Your search keyword '"Johnston, Emma L."' showing total 25 results

1. Variation in Successional Dynamics Shape Biodiversity Patterns over a Tropical-Temperate Latitudinal Gradient.

Author

Bracewell SA, Johnston EL, and Clark GF

Subjects

Animals, Population Dynamics, Biodiversity, Tropical Climate, Invertebrates physiology

Abstract

AbstractSuccessional dynamics can vary because of a range of ecological and environmental factors, but our understanding of biogeographic variation in succession, and the processes contributing to community development across ecosystems, is limited. The pattern and rate of recruitment of dispersive propagules likely differs over large spatial scales and can be an important predictor of successional trajectory. Over a 20° tropical-temperate latitudinal gradient, we measured sessile invertebrates over 12 months of community development and successive 3-month recruitment windows to understand succession and how it is influenced by recruitment. Succession and recruitment patterns varied over latitude. In the tropics, fast temporal turnover, fluctuating abundances, and lack of successional progression suggest that the contribution of stochastic processes was high. As latitude increased, successional progression became more apparent, characterized by increasing species richness and community cover and a shift to more competitive taxa over time. At temperate locations, species identities were similar between older communities and recruiting assemblages; however, community composition became more variable across space over time. Such divergence suggests an important role of early colonizers and species interactions on community structure. These findings demonstrate differences in the processes contributing to community development and biodiversity patterns over latitude. Understanding such biogeographic variation in community dynamics and identifying the prevalence of different processes can provide insights into how communities assemble and persist in response to environmental variability.

Published

2024

2. A global horizon scan of issues impacting marine and coastal biodiversity conservation.

Author

Herbert-Read JE, Thornton A, Amon DJ, Birchenough SNR, Côté IM, Dias MP, Godley BJ, Keith SA, McKinley E, Peck LS, Calado R, Defeo O, Degraer S, Johnston EL, Kaartokallio H, Macreadie PI, Metaxas A, Muthumbi AWN, Obura DO, Paterson DM, Piola AR, Richardson AJ, Schloss IR, Snelgrove PVR, Stewart BD, Thompson PM, Watson GJ, Worthington TA, Yasuhara M, and Sutherland WJ

Subjects

Animals, Climate Change, Humans, Biodiversity, Ecosystem

Abstract

The biodiversity of marine and coastal habitats is experiencing unprecedented change. While there are well-known drivers of these changes, such as overexploitation, climate change and pollution, there are also relatively unknown emerging issues that are poorly understood or recognized that have potentially positive or negative impacts on marine and coastal ecosystems. In this inaugural Marine and Coastal Horizon Scan, we brought together 30 scientists, policymakers and practitioners with transdisciplinary expertise in marine and coastal systems to identify new issues that are likely to have a significant impact on the functioning and conservation of marine and coastal biodiversity over the next 5-10 years. Based on a modified Delphi voting process, the final 15 issues presented were distilled from a list of 75 submitted by participants at the start of the process. These issues are grouped into three categories: ecosystem impacts, for example the impact of wildfires and the effect of poleward migration on equatorial biodiversity; resource exploitation, including an increase in the trade of fish swim bladders and increased exploitation of marine collagens; and new technologies, such as soft robotics and new biodegradable products. Our early identification of these issues and their potential impacts on marine and coastal biodiversity will support scientists, conservationists, resource managers and policymakers to address the challenges facing marine ecosystems., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

3. Variations in benthic fluxes of sediments near pier pilings and natural rocky reefs.

Author

Martinez AS, Dafforn KA, Johnston EL, Filippini G, Potts J, and Mayer-Pinto M

Subjects

Chlorophyll A, Geologic Sediments chemistry, Nitrogen, Water, Biodiversity, Ecosystem

Abstract

Marine artificial structures such as pilings are replacing natural habitats, and modifying surrounding areas, often resulting in local decreases in species diversity and facilitation of bioinvasion. Most research on the impacts of artificial structures in marine ecosystems has primarily focused on rocky bottom habitats and biodiversity, overlooking the effects of these structures on the functioning of nearby sedimentary habitats. Here we compared, for the first time, benthic metabolism (O 2 fluxes) and sediment-water nutrient (inorganic nitrogen, phosphate, and dissolved organic nitrogen) fluxes in shallow water sediments adjacent to pilings and natural reefs. We also measured sediment properties (grain size, total organic carbon, total nitrogen, C:N ratio and chlorophyll-a content). We found that sediments near pilings were generally finer with greater C:N ratios than those near reefs, while differences in other sediment properties between types of habitats were dependent on the site. We found significant differences in the oxygen consumption, primary productivity, and net ecosystem metabolism in sediments around pilings compared to sediments near natural reefs, but these patterns differed by site. Net nutrient fluxes were similar in sediments near pilings and reefs at both sites. This study showed that although pilings can be associated with changes in the functioning of sedimentary habitats, patterns and the direction of change seem to vary depending on local conditions., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

4. Habitat complexity effects on diversity and abundance differ with latitude: an experimental study over 20 degrees.

Author

Bracewell SA, Clark GF, and Johnston EL

Subjects

Aquatic Organisms, Australia, Biodiversity, Ecosystem

Abstract

Habitat complexity is accepted as a general mechanism for increasing the abundance and diversity of communities. However, the circumstances under which complexity has the strongest effects are not clear. Over 20 degrees of Australia's east coast, we tested whether the effects of within-site structural habitat complexity on the diversity and community structure of sessile marine invertebrates was consistent over a latitudinal gradient where environmental conditions and species composition vary. We used experimental arrays with varied structural treatments to detect whether community cover, species richness, diversity and community composition (β-diversity) changed with increasing complexity. Community response to complexity varied over latitude due to differences in species richness and community development. Increased complexity had the greatest positive effects on community cover and species richness at higher latitudes where recruitment and growth were low. At lower latitudes, community cover and species richness were higher overall and did not vary substantially between complexity treatments. Latitudinal variation in within-treatment β-diversity relative to complexity further suggest divergent community responses. At higher latitudes, increased similarity in more complex treatments suggests community dominance of successful taxonomic groups. Despite limited effects on species richness and community cover at lower latitudes, β-diversity was higher in more complex treatments, signifying potential positive effects of increased complexity at these sites. These results demonstrate the context-dependency of complexity effects in response to variation in species richness and community development and should be taken into consideration to help direct conservation and restoration efforts., (© 2018 by the Ecological Society of America.)

Published

2018

5. An empirical examination of consumer effects across twenty degrees of latitude.

Author

Lavender JT, Dafforn KA, Bishop MJ, and Johnston EL

Subjects

Animals, Australia, Predatory Behavior, Biodiversity, Ecosystem

Abstract

The strength and importance of consumer effects are predicted to increase toward low latitudes, but this hypothesis has rarely been tested using a spatially consistent methodology. In a consumer-exclusion experiment spanning twenty degrees of latitude along the east Australian coast, the magnitude of consumer effects on sub-tidal sessile assemblage composition was not greater at low than high latitudes. Across caged and control assemblages, Shannon's diversity, Pielou's evenness, and richness of functional groups decreased with increasing latitude, but the magnitude of consumer effects on these metrics did not display consistent latitudinal gradients. Instead, latitudinal gradients in consumer effects were apparent for individual functional groups. Solitary ascidians displayed the pattern consistent with predictions of greater direct effects of predators at low than high latitude. As consumers reduced the biomass of this and other competitive dominants, groups less prone to predation (e.g., hydroids, various groups of bryozoans) were able to take advantage of freed space in the presence of consumers and show increased abundances there. This large-scale empirical study demonstrates the complexity of species interactions, and the failure of assemblage-level metrics to adequately capture consumer effects over large spatial gradients., (© 2017 by the Ecological Society of America.)

Published

2017

6. What does impacted look like? High diversity and abundance of epibiota in modified estuaries.

Author

Clark GF, Kelaher BP, Dafforn KA, Coleman MA, Knott NA, Marzinelli EM, and Johnston EL

Subjects

Animals, Aquatic Organisms growth & development, Conservation of Natural Resources, Ecosystem, Environmental Monitoring, Geologic Sediments chemistry, Human Activities, Invertebrates classification, Invertebrates growth & development, Metals analysis, Polychaeta, South Australia, Water Pollutants, Chemical analysis, Aquatic Organisms classification, Biodiversity, Estuaries

Abstract

Ecosystems modified by human activities are generally predicted to be biologically impoverished. However, much pollution impact theory stems from laboratory or small-scale field studies, and few studies replicate at the level of estuary. Furthermore, assessments are often based on sediment contamination and infauna, and impacts to epibiota (sessile invertebrates and algae) are seldom considered. We surveyed epibiota in six estuaries in south-east Australia. Half the estuaries were relatively pristine, and half were subject to internationally high levels of contamination, urbanisation, and industrialisation. Contrary to predictions, epibiota in modified estuaries had greater coverage and were similarly diverse as those in unmodified estuaries. Change in epibiota community structure was linearly correlated with sediment-bound copper, and the tubeworm Hydroides elegans showed a strong positive correlation with sediment metals. Stressors such as metal contamination can reduce biodiversity and productivity, but others such as nutrient enrichment and resource provision may obscure signals of impact., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2015

7. The interacting effects of diversity and propagule pressure on early colonization and population size.

Author

Hedge LH, Leung B, O'Connor WA, and Johnston EL

Subjects

Animals, Bivalvia genetics, Computer Simulation, Genetic Variation, Genotype, Larva genetics, Larva physiology, Models, Biological, Population Dynamics, Biodiversity, Bivalvia physiology

Abstract

We are now beginning to understand the role of intraspecific diversity on fundamental ecological phenomena. There exists a paucity of knowledge, however, regarding how intraspecific, or genetic diversity, may covary with other important factors such as propagule pressure. A combination of theoretical modelling and experimentation was used to explore the way propagule pressure and genetic richness may interact. We compare colonization rates of the Australian bivalve Saccostrea glomerata (Gould 1885). We cross propagule size and genetic richness in a factorial design in order to examine the generalities of our theoretical model. Modelling showed that diversity and propagule pressure should generally interact synergistically when positive feedbacks occur (e.g. aggregation). The strength of genotype effects depended on propagule size, or the numerical abundance of arriving individuals. When propagule size was very small (<4 individuals), however, greater genetic richness unexpectedly reduced colonization. The probability of S. glomerata colonization was 76% in genetically rich, larger propagules, almost 39 percentage points higher than in genetically poor propagules of similar size. This pattern was not observed in less dense, smaller propagules. We predict that density-dependent interactions between larvae in the water column may explain this pattern., (© 2013 The Authors. Journal of Animal Ecology © 2013 British Ecological Society.)

Published

2014

8. Continental-scale governance and the hastening of loss of Australia's biodiversity.

Author

Ritchie EG, Bradshaw CJ, Dickman CR, Hobbs R, Johnson CN, Johnston EL, Laurance WF, Lindenmayer D, McCarthy MA, Nimmo DG, Possingham HH, Pressey RL, Watson DM, and Woinarski J

Subjects

Australia, Conservation of Natural Resources methods, Biodiversity, Conservation of Natural Resources legislation & jurisprudence

Published

2013

9. Polychaete richness and abundance enhanced in anthropogenically modified estuaries despite high concentrations of toxic contaminants.

Author

Dafforn KA, Kelaher BP, Simpson SL, Coleman MA, Hutchings PA, Clark GF, Knott NA, Doblin MA, and Johnston EL

Subjects

Analysis of Variance, Animals, Environmental Monitoring statistics & numerical data, Geologic Sediments parasitology, Mass Spectrometry, Metals, Heavy analysis, New South Wales, Particle Size, Polycyclic Aromatic Hydrocarbons analysis, Population Density, Principal Component Analysis, Rose Bengal, Biodiversity, Environmental Monitoring methods, Environmental Pollutants analysis, Estuaries, Geologic Sediments chemistry, Polychaeta physiology

Abstract

Ecological communities are increasingly exposed to multiple chemical and physical stressors, but distinguishing anthropogenic impacts from other environmental drivers remains challenging. Rarely are multiple stressors investigated in replicated studies over large spatial scales (>1000 kms) or supported with manipulations that are necessary to interpret ecological patterns. We measured the composition of sediment infaunal communities in relation to anthropogenic and natural stressors at multiple sites within seven estuaries. We observed increases in the richness and abundance of polychaete worms in heavily modified estuaries with severe metal contamination, but no changes in the diversity or abundance of other taxa. Estuaries in which toxic contaminants were elevated also showed evidence of organic enrichment. We hypothesised that the observed response of polychaetes was not a 'positive' response to toxic contamination or a reduction in biotic competition, but due to high levels of nutrients in heavily modified estuaries driving productivity in the water column and enriching the sediment over large spatial scales. We deployed defaunated field-collected sediments from the surveyed estuaries in a small scale experiment, but observed no effects of sediment characteristics (toxic or enriching). Furthermore, invertebrate recruitment instead reflected the low diversity and abundance observed during field surveys of this relatively 'pristine' estuary. This suggests that differences observed in the survey are not a direct consequence of sediment characteristics (even severe metal contamination) but are related to parameters that covary with estuary modification such as enhanced productivity from nutrient inputs and the diversity of the local species pool. This has implications for the interpretation of diversity measures in large-scale monitoring studies in which the observed patterns may be strongly influenced by many factors that covary with anthropogenic modification.

Published

2013

10. Core sediment bacteria drive community response to anthropogenic contamination over multiple environmental gradients.

Author

Sun MY, Dafforn KA, Johnston EL, and Brown MV

Subjects

Bacteria drug effects, Bacteria genetics, Geologic Sediments chemistry, Geologic Sediments microbiology, Metals, Heavy pharmacology, Polycyclic Aromatic Hydrocarbons pharmacology, RNA, Ribosomal, 16S genetics, Salinity, Temperature, Bacterial Physiological Phenomena drug effects, Biodiversity, Estuaries, Soil Microbiology, Soil Pollutants pharmacology

Abstract

In this study, 454 pyrosequencing of the 16S rRNA gene was used to investigate sediment bacterial community response to contaminant disturbance across six estuaries with differing levels of 'modification'. We observed a significant influence of metal and polycyclic aromatic hydrocarbon contaminants in shaping bacterial community composition, structure and diversity, with metals being the more influential contaminant. An abundant and pervasive 'core' set of bacteria found in every sample were largely responsible for mediating community response to contamination. These 13 core operational taxonomic units were mostly comprised of Gamma-, Delta-, Alphaproteobacteria and Acidobacteria. Sediment silt and metals together explained the most variation in bacterial community composition (19.7%). Following this strong contaminant signature, salinity and temperature represented important environmental variables predicting 10.9% of community variation. While overall network connectivity measures supported the idea of an inherently diverse soil microbiome with some degree of functional redundancy, lower values observed in contaminated sediments indicate potential structural perturbations in the community from fracturing or loss of bacterial associations. The large number of unclassified sequences obtained in this study contribute to improving our understanding of environmentally relevant strains in relation to anthropogenic contamination, which have been overlooked in laboratory studies., (© 2013 John Wiley & Sons Ltd and Society for Applied Microbiology.)

Published

2013

11. Intrinsic time dependence in the diversity-invasibility relationship.

Author

Clark GF, Johnston EL, and Leung B

Subjects

Animals, Plant Development, Time Factors, Biodiversity, Introduced Species, Models, Biological, Plants classification

Abstract

Contrasting patterns in the diversity-invasibility relationship have intrigued ecologists for many years, and are now known as the "invasion paradox." Experiments usually detect negative relationships, while field surveys find them to be positive. It is widely believed that the paradox is driven by differences in spatial scale, but this is challenged by field surveys that find positive relationships at all spatial scales. If factors that determine invasion dynamics change during the invasion process, the paradox may be partially driven by differences in temporal scale. Here we used simulation (cellular automata) models to explore the generality of temporal change in the diversity-invasibility relationship. The probability of invaders colonizing an area was inversely related to the density of natives, creating a negative native-exotic correlation when invaders first arrived. Over time, native and exotic populations were both shaped by the same post-introduction processes (disturbance, dispersal, and recolonization), shifting their correlation to positive. The rate of temporal change in the diversity-invasibility relationship was mainly dependent upon the fecundity of invaders. Greater fecundity meant that invaders spread through the landscape faster and were subject to post-introduction processes sooner. We propose a unified conceptual model where the diversity-invasiblity relationship is a function of both spatial and temporal scales.

Published

2013

12. Temporal change in the diversity-invasibility relationship in the presence of a disturbance regime.

Author

Clark GF and Johnston EL

Subjects

Animals, Aquatic Organisms, Ecosystem, Linear Models, New South Wales, Population Dynamics, Time Factors, Biodiversity, Bryozoa physiology, Introduced Species

Abstract

Disturbance can affect both the diversity and invasibility of communities. Many field studies have found correlations between diversity and susceptibility to invasion, but if both factors independently respond to disturbance then spurious non-causal relationships may be observed. Here, we show that disturbance can cause a temporal shift in the diversity-invasibility relationship. In a field experiment using sessile marine communities, disturbance strongly affected both diversity and invasion such that they were highly correlated. Disturbance facilitated initial invasion, creating a negative diversity-invasibility relationship when the invader first arrived. Over time, disturbance hindered the persistence of invaders, creating a positive diversity-invasibility relationship. We suggest that temporal changes in the diversity-invasibility relationship may have contributed to the 'invasion paradox', a term for the contrasting patterns of experimental and observational studies of the diversity-invasibility relationship., (© 2010 Blackwell Publishing Ltd/CNRS.)

Published

2011

13. MBACI sampling of an episodic disturbance: stormwater effects on algal epifauna.

Author

Roberts DA, Poore AG, and Johnston EL

Subjects

Amphipoda physiology, Animals, Copepoda physiology, Crustacea physiology, Gastropoda physiology, Polychaeta physiology, Population Dynamics, Water Pollution analysis, Biodiversity, Environmental Monitoring methods, Rain, Sargassum physiology, Water chemistry

Abstract

Whilst it has been well established that stormwater and associated contaminants negatively impact the quality of recipient waters, the ecological effects of individual stormwater pulses in marine environments are relatively unknown. In this study, the impacts of stormwater outfalls upon water quality and epifaunal invertebrates inhabiting the alga Sargassum linearifolium are assessed through an MBACI sampling program. Water quality and the abundance of mobile algal epifauna were recorded at three control sites and three impact sites every 10-12 weeks during dry weather and opportunistically within 24h of large rain events (>50 ml rainfall in 24h) and again 4d after the rain event. Sampling took place during two periods over two separate years and this included four large rainfall events. Following rainfall, salinity dropped rapidly at impact sites close to stormwater outfalls, whilst turbidity increased. Declines in salinity at control sites were slight and turbidity did not differ to 'before' periods. The abundance of epifaunal gastropods and polychaetes were reduced at impact sites 24h after rain events, but not control sites. The abundance of copepods, amphipods and ostracods, however, were reduced at both control and impact sites for up to 4d following rainfall. Reductions of these taxonomic groups could not be attributed to stormwater outfalls. Whilst short-term impacts of stormwater runoff were identified for some faunal groups, impacts were not identified for the majority. Instead, effects were harbour-wide (i.e. at control and impact sites), probably in response to the physical disturbance of heavy seas associated with large rain events.

Published

2007

14. Nearshore marine communities at three New Zealand sub-Antarctic islands

Author

Clark, Graeme F., Pastorino, Sara, Marzinelli, Ezequiel M., Turney, Chris S. M., Fogwill, Chris J., and Johnston, Emma L.

Published

2019

15. Marine urbanization: an ecological framework for designing multifunctional artificial structures

Author

Dafforn, Katherine A, Glasby, Tim M, Airoldi, Laura, Rivero, Natalie K, Mayer-Pinto, Mariana, and Johnston, Emma L

Published

2015

16. A global analysis of complexity–biodiversity relationships on marine artificial structures.

Author

Strain, Elisabeth M. A., Steinberg, Peter D., Vozzo, Maria, Johnston, Emma L., Abbiati, Marco, Aguilera, Moises A., Airoldi, Laura, Aguirre, J. David, Ashton, Gail, Bernardi, Maritina, Brooks, Paul, Chan, Benny K. K., Cheah, Chee B., Chee, Su Yin, Coutinho, Ricardo, Crowe, Tasman, Davey, Adam, Firth, Louise B., Fraser, Clarissa, and Hanley, Mick E.

Subjects

OFFSHORE structures, MARINE biodiversity, GLOBAL analysis (Mathematics), APPLIED ecology, SPECIES diversity, BIOTIC communities, BIOLOGICAL laboratories

Abstract

Aim: Topographic complexity is widely accepted as a key driver of biodiversity, but at the patch‐scale, complexity–biodiversity relationships may vary spatially and temporally according to the environmental stressors complexity mitigates, and the species richness and identity of potential colonists. Using a manipulative experiment, we assessed spatial variation in patch‐scale effects of complexity on intertidal biodiversity. Location: 27 sites within 14 estuaries/bays distributed globally. Time period: 2015–2017. Major taxa studied: Functional groups of algae, sessile and mobile invertebrates. Methods: Concrete tiles of differing complexity (flat; 2.5‐cm or 5‐cm complex) were affixed at low–high intertidal elevation on coastal defence structures, and the richness and abundance of the colonizing taxa were quantified after 12 months. Results: The patch‐scale effects of complexity varied spatially and among functional groups. Complexity had neutral to positive effects on total, invertebrate and algal taxa richness, and invertebrate abundances. However, effects on the abundance of algae ranged from positive to negative, depending on location and functional group. The tidal elevation at which tiles were placed accounted for some variation. The total and invertebrate richness were greater at low or mid than at high intertidal elevations. Latitude was also an important source of spatial variation, with the effects of complexity on total richness and mobile mollusc abundance greatest at lower latitudes, whilst the cover of sessile invertebrates and sessile molluscs responded most strongly to complexity at higher latitudes. Conclusions: After 12 months, patch‐scale relationships between biodiversity and habitat complexity were not universally positive. Instead, the relationship varied among functional groups and according to local abiotic and biotic conditions. This result challenges the assumption that effects of complexity on biodiversity are universally positive. The variable effect of complexity has ramifications for community and applied ecology, including eco‐engineering and restoration that seek to bolster biodiversity through the addition of complexity. [ABSTRACT FROM AUTHOR]

Published

2021

17. Caught between a rock and a hard place: Fish predation interacts with crevice width and orientation to explain sessile assemblage structure.

Author

Bolton, Damon K., Johnston, Emma L., Coleman, Melinda A., and Clark, Graeme F.

Subjects

*PREDATORY animals, *SESSILE organisms, *INVERTEBRATE genetics, *PREDATION, *ANIMAL ecology

Abstract

Abstract Complexity in physical habitats may modify predation pressure by allowing differential access of predators to prey. Rocky subtidal environments are inherently complex with many cryptic micro habitats, such as overhangs and crevices. Here, we examine the influence of habitat complexity in mediating predation on sessile assemblage structure by experimentally manipulating fish access to a range of crevice orientations and sizes. Nine fish species/families were recorded actively feeding within crevices, but australian mado, eastern stripey, wrasses and sawtail surgeon accounted for almost 70% of all entries. Sessile assemblages were influenced by crevice width, fish predation and surface orientation, with more predation activity in larger crevices. Assemblage similarity on upward facing surfaces decreased as crevice width increased. While assemblage structure on downward and vertical surfaces was influenced by crevice width and caging separately. Thus, crevice size and orientation are important habitat complexity features that act to partition predation pressure. This may allow distinct sessile assemblages to persist, even when predation can be intense. Graphical abstract Image 1 Highlights • Fish predation affects sessile hard-substrate assemblages. • We used video observation and experimental predator exclusion. • Predation pressure is mediated by crevice size and orientation. • Habitat complexity partitions sessile invertebrate community diversity. • Crevice size and orientation are important features of rocky-reef habitat. [ABSTRACT FROM AUTHOR]

Published

2018

18. Key drivers of effectiveness in small marine protected areas.

Author

Turnbull, John W., Shah Esmaeili, Yasmina, Clark, Graeme F., Figueira, Will F., Johnston, Emma L., and Ferrari, Renata

Subjects

MARINE parks & reserves, BIODIVERSITY, RESTORATION ecology, HABITATS, BIOMASS

Abstract

Marine Protected Areas (MPAs) are a key management tool for the conservation of biodiversity and restoration of marine communities. While large, well-designed and enforced MPAs have been found to be effective, results from small MPAs vary. The Hawkesbury Shelf, a coastal bioregion in New South Wales, Australia, has ten small, near-shore MPAs known as Aquatic Reserves with a variety of protection levels from full no-take to partial protection. This study assessed the effectiveness of these MPAs and analysed how MPA age, size, protection level, wave exposure, habitat complexity, and large canopy-forming algal cover affected fish, invertebrate and benthic communities. We found aspect, protection level, complexity and algal canopy to be important predictors of communities in these MPAs. Most MPAs, however, were not effective in meeting their goals. Only full no-take protection (three out of ten MPAs) had a significant impact on fish assemblages. One no-take MPA—Cabbage Tree Bay—which is naturally sheltered from wave action and benefits from an active local community providing informal enforcement, accounted for most of the increased richness of large fish and increased biomass of targeted fish species. Our findings suggest that small MPAs can enhance biodiversity and biomass on a local scale but only if they have full no-take protection, are in sheltered locations with complex habitat, and have positive community involvement to engender support and stewardship. These results provide a baseline for robust assessment of the effectiveness of small MPAs and inform future management decisions and small MPA design in other locations. [ABSTRACT FROM AUTHOR]

Published

2018

19. Contaminant pulse following wildfire is associated with shifts in estuarine benthic communities.

Author

Bracewell, Sally A., Barros, Thayanne L., Mayer-Pinto, Mariana, Dafforn, Katherine A., Simpson, Stuart L., and Johnston, Emma L.

Subjects

COMMUNITIES, BIOTIC communities, WILDFIRES, ESTUARINE sediments, ECOLOGICAL impact, WILDFIRE prevention, FIRE management, HABITATS, FOREST fire ecology

Abstract

Novel combinations of climatic conditions due to climate change and prolonged fire seasons have contributed to an increased occurrence of "megafires". Such large-scale fires pose an unknown threat to biodiversity due to the increased extent and severity of burn. Assessments of wildfires often focus on terrestrial ecosystems and effects on aquatic habitats are less documented, particularly in coastal environments. In a novel application of eDNA techniques, we assessed the impacts of the 2019–2020 Australian wildfires on the diversity of estuarine benthic sediment communities in six estuaries in NSW, Australia, before and after the fires. Estuaries differed in area of catchment burnt (0–92%) and amount of vegetative buffer that remained post-fire between burnt areas and waterways. We found greater dissimilarities in the composition and abundance of eukaryotic and bacterial sediment communities in estuaries from burnt catchments with no buffer compared to those with an intact buffer or from unburnt catchments. Shifts in composition in highly burnt catchments were associated with increased concentrations of nutrients, carbon, including fire-derived pyrogenic carbon, and copper, which was representative of multiple highly correlated trace metals. Changes in the relative abundances of certain taxonomic groups, such as sulfate-reducing and nitrifying bacterial groups, in the most impacted estuaries indicate potential consequences for the functioning of sediment communities. These results provide a unique demonstration of the use of eDNA to identify wildfire impacts on ecological communities and emphasize the importance of vegetative buffers in limiting wildfire-associated impacts. [Display omitted] • Estuarine benthic eukaryotic and bacterial community composition changed post-fire. • Greater differences were observed in severely burnt compared to unburnt catchments. • Changes were associated with increased sediment py-C, TOC, Cu and nutrients. • Shifts in certain bacterial groups may have implications for sediment functioning. • EDNA is a useful tool for rapid assessment of wildfire impacts in aquatic systems. [ABSTRACT FROM AUTHOR]

Published

2023

20. Vulnerability of Antarctic shallow invertebrate-dominated ecosystems.

Author

Clark, Graeme F., Raymond, Ben, Riddle, Martin J., Stark, Jonathan S., and Johnston, Emma L.

Subjects

ANTARCTIC environmental conditions, EFFECT of climate on biodiversity, CLIMATE change, PSYCHOLOGICAL vulnerability

Abstract

Human impacts threaten not only species, but also entire ecosystems. Ecosystems under stress can collapse or transition into different states, potentially reducing biodiversity at a variety of scales. Here we examine the vulnerability of Antarctic shallow invertebrate-dominated ecosystems, which may be threatened for several reasons. These unique shallow-water communities mostly consist of dark-adapted invertebrates, and rely on sea ice to create low-light marine environments. Climate change is likely to cause early breakout of seasonal sea ice in parts of Antarctica, which will dramatically increase the amount of light reaching shallow seabed. This is predicted to result in ecological regime shifts, in which invertebrate-dominated communities are replaced by macroalgal beds. Habitat for these endemic Antarctic ecosystems is globally rare, and the fragmented nature of their distribution along Antarctic coast increases their sensitivity to change. Concurrently, human activities in Antarctica are concentrated in areas where these habitats occur, compounding potential impacts. While there are clear mechanisms of threat to these ecosystems, lack of knowledge about their spatial distribution obscures predictions of potential ecosystem loss, and the likelihood of recovery. In this paper we describe these ecosystems, their association with the environment and the reasons for their vulnerability. We estimate their spatial distribution around Antarctica using sea ice and bathymetric data, and apply the International Union for Conservation of Nature Red List of Ecosystems criteria to assess their vulnerability. Best available data suggest that shallow ice-covered ecosystems are likely Near Threatened to Vulnerable in places, although the magnitude of risk is spatially variable and requires additional data to strengthen the assessment. [ABSTRACT FROM AUTHOR]

Published

2015

21. The Role of Habitat Complexity in Community Development Is Mediated by Resource Availability.

Author

Smith, Rachel S., Johnston, Emma L., and Clark, Graeme F.

Subjects

*HABITATS, *BIOTIC communities, *SPECIES diversity, *RESOURCE availability (Ecology), *COMMUNITY development, *SPATIAL variation

Abstract

Habitat complexity strongly affects the structure and dynamics of ecological communities, with increased complexity often leading to greater species diversity and abundance. However, habitat complexity changes as communities develop, and some species alter their environment to themselves provide habitat for other species. Most experimental studies manipulate basal substrate complexity, and while the importance of complexity likely changes during community development, few studies have examined the temporal dynamics of this variable. We used two experiments to quantify the importance of basal substrate complexity to sessile marine invertebrate community development through space and time. First, we compared effects of substrate complexity at 70 sites across ten estuaries. Sites differed in recruitment and community development rates, and after three months provided spatial variation in community development stage. Second, we tested for effects of substrate complexity at multiple times at a single site. In both experiments, complexity affected marine sessile invertebrate community composition in the early stages of community development when resource availability was high. Effects of complexity diminished through time as the amount of available space (the primary limiting resource) declined. Our work suggests the presence of a bare-space threshold, at which structural complexity of the basal substrate is overwhelmed by secondary biotic complexity. This threshold will be met at different times depending on local recruitment and growth rates and is likely to vary with productivity gradients. [ABSTRACT FROM AUTHOR]

Published

2014

22. Light-driven tipping points in polar ecosystems.

Author

Clark, Graeme F., Stark, Jonathan S., Johnston, Emma L., Runcie, John W., Goldsworthy, Paul M., Raymond, Ben, and Riddle, Martin J.

Subjects

BIODIVERSITY, MARINE ecology, ENVIRONMENTAL protection, BIOTIC communities, BENTHIC ecology, CLIMATE change

Abstract

Some ecosystems can undergo abrupt transformation in response to relatively small environmental change. Identifying imminent 'tipping points' is crucial for biodiversity conservation, particularly in the face of climate change. Here, we describe a tipping point mechanism likely to induce widespread regime shifts in polar ecosystems. Seasonal snow and ice-cover periodically block sunlight reaching polar ecosystems, but the effect of this on annual light depends critically on the timing of cover within the annual solar cycle. At high latitudes, sunlight is strongly seasonal, and ice-free days around the summer solstice receive orders of magnitude more light than those in winter. Early melt that brings the date of ice-loss closer to midsummer will cause an exponential increase in the amount of sunlight reaching some ecosystems per year. This is likely to drive ecological tipping points in which primary producers (plants and algae) flourish and out-compete dark-adapted communities. We demonstrate this principle on Antarctic shallow seabed ecosystems, which our data suggest are sensitive to small changes in the timing of sea-ice loss. Algae respond to light thresholds that are easily exceeded by a slight reduction in sea-ice duration. Earlier sea-ice loss is likely to cause extensive regime shifts in which endemic shallow-water invertebrate communities are replaced by algae, reducing coastal biodiversity and fundamentally changing ecosystem functioning. Modeling shows that recent changes in ice and snow cover have already transformed annual light budgets in large areas of the Arctic and Antarctic, and both aquatic and terrestrial ecosystems are likely to experience further significant change in light. The interaction between ice-loss and solar irradiance renders polar ecosystems acutely vulnerable to abrupt ecosystem change, as light-driven tipping points are readily breached by relatively slight shifts in the timing of snow and ice-loss. [ABSTRACT FROM AUTHOR]

Published

2013

23. Contaminants reduce the richness and evenness of marine communities: A review and meta-analysis

Author

Johnston, Emma L. and Roberts, David A.

Subjects

POLLUTANTS, MARINE biology, META-analysis, FIELD research, BIOTIC communities, ANTHROPOGENIC effects on nature, BIODIVERSITY, INFORMATION measurement

Abstract

Abstract: Biodiversity of marine ecosystems is integral to their stability and function and is threatened by anthropogenic processes. We conducted a literature review and meta-analysis of 216 studies to understand the effects of common contaminants upon diversity in various marine communities. The most common diversity measures were species richness, the Shannon–Wiener index (H′) and Pielou evenness (J). Largest effect sizes were observed for species richness, which tended to be the most sensitive index. Pollution was associated with marine communities containing fewer species or taxa than their pristine counterparts. Marine habitats did not vary in their susceptibility to contamination, rather a ∼40% reduction in richness occurred across all habitats. No class of contaminant was associated with significantly greater impacts on diversity than any other. Survey studies identified larger effects than laboratory or field experiments. Anthropogenic contamination is strongly associated with reductions in the species richness and evenness of marine habitats. [Copyright &y& Elsevier]

Published

2009

24. A global horizon scan of issues impacting marine and coastal biodiversity conservation

Author

James E. Herbert-Read, Ann Thornton, Diva J. Amon, Silvana N. R. Birchenough, Isabelle M. Côté, Maria P. Dias, Brendan J. Godley, Sally A. Keith, Emma McKinley, Lloyd S. Peck, Ricardo Calado, Omar Defeo, Steven Degraer, Emma L. Johnston, Hermanni Kaartokallio, Peter I. Macreadie, Anna Metaxas, Agnes W. N. Muthumbi, David O. Obura, David M. Paterson, Alberto R. Piola, Anthony J. Richardson, Irene R. Schloss, Paul V. R. Snelgrove, Bryce D. Stewart, Paul M. Thompson, Gordon J. Watson, Thomas A. Worthington, Moriaki Yasuhara, William J. Sutherland, Herbert-Read, James E [0000-0003-0243-4518], Thornton, Ann [0000-0002-7448-8497], Amon, Diva J [0000-0003-3044-107X], Birchenough, Silvana NR [0000-0001-5321-8108], Côté, Isabelle M [0000-0001-5368-4061], Dias, Maria P [0000-0002-7281-4391], Keith, Sally A [0000-0002-9634-2763], McKinley, Emma [0000-0002-8250-2842], Peck, Lloyd S [0000-0003-3479-6791], Defeo, Omar [0000-0001-8318-528X], Degraer, Steven [0000-0002-3159-5751], Johnston, Emma L [0000-0002-2117-366X], Macreadie, Peter I [0000-0001-7362-0882], Metaxas, Anna [0000-0002-1935-6213], Obura, David O [0000-0003-2256-6649], Piola, Alberto R [0000-0002-5003-8926], Richardson, Anthony J [0000-0002-9289-7366], Schloss, Irene R [0000-0002-5917-8925], Snelgrove, Paul VR [0000-0002-6725-0472], Thompson, Paul M [0000-0001-6195-3284], Watson, Gordon J [0000-0001-8274-7658], Worthington, Thomas A [0000-0002-8138-9075], Yasuhara, Moriaki [0000-0003-0990-1764], Apollo - University of Cambridge Repository, University of St Andrews. School of Biology, University of St Andrews. Scottish Oceans Institute, University of St Andrews. St Andrews Sustainability Institute, University of St Andrews. Coastal Resources Management Group, University of St Andrews. Sediment Ecology Research Group, University of St Andrews. Marine Alliance for Science & Technology Scotland, Repositório da Universidade de Lisboa, Suomen ympäristökeskus, and The Finnish Environment Institute

Subjects

Climate Change, meriensuojelu, marine and costal areas, ekosysteemit, rannikot, SDG 13 - Climate Action, Animals, Humans, SDG 14 - Life Below Water, suojelu, new technologies, luonnonvarat, Ecology, Evolution, Behavior and Systematics, Ecosystem, hyväksikäyttö, GC, ecosystem impacts, Ecology, uusi teknologia, resource exploitation, DAS, Biodiversity, luonnon monimuotoisuus, AC, biodiversiteetti, ympäristövaikutukset, GC Oceanography, biodiversity conservation, meret

Abstract

This Marine and Coastal Horizon Scan was funded by Oceankind. S.N.R.B. is supported by EcoStar (DM048) and Cefas (My time). R.C. acknowledges FCT/MCTES for the financial support to CESAM (UIDP/50017/2020, UIDB/50017/2020, LA/P/0094/2020) through national funds. O.D. is supported by CSIC Uruguay and Inter-American Institute for Global Change Research. J.E.H.-R. is supported by the Whitten Lectureship in Marine Biology. S.A.K. is supported by a Natural Environment Research Council grant (NE/S00050X/1). P.I.M. is supported by an Australian Research Council Discovery Grant (DP200100575). D.M.P. is supported by the Marine Alliance for Science and Technology for Scotland (MASTS). A.R.P. is supported by the Inter-American Institute for Global Change Research. W.J.S. is funded by Arcadia. A.T. is supported by Oceankind. M.Y. is supported by the Deep Ocean Stewardship Initiative and bioDISCOVERY. The biodiversity of marine and coastal habitats is experiencing unprecedented change. While there are well-known drivers of these changes, such as overexploitation, climate change and pollution, there are also relatively unknown emerging issues that are poorly understood or recognized that have potentially positive or negative impacts on marine and coastal ecosystems. In this inaugural Marine and Coastal Horizon Scan, we brought together 30 scientists, policymakers and practitioners with transdisciplinary expertise in marine and coastal systems to identify new issues that are likely to have a significant impact on the functioning and conservation of marine and coastal biodiversity over the next 5–10 years. Based on a modified Delphi voting process, the final 15 issues presented were distilled from a list of 75 submitted by participants at the start of the process. These issues are grouped into three categories: ecosystem impacts, for example the impact of wildfires and the effect of poleward migration on equatorial biodiversity; resource exploitation, including an increase in the trade of fish swim bladders and increased exploitation of marine collagens; and new technologies, such as soft robotics and new biodegradable products. Our early identification of these issues and their potential impacts on marine and coastal biodiversity will support scientists, conservationists, resource managers and policymakers to address the challenges facing marine ecosystems. Postprint

Published

2022

25. Identifying the consequences of ocean sprawl for sedimentary habitats

Author

Mariana Mayer-Pinto, Melanie J. Bishop, Eliza C. Heery, Larissa A. Naylor, Valeriya Komyakova, Ana B. Bugnot, Ross A. Coleman, Rebecca L. Morris, Emma V. Sheehan, Lincoln P. Critchley, Katherine A. Dafforn, Elisabeth M. A. Strain, Lynette H.L. Loke, Laura Airoldi, Emma L. Johnston, Heery, Eliza C, Bishop, Melanie J., Critchley, Lincoln P., Bugnot, Ana B., Airoldi, Laura, Mayer-Pinto, Mariana, Sheehan, Emma V., Coleman, Ross A., Loke, Lynette H.L., Johnston, Emma L., Komyakova, Valeriya, Morris, Rebecca L., Strain, Elisabeth M.A., Naylor, Larissa A., and Dafforn, Katherine A.

Subjects

0106 biological sciences, Evolution, Biodiversity, Aquatic Science, Biology, 010603 evolutionary biology, 01 natural sciences, Offshore wind farm, Coastal defense, Behavior and Systematics, Ecosystem, 14. Life underwater, Artificial structure, Ecological impact, Marine sediment, Urbanization, Ecology, Ecology, Evolution, Behavior and Systematics, 010604 marine biology & hydrobiology, fungi, Marine habitats, Cumulative effects, Urban sprawl, 15. Life on land, Ecology, Evolution, Behavior and Systematic, Habitat destruction, Habitat, 13. Climate action, Sedimentary rock

Abstract

Extensive development and construction in marine and coastal systems is driving a phenomenon known as “ocean sprawl”. Ocean sprawl removes or transforms marine habitats through the addition of artificial structures and some of the most significant impacts are occurring in sedimentary environments. Marine sediments have substantial social, ecological, and economic value, as they are rich in biodiversity, crucial to fisheries productivity, and major sites of nutrient transformation. Yet the impact of ocean sprawl on sedimentary environments has largely been ignored. Here we review current knowledge of the impacts to sedimentary ecosystems arising from artificial structures.\ud \ud Artificial structures alter the composition and abundance of a wide variety of sediment-dependent taxa, including microbes, invertebrates, and benthic-feeding fishes. The effects vary by structure design and configuration, as well as the physical, chemical, and biological characteristics of the environment in which structures are placed. The mechanisms driving effects from artificial structures include placement loss, habitat degradation, modification of sound and light conditions, hydrodynamic changes, organic enrichment and material fluxes, contamination, and altered biotic interactions. Most studies have inferred mechanism based on descriptive work, comparing biological and physical processes at various distances from structures. Further experimental studies are needed to identify the relative importance of multiple mechanisms and to demonstrate causal relationships. Additionally, past studies have focused on impacts at a relatively small scale, and independently of other development that is occurring. There is need to quantify large-scale and cumulative effects on sedimentary ecosystems as artificial structures proliferate. We highlight the importance for comprehensive monitoring using robust survey designs and outline research strategies needed to understand, value, and protect marine sedimentary ecosystems in the face of a rapidly changing environment.

Published

2017