1. Introduction
The environment poses continuous challenges to all living organisms. Environmental heterogeneity is ubiquitous, as gradients and spatial variation in temperature, radiation, water availability, and soil composition and chemistry exist at different spatial and temporal scales (Bell et al., 1993; Pigliucci, 2001). In addition, anthropogenic activities change the environment altering climate, the structure of the landscape, the major biogeochemical cycles, and also introducing pollutants into the ecosystems (Anderson, Willis, & Mitchell-Olds, 2011; Vitousek, Mooney, Lubchenco, & Melillo, 1997; Tilman and Lehman, 2001;). Coping with these conditions is, therefore, one of the main challenges faced by organisms throughout their lifespan. The sessile nature of plants makes this task even more demanding, as it requires the ability to respond without moving. Failure to do so would compromise their survival and reproduction, and increase the probability of population extinction (Willi & Hoffmann, 2009).
Exposure to heavy metals (i.e. elements with a specific density > 5 g/cm3; Jarup, 2003) is a powerful selective pressure for plants with important ecological and evolutionary implications (Antonovics, Bradshaw, & Turner, 1971; Ernst, 2006; Macnair, 1987; Shaw, 1990; Boyd, 2004; Wright, Stanton, & Scherson, 2006). Some heavy metals are essential for normal functioning in all plants but they can be toxic at high concentrations (e.g. Co, Cu, Fe, Mn, Zn), while others have no known physiological functions and can be toxic even at very low concentrations (e.g. Cd, Pb, Hg). Such toxicity can exert intense selective pressures on plants, and has led to the evolution of tolerant and/or hyperaccumulator ecotypes in many plant species (e.g. Pauwels, Frérot, Bonnin, & Saumitou-Laprade, 2006; Reeves et al., 2017; Wright et al., 2006). The natural weathering of metal-rich rocks has generated soils to which some plant species have adapted in the long run, giving rise to a metallophyte flora with a considerable level of endemicity (e.g. Brooks and Malaisse, 1985; Kruckeberg and Kruckeberg, 1990; Reeves, Baker, Borhidi, & Berazaín, 1996) of significant conservation value (Whiting et al., 2004). However, during the last decades anthropogenic activities have caused a dramatic increase in the concentrations of metals in soils that are not naturally enriched in metals as a result of surface deposition of dust and particles derived from industrial, agricultural, and mining activities, as well as energy production (Bradl et al., 2002; He, Yang, & Stoffella, 2005; Singh, Labana S., Pandey, Budhiraja & Jain, 2003). Such rapid increase in soil toxicity requires a similarly rapid response of plant populations to develop tolerance to heavy metal pollution, or the capacity to maintain fitness in the presence of exposure to heavy metals (Simms, 2000).
Most plants living in heavy metal enriched substrates have mechanisms to avoid uptake of metals while others can accumulate them at different levels (Adlassnig et al., 2016; Baker, 1981,). Accumulation and tolerance are thus complex genetically distinct quantitative traits that show high levels of inter- and intraspecific variation in plants (Goolsby and Mason, 2015). However, our current knowledge of the extent of intraspecific variation for heavy metal accumulation and tolerance in plants, the mechanisms underlying these traits, and their ecological and evolutionary significance is largely derived from tracheophytes, especially angiosperms (Cappa & Pilon-Smits, 2014; Ernst, 2006; Reeves et al., 2017; Verbruggen, Hermans, & Schat, 2009). Bryophytes have also shown the capacity to tolerate and accumulate high concentrations of these pollutants (Shaw, 1994). These plants diverged from their sister group of vascular plants ~500 mya, and they are non-vascular, gametophyte-dominant (haploid) plants with a relatively low degree of morphological and anatomical complexity, and a low capacity of self-internal regulation due to their poikilohydric nature (Vanderpoorten & Goffinet, 2009). Since they use a variety of unique metabolic pathways to deal with environmental challenges (Cuming 2009; Glime, 2017a,b), their study could provide important insights into the evolution of these responses.
Several studies of inter- and intraspecific variation in the capacity of bryophytes to tolerate heavy metal pollution have found ecotypic differentiation, as well as broad inherent plasticity in a few species (e.g. Briggs, 1972; Brown & House, 1978; Cogolludo, Estébanez, & Medina, 2017; Jules & Shaw, 1994; Shaw, 1988; Shaw, Antonovics, & Anderson, 1987; Shaw, Jules, & Beer, 1991). However, the bulk of the work on heavy metal tolerance and accumulation in natural bryophyte populations dates from the late 1970s and early 1990s, and was focused on a few target species. Recent research in this field has mostly focused on the applied value of bryophytes as biomonitors of heavy metal pollution (reviewed in: Ares et al., 2014; Fernández, Boquete, Carballeira, & Aboal, 2015; Onianwa, 2001; Stanković, Sabovljević, & Sabovljević, 2018) and phytoremediation (e.g. Itouga et al., 2017; Kobayashi, Kofuji R., Yamashita, & Nakamura, 2006; Sandhi, Landberg, & Greger, 2018; Sut-Lohmanna, Jonczakb, & Raaba, 2020), or their physiological and biochemical responses to heavy metal exposure under controlled laboratory conditions without a clear focus on the natural variation of these traits (e.g. Bellini et al., 2020; Esposito et al., 2018; Kovácik, Dresler, & Babula, 2020; Liang et al., 2018).
This study builds on the classic research to explore in more detail the extent of intraspecific phenotypic variation for heavy metal accumulation and tolerance in bryophytes in relation to contrasting habitat specialization. We selected two ecologically different terrestrial moss species with contrasting affinities for heavy metals, grew them in the laboratory under different metal treatments, and examined their patterns of accumulation and tolerance. Here, we define tolerance as the ability to maintain vegetative growth in a metal stressed vs. a control environment (sensu Simms, 2020). For the heavy metal specialist Scopelophila cataractae (Mitt.) Broth (Pottiaceae), we studied four field populations collected within a former copper mine to determine if there was variation for accumulation and tolerance among populations growing in a range of metal-rich soils. For the non-specialist, but metal tolerant Ceratodon purpureus(Hedw.) Brid. (Ditrichaceae), we studied one population collected in the field and compared it with male and female populations grown in the laboratory under axenic conditions. We evaluated phenotypic differences among populations, and examined whether sexes differed in their capacity to accumulate and tolerate metals, an aspect that has not been addressed previously to our knowledge. We predict that the metal specialistS. cataractae would show a “stress tolerator” strategy i.e. increased tolerance under similar accumulation levels, whereas the non-specialist C. purpureus would show a “stress avoidance” strategy, i.e. increased tolerance resulting from decreased accumulation, (sensu Baker, 1981). Also, we predict that females of C. purpureus would be more tolerant to heavy metal exposure than males as shown for other species in different environmental settings (Bowker, Stark, McLetchie, & Mishler, 2000; Marks, Burton, & Mcletchie, 2016; Moore, 2017).