2009) With the exception of area, which usually declines continu

2009). With the exception of area, which usually declines continuously with elevation, all of these factors may be related with hump-shaped species richness patterns. As a result, discrimination between the different potential explanations is difficult. In New Guinea, variation in hump-shaped pattern of palm species richness has been linked to the mid-domain effect (Bachmann et al. 2004), but the biological reality of this effect is commonly questioned (Currie and Kerr 2008). In our study region, many species click here overlap in their upper or lower elevational limits at 1000 and 1100 m, which may also increase species richness here, but runs contrary to the assumptions

of the mid-domain effect which is based on random species distributions (Herzog et al. Small molecule library 2005; Kluge et al. 2008). The high species richness at mid-elevation could be also related to a lower

canopy height (Siebert 2005), because rattan individuals can reach higher light intensities more easily. The density of rattan palms also exhibited a humped-shaped distribution. Usually, the species richness and density of lianas are highest in tropical lowland forests and decline with elevation (Gentry 1991; Schnitzer and Bongers 2002), although the opposite pattern has also been found (Homeier et al. 2010). In Sarawak, rattan palms are more abundant on ridges than in valleys, contrary to other lianas (Putz and Chai 1987). In Malaysia, rattan palms also Metabolism inhibitor C-X-C chemokine receptor type 7 (CXCR-7) reach their highest density at mid-elevations (Appanah et al. 1993). Thus, it appears that the density and richness patterns of rattan palms differ substantially from both patterns of palms and lianas in general. We didn’t find any correlation of mean annual precipitation to species richness or density.

Unlike temperature, precipitation in the study region varies not only with elevation but also with locality and topography (Dechert et al. 2004). Furthermore, our elevational transect reaches the regular cloud band commonly found in humid tropical mountains and “horizontal” precipitation may be captured from fog. Unfortunately, no data are available for the study region on this phenomenon. Thus, more detailed measurements are needed to detect any possible relationship of rattan palms to environmental humidity. However, so far correlations between precipitation and rattan palms haven’t been found in other studies as well, though some species seem to be adapted to certain soil moisture regimes (Dransfield and Manokaran 1994). In addition to elevation and closely related climatic parameters, a set of other factors are also likely to influence the species richness and density of rattan palms. Lianas are more diverse and abundant in forests with gaps (Putz 1984; Hegarty and Caballé 1991; Schnitzer and Carson 2001) and most rattan palms establish and grow more rapidly in forest gaps (Appanah and Nor 1991).

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