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Brief Communication |
2Departamento de Geoecología, Instituto de Recursos Naturales y Agrobiología de Sevilla (CSIC), P.O. Box 1052, 41080 Sevilla, Spain; 3Department of Animal and Plant Sciences, University of Sheffield, Sheffield S10 2TN, UK
Received for publication January 21, 2005. Accepted for publication June 14, 2005.
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONLITERATURE CITED |
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Key Words: Doñana • helophytes • Juncus, Mediterranean wetland • Scirpus • seed buoyancy • seed rain • soil cracks
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INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONLITERATURE CITED |
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; Bekker et al., 1998
). Seed bank distributions with a peak density below the soil surface are usually assumed to have a historical explanation, reflecting a seed input that was greater at some time in the past and has subsequently declined. Examples include the presence of deeply buried seeds of arable weeds under formerly cultivated pasture (e.g., Chippindale and Milton, 1934
) and deeply-buried seeds of pioneer species in the later stages of succession (e.g., Bekker et al., 1999
). The assumption that deeper seeds are older may also be violated, especially in cultivated soils, and cultivation by different implements may lead to quite complicated depth profiles, with mixtures of seed ages at all depths (Grundy et al., 1999
).
Climates with alternating dry/wet seasons frequently develop vertic soils, that is, fine-textured soils that experience extreme changes in key soil properties throughout the year and tend during the dry season to develop cracks of varying width and depth, which become closed during the wet season (Eswaran et al., 1999
). Frequently, the opened cracks tend to be filled with materials from the surface that are dislodged by animals, wind, or water, and these can become trapped when the cracks close. These "internal movements" in the soil redistribute materials (churning, or horizon disruption, Buol et al., 1989
) in the horizons affected by cracking, which may affect the distribution of plant propagules. Vertic soils are distributed worldwide and predominantly under a natural vegetation of salt marshes, grasses, savannas, open forest, or desert shrubs (FAO-ISRIC-ISSS, 1998
; Soil Survey Staff, 1999
).
Little is known about how much (1) cracks influence the vertical distribution in the soil of seeds from different species, (2) timing and velocity of seed release could affect the final distribution of the seed bank of different species, and (3) trapped seeds can preserve their viability after favorable conditions are reestablished.
Here we determine the impact of seasonal soil cracking on the distribution of the soil seed bank in a Mediterranean wetland. We hypothesize that, in contrast to the overwhelming majority of reports in the literature (Thompson et al., 1997
), the viable seed bank of some species may have a bimodal distribution (U-shaped). We also discuss the roles of soil cracks and primary dispersal syndrome (i.e., time of seed release and seed buoyancy) in generating this distribution.
Study site
During the summer, soils of wetlands under Mediterranean climates (frequently calcareous, saline, and clayey) develop cracks, which then close in autumn during the wet season. In Doñana salt marshes, a nontidal marsh with a Mediterranean climate located in southwest Spain (37° N, 6° W), areas colonized by perennial plants have abundant cracks in the soil (especially in the range 0–20 cm depth, Clemente et al., 1998
) during the dry season, when many species, including some perennial emergent macrophytes, shed their seeds.
Study species
The major components of the vegetation in Doñana temporary marshes are the rhizomatous and perennial emergent macrophytes Juncus subulatus Forsskal, Scirpus maritimus L., and S. litoralis Scharader. Juncus subulatus inhabits shallow brackish waters in coastal areas of the Mediterranean and Irano-Turacic regions (Valdes et al., 1987
). Scirpus litoralis Scharader and S. maritimus L. (Cyperaceae) are more widely distributed in shallow, brackish water bodies of temperate regions (Valdes et al., 1987
). In all three species, belowground parts sprout once the wet season begins in autumn. The shoot grows up through the water column, emerging in autumn (J. subulatus) or winter (Scirpus spp.), fruits through the spring, and dies in the dry season (summer). Previous studies (García et al., 1993
; Espinar et al., 2002
) have shown that these geophytes become dominant in different zones of the microtopographic gradient, with J. subulatus occupying the highest parts, which are flooded to a lesser depth and for a shorter time, while S. litoralis uses the deepest areas, flooded longest. Scirpus maritimus occupies intermediate areas.
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MATERIALS AND METHODS |
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).To estimate the rate of seed loss from fertile shoots of all three species, shoot seed content was sampled in June, August, and early November. From each study population, the inflorescences of 10 shoots were collected at random, with each shoot separated from each other by at least 1 m. In the laboratory, the number of seeds per shoot was counted (in three spikes per inflorescence for Scirpus species and three capsules per inflorescence for J. subulatus).
Seed bank estimation
In October 2002, at the beginning of the wet season, three soil cores were collected in two study plots for each species (6 cores per species; 0.08 m diameter and 0.16 m depth). Each core was carefully separated (to avoid contamination between different depths) into four depths (0–0.04, 0.04–0.8, 0.08–0.12, 0.12–0.16 m) and placed in separate bags. Each sample was air dried and carefully homogenized by hand in the laboratory. To obtain a complete inventory of seeds, we obtained three sets of data for each sample: "by germination," followed by sieving for "direct counts," and then following cold treatment a second germination period for "recovery." A 0.05-kg subsample of each homogenized sample was placed in a 14-cm petri dish with demineralized water until soil saturation. The petri dishes were closed to avoid loss of humidity and stored in the dark at 4°C for 30 days to stimulate germination (Clevering, 1995
; Espinar et al., 2004
). After this period, demineralized water was added to each petri dish until the soil was covered. Dishes were then placed in a germination chamber with a 12 h–12 h light–dark photoperiod, photon flux of 500 µmol photons/m2 and temperature cycle of 25°/15°C. Every 3 days, the soil was disturbed and the number of seedlings in each dish was counted (and removed) to obtain, after 60 days, the soil seed bank density "by germination." After germination, the same soil sample was sieved and the number of intact seeds was counted, to obtain the soil seed bank density "by direct counts." The soil samples were not dried before sieving. To detect the viability of seeds revealed by direct counting, they were placed in a freshwater medium for a month at 4°C in darkness, then placed in a petri dish containing a Whatman No. 1 filter paper (Maidstone, UK) and 20 mL demineralizd water. Germination was tested under the conditions described; every 3 days for 30 days, the number of seeds germinated on each dish was counted to obtain the total percentage germination "by recovery."
Data analysis
Variation of all study variables with depth was analyzed using a nonparametric test (Kruskal-Wallis nonparametric ANOVA). The analyzed dependent variables did not meet the assumption of normality and homogeneity of variance necessary for a parametric ANOVA. For each species, the relationships between the different seed variables and depth were first explored using a local regression procedure (distance weighted least squares regression lines (DWLS) are shown; McLain, 1974
). When we found significant differences in the Kruskal-Wallis test, we were interested in testing if a U-shaped model of seed bank depth distribution significantly improves on a monotonic decreasing one. That is, when a positive one-tailed test for the quadratic polynomial coefficient (a2) was positive, a test of H0: a2 = 0 vs H1: a2 > 0 (where H0 is the null hypothesis and H1 is the alternate hypothesis) was performed. To test the U-shaped model, we using a generalized linear model (GLM), assuming a Poisson distribution (given the nature of the analyzed dependent variable—counts) and a log link function (Dobson, 2002
) using depth as the independent variable. The increased type 1 error rate by repeated testing was controlled at an overall 0.05 level by using the Holm sequential Bonferroni procedure (Holm, 1979
; García, 2004
).
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RESULTS |
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DISCUSSION |
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), the viable seed bank of two study species (S. litoralis and J. subulatus) shows a bimodal distribution, with seeds found at all depths, but highest densities in topsoil and in the deepest samples. This pattern could be associated with early seed release in S. litoralis and J. subulatus. Scirpus maritimus, which inhabits the same area, but has a more delayed seed release, has viable seeds only at the soil surface. We suggest that the entry of seeds into deep soil layers via cracks in dry soil during the period of summer seed rain for S. litoralis and J. subulatus (but not for S. maritimus) could be the fundamental cause of this depth distribution. In addition to this effect of cracks, the buoyancy capacity of seed plays an additive role in the process, because the high floating capacity of S. maritimus seeds means that the seeds that could fall into the cracks (about 40% of seed production) can easily float out again when flooding begins at the start of the wet season. Seeds of S. litoralis are mostly released, while cracks are still open, sink fast in water, and are easily trapped in the soil (see Fig. 1).Thus the U-shaped depth distribution in S. litoralis and J. subulatus is linked to the fact that the average depth of soil cracks in the study area is around 20 cm (Clemente et al., 1999), and the majority of seeds that fall into cracks end up at or near the bottom of the cracks. During the dry season, these cracks are partially filled with superficial soil materials and a noticeable number of seeds, which become trapped in the soil when the cracks suddenly close at the beginning of the wet season. Although viable seeds of S. maritimus were found only in the surface soil, we found large numbers of nonviable seeds of all three species at all depths. Seeds of S. maritimus may be short-lived, or they may suffer a rapid loss of viability when buried, but we have no data on seed longevity or the effects of burial on seed viability. After several or many cycles of swelling—shrinking, the soil becomes "inverted," and subsoil materials may eventually come to the surface (Buol et al., 1989
) and interact with light and less saline water. However, it is difficult to evaluate the percentage of deeply buried seeds that reach the soil surface via this route, and the time period involved in the process.
Ecological implication of burial seeds
The ecological implications of the different capacity of seeds for burial remain unexplored, but are probably different in each study species. Although seeds of both Scirpus species are usually consumed by birds (Espinar et al., 2004
), S. maritimus seeds are bigger than S. litoralis, and S. maritmus can float at the water surface for several weeks. Both facts suggest that S. maritimus seed are more susceptible to predation than S. litoralis. Furthermore, the timing of massive seed release of S. maritimus coincides with the presence of large migratory birds. The ratios of seed production by S. maritimus (Sm), S. litoralis (Sl), and J. subulatus (Js) are nearly 1 : 8 : 188 (Sm : Sl : Js); yet the ratios of their viable seeds in the upper 4 cm (with proven ability to germinate and establish) are nearly 1 : 1 : 1. Considering only seed that could germinate and establish and the importance of the local seed bank, the processes described in this paper might seem to favor the dispersal syndrome of S. maritimus (i.e., with a low production of seed yet a local seed bank with the same density of viable seeds) rather than the other two species. As mentioned, both the eventual fate and ecological significance of deeply buried seeds in S. litoralis and J. subulatus remain unknown. Clearly, we need to discover the capacity of buried seeds to return to the surface and the possible loss of viability in buried seed. An important reserve of viable seed exists only in S. litoralis and J. subulatus, and buried seeds of these species are protected from predation. On the other hand, seeds that fall into cracks are subject to different conditions of humidity and salinity (increased exposure to moisture and different salinity levels) than seeds that remain at or near the surface. The duration of exposure to salinity and moisture, as tested in laboratory conditions, has a significant effect on seed germination pattern in all three study species (Espinar et al., 2005
), but the effects under field conditions remain unknown. There are several reports of a persistent seed bank in S. maritimus (Thompson et al., 1997
). There is no published information on S. litoralis or J. subulatus, but all species of Juncus appear to have persistent seed banks.
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FOOTNOTES |
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4 Author for correspondence (e-mail: jespinar{at}usgs.gov
or jlespinar{at}irnase.csic.es
), present address: U.S. Geological Survey, National Wetlands Research Center, 700 Cajundome Blvd., Lafayette, Louisiana, USA
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LITERATURE CITED |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONLITERATURE CITED |
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Bekker R. M. E. J. Lammerts A. Schutter A. P. Grootjans 1999 Vegetation development in dune slacks: the role of persistent seed banks. Journal of Vegetation Science 10: 745-754[CrossRef][ISI]
Buol S. W. F. D. Hole R. J. McCracken 1989 Soil genesis and classification, 3rd ed. Iowa State University Press, Ames, Iowa, USA
Chippindale H. G. W. E. J. Milton 1934 On the viable seeds present in the soil beneath pastures. Journal of Ecology 22: 508-531[CrossRef]
Clevering O. A. 1995 Germination and seedling emergence of Scirpus lacustris L. and Scirpus maritimus L. with special reference to the restoration of wetlands. Aquatic Botany 50: 63-78[CrossRef]
Clemente L. L. V. García P. Siljeström 1998 Suelos del Parque Nacional de Doñana. Ministerio de Medio Ambiente, Madrid, Spain
Dobson A. J. 2002 An introduction to generalized linear models, 2nd ed. Chapman & Hall, London, UK
Espinar J. L. L. V. García L. Clemente 2005 Seed storage condition changes the germination pattern of clonal growth plants in Mediterranean salt-marshes. American Journal of Botany 92: 1094-1101
Espinar J. L. L. V. García J. Figuerola A. J. Green L. Clemente 2004 Helophyte germination in Mediterranean wetlands: gut-passage by ducks changes seed response to salinity. Journal of Vegetation Science 15: 313-320
Espinar J. L. L. V. García P. García-Murillo J. Toja 2002 Submerged macrophyte zonation in a Mediterranean salt marsh: a facilitation effect from established helophytes?. Journal of Vegetation Science 13: 831-840[CrossRef][ISI]
Eswaran H. F. H. Beinroth P. F. Reich L. A. Quandt 1999 Vertisols: their properties, classification, distribution and management. U.S. Department of Agriculture, Lincoln, Nebraska, USA
García L. V. 2004 Escaping the Bonferroni iron claw in ecological studies. Oikos 105: 657-663[CrossRef][ISI]
García L. V. T. Marañón A. Moreno L. Clemente 1993 Above-ground biomass and species richness in a Mediterranean salt marsh. Journal of Vegetation Science 4: 417-424[CrossRef][ISI]
Grundy A. C. A. Mead S. Burston 1999 Modelling the effect of cultivation on seed movement with application to the prediction of weed seedling emergence. Journal of Applied Ecology 36: 663-678[CrossRef][ISI]
Holm S. 1979 A simple sequential rejective multiple test procedure. Scandinavian Journal of Statistics 6: 65-70[ISI]
Hroudová Z. L. Moravcová P. Zákravsk 1997 Effect of anatomical structure on the buoyancy of achenes of two subspecies of Bolboschoenus maritimus. Folia Geobotanica et Phytotaxonomica 32: 377-390
ISSS-ISRIC-FAO. 1998 World reference base for soil resources. World Soil Resources Reports 84. Food and Agriculture Organization of the United Nations, Rome, Italy
McLain D. H. 1974 Drawing contours from arbitrary data points. The Computer Journal 17: 318-324
Soil Survey Staff. 1999 Soil taxonomy: a basic system of soil classification for making and interpreting soil surveys, 2nd ed. U.S. Department of Agriculture Handbook No. 436, USDA Natural Resources Conservation Services, U.S. Government Printing Office, Washington, D.C., USA
Thompson K. J. P. Bakker R. M. Bekker 1997 Soil seed banks of north-west Europe: methodology, density and longevity. University Press, Cambridge, UK
Valdés B. S. Talavera E. Fernández-Galiano 1987 Flora vascular de Andalucía Occidental. Ketres, Barcelona, Spain
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