involve diffusible components of low molecular weight or antibiotics produced by Trichoderma isolates, which inhibit the growth of other microorganisms 39,49,50.
Most strains of this genus produce volatile and non-volatile toxic metabolites, very diverse in structure and function, which prevent the colonization of pathogenic microorganisms 51. Among these compounds are alkyl-pyrones (6-pentyl-(-pyrone), isonitriles (isonitrine), polyketides (harzyanolide), peptabioles (trichodermine, atroviridine, alameticine, suzucacillin and trichorzianine), diketopiperacins (gliovirin, and gliotoxin (sestoxin) heptelidic acid) and steroids (viridine), among others. The same strain can simultaneously produce several antibiotics, which reduces the risk of resistant microorganisms.
Micoparasitism
Mycoparasitism consists of a direct attack from one fungus to another, and leads to the modification or destruction of some of the host structures (mycelium, spores, sclerotia or others), with the consequent use of its components as a source of nutrients.
The mycoparasitic process is complex and may involve the chemotherapy growth of Trichoderma towards the host, stimulated by molecules from it, such as amino acids and sugars; lectin-mediated recognition; the formation of appressorium-like structures that contain high concentrations of osmotically active solutes, such as glycerol, and that facilitate penetration; the secretion of extracellular hydrolytic enzymes; and finally the penetration and death of the host 41,52,53. Structural changes can be seen at the cellular level such as vacuolization, granulation, cytoplasm disintegration and cell lysis 46,54,55.
Enzymes that degrade the cell walls of phytopathogenic fungi can often act synergistically in combination with some toxic compounds and/or secondary metabolites such as peptabioles, which facilitates the entry of the Trichoderma hypha into the lumen of the parasitized fungus and the assimilation of cell wall content 56. These enzymes are grouped into various families of chitinases, glucanases and proteases.
Mechanisms of indirect action
Indirect action is based, both on the ability of the biocontroller to stimulate the growth and development of plants, and on the induction of plant defense mechanisms that increase their resistance to a wide range of phytopathogenic microorganisms (37- 39).
Trichoderma promotes plant growth, manifested in the empowerment of seminal germination, radical growth and development, nutrient intake and use, resistance to abiotic stress, a more abundant and early flowering, increase in height and weight of plants, even an increase in yields 56,57. These processes are mediated by the synthesis or stimulation of the production of phytohormones by the plant due to the interaction with some strains of Trichoderma, such as cytokinin-like molecules (zeatin) and gibberellin GA3; as well as the acidification of the surrounding environment due to the excretion of organic acids: gluconic, citric and fumaric, which allow the solubilization of phosphates, micronutrients and mineral traces (iron, manganese and magnesium) 37.
Induction of local or systemic resistance by Trichoderma is effective for many crops. It has similarities with the hypersensitivity response (HR) and acquired systemic resistance (SAR).
Trichoderma species have been widely used in the control of soil pathogens, foliage and seeds. Among the controlled phytopathogens are: R. solani, Fusarium Schlecht. oxysporum f. sp. dianthi (Prill. & Del.) Snyder. & Hans, Sclerotinia sclerotiorum Lib., Colletotrichum gloeosporioides (Penz.) Sacc., S. rolfsii, Rosellinia bunodes (Berk. & Br.) Sacc., Phytophthora sp. Heinrich Anton de Bary, Phytophthora cinnamomi Rands, Phytophthora cactorum (Lebert et Cohn) Schröter, B. cinerea, Armillaria mellea (Vahl: Fr.) Kumm., Pythium sp. Pringsh, and parasitic Cryptonectria (Murr.) Barr., among others 36,55.
CONCLUSIONS AND PERSPECTIVES
Wilt or fusariosis of chickpea, is the most economically important disease in this crop, and is distributed worldwide. This is caused by different species of the genus Fusarium, so having a correct identification of the pathogen and the precise selection of biological control agents as alternatives for its control, and they are essential elements for the performance of a more efficient management, which can be combined with the remaining measures of disease management. Taking into account that in order to reduce the effects of Wilt, repeated and insufficient pesticide applications are recommended, having Trichoderma asperellum strains as an effective antagonistic microorganism, in addition to greatly reducing the effects of the disease, resource savings are achieved by concept of application of chemical products and in turn, the workforce of personnel dedicated to these tasks is reduced, which leads to a lower degree of toxicity in human health, improving the quality of life and therefore, allows us to adjust to the development of a more ecological and sustainable agriculture, considering that Trichoderma not only has the function of acting as an antifungal, but also, it is a stimulator of the growth and development of the crop and therefore the yields would be highly considerable.
BIBLIOGRAFÍA
1. Maessen LJG. Cicer arietinum L. a monograph of the genus, with special reference to the chickpea Cicer arietinum L.), its ecology and cultivation [Internet] [phd]. [Wageningen]: Veenman; 1972 [cited 28/04/2019]. 342 p. Available from: https://library.wur.nl/WebQuery/wurpubs/4217261. [ Links ]
2. Chenea G, Crispín A, Larrea E. El cultivo del Garbanzo. In: Revisión Bibliográfica del Cultivo del Garbanzo. México: Limusa; 1975. p. 469-99. [ Links ]
3. Marichal R. Curso de mejora genética de leguminosas grano. CIEAM-IAMZ; 1988. [ Links ]
4. INFOAGRO. Agricultura. El cultivo del garbanzo. [Internet]. 2005. [cited 04/07/2011]. Available from: https://www.infoagro.com/herbaceos/legumbres/garbanzo.htm4. [ Links ]
5. Valenzuela IP, Valenzuela RIV, Castro CMA, Pérez LMR, Sánchez EAS. Comportamiento agronómico de genotipos de garbanzo en siembra tardía en el Valle del Mayo, Sonora, México. Rev. Fitotecnia Mexicana. 2008;31(4):43-9. [ Links ]
6. Singh O, Rheenen HA van, Rupela OP. Inheritance of a New Nonnodulation Gene in Chickpea. Crop Science. 1992;32(1):41-3. doi:10.2135/cropsci1992.0011183X003200010009x [ Links ]
7. Simorte T, Alarcón R, Lacasta C. Perspectivas de nuevas variedades de garbanzo. In: Agricultura, Ecología y Desarrollo rural. 2003. [cited 28/04/2019]. Available from: http://wwwagroecología. net./congresos/pamplna/43pdf7. . [ Links ]
8. FAO. Seguimiento del Mercado de los cultivos de granos [Internet]. 2010. [cited 28/04/2019]. Available from: http://www.fao.org/search/es/?cx=018170620143701104933%3Aqq82jsfba7w&q=Seguimiento+del+Mercado+de+los+cultivos+de+granos%2C+2010&cof=FORID%3A9&siteurl=www.fao.org%2Fhome%2Fes%2F&ref=www.google.com%2F&ss=8. [ Links ]
9. Marginet C. El garbanzo y sus perspectivas. 2002. [cited 04/01/2004]. Available from: http://www. alimantaciónsana. com. ar9. . [ Links ]
10. Del Moral J. El garbanzo, un cultivo para el siglo XXI. 1998. [cited 16/01/2004] Available from: http://www. juntaex. es10. . [ Links ]
11. Shagarodsky T, Chiang ML, Cabrera M, Chaveco O, López MR, Dibut B, et al. Manual de instrucciones técnicas para el cultivo del garbanzo Cicer arietinum L) en las condiciones de Cuba. INIFAT-ETIAH, MINAG, Holguín. 2005:24. [ Links ]
12. Shagarodsky T, Morffi L, Chiang ML, Dueñas M, Vega M, López MR, et al. Producción de semilla de Garbanzo Cicer arietinum L.). Instituto de Investigaciones Fundamentales en Agricultura Tropical "Alejandro de Humboldt" (INIFAT). 2007. [ Links ]
13. Shagarodski T. Informe de una mutación en la colección cubana de garbanzo Cicer arietinum L.). Cultivos Tropicales. 2004;25(4):75-6. [ Links ]
14. InfoAgro. El cultivo del garbanzo [Internet]. 2002 [cited 28/04/2019]. Available from: https://infoagro.com/14. [ Links ]
15. Aguaysol NC, de Lisi V, Muñoz L, Gonzalez V, Fogliata G, Ploper LD. Marchitamiento de plantas en cultivos de garbanzo Cicer arietinum del norte argentino, causado por Fusarium oxysporum y Rhizoctonia sp. Avance Agroindustrial. 2013;34(4):25-7. [ Links ]
16. Nene Y, Sheila VK, Sharma SB. Important problems of Kabuli chickpea. In: Proceedings of the Consultative Meeting on Breeding for Diseases Resistance in Kabuli Chickpea. Syria: ICARDA, Aleppo; 1989. p. 1-23. [ Links ]
17. INIFAT. Propuesta de manejo para el cultivo del garbanzo en las condiciones de Sancti Spíritus. MINAGRI; 1999. [ Links ]
18. Singh KB, Reddy MV. Advances in disease-resistance breeding in chickpea. Advances in Agronomy. 1991;45:191-222. [ Links ]
19. INIFAT. Instrucciones técnicas para el cultivo del garbanzo Cicer arietinum L.) bajo las condiciones de Cuba. INIFAT; 1996. [ Links ]
20. García JL, González L, Shagarodsky T. Enfermedades del garbanzo, su importancia y posibles medidas de control. In: Resultados de las investigaciones para el desarrollo presente y futuro del garbanzo en Cuba. VIII FORUM de Ciencia y Técnica, INIFAT-MINAGRI, Cuba. 1993. p. 42-52. [ Links ]
21. Tay UJ. Manual para la producción de garbanzo, recomendaciones para la siembra en suelos arcillosos. Boletín INIA. 2006;(143):108. [ Links ]
22. Haware MP, Nene YL. Races of Fusarium oxysporum f.sp. ciceri. Plant Disease. 1982;66(9):809-10. [ Links ]
23. Martínez E, Barrios G, Rovesti L, Santos R. Manejo integrado de plagas. Manual práctico. Centro Nacional de Sanidad Vegetal, Cuba. 2007;526. [ Links ]
24. AGRI-NOVA. Productos para Agricultura [Internet]. 2010 [cited 06/11/2019]. Available from: http://www.agri-nova.com/24. [ Links ]
25. Trapero Casas A, Jiménez Díaz RM. Fungal wilt and root rot diseases of chickpea in southern Spain. Phytopathology. 1985;75:1146-51. [ Links ]
26. García JMD, Shagarodsky T, Fresneda JA, Fundora YH, González J. Caracterización de especies del género Fusarium en el cultivo del garbanzo Cicer arietinum en las provincias Ciudad Habana y la Habana. Temas de Ciencia y Tecnología. 2007;32(11):63-6. [ Links ]
27. Haware MP, Nene YL, Mathur SB. Seed-borne Diseases of chickpea. The Danish Goverment Institute of Seed Pathology for Developing Countries. Copenhague, Denmark. No (ICRISAT), 1986 [ Links ]
28. Fernandez DJ. Estudio de la interacción de Fusarium spp. con cultivares de garbanzo (Cicer arietinum L.) asociados a la Fusariosis Vascular mediante técnicas biotecnológicas [Internet] [Tesis en acceso abierto]. [España]: Universidad de Córdoba; 2011 [cited 28/04/2019]. Available from: https://dialnet.unirioja.es/servlet/tesis?codigo=5678328. [ Links ]
29. FAOSTAT. Food and Agriculture Organization of the United Nations Statistical Database [Internet]. 2009 [cited 28/04/2019]. Available from: http://www.fao.org/faostat/en/#home29. [ Links ]
30. Guerrero A. Garbanzos. In: Cultivos Herbáceos Extensivos. 6ª edición. Madrid: Mundi‐Prensa. 1999. [cited 28/04/2019]. 638 p. Available from: https://www.mundiprensa.com//catalogo/9788471147974/cultivos-herbaceos-extensivos [ Links ]
31. Akrami M, Khiavi HK, Shikhlinski H, Khoshvaghtei H. Bio controlling two pathogens ofchickpea Fusarium solaniand Fusarium oxysporumby different combinations of Trichoderma harzianum, Trichoderma asperellumand Trichoderma virensunder field condition. International Journal of Microbiology Research. 2013;1(2):52-5. [ Links ]
32. Merkuz A, Getachew A. Getachew A. Epidemic of Fusarium wilt Fusarium oxysporum f. sp. ciceri) of chickpea at wilt sick plot in Adet-Ethiopia. International Journal of Current Research. International Journal of Current Research. 2012;4(5):135-41. [ Links ]
33. Druzhinina I, Kubicek CP. Species concepts and biodiversity in Trichoderma and Hypocrea: from aggregate species to species clusters? Journal of Zhejiang University. Science. B. 2005;6(2):100-12. doi:10.1631/jzus.2005.B0100 [ Links ]
34. Arenas V. Trichoderma pers. Características generales y su potencial biológico en la agricultura sostenible. 2005; [ Links ]
35. Rifai MA. A revision of the genus Trichoderma. Mycological Papers. [Internet]. 1969 [cited 28/04/2019]. Available from: http://www.mycobank.org/BioloMICS.aspx?Link=T&TableKey=14682616000000061&Rec=2936&Fields=All35. [ Links ]
36. Harman GE, Howell CR, Viterbo A, Chet I, Lorito M. Trichoderma species - opportunistic, avirulent plant symbionts. Nature Reviews Microbiology. 2004;2(1):43-56. doi:10.1038/nrmicro797 [ Links ]
37. Rodríguez I, Arcia A. Efecto de doce aislamientos de Trichoderma spp., sobre el número, tiempo de formación y porcentaje de parasitismo de esclerocios de Sclerotium rolfsii, en cuatro temperaturas diferentes. Resumen). Fitopatol Venezol. 1993;6(2):54. [ Links ]
38. Martínez B, Infante D, Reyes Y. Trichoderma spp. y su función en el control de plagas en los cultivos. Revista de Protección Vegetal. 2013;28(1):1-11. [ Links ]
39. Benítez T, Rincón AM, Limón MC, Codón AC. Control mechanisms of Trichoderma strains. International microbiology. 2004;7(4):249-60. [ Links ]
40. Samuels GJ, Lieckfeldt E, Nirenberg HI. Trichoderma asperellum, a new species with warted conidia, and redescription of T. viride. Sydowia. 1999;51(1):71-88. [ Links ]
41. Hoyos-Carvajal L, Orduz S, Bissett J. Genetic and metabolic biodiversity of Trichoderma from Colombia and adjacent neotropic regions. Fungal Genetics and Biology. 2009;46(9):615-31. [ Links ]
42. Martínez B, Reyes Y, Infante D, González E, Baños H, Cruz A. Selección de aislamientos de Trichoderma spp. candidatos a biofungicidas para el control de Rhizoctonia sp. en arroz. Revista de Protección Vegetal. 2008;23(2):118-25. [ Links ]
43. Reyes Y, Martínez B, Infante D. Evaluación de la actividad antagónica de trece aislamientos de Trichoderma spp. sobre Rhizoctonia sp. Revista de Protección Vegetal. 2008;23(2):112-7. [ Links ]
44. Harman GE. Myths and dogmas of biocontrol changes in perceptions derived from research on Trichoderma harzinum T-22. Plant disease. 2000;84(4):377-93. [ Links ]
45. Delgado-Jarana J, Moreno-Mateos MA, Benítez T. Glucose uptake in Trichoderma harzianum: role of gtt1. Eukaryotic cell. 2003;2(4):708-17. [ Links ]
46. Kubicek CP, Bissett J, Druzhinina I, Kullnig-Gradinger C, Szakacs G. Genetic and metabolic diversity of Trichoderma: a case study on South-East Asian isolates. Fungal genetics and biology. 2003;38(3):310-9. [ Links ]
47. Chet I, Inbar J. Biological control of fungal pathogens. Applied Biochemistry and Biotechnology. 1994;48(1):37-43. doi:10.1007/BF02825358 [ Links ]
48. Tronsmo HL, Hjeljord A. Trichoderma and Gliocladium in biological control, and overview. Trichoderma and Gliocladium. 1998;2:131-45. [ Links ]
49. Sid Ahmed A, Ezziyyani M, Pérez Sánchez C, Candela ME. Effect of chitin on biological control activity of Bacillus spp. and Trichoderma harzianum against root rot disease in pepper Capsicum annuum plants. European Journal of Plant Pathology. 2003;109(6):418/26. doi:10.1023/A:1024734216814 [ Links ]
50. Vey A, Hoagland RE, Butt TM. Toxic Metabolites of Fungal Biocontrol Agents. In: Butt TM, Jackson C, Magan N (ed). Fungi as biocontrol agents: Progress, problems and potential. CAB International, 2001: 311-46. [ Links ]
51. Viterbo A, Montero M, Ramot O, Friesem D, Monte E, Llobell A, et al. Expression regulation of the endochitinase chit36 from Trichoderma asperellum (T. harzianum T-203). Current genetics. 2002;42(2):114-22. [ Links ]
52. Ezziyyani M, Sánchez CP, Ahmed AS, Requena ME, Castillo MEC. Trichoderma harzianum como biofungicida para el biocontrol de Phytophthora capsici en plantas de pimiento Capsicum annuum L.). In: Anales de biología. Servicio de Publicaciones de la Universidad de Murcia; 2004. p. 35-45. [ Links ]
53. Woo SL, Scala F, Ruocco M, Lorito M. The molecular biology of the interactions between Trichoderma spp., phytopathogenic fungi, and plants. Phytopathology. 2006;96(2):181-5. [ Links ]
54. Wiest A, Grzegorski D, Xu B-W, Goulard C, Rebuffat S, Ebbole DJ, et al. Identification of peptaibols from Trichoderma virens and cloning of a peptaibol synthetase. Journal of Biological Chemistry. 2002;277(23):20862-8. [ Links ]
55. Kim D-J, Baek J-M, Uribe P, Kenerley CM, Cook DR. Cloning and characterization of multiple glycosyl hydrolase genes from Trichoderma virens. Current genetics. 2002;40(6):374-84. [ Links ]
56. Benitez T. Biofungicides?: Trichoderma as a biocontrol agent against phytopathogenic fungi. Recent Research Developments in Microbiology. 1998;2:129-50. [ Links ]
57. Stacey G, Keen NT, editors. Plant-Microbe Interactions. Biologic Plantarum. 2000;43(4):610. doi:10.1007/978-1-4613-1213-0 [ Links ]
Received: July 18, 2018; Accepted: May 07, 2019
