Small habitat size and isolation can promote species richness: second‐order effects on biodiversity in shallow lakes and ponds

Scheffer, Marten; Geest, G.J. van; Zimmer, Kyle D.; Jeppesen, Erik; Søndergaard, Martin; Butler, Malcolm G.; Hanson, Mark A.; Declerck, Steven; Meester, Luc De

doi:10.1111/j.0030-1299.2006.14145.x

Cited by 368 publications

(303 citation statements)

References 54 publications

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“…Field studies show that macrophyte richness is related to several lake variables, including lake area, altitude, shoreline complexity, connectivity, trophic state, conductivity and water and sediment quality (Rorslett, 1991;Murphy, 2002;Makela et al, 2004;Declerck et al, 2005;Scheffer et al, 2006;Geurts et al, 2008). This makes macrophyte species richness generally hard to predict (Edvardsen & Okland, 2006).…”

Section: Macrophyte Biodiversitymentioning

confidence: 99%

“…An explanation for the counterintuitive relationship between isolation and species richness is that isolated ponds frequently lack benthivorous fish, which create turbid conditions through their foraging in sediment. Isolated ponds that lack those fish have higher richness of macrophyte species because they become turbid less easily if habitat conditions deteriorate (Scheffer et al, 2006). However, at high macrophyte productivity, moderate levels of disturbance may actually increase macrophyte diversity.…”

Section: Macrophyte Biodiversitymentioning

confidence: 99%

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Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

et al. 2012

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Although many lake restoration projects have led to decreased nutrient loads and increased water transparency, the establishment or expansion of macrophytes does not immediately follow the improved abiotic conditions and it is often unclear whether vegetation with high macrophyte diversity will return. We provide an overview of the potential bottlenecks for restoration of submerged macrophyte vegetation with a high biodiversity and focus on the biotic factors, including the availability of propagules, herbivory, plant competition and the role of remnant populations. We found that the potential for restoration in many lakes is large when clear water conditions are met, even though the macrophyte community composition of the early 1900s, the start of humaninduced large-scale eutrophication in Northwestern Europe, could not be restored. However, emerging charophytes and species rich vegetation are often lost due to competition with eutrophic species. Disturbances such as herbivory can limit dominance by eutrophic species and improve macrophyte diversity. We conclude that it is imperative to study the role of propagule availability more closely as well as the biotic interactions including herbivory and plant competition. After abiotic conditions are met, these will further determine macrophyte diversity and define what exactly can be restored and what not.

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Section: Macrophyte Biodiversitymentioning

confidence: 99%

Section: Macrophyte Biodiversitymentioning

confidence: 99%

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

et al. 2012

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“…Studies involving pond area have yielded conflicting results, with some demonstrating strong influences on plants and invertebrates ) and others demonstrating weak (if any) effects on macroinvertebrate richness (Oertli et al 2002;Søndergaard et al 2005). This break from conventional species-area relationships may be due to second-order effects in the form of ecological interactions which vary between ponds of differing connectivity and dimensions (Scheffer et al 2006). The relatively small size of ponds also renders them vulnerable to drying out, and drying has been shown to have an effect on alpha diversity of ponds , with variations between the biological communities of temporary and permanent ponds (Collinson et al 1995).…”

Section: Physical Correlates Of Pond Species Richnessmentioning

confidence: 99%

Environmental correlates of plant and invertebrate species richness in ponds

2011

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Ponds (lentic water bodies <2ha) constitute a considerable biodiversity resource. Understanding the environmental factors that underlie this diversity is important in protecting and managing the habitat. We surveyed 425 ponds for biological and physical characteristics with 78 of those also surveyed for chemical characteristics. A total of 277 invertebrate species and 265 plant species were found. Species richness varied between 2 and 99 (mean 27.2 ± 0.6 SE) for invertebrates and 1 and 58 (mean 20.8 ± 0.4 SE) for plants. Generalised linear models were used to investigate variables that correlate with the species richness of plants and invertebrates, with additional models to investigate insect, Coleoptera, Odonata, Hemiptera, Trichoptera and Mollusca species richness. Models performed well for invertebrates in general (R 2 =39.8%) but varied between lower-order invertebrate taxa (8.2-34.9%). Ponds with lower levels of shading and no history of drying contained higher numbers of species of plants and all invertebrate groups. Aquatic plant coverage positively correlated with species richness in all invertebrate groups apart from Trichoptera and the presence of fish was associated with high invertebrate species richness in all groups apart from Coleoptera. The addition of chemistry variables only increased the explanatory power of the model explaining plant species richness, for which phosphate was a highly significant factor. We demonstrate that the composition of biological communities varies along with their species richness and that less diverse ponds are more variable compared to more diverse ponds. Promoting a high landscape-level pond biodiversity will involve the management of a high diversity of pond types within that landscape.

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“…Recent studies have revealed their importance for aquatic biodiversity (Pyke 2005, Dimitriou et al 2006, Scheffer et al 2006, EPCN 2007 because, despite their small size, they disproportionately contribute to regional diversity, e.g., when compared to streams, large rivers, or lakes (Oertli et al 2002, Williams et al 2004, Karaus et al 2005. To date, the structure of biological communities in ponds was mostly studied on the basis of taxonomic composition (Sahuquillo et al 2007, Céréghino et al 2008.…”

Section: Introductionmentioning

confidence: 99%

Influence of vegetation cover on the biological traits of pond invertebrate communities

Céréghino

Ruggiero

Marty

et al. 2008

Ann. Limnol. - Int. J. Lim.

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Without human intervention, ponds progressively fill up with aquatic vegetation, so that the structure and age of the vegetal formations show great contrasts within a given set of water bodies. We hypothesized that the biological traits of pond invertebrate communities differed significantly among ponds having different vegetal formations. To test this hypothesis, we selected three neighbouring ponds showing a gradient of vegetation cover and type (sparse bryophytes on rocky substrata (pond 1), extensive submerged Chara beds (pond 2), aerial Typha stands (pond 3)), and we studied between-ponds variations in the combinations of species traits. Taxa biomass was monthly recorded in each pond over one year, to take into account species' seasonality. Species traits were described using a fuzzy-coding method and a simultaneous analysis of the two matrices (co-inertia analysis) was used to investigate changes in biological trait composition. Biomass increased from pond 1 to pond 3, and was higher in vegetal than in muddy mesohabitats. Among 25 biological traits, 10 were significantly correlated to the distribution of samples: number of generations per year, cohort production interval, adult longevity, adult size, number of eggs per female, dispersal ability, dispersal mode, consumer level, ingested food type, and feeding group. Invertebrates in pond 1 species allocated much energy to reproduction, while in pond 3 resource use was favoured by larger body size, long-lived organisms, and a higher diversity of feeding groups. Our results suggest that the structure and age of the vegetal formation play role in selecting species traits related to population dynamics and feeding habits.

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Small habitat size and isolation can promote species richness: second‐order effects on biodiversity in shallow lakes and ponds

Cited by 368 publications

References 54 publications

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

Restoring macrophyte diversity in shallow temperate lakes: biotic versus abiotic constraints

Environmental correlates of plant and invertebrate species richness in ponds

Influence of vegetation cover on the biological traits of pond invertebrate communities

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