TY - JOUR
T1 - Evolution and ecology of anti-defence systems in phages and plasmids
AU - Niault, Theophile
AU - van Houte, Stineke
AU - Westra, Edze
AU - Swarts, Daan C.
PY - 2025/1/6
Y1 - 2025/1/6
N2 - Prokaryotes (Bacteria and Archaea) encode a highly diversified arsenal of defence systems that protect them against mobile genetic elements, such as phages and plasmids. In turn, mobile genetic elements encode anti-defence systems that allow them to escape the activity of these defence systems. This has resulted in an evolutionary arms race in which defence systems and anti-defence systems evolve and adapt continuously, driving intriguing innovation and enormous diversification on both sides. Over 150 prokaryotic defence systems have been identified to date. Anti-defence systems are known for only a subset of these, but more are being discovered at a steady rate. Despite an increasing understanding of the highly diverse molecular mechanisms of anti-defence systems, their diverse evolutionary origins, the selective pressures they are subjected to, and their ecological importance and implications often remain obscure. In this review, we describe the diverse strategies that phage and plasmid anti-defence systems employ to escape host defence systems. We explore the evolutionary origins of anti-defence systems and describe different factors that exert selective pressure, affecting their maintenance and diversification. We describe how, in turn, defence systems themselves evolved to act upon anti-defence mechanisms, thereby adding a new layer to the co-evolutionary battle between prokaryotes and their mobile genetic elements. We discuss how the continuous selective pressures found in dynamic microbial communities promote the retention and diversification of these anti-defence systems. Finally, we consider the ecological implications for both hosts and their mobile genetic elements, noting how the balance of defence and anti-defence strategies can shape microbial community composition, influence horizontal gene transfer, and impact ecosystem stability.
AB - Prokaryotes (Bacteria and Archaea) encode a highly diversified arsenal of defence systems that protect them against mobile genetic elements, such as phages and plasmids. In turn, mobile genetic elements encode anti-defence systems that allow them to escape the activity of these defence systems. This has resulted in an evolutionary arms race in which defence systems and anti-defence systems evolve and adapt continuously, driving intriguing innovation and enormous diversification on both sides. Over 150 prokaryotic defence systems have been identified to date. Anti-defence systems are known for only a subset of these, but more are being discovered at a steady rate. Despite an increasing understanding of the highly diverse molecular mechanisms of anti-defence systems, their diverse evolutionary origins, the selective pressures they are subjected to, and their ecological importance and implications often remain obscure. In this review, we describe the diverse strategies that phage and plasmid anti-defence systems employ to escape host defence systems. We explore the evolutionary origins of anti-defence systems and describe different factors that exert selective pressure, affecting their maintenance and diversification. We describe how, in turn, defence systems themselves evolved to act upon anti-defence mechanisms, thereby adding a new layer to the co-evolutionary battle between prokaryotes and their mobile genetic elements. We discuss how the continuous selective pressures found in dynamic microbial communities promote the retention and diversification of these anti-defence systems. Finally, we consider the ecological implications for both hosts and their mobile genetic elements, noting how the balance of defence and anti-defence strategies can shape microbial community composition, influence horizontal gene transfer, and impact ecosystem stability.
U2 - 10.1016/j.cub.2024.11.033
DO - 10.1016/j.cub.2024.11.033
M3 - Article
AN - SCOPUS:85213554582
SN - 0960-9822
VL - 35
SP - R32-R44
JO - Current Biology
JF - Current Biology
IS - 1
ER -