Your search keyword '"Monsinjon, Jonathan R."' showing total 2 results

1. Symbiotic endolithic microbes reduce host vulnerability to an unprecedented heatwave.

Author

Zardi, Gerardo I., Monsinjon, Jonathan R., Seuront, Laurent, Spilmont, Nicolas, McQuaid, Christopher D., and Nicastro, Katy R.

Subjects

*HEAT waves (Meteorology), *CLIMATE extremes, *THERMAL stresses, *MYTILUS edulis, *MICROORGANISMS, *SYMBIODINIUM, *CORAL bleaching, *ECOSYSTEMS, *MARINE organisms

Abstract

Heatwaves are increasingly severe and frequent, posing significant threats to ecosystems and human well-being. Characterised by high thermal variability, intertidal communities are particularly vulnerable to heat stress. Microbial endolithic communities that are found in marine calcifying organisms have been shown to induce shell erosion that alters shell surface colour, lowering body temperatures and increasing survival rates. Here, we investigate how the symbiotic relationship between endolithic microbes and the blue intertidal mussel Mytilus edulis mitigates thermal stress during the unprecedented 2022 atmospheric heatwave in the English Channel. Microbial infestation of the shell significantly enhanced mussel survival, particularly higher on the shore where thermal stress was greater. Using data from biomimetic temperature loggers, we predicted the expected thermal buffer and observed differences up to 3.2 °C between individuals with and without symbionts under the known conditions of the heat wave-induced mortality event. The ecological implications extend beyond individual mussels, affecting the reef-building capacity of mussels, with potential cascading effects for local biodiversity, carbon sequestration, and coastal defence. These findings emphasize the importance of understanding small-scale biotic interactions during extreme climate events and provide insights into the dynamic nature of the endolith-mussel symbiosis along a parasitic-mutualistic continuum influenced by abiotic factors. • Heatwaves are intensifying, posing significant threats to ecosystems and well-being. • Intertidal communities, facing high thermal variability, are particularly vulnerable. • Endolithic microbes induce shell changes, enhancing mussel survival. • These symbionts increased survival during the 2022 English Channel heatwave. • The impact extends beyond the single mussel species to the intertidal biodiversity it supports. [ABSTRACT FROM AUTHOR]

Published

2024

2. Biogeographic drivers of distribution and abundance in an alien ecosystem engineer: Transboundary range expansion, barriers to spread, and spatial structure.

Author

Ma, Kevin C. K., Gusha, Molline N. C., Zardi, Gerardo I., Nicastro, Katy R., Monsinjon, Jonathan R., McQuaid, Christopher D., and Bernardi, Giacomo

Subjects

MYTILUS galloprovincialis, ECOSYSTEMS, INTRODUCED species, PLANT invasions, ENGINEERS, BIOLOGICAL invasions, ENGINEERING

Abstract

Aim: Biogeographic boundaries can act as either weak or strong barriers to the spread of species undergoing distributional change. Once a novel species spreads across a boundary, it can have a substantial impact on the ecosystem, for instance by competing with local species, and, over the long‐term, re‐engineer the ecosystem. Marine biogeographic regions are clearly defined on the coast of southern Africa and we tested the influence of their boundaries on the spread and spatial structure of an alien ecosystem engineer. Location: Southern Africa. Taxon: An invasive mussel, Mytilus galloprovincialis. Methods: Records of M. galloprovincialis were compiled into a database to determine its decadal patterns of spread across multiple bioregions. Distribution and abundance (estimated using density and semi‐quantitative abundance scale [ACFOR]) of this mussel were surveyed to determine patterns in spatial structure across bioregions. In addition, we compared the size structure of populations at the eastern margins of its range with those of larger populations nearer the range centre. Results: Initial breaching of biogeographic boundaries was associated with rapid spread, but other boundaries encountered decades later acted as barriers to further spread. Across >2,800 km of coast, spatial autocorrelation was observed in densities (low and mid shore levels) and in ACFOR abundances. Repeating spatial patterns in densities and ACFOR abundance were detected at scales of 120–160 km and of 400–990 km. Considerable effort was required to detect populations at the absolute eastern limits of its distribution. Main conclusion: Detection of spatial structures at multiple scales suggests that ecologically determined processes regulate abundance at both intra‐bioregional and inter‐bioregional scales, which may help tease apart the historic and contemporary consequences of interspecific interactions on the structure of rocky shore communities. This study demonstrates the influence of biogeography in driving temporal patterns of spread and spatial structure on the distribution and abundance of an invasive species. [ABSTRACT FROM AUTHOR]

Published

2021