Seed collection

Freshly matured seeds from ten populations of E. nutans were collected in September 2016 along an altitudinal gradient on the eastern Qinghai-Tibet Plateau (Gansu province, China) (Fig. 2). Infructescences with ripe seeds were collected from several hundred individual plants at each of the ten collection sites and taken to the laboratory, where seeds were separated from other plant material. Seeds were dried at room temperature for 1 week (RH 20–35%, 18–25°C) and stored at −20°C until used in experiments. Germination tests and field experiments for fresh seeds were conducted within 2 weeks after seed collection.

Figure 2. Locations of seed collection sites and common garden sites.

Laboratory germination experiments

Germination responses to temperature were tested for fresh seeds from all populations by incubation at 10, 15, 20 and 25°C in light (12/12 h). Photon irradiance was 60 μmol m⁻² s⁻¹, 400–700 nm, from white fluorescent tubes. For each test, three replicates of 50 seeds were placed in 10 cm Petri dishes on two sheets of filter paper (Shuangquan, Hangzhou, China) moistened with 7 ml distilled water. All Petri dishes were placed in the incubator and distilled water was added daily as needed to keep the filter paper moist. Germination was monitored daily for at least 28 days until no further germination occurred for three consecutive days. Seeds were counted as germinated when the radicle was visible (≥2 mm).

To determine the effect of dry storage on seed germination, fresh seeds from each of the ten populations were placed in paper bags and stored at room temperature (RH 20–35%, 18–25°C) for 6 months. After dry storage, germination was tested at 10, 15, 20 and 25°C in light as described earlier.

Common garden experiments

To determine the effect of population, growing site, dry storage and their interactions on seedling establishment, both fresh and stored (RH 20–35%, 18–25°C, 6 months) seeds from seven (a, b, f, g, h, i and j) out of the ten populations were sown at Xiahe (35°11′ N, 102°35′ E, 2900 m a.s.l, hereafter XH) and Maqu (34°41′ N, 101°52′ E, 3500 m a.s.l, hereafter MQ) on the Plateau. Fresh seeds were sown in October 2016, and stored seeds were sown in April 2017. XH has a Mean annual temperature (MAT) and mean annual precipitation (MAP) of 2.6°C and 516 mm, respectively, and for MQ 1.2°C and 620 mm, respectively.

The field experiment was performed in a completely randomized block design. Twenty replicates per population and 20 seeds per replicate were used in this experiment. A total of 11,200 seeds was used in common garden experiments (2 common gardens × 7 populations × 20 replicates × 20 seeds × 2 seed states). To facilitate the identification of emerging seeds, we prepared the ground by placing iron fences with a grid size of 5 × 5 cm and securing them with u-nails before sowing. For each seed population, the seeds were sown (one seed per each 5 × 5 cm area) at a depth of 1 cm with a spacing between each sowing of 20 cm. Seedling emergence and survival were monitored every 2 weeks for 5 months during the growing season. A seedling was counted as emerged when the true leaves were visible, and a seedling was classified as surviving if it remained without withering or dying after emerging from the ground. The emergence percentage was calculated by dividing the number of seeds that have emerged by the number of seeds sown, while the survival percentage was determined by dividing the number of seedlings that survived by the number of seedlings that emerged. During the growing season, weeds were manually removed at 2-week intervals without applying any herbicide treatment.

Soil sampling and chemical measurements

Three soil samples were collected from each of the 10 sites in 2016. Each sample was comprised of five soil cores (0–10 cm depth) taken with a soil auger (7.5 cm inner diameter). All soil samples were placed in individual plastic bags and immediately stored in a portable refrigerator. In the laboratory, all soil samples were subdivided into two subsamples. One subsample was stored at 4°C until analysis for ${\rm NO}_3^-$-N (NON) and ${\rm NH}_4^ +$-N (NHN). The second subsample was air-dried at room temperature and used for analysing available phosphorus (AP). To determine NON and NHN, a subsample of 10 g fresh soil was extracted in 50 ml of a 2M KCl solution and then analysed by colorimetry (UV-1601, Shimadzu Inc.). AP was extracted in 50 ml of a 0.5 M NaHCO₃ solution (pH = 8.5) from 5 g dry soil subsample, and then the amount was measured calorimetrically using the molybdate-ascorbic acid method UV-1601, Shimadzu Inc.).

Climate data

Climate data were obtained from the Loess Plateau SubCenter, National Earth System Science Data Center, National Science and Technology Infrastructure of China (http://loess.geodata.cn) (Peng et al., Reference Peng, Ding, Liu and Li2019). MAT and MAP from 2000 to 2020 were used to characterize the climatic variations at the ten seed collection sites. MAT and MAP data for the ten collection sites were extracted through ArcGIS.

Data analysis

Generalized linear mixed models (GLMMs) were performed, using the glmer function in the lme4 package of R version 4.1.2 to investigate the effect of storage, population, temperature and their interactions on germination percentage and germination speed (1/t_g). Similarly, the effect of common garden, storage, population and their interactions on seedling emergence and seedling survival were tested by fitting GLMMs. In each model, these variables were used as fixed effects, while replicates were included as random effects. Seed germination and seedling establishment were a probability ranging from 0 to 1; hence, we applied a binomial estimation of the model using a logit link function. Duncan's test was used to compare means when significant differences were found.

Germination speed was represented by 1/t_g (the reciprocal of t_g), and t_g is defined as the time to reach a given germination fraction g. t_g was estimated using a GERMINATOR package developed by Joosen et al. (Reference Joosen, Kodde, Willems, Ligterink, van der Plas and Hilhorst2010) using the visual basic module from Microsoft Excel.

A thermal time model was used to quantify the temperature requirements at suboptimal temperature ranges for seed germination according to Bradford (Reference Bradford2002). Germination percentage response can be expressed as:

$$\theta _{T( g ) } = ( {T\;{-} \;T_{\rm b}} ) \;\cdot \;t_g$$

and the relationship among germination percentage, imbibition time and temperature is:

$${\rm \;probit( g) }\;{\rm} = \displaystyle{{{\rm ln\;}( {( {T{\rm \;\;} {-} {\rm \;}T_{\rm b}} ) {\rm \;\cdot \;}t_g{\rm \;}} ) \;{-} {\rm \;ln\;}( {\theta_{T( { 50} ) }} ) } \over {\sigma _{{\rm ln\theta }T}}}\;$$

where θ_{T (g)} is the thermal time required to reach a given germination fraction g (with units of °C per day or hour); T is the germination temperature; T _b is the base temperature below which a seed will not germinate; t_g is the actual time to germination of fraction g; probit(g) is the probit transformation of cumulative germination percentage g, which linearizes the sigmoidal time course on a log time scale (Finney Reference Finney1971); θ_{T (50)} and σ _lnθT are the median thermal time and standard deviation of ln(θ_T) requirements among individual seeds in the population, respectively. The thermal time model was fitted to data using non-linear regression in SPSS 25.0 (SPSS Inc., Chicago, IL). Goodness-of-fit between predicted and observed data was assessed by the coefficient of determination (R ²).

$$R^ 2 = {\rm 1\;} {-} {\rm \;}\displaystyle{{\sum {( {y_{{\rm obs}}\;{-} {\rm \;}y_{{\rm pre}}} ) }^ 2} \over {\sum {( {y_{{\rm obs}}\;{-} {\rm \;}{\bar{y}}_{{\rm obs}}} ) }^ 2}}$$

where y _obs is the observed value, y _pre is the predicted value, $\bar{y}_{{\rm obs}}$ is the mean of the observed value.

General linear regression using the lm function in the stats package of R version 4.1.2 was performed to test how increasing altitude where seeds were collected affected T _b, θ_{T (50)}, seedling emergence and seedling survival, both in fresh and stored seeds.

Redundancy analysis (RDA) using the rda function in the vegan package of R version 4.1.2 were used to examine the relationships between seed germination traits and environmental conditions where the seeds matured. Additionally, we investigated the relationship between seed germination traits and seedling traits, such as emergence and survival. The significance of these relationships was assessed using Monte Carlo permutation test. We checked for multicollinearity of explanatory variables before RDA analysis and excluded variables with a variance inflation factor (VIF) greater than 10. Therefore, T _b and θ_{T (50)} were included as response variables, while MAT, MAP, NON, NHN and AP as explanatory variables. Before implementing the RDA process, the analysed data were normalized based on Euclidean distance (Warton et al., Reference Warton, Wright and Wang2012).