Seed quality of <i>Amburana cearensis</i> (Allemão) A.C. Sm. (Fabaceae) is influenced by storage condition

Araujo, Marcelo do Nascimento; Ferraz, Marisol; Américo, Fabiana Karla Araújo; Silva, Fabrício Francisco Santos; Dantas, Bárbara França; Cruz, Claudineia Regina Pelacani

doi:10.1590/2317-1545v39n4179328

Abstract:

The aim of this study was to evaluate the effects of storage conditions on the germination of A. cearensis seeds. The experimental design was completely randomized into split plots over time with four replicates. The storage conditions of the airtight containers in the refrigerator and laboratory, paper bags in the laboratory and liquid nitrogen were assessed for 27 months. In the laboratory, we evaluated the germination, the germination rate, uniformity of germination, and total soluble and reducing sugars in the radicle. In the greenhouse, we evaluated seedling emergence, emergence rate and height of 30-day-old seedlings. Seeds stored in the refrigerator maintained a high initial germination rate, which decreased from the 21^st month. Seeds stored in paper bags in the laboratory showed low emergence and small seedlings. Total soluble sugars and reducing sugars were mobilized when the seeds were stored at low temperatures. Thus, it is not advisable to store A. cearensis seeds in a laboratory environment without airtight containers. A. cearensis seeds kept in a refrigerated environment maintained their viability for at least two years.

Index terms:
caatinga; conservation; emergence; Leguminosae; umburana-de-cheiro

Resumo:

O objetivo deste trabalho foi avaliar os efeitos das condições de armazenamento sobre a germinação de sementes de A. cearensis. O delineamento experimental foi inteiramente casualizado em parcelas subdivididas ao longo do tempo com quatro repetições. As condições de armazenamento como recipiente hermético no refrigerador; recipiente hermético em laboratório, sacos de papel em laboratório e nitrogênio líquido foram avaliadas durante 27 meses. No laboratório foram avaliadas germinação, taxa de germinação, uniformidade de germinação, açúcares solúveis totais e redutores da radícula. Em casa de vegetação avaliou-se emergência das plântulas, taxa de emergência e altura de mudas no decorrer dos 30 dias. As sementes armazenadas no refrigerador mantiveram alta germinação inicial e diminuíram a partir do 21º mês. O armazenamento de sementes em sacos de papel em laboratório apresentou baixa emergência e menores mudas. Os açúcares solúveis totais e os açúcares redutores são mobilizados quando as sementes são armazenadas a baixas temperaturas. Não é aconselhável armazenar sementes de A. cearensis em ambiente de laboratório sem um recipiente hermético. As sementes de A. cearensis mantidas em ambiente refrigerado mantêm a viabilidade durante pelo menos dois anos.

Termos para indexação:
caatinga; conservação; emergência; Leguminosae; umburana-de-cheiro

Introduction

The Caatinga biome (Brazilian semi-arid vegetation) has a significant biological diversity compared with other semi-arid regions of the world. This biodiversity is extremely important for local communities to which this biome provides timber, food, medicine and forage (Loiola et al., 2012LOIOLA, M.I.B.; ROQUE, A.A.; OLIVEIRA, A.C.P. Caatinga: Vegetação do semiárido brasileiro. Revista Ecologi@: Artigos de Divulgação, v.4, p.14-19, 2012. http://speco.fc.ul.pt/revistaecologia_4.pdf#page=15
http://speco.fc.ul.pt/revistaecologia_4.... ; Santos et al., 2011SANTOS, J.C.; ALMEIDA-CORTEZ, J.S.; FERNANDES, G.W. Diversity of gall-inducing insects in the high altitude wetland forests in Pernambuco, Northeastern Brazil. Brazilian Journal of Biology, v.71, n.1, p.47-56, 2011. http://dx.doi.org/10.1590/S1519-69842011000100008
http://dx.doi.org/10.1590/S1519-69842011... ; Santos et al., 2010SANTOS, M.V.F.D.; LIRA, M.D.A.; JUNIOR, D.; BATISTA, J.C.; GUIM, A.; MELLO, A.C.L.D.; CUNHA, M.V.D. Potential of Caatinga forage plants in ruminant feeding. Revista Brasileira de Zootecnia, v.39, p.204-215, 2010. http://dx.doi.org/10.1590/S1516-35982010001300023
http://dx.doi.org/10.1590/S1516-35982010... ). Uncontrolled exploitation of natural resources of Caatinga has caused severe degradation of vegetation, mainly because of deforestation due to agricultural activities, without allowing species regeneration or reforestation (Farias et al., 2013FARIAS, A.A.; SILVA, M.J.; ALVES, T.L.B.; BARBOSA, M.P.; NETO, J.M.M. Análise das classes de cobertura vegetal no entorno do açude Manoel Marcionílo, Taperoá-PB (Class analysis of vegetation cover in surrounding the weir Manoel Marcionílo, Taperoá-PB). Revista Brasileira de Geografia Física, v.6, n.6, p.1719-1732, 2013. https://periodicos.ufpe.br/revistas/geografiafisica/article/view/12670
https://periodicos.ufpe.br/revistas/geog... ).

This region’s climate presents average temperatures of approximately 26 °C, with little annual variation and rainfall lower than 750 millimetres per year (Costa et al., 2007COSTA, R.C.; ARAUJO, F.S.; LIMA-VERDE, L.W. Flora and life-form spectrum in an area of deciduous thorn woodland (caatinga) in northeastern, Brazil. Journal of Arid Environments, v.68, p.237-247, 2007. http://doi.org/10.1016/j.jaridenv.2006.06.003
http://doi.org/10.1016/j.jaridenv.2006.0... ). The vegetation is conditioned to water deficit throughout the year, which is mainly related to stochastic rainfall events associated with high temperatures and high light intensity, which cause a high evaporative demand and consequent desiccation of the soil (Trovão et al., 2007TROVÃO, D.M.B.M.; FERNANDES, P.D.; ANDRADE, L.A.; NETO, J.D. Variações sazonais de aspectos fisiológicos de espécies da Caatinga. Revista Brasileira de Engenharia Agrícola e Ambiental, v.11, n.3, p.307-311, 2007. http://www.scielo.br/pdf/rbeaa/v11n3/a10v11n3
http://www.scielo.br/pdf/rbeaa/v11n3/a10... ). This climatic instability, together with human occupation, threatens the native biodiversity of Caatinga (Leal et al., 2005LEAL, I.R.; SILVA, J.M.C.; TABARELLI, M.; LACHER-JR., T.E. Changing the course of biodiversity conservation in the Caatinga of Northeastern Brazil. Conservation Biology, v.19, n.3, p.701-706, 2005. 10.1111/j.1523-1739.2005.00703.x ; Lima-Araújo et al., 2007LIMA-ARAÚJO, E.; CASTRO, C.C.; ALBUQUERQUE, U.P. Dynamics of Brazilian Caatinga - A review concerning the plants, environment and people. Functional Ecosystems and Communities, v.1, n.1, p.15-28, 2007. https://www.researchgate.net/profile/Cibele_Castro2/publication/282363215_Dynamics_of_Brazilian_Caatinga_-_A_Review_Concerning_the_Plants_Environment_and_People/links/560e97a608ae0fc513ed8d5e/Dynamics-of-Brazilian-Caatinga-A-Review-Concerning-the-Plants-Environment-and-People.pdf
https://www.researchgate.net/profile/Cib... ). A significant part of Caatinga has suffered from drought since 2011 (Leivas et al., 2014LEIVAS, J.F.; ANDRADE, R.G.; CASTRO VICTORIA, D.; TORRESAN, F.E.; BOLFE, E.L. Monitoramento da seca 2011/2012 no nordeste brasileiro a partir do satélite spot-vegetation e trmm/drought monitoring in 2011/2012 for the brazilian northeast based on the satellite spot-vegetation and trmm. Revista Engenharia na Agricultura, v.22, n.3, p.211-221, 2014. http://search.proquest.com/openview/eddd0926083d224dbeb3e94383b8b499/1?pq-origsite=gscholar&cbl=426377
http://search.proquest.com/openview/eddd... ), leading to lower seedling recruitment, the death of adult trees and loss of biodiversity.

The Amburana cearensis tree is native to South-America, typical of the Caatinga biome and often explored by local populations for its medicinal potential, leading this species to extinction (Pimentel and Guerra, 2010PIMENTEL, J.V.F.; GUERRA, H.O.C. Semiárido, caatinga e legislação ambiental. Prima Facie-Direito, História e Política, v.8, n.14, p.104-126, 2010. http://www.biblionline.ufpb.br/ojs2/index.php/primafacie/article/view/4372
http://www.biblionline.ufpb.br/ojs2/inde... ). It is known for its medicinal properties: the bark and seeds are used to produce popular medications to treat pulmonary diseases, cough, asthma, bronchitis and whooping cough (Maia, 2008MAIA, G.N. Caatinga: árvores e arbustos e suas utilidades. São Paulo: Editora Leitura e Arte, 2008. 413p.). Therefore, A. cearensis is currently listed in the global IUCN list as an endangered species and was listed in the Brazilian national list of endangered species until 2015 (Americas Regional Workshop, 1998AMERICAS REGIONAL WORKSHOP (Conservation & Sustainable Management of Trees, Costa Rica, November 1996) 1998. Amburana cearensis. The IUCN Red List of Threatened Species. Version 2015.2. <http://www.iucnredlist.org>.
http://www.iucnredlist.org... ).

Seed deterioration is inevitable, even when seeds are placed in appropriate preservation environments (Arjmand et al., 2014ARJMAND, H.S.; ABARGHOOEI, G.H.B.; GHORBANPOUR, M.; SHARAFI, S. Effect of zinc coated during storage on the seed quality of barley. International Journal of Farming and Allied Science, v.3, p.845-850, 2014. http://ijfas.com/wp-content/uploads/2014/08/845-850.pdf
http://ijfas.com/wp-content/uploads/2014... ). Factors such as temperature and humidity can influence the process of seed deterioration during storage (Moncaleano-Escandon et al., 2013MONCALEANO-ESCANDON, J.; SILVA, B.C.; SILVA, S.R.; GRANJA, J.A.; ALVES, M.C.J.; POMPELLI, M. F. Germination responses of Jatropha curcas L. seeds to storage and aging. Industrial Crops and Products, v.44, p.684-690, 2013. http://doi.org/10.1016/j.indcrop.2012.08.035
http://doi.org/10.1016/j.indcrop.2012.08... ). Therefore, it is imperative to ascertain, for all species, efficient methods and conditions to store seeds to maintain their viability. Thus, in endangered species, there is an urgent need to determine seed conservation strategies that involve the maintenance of a high level of seed germination, seedling establishment and the preservation of their physiological potential during seed storage. Some studies have reported alternative storage conditions for Caatinga species seeds such as the use of plastic containers in a dry chamber and freezer environments for Caesalpinia pyramidalis (Oliveira et al., 2012OLIVEIRA, L.M.; BRUNO, R.L.A.; SILVA, K.R.G.; ALVES, E.U.; SILVA, G.Z.; ANDRADE, A.P. Qualidade fisiológica de sementes de Caesalpinia pyramidalis Tul. armazenadas. Journal of SeedScience , v.33, n.2, p.289-298, 2012. http://submission.scielo.br/index.php/jss/article/view/36619
http://submission.scielo.br/index.php/js... ); paper, cotton, plastic or aluminium foil bags maintained in a refrigerator or freezer for Myracrodruon urundeuva seeds (Guedes et al., 2012GUEDES, R.S.; ALVES, E.U.; BRUNO, R.L.A.; GONÇALVES, E.P.; COSTA, E.G.; MEDEIROS, M.S. Armazenamento de sementes de Myracrodruon urundeuva Fr. All. em diferentes embalagens e ambientes. Revista Brasileira de Plantas Medicinais, v.14, n.1, p.68-75, 2012. http://www.scielo.br/pdf/rbpm/v14n1/v14n1a10
http://www.scielo.br/pdf/rbpm/v14n1/v14n... ); and maintenance of seeds inside the fruits of Caesalpinia leiostachya (Biruel et al., 2007BIRUEL, R.P.; AGUIAR, I.B.; PAULA, R.C. Germinação de sementes de pau-ferro submetidas a diferentes condições de armazenamento, escarificação química, temperatura e luz. Revista Brasileira de Sementes, v.29, n.3, p.151-159, 2007. http://www.scielo.br/pdf/rbs/v29n3/a18v29n3
http://www.scielo.br/pdf/rbs/v29n3/a18v2... ). However, all of the methods mentioned above show oscillations in seed vigour due to different methods of packing seeds for storage.

To maintain the quality of stored seeds, factors such as seed moisture and storage temperature are important. Although the seed quality cannot be improved during the storage period, it can be maintained for a long period (Zuchi et al., 2013ZUCHI, J.; FRANÇA-NETO, J.B.; SEDIYAMA, C.S.; LACERDA FILHO, A.F.D.; REIS, M.S. Physiological quality of dynamically cooled and stored soybean seeds. Journal of Seed Science , v.35, n.3, p.353-360, 2013. http://dx.doi.org/10.1590/S2317-15372013000300012
http://dx.doi.org/10.1590/S2317-15372013... ). Moreover, to better understand seed behaviour in storage, it is essential to verify factors such as tolerance of these species to low temperatures. Thus, this study aimed to evaluate the quality of A. cearensis seeds in different storage conditions.

Material and Methods

Amburana cearensis seeds used in this experiment were harvested in the Caatinga biome in Lagoa Grande, state of Pernambuco (S 8º34’04,00’’; O 040º10’18,00’’; Figure 1), from dehiscent fruits in August 2013. Fresh seeds were readily evaluated for seed quality and were compared with the stored seeds.

Figure 1
Map of the collecting area (square) in Lagoa Grande / Pernambuco state in Brazil (Made by: Lab Geoprocessing and remote sensing EMBRAPA Semiárido).

Seed storage: Seeds were stored in four different conditions including craft paper bags enclosed in airtight containers in refrigerator (4±3 °C, 60±4% RH), craft paper bags enclosed in airtight container in a laboratory environment (25±4 °C, 19±3% RH), craft paper bags in laboratory environment (25±4 °C, 56±6% RH) and polypropylene tubes in liquid nitrogen (-196 °C). The seeds remained in these conditions for 27 months. Seed samples were removed from each storage condition to evaluate seed quality. Temperature and relative humidity were monitored with a data logger: Hobo data logger - model U10-003. The experimental design was completely randomized in split-plots along time, with four replicates. Four different storage conditions were considered as plots and the storage time was considered as sub plots.

Before storage, all seeds were put in a container with silica gel for 60 min to standardize the water content at approximately 9%. Seeds in cryopreservation were placed in Falcon tubes in a container with liquid nitrogen. Seeds removed from liquid nitrogen were immediately placed in a refrigerator (5±3 °C, 60±4% UR) for 60 min, allowing gradual thawing and relative rewarming of samples (Pritchard and Nadarajan, 2008PRITCHARD, H.W.; NADARAJAN, J. Cryopreservation of orthodox (desiccation tolerant) seeds. In Plant Cryopreservation: A Practical Guide (pp. 485-501). Springer New York. 2008. DOI 10.1007/978-0-387-72276-4_19).

To evaluate the quality of fresh and stored seeds, four replicates of 25 seeds were used in germination and seedling emergence tests and quantifying sugar metabolism in germinating seeds during 27 months.

Water content: The water content was determined by the oven method at 105±3 °C for 24 hours, using two samples of 10 seeds and the results were expressed as a percentage based on the seed fresh weight (Brasil, 2013BRASIL, Ministério da Agricultura, Pecuária e Abastecimento. Instruções para análise de sementes de espécies florestais, de 17 de janeiro de 2013, Brasília: MAPA, 2013. 98 p. http://www.agricultura.gov.br/assuntos/insumos-agropecuarios/arquivos-publicacoes-insumos/2946_regras_analise__sementes.pdf
http://www.agricultura.gov.br/assuntos/i... ).

Germination test: Were carried out on germination paper soaked with distilled water at a proportion of 2.5 times the dry paper weight. Seeds were germinated in a BOD chamber at 30 °C with a 12-hour photoperiod (Brasil, 2013BRASIL, Ministério da Agricultura, Pecuária e Abastecimento. Instruções para análise de sementes de espécies florestais, de 17 de janeiro de 2013, Brasília: MAPA, 2013. 98 p. http://www.agricultura.gov.br/assuntos/insumos-agropecuarios/arquivos-publicacoes-insumos/2946_regras_analise__sementes.pdf
http://www.agricultura.gov.br/assuntos/i... ). Seed germination scoring was performed daily until seedling establishment, which occurred after approximately 15 days. The seeds were considered as germinated at 1 mm radicle emergence.

Final germination (FG, %); germination uniformity (GU; time elapsed between 20% and 80% germination, days^-2) and germination rate (reciprocal of time to reach 50% of final germination, GR, days^-1) were also estimated (Toorop et al., 2012TOOROP, P.E.; CUERVA, R.C.; BEGG, G.S.; LOCARDI, B.; SQUIRE, G.R.; IANNETTA, P.P. Co-adaptation of seed dormancy and flowering time in the arable weed Capsella bursa-pastoris (shepherd’s purse). Annals of Botany, v.109, p.481-489, 2012. https://doi.org/10.1093/aob/mcr301
https://doi.org/10.1093/aob/mcr301... ).

Seedling emergence test: These tests were performed by sowing fresh and stored seeds in polystyrene trays containing the commercial substrate Plantmax® and arranging the trays in a greenhouse with a controlled environment (40% luminosity with black shading screens and manual irrigation according to plant requirements). The emergence was evaluated daily for 30 days (Brasil, 2013BRASIL, Ministério da Agricultura, Pecuária e Abastecimento. Instruções para análise de sementes de espécies florestais, de 17 de janeiro de 2013, Brasília: MAPA, 2013. 98 p. http://www.agricultura.gov.br/assuntos/insumos-agropecuarios/arquivos-publicacoes-insumos/2946_regras_analise__sementes.pdf
http://www.agricultura.gov.br/assuntos/i... ), and final emergence (FE, %), emergence rate (reciprocal of time to reach 50% of final emergence, ER, days^-1) and average 30 days seedling height (SH) were calculated.

Total soluble sugars and reducing sugars quantification: The extractions were performed by grinding a 0.5 g root sample (c. 10 seedlings) in a sterile mortar with 10 mL of distilled water. The mixture was centrifuged at 3.000 x g for 20 minutes without refrigeration. The supernatant was collected to microtubes and kept in a freezer at -20 °C until reducing sugars (Miller, 1959MILLER, G.L. Use of dinitrosalicylic acid reagent for determination of reducing sugar. Analytical Chemistry, v.31, n.3, p.426-428, 1959. http://nsrdec.natick.army.mil/LIBRARY/59-69/R59-36.pdf
http://nsrdec.natick.army.mil/LIBRARY/59... ) and total soluble sugars (Morris, 1948MORRIS, D.L. Quantitative determination of carbohydrates with Dreywood´s anthrone reagent. Science, v.107, p.254-255, 1948. https://www.ncbi.nlm.nih.gov/ pubmed/17814729
https://www.ncbi.nlm.nih.gov/ pubmed/178... ; Yemm and Willis, 1954YEMM, E.W.; WILLIS, A.J. The estimation of carbohydrates in plants extracts by anthrone. Biochemistry Journal, v.57, p.508-514, 1954. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1269789/
https://www.ncbi.nlm.nih.gov/pmc/article... ) assays. Four replicates of each sample were maintained.

Statistical analysis: Data were tested for normality and homogeneity of variance before comparing means using the Shapiro-Wilk and Levene’s tests, both at 0.05 probability level. Non-normal percentage data were arcsine-transformed and re-tested. Continuing non-normal data were analysed by the non-parametric Kruskal-Wallis test at 0.05 probability level. For normal data, the Tukey test was used at 0.05 probability level. Fresh seeds were compared with stored seeds by the Dunnett (normal data) and Kruskal-Wallis (non-normal data) tests at 0.05 probability level.

Results and Discussions

A. cearensis seeds showed an initial water content of 9.2%, which did not change during storage, regardless of the conditions.

Germination (FG), germination rate (GR), emergence (FE), emergence rate (ER) and total soluble sugars (TSS) data were not normally distributed and/or were not homogeneous, and therefore, the media test used was Kruskal-Wallis.

Storage conditions influenced the germination behaviour of A. cearensis seeds. Seeds from the laboratory environment packed only in paper bags showed decreased FG in the 27^th month differing statistically from fresh seeds and 6-months of storage. Seeds kept in airtight containers in the refrigerator and laboratory did not show germination differences compared to fresh seeds over time. Seeds stored in liquid nitrogen showed different FG compared with fresh seeds and storage conditions with airtight container in the 24^th month (Table 1).

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Table 1
Final germination (%) of A. cearensis seeds in different storage conditions and times of storages.

Amburana cearensis seeds kept in the laboratory without a container showed decreased GR (high-speed germination), and this difference was statistically significant compared with seeds kept in airtight containers in the laboratory in the 27^th month of storage. Except for the 12^th month, the seeds stored in the laboratory without a container (which can be attributed to an outlier) did not show differences in GR compared with fresh seeds. Moreover, there were differences between seeds stored in the laboratory without a container and those in liquid nitrogen (N₂) container at 6 and 12 months (Table 2).

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Table 2
Germination rate (days^-1) of A. cearensis seeds in different storage conditions and times of storage.

The GU of seeds in liquid nitrogen differed from that of fresh seeds as of 12^th month and showed slow germination, which was twice as slow compared with that of fresh seeds (Table 3).

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Table 3
Germination uniformity (day^-1) of A. cearensis seeds in different storage conditions and times of storage.

FE percentage in the greenhouse conditions for A. cearensis stored seeds showed that the refrigerator-stored seeds maintained their vigour in comparison to fresh seeds and over storage time. Seeds stored in the laboratory environment, packed in paper bags and in a liquid nitrogen container showed lower FE percentage than fresh seeds in the 21^st month of storage. Following similar behaviour, A. cearensis seeds stored in airtight containers in a laboratory environment showed a reduction in the values in the 21^st month of storage and showed differences compared to fresh seeds in the 24^th and 27^th months (Table 4).

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Table 4
Final emergence (%) of A. cearensis seeds in different storage conditions and times of storage.

Regarding ER and seedlings height (SH) of stored seeds in the laboratory without a container, the latter two storage evaluations were different compared with fresh seeds and the former two storage evaluations (Tables 5 and 6). We also noticed this trend in the SH of seeds kept in a container in the laboratory (Table 6). There were also significant losses in SH between months 9 and 12 for seeds maintained in the laboratory environment (with and without airtight container).

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Table 5
Emergence rate (days^-1) of A. cearensis seeds in different storage conditions and times of storage.

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Table 6
Seedling height (cm^-1) of A. cearensis seeds under different storage conditions and times of storage.

In all storage conditions, the roots of A. cearensis seedlings showed a slight decrease in TSS content until the 21^st month, with lower values followed by an increase up to the last evaluation month. Among all storage conditions, no differences were observed in the levels of TSS in stored seeds compared to fresh seeds (Table 7).

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Table 7
Total soluble sugars (TSS, µmol.mg^-1.fw) of A. cearensis seedlings’ roots in different storage conditions and times of storage.

Seeds in liquid N₂ also differed in ER and SH compared with the two former storage evaluations. However, the differences in ER were observed only in the 12^th month, and the latest storage evaluation of SH differed from that of the fresh seeds (Tables 5 and 6).

Reducing sugars (RS) content in the liquid nitrogen stored seeds reached higher values at 21 months of storage compared with roots of fresh seeds and seeds stored in the laboratory without a container (determined by Dunnett’s test). The RS content of the roots of seeds stored in the laboratory without container showed significantly lower values in the 12^th month compared with the former two storage evaluations (Table 8).

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Table 8
Reducing sugar (RS, µmol.mg^-1.fw) of A. cearensis seedlings’ roots in different storage conditions and times of storage.

Seeds of A. cearensis support a water content as low as 5.27% (Lúcio et al., 2016LÚCIO, A.A.; ARAUJO, M.N.; SILVA, F.F.S.; DANTAS, B.F. Effect of storage in different environments and packages on germination of Amburana cearensis (Allemao) A. C. Sm. seeds. International Journal of Environment, Agriculture and Biotechnology (IJEAB), v.1, n.4, p.1037-1040, 2016. http://dx.doi.org/10.22161/ijeab/1.4.57
http://dx.doi.org/10.22161/ijeab/1.4.57... ) during storage; thus, they have an orthodox behaviour that allows their storage for a long period of low temperatures and relative humidity (Galíndez et al., 2015GALÍNDEZ, G.; MALAGRINA, G.; CECCATO, D.; LEDESMA, T.; LINDOW-LÓPEZ, L.; BAES, P.O. Dormición física y conservación ex situ de semillas de Amburana cearensis y Myroxylon peruiferum (Fabaceae). Boletín de la Sociedad Argentina de Botánica, v.50, n.2, p.153-161, 2015. http://www.scielo.org.ar/scielo.php?script=sci_arttext&pid=S1851-23722015000200003
http://www.scielo.org.ar/scielo.php?scri... ), with a reduced respiratory rate (Nascimento, 2009NASCIMENTO, W.M. (Org.). Tecnologia de sementes de hortaliças. Brasília, DF: Embrapa Hortaliças, 2009. 432 p.). The water content of A. cearensis seeds in this study was the same (9.2%) in all storage environments. Guedes et al. (2010GUEDES, R. S.; ALVES, E.U.; GONÇALVES, E.P.; VIANA, J.S.; FRANÇA, P.R.C.; SILVA SANTOS, S. Qualidade fisiológica de sementes armazenadas de Amburana cearensis (Allemão) A.C. Smith. Semina: Ciências Agrárias, v.31, n.2, p.331-342, 2010. https://www.researchgate.net/profile/Roberta_Guedes/publication/46575897_Physiological_quality_of_Amburana_cearensis_Allemao_AC_Smith_seeds_stored_Qualidade_fisiologica_de_sementes_armazenadas_de_Amburana_cearensis_Allemao_AC_Smith/links/564090d608aef2be8e051696.pdf
https://www.researchgate.net/profile/Rob... ) observed values ranging from 6.25 to 15.89% in seeds kept in the laboratory and 6.31 to 9.52% in seeds stored in the refrigerator; the worst emergence values were attributed to a high water content.

Storage method in a laboratory environment without an airtight container reduced the FG and GR compared with the fresh seeds and those stored in the laboratory in airtight containers respectively. Irrespective of the differences in FG and GR, A. cearensis seed germination was higher than 70% and demonstrated the capacity of survival even with high temperature and relative humidity (RH) oscillations based on the average daily oscillations. Therefore, A. cearensis seeds stored in airtight containers and, consequently without variations in RH, were not influenced by daily temperature fluctuations and did not lose their viability. The laboratory seeds exposed to natural environment showed decreasing viability over time (Guedes et al., 2012GUEDES, R.S.; ALVES, E.U.; BRUNO, R.L.A.; GONÇALVES, E.P.; COSTA, E.G.; MEDEIROS, M.S. Armazenamento de sementes de Myracrodruon urundeuva Fr. All. em diferentes embalagens e ambientes. Revista Brasileira de Plantas Medicinais, v.14, n.1, p.68-75, 2012. http://www.scielo.br/pdf/rbpm/v14n1/v14n1a10
http://www.scielo.br/pdf/rbpm/v14n1/v14n... ). The laboratory seeds exposed to natural environment showed decreasing viability over time (Guedes et al., 2012). In laboratory conditions, the combination of high temperatures and RH can cause damage to A. cearensis seeds, by decreasing vigour and favouring the development of harmful microorganisms. In this way, only highly vigorous seeds are likely to survive.

The lower FG of seeds stored in liquid N₂, after 24 months of storage, could be attributed to the time of withdrawal of the seeds from the N₂ flasks to the refrigerator. The seeds were observed to have tissue disruption during thawing when they were removed from liquid N₂ (Table 1).

Difference on the time between first and last 20% of germinated seeds (GU) as of the 12^th month in liquid N₂ stored seeds compared with fresh seeds could be explained by the viability loss at low storage temperature. The low storage temperature induced greater germination uniformity with potentially delayed values that suggest a capacity for wide spread germination over time over by a natural need of survival of the species (Table 3). Notwithstanding the differences presented in relation to fresh seeds, the values obtained in N₂ did not differ significantly from those in other treatments.

Amburana cearensis seeds had high viability with 90% of germination in the 27^th month for seeds stored in airtight containers in the laboratory and liquid N₂ and showed low emergence for this same period in the field. FE was demonstrated to be a good test to determine the deteriorated or low seed vigour seed because the FE test is thinner (detectable) and easily determines the seed vigour of A. cearensis seeds. Many authors support the possibility of a relationship between emergence and seed vigour (Demir et al., 2008DEMIR, I.; ERMIS, S.; MAVI, K.; MATTHEWS, S. Mean germination time of pepper seed lots (Capsicum annuum L.) predicts size and uniformity of seedlings in germination tests and transplant modules. Seed Science and Technology, v.36, n.1, p.21-30, 2008. https://doi.org/10.15258/sst.2008.36.1.02
https://doi.org/10.15258/sst.2008.36.1.0... ; Milošević et al., 2010MILOŠEVIĆ, M.; VUJAKOVIĆ, M.; KARAGIĆ, Đ. Vigour tests as indicators of seed viability. Genetika, v.42, n.1, p.103-118, 2010. https://doi.org/10.2298/GENSR1001103M
https://doi.org/10.2298/GENSR1001103M... ; Perveen et al., 2010PERVEEN, S.; NIGAR, S.; KHALIL, S.; ZUBAIR, M. Vigor tests used to rank seed lot quality and predict field emergence in wheat. Pakistan Journal of Botany, v.42, n.5, p.3147-3155, 2010. DOI: 10.3923/ajpp.2007.311.317
https://doi.org/10.3923/ajpp.2007.311.31... ). For example, FE can also be used to separate accessions for use in reforestation and conservation.

Higher RH in the laboratory could be responsible for differences in vigour for the ER of seeds stored without containers, which may be influenced at the end of the storage period by the non-environmental control during the storage period (Table 5). Seed vigour is associated with the deterioration process (Shelar et al., 2008SHELAR, V.R.; SHAIKH, R.S.; NIKAM, A.S. Soybean seed quality during storage: a review. Agricultural Reviews, v.29, n.2, p.125-131, 2008. http://www.arccjournals.com/uploads/articles/ar292006.pdf
http://www.arccjournals.com/uploads/arti... ), which may have occurred in seeds stored in the laboratory outside of the airtight containers.

Reserve mobilization in the A. cearensis germinated seeds was directly influenced by the ultra-low storage temperatures (Tables 7 and 8). These results evidenced the mobilization of reserve compounds in the cotyledons (source) and their translocation to the root (drain) when the seeds were stored at low temperatures in the last 3 storage periods evaluated. Therefore, the selective mobilization of sugars at low temperatures can be highlighted, and their levels could be attributed to stress factors.

Storing seeds in airtight containers in a laboratory environment can maintain their quality for at least one year (Table 4). This allows the maintenance of high seed vigour until seedling production in nurseries for reforestation in the next rainy season. Seeds should be kept well preserved at least until the next season, which is the period when flowering generally occurs. Under laboratory environments, seeds typically lose their viability within months (Barbedo et al., 2002BARBEDO, C.J.; BILIA, D.A.; FIGUEIREDO-RIBEIRO, R.C. Tolerância à dessecação e armazenamento de sementes de Caesalpinia echinata Lam.(pau-brasil), espécie da Mata Atlântica. Revista Brasileira de Botânica, v.25, n.4, p.431-439, 2002. http://www.scielo.br/pdf/%0D/rbb/v25n4/a07v25n4.pdf.
http://www.scielo.br/pdf/%0D/rbb/v25n4/a... ), and Caatinga seedlings can only be sown at a specific time (January to May) of soil water availability (Meiado et al., 2012MEIADO, M.V.; SILVA, F.F.S.; CARVALHO, D.C.A.; SIQUEIRA FILHO, J.A. Diaspore of the caatinga: a review. Flora of the Caatingas of the São Francisco River: Natural History and Conservation. Rio de Janeiro: Andrea Jakobsson Estúdio Editorial, 2012. p.306-365.). Therefore, these studies, through the response of germinability time, allow progress in our understanding of seed storage. Moreover, cryopreservation and defrosting techniques should be improved for this species.

Conclusions

It is not advisable to store A. cearensis seeds in a laboratory environment without airtight containers.

Amburana cearensis seeds kept in a refrigerated environment maintain their viability for at least two years.

Mobilization of reserve compounds is directly influenced when seeds are stored at low temperatures.

Acknowledgements

The authors would like to thank the CAPES / EMBRAPA (BEX 4133/14-5) and Fapesb scholarship, for all support during the production of this work.

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Publication Dates

Publication in this collection
Oct-Dec 2017

History

Received
02 May 2017
Accepted
07 Aug 2017

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[1] AMERICAS REGIONAL WORKSHOP (Conservation & Sustainable Management of Trees, Costa Rica, November 1996) 1998. Amburana cearensis The IUCN Red List of Threatened Species. Version 2015.2. <http://www.iucnredlist.org>.
» http://www.iucnredlist.org

[2] ARJMAND, H.S.; ABARGHOOEI, G.H.B.; GHORBANPOUR, M.; SHARAFI, S. Effect of zinc coated during storage on the seed quality of barley. International Journal of Farming and Allied Science, v.3, p.845-850, 2014. http://ijfas.com/wp-content/uploads/2014/08/845-850.pdf
» http://ijfas.com/wp-content/uploads/2014/08/845-850.pdf

[3] BARBEDO, C.J.; BILIA, D.A.; FIGUEIREDO-RIBEIRO, R.C. Tolerância à dessecação e armazenamento de sementes de Caesalpinia echinata Lam.(pau-brasil), espécie da Mata Atlântica. Revista Brasileira de Botânica, v.25, n.4, p.431-439, 2002. http://www.scielo.br/pdf/%0D/rbb/v25n4/a07v25n4.pdf.
» http://www.scielo.br/pdf/%0D/rbb/v25n4/a07v25n4.pdf.

[4] BIRUEL, R.P.; AGUIAR, I.B.; PAULA, R.C. Germinação de sementes de pau-ferro submetidas a diferentes condições de armazenamento, escarificação química, temperatura e luz. Revista Brasileira de Sementes, v.29, n.3, p.151-159, 2007. http://www.scielo.br/pdf/rbs/v29n3/a18v29n3
» http://www.scielo.br/pdf/rbs/v29n3/a18v29n3

[5] BRASIL, Ministério da Agricultura, Pecuária e Abastecimento. Instruções para análise de sementes de espécies florestais, de 17 de janeiro de 2013, Brasília: MAPA, 2013. 98 p. http://www.agricultura.gov.br/assuntos/insumos-agropecuarios/arquivos-publicacoes-insumos/2946_regras_analise__sementes.pdf
» http://www.agricultura.gov.br/assuntos/insumos-agropecuarios/arquivos-publicacoes-insumos/2946_regras_analise__sementes.pdf

[6] COSTA, R.C.; ARAUJO, F.S.; LIMA-VERDE, L.W. Flora and life-form spectrum in an area of deciduous thorn woodland (caatinga) in northeastern, Brazil. Journal of Arid Environments, v.68, p.237-247, 2007. http://doi.org/10.1016/j.jaridenv.2006.06.003
» http://doi.org/10.1016/j.jaridenv.2006.06.003

[7] DEMIR, I.; ERMIS, S.; MAVI, K.; MATTHEWS, S. Mean germination time of pepper seed lots (Capsicum annuum L.) predicts size and uniformity of seedlings in germination tests and transplant modules. Seed Science and Technology, v.36, n.1, p.21-30, 2008. https://doi.org/10.15258/sst.2008.36.1.02
» https://doi.org/10.15258/sst.2008.36.1.02

[8] FARIAS, A.A.; SILVA, M.J.; ALVES, T.L.B.; BARBOSA, M.P.; NETO, J.M.M. Análise das classes de cobertura vegetal no entorno do açude Manoel Marcionílo, Taperoá-PB (Class analysis of vegetation cover in surrounding the weir Manoel Marcionílo, Taperoá-PB). Revista Brasileira de Geografia Física, v.6, n.6, p.1719-1732, 2013. https://periodicos.ufpe.br/revistas/geografiafisica/article/view/12670
» https://periodicos.ufpe.br/revistas/geografiafisica/article/view/12670

[9] GALÍNDEZ, G.; MALAGRINA, G.; CECCATO, D.; LEDESMA, T.; LINDOW-LÓPEZ, L.; BAES, P.O. Dormición física y conservación ex situ de semillas de Amburana cearensis y Myroxylon peruiferum (Fabaceae). Boletín de la Sociedad Argentina de Botánica, v.50, n.2, p.153-161, 2015. http://www.scielo.org.ar/scielo.php?script=sci_arttext&pid=S1851-23722015000200003
» http://www.scielo.org.ar/scielo.php?script=sci_arttext&pid=S1851-23722015000200003

[10] GUEDES, R. S.; ALVES, E.U.; GONÇALVES, E.P.; VIANA, J.S.; FRANÇA, P.R.C.; SILVA SANTOS, S. Qualidade fisiológica de sementes armazenadas de Amburana cearensis (Allemão) A.C. Smith. Semina: Ciências Agrárias, v.31, n.2, p.331-342, 2010. https://www.researchgate.net/profile/Roberta_Guedes/publication/46575897_Physiological_quality_of_Amburana_cearensis_Allemao_AC_Smith_seeds_stored_Qualidade_fisiologica_de_sementes_armazenadas_de_Amburana_cearensis_Allemao_AC_Smith/links/564090d608aef2be8e051696.pdf
» https://www.researchgate.net/profile/Roberta_Guedes/publication/46575897_Physiological_quality_of_Amburana_cearensis_Allemao_AC_Smith_seeds_stored_Qualidade_fisiologica_de_sementes_armazenadas_de_Amburana_cearensis_Allemao_AC_Smith/links/564090d608aef2be8e051696.pdf

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Time Storage (Months)	Storage conditions
Time Storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	98.0
6	90.0 Aa	87.5 Aa	98.0 Aa	87.0 Aa
9	93.0 Aa	93.0 Aa	93.0 Aab	83.0 Aa
12	94.0 Aa	91.0 Aa	94.0 Aab	87.0 Aa
21	92.7 Aa	90.0 Aa	82.0 Aab	85.0 Aa
24	94.0 Aa	95.0 Aa	83.0 ABab	•72.0 Ba
27	90.7 Aa	90.0 Aa	•76.0 Ab	90.0 Aa
CV% = 7.70; W= 0.98ns; F= 2.29**

Time Storage (Months)	Storage conditions
Time Storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	0.188
6	0.154 ABa	0.150 ABa	0.185 Aab	0.143 Ba
9	0.155 Aa	0.181 Aa	0.195 Aab	0.173 Aa
12	0.174 ABa	0.198 ABa	•0.236 Aa	0.162 Ba
21	0.152 Aa	0.153 Aa	0.150 Aab	0.164 Aa
24	0.170 Aa	0.171 Aa	0.147 Ab	0.144 Aa
27	0.170 ABa	0.177 Aa	0.130 Bb	0.142 ABa
CV% = 10.28; W= 0.97; F= 1.87

Time storage (Months)	Storage conditions
Time storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	2.53
6	3.61 Aa	3.69 Aa	2.62 Aa	3.70 Aa
9	4.36 Aa	3.45 Aa	3.53 Aa	3.96 Aa
12	3.85 Aa	3.24 Aa	1.95 Aa	•5.18 Aa
21	4.34 Aa	3.57 Aa	2.82 Aa	•5.10 Aa
24	3.60 Aa	3.04 Aa	3.19 Aa	•4.87 Aa
27	4.07 Aa	2.46 Aa	3.70 Aa	•4.96 Aa
CV% = 23.80; W= 0.99ns; F= 1.39ns

Time storage (Months)	Storage conditions
Time storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	81.25
6	80.0 Aa	62.5 ABa	43.7 Ba	56.7 ABa
9	77.5 Aa	61.2 Aa	48.8 Aa	56.7 Aa
12	77.5 Aa	72.5 Aa	48.7 Aa	63.7 Aa
21	64.4 Aa	•31.4 Aa	•30.5 Aa	•35.0 Aa
24	65.7 Aa	40.0 ABa	•21.5 Ba	•38.7 ABa
27	63.0 Aa	•35.0 ABa	•20.0 Ba	•33.7 ABa
CV% = 25.16; W= 0.97; F= 2.04

Time Storage (Months)	Storage conditions
Time Storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	0.0668
6	0.0660 ABa	0.0698 ABab	0.0720 Aa	0.0623 Ba
9	0.0679 Aa	0.0728 Aa	0.0741 Aa	0.0681 Aa
12	0.0597 Aa	0.0594 Ab	0.0585 Aab	•0.0552 Aab
21	0.0628 Aa	0.0594 Aab	0.0585 Aab	0.0650 Aab
24	0.0560 Aa	0.0561 Aab	•0.0485 Bb	0.0581 Ab
27	0.0571 ABa	0.0594 Aab	•0.0487 Bb	0.0596 ABb
CV% = 6.50; W= 0.97; F= 1.90

Brasil

Brasil

Seed quality of Amburana cearensis (Allemão) A.C. Sm. (Fabaceae) is influenced by storage condition

A qualidade de sementes de Amburana cearensis (Allemão) A.C. Sm. (Fabaceae) é influenciada pelas condições de armazenamento

Abstract:

Resumo:

Introduction

Material and Methods

Results and Discussions

Conclusions

Acknowledgements

References

Publication Dates

History

Time Storage (Months)	Storage conditions
Time Storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	12.4
6	10.8 Bb	12.9 Aab	12.9 Aab	12.5 Aab
9	13.8 Aa	14.1 Aa	14.6 Aa	14.4 Aa
12	12.3 Aab	11.1 Abc	12.0 Ab	11.5 Abc
21	12.1 Aab	12.9 Aab	11.2 Ab	12.8 Aab
24	10.7 Ab	•9.4 ABc	•7.8 Bc	10.6 Abc
27	11.1 Ab	•9.8 ABc	•8.1 Bc	•9.9 ABc
CV% = 9.60; W= 0.98ns; F= 1.49ns

Time Storage (Months)	Storage conditions
Time Storage (Months)	Airtight container in Refrigerator	Airtight container in Laboratory	Laboratory without container	Liquid nitrogen (N₂) container
0	177.9
6	•273.5 Aa	185.4 Bab	229.6 ABa	228.2 ABbc
9	•246.3 Aab	202.4 Aa	•240.7 Aa	207.2 Acd
12	158.2 Ad	179.7 Aab	153.7 Ab	156.9 Ad
21	177.8 Bcd	148.9 Bb	160.7 Bb	•276.2 Aab
24	166.6 Bcd	207.5 Ba	172.5 Bb	•295.6 Aa
27	212.8 Abc	215.5 Aa	159.4 Bb	•260.5 Aabc
CV% = 13.48; W= 0.99ns; F= 1.39ns