Soil-borne pathogens restrict the recruitment of a subtropical tree: a distance-dependent effect
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- 作者:Meng Xu ; Yongfan Wang ; Yu Liu ; Zhiming Zhang ; Shixiao Yu
- 关键词:Distance ; dependent mortality ; Janzen–Connell hypothesis ; Specificity ; Engelhardia fenzelii ; Subtropical forest
- 刊名:Oecologia
- 出版年:2015
- 出版时间:March 2015
- 年:2015
- 卷:177
- 期:3
- 页码:723-732
- 全文大小:385 KB
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文摘
The Janzen–Connell hypothesis suggests that density- and/or distance-dependent juvenile mortality driven by host-specific natural enemies can explain high species diversity in tropical forests. However, such density and distance effects may not occur simultaneously and may not be driven by the same mechanism. Also, reports of attempts to identify and quantify the differences between these processes in tropical forests are scarce. In a primary subtropical forest in China, we (1) experimentally examined the relative influence of the distance to parent trees vs. conspecific seedling density on mortality patterns in Engelhardia fenzelii, (2) tested the role of soil-borne pathogens in driving density- or distance-dependent processes that cause seedling mortality, and (3) inspected the susceptibilities of different tree species to soil biota of E. fenzelii and the effects of soil biota from different tree species on E. fenzelii. The results from these field experiments showed that distance- rather than density-dependent processes driven by soil pathogens strongly affect the seedling survival of this species in its first year. We also observed increased survival of a fungicide treatment for E. fenzelii seedlings in the parent soil but not for the seedlings of the other three species in the E. fenzelii parent soil, or for E. fenzelii seedlings in the parent soil of three other species. This study illustrates how the distance-dependent pattern of seedling recruitment for this species is driven by soil pathogens, a mechanism that likely restricts the dominance of this abundant species.