Rooting performance from leaf petioles of accessions and hybrids of wild Arachis species

Fávero, Alessandra Pereira; Nass, Luciano Lourenço; Cargnin, Adeliano; Leonardecz Neto, Eduardo

doi:10.1590/S0103-90162005000100012

Abstracts

The genus Arachis has 69 species, the majority native to Brazil. Arachis spp. seedling root tips have been used to obtain dividing cells for cytological preparations. Several wild species produce small amounts of seeds and consequently few root meristems, making the cytogenetic characterization very difficult. The purpose of this study was to evaluate the rooting capacity of several wild species of Arachis using the detached leaves technique for obtaining roots from petioles. One hundred and thirty accessions and 27 interspecific hybrids were studied. Three evaluations were performed at 15, 31, and 49 days after planting. Leaf rooting observed in the wild species confirmed the great genetic variability typical of the Arachis genus, indicating that the number of days interferes with the rooting percentage. The Arachis Section presented the highest rate of rooting leaves. The Caulorrhizae Section showed the same pattern observed in the Erectoides Section. Accessions from Heteranthae, Trierectoides, Extranervosae, and Rhizomatosae Sections did not differ among each other. Differences were not observed in Erectoides Section when compared to Rhizomatosae and Extranervosae Sections. The number and morphology of roots obtained through this technique were promising to be used on cytological preparations.

cytology; germplasm

O gênero Arachis possui 69 espécies, sendo a maioria nativa do Brasil. Ápices radiculares de plântulas têm sido usados para a obtenção de células em divisão. Diversas espécies silvestres produzem pouca quantidade de sementes, o que dificulta a obtenção de meristemas para preparações citológicas. O objetivo deste trabalho foi avaliar a capacidade de enraizamento de diversas espécies silvestres de Arachis, usando a técnica de folhas destacadas para a obtenção de raízes a partir de pecíolos. Foram avaliados 130 acessos e 27 híbridos interespecíficos aos 15, 31 e 49 dias após o plantio. A formação de raízes a partir de folhas observada em espécies silvestres confirmou a ampla variabilidade genética típica do gênero Arachis, indicando que o número de dias também interfere na porcentagem de enraizamento. A Secção Arachis apresentou a maior taxa de enraizamento de folhas e a Secção Caulorrhizae apresentou o mesmo padrão da Secção Erectoides. Acessos pertencentes às Secções Heteranthae, Trierectoides, Extranervosae e Rhizomatosae não diferiram com relação à porcentagem de enraizamento. A Secção Erectoides apresentou comportamento similar ao das Secções Rhizomatosae e Extranervosae. A quantidade e morfologia de raízes obtidas por meio dessa técnica mostraram-se promissoras para uso em preparações citológicas.

citologia; germoplasma

NOTE

Rooting performance from leaf petioles of accessions and hybrids of wild Arachis species

Enraizamento de pecíolos de folhas de espécies silvestres e híbridos de Arachis

Alessandra Pereira Fávero^I,^* * Corresponding author < favero@cenargen.embrapa.br> ; Luciano Lourenço Nass^I; Adeliano Cargnin^II; Eduardo Leonardecz Neto^III

^IEmbrapa Recursos Genéticos e Biotecnologia, C.P. 02372 - 70770-900 - Brasília, DF - Brasil

^IIUFV - Depto. de Fitotecnia, Av. P.H. Rolfs s/nº - Campus Universitário - 36570-000 - Viçosa, MG - Brasil

^IIIUniversidade Católica de Brasília, SGAN 916, Módulo B, Asa Norte - 70790-160 - Brasília, DF - Brasil

ABSTRACT

The genus Arachis has 69 species, the majority native to Brazil. Arachis spp. seedling root tips have been used to obtain dividing cells for cytological preparations. Several wild species produce small amounts of seeds and consequently few root meristems, making the cytogenetic characterization very difficult. The purpose of this study was to evaluate the rooting capacity of several wild species of Arachis using the detached leaves technique for obtaining roots from petioles. One hundred and thirty accessions and 27 interspecific hybrids were studied. Three evaluations were performed at 15, 31, and 49 days after planting. Leaf rooting observed in the wild species confirmed the great genetic variability typical of the Arachis genus, indicating that the number of days interferes with the rooting percentage. The Arachis Section presented the highest rate of rooting leaves. The Caulorrhizae Section showed the same pattern observed in the Erectoides Section. Accessions from Heteranthae, Trierectoides, Extranervosae, and Rhizomatosae Sections did not differ among each other. Differences were not observed in Erectoides Section when compared to Rhizomatosae and Extranervosae Sections. The number and morphology of roots obtained through this technique were promising to be used on cytological preparations.

Key words: cytology, germplasm

RESUMO

O gênero Arachis possui 69 espécies, sendo a maioria nativa do Brasil. Ápices radiculares de plântulas têm sido usados para a obtenção de células em divisão. Diversas espécies silvestres produzem pouca quantidade de sementes, o que dificulta a obtenção de meristemas para preparações citológicas. O objetivo deste trabalho foi avaliar a capacidade de enraizamento de diversas espécies silvestres de Arachis, usando a técnica de folhas destacadas para a obtenção de raízes a partir de pecíolos. Foram avaliados 130 acessos e 27 híbridos interespecíficos aos 15, 31 e 49 dias após o plantio. A formação de raízes a partir de folhas observada em espécies silvestres confirmou a ampla variabilidade genética típica do gênero Arachis, indicando que o número de dias também interfere na porcentagem de enraizamento. A Secção Arachis apresentou a maior taxa de enraizamento de folhas e a Secção Caulorrhizae apresentou o mesmo padrão da Secção Erectoides. Acessos pertencentes às Secções Heteranthae, Trierectoides, Extranervosae e Rhizomatosae não diferiram com relação à porcentagem de enraizamento. A Secção Erectoides apresentou comportamento similar ao das Secções Rhizomatosae e Extranervosae. A quantidade e morfologia de raízes obtidas por meio dessa técnica mostraram-se promissoras para uso em preparações citológicas.

Palavras-chave: citologia, germoplasma

INTRODUCTION

Although plant researchers know the importance of plant genetic resources, the limited use of germplasm banks accessions is a reality around the world. Two alternatives have been emphasized for increasing the use of available accessions: pre-breeding programs and organization of core collections (Frankel & Brown, 1984; Brown, 1989; Vilela-Morales et al., 1997; Nass, 2001).

The genus Arachis has 69 species (Krapovickas & Gregory, 1994), the majority of them of Brazilian occurrence. Several wild species of the genus show interesting characteristics for groundnut genetic improvement (Arachis hypogaea L.), to be used as forage, ornamental, as well as for erosion control. Several of them are more pest resistant than the culti- vated groundnut (Stalker & Moss, 1987; Fávero et al., 2001).

Chromosome number and morphological observations are important for species characterization and germplasm bank organization. Root tips of seedlings have been used for obtaining division cells to allow investigation based on mitotic characterization of Arachis species (Stalker,1991; Lavia, 1998). Several wild species produce small amounts of seeds in their natural habitat or even in germplasm banks, making the work on cytogenetic characterization very difficult. Usually, root tips are obtained from cuttings. However, this technique sometimes demands a long time to produce results. To overcome this difficulty, petioles rooting and callus productions through in vitro culture have been used (Nakano et al., 1999; Shibli et al., 2001). The detached leaves technique has been used in phytopathological characterization of accessions (Subrahmanyam & Moss, 1983), and in molecular studies of root development (Brown & Mangat, 1970). A petiole-rooting technique to obtain root tips was described by Blomgren et al. (1988) in soybean, which also shows chromosomes in mitosis from root tips developed in detached petioles. This technique can also be used in cases of seed unavailability and/or unfeasibility of the cutting alternative.

Fávero et al. (2004) showed that for some interspecific hybrids of Section Arachis, the detached leaf technique presented in this work may be used to produce root in sufficient amount and quality to be used in cytological preparations.

Our objective was to evaluate the rooting capacity of several wild species of Arachis using a detached leaf technique to obtain roots from petioles.

MATERIAL AND METHODS

One hundred and thirty accessions and 27 interspecific hybrids belonging to the Arachis Germplasm Bank of Embrapa Genetic Resources and Biotechnology - Cenargen (Brasília, Brazil) were used.

From each accession, four new totally expanded leaves were collected, placed in plastic bags and stored in a refrigerator. Petioles were treated with 0.4% naphthalene acetic acid rooting hormone (NAA) powder and leaves were immediately placed in cells of polystyrene trays containing vegetable substratum (Plantmax^®). The trays were covered with transparent plastic bags for humidity maintenance and transferred to the greenhouse in shadow conditions, with an average temperature of 24ºC. The substrate was watered every two days. Accessions were evaluated in a completely randomized block design with four replications. The evaluations were performed at 15, 31, and 49 days after planting. In each evaluation, accessions were classified as rooted, non-rooted and dead leaves. The statistical analysis was made using PROCREG of the Statistical Analysis System (SAS). The chi-square and t tests were used to verify the rooting differences among Sections as well as to identify which Sections were different from each other. The Nemenyi test of non parametric multiple comparison was used to verify differences among the earliest and the latest rooting accessions.

RESULTS AND DISCUSSION

The leaf petioles rooting observed in wild Arachis species (Figure 1) confirms the great variability displayed by the genus. Great differences (P < 0.01) among genotypes were observed.

Species of all Sections were evaluated, except Trisseminatae Section. During the first evaluation (15 days) 26 accessions (16.25%) rooted in at least one replication. During the second (31 days) and on the third (49 days) evaluations, root development was observed in 103 (64.40%) and in 126 (78.75%) accessions, respectively.

Root induction frequencies for each accession are presented in Table 1. The Nemenyi test (a non parametric test of multiple comparisons, type Tukey) was done and it was verified that there was no cluster, unless for those that had the same results. Consequently, all accessions that had different rooting were also different for the Nemenyi test. Accessions V 9923 (A. sp.) and Wi 1302-2 (A. cruziana) rooted within 15 days in four and three replications, respectively, being considered the earliest accessions among the evaluated materials. Accession V 13774 (A. aff. diogoi) leaves died in all replications, indicating that this methodology may not be appropriate. After the third evaluation, leaves of 34 accessions (21.25%) did not root or died. Such accessions will be revaluated using another methodology.

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Distinct performance among Sections were observed concerning rooting leaves (Table 2). The Arachis Section presented the highest precocity, showing the highest rate of rooting leaves among the Sections studied, concentrating the largest frequencies between 15 and 31 days. The Erectoides, Extranervosae, Rhizomatosae and Procumbentes Sections displayed the latest or non-rooting rates. The Caulorrhizae, Heteranthae and Trierectoides Sections displayed intermediate rooting rates, concentrated in 31 days. For most of the sections, petiole rooting initiated on the average at day 31. Most of the leaves did not root or died.

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The chi-square test (P < 0.0001) indicated that petiole rooting is a genotype dependent process, suggesting that there is a genetic factor associated to this characteristic. Section Arachis displayed the largest rooting ratio, and it is different from the other Sections by the t test. Induction of roots in accessions from Caulorrhizae Section was not different from Erectoides Section. This result is due to their similar distributions, which differ basically in the number of accessions with 75% of rooting. Due to the low degrees of freedom associated to the other sections, these could not be efficiently discriminated. The Heteranthae, Trierectoides, Extranervosae and Rhizomatosae Sections did not differ from each other. Differences were not observed in the Erectoides Section when compared to the Rhizomatosae and Extranervosae Sections.

Rios et al. (1994) obtained detached leaf rooting from several species, using vermiculite as substratum, including 16 different legume genus, sunflower (Helianthus annuus), colza (Brassica campestris) and forage turnip (Brassica napus). Leaves of common bean (Phaseolus vulgaris), faba bean (Vicia faba) and cowpea (Vigna unguiculata) presented the best rooting performance among all species.

In conclusion, the use of detached leaves allows high efficiency for the production of roots in several species of the genus Arachis, with an average rooting rate of 78.75% in 49 days. The amount and morphology of the roots produced through this technique were promising and could be tested for cytological preparations, which demands a high amount of roots. Other aspects that may be mentioned are the short time required to obtain roots and the easy handling of them.

ACKNOWLEDGMENTS

To José F. M. Valls for providing the accessions used in this work and to Maurício A. Lopes for his critical review of the manuscript.

Received February 06, 2004

Accepted November 04, 2004

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FÁVERO, A.P.; CUCO, S.M.; AGUIAR-PERECIN, M.L.R.; VALLS, J.F.M.; VELLO, N.A. Rooting in leaf petioles of Arachis for cytological analysis. Cytologia, v.69, p.215-219, 2004.
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SHIBLI, R.A.; SHATNAWI, M.; ABU-EIN; AL-JUBOORY, K.H. Somatic embryogenesis and plant recovery from callus of 'Nabali' Olive (Olea europea L.) Scientia Horticulturae, v.88, p.243-256, 2001.
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*

Corresponding author <

favero@cenargen.embrapa.br>

Publication Dates

Publication in this collection
22 Feb 2005
Date of issue
Jan 2005

History

Received
06 Feb 2004
Accepted
04 Nov 2004

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] BLOMGREN, S.M.; AMBERGER, L.A.; HEER, H.E.; PALMER, R.C. A petiole-rooting technique for soybean chromosome observation. Soybean Genetics Newsletter, v.15, p.153-154, 1988.

[2] BROWN, A.H.D. Core collections: a practical approach to genetic resources management. Genome, v.31, p.818-824, 1989.

[3] BROWN, E.G.; MANGAT, B.S. Studies on free nucleotide pool and RNA components of detached leaves of Phaseolus vulgaris during root development. Phytochemistry, v.9, p.1859-1868, 1970.

[4] FÁVERO, A.P.; MORAES, S.A.; VELLO, N.A.; VALLS, J.F.M. Caracterização de espécies silvestres de amendoim quanto à resistência à mancha castanha visando à introgressão de genes ao amendoim cultivado. In: BRAZILIAN CONGRESS OF BREEDING PLANTS, Goiânia, 2001. Proceedings. Goiânia: Sociedade Brasileira de Melhoramento de Plantas, 2001.

[5] FÁVERO, A.P.; CUCO, S.M.; AGUIAR-PERECIN, M.L.R.; VALLS, J.F.M.; VELLO, N.A. Rooting in leaf petioles of Arachis for cytological analysis. Cytologia, v.69, p.215-219, 2004.

[6] FRANKEL, O.H.; BROWN, A.H.D. Plant genetic resources today: a critical appraisal. In: HOLDEN, J.H.W.; WILLIAMS, J.T. (Ed.) Crop genetic resources: conservation and evaluation London: George Allen & Unwin, 1984. p.249-257.

[7] KRAPOVICKAS, A.; GREGORY, W.C. Taxonomia del género Arachis (Leguminosae). Bonplandia, v.8, p.1-186, 1994.

[8] LAVIA, G.I. Karyotypes of Arachis palustris and A. praecox (Section Arachis), two species with basic chromosome number x=9. Cytologia, v.63, p.177-181, 1998.

[9] NAKANO, M.; NIIMI, Y.; KOBAYASHI, D.; WATANABE, A. Adventitious shoot regeneration and micropropagation of hybrid tuberous begonia (Begonia x tuberhybrida Voss). Scientia Horticulturae, v.79, p.245-251, 1999.

[10] NASS, L.L. Utilização de recursos genéticos vegetais no melhoramento. In: NASS, L.L.; VALOIS, A.C.C.; MELO, I.S.; VALADARES-INGLIS, M.C. (Ed.) Recursos genéticos e melhoramento plantas. Rondonópolis: Fundação MT, 2001. p.29-55.

[11] RIOS, G.P.; ANTONIO, F.G.; RODRIGUES, F.A. Enraizamento de folhas em vermiculita para estudos de doenças foliares. Fitopatologia Brasileira, v.19, p.268, 1994.

[12] SHIBLI, R.A.; SHATNAWI, M.; ABU-EIN; AL-JUBOORY, K.H. Somatic embryogenesis and plant recovery from callus of 'Nabali' Olive (Olea europea L.) Scientia Horticulturae, v.88, p.243-256, 2001.

[13] SUBRAHMANYAM, P.; MOSS, J.P. Resistance to peanut rust in wild Arachis species. Plant Disease, v.67, p.209-212, 1983.

[14] STALKER, H.T. A new species in section Arachis of peanuts with a D genome. American Journal of Botany, v.78, p.630-637, 1991.

[15] STALKER, H.T.; MOSS, J.P. Speciation, citogenetics and utilization of Arachis species. Advances in Agronomy, v.41, p.1-40, 1987.

[16] VILELA-MORALES, E.A.; VALOIS, A.C.C.; NASS, L.L. Recursos genéticos vegetales Brasília: EMBRAPA, SPI; CENARGEN, 1997. 78p.

Brasil

Brasil

Rooting performance from leaf petioles of accessions and hybrids of wild Arachis species

Enraizamento de pecíolos de folhas de espécies silvestres e híbridos de Arachis

Abstracts

Publication Dates

History