Abstract
By considering the role of site-level factors and dispersal, metacommunity concepts have advanced our understanding of the processes that structure ecological communities. In dendritic systems, like streams and rivers, these processes may be impacted by network connectivity and unidirectional current. Streams and rivers are central to the dispersal of many pathogens, including parasites with complex, multi-host life cycles. Patterns in parasite distribution and diversity are often driven by host dispersal. We conducted two studies at different spatial scales (within and across stream networks) to investigate the importance of local and regional processes that structure trematode (parasitic flatworms) communities in streams. First, we examined trematode communities in first-intermediate host snails (Elimia proxima) in a survey of Appalachian headwater streams within the Upper New River Basin to assess regional turnover in community structure. We analyzed trematode communities based on both morphotype (visual identification) and haplotype (molecular identification), as cryptic diversity in larval trematodes could mask important community-level variation. Second, we examined communities at multiple sites (headwaters and main stem) within a stream network to assess potential roles of network position and downstream drift. Across stream networks, we found a broad scale spatial pattern in morphotype- and haplotype-defined communities due to regional turnover in the dominant parasite type. This pattern was correlated with elevation, but not with any other environmental factors. Additionally, we found evidence of multiple species within morphotypes, and greater genetic diversity in parasites with hosts limited to in-stream dispersal. Within network parasite prevalence, for at least some parasite taxa, was related to several site-level factors (elevation, snail density and stream depth), and total prevalence decreased from headwaters to main stem. Variation in the distribution and diversity of parasites at the regional scale may reflect differences in the abilities of hosts to disperse across the landscape. Within a stream network, species-environment relationships may counter the effects of downstream dispersal on community structure.
Highlights
Metacommunity paradigms have broadened the scope of community-level investigations by addressing the roles of both local and regional scale processes in driving community structure [1, 2]
10% (Chisholm Creek) to 49% (Little Wilson Creek) (Fig 3a, S1 Table in S1 Appendix). Both M. oregonensis and virgulate infections were encountered at all 20 sites
We found that trematode communities exhibited a broad scale spatial pattern due to regional turnover in the dominant trematode species for both morphotype- and haplotype-defined community structure
Summary
Metacommunity paradigms have broadened the scope of community-level investigations by addressing the roles of both local (e.g. within-site factors) and regional scale processes (e.g. dispersal) in driving community structure [1, 2]. Trematodes (Phylum: Platyhelminthes, Subclass: Digenea), known as flukes or parasitic flatworms, are common in aquatic systems. They have complex life cycles, usually involving a series of three hosts, life histories vary. Adult trematodes sexually reproduce in vertebrate definitive hosts and release eggs into the environment via host feces. Eggs hatch into larvae that infect aquatic mollusks as first-intermediate hosts and reproduce asexually to generate free-swimming cercariae. Cercariae leave mollusks and form metacercarial cysts either in second-intermediate hosts (invertebrate or vertebrate) or on aquatic vegetation. The life cycle is completed when a definitive host consumes an infected second-intermediate host or ingests environmental cysts [7]
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