Hostname: page-component-745bb68f8f-b95js Total loading time: 0 Render date: 2025-02-06T15:02:08.078Z Has data issue: false hasContentIssue false
  • English
  • Français

Maternal effects on seed heteromorphism: a dual dynamic bet hedging strategy

Published online by Cambridge University Press:  05 July 2019

Li Jiang ,
Lei Wang Open the ORCID record for Lei Wang [Opens in a new window] ,
Carol C. Baskin ,
Changyan Tian  and
Zhenying Huang
Li Jiang
Affiliation:
State Key Laboratory of Desert and Oasis Ecology, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China
Lei Wang*
Affiliation:
State Key Laboratory of Desert and Oasis Ecology, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China
Carol C. Baskin
Affiliation:
Department of Biology, University of Kentucky, Lexington, KY 40506, USA Department of Plant and Soil Sciences, University of Kentucky, Lexington, KY 40546, USA
Changyan Tian
Affiliation:
State Key Laboratory of Desert and Oasis Ecology, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China
Zhenying Huang*
Affiliation:
State Key Laboratory of Vegetation and Environmental Change, Institute of Botany, Chinese Academy of Sciences, Beijing, China
*
Author for correspondence: Lei Wang, Email: egiwang@ms.xjb.ac.cn and Zhenying Huang, Email: zhenying@ibcas.ac.cn
Author for correspondence: Lei Wang, Email: egiwang@ms.xjb.ac.cn and Zhenying Huang, Email: zhenying@ibcas.ac.cn
Rights & Permissions [Opens in a new window]

Abstract

Maternal effects on offspring seeds are mainly caused by seed position on, and the abiotic environment of, the mother plant. Seed heteromorphism, a special form of position effect, is the production by an individual plant of morphologically distinct seed types, usually with different ecological behaviours. Seed heteromorphism is assumed to be a form of bet hedging and provides an ideal biological model to test theoretical predictions. Most studies of maternal effects on seeds have focused on abiotic environmental factors and changes in mean seed traits of offspring. Suaeda salsa is an annual halophyte that produces dimorphic seeds within the same inflorescence. We tested the hypothesis that plants grown from brown seeds of S. salsa have a higher offspring brown seed:black seed morph ratio and variance in seed size than plants from black seeds. Results from a pot experiment showed that plants grown from brown seeds had a higher brown seed:black seed ratio than plants grown from black seeds. This is the first layer of dynamic bet hedging. Brown seeds had higher size variation than black seeds, and seeds produced by plants from brown seeds also had higher seed size variation than plants grown from black seeds. This is the second layer of dynamic bet hedging. Thus, the maternal effect of seed heteromorphism is dual dynamic bet hedging. Furthermore, for seed traits we verified for the first time the theoretical prediction that an increase in offspring size variability induces an increase in the mean size of offspring.

Keywords

bet hedgingmaternal effectseed heteromorphismseed sizeSuaeda
Type
Short Communication
Information
Seed Science Research , Volume 29 , Issue 2 , June 2019 , pp. 149 - 153
Copyright
Copyright © Cambridge University Press 2019 

Introduction

For plants, maternal effects occur when the abiotic environment experienced during growth and maturation of the maternal plant influences the offspring phenotype beyond the direct effect of transmitted genes (Gutterman and Fenner, Reference Gutterman and Fenner2000; Marshall and Uller, Reference Marshall and Uller2007). Seeds are simultaneously an important maternal component and subsequent offspring. Maternal conditions influencing seed traits include seed position on the parent plant (e.g. seed position in the fruit, seed position in the inflorescence, position of the inflorescence on the mother plant, etc.), age of the mother plant and abiotic environment of the plant (e.g. light quality, mineral nutrition or salinity) during seed development (Gutterman and Fenner, Reference Gutterman and Fenner2000; El-Keblawy et al., Reference El-Keblawy, Gairola and Bhatt2016; Doudová et al., Reference Doudová, Douda and Mandák2017). Seed position can affect a series of seed traits in many plants, and it is often accompanied by seed heteromorphism (Gutterman and Fenner, Reference Gutterman and Fenner2000; Imbert, Reference Imbert2002; Kołodziejek, Reference Kołodziejek2017).

Seed heteromorphism is the production by an individual plant of morphologically distinct seed types (morphs), usually with different ecological behaviours, including dispersal ability, dormancy and germination (Venable, Reference Venable1985; Khan et al., Reference Khan, Gul and Weber2001; Imbert, Reference Imbert2002; Yao et al., Reference Yao, Lan and Zhang2010; Liu et al., Reference Liu, Wang, Tanveer and Song2018). For example, on one individual of the annual Aethionema arabicum mucilaginous seeds in dehiscent fruits support anti-telechory, while non-mucilaginous seeds in indehiscent fruits support telechory (Arshad et al., Reference Arshad, Sperber, Steinbrecher, Nichols, Jansen, Leubner-Metzger and Mummenhoff2019). Considering distinct seed traits, seed heteromorphism is an ideal biological phenomenon with which to test theoretical predictions about ecological adaptations.

Seed heteromorphism often is considered to be a typical example of adaptive bet hedging in a highly variable environment (Hughes, Reference Hughes2018). According to the model for the ecology and evolution of seed heteromorphism developed by Venable (Reference Venable1985), there are two kinds of seed heteromorphism: high-risk–low-risk (one morph with a high mean fitness but high risk of reproductive failure and another morph with a low mean fitness and a low risk of failure) and high-risk–high-risk (high mean fitness and high risk of reproductive failure for each seed morph). Production of two or more seed types with different ecological strategies by a single individual is adaptive via bet hedging in an unpredictable environment because among-generation variance of reproductive success is reduced, and thus the geometric mean fitness is increased (Crean and Marshall, Reference Crean and Marshall2009; Sadeh et al., Reference Sadeh, Guterman, Gersani and Ovadia2009; Simons, Reference Simons2011; Hughes, Reference Hughes2018). Variation in seed morph ratio reflects the prediction of plants to good/bad years and the factors that influence this variation include the phenotype of maternal plant, nutrient availability, competition and others (Venable, Reference Venable1985; Wang et al., Reference Wang, Baskin, Baskin, Cornelissen, Dong and Huang2012; Doudová, Reference Doudová, Douda and Mandák2017). Plants grown from heteromorphic seeds differ in biomass, salt tolerance, competition ability and seed production (Imbert, Reference Imbert2002; Wang et al., Reference Wang, Baskin, Baskin, Cornelissen, Dong and Huang2012; Sendek et al., Reference Sendek, Herz, Auge, Hensen and Klotz2015).

Most studies of maternal effects on seeds have focused on abiotic environmental factors or on changes in the mean offspring seed traits (Cheplick and Quinn, Reference Cheplick and Quinn1983; Galloway, Reference Galloway2005; Lu et al., Reference Lu, Tan, Baskin and Baskin2012). In fact, the phenotype of the mother plant can influence variation of offspring seed size (Wang et al., Reference Wang, Baskin, Baskin, Cornelissen, Dong and Huang2012). Furthermore, there is size variation even within each seed type in heteromorphic plants (Mandák and Pyšek, Reference Mandák and Pyšek1999). Seed size variance is the response of mother plants to environmental unpredictability to gain maximum fitness (Wang et al., Reference Wang, Baskin, Baskin, Cornelissen, Dong and Huang2012). Suaeda salsa (L.) Pall. (Amaranthaceae) is an annual halophyte, producing dimorphic seeds at specific positions in the inflorescence. Freshly matured brown seeds absorb water more quickly and have a higher germination percentage and velocity than black seeds under different levels of salinity (Song and Wang, Reference Song and Wang2015). Maternal salinity level can affect offspring seed germination and other traits (Wang et al., Reference Wang, Xu, Wang, Shi, Liu, Feng and Song2015). Based on the theory of Venable (Reference Venable1985) and Hughes (Reference Hughes2018), dimorphic seeds of this species show high-risk–low-risk heteromorphism: brown seeds represent the high-risk strategy and black seeds the low-risk strategy. Dynamic bet hedging is a phenomenon in which mother plants adaptively change the variation of offspring traits (Crean and Marshall, Reference Crean and Marshall2009). In this study, we tested the dual dynamic bet hedging hypothesis that plants grown from brown seeds of S. salsa have a higher offspring brown seed:black seed morph ratio and variance in seed size than plants from black seeds under different levels of salinity.

Based on the possibility that an offspring size fitness function is asymmetrical, Crean and Marshall (Reference Crean and Marshall2009) speculated that an increase in offspring size variability will increase the mean size of offspring. In this study, we tested this hypothesis using dimorphic seeds of S. salsa.

Materials and methods

Study species and seed collection

Suaeda salsa, a succulent halophyte, occurs on saline soil or in inter-tidal zones. The average total salt content of dry soil at the sampling site is 5.2 g kg–1. The average annual temperature is 13°C and the annual rainfall is 560–690 mm. Seeds germinate in April, and plants mature seeds in October in the field. Freshly matured fruits of S. salsa were collected from plants in a natural population (37°20′N; 118°36′E) growing in saline soil on the Yellow River Delta in Shandong Province, China, in October 2011. Fruits were taken from at least 50 plants and allowed to dry naturally at ambient room conditions. Seeds were separated and sorted into brown and black seeds. The mean length of brown and black seeds was 1.38 and 1.14 mm, respectively. The brown seed:black seed ratio was 2.4. The dimorphic seeds were stored at 4°C until transferred to the Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, in March 2012. The seeds were then stored at room temperature until used in this study.

Pot experiment

A pot experiment was carried out in a greenhouse (28 ± 3°C by day, 18 ± 3°C at night, natural light conditions) at Fukang Field Research Station of the Chinese Academy of Sciences (44°17′N, 87°56′E; 460 m above sea-level) in Xinjiang Province, China. To reduce the effect of differential germination time of the dimorphic seeds of S. salsa, black seeds were cold stratified for 20 days to break dormancy. About 20 seeds of each morph were sown at a soil depth of 2 mm in individual plastic pots (17 cm deep and 16 cm in diameter) filled with 2000 cm3 mix of quartz sand and vermiculite (3:1 v/v) on 15 April 2012. After 20 days, seedlings were thinned to one per pot, at which time all seedlings were about 3 cm tall.

A randomized block design with six replicates was used. Each block contained six pots representing a combination of two seed morphs and three salinity levels. There was a total of 36 pots. For fertilization, a commonly available granular lawn fertilizer (Osmocote 301, Scotts, Marysville, OH, USA) and a commercial nutrient solution (Peters1, Scotts) were used. Each pot received 1.2 g Osmocote 301 once before sowing as basic fertilizer and 100 ml Peters1 nutrient solution (0.03 g l–1) once each week as supplemental fertilizer, beginning 4 weeks after sowing. For salinity treatment, a mixed salt with a 20 NaCl:20Na2SO4:1NaHCO3 (mass ratio) was used. The pots receiving low, moderate and high salinity received 100 ml salinity solution (0.3 g l–1) twice a week, 100 ml salinity solution (1.1 g l–1) twice a week and 100 ml salinity solution (4.4 g l–1) twice a week, respectively. The pots were watered every day. The experiment was terminated on 25 October 2012, and offspring seeds were the harvested. This is a self-compatible and autogamous (or wind-pollinated) species (Jie Song, Shandong Normal University, personal communication, 1 March 2019).

Seed production and size

The mass of each seed morph for each individual plant was determined using a microbalance (Chyo Balance, JPN-200W). Offspring seed ratio was calculated as the mass of brown seeds divided by the mass of black seeds on a single plant. The diameter of 20 randomly selected brown and black seeds from each plant was measured using a computer imaging system. Seed size variation was expressed as the coefficient of variation per treatment: CV = (standard deviation/mean) × 100%.

Statistical analyses

ANOVA assumptions were checked, and seed ratio data followed a normal distribution. Two-way ANOVA was used to determine the significant effects of salinity and maternal seed type and their interaction on offspring seed ratio. Data for seed diameter and its CV were analysed by linear regression using the enter linear regression method (all independent variables ware entered into the equation in a single step). The multiple linear regression model included maternal seed type, offspring seed type (brown seed and black seed) and salinity (low, moderate and high). All statistical analyses were conducted using SPSS 16.0 (SPSS, Inc., Chicago, IL, USA).

Results

We counted the block effects, and there was no significant effect (P = 0.136). ANOVA results showed that the offspring seed ratio was significantly affected by maternal seed type (P = 0.01), but it was not significantly affected by salinity (P = 0.455) or the interaction between salinity and seed morph type (P = 0.834). Seed ratio (mean values ranged from 2.93 to 4.24) of plants from brown seeds was higher than that (from 1.60 to 1.85) of plants from black seeds (Fig. 1).

Fig. 1. Effect of maternal seed type on the brown seed:black seed mass ratio of S. salsa plants grown at three levels of salinity. *Significant difference between the two plant types at a salinity level with Tukey's test (P < 0.05). Error bars represent standard error (SE).

Offspring seed diameter was significantly affected by maternal seed type (P < 0.001) but not significantly affected by offspring seed type (P = 0.190) or salinity (P = 0.697) (Table 1). For each seed type, seed diameter of plants from brown seeds was significantly higher than that of plants from black seeds under different levels of salinity (Fig. 2a,b).

Table 1. Multivariate analysis of correlates associated with diameter and its CV of heteromorphic seeds of S. salsa

SE, standard error.

Fig. 2. Effect of maternal seed type on mean diameter of (a) brown and (b) black seeds, and on CV (coefficient of variation) of seed diameter for (c) brown and (d) black seeds of S. salsa grown at three levels of salinity. *Significant difference between the two plant types at a salinity level with Tukey's test (P < 0.05). Error bars represent standard error (SE).

Variability in diameter of offspring seeds was significantly affected by maternal seed type (P < 0.05), offspring seed type (P  < 0.001) and salinity (P < 0.05) (Table 1). The CV of brown seed diameter was significantly higher than that of black seeds (Fig. 2c,d). Seed size variability of plants from brown seeds was higher than that of plants from black seeds (Fig. 2c,d). With an increase in maternal salinity, variation in offspring (seed) diameter of both seed types in plants from brown seeds decreased accordingly. However, for mother plants from black seeds variation in diameter of dimorphic seeds was lowest at moderate salinity (Fig. 2c,d).

Discussion

Effects of the maternal seed type on offspring seed traits have been studied extensively (Imbert, Reference Imbert2002; Lu et al., Reference Lu, Tan, Baskin and Baskin2012; Wang et al., Reference Wang, Baskin, Baskin, Cornelissen, Dong and Huang2012; Doudová et al., Reference Doudová, Douda and Mandák2017). However, our data are the first to document variance in offspring seed size via interactions between maternal seed type and offspring seed type. In addition, our data indicate that plants grown from brown seeds of S. salsa have a higher offspring brown seed:black seed ratio and variance in seed size than plants from black seeds. The results suggest that S. salsa has a dual dynamic bet hedging strategy, which would be adaptive to the environmental uncertainty of its saline habitat (Song and Wang, Reference Song and Wang2015), but to show this fitness needs to be determined.

Our results indicated that regardless of the maternal seed type, mother plants produce both types of seeds. This result suggests that both plant types have a bet hedging strategy because they cannot successfully predict their offspring's environment. However, plants grown from brown seeds produced a higher brown seed:black seed ratio than those produced by plants from black seeds. Brown seeds of S. salsa are non-dormant and have high germinability, high salt tolerance and a high-risk strategy, whereas black seeds are dormant and have low germinability, low salt tolerance and a low-risk strategy (Venable, Reference Venable1985; Song and Wang, Reference Song and Wang2015). The function of producing dimorphic seeds is to minimize total fitness variance. The function of producing more brown seeds by plants grown from brown seeds is to maximize the fitness-risk ratio (Hughes, Reference Hughes2018). Thus, the ratio of dimorphic seeds is a risk index, and plants from brown seeds have a higher risk index than those from black seeds. This seed-set pattern suggests that mother plants can adaptively adjust variance by changing the seed type ratio, i.e. a form of dynamic bet hedging, which Sadeh et al. (Reference Sadeh, Guterman, Gersani and Ovadia2009) called plastic bet hedging.

Not only did the ratio of dimorphic seeds vary but seed size also varied. Size variation of brown seeds of S. salsa was significantly higher than that of black seeds. Furthermore, seeds produced by plants from brown seeds had a higher size variation than those produced by plants from black seeds. Maternal effect of seed size variation suggests that mother plants adaptively adjust seed traits above the effect of the dynamic shift in seed morph ratio, which is recognized as the second layer of dynamic bet hedging. Thus, the maternal effect of seed heteromorphism is probably dual dynamic bet hedging. There are some important ecological implications of this dual strategy. On the one hand, S. salsa produces heteromorphic seeds and increases within-clutch variation in seed size that allows the species to cope with environmental uncertainty. On the other hand, it adaptively adjusts seed morph ratio and seed size of each morph according to the environmental predictability of mother plants. This integrated strategy might be a trade-off between geometric mean fitness among generations and arithmetic mean fitness within generations (Crean and Marshall, Reference Crean and Marshall2009).

In our experiment, different salinity treatments did not significantly affect seed morph ratio and most variation of seed size. Similar findings have been reported for Suaeda aralocaspica (Wang et al., Reference Wang, Baskin, Baskin, Cornelissen, Dong and Huang2012). This result can be explained by the fact that our salinity levels just reflect the range of salinity in the field and not the range of salinities that limit plant growth and reproduction of this species. The brown seed:black seeds ratio of S. salsa plants grown from brown seeds is 3.8 under 500 mmol l–1 NaCl (Wang et al., Reference Wang, Xu, Wang, Shi, Liu, Feng and Song2015). This salinity treatment is in the range between moderate and high salinity treatment in our experiment and the seed morph ratio is also in our ratio range between moderate and high salinity (2.9–4.2). However, the seed morph ratio of S. salsa plants grown from brown seeds is ca 2 under 1 mmol l–1 NaCl (Wang et al., Reference Wang, Xu, Wang, Shi, Liu, Feng and Song2015). In other words, unfavourable salinity will increase the percentage of black seeds that represent low-risk strategy. These results indicate that our salinity levels did not cause significant changes for most seed traits, and only a very low or high level of salinity could change seed morph ratio and variation of seed size in this species. Further work is necessary to determine the low and high salinity limitations for variation in seed traits.

If an experimental manipulation induces an increase in offspring size variation and retains the same mean size of their offspring, then part of the offspring should decrease to a certain minimum size threshold. Thus, mothers should increase offspring mean size (Crean and Marshall, Reference Crean and Marshall2009). In our study, we found support for the prediction. For each offspring seed type, seed size variability of plants from brown seeds was higher than that of plants from black seeds. Accordingly, the size of seeds produced by plants from brown seeds was significantly larger than that produced by plants from black seeds. Furthermore, when comparing offspring mean size and variation under different levels of salinity, we also find this increasing trend. The induction of an adaptive shift in offspring mean seed size is a side-effect of offspring seed size variation. This shift highlights the internal relevance of mean and variance in offspring seed size. This is the first verification of this theoretical prediction for plant traits.

In conclusion, our results suggest that the diaspore heteromorphic species S. salsa probably has a dual dynamic bet hedging strategy that allows it to cope with environmental uncertainty. In addition, our study is the first to show excellent agreement with the theoretical prediction that an increase in offspring size variability in seed traits increases mean size of offspring (seeds). We suggest that the dual bet hedging concept is a useful framework for understanding the life history strategies of heteromorphic species.

Author ORCIDs

Lei Wang, 0000-0002-8253-7295.

Financial support

This work was supported by the National Natural Science Foundation of China (31770451) and Foundation for Western Young Scholars, Chinese Academy of Sciences (2017-XBQNXZ-A-001).

Conflicts of interest

None.

References

Arshad, W, Sperber, K, Steinbrecher, T, Nichols, B, Jansen, VAA, Leubner-Metzger, G and Mummenhoff, K (2019) Dispersal biophysics and adaptive significance of dimorphic diaspores in the annual Aethionema arabicum (Brassicaceae). New Phytologist 221, 14341446.Google Scholar
Cheplick, GP and Quinn, JA (1983) The shift in aerial/subterranean fruit ratio in Amphicarpum purshii: causes and significance. Oecologia 57, 374379.Google Scholar
Crean, AJ and Marshall, DJ (2009) Coping with environmental uncertainty: dynamic bet hedging as a maternal effect. Philosophical Transactions of the Royal Society of London Series B - Biological Sciences 364, 10871096.Google Scholar
Doudová, J, Douda, J and Mandák, B (2017) The complexity underlying invasiveness precludes the identification of invasive traits: a comparative study of invasive and non-invasive heterocarpic Atriplex congeners. PloS ONE 12, e0176455.Google Scholar
El-Keblawy, A, Gairola, S and Bhatt, A (2016) Maternal salinity environment affects salt tolerance during germination in Anabasis setifera: a facultative desert halophyte. Journal of Arid Land 8, 254263.Google Scholar
Galloway, LF (2005) Maternal effects provide phenotypic adaptation to local environmental conditions. New Phytologist 166, 9399.Google Scholar
Gutterman, Y and Fenner, M (2000) Maternal effects on seeds during development. In Seeds: The Ecology of Regeneration in Plant Communities (2nd edn), pp. 5984. Wallingford, UK: CABI Press.Google Scholar
Hughes, PW (2018) Minimal-risk seed heteromorphism: proportions of seed morphs for optimal risk-averse heteromorphic strategies. Frontiers in Plant Science 9, 1412.Google Scholar
Imbert, E (2002) Ecological consequences and ontogeny of seed heteromorphism. Perspectives in Plant Ecology Evolution and Systematics 5, 1336.Google Scholar
Khan, MA, Gul, B and Weber, DJ (2001) Germination of dimorphic seeds of Suaeda moquinii under high salinity stress. Australian of Jouranl Botany 49, 185192.Google Scholar
Kołodziejek, J (2017) Effect of seed position and soil nutrients on seed mass, germination and seedling growth in Peucedanum oreoselinum (Apiaceae). Scientific Reports 7, 1959.Google Scholar
Liu, RR, Wang, L, Tanveer, M and Song, J (2018) Seed heteromorphism: an important adaptation of halophytes for habitat heterogeneity. Frontiers in Plant Science 9, 1515.Google Scholar
Lu, JJ, Tan, DY, Baskin, JM and Baskin, CC (2012) Phenotypic plasticity and bet-hedging in a heterocarpic winter annual/spring ephemeral cold desert species of Brassicaceae. Oikos 121, 357366.Google Scholar
Mandák, B and Pyšek, P (1999) Effects of plant density and nutrient levels on fruit polymorphism in Atriplex sagittata. Oecologia 119, 6372.Google Scholar
Marshall, DJ and Uller, T (2007) When is a maternal effect adaptive? Oikos 116, 19571963.Google Scholar
Sadeh, A, Guterman, H, Gersani, M and Ovadia, O (2009) Plastic bet-hedging in an amphicarpic annual: an integrated strategy under variable conditions. Ecology and Evolution 23, 373388.Google Scholar
Sendek, A, Herz, K, Auge, H, Hensen, I and Klotz, S (2015) Performance and responses to competition in two congeneric annual species: does seed heteromorphism matter? Plant Biology 17, 12031209.Google Scholar
Simons, AM (2011) Modes of response to environmental change and the elusive empirical evidence for bet hedging, Proceedings of the Royal Society B - Biological Sciences 278, 16011609.Google Scholar
Song, J and Wang, BS (2015) Using euhalophytes to understand salt tolerance and to develop saline agriculture: Suaeda salsa as a promising model. Annals of Botany 115, 541553.Google Scholar
Venable, DL (1985) The evolutionary ecology of seed heteromorphism. American Naturalist 126, 577595.Google Scholar
Wang, L, Baskin, JM, Baskin, CC, Cornelissen, JHC, Dong, M and Huang, ZY (2012) Seed dimorphism, nutrients and salinity differentially affect seed traits of the desert halophyte Suaeda aralocaspica via multiple maternal effects. BMC Plant Biology 12, 170.Google Scholar
Wang, F, Xu, Y, Wang, S, Shi, W, Liu, R, Feng, G and Song, J (2015) Salinity affects production and salt tolerance of dimorphic seeds of Suaeda salsa. Plant Physiology and Biochemistry 95, 4148.Google Scholar
Yao, S, Lan, H and Zhang, F (2010) Variation of seed heteromorphism in Chenopodium album and the effect of salinity stress on the descendants. Annals of Botany 105, 10151025.Google Scholar
Figure 0

Fig. 1. Effect of maternal seed type on the brown seed:black seed mass ratio of S. salsa plants grown at three levels of salinity. *Significant difference between the two plant types at a salinity level with Tukey's test (P < 0.05). Error bars represent standard error (SE).

Figure 1

Table 1. Multivariate analysis of correlates associated with diameter and its CV of heteromorphic seeds of S. salsa

Figure 2

Fig. 2. Effect of maternal seed type on mean diameter of (a) brown and (b) black seeds, and on CV (coefficient of variation) of seed diameter for (c) brown and (d) black seeds of S. salsa grown at three levels of salinity. *Significant difference between the two plant types at a salinity level with Tukey's test (P < 0.05). Error bars represent standard error (SE).