STUDY SITE

The research was conducted at the Teberda Biosphere Reserve (northwestern Caucasus, Russia). The experimental site was within an alpine lichen heath plant community on the south slope of Mount Malaya Khatipara (43°27′N, 41°42′E at ∼2800 m above sea level).

In the alpine zone of the Caucasus Mountains, alpine lichen heath plant communities are typically situated on south-facing, windward crests and slopes (Onipchenko, 1994). The climate of the area is characterized by low air temperatures (mean annual temperature at the study site is −1.2°C, and mean July temperature is 7.9°C) and high wind velocities (Grishina et al., 1986). Annual precipitation at the study site is high (1400 mm), although the majority falls as snow. Because of the site's position on a windward slope, most of the snow is blown away. Therefore, summer water shortage and deep winter frost are typical of the soil. The soil humus layer is thin (15–20 cm) and contains many stones. The soils are acid (pH_KCl = 4.0) and relatively poor (available N [determined as NH₄] in the upper soil layer is 120 mg g⁻¹; available P is 60 mg g⁻¹) (Onipchenko, 1994).

The plant community is dominated by fruticose lichens (mainly Cetraria islandica), which cover ∼50–60% of the area. Vascular plants are represented by >40 species, the most common of which are Anemone speciosa, Antennaria dioica, Campanula tridentata, Carex sempervirens, Carex umbrosa, Festuca ovina, Trifolium polyphyllum, and Vaccinium vitis-idaea (nomenclature after Vorob'eva and Onipchenko, 2001). Aboveground vascular plant cover is not continuous but rather consists of patches of isolated vascular plants surrounded by lichen areas. The typical size of lichen or vascular plant patches is ∼5–10 cm across. For detailed descriptions of the site's plant community, see Onipchenko (1994) and Onipchenko (2002).

EXPERIMENTAL DESIGN AND SAMPLING

The study was conducted during a 5-yr period from 1998 until 2002. The experiment included five treatments: Ca addition (in order to raise soil pH), P, N, and N + P additions, and irrigation. A visually homogeneous area of 19 × 6.5 m was selected on the site and divided into 24 plots. Each plot was 1.5 × 1.5 m; 1-m buffer zones separate plots. The plots were randomly assigned to the treatments, each of which was replicated four times. Within each plot, the numbers of plants per species were counted on a subplot of 0.25 m × 1.0 m, situated at the bottom of the plot. The numbers of generative shoots per species were counted within another subplot of 1.5 m × 0.5 m, situated at the top of each plot.

During the first experimental year (1998), no treatment was applied to the experimental plots, but initial plant abundance was obtained. In 1999, Ca, N, P, and N + P fertilization treatments were started. Calcium was added as lime (52 g lime m⁻² yr⁻¹) only in 1999 and in 2002. N, P and N + P plots were fertilized annually once a year at the beginning of each growing season. Nitrogen added was in the form of urea (9 g N m⁻² yr⁻¹); phosphorus added was in the form of double superphosphate (2.5 g P m⁻² yr⁻¹). Irrigation was conducted in 1999–2002 during the vegetation period (July–August). The mean daily value of evapotranspiration in the area is ∼3 mm (Grishina et al., 1986). Every day the precipitation was measured. If the precipitation over a 3-day period did not compensate for the water loss due to evapotranspiration, the plots were irrigated.

Plants and generative shoots were counted by species once a year at the end of July, in the middle of the growing season. In this paper we define “plant” as an individual tiller for graminoids, individual ramet for clonal forbs, or individual rosette for rosette and semirosette forbs. By the term “generative shoot,” we mean individual flowering shoots. The counting was done for all the vascular species found on the plots (Appendix 1). It was impossible to distinguish vegetative tillers of Carex caryophyllea, Carex sempervirens, and Carex umbrosa in situ. Therefore, these species were analyzed together as one group, further referred as Carex spp.

DATA ANALYSIS

All the statistical analyses—except for the analysis of changes in biodiversity—were done in the same way twice, once for a change in total number of plants and once for a change in number of generative shoots. The statistical analyses performed for changes in the total number of plants and for changes in the number of generative shoots were done through the use of exactly the same methods. To refrain from repetition we therefore only describe the analysis methods for changes in plant numbers.

RESPONSE TO NITROGEN AND PHOSPHORUS ADDITIONS

Our experiment has demonstrated the importance of nutrient limitations for the composition of an alpine lichen heath plant community. Körner (2003) suggested that in many parts of the world, productivity of alpine plants is limited mostly by nitrogen. Our results indicate that in the Caucasus, a second limiting factor might be phosphorus. This finding is consistent with data showing a low concentration of soil phosphorus at the experimental site (Makarov, 1995; Vertelina et al., 1996). Addition of nitrogen and phosphorus together caused the strongest positive response, both in number of plants and number of generative shoots, indicating that these nutrients are co-limiting productivity on the site. Remarkably, there were no clear annual trends in any of the responses to treatments.

Overall plant density strongly increased after N + P additions and slightly increased after N additions. However, the total number of forbs plants was not affected by the experimental treatments. Thus, the shift in total plant number was caused mostly by an increase in the number of graminoid plants. Nevertheless, many forbs responded (although not always to a statistically significant degree) to N and N + P treatments by an increase in the number of generative shoots. This finding is in agreement with the work of Castro-Díez et al. (2003), who suggested that plant growth can follow one of two strategies: allocation most of available resources to seed production or to vegetative growth.

All graminoids increased their abundance in response to N + P treatment. This finding is consistent with results obtained in similar experiments (e.g., Jonasson, 1992; Press et al., 1998a; Turkington et al., 1998). The response to additions of only nitrogen or phosphorus, however, varied between graminoid species. Thus, the N + P co-limitation of graminoids is rather a result of a coexistence of N- and P-limited species within the community, than an overall pattern.

Similar to previous reports (Jeffrey, 1971; Rosén, 1982; Pop and Resmerita, 1988), Festuca ovina responded positively to N + P fertilization. However, this species, which is known as stress tolerant (Grime, 1977), but a bad competitor in richer soils (Grime, 1977; Austin and Austin, 1980), decreased plant number and the number of generative shoots during N treatment. Helictotrichon versicolor showed the same pattern. Bohmer (1994) claimed that Helictotrichon versicolor prefers rich soils. Our results show that this species, nevertheless, lost to other species in competition for soil nutrients, when nitrogen fertilizer was applied.

Three Carex species found at the site were analyzed together as one group. This approach might have led to some misinterpretation of the results, as Carex species can vary in their nutrient requirements (Henry et al., 1986; Aerts and De Caluwe, 1994). Gigon (1971) claimed that Carex sempervirens does not show a positive response to nitrogen fertilizers. Henry et al. (1986) reported that Carex species responded positively only to N + P + K fertilizer, but did not show any response to addition of nitrogen only. In contrast to these findings, our results demonstrate that Carex spp. was the only graminoid that responded positively to addition of nitrogen only and even possibly caused a decrease of other graminoids on these plots. Grime (2001) stressed the importance of cluster roots that increase the capacity of certain sedges for phosphorus scavenging and uptake. In line with this claim, in our experiment the number of Carex plants decreased after phosphorus fertilization, suggesting little limitation by phosphorus for Carex. At the same time, Festuca ovina increased its abundance and the number of generative shoots in response to phosphorus additions. This finding is consistent with data presented by Tyler (1996), who reported that the abundance of F. ovina is positively correlated with the availability of exchangeable soil phosphates. These facts suggest that the changes in soil-nutrient availability induced an alteration of the competitive balance between the Carex species and F. ovina (Tilman and Wedin, 1991; Hartley and Amos, 1999). These two species are the most abundant at the site. Our data demonstrate that on phosphorus-fertilized plots, Festuca ovina possibly became a stronger competitor than Carex and caused the decrease of the latter, whereas Carex benefited more from nitrogen.

RESPONSE TO CALCIUM ADDITION

It has been demonstrated that pH level can influence uptake of nitrogen and phosphorus from soil and therefore plant performance (Tilman and Olff, 1991; Tyler, 1994). Shatvorjan (1977) reported that calcium additions increased biomass production on a grassland with a relatively low soil pH (4.7 in the deep soil layer, 5.5 in the upper soil layer). These results suggest that at lower soil pH, some species may benefit from calcium additions. Although at our site the soil properties are comparable with those in the work of Shatvorjan (1977), our results show that calcium fertilization did not cause a considerable change in the plant community. Only Festuca ovina increased its plants number unequivocally during the calcium-addition experiment, but the magnitude of the increase was not high in comparison with the control.

RESPONSE TO IRRIGATION

It has been demonstrated (see reviews of Oberbauer and Dawson [1992] and Callagan and Jonasson [1995]) that plant communities of the High Arctic, which grow in somewhat similar conditions and are often compared to those of alpine tundra, are often limited by water availability. Our results suggest that the majority of alpine heath plants are well adapted to the natural water shortage. Similar results of absence of response to irrigation were reported by Bowman et al. (1995) for an alpine tundra plant community on Niwot Ridge of the Colorado Rocky Mountains.

The only species that increased its number of plants sharply, even 10-fold, in irrigated plots was the annual Euphrasia ossica. Euphrasia ossica is a hemiparasitic species (Michelsen et al., 1998), but at early stages it obtains water and nutrients from soil and depends therefore on soil humidity. Like most hemiparasitic species, it has a high transpiration rate (Press et al., 1998b). Because of this, it is probably strongly affected by summer droughts. Release from water shortage, therefore, caused a major increase in number of plants. This finding is consistent with that of Grubb (1983), who claimed that a morphologically close species, Euphrasia officinalis, is very sensitive to drought in meadows of south England.

Among perennials, only Festuca ovina increased its abundance in response to irrigation, but the magnitude of the increase was not large in comparison with controls. Vaccinium vitis-idaea did not show any response to irrigation. In a similar experiment in the subarctic, Vaccinium vitis-idaea responded idiosyncratically. Shevtsova et al. (1997) reported that it increased the growth rate in response to irrigation, whereas in experiment of Press et al. (1998a), it did not respond to additional water supply.

CORRELATION WITH ROOT DEPTHS

It is commonly agreed that root properties play an important role in the mineral nutrition of plants (Chapin, 1980). In our experiment, changes in total plant number in response to treatments closely correlated with the root depth of the species. The data about species' root systems was adopted from the work of Onipchenko (1987). Deep-rooted Trifolium polyphyllum and Arenaria lychnidea (roots penetrate deeper than 15 cm) responded only to nitrogen treatment, whereas species with intermediate and shallow root systems (Alchemilla caucasica, Carex spp., Festuca ovina, Helictotrichon versicolor, Luzula spicata) also showed pronounced response to phosphorus additions (P and/or N + P treatments). This difference probably occurred because the added phosphorus did not penetrate into deep soil layers. Species with shallow root systems (roots do not penetrate deeper than 5 cm), such as Festuca ovina and Euphrasia ossica, are probably strongly influenced by droughts and therefore responded positively to irrigation. The changes in number of generative shoots induced by fertilization did not have any correlation with root depth of plants.

CLONAL VS. NONCLONAL SPECIES

Several studies have shown that clonality improves the efficiency of nutrient use (Headly et al., 1988; Jónsdóttir and Callagan, 1988) and nutrient scavenging (De Kroon and Van Groenendael, 1997). As the physiological adaptations for efficient nutrient use, rather than for efficient nutrient uptake, are of greater importance in poor soils (Chapin, 1980), it would be logical to expect that clonal species would benefit more from nutrient additions than nonclonal species. Our results confirm this assumption. The analysis of individual species demonstrated that, except for Euphrasia ossica, only clonal species increased their abundance significantly. Considered as a group, nonclonal species did not respond to any experimental treatment. A possible explanation for such a response pattern could be that seedling establishment, which is critical for nonclonal species, is more difficult in the dense cover after fertilization. However, the analysis of the response of clonal species indicated that this group increased its density only in response to N + P treatment, whereas the total community density increased in response to N + P and N treatments. Similarly, the number of generative shoots of clonal species increased in response to N + P and P treatments, whereas the number of generative shoots of the total community increased in response to N, N + P, and P treatments. This result suggests that it was the group of nonclonal species that made a positive response to N treatment in both cases.

CHANGES IN BIODIVERSITY AND SPECIES RICHNESS

Increased availability of limiting nutrients often leads to increase in community productivity and reduction of diversity (Tilman, 1982; Elisseou et al., 1995; Grime, 2001). Although nitrogen additions slightly increased the productivity of our site, this increase tended to be proportional for the site species and therefore did not result in changes of vegetation diversity. In contrast, addition of nitrogen and phosphorus together caused a disproportionate increase in plant numbers of several species. This result suggests an increase in competitive interactions caused by the increase in availability of this nutrient (Grime, 1973). However, similar to the findings of Elisseou et al. (1995) and Kalmbacher and Martin (1996), the addition of phosphorus alone did not change the vegetation diversity. It is, nevertheless, important to realize that changes in shoot number do not necessary lead to changes in biomass. The question, whether a response of the community biomass follows a similar pattern, stays open for future research.

In recent years many researchers sought the evidence that species richness changes with the increase in nutrient availability, resulting in an increase in community productivity. However, the results reported are contradictory. Some authors (Willems et al., 1993; Chapin, 1995; Molau and Alatalo, 1998; Aerts et al., 2003) have demonstrated a decrease in species number caused by an increase in soil-nutrient availability, whereas others (Jonasson, 1992; Bowman et al., 1993; Huber, 1994) reported an absence of significant changes or even an increase in the number of species.

Grime (2001) stressed the importance of competition for light for the process of local species extinction caused by increased biomass. However, the hump-shaped relationship between productivity and species richness suggested by Grime has not always been found (Waide et al., 1999; Cornwell and Grubb, 2003) especially when the observations were conducted at small plots (Oksanen, 1996; Gross et al., 2000). When such a relationship is observed, the location of the hump in the hump-shaped curve depends on many biotic and abiotic factors such as type of plant community and availability of soil nutrients and water (Cornwell and Grubb, 2003).

Although Cornwell and Grubb (2003) showed that for grassland species, richness peaks occur on poor nutrient soils, decreasing with fertilization, they questioned the generality of this pattern for all types of plant community. It is suggested that in communities in which an individual plant has a lot of space aboveground (we consider the plant community in this study to be of this type), light competition does not play an important role and does not lead to species' die-off even when the productivity increases. Similarly, Jonasson (1992) suggested that tendencies in the changes of the number of species depend not only on nutrient availability but also on the rate of competitive exclusion. If this rate stays low, then the number of species does not decline under fertilization. In line with this theory, the number of species in our experiment did not change significantly under any of the experimental treatment. Another important factor is that most of the species analyzed within the experiment are perennials and therefore might have resources to survive for several years under unfavorable conditions. Thus, considerable changes in species number might take longer than 4 yr.

Several researchers have demonstrated that, in contradiction to nutrients, increased water availability does not lead to decrease in species number, caused by increase in productivity, but rather leads to increase in species number or does not cause any changes in species richness (Sarmiento, 1983; Goldberg and Miller, 1990; Jobbágy et al., 1996). Cornwell and Grubb (2003) suggested that water limitation is a more stochastic factor than nutrient limitation and therefore it more often causes extinction of species. Thus, release from water shortage should increase rather than decrease the species number. This explanation is applicable to our results. We found that irrigation did not decrease the number of species and the relatively short time of the experiment was not enough for new species to establish.