Verdín: black bean variety tolerant to drought terminal for Veracruz and Chiapas, Mexico

Tosquy Valle, Oscar Hugo; López Salinas, Ernesto; Villar Sánchez, Bernardo; Acosta Gallegos, Jorge Alberto; Rodríguez-Rodríguez, José Raúl; Tosquy Valle, Oscar Hugo; López Salinas, Ernesto; Villar Sánchez, Bernardo; Acosta Gallegos, Jorge Alberto; Rodríguez-Rodríguez, José Raúl

Serviços Personalizados

Journal

Artigo

Indicadores

Citado por SciELO
Acessos

Links relacionados

Similares em SciELO

Mais
Mais

Permalink

Revista mexicana de ciencias agrícolas

versão impressa ISSN 2007-0934

Rev. Mex. Cienc. Agríc vol.7 no.7 Texcoco Set./Nov. 2016

Description of cultivars

Verdín: black bean variety tolerant to drought terminal for Veracruz and Chiapas, Mexico

Oscar Hugo Tosquy Valle¹^§

Ernesto López Salinas¹

Bernardo Villar Sánchez²

Jorge Alberto Acosta Gallegos³

José Raúl Rodríguez-Rodríguez⁴

^¹Campo Experimental Cotaxtla. INIFAP. Carretera km 34. Veracruz-Córdoba, municipio, Medellín de Bravo, Ver. Apdo. Postal 429, C. P. 91700, Veracruz, Veracruz, México. Tel. 018000882222 ext. 87232 y 87209. (lopez.ernesto@inifap.gob.mx).

^²Campo Experimental Centro de Chiapas. INIFAP. Carretera km 3.0. Ocozocoautla-Cintalapa. C. P. 29140, Ocozocoautla, Chis. Tel. 018000882222 ext. 86303. (villar.bernardo@inifap.gob.mx).

^³Campo Experimental Bajío. INIFAP. Carretera km 6.5. Celaya-San Miguel de Allende. C. P. 38000, Celaya, Guanajuato. Tel. 018000882222 ext. 85227. (acosta.jorge@inifap.gob.mx).

^⁴Campo Experimental Ixtacuaco. INIFAP. Carretera km 4.5. Martínez de la Torre-Tlapacoyan, Apdo. Postal 162, Martínez de la Torre, Ver. Tel. 018000882222 ext. 87606. (rodriguez.jose@inifap.gob.mx).

Abstract

In Veracruz and Chiapas, the terminal drought is the most limiting factor abiotic bean production in the system of residual moisture. In 2014, the SEN-70 line was released by the INIFAP as a new variety with the name of Verdín. This variety is tolerant to drought early cycle terminal and adapted to tropical areas of southeastern Mexico. From 2011 to 2013, Verdín was evaluated along with the varieties Black Papaloapan and Black Comapa in 11 environments ofVeracruz and Chiapas, and temporary residual moisture. The average yield ofthe new variety was 1 446 kg ha^-1, up 12.8 and 10.2%, that obtained by these varieties. In winter-spring 2013, Verdín was evaluated under irrigation-drought and was selected for its terminal drought tolerance and good grain yield. During 2013 and 2014 with residual moisture, Verdín was evaluated in uniform yield trials in six environments Veracruz and Chiapas (four with drought and two non-drought); the new variety was the most productive; with drought earned an average yield of1 122 kg ha^-1, up 49.9 and 41.8% as of the varieties Black Tacanal and Black Jamapa, without moisture stress, yielded 1 844 kg ha^-1, up 23.4 and 61.5% to those obtained by the same varieties. Verdín can be grown under conditions of residual and temporary humidity in Veracruz and Chiapas.

Keywords: Phaseolus vulgaris L.; genetic resistance performance; water stress

Resumen

En Veracruz y Chiapas, la sequía terminal es el factor abiótico que más limita la producción de frijol en el sistema de humedad residual. En 2014, la línea SEN-70 fue liberada por el INIFAP como nueva variedad con el nombre de Verdín. Esta variedad es de ciclo precoz, tolerante a la sequía terminal y se adapta a las áreas tropicales del sureste de México. De 2011 a 2013, Verdín se evaluó junto con las variedades Negro Papaloapan y Negro Comapa en 11 ambientes de Veracruz y Chiapas, con humedad residual y temporal. El rendimiento promedio de la nueva variedad fue de 1 446 kg ha^-1, superior en 12.8 y 10.2%, al obtenido por estas variedades. En invierno-primavera de 2013, Verdín se evaluó bajo condiciones de riego-sequía y fue seleccionada por su tolerancia a la sequía terminal y buen rendimiento de grano. Durante 2013 y 2014 con humedad residual, Verdín se evaluó en ensayos uniformes de rendimiento en seis ambientes de Veracruz y Chiapas (cuatro con sequía y dos sin sequía); la nueva variedad fue la más productiva; con sequía obtuvo un rendimiento promedio de 1 122 kg ha^-1, superior en 49.9 y 41.8% al de las variedades Negro Tacaná y Negro Jamapa, y sin estrés de humedad, rindió 1 844 kg ha^-1, superior en 23.4 y 61.5% a los obtenidos por estas mismas variedades. Verdín puede sembrarse bajo condiciones de humedad residual y temporal, en Veracruz y Chiapas.

Palabras clave: Phaseolus vulgaris L.; estrés hídrico; rendimiento; resistencia genética

In Veracruz and Chiapas, almost all bean plantings are made with materials of black beans, because they have the greatest commercial demand in southeastern Mexico. In both entities, plantings residual moisture cycles autumn-winter and winter-spring, it is common the occurrence of terminal drought, which occurs after flowering crop when bean plants are more sensitive to lack of moisture (^{Acosta et al, 2004}; ^{Muñoz-Perea et al., 2006}; ^{López et al., 2011}) and depended on its duration and magnitude, can cause losses of 20 to 100% in grain yield (^{De Allende et al, 2006}; ^{López et al., 2008}).

Breeding for drought resistance is one of the best ways to increase the productivity of bean production under these conditions (^{Frahm et al., 2003}). In the Bean Program Experimental Cotaxtla the National Institute of Forestry, Agriculture and Livestock (INIFAP), from 2007, they have conducted studies on drought in black bean plantings for residual moisture. Of these, some advanced lines and varieties showed good adaptation to conditions of moisture deficiency (^{López et al., 2008}; (²⁰¹¹) were identified which was necessary to continue evaluating them to determine more accurately their productive behavior under stress humidity. So was generated the Verdín variety, which is tolerant to drought terminal, and has high yield potential and wide adaptation in different areas where bean occurs in the states of Veracruz and Chiapas.

This variety originated from triple crosses (SXB 114 x DOR 605) x SXB 123 and obtained by gametic selection (individual plant) in F₁ and mass selection in F₂ under drought stress at the International Center for Tropical Agriculture (CIAT) in Cali , Colombia; individual selection in F₃ anthracnose in Popayan, Colombia; mass selection in F₄ by angular leaf spot in Quilichao, Colombia; F₅ masal compound under drought stress; individual selection in F₆, masal in F₇ and masal compound F₈ in Cali, Colombia the SXB 114 and SXB 123 lines were used as sources of resistance to drought and DOR 605 as a source of resistance to bean golden yellow mosaic virus (BGYMV).

The SEN-70 line which was derived Verdin was introduced to Mexico in 2009, through a nursery of advanced lines CIAT Bean Program. From 2011 to 2013 we were evaluated in an elite trial in 11 environments of Veracruz and Chiapas, for high performance, wide adaptation and disease tolerance and 2013-2014 in performance testing for tolerance to terminal drought conditions residual moisture.

The plants of Verdín variety are indeterminate growth habit, erect shrub and type II (^{Singh, 1982}), with medium guides and canopy height of about 59 centimeters. Its flowers are purple, yellow pods at physiological maturity and grain is black, opaque and small. One of the most outstanding characteristics of this variety is its earliness, as in tropical and subtropical areas, flowering occurs between 34 and 37 days and reaches physiological maturity between 67 and 70 days after planting, which allows you lower risk of yield loss due to the occurrence of drought periods terminal, which commonly occur in crops of residual moisture. Another quality that stands out in this variety is its tolerance to anthracnose disease virus and bean golden yellow mosaic, which affect the bean field areas of the states of Veracruz and Chiapas.

From 2011 to 2013, Verdin was compared with the varieties Black Papaloapan and Black Comapa latest release by the Bean Program INIFAP in Veracruz, (^{Lopez et al., 2007}; ²⁰¹⁰), through an essay elite performance, which it was established in 11 environments Veracruz and Chiapas, during cycles autumn-winter and winter-spring conditions and residual moisture in the summer cycle under temporary. The new variety exceeded by 5.5 and 10.4% yield varieties Black Papaloapan and Black Comapa, respectively, residual moisture conditions and at 46.4 and 9.6% temporary low. The overall average yield of the new variety was higher by 12.8 and 10.2%, the varieties obtained by Black Papaloapan and Black Comapa (Table 1).

Table 1 Grain yield (kg ha^-1) comparative bean variety Verdín in nine environments in Veracruz and two in Chiapas.

OI= otoño-invierno; IP= primavera- verano; V= verano; HR= humedad residual.

In the winter-spring cycle of 2013, in the town of Cotaxtla, in central Veracruz, Verdin was evaluated along with other 22 lines and commercial varieties Black INIFAP, Black Tacaná and Black Jamapa (regional control), using the methodology irrigation-drought, in order to classify them for their tolerance to drought, as well as its efficiency in performance in both moisture conditions (^{Fisher and Maurer, 1978}; ^{Graham, 1984}). The new variety was selected, along with 10 other lines, for their tolerance to terminal drought (ISS= 0.8) and high efficiency in performance in both moisture conditions (IER= 1.45) (^{Tosquy et al., 2014}). Under drought conditions, the performance of Verdin was 47.8, 19.1 and 63.7% higher than those obtained by the varieties INIFAP Black, Black Tacaná and Black Jamapa respectively.

During cycles 2013-2014 autumn-winter and winter-spring 2014, Verdín was also evaluated in a uniform test performance conformed with the 10 selected trials irrigation-drought and regional witnesses lines Black Tacaná and Black Jamapa, which were conducted under conditions of residual moisture in four locations in Veracruz and two in Chiapas. According to the results of soil moisture balance (^{Hillel, 1980}), in four of six environments, there was occurrence of drought during the growing season; Verdin was the most productive in both drought conditions, as moisture stress. The overall average yield of Verdín was 34.6 and 41% higher than the average obtained by the varieties Black Tacaná and Black Jamap, respectively (Table 2).

Table 2 Grain yield (kg ha^-1) and two regional witnesses Verdín evaluated in four environments with drought and two moisture stress in Veracruz and Chiapas.

OI= otoño-invierno; IP= invierno-primavera.

The results show the greatest potential performance and better adaptation to the conditions of moisture stress, which has the variety Verdín, with respect to the varieties commonly used by farmers in Veracruz and Chiapas.

The Verdín variety has adaptability in tropical and subtropical areas of both entities, as well as similar regions of southeastern Mexico. It can be grown under conditions of residual and temporary humidity in areas with rainfall greater than or equal to 300 mm, well distributed during the crop cycle, with altitudes of 0 to 1 200 m in soils of different textures, preferably well drained with pH of 5.5 to 7.

In Cotaxtla Experimental INIFAP, there is the original seed Verdin, to produce registered seed, if seed producer associations or companies wishing to acquire, to produce certified seed. The number of recorded final of this cultivar in the National Catalogue of Plant Varieties established by the SNICS is: FRI-091-050315.

Conclusions

Verdín productive variety, with drought earned an average yield of1122 kg ha^-1, up 49.9 and 41.8% as of the varieties Negro Tacaná and Negro Jamapa, without moisture stress, yielded 1 844 kg ha^-1, top 61.5% 23.4 and those obtained by the same varieties. Verdín can be grown under conditions of residual and temporary humidity in Veracruz and Chiapas.

Literatura citada

Acosta, D. E.; Trejo, L. C.; Ruíz, P. L. del M.; Padilla, R. J. S. y Acosta, G. J. A. 2004. Adaptación del frijol a sequía en la etapa reproductiva. Terra Latinoam. 22(1):49-58. [ Links ]

De Allende, A. G.; Rivera, de L. M. M.; Rosales, S. R.; Acero, G. M. G. y Mayek, P. N. 2006. Calidad bioquímica del frijol cultivado en distintas condiciones de humedad del suelo. Inv. y Ciencia. 14:12-18. [ Links ]

Fisher, R. A. and Maurer, R. 1978. Drought resistance in spring wheat cultivars. I. Grainyield responses. Aust. J.Agric. Res. 29:897-912. [ Links ]

Frahm, M.; Rosas, J. C.; Mayek, N.; López, E.; Acosta, J. A. y Kelly, J. D. 2003. Resistencia a sequía terminal en frijol negro tropical. Agron. Mesoam. 14(2):143-150. [ Links ]

Graham, R. D. 1984. Breeding for nutritional characteristics in cereals. Adv. Plant Nutr. 1:57-102. [ Links ]

Hillel, D. 1980. Applications of soil physics. 1rd. ed. Academic Press. New York, USA. 385 p. [ Links ]

López, S. E.; Tosquy, V. O. H.; Acosta, G. J. A.; Villar, S. B. and Ugalde, A. F. J. 2011. Drought resistance of tropical dry black bean lines and cultivars. Tropical and Subtropical Agroecosystems 14(2):749-755. [ Links ]

López, S. E.; Tosquy, V. O. H.; Ugalde, A. F. J. y Acosta, G. J. A. 2008. Rendimiento y tolerancia a sequía de genotipos de frijol negro en el estado de Veracruz. Rev. Fitotec. Mex. 31(3):35-39. [ Links ]

López, S. E.; Tosquy, V. O. H.; Villar, S. B.; Cumpián, G. J.; Ugalde, A. F. J. y Becerra, L. E. N. 2007. Negro Papaloapan, nuevo cultivar de frijol para las áreas tropicales de México. Agric. Téc. Méx. 33(3):257-267. [ Links ]

López, S. E.; Tosquy, V. O. H.; Villar, S. B.; Rodríguez, R. J. R.; Ugalde, A. F. J.; Morales, R. A. y Acosta, G. J.A. 2010. Negro Comapa, nueva variedad de frijol para el estado de Veracruz. Rev. Mex. Cienc. Agríc. 1(5):715-721. [ Links ]

Muñoz-Perea, G.; Terán, H.; Allen, R.; Wright, J.; Westermann, D. and Singh, S. P. 2006. Selection for drought resistance in dry bean landraces and cultivars. Crop Sci. 46:2111-2120. [ Links ]

Singh, S. P. 1982. A key for identification of different growth habits of Phaseolus vulgaris L. Ann. Rep. Bean Improv. Coop. 25:92-95. [ Links ]

Tosquy, V. O. H.; López, S. E.; Francisco, N. N.; Acosta, G. J. A. y Villar, S. B. 2014. Genotipos de frijol negro opaco resistentes a sequía terminal. Rev. Mex. Cienc. Agríc. 5(7):1205-1217. [ Links ]

Received: June 2016; Accepted: August 2016

Este es un artículo publicado en acceso abierto bajo una licencia Creative Commons