🚨 New preprint from the lab! 🚨
We show that multireplicon plasmids are true AMR "jack-of-all-trades":
Widespread, highly mobile, broad host-range, and packed with resistance genes.
Far from random, they form co-evolving associations driven & 𝘮𝘢𝘪𝘯𝘵𝘢𝘪𝘯𝘦𝘥 by IS elements.
See Nacho's thread below!👇👇
What if multireplicon plasmids are not an oddity, but an evolutionary strategy?
We found that they are common, more mobile, broader-host-range, and enriched in AMR.
Even more interesting: their assembly doesn’t look random. 👀
Paper preprint: www.biorxiv.org/content/10.6...
Thread below!🧵👇
New paper out! 🔈🔈📣📣
Plasmids promote antimicrobial resistance through Insertion Sequence-mediated gene inactivation.
Combining experimental and computational approaches, we unveil how two of the most prevalent bacterial MGE accelerate the evolution of AMR. 🧵👇🏻
www.biorxiv.org/content/10.1...
New paper alert! 🚨
Plasmids promote bacterial evolution through a copy number-driven increase in mutation rate.
We combine theory, simulations, experimental evolution, and bioinformatics to demonstrate that mutation rates scale with plasmid copy number.
Let's dive in! 🧵👇
2/5.
These plasmids also seem better at disseminating ✈️. They were more often conjugative and showed broader host ranges, with some replicons appearing in new bacterial hosts when they were part of multireplicon plasmids.
Big shoutout to my coauthors and everyone involved in this work! Thank you!🥳
@jerorb.bsky.social @paularamiro.bsky.social @crisherencias.bsky.social
3/5. Plasmid fusion is not random chaos. Some replicon pairs repeatedly end up on the same plasmid, while others often coexist in the same cell but remain separate. Meeting is not the same as merging. 🫂
1/5. Multireplicon plasmids are everywhere. Across ~24,000 closed plasmids, >30% carried two or more replicons. These plasmids were larger and enriched in AMR, metal/biocide resistance and virulence genes. 🦠
4/5.
Some pairs of replicons look like long-term partners. They keep similar positions within the plasmid, and pairs with more conserved spacing show stronger phylogenetic concordance. They've been evolving together! 💍
5/5.
The molecular scars are still visible. Fusion breakpoints show signatures of homologous recombination and insertion sequences, especially IS6-family elements. Many duplicated ISs are inverted, which may help lock fused plasmids in place! ⛓️
www.biorxiv.org
Antimicrobial Resistance (AMR) is a major threat to public health. Plasmids are mobile genetic elements that can rapidly spread across bacterial populations, promoting the dissemination of AMR genes i...
Plasmids are DNA molecules that replicate independently of the bacterial chromosome and are typically associated with the spread of antimicrobial resistance (AMR) and virulence determinants, among other relevant traits. Fusion events between plasmids generate larger, complex backbones that carry two or more replication systems, known as multireplicon plasmids. Despite decades of study, we are still far from understanding how multireplicon plasmids arise, persist, and shape the evolution of AMR. Here, we analyzed 24,000 non-redundant plasmids across bacterial genera and found that more than 30% of them encoded multiple replicons. Compared to single-replicon plasmids, multireplicon plasmids were larger, were enriched in genes encoding antimicrobial, metal, and biocide resistance as well as virulence factors, and showed higher mobility and a broader host range. We also found that multireplicon assembly is not random. Some replicon pairs repeatedly merge into stable multireplicon plasmids, while other pairs rarely fuse even when they commonly coexist intracellularly. We also show that replicon pairs tend to be localized either in close proximity to one another or on opposite poles of the plasmid. We further highlight that multireplicon plasmids can be broadly classified into two groups: long-term coevolving replicon pairs and transient associations that lack a shared evolutionary history. Finally, we reveal the molecular mechanisms underlying multireplicon formation and highlight the role of insertion sequences in their formation and maintenance. Together, our work sheds light on the abundance, gene content, evolutionary patterns, and formation dynamics of multireplicon plasmids and pinpoints their relevance to bacterial evolution and human health. ### Competing Interest Statement The authors have declared no competing interest. Instituto de Salud Carlos III, https://ror.org/00ca2c886, PI23/01945, PFIS - FI22/00265, Miguel Servet - CP22/00164 European Research Council, https://ror.org/0472cxd90, HorizonGT, 101077809 Fundación Ramón Areces, "Ayudas Fundación Ramón Areces para la realización de Tesis Doctorales en Ciencias de la Vida y de la Materia 2025" Coordenação de Aperfeicoamento de Pessoal de Nível Superior, https://ror.org/00x0ma614, 88881.128025/2025-01
What if multireplicon plasmids are not an oddity, but an evolutionary strategy?
We found that they are common, more mobile, broader-host-range, and enriched in AMR.
Even more interesting: their assembly doesn’t look random. 👀
Paper preprint: www.biorxiv.org/content/10.6...
Thread below!🧵👇
