The regeneration levels of the two

The regeneration levels of the two species from the HCS included in the analysis were influenced more by physical environmental than by forest structure factors (Table 8). The regeneration levels of both species included in the anal- ysis had significant positive relationships with RC and PAR. The regeneration of Ficus macleilandii was determined by BA, RC, and PAR (positive or negative effects). The re- generation value of Dracaena cochinchinensis was affected positively by RC and PAR, but negatively by SDb (Table 8). Physical factors, especially RC and PAR, had greater significant positive effects on the regeneration of the domi- nant species at the HCS than did factors related to forest structure. This site was relatively dry due to the very shal- low soils and relatively high summer temperatures caused by intense solar radiation, which exceeded the levels in sur- rounding areas. The cliffs are protected as special habitats, but access is allowed to interesting viewpoints at the tops of selected promontories, and rock climbing is allowed in some places (Wezel 2007). The dominant species had strong colonization capabilities under the extreme conditions pre- vailing at the HCS. The biological assemblages in such cliff environments have limited ecological stability; they readily lose community organization when perturbed by external agents (Clark and Hessl 2015). Tree species that regenerate on rocky cliffs, such as Ficus spp. and Dracaena spp., usu- ally have specialized root systems that are able to thread through the rocky substratum and extract nutrients from the thin soil/humus layer (Denk et al. 2014; Duarte et al. 2015). The roots commonly grow deep into the rock fis- sures of the epikarst substratum (Huang et al. 2011). A classification system is required for tree species based on the degree to which their roots alter nutrient availability and soil organic matter decomposition (Yin et al. 2014).

Among species from the HCS, PAR had significant pos- itive effects on regeneration. Establishment occurred in well-illuminated sites, indicating that the species likely re- quired high light conditions and had rapid growth rates (Carreño-Rocabado et al. 2012; Lusk et al. 2013). Light is the main factor that limits the growth and survival of many species, and variation in light availability affects the re- generation pattern at forest sites (Lusk et al. 2011; Lusk et al. 2013). The heterogeneity of light distribution changes with differences in light availability during the day and among seasons (Dlugos et al. 2015; Tarvainen et al. 2015). Changes in the availability of sunlight resulting from natu- ral or anthropogenic clearances play key roles in the initial development and survival of trees in tropical rainforests (Seidler and Bawa 2000; Edwards et al. 2014; Mao et al. 2014).

Implications for management of the forest cover on limestone hills

We demonstrated that light, soil conditions, and the ex- tent of rocky outcroppings determined species composition in different forest stands distributed over a limestone hill. These factors variably influenced regeneration among tree species. We found that the regeneration of shade-tolerant species in the HSS, such as A. elliptica and S. taxoides, was influenced by many factors, suggesting that these species are difficult to replace through natural regeneration proc- esses and that they are sensitive to disturbances. Light-de- manding species, such as F. macleilandii and D. cochinchi- nensis at the HCS, and P. mirabilis at the SHS, grew rap- idly (Lusk et al. 2013; De Vasconcellos et al. 2014; Schön- beck et al. 2015). They established well under high light conditions and in the limestone hill environment, where large rocky outcroppings, shallow soils, and relatively high

summer temperatures created by intense solar radiation were prevalent. They are likely good candidate species for the restoration of disused limestone quarries. The preva- lence of bare land, rocky outcroppings, and high light would provide suitable habitat for these light-demanding species, especially the relict taxa that are largely endemic to these environments. Improved knowledge of the physical and biological factors of limestone hill environments will help to optimize the use of available funds for restoration and conservation of the special biological communities on karst landforms.