Implications of climate change for terrestrial microbiomes and global cycles

Soil microbiomes are highly diverse ecosystems that play a central role in ecosystem functioning and regulating global biogeochemical cycles. 

The collection ‘Implications of climate change for terrestrial microbiomes and global cycles’ is guest-edited by Drs Michael Macey (Open University), Sarah Worsley (UEA), and Geertje van Keulen (Swansea University), aims to highlight key research investigating the role of soil microbiomes in climate feedback processes, and their response to global change. 


Symbiosis has played a key role in the evolution of life on Earth. Symbiotic mergers of once independent species drove the origin of eukaryotes. Moreover, symbiosis has enabled many species to gain novel functions and occupy new ecological niches, thus underpinning the functioning of diverse ecosystems. 

This collection, guest edited by Professor Michael Brockhurst (University of Manchester) and Dr. Rebecca J Hall (University of Birmingham), will feature microbe-focused studies of symbiosis, ranging from the molecular mechanisms of host-symbiont interactions, their genetic and genomic diversity, to understanding the impacts of symbioses in natural and manmade ecosystems.

Antimicrobial Resistance

Antimicrobial drugs underpin much of modern medicine. Bacteria, fungi, parasites and viruses that exhibit resistance to antimicrobials threaten the efficacy of therapeutics and impose significant global healthcare and economic burdens. 

Guest-edited by Prof. Willem van Schaik and Dr. Robert Moran, this Antimicrobial Resistance special collection aims to highlight research on the emergence, accumulation and spread of antimicrobial resistance, with a particular focus on opportunistic pathogens and the mobile genetic elements therein.

Marine Microbiology

Covering over 70% of the Earth’s surface, the Oceans represent an incredibly diverse, yet understudied ecosystem. In particular, micro-organisms (bacteria, fungi, viruses and archaea) mediate key ecosystem processes in these marine systems and account for a majority of the biodiversity.

Guest-edited by Dr. Katherine Duncan and Dr. Alex Chase, this Marine Microbiology special collection aims to highlight key research on marine microorganisms as they underpin the complex processes of our blue planet. 

Metals in Microbiology

Metals catalyse almost a half of all microbial reactions and yet can poison microorganisms. Metal handling systems - that maintain metal homeostasis - are thus vital to sustain microbial life. For microbial pathogens, the challenge of metal homeostasis is exacerbated by host immune defences that restrict metal access and that exploit the microbicidal activity of metals. 

Guest-edited by Dr Jennifer Cavet (University of Manchester) and Dr Karrera Djoko (Durham University), this collection of keynote research articles will highlight research on metal-microbe interactions, bringing together advances in our understanding of how microbes handle metals, the utilization of metals in proteins and the importance of metal handling systems in host-pathogen interactions.


Mycobacteria are a vast group of microorganisms characterized by a unique thick, hydrophobic cell wall rich in mycolic acids, which makes them highly resistant to environmental stresses. 

Guest-edited by Dr. Riccardo Manganelli, this collection of keynote research articles will highlight all aspects of mycobacterial biology, with particular focus on physiological aspects, such as stress response mechanisms, regulatory networks, and metabolic pathways, that might lead to a better understanding of the intriguing aspects of mycobacterial host-pathogen interaction and lead to the design of new strategies to fight these important pathogens.