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Papers
20 resultsShowing papers similar to Insight into the multifactorial effect of climate change on marine bacteria: resilience mechanisms and mitigation strategies
ClearFunctional responses of key marine bacteria to environmental change – toward genetic counselling for coastal waters
This review examined the functional responses of key marine bacteria to environmental stressors including nutrient pollution and chemical contamination in coastal ecosystems, arguing that bacteria are overlooked both as indicators and mediators of ecosystem health. The authors call for incorporating bacterial functional metrics into marine ecosystem monitoring and management frameworks.
Culture dependent analysis of bacterial activity, biofilm-formation and oxidative stress of seawater with the contamination of microplastics under climate change consideration
Researchers examined how temperature changes and microplastic contamination jointly affect bacterial activity, biofilm formation, and oxidative stress in seawater. The study found that different plastic materials at varying temperatures produced distinct bacterial responses, suggesting that climate change could compound the environmental effects of microplastic pollution in marine settings.
Distribution and Metabolic Activities of Marine Microbes in Response to Natural and Anthropogenic Stressors
This review examines how natural stressors such as temperature warming and acidification, combined with anthropogenic pressures like biodiversity loss and water quality degradation, affect the distribution and metabolic activities of marine microbial communities. Researchers synthesized evidence showing that microbial responses to combined stressors are often non-additive and context-dependent, with implications for biogeochemical cycling in changing ocean environments.
The role of marine bacteria in modulating the environmental impact of heavy metals, microplastics, and pesticides: a comprehensive review
This comprehensive review covers how marine bacteria mitigate environmental impacts of heavy metals, microplastics, and pesticides through processes including biosorption, biotransformation, biofilm colonization of microplastics, and enzymatic pesticide degradation.
The evolution of bacterial pathogens in the Anthropocene
Researchers reviewed how anthropogenic environmental changes — including plastic pollution — may accelerate bacterial pathogen evolution by altering mutation rates, horizontal gene transfer, and selection pressures, using the microplastic plastisphere as a case study for how pollution can drive microbial diversification with implications for human infection risk.
Research progress in ecotoxicology of climate change coupled with marine pollutions
This review examined how rising ocean temperatures and acidification from climate change interact with marine pollutants including microplastics, finding that combined stressors often produce worse effects than either alone. The research underscores that plastic pollution cannot be addressed in isolation from the broader context of global climate change.
The Role Of Bacteria In Microplastic Bioremediation And Implications For Marine Ecosystems
This literature review summarizes how bacteria can be harnessed through bioremediation to break down microplastics in marine environments, cataloging the bacterial species and mechanisms involved. While biological degradation is slow and not yet a practical cleanup solution at scale, identifying effective bacteria is an important step toward developing tools to reduce the long-term accumulation of microplastics in ocean ecosystems.
Environmental drivers of antibiotic resistance: Synergistic effects of climate change, co-pollutants, and microplastics
This review examines how climate change, chemical pollutants, and microplastics work together to accelerate the spread of antibiotic resistance, a growing global health crisis. Microplastics provide surfaces where bacteria form communities that exchange resistance genes, and as these plastics age in the environment, they become even better at absorbing other pollutants, creating hotspots that amplify drug resistance.
Unlocking secrets of microbial ecotoxicology: recent achievements and future challenges
This review explores how microorganisms interact with environmental pollutants, including microplastics, covering how bacteria can break down pollutants but are also harmed by them. The authors highlight that microplastics create new surfaces in the environment where bacteria form communities, potentially spreading harmful species or antibiotic resistance. Understanding these microbial interactions is critical for developing nature-based solutions to reduce pollution and protect human health.
Unveiling the hidden world of microorganisms and their impact on the Earth's ecosystems
This paper is not directly about microplastics; it is a broad review of microbial ecology covering microorganism roles in biogeochemical cycling of carbon, nitrogen, phosphorus, sulfur, and metals, and how advances in genomics have transformed our understanding of microbial community diversity and function.
Can Microplastic Pollution Change Important Aquatic Bacterial Communities?
Microplastics in coastal sediments can change the composition of important bacterial communities that cycle nutrients and maintain ecosystem health. Microplastic-associated bacteria differ significantly from natural sediment bacteria, with potential consequences for the chemical processes these communities perform.
Emerging challenges of microplastic impacts to ecological health and climate change
This review examines how microplastics contribute not only to environmental pollution but also to climate change by altering microbial processes, disrupting biogeochemical cycles, and promoting greenhouse gas release. Researchers found that microplastics affect carbon cycling, phytoplankton photosynthesis, and atmospheric processes in ways that may exacerbate global warming. The study highlights significant knowledge gaps in understanding the mechanisms linking microplastic pollution to greenhouse gas emissions.
A Comprehensive Review of Climatic Threats and Adaptation of Marine Biodiversity
This comprehensive review examines how climate change threatens marine biodiversity through rising ocean temperatures, acidification, and habitat loss. Among the many environmental stressors discussed, microplastic pollution is highlighted as an additional threat that compounds the effects of climate change on marine ecosystems. The paper evaluates adaptation strategies like marine protected areas and habitat restoration that could help protect the ocean ecosystems humans depend on for food.
The threat of microplastics and microbial degradation potential; a current perspective
This review covers the growing threat of microplastics in marine environments, where they enter the food chain and can transfer to humans along with pathogenic organisms, causing various toxic effects. The paper also explores how bacteria and fungi found in ocean environments could be harnessed to biodegrade different types of plastics as a future strategy for reducing microplastic pollution.
Research progress on the interaction between climate change and marine microplastic pollution
This review examines the two-way relationship between climate change and marine microplastic pollution, finding that rising ocean temperatures, acidification, and hypoxia can accelerate plastic fragmentation and alter how microplastics are distributed and ingested by marine life. Conversely, microplastics may affect carbon cycling and plankton productivity in ways that feed back into climate dynamics. The findings highlight that microplastic risks cannot be assessed in isolation from the broader context of a changing ocean.
Warming and microplastic pollution shape the carbon and nitrogen cycles of algae
Researchers investigated how ocean warming combined with microplastic pollution affects carbon and nitrogen cycling in marine diatoms and dinoflagellates, revealing that these combined stressors alter key biochemical processes in dominant phytoplankton species.
Marine microbes in the Plastic Age
This review examines how marine microbes interact with plastic debris in the ocean, describing the physical threats of plastic ingestion and entanglement as well as chemical threats from plastic-associated toxins that can bioaccumulate through food webs. Researchers call for greater investigation into how plastic pollution alters microbial community composition, biodegradation potential, and the broader functioning of ocean ecosystems.
Global Changes Alter the Successions of Early Colonizers of Benthic Surfaces
Not relevant to microplastics — this review examines how climate change and ocean acidification alter the succession of early-colonising organisms (bacteria, diatoms) on underwater surfaces, with no microplastic content.
Microplastics and microbial interactions in marine environments: A critical review on biogeochemical cycling and ecological impacts
This review integrated bibliometric analysis of 2015-2025 literature with mechanistic synthesis to examine how marine microplastic pollution affects ecosystems through physicochemical and biological processes, highlighting the multifaceted interactions between microplastics and microbial communities.
Comparative whole-genome approach to identify bacterial traits for microbial interactions
A genome-based trait analysis of 473 marine bacterial species was developed to systematically map the functional and interaction potential of marine microbial communities. The findings advance understanding of how marine bacteria function, with relevance to how microbial communities respond to plastic pollution in the ocean.