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Germination ecology of the perennial Centaurium somedanum, a specialist species of mountain springs

Published online by Cambridge University Press:  17 May 2012

Eduardo Fernández-Pascual ,
Borja Jiménez-Alfaro ,
Ana I. García-Torrico ,
Félix Pérez-García  and
Tomás E. Díaz
Eduardo Fernández-Pascual*
Affiliation:
Jardín Botánico Atlántico, Universidad de Oviedo, Avda. del Jardín Botánico 2230, 33394 Gijón/Xixón, Spain
Borja Jiménez-Alfaro
Affiliation:
Jardín Botánico Atlántico, Universidad de Oviedo, Avda. del Jardín Botánico 2230, 33394 Gijón/Xixón, Spain
Ana I. García-Torrico
Affiliation:
Jardín Botánico Atlántico, Universidad de Oviedo, Avda. del Jardín Botánico 2230, 33394 Gijón/Xixón, Spain
Félix Pérez-García
Affiliation:
Departamento de Biología Vegetal, EUIT Agrícola, Universidad Politécnica de Madrid, Spain
Tomás E. Díaz
Affiliation:
Jardín Botánico Atlántico, Universidad de Oviedo, Avda. del Jardín Botánico 2230, 33394 Gijón/Xixón, Spain
*
*Correspondence Fax: +34 985130685 Email: eduardofp@indurot.uniovi.es
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Abstract

To improve understanding of how a rare endemic species of Centaurium adapts to a specialized ecological niche, we studied the germination ecology of the mountain spring specialist, C. somedanum, a perennial species restricted to an unusual habitat for this genus. We conducted laboratory experiments with fresh seeds collected from two populations for three consecutive years, to investigate: (1) the effect of temperature and light on germination; (2) the existence of seed dormancy; and (3) inter-population and inter-annual variation in germinability. Germination occurred only in the light and at relatively low temperatures (15–22°C) with no differences between constant and alternating regimes, and a significant decrease at high temperatures (25°C and 30°C). We found non-deep simple morphophysiological dormancy and variation in seed germinability depending on the year of seed collection. C. somedanum diverged from the common germination characteristics of the genus in: (1) its germination at lower temperatures, which contrasts with what is generally expected in wetland species but could be adaptive in the spring habitat; and (2) its morphophysiological dormancy, which we report here for the first time in the genus and which could be an adaptation to its mountain habitat.

Keywords

CentauriumdormancyendemicGentianaceaegerminationspringswetlands
Type
Research Papers
Information
Seed Science Research , Volume 22 , Issue 3 , September 2012 , pp. 199 - 205
Copyright
Copyright © Cambridge University Press 2012

Introduction

Centaurium Hill (Gentianaceae), as defined by Mansion (Reference Mansion2004), includes c. 27 species of Mediterranean origin and Old World distribution. It is comprised of annual, biennial and, rarely, perennial herbs occurring in different habitats of the Mediterranean basin and surrounding areas (Mansion et al., Reference Mansion, Zeltner and Bretagnolle2005). Because of its wide distribution and pharmacological importance (Jensen and Schripsema, Reference Jensen, Schripsema, Struwe and Albert2002; Sefi et al., Reference Sefi, Fetoui, Lachkar, Tahraoui, Lyoussi, Boudawara and Zeghal2011), certain aspects of Centaurium germination ecology have been studied in detail. The comparative germination study of Grime et al. (Reference Grime, Mason, Curtis, Rodman, Band, Mowforth, Neal and Shaw1981) reported germination of the biennial C. erythraea Rafn. over a wide range of temperatures (13–29°C) and only in light. Thompson and Grime (Reference Thompson and Grime1983) confirmed the light requirement for the same species and reported that germination was insensitive to temperature fluctuations, while Schat (Reference Schat1983) found very similar germination characteristics in another biennial, C. littorale (D. Turner) Gilmour. More recently, a series of studies focusing on the effects of salinity, manganese and plant growth regulators reported successful germination at 24–25°C in light (Mijajlovic et al., Reference Mijajlovic, Grubisic, Giba and Konjevic2005; Zivkovic et al., 2007; Todorovic et al., Reference Todorovic, Giba, Bacic, Nikolic and Grubisic2008, Reference Todorovic, Giba, Simonovic, Bozic, Banjanac and Grubisic2009; Misic et al., Reference Misic, Siler, Filipovic, Popovic, Zivkovic, Cvetic and Mijovic2009) for the same two species as well as for C. maritimum (L.) Fritsch, C. pulchellum (Swartz) Druce, C. spicatum (L.) Fritsch and C. tenuiflorum (Hoffmanns. & Link) Fritsch, all of them annual or biennial. All these reports also indicated that germination takes place without previous dormancy-breaking treatments, in contrast with the requirement for cold stratification found in other genera of Gentianaceae (Favarger, Reference Favarger1953) and the morphophysiological dormancy reported in Frasera caroliniensis Walt. (Threadgill et al., Reference Threadgill, Baskin and Baskin1981) and Sabatia angularis (L.) Pursh (Baskin and Baskin, Reference Baskin and Baskin2005). However, investigating dormancy was not the aim of any of the aforementioned Centaurium references, and they only studied lowland annual/biennial generalist species of broad geographical distribution. It remains to be seen if the same germination patterns apply in perennial Centaurium species, especially in those living in particular habitats departing from those commonly inhabited by the genus.

The rare C. somedanum M. Laínz shows several divergences from the general Centaurium traits, as it is a perennial chamaephyte and a specialist species of mountain calcareous springs (Jiménez-Alfaro et al., Reference Jiménez-Alfaro, Bueno Sánchez and Fernández Prieto2005). It is also a narrow endemic species, confined to a small geographical area (210 km2) located in a transitional region between Mediterranean and Oceanic climatic zones in the Cantabrian Mountain Range of north-west Spain (Jiménez-Alfaro et al., Reference Jiménez-Alfaro, Fernández-Pascual, García-Torrico, Bañares, Blanca, Güemes, Moreno and Ortiz2010). Because of the ecological and geographical uniqueness of C. somedanum, we may expect divergences from the general germination patterns of the annual/biennial, generalist and widely distributed Centaurium species. For example, temperate wetland species show a preference for relatively high (c. 30°C) or alternating germination temperatures (Grime et al., Reference Grime, Mason, Curtis, Rodman, Band, Mowforth, Neal and Shaw1981; Thompson and Grime, Reference Thompson and Grime1983; Schütz, Reference Schütz2000). Another possible adaptation of C. somedanum could be seed dormancy to avoid the risks of winter germination in a mountain environment (Baskin and Baskin, Reference Baskin and Baskin1998), although this dormancy could vary among years and populations, as is usually the case in wild species (Andersson and Milberg, Reference Andersson and Milberg1998; Giménez-Benavides et al., Reference Giménez-Benavides, Escudero and Pérez García2005).

In the present study, we investigated the germination ecology of C. somedanum as a contribution to understanding germination in Centaurium and the adaptation of rare endemic species to an ecological niche unusual in this genus. Specifically, we wanted to determine: (1) the temperature and light requirements for its germination; (2) the possible existence of physiological and/or morphological dormancy; and (3) the existence of inter-population and inter-annual variation in seed germinability.

Materials and methods

Plant material

Discrete populations of C. somedanum occur from 600 to 1700 m above sea level (asl) at the edges of calcareous mountain springs. In these habitats, alkaline spring waters (pH>7.7) flow from aquifers continuously through the year and are relatively cold even in summer (mean day temperature in late summer = 14.1 ± 0.2°C; data from 160 measurements covering the entire altitudinal gradient of the species). Depending on the slope and species composition of the spring edges, two habitat types harbour the populations of C. somedanum: vertical travertines and flat calcareous fens (Jiménez-Alfaro et al., Reference Jiménez-Alfaro, Bueno Sánchez and Fernández Prieto2005).

Although little information is available regarding its reproductive biology, C. somedanum is assumed to be a facultative outcrosser, like other species in the genus (Brys and Jacquemyn, Reference Brys and Jacquemyn2011). Flowering begins in early July, proceeds during summer and ripe seeds are dispersed in September and October (Jiménez-Alfaro et al., Reference Jiménez-Alfaro, Fernández-Pascual, García-Torrico, Bañares, Blanca, Güemes, Moreno and Ortiz2010). We observed abundant seedlings in the field in August, so we assume that emergence occurs in summer (mean summer temperature = 15°C, min. = 10°C, max. = 22°C), after the cold season has ended (mean winter temperature = 4°C, min. = 0°C, max. = 8°C) (data extrapolated from neighbouring climate stations, Spanish National Meteorological Agency). Seed set is relatively high in wild populations, with c. 140 seeds per fruit. The seeds are roughly spherical, extremely small (c. 390 μm wide) and show a reticulate pattern which is common in the Centaurium genus (Bouman et al., Reference Bouman, Cobb, Devente, Goethals, Maas, Smets, Struwe and Albert2002). Seed mass (c. 20 μg) is also similar to that of other Centaurium species (Royal Botanic Gardens Kew, 2008). The embryo belongs to Martin's dwarf category (Martin, Reference Martin1946).

For three consecutive years, we harvested fruits from the two largest populations of C. somedanum, which are representative of the two associated habitat types and the altitude gradient of the species (Table 1). In both sites, we sampled all individuals bearing ripe fruits (dry and brownish). The fruits spent a 3-week period in our laboratory (c. 22°C, 50% relative humidity) to ensure homogeneous after-ripening. Afterwards, we removed the seeds from the fruits; cleaned them using sieves and by hand sorting, and used them immediately in the experiments.

Table 1 Description of the two populations included in this study

Embryo measurements

We sowed seeds from 2009, from both populations, on 1% distilled water agar in Petri dishes (diameter 6 cm) sealed with Parafilm to prevent desiccation (four dishes with 25 seeds each per population) and kept them in continuous darkness for 24 h at 20°C. Afterwards, we excised and measured embryos from 15 seeds per population using a dissecting microscope (MZ6, Leica Microsystems GmbH, Wetzlar, Germany) equipped with a micrometer. The remaining seeds were cold stratified for 12 weeks (3°C, darkness) and then 15 embryos per population were measured. After cold stratification, seeds were incubated in a growth chamber (Grow-S 360, Ing. Climas, Barcelona, Spain) with a 12/12 h photoperiod (c. 20 μmol m− 2 s− 1 provided by six Philips TLD30W/54-765 cool fluorescent tubes) at 22/12°C, the summer temperature expected to be optimal. We examined them daily and when the seed coat began to split, i.e. when the embryo had reached its critical length for radicle emergence, we measured another 15 embryos per population. To analyse the embryo measurements, we performed a main effects analysis of variance (ANOVA) with stratification/incubation stage and population as fixed effects using SPSS for Windows 15.0.1 (SPSS Inc., Chicago, Illinois, USA).

Germination experiments

We carried out laboratory germination experiments on 1% distilled water agar in Petri dishes sealed with Parafilm. For each treatment, we sowed four dishes with 25 seeds each. To assess the effect of incubation temperature on germination, we incubated seeds from 2009, from both populations, in growth chambers under a 12/12 h photoperiod at 22/12, 15, 20, 25 and 30°C. To take into account the inter-annual variation on seed germinability, we also incubated seeds from 2008 and 2010 at 22/12°C. Finally, to assess the effect of light on germination, we incubated seeds from 2008 at 22/12°C in continuous darkness (achieved by wrapping the dishes in two layers of aluminium foil). In all cases, we incubated seeds both after 0 ( = fresh, i.e. after 3 weeks of after-ripening in the laboratory) and 12 ( = stratified) weeks of cold stratification in 1% agar at 3°C in darkness, to check for the existence of physiological dormancy. We did not consider warm stratification as it would be ecologically meaningless according to available knowledge on the habitat and dispersion timing of the species.

We counted and discarded germinated seeds three times a week (with the exception of the dark-incubated seeds, which we only checked at the end of the experiment). Radicle emergence was the criterion for germination. After 4 weeks, we terminated all germination tests and opened the non-germinated seeds with a scalpel, classifying them as normal, empty or fungus infected. We excluded the empty and infected seeds from the statistical analyses and the calculation of germination percentages (pooling all the dishes, empty seeds = 3 ± 1%; infected seeds = 3 ± 1%). We analysed the results by fitting main effects Generalized Linear Models (GLM, binomial error distribution, logit link function) with the test conditions as fixed factors, using SPSS.

Results

Embryo growth

We found significant differences in embryo length depending on the stage of the stratification/incubation process (F = 279.592; P < 0.001). While after cold stratification embryo length was similar to that of fresh embryos, at the point of radicle emergence embryos had undergone an increase of 86% in their length (Fig. 1). We did not detect significant differences in embryo growth between the populations (F = 0.029; P = 0.866).

Figure 1 Embryo length ( ± SE) in two populations (La Malva, grey bars; El Va{ l _{\dot } }{ l _{\dot } } e, white bars) at three different stages of the seed stratification–incubation process.

Germination temperature

Higher seed germination occurred at lower temperatures (15–22°C) with a marked decrease at warmer temperatures (Fig. 2). No seeds germinated at 30°C and only cold-stratified seeds germinated to a low percentage at 25°C. These two temperature regimes were qualitatively different and thus we did not include them in the statistical analysis, as their lack of variance would alter the GLM procedure. Analysing the results for the other three temperatures, we detected a significant positive effect of cold stratification on germination (Wald's χ2 = 186.720; P < 0.001) but neither an effect of incubation temperature (Wald's χ2 = 5.195; P = 0.074) nor of population (Wald's χ2 = 0.352; P = 0.553). Thus, in the range most favourable for seed germination, we did not find differences between constant (15, 20°C) and alternating (22/12°C) regimes and no differences between the germination temperature range of seeds from the two populations.

Figure 2 Final germination percentages of fresh (top panel) and stratified (bottom panel) seeds from two populations (La Malva, grey bars; El Va{ l _{\dot } }{ l _{\dot } } e, white bars) after 4 weeks of incubation at different temperatures. Percentages are the mean ±  SE of four dishes.

Germinability variation

We found differences in seed germinability among our collections (Fig. 3). Cold stratification produced a significant germination increase (Wald's χ2 = 222.293; P < 0.001) across years and populations, but we only obtained almost complete germination in 2008. In the other 2 years, a percentage (47–80%) of the seeds did not germinate after 12 weeks of cold stratification. Analysing together all years and populations, we found a significant effect of year (Wald's χ2 = 173.515; P < 0.001) but not of population (Wald's χ2 = 0.647; P = 0.421).

Figure 3 Cumulative germination of fresh (black circles) and stratified (open circles) seeds from each population and year of collection after 4 weeks of incubation at 22/12°C. The lines represent the Gompertz function fitted to the germination data using SigmaPlot 11.0 (Systat Software Inc., San José, California, USA).

Effect of light

Darkness had a clear negative effect on germination. When incubated in darkness, the fresh seeds did not germinate at all, and only 1 ± 1% cold-stratified seeds from one population (La Malva) did germinate. This clear-cut effect of darkness made it impossible, as well as unnecessary, to apply any statistical test.

Discussion

C. somedanum shows two significant divergences from the previously reported Centaurium germination patterns: (1) a lower germination temperature range; and (2) seed dormancy. Furthermore, its germination requirements are in contrast to the typical responses of wetland species (Grime et al., Reference Grime, Mason, Curtis, Rodman, Band, Mowforth, Neal and Shaw1981; Thompson and Grime, Reference Thompson and Grime1983; Schütz, Reference Schütz2000) as germination not only occurred at low temperatures, but also showed no increase in response to alternating temperatures. Among the tested conditions, highest germination occurred between 15 and 22°C. As we did not test colder temperatures, it is not possible to establish the lower temperature limit of the species. In addition, the low germination percentages achieved at 22/12°C in 2009 and 2010 could indicate that these are suboptimal conditions and that the optimal germination temperature is even lower. However, since the germination of the 2008 stratified seeds was almost complete at 22/12°C, the lower germination found in the following years seems more related to a deeper dormancy in those years, suggesting that the optimal germination temperature should not be too far from the 15–22°C range.

In any case, the upper germination temperature limit of C. somedanum is below what was expected. Germination at low temperatures is a common trait of lowland Mediterranean species (Escudero et al., Reference Escudero, Carnes and Pérez García1997; Doussi and Thanos, Reference Doussi and Thanos2002), and consequently the temperature requirement for C. somedanum germination would seem to be related to the Mediterranean origin of the genus. However, lower germination temperature ranges are usually interpreted as an adaptation to the seasonality of Mediterranean climates that prevents germination during the dry season (Doussi and Thanos, Reference Doussi and Thanos2002), and this is obviously not the case in the extremely wet environment of C. somedanum. The traditional understanding of germination in wetland habitats, as proposed by Thompson and Grime (Reference Thompson and Grime1983), indicates that the fall of the water table during the spring season produces rising soil temperatures and an increase in diurnal temperature fluctuations. Wetland seeds perceive these signals as marking the optimal season for germination, but the conditions may be very different in mountain spring habitats where water flow is continuous, and even more intense during the spring season when snowmelt recharges aquifers. In our study, seed germination and seedling establishment in C. somedanum take place in the soil of spring edges, where the constantly cold running waters heavily influence the temperature. According to data obtained by a soil data-logger in La Malva population (M-Log5W, GeoPrecision GmbH, Ettlingen, Germany; data from September 2010 to September 2011), the diurnal thermal amplitude in the soil of the spring edges is relatively low throughout the year (winter = 1.9 ± 0.1°C, summer = 3.0 ± 0.1°C) and the summer temperature is considerably less variable than expected (mean = 16.9°C, min. = 15.7°C, max. = 18.8°C). In this environment, germination at low and constant temperatures is probably the only option for the species. However, since we could not establish the lower germination temperature limit, it cannot be excluded that seed germination begins earlier in the year, as from April onwards the soil mean temperature exceeds 10°C.

The inability of C. somedanum to germinate at 25°C and above also differs from the successful germination achieved at 25°C (Mijajlovic et al., Reference Mijajlovic, Grubisic, Giba and Konjevic2005; Zivkovic et al., 2007; Todorovic et al., Reference Todorovic, Giba, Bacic, Nikolic and Grubisic2008, Reference Todorovic, Giba, Simonovic, Bozic, Banjanac and Grubisic2009) and the 29°C upper germination limit found by Grime et al. (Reference Grime, Mason, Curtis, Rodman, Band, Mowforth, Neal and Shaw1981) in generalist Centaurium species of broad European distribution. It is still necessary to determine whether the lower range in C. somedanum is an ancestral Mediterranean character of the genus, which was conserved in this rare endemic and allowed it to colonize the spring habitat; or if it is rather a recent adaptation acquired in the course of such colonization. Although the phylogenetic origin of C. somedanum is unclear, the molecular study of Mansion et al. (Reference Mansion, Zeltner and Bretagnolle2005) suggests an allopolyploid origin from the perennial C. scilloides (L. fil.) Samp and the biennial Spanish endemic C. gypsicola (Boiss & Reut.) Ronniger. C. scilloides is a generalist species widely distributed over the Atlantic coasts of Europe, while C. gypsicola is a specialist species of Mediterranean semi-arid gypsum communities of the central Iberian Peninsula. Thus, investigating the germination response of these species would shed some light on whether the low germination temperature trait of C. somedanum has a phylogenetic origin or is a new trait.

The second divergence from the Centaurium germination pattern regards the seed dormancy we found in the 3 years analysed, contrasting with the non-dormant behaviour reported in the literature for other Centaurium species. Our results show that C. somedanum seeds have non-deep simple morphophysiological dormancy (MPD) according to the classification system of Baskin and Baskin (Reference Baskin and Baskin2004) and that the embryo belongs to the underdeveloped linear embryo category proposed by Baskin and Baskin (Reference Baskin and Baskin2007). Fresh seeds have a non-deep physiological dormancy (PD) which prevents embryo growth and which is overcome by a period of cold stratification. As we did not test warm stratification, it is not possible to determine if cold is a requirement per se, but in nature this dormancy release takes place during the cold winter season. Once the PD is broken, embryo growth must take place before the seed germinates (morphological dormancy, MD). Since embryo growth did not occur during cold stratification, but did occur at warmer temperatures after the seeds were moved to 22/12°C, they have non-deep simple MPD. To our knowledge, this is the first time that MPD has been found in the Centaurium genus, although it has been reported in New World Gentianaceae genera (Threadgill et al., Reference Threadgill, Baskin and Baskin1981; Baskin and Baskin, Reference Baskin and Baskin2005). As we have already explained, the thermal regime in the spring habitat is stable during the year in comparison to other, more seasonal, wetland environments. In this context, seed dormancy becomes of foremost importance to ensure that germination takes place in the correct period of the year, i.e. after the colder months of winter.

It is interesting to note that, contrary to what happened with the temperature and light requirements, we found a relatively large variation among seed collections in their germinability. Such variation, depending on year and population, is a well-known phenomenon (Andersson and Milberg, Reference Andersson and Milberg1998; Giménez-Benavides et al., Reference Giménez-Benavides, Escudero and Pérez García2005), which has been usually related to genetic adaptation to local conditions or to the parental environment effect on seed maturation (Fenner, Reference Fenner1991; Baskin and Baskin, Reference Baskin and Baskin1998). In our case study, the significant effect of year rather than location suggests that it is the environment in each maturation season that determines seed germinability. Nevertheless, further studies controlling either the seed maturation environment (common garden studies) or the genetic background of the populations are necessary to elucidate the relative contribution of the genotype versus the environment.

Besides the divergences commented on above, C. somedanum germination agrees with previous Centaurium studies regarding the lack of response to alternating temperatures (Thompson and Grime, Reference Thompson and Grime1983) and the light requirement for germination (Grime et al., Reference Grime, Mason, Curtis, Rodman, Band, Mowforth, Neal and Shaw1981; Schat, Reference Schat1983). The incapacity to germinate in darkness is a trait generally associated with the ability to form a soil seed bank (Pons, Reference Pons1991; Milberg, Reference Milberg1994) especially in small seeds (Milberg et al., Reference Milberg, Andersson and Thompson2000). Other traits of C. somedanum seeds tend to be related to persistence in the soil bank, namely their small size and rounded shape (Thompson et al., Reference Thompson, Band and Hodgson1993; Cerabolini et al., Reference Cerabolini, Ceriani, Caccianiga, De Andreis and Raimondi2003). Thus, it is possible that C. somedanum forms a persistent soil seed bank, as has been reported for other Centaurium species (Thompson et al., Reference Thompson, Bakker and Bekker1997).

In conclusion, our study shows that a rare perennial species of Centaurium living in an unusual habitat presents divergences from the general germination patterns of the genus. The lower germination temperature range in C. somedanum could be of adaptive significance in the very particular conditions of mountain springs, where water flow is continuous and relatively cold throughout the year. It would be of great interest to study the germination temperature ranges of those species phylogenetically linked to C. somedanum, i.e. C. scilloides and C. gypsicola, to improve understanding of the evolutionary history of this trait in the genus. Additionally, it remains to be seen if MPD, a possible adaptation to mountain spring habitats, is shared by more Centaurium species, especially those with a similar ecology, such as C. littorale subsp. uliginosum (Waldst. & Kit.) Melderis, which lives in travertines and calcareous fens of central Europe. Our findings also suggest that the germination traits of species living in temperate mountain springs could differ from those living in other wetland types, although more studies focused on spring specialists are needed to clarify germination ecology in these habitats.

Acknowledgements

We would like to thank C. Álvarez, R. Álvarez, Á. Bueno, E. Moratón and J.I. Sanzo for their help during seed collection, and C. Baskin and two anonymous reviewers for their insightful comments on the manuscript and the English revision. The Fundación Biodiversidad (Spanish Ministry of the Environment) funded this research through the project Conservación ex situ de plantas amenazadas de máxima prioridad en el norte peninsular: Aster pyrenaeus y Centaurium somedanum. E.F.P. received a PhD grant from the Government of Asturias (Plan de Ciencia, Tecnología e Innovación del Principado de Asturias) and B.J.A. from the European Social Fund through the Spanish Ministry of Science (PTA2007-0726-I).

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Figure 0

Table 1 Description of the two populations included in this study

Figure 1

Figure 1 Embryo length ( ± SE) in two populations (La Malva, grey bars; El Va{ l _{\dot } }{ l _{\dot } } e, white bars) at three different stages of the seed stratification–incubation process.

Figure 2

Figure 2 Final germination percentages of fresh (top panel) and stratified (bottom panel) seeds from two populations (La Malva, grey bars; El Va{ l _{\dot } }{ l _{\dot } } e, white bars) after 4 weeks of incubation at different temperatures. Percentages are the mean ±  SE of four dishes.

Figure 3

Figure 3 Cumulative germination of fresh (black circles) and stratified (open circles) seeds from each population and year of collection after 4 weeks of incubation at 22/12°C. The lines represent the Gompertz function fitted to the germination data using SigmaPlot 11.0 (Systat Software Inc., San José, California, USA).