Abstracts

AGRICULTURE, AGRIBUSINESS AND BIOTECHNOLOGY

Genetic control on morphoagzronomic traits in snap bean

Marlon Peres da Silva; Antônio Teixeira do Amaral Júnior^* * Author for correspondence ; Rosana Rodrigues; Messias Gonzaga Pereira; Alexandre Pio Viana

Laboratório de Melhoramento Genético Vegetal; Centro de Ciências e Tecnologias Agropecuárias; Universidade Estadual do Norte Fluminense Darcy Ribeiro; Av. Alberto Lamego, 2000; Parque Califórnia; 28013-600; amaraljr@uenf.br; Campos dos Goytacazes - RJ - Brazil

ABSTRACT

Five divergent snap bean accessions from the vegetables germplasm bank at UENF and their ten diallel hybrids were evaluated to inheritance on five morphoagronomic traits using Hayman's methodology (1954). The results showed that additive effects were predominant for pod weight per plant, number of seeds per pod, height of the insertion of the first pod and number of days to flowering while non-additive effects were more important for number of pods per plant. The best strategy to be adopted was the use of these acessions in an intrapopulation breeding program aiming the obtaintion of superior segregants. For pod numbers the indicated strategy would be an interpopulational breeding procedure, to exploite the heterosis related to the non-additive effects. The analysis also revealed that dominant alleles increased the number of pods per plant, pod weight per plant and number of seeds per pod. Allelic interaction was overdominance to the number of pods per plant, while the partial dominance controled the expression of other traits.

Key words: Snap bean, Phaseolus vulgaris, diallel analysis, inheritance

RESUMO

Cinco acessos divergentes de feijão-de-vagem do banco de germoplasma da UENF, Rio de Janeiro, Brasil, e seus dez híbridos dialélicos possíveis, foram avaliados quanto à herança para cinco características morfoagronômicas, utilizando a metodologia de Hayman (1954). Os resultados evidenciaram que os efeitos gênicos aditivos foram predominantes para peso de vagem por planta, número de sementes por vagem, altura da inserção da primeira vagem e número de dias para florescimento, enquanto os efeitos gênicos não aditivos foram mais importantes na expressão de número de vagens por planta. Isso demonstra que, para as quatro primeiras características, a melhor estratégia a ser adotada é o uso dos acessos em programa de melhoramento intrapopulacional, visando a obtenção de segregantes superiores. Para número de vagens, a estratégia de melhoramento interpopulacional seria mais indicada, por explorar a heterose. Os resultados revelaram ainda que os alelos dominantes são responsáveis por aumentos no número de vagens por planta, no peso de vagem por planta e no número de sementes por vagem. A interação alélica de sobredominância destacou-se para número de vagens por planta, enquanto para as demais características houve a prevalência de dominância parcial.

INTRODUCTION

Planning and execution of a breeding program require information on the genetic systems controlling the characters of the interest, so that the expected gains can be maximized with use of the selection process (Vencovsky and Barriga, 1992; Barelli et al., 1999; Viana et al., 1999). In snap bean, studies about inheritance of important morphoagronomic traits for plant breeders are scarce. Besides, there are controversial results considering the same traits. Rodrigues et al. (1998), as an example, found that dominance effects were more important for plant height while additive effects were superiors for pod length. Leal et al. (1979), studying a partial diallel in snap bean, in order to investigate genetic effects over yield traits, comparing performance on F₅ and F₆ with F₁ and F₂, concluded that additivity and epistasis were predominant for pod lenght, yield per plant, number of pods per plant, individual pod weight, number of pods per plant, and incidence of interlocular cavitation. Carvalho et al. (1999), studying, tested four snap bean cultivars (Alessa, Andra, Cota and Cascade) as parents in a diallel design without reciprocals, and verified significance for all traits considering specific combining ability, indicating that epistatic and, or dominance effects were involved in genetic control for number of pods, pod diameter, pod length and number of days to flowering.

Considering different crops, the diallel analysis has been emphasized in many breeding programs because of the large amount of information this approach can offer to the breeder (Foolad and Bassiri, 1983; Amaral Júnior et al., 1996; Barelli et al., 1999; Cruz and Regazzi, 2001). According to Cruz and Regazzi (2001), Hayman's procedure (1954), among methodologies of diallel analysis available, has greatly contributed to breeding. It provides an efficient study of the genetic action involved in the control of traits and identifies the presence of epistatic interactions. It also estimates the genetic component of genotype determination and the limit of selection which may be obtained from assessed parents. The present study was carried out using a diallel cross system based on Hayman's methodology (1954) among five divergent snap bean accessions to obtain genetic information for morphoagronomic traits to start a breeding program.

MATERIALS AND METHODS

Parents and hybrids: The snap bean accessions UENF 1429, UENF 1432, UENF 1442, UENF 1445 and UENF 1448, from the vegetable germoplasm bank at UENF (Darcy Ribeiro North Fluminense State University), Rio de Janeiro, Brazil, were chosen because of their divergent morphological and agronomic traits identified by Abreu (2001) and used as parents in a complete diallel without reciprocals. Crosses were made using the method proposed by Vieira (1967), which consisted of mechanical emasculation of the female parent using tweezers on flower buds one day before flowering followed by crosses pollination. Ripe pollen from open flowers of the male parents was used to perform the crosses. The hybrids were confirmed by flower color and RAPD markers.

The following traits were evaluated: a) mean number of pods per plant (MNP), obtained from the ratio between the total number of pods and the total number of plants, in each treatment; b) mean pod weight per plant (MPW), expressed in grams, obtained from the ratio between the total weight of pods and the total number of plants, in each treatment; c) mean number of seeds per pod (MNS), obtained from the average number of seeds in a sample of ten pods per plant, in each treatment; d) mean height of the insertion of the first pod (HFP), expressed in cm, as the ratio between the measurement from the soil to the insertion of the first pod and the respective number of plants in each treatment; and e) number of days to flowering (NDF), obtained by counting the number of days, from sowing to the complete opening of the first flower.

Treatments and experimental design: The populations of five parents and 10 F₁, totalizing 15 treatments were assessed in the greenhouse at the UENF, Campos dos Goytacazes, Rio de Janeiro, in 2002. The experimental design was a randomized complete block with fifteen replications. Two seeds were sown in 5 dm³ pot containing substrate. They were thinned fifteen days after emergence, and one plant was left in each pot. Each pot with one plant made up an experimental unit.

An analysis of variance considering randomized complete block design for the data of each characteristic was carried out, using GENES program (Cruz, 2001). The value of each observation provided by the following statistical model, considering accession as fixed effect was used:

Y_ijk = m + A_i + B_j + x_ijk,

where Y_ijk observation of i^th treatment in the j^th block (i = 1, 2, , a = 15; j = 1, 2, , b = 15); m = general mean; A_i = effect of the i^th access; B_j = effect of the j^th block and x_ijk = experimental error.

Hayman's diallel analysis (1954): The Hayman's diallel analysis (1954) was carried out based on Cruz and Regazzi (2001), considering that homozygous parents were different in only one locus (T/t), and present desirable alleles in an u₁ratio and undesirable alleles in a v₁ ratio. The GENES program (Cruz, 2001) was used for this analysis.

RESULTS AND DISCUSSION

Sufficiency test of the additive-dominant model: Assuming that the genetic effects are the results of the additive and dominant action of genes, Hayman (1954) imposed a series of restrictions which required the application of tests to verify the sufficiency of the model. Table 1 shows the results of the applications of two tests for the traits assessed. The totality of the traits was no significant in test F, hence the assumptions imposed were valid and indicated that the additive-dominant model was adequate to the genetic study of these traits.

Mean number of pods per plant (MNP): Table 2 shows the correlation between the genotypic values of the i^th parents (_ii) and the sum of the covariance and variance among means of the i^th lines (_i + _i) and the expected values of the coordinates _R, _R and _D, _D and their sums. There was a negative correlation between _ii and (_i + _i), of magnitude equal to -0.8322, showing that the alleles which acted to increase the number of pods per plant were predominantly dominant. In this case, parents UENF 1448, UENF 1429 and UENF 1432, which were closer to the dominant end of the regression of _i over _i (Fig. 1) would be suitable for selection of earlier lines.

Mean pod weight per plant (MPW): The high negative correlation value (-0.9493) between

Fig. 2 shows that accession UENF 1448 had the greatest concentration of dominant genes. Considering that the maximum value for the parental _D + _D sum was -2.5965 (Table 2), it was possible to obtain desirable pure lines, with higher weight of pods, since parent UENF 1448 showed a value for _i + _i = 2.4278 (Table 3). This was ratified by the predominance of the additive effects over the dominance ( - ₁ = 11.3028), and also by the high value of the genotypic determination coefficient ( = 0.8881) expressed for this trait (Table 4).

Table 4 shows the presence of the partial dominance for the allelic relation because of the value 0.5567 for the mean degree of dominance. Hence, it would be more difficult selecting superior individuals since heterozygous would be almost so valuable than recessive homozygous. Based on value 1.1499, revealed by _D/ _R, there was allelic symmetry between dominant and recessive alleles, which could be observed in Fig. 2.

Mean number of seeds per pod (MNS): Similarly to the mean number of pods per plant and mean pod weight per plant, the dominant alleles contributed mainly to an increase in the number of seeds per pod, as indicated by the correlation value for

Mean height of the insertion of the first pod (HFP): There was a positive correlation between

The parent with higher concentration of dominant alleles was UENF 1448 (Table 3 and Fig. 4), presenting a value of 30.9895 (Table 3). Nevertheless, it was still possible to obtain materials with major concentration of dominant alleles, considering that the value of limit of selection was 9.9822 (Table 2) according to expression _i + _i (Table 3). The opportunity to obtaining these materials became more evident because of the predominance of additive effects of genes (- ₁= 68.2692, Table 4) and the high heritability value ( = 0.7713, Table 4), which ensured the success of the transmission of the desirable alleles to future generations.

Number of days to flowering (NDF): The major aim of a snap bean breeding program is to reduce the number of days to flowering and to obtain earlier cultivars and larger number of harvest per year, increasing farmers gain. In this case, the plant breeder is interested in alleles which reduces the magnitude of this character. Although the positive correlation between

Received: May 16, 2003;

Revised: October 21, 2003;

Accepted: May 17, 2004.

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