Your search keyword '"John K. Pearman"' showing total 4 results

1. It's all in the mud - The use of sediment geochemistry to estimate contemporary water quality in lakes

Author

Sean Waters, Javier Atalah, Lucy Thompson, Georgia Thomson-Laing, John K. Pearman, Jonathan Puddick, Jamie D. Howarth, Lizette Reyes, Marcus J. Vandergoes, and Susanna A. Wood

Subjects

Geochemistry and Petrology, Environmental Chemistry, Pollution

Published

2023

2. First transcriptome of the copepod Gladioferens pectinatus subjected to chronic contaminant exposures

Author

Andrew Barrick, Olivier Laroche, Michael Boundy, John K. Pearman, Tanja Wiles, Juliette Butler, Xavier Pochon, Kirsty F. Smith, and Louis A. Tremblay

Subjects

Copepoda, Health, Toxicology and Mutagenesis, Animals, Pectinatus, Aquatic Science, Transcriptome, Ecosystem, Water Pollutants, Chemical

Abstract

Contaminants are often at low concentrations in ecosystems and their effects on exposed organisms can occur over long periods of time and across multiple generations. Alterations to subcellular mechanistic pathways in response to exposure to contaminants can provide insights into mechanisms of toxicity that methods measuring higher levels of biological may miss. Analysis of the whole transcriptome can identify novel mechanisms of action leading to impacts in exposed biota. The aim of this study was to characterise how exposures to copper, benzophenone and diclofenac across multiple generations altered molecular expression pathways in the marine copepod Gladioferens pectinatus. Results of the study demonstrated differential gene expression was observed in cultures exposure to diclofenac (569), copper (449) and benzophenone (59). Pathways linked to stress, growth, cellular and metabolic processes were altered by exposure to all three contaminants with genes associated with oxidative stress and xenobiotic regulation also impacted. Protein kinase functioning, cytochrome P450, transcription, skeletal muscle contraction/relaxation, mitochondrial phosphate translocator, protein synthesis and mitochondrial methylation were all differentially expressed with all three chemicals. The results of the study also suggested that using dimethyl sulfoxide as a dispersant influenced the transcriptome and future research may want to investigate it's use in molecular studies. Data generated in this study provides a first look at transcriptomic response of G. pectinatus exposed to contaminants across multiple generations, future research is needed to validate the identified biomarkers and link these results to apical responses such as population growth to demonstrate the predictive capacity of molecular tools.

Published

2022

3. Environmental DNA metabarcoding reveals estuarine benthic community response to nutrient enrichment – Evidence from an in-situ experiment

Author

Anastasija Zaiko, Conrad A. Pilditch, Joanne I. Ellis, John K. Pearman, and Dana Clark

Subjects

010504 meteorology & atmospheric sciences, Ecological health, Health, Toxicology and Mutagenesis, 010501 environmental sciences, Biology, Toxicology, 01 natural sciences, RNA, Ribosomal, 16S, Environmental monitoring, DNA Barcoding, Taxonomic, Environmental DNA, Ecosystem, 0105 earth and related environmental sciences, Ecology, Community structure, Biodiversity, Nutrients, General Medicine, biology.organism_classification, DNA, Environmental, Pollution, Diatom, Benthic zone, Metagenomics, Environmental Monitoring, New Zealand

Abstract

Nutrient loading is a major threat to estuaries and coastal environments worldwide, therefore, it is critical that we have good monitoring tools to detect early signs of degradation in these ecologically important and vulnerable ecosystems. Traditionally, bottom-dwelling macroinvertebrates have been used for ecological health assessment but recent advances in environmental genomics mean we can now characterize less visible forms of biodiversity, offering a more holistic view of the ecosystem and potentially providing early warning signals of disturbance. We carried out a manipulative nutrient enrichment experiment (0, 150 and 600 g N fertilizer m−2) in two estuaries in New Zealand to assess the effects of nutrient loading on benthic communities. After seven months of enrichment, environmental DNA (eDNA) metabarcoding was used to examine the response of eukaryotic (18S rRNA), diatom only (rbcL) and bacterial (16S rRNA) communities. Multivariate analyses demonstrated changes in eukaryotic, diatom and bacterial communities in response to nutrient enrichment at both sites, despite differing environmental conditions. These patterns aligned with changes in macrofaunal communities identified using traditional morphological techniques, confirming concordance between disturbance indicators detected by eDNA and current monitoring approaches. Clear shifts in eukaryotic and bacterial indicator taxa were seen in response to nutrient loading while changes in diatom only communities were more subtle. Community changes were discernible between 0 and 150 g N m−2 treatments, suggesting that estuary health assessment tools could be developed to detect early signs of degradation. Increasing variation in community structure associated with nutrient loading could also be used as an indicator of stress or approaching tipping points. This work represents a first step towards the development of molecular-based estuary monitoring tools, which could provide a more holistic and standardized approach to ecosystem health assessment with faster turn-around times and lower costs.

Published

2020

4. Translational Molecular Ecology in practice: Linking DNA-based methods to actionable marine environmental management

Author

Kat Bruce, Burton H. Jones, Susana Carvalho, Eric D. Stein, Gregory M. Ruiz, Xavier Pochon, Anastasija Zaiko, Ángel Borja, Susanna Theroux, Yasser Katan, Sultan Alamer, Carlos M. Duarte, Ammar Saleem, Pei-Ying Hong, Darren J. Coker, Nathan R. Geraldi, Alejandra Ortega, John K. Pearman, Tyas I. Hikmawan, Eva Aylagas, Laura Gajdzik, and Nigel Keeley

Subjects

Conservation of Natural Resources, Environmental Engineering, Ecology, 010504 meteorology & atmospheric sciences, Computer science, business.industry, Environmental resource management, Biodiversity, DNA, 010501 environmental sciences, 01 natural sciences, Pollution, Environmental Policy, Molecular ecology, Aquatic environment, Scale (social sciences), Environmental Chemistry, Environmental policy, Temporal scales, business, Waste Management and Disposal, Marine Policy, 0105 earth and related environmental sciences

Abstract

Molecular-based approaches can provide timely biodiversity assessments, showing an immense potential to facilitate decision-making in marine environmental management. However, the uptake of molecular data into environmental policy remains minimal. Here, we showcase a selection of local to global scale studies applying molecular-based methodologies for environmental management at various stages of implementation. Drawing upon lessons learned from these case-studies, we provide a roadmap to facilitate applications of DNA-based methods to marine policies and to overcome the existing challenges. The main impediment identified is the need for standardized protocols to guarantee data comparison across spatial and temporal scales. Adoption of Translational Molecular Ecology - the sustained collaboration between molecular ecologists and stakeholders, will enhance consensus with regards to the objectives, methods, and outcomes of environmental management projects. Establishing a sustained dialogue among stakeholders is key to accelerating the adoption of molecular-based approaches for marine monitoring and assessment.

Published

2020