Morphological characterization of active germoplasm bank fig tree accessions

Rodrigues, Maria Gabriela Fontanetti; Santos, Tatiane Paes dos; Ferreira, Antonio Flávio Arruda; Monteiro, Laís Naiara Honorato; Nakanishi, Eduarda Sayuri; Boliani, Aparecida Conceição

doi:10.1590/0100-29452019074

Abstract

Fig tree (Ficus carica L.) is a fruit of great importance worldwide, being able to be implanted as new source of agricultural variability. The aim of the present work was to characterize the active germplasm bank of fig trees by means of morphological descriptors of 45 fig accessions at the Faculty of Agrarian and Technological Sciences, Campus of Dracena, FCAT / UNESP aiming at the recognition of the quality and genetic variability potential of the species. Thus, their biometric characteristics were evaluated by qualitative and quantitative descriptors of leaves and fruits. Fig tree accessions were characterized by means of the morphological characteristics of leaves and fruits, identifying AGB with high phenotypic variability and well adapted to the region and, by the analysis of the qualitative and quantitative characteristics, it was concluded that the most divergent accessions presented characteristics of agronomic interest, allowing the selection of features in order to subsidize conservation works, genetic improvement and crop production.

Index terms
Ficus carica L.; ex situ conservation; genetic resources; biometrics

Resumo

A figueira (Ficus carica L.) é uma frutífera de grande importância mundial, podendo ser implantada como fonte de variabilidade agrícola. Diante disso, o objetivo do presente trabalho foi realizar a caracterização do banco ativo de germoplasma da cultura da figueira por meio de descritores morfológicos de 45 acessos de figo, na Faculdade de Ciências Agrárias e Tecnológicas, Câmpus de Dracena, FCAT/UNESP, visando ao reconhecimento da qualidade e da potencialidade da variação genética da espécie. Assim, foram avaliadas características biométricas por descritores qualitativos e quantitativos de folhas e de frutos. Foi possível caracterizar os acessos de figueira por meio das características morfológicas de folhas e de frutos, identificando um BAG com alta variabilidade fenotípica e bem adaptado à região e, pela análise dos caracteres qualitativos e quantitativos, conclui-se que os acessos mais divergentes apresentaram características de interesse agronômico, possibilitando a seleção de caracteres a fim de subsidiar trabalhos de conservação, de melhoramento genético e de produção da cultura.

Termos para indexação
Ficus carica L.; conservação ex situ; recursos genéticos; biometria

Introduction

Fig (Ficus carica L.) is among the twenty main fruits exported by Brazil and has maintained third position in the ranking of marketed volume among temperate climate fruits, with production of approximately 26 thousand tonnes per year in 2,600 hectares of planted area, ranking ninth in terms of world production (FAOSTAT, 2019 FAOSTAT. Crops production. Rome: FAO, 2019. Disponível em: http://www.fao.org/faostat/en/#data/QC/visualize/figs. Acesso em: 25 abr. 2019.
http://www.fao.org/faostat/en/#data/QC/v... ).

However, in Brazil, there is predominance of a single fig-tree cultivar, ‘Roxo-de-Valinhos’, resulting in serious problems related to pests and diseases, which compromise cultivation and damage fruits, reducing profits, hampering plant development and demanding high expenses with inputs and cultural treatments (FERRAZ, 2017 FERRAZ, R.A. Propagação e desempenho agronômico de variedades de figueira (Ficus carica L.) com potencial de cultivo. 2017. Tese (Doutorado) - Faculdade de Ciências Agronômicas, Universidade Estadual Paulista, Botucatu, 2017. ).

Thus, studies aimed at finding solutions to some of these problems would make an enormous contribution for the development of the fig tree crop, being variety diversification, with the use of resistant cultivars and adapted to different environments, an important strategy for the development of the fig culture.

According to Frankham (2005) FRANKHAM, R. Genetics and extinction. Biological Conservation, Oxford, v.126, p.131–140, 2005. , genetic diversity has become the key to species survival and adaptation to changes in the environment, and the elucidation of the mechanisms of origin and maintenance of this variation is essential (PLATT et al., 2010 PLATT, A.; HORTON, M.; HUANG, Y.S.; LI, Y.; ANASTASIO, A.E.; MULYATI, N.W. The scale of population structure in Arabidopsis thaliana. PLoS Genetics, San Francisco, v.6, n.2, e1000843, 2010. ; HUANG et al., 2014 HUANG, P.; FELDMAN, M.; SCHRODER, S.; BAHRI, B.A.; DIAO, X.; ZHI, H.; ESTEP, M.; BAXTER, I.; DEVOS, K.M.; KELLOGG, E.A. Population genetics of Setaria viridis, a new model system. Molecular Ecology, London, v.23, p.4912–4925, 2014. ).

He et al. (2016) HE, S.L.; HOLLINGSWORTH, P.; YI, T.S.; LI, D.Z. Environmental and historical determinants of patterns of genetic differentiation in wild soybean (Glycine soja Sieb. et Zucc). Scientific Reports, Londres, v.6, p.22795, 2016. emphasize the importance of maintaining accessions available in Active Germplasm Banks (AGBs) for the crop, as well as measures for their conservation, which should be implemented in different populations according to their potential to adapt to future climate and environmental changes induced by man.

According to Ramalho et al. (2012) RAMALHO, M.A.P.; PINTO, C.A.B.P.; SANTOS, J.B. Genética na agropecuária. 5.ed. Lavras: Editora da UFLA, 2012. 566p. , in addition to its conservation and maintenance, the correct characterization of existing AGBs is essential, allowing the recognition of the quality and potentiality of germplasm under the most varied aspects, since they play a fundamental role in the preservation of the genetic variability.

The availability of plant genetic resources necessarily involves the morphological characterization of accessions registered in germplasm banks through the knowledge of a series of data aiming to describe them by means of characteristics of interest, including culture attributes or traits, establishing an identity for each component (VALOIS et al., 2001 VALOIS, A.C.C.; NASS, L.L.; GOES, M. Conservação “ex situ” de recursos genéticos vegetais. In: NASS, L.L.; VALOIS, A.C.C.; MELO, I.S.; VALADARES-INGLIS, M.C. (ed.). Recursos genéticos &melhoramento: planta. Rondonópolis: Fundação MT, 2001. p.123-158. ).

In view of the above, the aim of the present work was to perform the morphological characterization of leaves and fruits of 45 fig tree accessions (Ficus carica L.) of the Active Germplasm Bank introduced at the Faculty of Agrarian and Technological Sciences, Campus of Dracena, FCAT / UNESP, through quantitative and qualitative descriptors.

Material and methods

The genetic material was composed of 45 Ficus sp. accessions belonging to the one-year-old Active Germplasm Bank of the Agricultural Sector of the Faculty of Agrarian and Technological Sciences FCAT / UNESP, Campus of Dracena-SP.

The experimental design was randomized blocks, consisting of 45 treatments, each accession being considered a treatment, with two blocks and three plants per plot, totaling 270 plants, grown in 1.5 m x 1.5 m spacing. Treatments evaluated, with their respective accessions and places of origin, are presented in Table 1.

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Table 1
Active Germplasm Bank Fig tree accessions of the Faculty of Agricultural and Technological Sciences (FCAT / UNESP). Dracena / SP, 2017

Fertilization was performed according to soil analysis and recommendations of Raij et al. (1997) RAIJ, B. van.; CANTARELLA, H.; QUAGGIO, J.A.; FURLANI, A.M.C. (ed.). Recomendações de adubação e calagem para o estado de São Paulo. 2.ed.rev. Campinas: IAC,1997. p.45-47 (Boletim Técnico, 100). , in the projection of fig tree canopies, with soil lacking mulch.

Phytosanitary treatment was carried out with biweekly applications of Bordeaux mixture (1%) and Mancozeb (200 g p.c./100 liters of water) for the control mainly of fig leaf rust (Cerotelium fici Cast.), alternately applied.

Whenever necessary, weed control was performed by weeding, and irrigation by drip tape three times a week with average precipitation of 2.0 mm / h and a 50 cm wide strip in the planting line.

For the morphological characterization of leaves, branches from the median region of plants were selected and three axillary leaves close to the first fruit were photo-documented, and the following evaluations were performed:

a) Number of lobes per leaf;

b) Length and width of the leaf blade, in centimeters;

c) Petiole length, in centimeters.

For fruit characterization, four fruits at the beginning of maturation from each plant of the experiment were used for the following evaluations:

a) Shape of each fruit: elongate, pyriform oblong or oval;

b) Length and diameter of the median region of each fruit, in centimeter, with the aid of a pachymeter;

c) Length of the peduncle, in centimeter, from its insertion in the stem to the support of syicons.

d) Open or closed ostiole, considering the possibility of visualizing or not the inside of the fruit.

e) The pulp color of each fruit: red, pink or amber.

From the biometric results obtained, statistical analysis of all accessions was performed, grouping the averages obtained by the Scott-Knott test at 5% probability level. Statistical analyses were performed using the Sisvar software: a computer statistical analysis system, version 5.6 (FERREIRA, 2014 FERREIRA, D. F.. Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência e Agrotecnologia, Lavras, v.38, n.2, p.109-112, 2014. ).

Results and discussion

Morphological Characterization of Leaves-Biometric markers have an extreme ecological value, helping to determine the variability of the species and making it possible to differentiate phenotypic parameters among individuals of a given population, which is one of the most important sources of variability available for plant breeding (PALACE et al. 2016 PALACE, M.; SULLIVAN, F.B.; DUCEY, M.; HERRICK, C. Estimating tropical forest structure using a terrestrial lidar. PLoS One, San Francisco, v.11, n.4, e0154115, 2016. , STOJANOVIĆ et al., 2016 STOJANOVIC M, PEZO L, LACNJEVAC C, MIHAJLOVIC M, PETROVIC J, MILOJKOVIC J. Biometric approach in selecting plants for phytoaccumulation of uranium. International Journal of Phytoremediation, Boca Raton, v.18, n.5, p.527-533, 2016. ).

Leaf biometric markers exhibit drastic shape variation within the same species, reflecting both the heteroblastic development of the apical meristem from which they are derived and the ontogeny of individual leaves as they expand alometrically (CHITWOOD et al., 2016 CHITWOOD, D.H.; KLEIN, L.L.; O’HANLON, R.; CHACKO, S.; GREG, M.; KITCHEN, C.; MILLER, A.J.; LONDO, J.P.Latent developmental and evolutionary shapes embedded within the grapevine leaf. New Phytologist, Cambridge, v.210, p.343–55, 2016. ).

Figure 1 shows that most accessions followed the pattern of the ‘Roxo-de-Valinhos’ cultivar (Figure 2-D), with differentiation in the pronunciation of the 2 secondary lobes. According to Medeiros (2002) MEDEIROS, A.R.M. Figueira (Ficus carica l.) do plantio ao processamento caseiro. Pelotas: Embrapa, 2002. 16p. (Circular técnica, 35). , the ‘Roxo-de- Valinhos’ cultivar is characterized by presenting large leaves with five large and two smaller lobes; dark green color; compact texture, somewhat rigid; creased margin; petiole sinus in the form of lyre and long petiole.

Figure 1
Number of lobes of Active Germplasm Bank fig accessions of the Faculty of Agricultural and Technological Sciences (FCAT / UNESP). Dracena / SP, 2017.

Figure 2
Leaves of accessions 17 (Troyano) (A), accessions 24 (Nazaret) (B), accessions 45 (Turco Fig) (C), accession 4 (Roxo-de-Valinhos) (D) and accession 44 (Preto de Piracicaba Fig) (E) characterizing respectively leaves with 3, 3 + 2, 5 + 2, 7 and 7 + 2 lobes. Dracena - SP, 2017.

However, a large variation in the number of lobes among certain fig tree accessions was observed, varying from 3 little pronounced large lobes, as occurs in the ‘Troyano’ variety (Accession 17), represented in Figure 2-A; 3 well pronounced large lobes added of 2 little pronounced lobes, observed in ‘Nazaret’ cultivar (Access 24), represented in Figure 2-B.

Up to 7 large well-defined lobes added of two small well-pronounced lobes were also found, as on the case of ‘Preto de Piracicaba Fig’ accession (Accession 44), Figure 2-E.

There is large variation in the number of leaf lobes among AGB fig tree accessions and differences regarding how pronounced these lobes were presented. As for the length and width of leaves, accessions 5, 28, 25, 6, 16 and 45 stood out. Accession 45 (Turco Fig) presented the highest length and width values (25.7 cm and 23.3 cm, respectively) of leaves (Figure 2-C), being statistically superior to the other accessions (Table 2).

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Table 2
Petiole length (CP), length (CF) and width (LF) of leaves of Active Germplasm Bank fig accessions of the Faculty of Agricultural and Technological Sciences (FCAT / UNESP). Dracena / SP, 2017

Accessions with the lowest length and width values were 20, 15, 26, 24, 23, 1, 21, 3 and 27, which, in principle, would lead plants to have smaller photosynthetic area, and, consequently, lower growth and development, as is the case of accessions 20, 23, 24 and 26, which stood out for the lowest effective height values.

According to Chitwood and Otoni (2017) CHITWOOD, D.H.; OTONI, W.C. Morphometric analysis of Passiflora leaves: the relationship between landmarks of the vasculature and elliptical Fourier descriptors of the blade. GigaScience, Oxford, v.6, n.1, p.1-13, 2017. , working with leaf morphology in Passiflora species, leaf shape diversity is considered a profound change in differentiation that causes the development of the primary vasculature pattern and laminar expansion.

Each of the aspects of leaf morphology provides different points of view about its pattern, and the number of lobes is a highly relevant factor for the differentiation of “toothed” plants, as is also the case with the fig tree, which proved to be promising feature of selection of leaf morphology among the features evaluated by Rodrigues et al. (2017) RODRIGUES, M.G.F.; MONTEIRO, L.N.H.; FERREIRA, A.F.A.; PAVAN, B.E.; BOLIANI, A.C. Caracterização morfológica de acessos de banco de germoplasma de figueira. In: CONGRESSO BRASILEIRO DE FRUTICULTURA, 25., 2017. Porto Seguro. Anais [...]. Campos dos Goytacazes: SBF, 2017. , because it presents high heritability and high genetic correlation, being little influenced by the environment.

Plants present different responses regarding tolerance to shading, reflecting on growth and development (PAEZ et al., 2000 PAEZ, A.; GEBRE, G.M.; GONZALEZ, M.E.; TSCHAPLINKI, T.J. Growth, soluble carbohydrates,and aloin concentration of Aloe vera plants exposed to three irradiance levels. Environmental and Experimental Botany, v. 44, p. 133-139, 2000. ). Luminosity is one of the limiting factors for plant development, since the edaphoclimatic conditions of the environment are reflected in the growth and in the different forms of adaptation (Andrade et al., 2004 ANDRADE, C. M. S.; VALENTIM, J. F.; CARNEIRO, J. C.; VAZ, F. A. Crescimento de gramíneas e leguminosas forrageiras tropicais sob sombreamento. Pesquisa Agropecuária Brasileira, v. 39, n.3, p. 263-270, 2004. ).

Thus, growth efficiency may be related to the ability of plants to adapt to light conditions, and the satisfactory growth of some species in low or high luminosity environments is attributed to their ability to rapidly adjust their biomass allocation model and physiological behavior (DIAS-FILHO 1997 DIAS-FILHO, M.B. Physiologycal response of Solanumcrinitum Lam. to contrasting light environments. Pesquisa Agropececuária Brasileira, v. 32, p.789-796, 1997. ).

Thus, for the other accessions that presented small leaves, this deficiency in the photosynthetic area, individually, may have been supplied by the greater number of active leaves in plants, since, in addition to individual leaf area, the number and angle of leaves alter the light distribution within the plant and, consequently, influence the self-shading inside the canopy (FALSTER and WESTOBY, 2003 FALSTER, D.S.; WESTOBY, M. Leaf size and angle vary widely across species: what consequences for light interception? New Phytologist, Oxford, v.158, p.509-525, 2003. , SARLIKIOTI et al., 2011 SARLIKIOTI, V.; DE VISSER, P.H.B.; MARCELIS, L.F.M. Exploring the spatial distribution of light interception and photosynthesis of canopies by means of a functional–structural plant model. Annals of Botany, London, v.107, n.5, p.875–883, 2011. , CHEN et al., 2014 CHEN, T.W.; NGUYEN, T.M.N.; KAHLEN, K.; STÜTZEL, H. Quantification of the effects of architectural traits on dry mass production and light interception of tomato canopy under different temperature regimes using a dynamic functional–structural plant model. Journal of Experimental Botany, Oxford, v.65, p.6399–6410, 2014. ).

Table 2 shows the leaf length and width values of all accessions, together with their statistical analysis, which obtained average of 17.0 cm for length and 14.9 cm for width, with variation coefficient VC (%) of 15.87 and 15.02, respectively.

According to Perez et al. (1988) PEREZ, R.P.A.; DAUZAT, J.; PALLAS, B.; LAMOUR, J.; VERLEY, P.; CALIMAN, J.; COSTES, E.; FAIVRE, R. Designing oil palm architectural ideotypes for optimal light interception and carbon assimilation through a sensitivity analysis of leaf traits, Annals of Botany, London, v.121, n.5, p.909-926, 2018. , the efficiency with which plant intercepts solar radiation also depends on other architectural features involved in the three-dimensional (3-D) arrangement of leaves, such as internode length (DAUZAT et al., 2008 DAUZAT, J.; CLOUVEL, P.; LUQUET, D.; MARTIN, P.Using virtual plants to analyse the light-foraging efficiency of a low-density cotton crop. Annals of Botany, London, v.101, p.1153–1166, 2008. ; Silva et al., 2014 SILVA, D. da; HAN, L.; FAIVRE, R.; COSTES, E. Influence of the variation of geometrical and topological traits on light interception efficiency of apple trees: sensitivity analysis and metamodelling for ideotype definition. Annals of Botany, London, v.114, p.739–752, 2014. ; CHEN et al., 2014 CHEN, T.W.; NGUYEN, T.M.N.; KAHLEN, K.; STÜTZEL, H. Quantification of the effects of architectural traits on dry mass production and light interception of tomato canopy under different temperature regimes using a dynamic functional–structural plant model. Journal of Experimental Botany, Oxford, v.65, p.6399–6410, 2014. ), petiole length (TAKENAKA, 1994 TAKENAKA, A. Effects of leaf blade narrowness and petiole length on the light capture efficiency of a shoot. Ecological Research, Oxford, v.9, p.109–114, 1994. ; CHENU et al., 2005 CHENU, K.; FRANCK, N.; DAUZAT, J.; BARCZI, J.F.; REY, H.; LECOEUR, J. Integrated responses of rosette organogenesis, morphogenesis and architecture to reduced incident light in Arabidopsis thaliana results in higher efficiency of light interception. Functional Plant Biology, Victoria, v.32, p.1123–1134. 2005. ) and branch patterns (NIINEMETS, 2007 NIINEMETS, Ü. Photosynthesis and resource distribution through plant canopies. Plant, Cell and Environment, Oxford, v.30, p.1052–1071, 2007. ; SILVA et al., 2014 SILVA, D. da; HAN, L.; FAIVRE, R.; COSTES, E. Influence of the variation of geometrical and topological traits on light interception efficiency of apple trees: sensitivity analysis and metamodelling for ideotype definition. Annals of Botany, London, v.114, p.739–752, 2014. ).

However, for leaf petiole length, in spite of a great variation among accessions, from 4.2 cm to 10.0 cm, except for accession 45 (Turco Fig), which presented larger petiole and both length and width statistically higher than the other accessions, its length had no relation to the length and width of leaves, which can be observed in Table 2, with mean of 6.8 cm and variation coefficient VC (%) of 19.5.

Morphological Characterization of Fruits The shape of fruits of the 45 Ficus sp. accessions were varied, from elongated to oval, which were already expected; however, the flattened shape of fruits was also observed. In this case, fruits with diameter significantly larger than their length were considered flattened, with abrupt ostiole area, such as, for example, accessions 8 and 9, which represent the ‘White Genova’ cultivar (Figure 3-D) of different regions, with mean length and width values, respectively, of 32.5-38.8 mm and 32.0-37.1 mm.

Figure 3
Fruit of accession 14 (Pingo-de-Mel) (A), accession 19 (Irradiated Plant 440) (B), accession 4 (Roxo-de-Valinhos) (C) and accession 8 (White Genova) (D) characterizing, respectively, oval, elongated, oblong pyriform and flattened fig fruits. Dracena - SP, 2017.

Among accessions considered flattened, accessions 28, 29, 30, 31, 32, 35 and 36 were still at an immature stage of development, not reaching their full physiological development, being discolored, with shape and density different from a mature fruit, weighting three times less than the mature fig (VENDRUSCOLO, 1988 VENDRUSCOLO, C.T. Aceitabilidade de figo (Ficus carica L.) cv. Roxo de Valinhos desidratado com açúcar e SO2. 1988. Dissertação (Mestrado em Ciência e Tecnologia Agroindustrial) - Universidade Federal de Pelotas, Pelotas, 1988. ). The physiological maturity point depends on the species, as it is affected by genetic factors and also by environmental factors such as temperature and relative humidity, and the knowledge of the maturation process is important for the establishment of the ideal harvesting point (SILVA, 2009 SILVA, L.; MARTINS, C.C.; MACHADO, C.G.; NAKAGAWA, J. Estádios de colheita e repouso pós-colheita dos frutos na qualidade de sementes de mamoneira. Revista Brasileira de Sementes, Londrina, v.31, n.1, p.50-59, 2009. ).

Oval shape (Figure -A) was observed in ‘Bonato’, ‘Smyrna’, and ‘Pingo de Mel’ cultivars, considered as characteristic of parthenocarpic fruits. In the case of ‘Smyrna’ cultivar in particular, its shape tends to change due to the caprification process, indispensable for the normal development of fruits of this pomological class (ARADHYA, DIANNE VELASCO and KOEHMSTEDT, 2010 ARADHYA, M.K.; DIANNE VELASCO, E.S.; KOEHMSTEDT, A. Genetic structure and differentiation in cultivated fig (Ficus carica L.). Genetica, Dordrecht,v.138, n.6, p.681-694, 2010. ), which does not occur in Brazil.

Still with respect to the shape of fruits, length and diameter measures, simultaneously, define this parameter.

For the length of fruits, the highest values were observed for accessions 4, 8, 19, 22, 23 and 37. For diameter, accessions 4, 8, 9 and 22 stood out, with the production of fruits already at the beginning of the maturation stage.

In the specific case of accession 19 - Plant 440 and 23 - Plant 301, elongated shape was observed, which is in agreement with descriptions of Rodrigues et al. (2012) RODRIGUES, M. G. F.; CORRÊA, L. S.; SANTOS, P.C.; TULMANN NETO, A. Seleção de clones de figueira cv. Roxo-de-Valinhos formados por gemas irrigadas. Revista Brasileira de Fruticultura, Jaboticabal, n.2, v.34, p.604- 611, 2012. .

An elongated fruit shape is defined as a fruit with its length significantly larger than its diameter; in this case, with mean values of 34.3 mm and 28.5 mm, respectively, which can be observed in Figure 3-B.

Rodrigues et al. (2012) RODRIGUES, M. G. F.; CORRÊA, L. S.; SANTOS, P.C.; TULMANN NETO, A. Seleção de clones de figueira cv. Roxo-de-Valinhos formados por gemas irrigadas. Revista Brasileira de Fruticultura, Jaboticabal, n.2, v.34, p.604- 611, 2012. , working with selection of mutants in fig plants formed by stakes irradiated with gamma rays, observed that the main commercial cultivar, ‘Roxo-de-Valinhos’ (Accession 4), ‘White Genova’ and Accession 22, which represents Plant 214 of that experiment, presented the same characteristics observed in the present work.

‘Roxo-de-Valinhos’ cultivar has predominance of fruits with oblong-pyriform shape (Figure 3-C), with short and thick neck, almost without limit of separation with body from the receptacle, as described by Rigitano (1955) RIGITANO, O. A figueira cultivada no Estado de São Paulo. 1955. Tese (Doutorado em Fitotecnia) - Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo, Piracicaba, 1955. . This shape was the one that prevailed among AGB fig tree fruits under study, as can be observed in Figure 4, which demonstrates the distinction among fruits of accessions that compose Ficus sp. AGB.

Figure 4
Shape of Fig fruits accessions. Dracena - SP, 2017.

The distribution of accessions, according to the length and diameter of fruits, is described in Table 3. The average values obtained were 28.4 mm for length and 28.3 mm for width with variation coefficient VC (%) of 11.3 and 11.4, respectively. The highest fruit length was observed for ‘Roxo-de-Valinhos’ cultivar (Accession 4), with 35.3 mm and the highest width for accessions 8 and 9 (White Genova), with 37.1 and 38.8 mm.

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Table 3
Peduncle length (CPE), length (CFR) and width (LFR) of fruits of Active Germplasm Bank fig accessions of the Faculty of Agricultural and Technological Sciences (FCAT / UNESP). Dracena / SP, 2017.

Still in Table 3, accession 16 (Palestino) presented the largest peduncle (4.0 mm). Large peduncle in fruits is an interesting agronomic characteristic for Ficus sp. production, because it facilitates harvest (SONG et al., 2016 SONG, Z.C.; MIAO, H.; ZHANG, S.; WANG, Y.; ZHANG, S.P.; GU, X.F.. Genetic Analysis and QTL Mapping of Fruit Peduncle Length in Cucumber (Cucumis sativus L.). PLoS ONE, San Francisco, v.11, n.12, e0167845, 2016. ), and increases the shelf life of fruits. According to Carvalho et al. (2008) CARVALHO, J.M.F.C; ARAÚJO, S.S.; SILVA, M.A. Preservação e intercâmbio de germoplasma. Campina Grande: Embrapa Algodão, 2008. 24p. (Documento, 196) , large peduncle is related to genotype, and presents high heritability index in the restricted sense, being a characteristic of early selection.

In the specific case of the fig tree crop, a very important aspect to determine the quality of fruits, in addition to the size of fruits, is the small ostiole opening (ALJANE and NAHDI, 2018 ALJANE, F.; ESSID, A.; NAHDI, S. Improvement of Fig (Ficus carica L.) by Conventional Breeding and Biotechnology. In: AL-KHAYRI, J.M., JAIN, S.M.; JOHNSON, D.V. Advances in Plant Breeding Strategies: fruits. Basel: Springer, 2013. v. 3, p. 343-375. ), which reduces the incidence of pests and avoids the depreciation of fruits with possible peel cracks. The ostiole is characterized as the opening for the entrance of the Blastophaga psene wasp so that inflorescence pollination within the siconium can occur for the development of fig fruits (LAMAS et al., 2009 LAMAS, L.; ELIAS, G.; PEREIRA, R.A.S. Comportamento agressivo em femeas de vespas polinizadoras (Hymenoptera: Agaonidae) de Ficus (Moraceae). In: CONGRESSO DE ECOLOGIA DO BRASIL, 9., 2009. São Lourenço. Anais [...] ). However, in addition to the fact that this wasp does not occur in Brazil due to climatic reasons, the fig fly (Zaprionus indianus Gupta, 1970) uses this hole for feeding and laying eggs (RAGA, 2002 RAGA, A. Mosca-do-figo. In: REUNIÃO ITINERANTE DE FITOSSANIDADE DO INSTITUTO BIOLÓGICO, 7., 2002, Indaiatuba. Anais [...]. Campinas: Instituto Biológico, 2002. p.54-57. ; RAGA and SOUZA FILHO, 2003 RAGA, A.; SOUZA FILHO, M.F. DE Captura de Zaprionus indianus (Gupta) (Dip.: Drosophilidae) em frascos de plásticos com iscas alimentares na cultura do figo. Revista Agriculturas, Rio de Janeiro, v.78, n.3, p.323-329, 2003. ), which causes fruit depreciation during production and marketing due to very severe damage.

One of the ways to prevent the entry of this pest within siconium is the selection of fig plants showing ostiole opening the less pronounced as possible (Figure 5), as is the case of accession 2 (Nobile), 3 (Genovesco), 6 (Adriatic White), 7 (Bonato), 11 (Smyrna), 14 (Pingo de Mel), 16 (Palestino), 17 (Troyano), 18 (Vermelho de Piracicaba Fig), 21 (Plant 189), 25 (Cuello Negro), 40 (Caprifig) and 43 (Mini Fig), as can be seen in Figure 6, which demonstrates the distribution of AGB fig accessions according to the opening of this hole. In the case of accession 21, which represents Plant 189, it maintained the characteristic of null ostiole opening, as observed by Rodrigues et al. (2012) RODRIGUES, M. G. F.; CORRÊA, L. S.; SANTOS, P.C.; TULMANN NETO, A. Seleção de clones de figueira cv. Roxo-de-Valinhos formados por gemas irrigadas. Revista Brasileira de Fruticultura, Jaboticabal, n.2, v.34, p.604- 611, 2012. .

Figure 5
Fruit of accession 4 (Roxo-de-Valinhos) (A) and accession 14 (Pingo de Mel) (B) characterizing, respectively, open and closed fig tree ostiole. Dracena - SP, 2017.

Figure 6
Characteristic of the ostiole of fruits from Fig tree accessions. Dracena - SP, 2017.

The other accessions that were considered with closed ostiole and that were not considered, presented white color of the internal siconium cavity (Figure 8-A), which characterizes fruit immaturity due to late maturation.

Figure 8
Fruit of accession 10 (Smyrna) (A), 14 (Pingo-de-Mel) (B) and accession 18 (Vermelho de Piracicaba Fig) (C) characterizing, respectively, immature fruit, amber and intense pink pulp fruit. Dracena - SP, 2017.

Regarding fruit coloration evaluation, the majority of accessions maintained the common reddish pink coloration, as can be observed in Figure 7. However, amber (Figure 8-B) and intense red colorations (Figure 8-C) were verified in some accessions, such as accessions 18 (Vermelho de Piracicaba Fig) and 23 (Plant 301), identified with more reddish coloration than the fruits of the other accessions.

Figure 7
Pulp coloration of fruits from Fig tree accessions. Dracena - SP, 2017.

The amber coloration was observed in accessions 2 (Nobile), 5 (Stanford), 6 (Adriático Branco), 10 and 11 (Smyrna), 14 (Pingo de Mel) and 40 (Caprifig), and unlike Nóbile, Adriatico Branco and Pingo-de-Mel, which present this characteristic coloration, need pollination to develop their fruits.

Conclusion

It was concluded that it was possible to characterize fig tree accessions through the morphological characteristics of leaves and fruits, identifying AGB with good adaptation to the region and, through the analysis of qualitative and quantitative features, it could be concluded that the most divergent accessions are 16 (Palestino), 17 (Troyano), 18 (Vermelho de Piracicaba Fig), 19 (Irradiated Plant 440), 21 (Irradiated Plant 189), 22 (Irradiated Plant 214), 23 (Irradiated Plant 301), 24 (Nazaret), 44 (Preto de Piracicaba Fig) and 45 (Turco Fig), with characteristics of agronomic interest, allowing the selection of features in order to subsidize conservation works, genetic improvement and crop production.

Acknowledgments

To the Faculty of Agrarian and Technological Sciences FCAT / UNESP and to the Foundation of Research Support of the State of São Paulo (FAPESP) for the financial assistance granted to the first author, process number 2016/20418-8.

ALJANE, F.; ESSID, A.; NAHDI, S. Improvement of Fig (Ficus carica L.) by Conventional Breeding and Biotechnology. In: AL-KHAYRI, J.M., JAIN, S.M.; JOHNSON, D.V. Advances in Plant Breeding Strategies: fruits Basel: Springer, 2013. v. 3, p. 343-375.
ANDRADE, C. M. S.; VALENTIM, J. F.; CARNEIRO, J. C.; VAZ, F. A. Crescimento de gramíneas e leguminosas forrageiras tropicais sob sombreamento. Pesquisa Agropecuária Brasileira, v. 39, n.3, p. 263-270, 2004.
ARADHYA, M.K.; DIANNE VELASCO, E.S.; KOEHMSTEDT, A. Genetic structure and differentiation in cultivated fig (Ficus carica L.). Genetica, Dordrecht,v.138, n.6, p.681-694, 2010.
CARVALHO, J.M.F.C; ARAÚJO, S.S.; SILVA, M.A. Preservação e intercâmbio de germoplasma. Campina Grande: Embrapa Algodão, 2008. 24p. (Documento, 196)
CHEN, T.W.; NGUYEN, T.M.N.; KAHLEN, K.; STÜTZEL, H. Quantification of the effects of architectural traits on dry mass production and light interception of tomato canopy under different temperature regimes using a dynamic functional–structural plant model. Journal of Experimental Botany, Oxford, v.65, p.6399–6410, 2014.
CHENU, K.; FRANCK, N.; DAUZAT, J.; BARCZI, J.F.; REY, H.; LECOEUR, J. Integrated responses of rosette organogenesis, morphogenesis and architecture to reduced incident light in Arabidopsis thaliana results in higher efficiency of light interception. Functional Plant Biology, Victoria, v.32, p.1123–1134. 2005.
CHITWOOD, D.H.; KLEIN, L.L.; O’HANLON, R.; CHACKO, S.; GREG, M.; KITCHEN, C.; MILLER, A.J.; LONDO, J.P.Latent developmental and evolutionary shapes embedded within the grapevine leaf. New Phytologist, Cambridge, v.210, p.343–55, 2016.
CHITWOOD, D.H.; OTONI, W.C. Morphometric analysis of Passiflora leaves: the relationship between landmarks of the vasculature and elliptical Fourier descriptors of the blade. GigaScience, Oxford, v.6, n.1, p.1-13, 2017.
DAUZAT, J.; CLOUVEL, P.; LUQUET, D.; MARTIN, P.Using virtual plants to analyse the light-foraging efficiency of a low-density cotton crop. Annals of Botany, London, v.101, p.1153–1166, 2008.
DIAS-FILHO, M.B. Physiologycal response of Solanumcrinitum Lam. to contrasting light environments. Pesquisa Agropececuária Brasileira, v. 32, p.789-796, 1997.
FALSTER, D.S.; WESTOBY, M. Leaf size and angle vary widely across species: what consequences for light interception? New Phytologist, Oxford, v.158, p.509-525, 2003.
FAOSTAT. Crops production. Rome: FAO, 2019. Disponível em: http://www.fao.org/faostat/en/#data/QC/visualize/figs. Acesso em: 25 abr. 2019.
» http://www.fao.org/faostat/en/#data/QC/visualize/figs.
FERRAZ, R.A. Propagação e desempenho agronômico de variedades de figueira (Ficus carica L.) com potencial de cultivo. 2017. Tese (Doutorado) - Faculdade de Ciências Agronômicas, Universidade Estadual Paulista, Botucatu, 2017.
FERREIRA, D. F.. Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência e Agrotecnologia, Lavras, v.38, n.2, p.109-112, 2014.
FRANKHAM, R. Genetics and extinction. Biological Conservation, Oxford, v.126, p.131–140, 2005.
HE, S.L.; HOLLINGSWORTH, P.; YI, T.S.; LI, D.Z. Environmental and historical determinants of patterns of genetic differentiation in wild soybean (Glycine soja Sieb. et Zucc). Scientific Reports, Londres, v.6, p.22795, 2016.
HUANG, P.; FELDMAN, M.; SCHRODER, S.; BAHRI, B.A.; DIAO, X.; ZHI, H.; ESTEP, M.; BAXTER, I.; DEVOS, K.M.; KELLOGG, E.A. Population genetics of Setaria viridis, a new model system. Molecular Ecology, London, v.23, p.4912–4925, 2014.
LAMAS, L.; ELIAS, G.; PEREIRA, R.A.S. Comportamento agressivo em femeas de vespas polinizadoras (Hymenoptera: Agaonidae) de Ficus (Moraceae). In: CONGRESSO DE ECOLOGIA DO BRASIL, 9., 2009. São Lourenço. Anais [...]
MEDEIROS, A.R.M. Figueira (Ficus carica l.) do plantio ao processamento caseiro. Pelotas: Embrapa, 2002. 16p. (Circular técnica, 35).
NIINEMETS, Ü. Photosynthesis and resource distribution through plant canopies. Plant, Cell and Environment, Oxford, v.30, p.1052–1071, 2007.
PAEZ, A.; GEBRE, G.M.; GONZALEZ, M.E.; TSCHAPLINKI, T.J. Growth, soluble carbohydrates,and aloin concentration of Aloe vera plants exposed to three irradiance levels. Environmental and Experimental Botany, v. 44, p. 133-139, 2000.
PALACE, M.; SULLIVAN, F.B.; DUCEY, M.; HERRICK, C. Estimating tropical forest structure using a terrestrial lidar. PLoS One, San Francisco, v.11, n.4, e0154115, 2016.
PEREZ, R.P.A.; DAUZAT, J.; PALLAS, B.; LAMOUR, J.; VERLEY, P.; CALIMAN, J.; COSTES, E.; FAIVRE, R. Designing oil palm architectural ideotypes for optimal light interception and carbon assimilation through a sensitivity analysis of leaf traits, Annals of Botany, London, v.121, n.5, p.909-926, 2018.
PLATT, A.; HORTON, M.; HUANG, Y.S.; LI, Y.; ANASTASIO, A.E.; MULYATI, N.W. The scale of population structure in Arabidopsis thaliana. PLoS Genetics, San Francisco, v.6, n.2, e1000843, 2010.
RAGA, A. Mosca-do-figo. In: REUNIÃO ITINERANTE DE FITOSSANIDADE DO INSTITUTO BIOLÓGICO, 7., 2002, Indaiatuba. Anais [...]. Campinas: Instituto Biológico, 2002. p.54-57.
RAGA, A.; SOUZA FILHO, M.F. DE Captura de Zaprionus indianus (Gupta) (Dip.: Drosophilidae) em frascos de plásticos com iscas alimentares na cultura do figo. Revista Agriculturas, Rio de Janeiro, v.78, n.3, p.323-329, 2003.
RAIJ, B. van.; CANTARELLA, H.; QUAGGIO, J.A.; FURLANI, A.M.C. (ed.). Recomendações de adubação e calagem para o estado de São Paulo. 2.ed.rev. Campinas: IAC,1997. p.45-47 (Boletim Técnico, 100).
RAMALHO, M.A.P.; PINTO, C.A.B.P.; SANTOS, J.B. Genética na agropecuária. 5.ed. Lavras: Editora da UFLA, 2012. 566p.
RIGITANO, O. A figueira cultivada no Estado de São Paulo. 1955. Tese (Doutorado em Fitotecnia) - Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo, Piracicaba, 1955.
RODRIGUES, M. G. F.; CORRÊA, L. S.; SANTOS, P.C.; TULMANN NETO, A. Seleção de clones de figueira cv. Roxo-de-Valinhos formados por gemas irrigadas. Revista Brasileira de Fruticultura, Jaboticabal, n.2, v.34, p.604- 611, 2012.
RODRIGUES, M.G.F.; MONTEIRO, L.N.H.; FERREIRA, A.F.A.; PAVAN, B.E.; BOLIANI, A.C. Caracterização morfológica de acessos de banco de germoplasma de figueira. In: CONGRESSO BRASILEIRO DE FRUTICULTURA, 25., 2017. Porto Seguro. Anais [...]. Campos dos Goytacazes: SBF, 2017.
SARLIKIOTI, V.; DE VISSER, P.H.B.; MARCELIS, L.F.M. Exploring the spatial distribution of light interception and photosynthesis of canopies by means of a functional–structural plant model. Annals of Botany, London, v.107, n.5, p.875–883, 2011.
SILVA, D. da; HAN, L.; FAIVRE, R.; COSTES, E. Influence of the variation of geometrical and topological traits on light interception efficiency of apple trees: sensitivity analysis and metamodelling for ideotype definition. Annals of Botany, London, v.114, p.739–752, 2014.
SILVA, L.; MARTINS, C.C.; MACHADO, C.G.; NAKAGAWA, J. Estádios de colheita e repouso pós-colheita dos frutos na qualidade de sementes de mamoneira. Revista Brasileira de Sementes, Londrina, v.31, n.1, p.50-59, 2009.
SONG, Z.C.; MIAO, H.; ZHANG, S.; WANG, Y.; ZHANG, S.P.; GU, X.F.. Genetic Analysis and QTL Mapping of Fruit Peduncle Length in Cucumber (Cucumis sativus L.). PLoS ONE, San Francisco, v.11, n.12, e0167845, 2016.
STOJANOVIC M, PEZO L, LACNJEVAC C, MIHAJLOVIC M, PETROVIC J, MILOJKOVIC J. Biometric approach in selecting plants for phytoaccumulation of uranium. International Journal of Phytoremediation, Boca Raton, v.18, n.5, p.527-533, 2016.
TAKENAKA, A. Effects of leaf blade narrowness and petiole length on the light capture efficiency of a shoot. Ecological Research, Oxford, v.9, p.109–114, 1994.
VALOIS, A.C.C.; NASS, L.L.; GOES, M. Conservação “ex situ” de recursos genéticos vegetais. In: NASS, L.L.; VALOIS, A.C.C.; MELO, I.S.; VALADARES-INGLIS, M.C. (ed.). Recursos genéticos &melhoramento: planta. Rondonópolis: Fundação MT, 2001. p.123-158.
VENDRUSCOLO, C.T. Aceitabilidade de figo (Ficus carica L.) cv. Roxo de Valinhos desidratado com açúcar e SO2. 1988. Dissertação (Mestrado em Ciência e Tecnologia Agroindustrial) - Universidade Federal de Pelotas, Pelotas, 1988.

Publication Dates

Publication in this collection
04 Nov 2019
Date of issue
2019

History

Received
25 Apr 2019
Accepted
11 July 2019

This is an Open-Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALJANE, F.; ESSID, A.; NAHDI, S. Improvement of Fig (Ficus carica L.) by Conventional Breeding and Biotechnology. In: AL-KHAYRI, J.M., JAIN, S.M.; JOHNSON, D.V. Advances in Plant Breeding Strategies: fruits Basel: Springer, 2013. v. 3, p. 343-375.

[2] ANDRADE, C. M. S.; VALENTIM, J. F.; CARNEIRO, J. C.; VAZ, F. A. Crescimento de gramíneas e leguminosas forrageiras tropicais sob sombreamento. Pesquisa Agropecuária Brasileira, v. 39, n.3, p. 263-270, 2004.

[3] ARADHYA, M.K.; DIANNE VELASCO, E.S.; KOEHMSTEDT, A. Genetic structure and differentiation in cultivated fig (Ficus carica L.). Genetica, Dordrecht,v.138, n.6, p.681-694, 2010.

[4] CARVALHO, J.M.F.C; ARAÚJO, S.S.; SILVA, M.A. Preservação e intercâmbio de germoplasma. Campina Grande: Embrapa Algodão, 2008. 24p. (Documento, 196)

[5] CHEN, T.W.; NGUYEN, T.M.N.; KAHLEN, K.; STÜTZEL, H. Quantification of the effects of architectural traits on dry mass production and light interception of tomato canopy under different temperature regimes using a dynamic functional–structural plant model. Journal of Experimental Botany, Oxford, v.65, p.6399–6410, 2014.

[6] CHENU, K.; FRANCK, N.; DAUZAT, J.; BARCZI, J.F.; REY, H.; LECOEUR, J. Integrated responses of rosette organogenesis, morphogenesis and architecture to reduced incident light in Arabidopsis thaliana results in higher efficiency of light interception. Functional Plant Biology, Victoria, v.32, p.1123–1134. 2005.

[7] CHITWOOD, D.H.; KLEIN, L.L.; O’HANLON, R.; CHACKO, S.; GREG, M.; KITCHEN, C.; MILLER, A.J.; LONDO, J.P.Latent developmental and evolutionary shapes embedded within the grapevine leaf. New Phytologist, Cambridge, v.210, p.343–55, 2016.

[8] CHITWOOD, D.H.; OTONI, W.C. Morphometric analysis of Passiflora leaves: the relationship between landmarks of the vasculature and elliptical Fourier descriptors of the blade. GigaScience, Oxford, v.6, n.1, p.1-13, 2017.

[9] DAUZAT, J.; CLOUVEL, P.; LUQUET, D.; MARTIN, P.Using virtual plants to analyse the light-foraging efficiency of a low-density cotton crop. Annals of Botany, London, v.101, p.1153–1166, 2008.

[10] DIAS-FILHO, M.B. Physiologycal response of Solanumcrinitum Lam. to contrasting light environments. Pesquisa Agropececuária Brasileira, v. 32, p.789-796, 1997.

[11] FALSTER, D.S.; WESTOBY, M. Leaf size and angle vary widely across species: what consequences for light interception? New Phytologist, Oxford, v.158, p.509-525, 2003.

[12] FAOSTAT. Crops production. Rome: FAO, 2019. Disponível em: http://www.fao.org/faostat/en/#data/QC/visualize/figs. Acesso em: 25 abr. 2019.
» http://www.fao.org/faostat/en/#data/QC/visualize/figs.

[13] FERRAZ, R.A. Propagação e desempenho agronômico de variedades de figueira (Ficus carica L.) com potencial de cultivo. 2017. Tese (Doutorado) - Faculdade de Ciências Agronômicas, Universidade Estadual Paulista, Botucatu, 2017.

[14] FERREIRA, D. F.. Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência e Agrotecnologia, Lavras, v.38, n.2, p.109-112, 2014.

[15] FRANKHAM, R. Genetics and extinction. Biological Conservation, Oxford, v.126, p.131–140, 2005.

[16] HE, S.L.; HOLLINGSWORTH, P.; YI, T.S.; LI, D.Z. Environmental and historical determinants of patterns of genetic differentiation in wild soybean (Glycine soja Sieb. et Zucc). Scientific Reports, Londres, v.6, p.22795, 2016.

[17] HUANG, P.; FELDMAN, M.; SCHRODER, S.; BAHRI, B.A.; DIAO, X.; ZHI, H.; ESTEP, M.; BAXTER, I.; DEVOS, K.M.; KELLOGG, E.A. Population genetics of Setaria viridis, a new model system. Molecular Ecology, London, v.23, p.4912–4925, 2014.

[18] LAMAS, L.; ELIAS, G.; PEREIRA, R.A.S. Comportamento agressivo em femeas de vespas polinizadoras (Hymenoptera: Agaonidae) de Ficus (Moraceae). In: CONGRESSO DE ECOLOGIA DO BRASIL, 9., 2009. São Lourenço. Anais [...]

[19] MEDEIROS, A.R.M. Figueira (Ficus carica l.) do plantio ao processamento caseiro. Pelotas: Embrapa, 2002. 16p. (Circular técnica, 35).

[20] NIINEMETS, Ü. Photosynthesis and resource distribution through plant canopies. Plant, Cell and Environment, Oxford, v.30, p.1052–1071, 2007.

[21] PAEZ, A.; GEBRE, G.M.; GONZALEZ, M.E.; TSCHAPLINKI, T.J. Growth, soluble carbohydrates,and aloin concentration of Aloe vera plants exposed to three irradiance levels. Environmental and Experimental Botany, v. 44, p. 133-139, 2000.

[22] PALACE, M.; SULLIVAN, F.B.; DUCEY, M.; HERRICK, C. Estimating tropical forest structure using a terrestrial lidar. PLoS One, San Francisco, v.11, n.4, e0154115, 2016.

[23] PEREZ, R.P.A.; DAUZAT, J.; PALLAS, B.; LAMOUR, J.; VERLEY, P.; CALIMAN, J.; COSTES, E.; FAIVRE, R. Designing oil palm architectural ideotypes for optimal light interception and carbon assimilation through a sensitivity analysis of leaf traits, Annals of Botany, London, v.121, n.5, p.909-926, 2018.

[24] PLATT, A.; HORTON, M.; HUANG, Y.S.; LI, Y.; ANASTASIO, A.E.; MULYATI, N.W. The scale of population structure in Arabidopsis thaliana. PLoS Genetics, San Francisco, v.6, n.2, e1000843, 2010.

[25] RAGA, A. Mosca-do-figo. In: REUNIÃO ITINERANTE DE FITOSSANIDADE DO INSTITUTO BIOLÓGICO, 7., 2002, Indaiatuba. Anais [...]. Campinas: Instituto Biológico, 2002. p.54-57.

[26] RAGA, A.; SOUZA FILHO, M.F. DE Captura de Zaprionus indianus (Gupta) (Dip.: Drosophilidae) em frascos de plásticos com iscas alimentares na cultura do figo. Revista Agriculturas, Rio de Janeiro, v.78, n.3, p.323-329, 2003.

[27] RAIJ, B. van.; CANTARELLA, H.; QUAGGIO, J.A.; FURLANI, A.M.C. (ed.). Recomendações de adubação e calagem para o estado de São Paulo. 2.ed.rev. Campinas: IAC,1997. p.45-47 (Boletim Técnico, 100).

[28] RAMALHO, M.A.P.; PINTO, C.A.B.P.; SANTOS, J.B. Genética na agropecuária. 5.ed. Lavras: Editora da UFLA, 2012. 566p.

[29] RIGITANO, O. A figueira cultivada no Estado de São Paulo. 1955. Tese (Doutorado em Fitotecnia) - Escola Superior de Agricultura “Luiz de Queiroz”, Universidade de São Paulo, Piracicaba, 1955.

[30] RODRIGUES, M. G. F.; CORRÊA, L. S.; SANTOS, P.C.; TULMANN NETO, A. Seleção de clones de figueira cv. Roxo-de-Valinhos formados por gemas irrigadas. Revista Brasileira de Fruticultura, Jaboticabal, n.2, v.34, p.604- 611, 2012.

[31] RODRIGUES, M.G.F.; MONTEIRO, L.N.H.; FERREIRA, A.F.A.; PAVAN, B.E.; BOLIANI, A.C. Caracterização morfológica de acessos de banco de germoplasma de figueira. In: CONGRESSO BRASILEIRO DE FRUTICULTURA, 25., 2017. Porto Seguro. Anais [...]. Campos dos Goytacazes: SBF, 2017.

[32] SARLIKIOTI, V.; DE VISSER, P.H.B.; MARCELIS, L.F.M. Exploring the spatial distribution of light interception and photosynthesis of canopies by means of a functional–structural plant model. Annals of Botany, London, v.107, n.5, p.875–883, 2011.

[33] SILVA, D. da; HAN, L.; FAIVRE, R.; COSTES, E. Influence of the variation of geometrical and topological traits on light interception efficiency of apple trees: sensitivity analysis and metamodelling for ideotype definition. Annals of Botany, London, v.114, p.739–752, 2014.

[34] SILVA, L.; MARTINS, C.C.; MACHADO, C.G.; NAKAGAWA, J. Estádios de colheita e repouso pós-colheita dos frutos na qualidade de sementes de mamoneira. Revista Brasileira de Sementes, Londrina, v.31, n.1, p.50-59, 2009.

[35] SONG, Z.C.; MIAO, H.; ZHANG, S.; WANG, Y.; ZHANG, S.P.; GU, X.F.. Genetic Analysis and QTL Mapping of Fruit Peduncle Length in Cucumber (Cucumis sativus L.). PLoS ONE, San Francisco, v.11, n.12, e0167845, 2016.

[36] STOJANOVIC M, PEZO L, LACNJEVAC C, MIHAJLOVIC M, PETROVIC J, MILOJKOVIC J. Biometric approach in selecting plants for phytoaccumulation of uranium. International Journal of Phytoremediation, Boca Raton, v.18, n.5, p.527-533, 2016.

[37] TAKENAKA, A. Effects of leaf blade narrowness and petiole length on the light capture efficiency of a shoot. Ecological Research, Oxford, v.9, p.109–114, 1994.

[38] VALOIS, A.C.C.; NASS, L.L.; GOES, M. Conservação “ex situ” de recursos genéticos vegetais. In: NASS, L.L.; VALOIS, A.C.C.; MELO, I.S.; VALADARES-INGLIS, M.C. (ed.). Recursos genéticos &melhoramento: planta. Rondonópolis: Fundação MT, 2001. p.123-158.

[39] VENDRUSCOLO, C.T. Aceitabilidade de figo (Ficus carica L.) cv. Roxo de Valinhos desidratado com açúcar e SO2. 1988. Dissertação (Mestrado em Ciência e Tecnologia Agroindustrial) - Universidade Federal de Pelotas, Pelotas, 1988.

TRATAMENT	ACESSION	PLACE OF ORIGIN
1	Calimyrna	São José do Rio Preto
2	Nobile	IAC¹
3	Genovesco	IAC¹
4	Roxo-de-Valinhos A	São Sebastião do Paraíso
5	Stanford	IAC¹
6	White Adriatic	IAC¹
7	Bonato	IAC¹
8	White Genova A	São José do Rio Preto
9	White Genova B	IAC¹
10	Smyrna A	IAC¹
11	Smyrna B	São José do Rio Preto
12	Brunswich	IAC¹
13	Caprifig A	IAC¹
14	Pingo de Mel	Ilha Solteira
15	Roxo-de-Valinhos Gigante	Ilha Solteira
16	Palestino	Campinas
17	Troyano	IAC¹
18	Vermelho	Piracicaba
19	PI 440	Ilha Solteira
20	PI 433	Ilha Solteira
21	PI 189	Ilha Solteira
22	PI 214	Ilha Solteira
23	PI 301 (trat6)	Ilha Solteira
24	Nazaret	Espanha
25	Cuello Negro	Espanha
26	Roxo-de-Valinhos B	Ilha Solteira
27	Acesso 27	Monte Alto
28	Acesso 28	Monte Alto
29	Acesso 29	Monte Alto
30	Acesso 30	Monte Alto
31	Acesso 31	Monte Alto
32	Acesso 32	Monte Alto
33	Acesso 33	Monte Alto
34	Acesso 34	Monte Alto
35	Acesso 35	Monte Alto
36	Acesso 36	Monte Alto
37	Acesso 47	Bahia
38	Acesso 44	Piracicaba
39	Acesso 46	Piracicaba
40	Caprifig B	Ilha Solteira
41	Acesso 41	Monte Alto
42	Acesso 42	Monte Alto
43	Mini Figo	IAC¹
44	Preto	Piracicaba
45	Turco	Campinas

TRATAMENT	CP (cm)	CF (cm)	LF (cm)
1	5,42 C	12,58 E	12,17 D
2	7,50 B	15,58 D	14,42 D
3	7,17 B	13,00 E	12,33 D
4	7,42 B	18,00 C	16,08 C
5	5,75 C	21,00 B	19,92 B
6	6,83 B	22,92 B	19,58 B
7	4,88 D	17,42 C	16,55 C
8	7,92 B	18,38 C	17,72 C
9	7,92 B	18,75 C	16,58 C
10	7,55 B	18,08 C	15,97 C
11	7,22 B	15,83 D	15,22 C
12	5,83 C	17,50 C	15,67 C
13	5,67 C	18,58 C	16,92 C
14	6,17 C	16,63 D	15,42 C
15	4,27 D	12,00 E	12,27 D
16	7,33 B	23,52 B	18,17 B
17	6,13 C	20,25 C	17,50 C
18	7,67 B	16,92 D	14,08 D
19	6,17 C	15,50 D	12,75 D
20	7,00 B	11,00 E	11,50 D
21	4,50 D	13,00 E	12,50 D
22	7,50 B	15,00 D	13,00 D
23	7,00 B	12,50 E	12,00 D
24	6,00 C	12,00 E	10,50 D
25	7,00 B	22,00 B	15,00 C
26	5,00 D	12,00 E	9,00 D
27	6,42 C	13,17 E	12,33 D
28	8,75 A	21,58 B	18,92 B
29	7,80 B	19,17 C	15,88 C
30	9,00 A	18,75 C	17,00 C
31	9,67 A	19,83 C	17,00 C
32	7,38 B	16,08 D	14,75 C
33	7,25 B	19,83 C	16,50 C
34	5,08 D	15,00 D	11,50 D
35	8,67 A	19,33 C	16,25 C
36	6,75 B	15,25 D	14,92 C
37	7,83 B	19,00 C	16,33 C
38	7,00 B	15,67 D	13,25 D
39	5,83 C	14,58 D	11,17 D
40	4,75 D	18,83 C	15,75 C
41	6,77 B	14,50 D	12,00 D
42	7,83 B	17,00 D	14,92 C
43	4,42 D	15,25 D	13,83 D
44	6,50 C	16,50 D	13,92 D
45	10,00 A	25,77 A	23,27 A
V.C. (%)	19,50	15,87	15,02
General mean	6,81	17,00	14,94

TRATAMENT	CPE (cm)	CFR (cm)	LFR (cm)
1	7.97 D	28.55 C	22.83 E
2	11.13 D	30.53 B	25.47 D
3	9.03 D	29.73 B	28.55 D
4	9.60 D	35.28 A	34.85 B
5	10.38 D	24.80 D	25.95 D
6	3.37 E	23.53 D	27.72 D
7	9.17 D	25.33 D	22.62 E
8	14.70 C	32.55 A	38.77 A
9	15.48 C	32.02 B	37.07 A
10	14.85 C	29.30 B	28.97 C
11	15.98 C	25.58 D	22.72 E
13	5.78 E	22.47 D	25.58 D
14	17.67 B	28.30 C	26.18 D
15	13.05 C	23.63 D	23.13 E
16	30.97 A	32.30 B	29.80 C
17	21.08 A	29.65 B	28.03 D
18	14.72 C	31.12 B	26.85 D
19	16.42 C	34.33 A	28.48 D
21	14.62 C	30.50 B	29.37 C
22	14.38 C	32.97 A	33.57 B
23	9.00 D	33.73 A	32.97 C
25	12.07 C	27.37 C	20.17 E
26	8.00 D	32.00 B	31.20 C
27	3.70 E	24.72 D	26.48 D
28	6.65 E	27.33 C	30.35 C
29	6.73 E	25.80 D	30.58 C
30	5.92 E	25.38 D	27.07 D
31	7.63 D	27.00 C	29.93 C
32	6.18 E	24.30 D	27.70 D
35	7.17 E	25.75 D	29.18 C
36	5.78 E	27.40 C	28.38 D
37	6.63 E	35.10 A	32.33 C
38	8.57 D	29.80 B	29.00 C
39	6.75 E	31.58 B	30.78 C
40	11.77 D	27.87 C	25.23 D
41	6.93 E	27.23 C	26.57 D
42	7.22 E	24.47 D	27.98 D
43	3.90 E	22.42 D	20.17 E
44	4.13 E	21.67 D	24.70 D
45	5.90 E	31.13 B	32.50 C
V.C. (%)	28.89	11.29	11.42
General mean	10.27	28.36	28.28

Brasil

Brasil

Morphological characterization of active germoplasm bank fig tree accessions

Caracterização morfológica de acessos de banco ativo de germoplasma de figueira

Abstract

Resumo

Introduction

Material and methods

Results and discussion

Conclusion

Acknowledgments

Publication Dates

History