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Effect of the seed coat on dormancy and germination in Stylosanthes humilis H. B. K. Seeds

Efeito do tegumento na dormência e na germinação de sementes de Stylosanthes humilis H. B. K.

Abstract:

Seed of Townsville stylo (Stylosanthes humilis H.B.K.) is known to exhibit a hard seed coat and when freshly harvested also show a physiological dormancy, however, the nature of the co-actions between seed coat and embryo growth that determine dormancy is poorly understood. In this study, physical dormancy of Townsville stylo seeds was not reduced during natural ageing at room temperature, in contrast to the physiological dormancy, which is gradually overcome during after-ripening. Furthermore, the permeability of seed coat was affected by scarification treatments as well as by low-pH solutions. Together, these data indicate that physical dormancy overcome of seed is prerequisite for radicle protrusion and physiological dormancy of Townsville stylo seeds contribute to its timing.

Index terms:
physical dormancy; physiological dormancy; Townsville stylo

Resumo:

Semente de estilosantes (Stylosanthes humilis H.B.K.) é conhecida por apresentar tegumento rijo e quando recém colhida também exibe dormência fisiológica, entretanto, a natureza da coação entre o tegumento e o crescimento do embrião que determina a sua dormência é pouco conhecida. Nesse estudo, a dormência física de sementes de estilosantes não foi reduzida durante o envelhecimento natural à temperatura ambiente, em contraste com a dormência fisiológica que foi superada gradualmente durante o envelhecimento pós-colheita. Além disso, a permeabilidade do tegumento foi afetada por tratamentos de escarificação bem como por soluções de baixo pH. Juntos, esses resultados indicam que a superação da dormência física da semente é um pré-requisito para a protrusão da radícula e a dormência fisiológica das sementes de estilosantes contribui para temporização da germinação.

Termo para indexação:
dormência física; dormência fisiológica; estilosante

Introduction

Townsville stylo (Stylosanthes humilis H.B.K.) is an annual forage legume common in natural pastures of tropical America (Williams et al., 1984WILLIAMS, R.J.; REID, R.; SCHULTZE-KRAFT, R.; SOUZA COSTA, N.M.; THOMAS, B.D. Natural distribution of Stylosanthes. In: STACE, H.M.; EDYE, L.A. (Eds.) The biology and agronomy of Stylosanthes. Sydney: Academic Press, p.73-101, 1984.; Stappen et al., 2000STAPPEN, J.V.; WELTJENS, I.; LOPEZ, S.G.; VOLCKAERT, G. Genetic diversity in Mexican Stylosanthes humilis as revealed by AFLP, compared to the variability of S. humilis accessions of South American origin. Euphytica, v.113, p.145-154, 2000. http://link.springer.com/article/10.1023%2FA%3A1003989505449
http://link.springer.com/article/10.1023...
;Santos-Garcia et al., 2012SANTOS-GARCIA, M.O.; TOLEDO-SILVA, G., SASSAKI, R.P.; FERREIRA, T.H.; RESENDE R.M.S.; CHIARI, L.; KARIA, C.T.; CARVALHO, M.A.; FALEIRO, F.B.; ZUCCHI, M.I.; SOUZA, A.P. Using genetic diversity information to establish core collections ofStylosanthes capitataand Stylosanthes macrocephala.Genetics and Molecular Biology, v.35, n.4, p.847-861, 2012. http://ncbi.nlm.nih.gov/pubmed/23271947
http://ncbi.nlm.nih.gov/pubmed/23271947...
). The species is utilizing for pasture improvement in tropical zones due to its high-quality forage for livestock, high seed production, and wide adaptability to low fertility soils (Edye, 1987EDYE, L.A. Potential of Stylosanthes for improving tropical grasslands. Outlook on Agriculture, v.16, p.124-130, 1987. http://agris.fao.org/agris-search/search.do?recordID=US201302062481
http://agris.fao.org/agris-search/search...
). In addition, Stylosanthes are potentially useful species aiming at ecological purposes, such as rehabilitation of damaged ecosystems (Grigg et al., 2000GRIGG, A.; SHELTON, M.; MULLEN, B. The nature and management of rehabilitated pastures on open-cut coal mines in central Queensland. Tropical Grasslands, v.34, p.242-250, 2000. http://tropicalgrasslands.asn.au/Tropical%20Grasslands%20Journal%20archive/PDFs/Vol_34_2000/Vol_34_03-04_00_pp242_250.pdf
http://tropicalgrasslands.asn.au/Tropica...
; Starr et al., 2013STARR, C.R.; CORREA, R.S.; FILGUEIRAS, T.S.; HAY, J.D.V.; SANTOS, P.F. Plant colonization in a gravel mine revegetated with Sthyloshantes spp. in a Neotropical area savannah. Landscape and Ecological Engineering, v.9, n.1, p.189-201, 2013. http://link.springer.com/article/10.1007%2Fs11355-012-0196-1
http://link.springer.com/article/10.1007...
). Seeds of Townsville stylo exhibit a physiological dormancy, which is gradually lost upon post-harvest ageing. Following harvesting physiological dormancy is lost very slowly; by six months germination increases substantially, and 12-15 after harvest seeds placed under a 30/25 oC day/night cycle with 60/70% relative humidity showed full germination (Vieira and Barros, 1994VIEIRA, H.D.; BARROS, R.S. Response of seed of Stylosanthes humilis to germination regulators. Physiologia Plantarum, v.92, p.17-20, 1994. http://scielo.br/scielo.php?script=sci_arttext&pid=S1677-04202004000200003
http://scielo.br/scielo.php?script=sci_a...
). Any stressing factor such as low pH solutions (Pelacani et al., 2005aPELACANI, C.R.; BARROS, R.S.; RIBEIRO, D.M.; FRIGERI R.B.C. Breaking dormancy of Stylosanthes humilis seeds with low pH solutions. Acta Physiologiae Plantarum, v.27, p.317-323, 2005a. http://Link.springer.com/article/10.1007/s11738-005-0016-4
http://Link.springer.com/article/10.1007...
,b), selenium compounds (Pinheiro et al., 2008PINHEIRO, F.J.A.; BARROS, R.S.; COELHO, T.G.; SOUZA, B.M.L. Breaking dormancy of Stylosanthes humilis seeds with selenium compounds. Seed Science Research , v.18, p.47-53, 2008. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=1696060
http://journals.cambridge.org/action/dis...
) and ferric ions (Ribeiro et al., 2011RIBEIRO, D.M.; MAPELI, A.M; DELATORRE, C.A.; CARNELOSSI, M.A.G.; BARROS, R.S. Action of ferric and aluminium ions on the dormancy breakage of Stylosanthes humilis seeds. Acta Physiologiae Plantarum , v.33, p.2117-2123, 2011. http://link.springer.com/article/10.1007%2Fs11738-011-0750-8
http://link.springer.com/article/10.1007...
), which induced ethylene production by seeds, promotes the overcome of physiological dormancy of S. humilis seeds. As with some other legumes such as Senna multijuga(Rodrigues-Junior et al., 2014RODRIGUES-JUNIOR, A.G.; FARIA, J.M.R.; VAZ, T.A.A.; NAKAMURA, A.T.; JOSE, A.C. Physical dormancy in Senna multijuga (Fabaceae: Caesalpinioideae) seeds: the role of seed structures in water uptake. Seed Science Research , v.24, n.2, p.147-157, 2014. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=9258135
http://journals.cambridge.org/action/dis...
) Cassia leptophylla and Senna macranthera (Paula et al., 2012PAULA, A.S.; DELGADO, C.M.L.; PAULILO, M.T.S.; SANTOS, M. Breaking physical dormancy of Cassia leptophylla and Senna macranthera (Fabaceae: Casealpinioideae) seeds: water absorption and alternating temperatures. Seed Science Research , v.22, n.4, p.259-267, 2012. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=8735812&fileId=S096025851200013X
http://journals.cambridge.org/action/dis...
), seeds of Townsville stylo also exhibit physical dormancy, resulting from an impermeable seed coat (Smýkal et al., 2014SMÝKAL, P.; VERNOUD, V.; BLAIR M.W.; SOUKUP, A.; THOMPSON R.D. The role of the testa during development and in establishment of dormancy of the legume seed. Frontiers in Plant Science, v.5, n.351, p.1-19, 2014. http://ncbi.nlm.nih.gov/pmc/articles/PMC4102250/
http://ncbi.nlm.nih.gov/pmc/articles/PMC...
).

The seed coat exerts its germination-restrictive action most of the time by being impermeable to water and/ or oxygen or by its mechanical resistance to radicle protrusion (Linkies et al., 2009LINKIES, A.; MÜLLER, K.; MORRIS, K.; TUREČKOVÁ, V.; CADMAN, C.S.C.; CORBINEAU, F.; STRNAD, M.; LYNN, J.R.; FINCH-SAVAGE, W.E.; LEUBNER-METZGER, G. Ethylene interacts with abscisic acid to regulate endosperm rupture during germination: a comparative approach using Lepidium sativum and Arabidopsis thaliana. The Plant Cell, v.21, p.3803-3822, 2009. http://plantcell.org/content/21/12/3803.abstract
http://plantcell.org/content/21/12/3803....
; Smýkal et al., 2014SMÝKAL, P.; VERNOUD, V.; BLAIR M.W.; SOUKUP, A.; THOMPSON R.D. The role of the testa during development and in establishment of dormancy of the legume seed. Frontiers in Plant Science, v.5, n.351, p.1-19, 2014. http://ncbi.nlm.nih.gov/pmc/articles/PMC4102250/
http://ncbi.nlm.nih.gov/pmc/articles/PMC...
). In legumes, a densely packed layer of palisade cells impregnated with water-repellent compounds causes mechanical resistance of seed coat (Baskin and Baskin, 2004BASKIN, J.M.; BASKIN, C.C. A classification system for seed dormancy. Seed Science Research, v.14, p.1-16, 2004. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=704528
http://journals.cambridge.org/action/dis...
; Smýkal et al., 2014SMÝKAL, P.; VERNOUD, V.; BLAIR M.W.; SOUKUP, A.; THOMPSON R.D. The role of the testa during development and in establishment of dormancy of the legume seed. Frontiers in Plant Science, v.5, n.351, p.1-19, 2014. http://ncbi.nlm.nih.gov/pmc/articles/PMC4102250/
http://ncbi.nlm.nih.gov/pmc/articles/PMC...
, Baskin and Baskin, 2014BASKIN, C.C.; BASKIN J.M. Seeds: ecology, biogeography, and evolution of dormancy and germination, 2ed. Elsevier, San Diego, CA, USA, 2014. 1600p.). The seed becomes permeable to water only when the coat is disrupted in some way, particularly at the lens (strophiole) region, which is usually the physically weakest part of the seed coat (Moïse et al., 2005MOÏSE, J.A.; HAN, S.; GUDYNAITE-SAVITCH, L.; JOHNSON, M.B. Seed coats: structure, development, composition and biotechnology. In Vitro Cellular and Development Biology-Plant, v.41, p.620-644, 2005. http://link.springer.com/article/10.1079/IVP2005686
http://link.springer.com/article/10.1079...
; Jaganathan et al., 2017JAGANATHAN, G.K.; WU, G.R.; HAN, Y.Y.; LIU, BL. Role of lens in controlling physical dormancy break and germination of Delonix regia (Fabaceae: Casealpinioideae). Plant Biology, v.19, n.1, p.53-60, 2017. http://ncbi.nlm.nih.gov/pubmed/26998975
http://ncbi.nlm.nih.gov/pubmed/26998975...
). Thus, in the absence of physiological dormancy, overcoming of physical dormancy may lead to immediate germination of the seeds upon imbibition. Despite of the known association between seed coat permeability and embryonic growth potential, the nature of the co-actions between seed coat and embryo growth that determine dormancy is still unclear.

A wide range of factors that may potentially disrupt seed-coat imposed dormancy under natural conditions have been identified, with differing implications for seed bank dynamics and seedling emergence patterns (Van Klinken et al., 2006VAN KLINKEN, R.D.; FLACK, L.K.; PETTIT, W. Wet-season dormancy release in seed banks of a tropical leguminous shrub is determined by wet heat. Annals of Botany , v.98, p.875-883, 2006. http://aob.oxfordjournals.org/content/98/4/875.short
http://aob.oxfordjournals.org/content/98...
; Gama-Arachchige et al., 2012GAMA-ARACHCHIGE, N.S.; BASKIN, J.M.; GENEVE, R.L.; BASKIN, C.C. The autumn effect: timing of physical dormancy break in seeds of two winter annual species of Geraniaceae by a stepwise process. Annals of Botany , v.110, p.637-651, 2012. http://aob.oxfordjournals.org/content/early/2012/06/08/aob.mcs122.full
http://aob.oxfordjournals.org/content/ea...
). For example, high temperatures promoted dormancy overcome in impermeable seeds of S. humilis and S. hamata during the hot, dry season in northern Australia (McKeon and Mott, 1982MCKEON, G.M.; MOTT, J.J. The effect of temperature on the field softening of hard seed of Stylosanthes humilis and S. hamata in a dry monsoonal climate. Australian Journal of Agricultural Research, v.33, p.75-85, 1982. http://publish.csiro.au/paper/AR9820075.htm
http://publish.csiro.au/paper/AR9820075....
). Mechanical abrasion by soil particle, decomposition of the seed coat by microbial action as well as smoke or heat shock from fire are the others possible environment factors affecting physical dormancy of seeds in nature (Briggs and Morris, 2008BRIGGS, C.L.; MORRIS, E.C. Seed-coat dormancy in Grevillea linearifolia: little change in permeability to an apoplastic tracer after treatment with smoke and heat. Annals of Botany, v.101, p.623-632, 2008. http://aob.oxfordjournals.org/content/101/5/623.full
http://aob.oxfordjournals.org/content/10...
). A strong positive relationship between acidic solutions (low pH) and overcome of physiological dormancy has been found in scarified seeds of S. humilis (Pelacani et al., 2005aPELACANI, C.R.; BARROS, R.S.; RIBEIRO, D.M.; FRIGERI R.B.C. Breaking dormancy of Stylosanthes humilis seeds with low pH solutions. Acta Physiologiae Plantarum, v.27, p.317-323, 2005a. http://Link.springer.com/article/10.1007/s11738-005-0016-4
http://Link.springer.com/article/10.1007...
,bPELACANI, C.R.; RIBEIRO, D.M.; BARROS, R.S.; FRIGERI, R.B.C. Germination of dormant seeds of Stylosanthes humilis as affected by organic acids. Seed Science and Technology , v.33, n.1, p.105-113, 2005b. http://ingentaconnect.com/content/ista/sst/2005/00000033/00000001/art00011
http://ingentaconnect.com/content/ista/s...
; Ribeiro et al., 2010RIBEIRO, D.M.; MAPELI, A.M.; CARNELOSSI, M.A.G.; DELATORRE, C.A.; BARROS, R.S. Dormancy breakage of Stylosanthes humilis seeds by aluminium. Seed Science Research , v.20, p.145-152, 2010. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=7857428
http://journals.cambridge.org/action/dis...
). However, the importance of low pH for dormancy overcome in intact seeds of S. humilis has been poorly explored. Thus, the aim of the present study was to analyse the consequence of seed-coat-imposed dormancy on the physiological dormancy and germination of S. humilis seeds.

Material and Methods

Plant material and germination assays

Plants of S. humilis H.B.K. were grown in 3.0 L plastic pots in a greenhouse in Viçosa (20o45’S, 42o15’W), Minas Gerais, Brazil. Matures pods were harvested and stored in paper bags in laboratory at 30/25 oC day/night cycle with 60/70% relative humidity for 1, 6, 12, 24, 36 and 48 months prior to extraction from the pods. In this way, six seed lots (with different natural ageing time) were used for germination experiments. Following dehusking, intact seeds or mechanically (scarification with fine sandpaper number 150) and chemically (immersion in H2SO4 98% for 1 or 5 min and subsequent washing in water) treated seeds were sterilized with 0.5% NaOCl for 10 min and thoroughly washed with distilled water. Seeds (intact or scarified) were placed in glass Petri-dishes 90 mm diameter containing two layers of Whatman no 1 filter paper moistened with 10 mL water (control), 1-aminocyclopropane-1-carboxylic acid (ACC), the biochemical precursor of ethylene, or 2-choroethylphosphonic acid (CEPA), an ethylene-releasing compound. To further evaluate the role of ethylene in seed germination, intact seeds were placed in 50 mL Erlenmeyer flasks containing two layers of Whatman no1 filter paper moistened with 10 mL of water. Erlenmeyer flasks were immediately sealed with serum rubber caps and ethylene (to attain 10 µM) was injected in sealed flasks. The atmosphere of flasks was occasionally stirred with a syringe with needle inserted through the rubber seal. The effects of low pH solution on the mechanism of seed germination were also examined by treating seeds (intact or mechanically scarified with sand paper) with 10 mL MacIlvaine (10 mM) buffer solution at pH 4.0-7.0 in glass Petri-dishes 90 mm diameter containing two layers of Whatman no1 filter paper. Petri-dishes and Erlenmeyer flasks containing fifty seeds were placed in the dark in a day/night growth chamber (Forma Scientific Inc., Ohio, USA) at 30 oC. The seed was considered as germinated upon protrusion of its radicle.

Seed coat permeability assay using tetrazolium staining

Entire seeds were incubated in a 1% (w/v) solution of 2, 3, 5-triphenyltetrazolium chloride (Sigma-Aldrich) at 30 oC in darkness for 5 d as described by Wharton (1955WHARTON, M.J. The use of tetrazolium test for determining the viability of seeds of the genus Brassica. Proceedings of the International Seed Testing Association, v.20, p.81-88, 1955.). The embryo and cotyledons of Townsville stylo seeds stain red upon entry of the tetrazolium salt solution in the viable seed, but stay whitish when the dye does not penetrate. Thus, enhanced staining intensity indicates enhanced seed coat permeability (Debeaujon et al., 2000DEBEAUJON, I.; LÉON-KLOOSTERZIEL, K.M.; KOORNNEEF, M. Influence of the testa on seed dormancy, germination, and longevity in Arabidopsis. Plant Physiology, v.122, p.403-413, 2000. http://ncbi.nlm.nih.gov/pubmed/10677433
http://ncbi.nlm.nih.gov/pubmed/10677433...
).

Microscopy

We performed microscopic analysis of mature seed coat to correlate the germination behaviour of Townsville stylo seeds with precise seed coat characteristics. Two treatments were compared for their effectiveness in overcoming hard seed coat dormancy (i) manual scarification - seeds were subject to manual scarification by gently rubbing between fine sand paper (no 150) for 1 min, (ii) chemical scarification - seeds were immersed in 20 mL of 98% H2SO4 for 1 min or 5 min at ambient temperature (~ 25 oC). The seeds were then washed thoroughly under running water for 5 min. Seeds were mounted directly on double-sided adhesive tape affixed to scanning electron microscopy stubs. Then, the samples were coated with gold-palladium (15 nm) in a sputter coater and examined using a scanning electron microscope (LEO; EVO 50 XVP, Cambridge, UK).

Statistical analysis

The statistical design of the assays was based on a completely randomized distribution with five replicates with 50 seeds each for germination test in Petri-dishes or Erlenmeyer flasks. Germination percentage was transformed to arcsin (% G/100)1/2, prior to analysis and all data were checked for normality. Analysis of variance (ANOVA; p < 0.05) was carried out to determine effects of treatments. If ANOVA showed significant effects, Tukey test was used to determine differences among treatments. All mean comparisons were performed with SPSS (Statistical Package for the Social Sciences) 11.0 for Windows Statistical Software Package.

Results and Discussion

The degree of dormancy of Townsville stylo seeds was assessed by determining the germination percentage of the seed lots with different post-harvest age (Figure 1a). After mechanical scarification of the seeds, freshly harvested seeds of Townsville stylo were dormant, but this physiological dormancy has disappeared after 12 months after-ripening (Figure 1a). This agreed with the suggestion of Vieira and Barros (1994VIEIRA, H.D.; BARROS, R.S. Response of seed of Stylosanthes humilis to germination regulators. Physiologia Plantarum, v.92, p.17-20, 1994. http://scielo.br/scielo.php?script=sci_arttext&pid=S1677-04202004000200003
http://scielo.br/scielo.php?script=sci_a...
) that, for Townsville stylo seeds, a dry storage for up to 1 year would be required for the enhancement of germination. However, compared with freshly harvested seeds, the non-dormant seeds displayed a similar permeability of seed coat, demonstrating that natural ageing time did not increase permeability of Townsville stylo seeds to tetrazolium solution (Figure 1b). Cell expansion growth required for radicle protrusion and seed coat rupture depends on environmentally and hormonally regulated cell wall-loosening mechanisms (Van Sandt et al., 2007; Linkies et al., 2009LINKIES, A.; MÜLLER, K.; MORRIS, K.; TUREČKOVÁ, V.; CADMAN, C.S.C.; CORBINEAU, F.; STRNAD, M.; LYNN, J.R.; FINCH-SAVAGE, W.E.; LEUBNER-METZGER, G. Ethylene interacts with abscisic acid to regulate endosperm rupture during germination: a comparative approach using Lepidium sativum and Arabidopsis thaliana. The Plant Cell, v.21, p.3803-3822, 2009. http://plantcell.org/content/21/12/3803.abstract
http://plantcell.org/content/21/12/3803....
; Muller et al., 2009MULLER, K.; LINKIES, A.; VREEBURG, R.A.M.; FRY, S.C.; KRIEGER-LISZKAY, A.; LEUBNER-METZGER, G. In Vivo cell wall loosening byhydroxyl radicals during cress seed germination and elongation growth. Plant Physiology , v.150, n.4, p.1855-1865, 2009. http://plantphysiol.org/content/150 /4/1855.long
http://plantphysiol.org/content/150 /4/1...
; Morris et al., 2011MORRIS, K.; LINKIES, A.; MÜLLER, K.; ORACZ, K.; WANG, X.; LYNN, J.R.; LEUBNER-METZGER, G.; FINCH-SAVAGE, W.E. Regulation of seed germination in the close arabidopsis relative Lepidium sativum: A Global Tissue-Specific Transcript Analysis. Plant Physiology , v.155, n.4, p.1851-1870, 2011. http://plantphysiol.org/content/155/4/1851.long
http://plantphysiol.org/content/155/4/18...
). In Townsville stylo embryo hypocotyl-radicle axis growth are associated with ethylene production as a mechanism for cell expansion growth (Vieira and Barros, 1994VIEIRA, H.D.; BARROS, R.S. Response of seed of Stylosanthes humilis to germination regulators. Physiologia Plantarum, v.92, p.17-20, 1994. http://scielo.br/scielo.php?script=sci_arttext&pid=S1677-04202004000200003
http://scielo.br/scielo.php?script=sci_a...
; Ribeiro and Barros, 2006RIBEIRO, D.M.; BARROS, R.S. Sensitivity to ethylene as a major component in the germination of seeds of Stylosanthes humilis. Seed Science Research , v.16, p.37-45, 2006. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=705764
http://journals.cambridge.org/action/dis...
). Freshly harvested seed and non-dormant seeds germinated only about 20% when treated with ACC (immediate precursor of ethylene), CEPA (an ethylene-releasing compound) or ethylene gas (Figure 1a). The observation that intact seeds were permeable to tetrazolium salt solution in a manner related to germination behaviour of seeds treated with ACC, CEPA or ethylene gas demonstrates that seed coat play a major role on the imposition of germination of Townsville stylo seeds and that seed coat weakening is not the consequence of ethylene action. Therefore, ethylene requirement for physiological dormancy alleviation as well as for germination of Townsville stylo seed appears to be under control of physical dormancy imposed by the hard seed coat. The hardseededness and water impermeability of many legume seeds is due to a palisade epidermal layer of thick-walled Malphighian cells in the outer testa (Moïse et al., 2005MOÏSE, J.A.; HAN, S.; GUDYNAITE-SAVITCH, L.; JOHNSON, M.B. Seed coats: structure, development, composition and biotechnology. In Vitro Cellular and Development Biology-Plant, v.41, p.620-644, 2005. http://link.springer.com/article/10.1079/IVP2005686
http://link.springer.com/article/10.1079...
). Thus, the germination behaviour of intact seeds of Townville stylo can be related with structure of the seed coat: a cuticle and a palisade layer composing the outer integument followed by an endothelium layer and a crushed parenchymatic layer forming the inner integument (Figures 2a-d).

Figure 1
Effect of dry storage on dormancy release of Townsville stylo seeds. (a) Germination was determined in mechanically scarified seeds imbibed just in water or in intact seeds treated with ACC (1 mM), CEPA (1 mM) and ethylene gas (10 μM). (b) Permeability of intact seeds to tetrazolium solution. Remaining fraction of seed to 100% corresponds to impermeable seeds. Germination and permeability of seeds to tetrazolium salt were carried out on the 5th day. Values with the same letter within (a) each natural aging time and (b) among natural aging time are not statistically different at the 5% level by Tukey test. Data points are means of five replicates ± standard error.

Figure 2
Scanning electron micrographs of Townsville stylo seed. (a) Entire mature seeds (15 post-harvest days old) showing radicle tip (r), cotyledons (c) and seed coat (sc). (b,c and d) Structure of the seed coat showing cuticle (cu), palisade layer (p), endothelium layer (e), crushed parenchymatic layer (cp) and cotyledons (c).

The important restrictive role of the seed coat in the germination of Townsville stylo seeds was supported further by scarification experiments. It is known that physical and chemical scarification overcome physical dormancy of Stylosanthes seeds (Mott and Mckeon, 1979MOTT, J.J.; MCKEON, G.M. Effect of heat treatments in breaking hardseededness in four species of Stylosanthes. Seed Science and Technology, v.7, n.1, p.15-25, 1979. http://library.ciat.cgiar.org/cgi-bin/koha/opac-detail.pl?biblionumber=68912&shelfbrowse_itemnu mber=86536#shelfbrowser
http://library.ciat.cgiar.org/cgi-bin/ko...
; Anand et al., 2011ANAND, A.; BHARDWAJ, J.; NAGARAJAN, S. Comparative evaluation of seed coat dorman breaking treatments in Stylosanthes seabrana. Grass and Forage Science, v.66, p.272-276, 2011. http://onlinelibrary.wiley.com/doi/10.1111/j.1365-2494.2011.00787.x/abstract
http://onlinelibrary.wiley.com/doi/10.11...
). In this context, seed coat permeability to tetrazolium salt solution was increased in dormant and non-dormant seeds scarified with sand paper or treated with H2SO4 (Table 1). However, scarification treatments increased germination of non-dormant seeds i.e., seeds without physiological dormancy, but not in seeds with physiological dormancy (Table 1). Scanning electron micrographs revealed that the surface of mechanically scarified seeds peeled at various places, resulting in a weakening of the seeds coat (Figure 3b). In contrast, scarification with H2SO4 overcame physical dormancy of seeds by causing many randomly located cracks in the seed coat, which than act as sites of water entry (Figures 3c-g). However, germination of freshly harvested seed was not increased after scarification treatments (Figures 4a, e), indicating that Townsville stylo seeds depend on a stepwise physiological dormancy-overcoming behaviour in timing their germination. In agreement with this, scarified dormant-seeds were able to germinate quite rapidly when imbibed in CEPA (Figure 4c), an ethylene-releasing compound. On the other hand, mechanical or chemical scarification of aged Townville stylo seeds can be substitute for the exogenous CEPA requirement for germination (Figures 4d, f). Together, these data indicate that physical dormancy overcome is prerequisite for radicle protrusion and physiological dormancy of Townsville stylo seeds contribute to its timing.

Table 1
Permeability of Townsville stylo seed coat to tetrazolium solution and germination of dormant (15 post-harvest days old) and non-dormant (765 post-harvest days old) seeds after treatment with different physical dormancy breaking methods. Permeability of seeds and germination were carried out on the 5th day.

Figure 3
Scanning electron micrographs of Townsville stylo seed coat after pre-treatment with different dormancy breaking methods. (a) Intact seeds (15 post-harvest days old) showing hilum (h) and micropyle (m); (b) mechanical scarification with fine sand paper. Detail shown the damage caused by sandpaper occurs preferentially in the curved region and at the extremity where the protrusion of the radicle occurs; (c and d) acid scarification with H2SO4 for 1 and 5 min, respectively. (e) Cracks are see on the surface of seeds treated with H2SO4 for 1 min. (f and g) Morphology of the hilum area after treatment with H2SO4 for 5 min.

Figure 4
Time course of germination for dormant seed (15 post-harvest days old) and non-dormant seed (765 post-harvest days old) after pre-treatment with different physical dormancy breaking methods. (a, b, c and d) Seeds were imbibed in water (filled circle) or 1 mM CEPA (open circle). (e and f) Seeds were pre-treated with H2SO4 for 1 and 5 min, and imbibed in water (open diamond, open square) or 1 mM CEPA (filled diamond, filled square), respectively. Data points are means of five replicates ± standard error.

In many ecosystems, soil moisture and temperature are the two most important factors that determine seasonal germination pattern and modulate persistence and dormancy of soil seed banks (Benech-Arnold et al., 2000BENECH-ARNOLD, R.L.; SANCHEZ, R.A.; FORCELLA, F.; KRUK, B.C.; GHERSA, C.M. Environmental control of dormancy in weed seed banks in soil. Field Crops Research, v.67, p.105-122, 2000. http://sciencedirect.com/science/article/pii/S0378429000000873
http://sciencedirect.com/science/article...
; Walck et al., 2005WALCK, J.L.; BASKIN, J.M.; BASKIN, C.C.; HIDAYATI, S. Defining transient and persistent seed banks in species with pronounced seasonal dormancy and germination patterns. Seed Science Research , v.15, p.189-196, 2005. http://journals.cambridge.org/action/displayAbstract?FromPage=online &aid=705880
http://journals.cambridge.org/action/dis...
; Batlla and Benech-Arnold, 2010BATLLA, D.; BENECH-ARNOLD, R.L. Predicting changes in dormancy level in natural seed soil banks. Plant Molecular Biology, v.73, p.3-13, 2010. http://ncbi.nlm.nih.gov/pubmed/20091421
http://ncbi.nlm.nih.gov/pubmed/20091421...
). For example, McKeon and Mott (1982)MCKEON, G.M.; MOTT, J.J. The effect of temperature on the field softening of hard seed of Stylosanthes humilis and S. hamata in a dry monsoonal climate. Australian Journal of Agricultural Research, v.33, p.75-85, 1982. http://publish.csiro.au/paper/AR9820075.htm
http://publish.csiro.au/paper/AR9820075....
showed that seeds of S. humilis and S. hamata were softened by temperature fluctuation during the hot, dry season in northern Australia. Soils in which species of Stylosanthes genus is distributed naturally are generally acidic (pH 4.0-5.5) (Williams et al., 1984WILLIAMS, R.J.; REID, R.; SCHULTZE-KRAFT, R.; SOUZA COSTA, N.M.; THOMAS, B.D. Natural distribution of Stylosanthes. In: STACE, H.M.; EDYE, L.A. (Eds.) The biology and agronomy of Stylosanthes. Sydney: Academic Press, p.73-101, 1984.), as the Cerrado (the Brazilian savannah) soils (Ruggiero et al., 2002RUGGIERO, P.G.C.; BATALHA, M.A.; PIVELLO V.R.; TADEU MEIRELLES, S.T. Soil-vegetation relationships in cerrado (Brazilian savanna) and semideciduous forest, Southeastern Brazil. Plant Ecology, v.160, p.1-16, 2002. http://link-springer-com.ez35.periodicos.capes.gov.br/article/ 10.1023/A%3A1015819219386
http://link-springer-com.ez35.periodicos...
). Low-pH solutions were effective in overcoming physiological dormancy of scarified seeds of Townsville stylo (Pelacani et al., 2005aPELACANI, C.R.; BARROS, R.S.; RIBEIRO, D.M.; FRIGERI R.B.C. Breaking dormancy of Stylosanthes humilis seeds with low pH solutions. Acta Physiologiae Plantarum, v.27, p.317-323, 2005a. http://Link.springer.com/article/10.1007/s11738-005-0016-4
http://Link.springer.com/article/10.1007...
,bPELACANI, C.R.; RIBEIRO, D.M.; BARROS, R.S.; FRIGERI, R.B.C. Germination of dormant seeds of Stylosanthes humilis as affected by organic acids. Seed Science and Technology , v.33, n.1, p.105-113, 2005b. http://ingentaconnect.com/content/ista/sst/2005/00000033/00000001/art00011
http://ingentaconnect.com/content/ista/s...
; Ribeiro et al., 2010RIBEIRO, D.M.; MAPELI, A.M.; CARNELOSSI, M.A.G.; DELATORRE, C.A.; BARROS, R.S. Dormancy breakage of Stylosanthes humilis seeds by aluminium. Seed Science Research , v.20, p.145-152, 2010. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=7857428
http://journals.cambridge.org/action/dis...
). In the present work, those data were expanded to include the effects of low-pH solutions on physical dormancy overcome of Townsville stylo seeds (Figures 5a-d). Low pH of the incubation medium-mediated increase in the seed coat tetrazolium salt permeability during dormant and non-dormant seed imbibition (Figures 5a, b). The maximum significant effect induced by acidic solution occurred at pH 4.0 when permeability of the dormant and non-dormant seeds to tetrazolium was increased by 2.1- and 2.3-fold, respectively, as compared with the control (pH 7.0) (Figures 5a, b). In line with this finding, acidic solutions increased germination of non-escarified seeds (Figures 5c, d, black bars). The maximum effect promoted by applied of low pH solutions occurred at pH 4.0 when seed germination of dormant and non-dormant seeds was increased by 22.0- and 2.8-fold, respectively, as compared with the control (pH 7.0) (Figures 5c, d, black bars). The occurrence of germination indicates that the permeability to tetrazolium salt can be used to monitor the permeability of Townsville stylo seeds to water entry. As expected, physiological dormancy of scarified seeds was partially broken by acidic solution at pH 4.0 and 5.0 (Figure 5c, white bars). In addition, low pH solutions had no toxic effect on the germination response of scarified non-dormant seeds (Figure 5 d, white bars). In other words, freshly harvested seeds exhibited a reduced germination compared with non-dormant seeds, indicating that the germination behaviour of freshly harvested seeds treated with acid solutions is related to the degree of the physiological dormancy in the seeds. Together, these data indicate that low pH solutions causes seed coat weakening, which in turn may require a lower embryo force for its rupture.

Figure 5
Response of Townsville stylo seeds to MacIlvaine buffer solutions at several pH(s). (a and b) Permeability of intact seed to tetrazolium salt supplied in MacIlvaine buffer at several pH(s). Remaining fraction of seed to 100% corresponds to impermeable seeds. (c and d) Germination of seeds incubated in serial pH MacIlvaine buffer solutions. Test-solutions were renewed 24 hours after start of imbibition. Permeability of seeds and germination were registered on the 5th day. After mechanical scarification, permeability of seed coat to tetrazolium salt supplied in MacIlvaive pH 7.0 was 95 ± 0.9% and 93 ± 0.7% in dormant (15 post-harvest days old) and non-dormant seeds (765 post-harvest days old), respectively. Bars followed by the same small or capital letter across the range of MacIlvaine solutions do not differ statistically at the 5% level by Tukey test.

Conclusions

Physical dormancy of Townsville stylo seed was not reduced during natural ageing at room temperature, in contrast to the physiological dormancy, which is gradually overcome during post-harvest ageing. Furthermore, the permeability of seed coat was affected by scarification treatments as well as by low-pH solutions, which leads to effects on germination. Given that under treatment with acidic solutions a tight relationships linking seed coat permeability and germination are observed, it is possible that low pH soils would play an important ecological role in the successful establishment of Stylosanthes species population. In summary, seed coat weakening was a prerequisite for radicle protrusion and physiological dormancy of Townsville stylo seeds contribute to its timing.

Acknowledgments

Thanks are due to CAPES (Coordination for Scientific Support for Post-Graduate Level) for the scholarship awarded to D.M.R. The Brazilian Research Council (CNPq) is also acknowledged for the scholarship awarded to I.S.C. and for their financial support granted during the conduct of this research.

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Publication Dates

  • Publication in this collection
    Apr-Jun 2017

History

  • Received
    11 Aug 2016
  • Accepted
    24 Apr 2017
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