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1. Linear dicentric chromosomes in bacterial natural isolates reveal common constraints for replicon fusion

   https://doi.org/10.1128/mbio.01046-25  

   Sanath-Kumar, Ram; Rahman, Arafat; Ren, Zhongqing; Reynolds, Ian P; Augusta, Lauren; Fuqua, Clay; Weisberg, Alexandra J; Wang, Xindan (June 2025, mBio)

   Komeili, Arash (Ed.)

   ABSTRACT Multipartite bacterial genome organization can confer advantages, including coordinated gene regulation and faster genome replication, but is challenging to maintain.Agrobacterium tumefacienslineages often contain a circular chromosome (Ch1), a linear chromosome (Ch2), and multiple plasmids. We previously observed that in some stocks of the C58 lab model, Ch1 and Ch2 were fused into a linear dicentric chromosome. Here we analyzedAgrobacteriumnatural isolates from the French Collection for Plant-Associated Bacteria and identified two strains distinct from C58 with fused chromosomes. Chromosome conformation capture identified integration junctions that were different from the C58 fusion strain. Genome-wide DNA replication profiling showed that both replication origins remained active. Transposon sequencing revealed that partitioning systems of both chromosome centromeres were essential. Importantly, the site-specific recombinase XerCD is required for the survival of the strains containing the fusion chromosome. Our findings show that replicon fusion occurs in natural environments and that balanced replication arm sizes and proper resolution systems enable the survival of such strains. IMPORTANCEMost bacterial genomes are monopartite with a single, circular chromosome. However, some species, likeAgrobacterium tumefaciens, carry multiple chromosomes. Emergence of multipartite genomes is often related to adaptation to specific niches, including pathogenesis or symbiosis. Multipartite genomes confer certain advantages; however, maintaining this complex structure can present significant challenges. We previously reported a laboratory-propagated lineage ofA. tumefaciensstrain C58 in which the circular and linear chromosomes fused to form a single dicentric chromosome. Here we discovered two geographically separated environmental isolates ofA. tumefacienscontaining fused chromosomes with integration junctions different from the C58 fusion chromosome, revealing the constraints and diversification of this process. We found that balanced replication arm sizes and the repurposing of multimer resolution systems enable the survival and stable maintenance of dicentric chromosomes. These findings reveal how multipartite genomes function across different bacterial species and the role of genomic plasticity in bacterial genetic diversification. 

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2. The role of active mRNA-ribosome dynamics and closing constriction in daughter chromosome separation in Escherichia coli

   https://doi.org/10.1101/2025.04.05.647368  

   Amarasinghe, Chathuddasie I; Chang, Mu-Hung; Männik, Jaana; Retterer, Scott T; Lavrentovich, Maxim O; Männik, Jaan (April 2025, bioRxiv)

   Abstract The mechanisms by which two sister chromosomes separate and partition into daughter cells in bacteria remain poorly understood. A recent theoretical model has proposed that out-of-equilibrium processes associated with mRNA–ribosome (polysome) dynamics play a significant role in this process. Here we investigate the role of ribosomal dynamics on nucleoid segregation and separation inEscherichia coliusing high-throughput fluorescence microscopy in microfluidic devices. We compare our experimental observations with predictions from a reaction-diffusion model that includes the interactions among ribosomal subunits, polysomes, and chromosomal DNA. Our results show that the non-equilibrium behavior of mRNA and ribosomes causes them to aggregate at the midcell and this process contributes to the separation of the two daughter chromosomes. However, this effect is considerably weaker than that predicted by the model. Rather than relying solely on active mRNA–ribosome dynamics, our data suggest that the closing division septum via steric interactions and potentially entropic forces between two DNA strands coupled to cell elongation act as additional mechanisms to ensure faithful partitioning of the nucleoids to two daughter cells. SignificanceThe mitotic spindle separates chromosomes in eukaryotic cells, but bacteria lack this structure. It remains unclear how bacterial chromosomes partition prior to cell division. It has been hypothesized that non-equilibrium dynamics of polysomes, that is mRNA–ribosome complexes, actively drive the separation of bacterial chromosomes. Using quantitative microscopy combined with computational modeling, we show that polysome dynamics significantly contribute to chromosome segregation inEscherichia colibut this process does not constitute the sole mechanism. Our findings suggest the closing division septum via steric interactions and potentially entropic forces between two DNA strands act as additional mechanisms. 

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3. XY sex determination in a cnidarian

   https://doi.org/10.1186/s12915-023-01532-2  

   Chen, Ruoxu; Sanders, Steven M.; Ma, Zhiwei; Paschall, Justin; Chang, E. Sally; Riscoe, Brooke M.; Schnitzler, Christine E.; Baxevanis, Andreas D.; Nicotra, Matthew L. (February 2023, BMC Biology)

   Abstract BackgroundSex determination occurs across animal species, but most of our knowledge about its mechanisms comes from only a handful of bilaterian taxa. This limits our ability to infer the evolutionary history of sex determination within animals. ResultsIn this study, we generated a linkage map of the genome of the colonial cnidarianHydractinia symbiolongicarpusand used it to demonstrate that this species has an XX/XY sex determination system. We demonstrate that the X and Y chromosomes have pseudoautosomal and non-recombining regions. We then use the linkage map and a method based on the depth of sequencing coverage to identify genes encoded in the non-recombining region and show that many of them have male gonad-specific expression. In addition, we demonstrate that recombination rates are enhanced in the female genome and that the haploid chromosome number inHydractiniaisn = 15. ConclusionsThese findings establishHydractiniaas a tractable non-bilaterian model system for the study of sex determination and the evolution of sex chromosomes. 

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4. Chromosome‐specific painting unveils chromosomal fusions and distinct allopolyploid species in the Saccharum complex

   https://doi.org/10.1111/nph.17905  

   Yu, Fan; Zhao, Xinwang; Chai, Jin; Ding, Xueer; Li, Xueting; Huang, Yongji; Wang, Xianhong; Wu, Jiayun; Zhang, Muqing; Yang, Qinghui; et al (December 2021, New Phytologist)

   Summary Karyotypes provide key cytogenetic information on the phylogenetic relationships and evolutionary origins in related eukaryotic species. Despite our knowledge of the chromosome numbers of sugarcane and its wild relatives, the chromosome composition and evolution among the species in theSaccharumcomplex have been elusive owing to the complex polyploidy and the large numbers of chromosomes of these species.Oligonucleotide‐based chromosome painting has become a powerful tool of cytogenetic studies especially for plant species with large numbers of chromosomes. We developed oligo‐based chromosome painting probes for all 10 chromosomes inSaccharum officinarum(2n = 8x = 80). The 10 painting probes generated robust fluorescencein situhybridization signals in all plant species within theSaccharumcomplex, including species in the generaSaccharum,Miscanthus,NarengaandErianthus.We conducted comparative chromosome analysis using the same set of probes among species from four different genera within theSaccharumcomplex. Excitingly, we discovered several novel cytotypes and chromosome rearrangements in these species.We discovered that fusion from two different chromosomes is a common type of chromosome rearrangement associated with the species in theSaccharumcomplex. Such fusion events changed the basic chromosome number and resulted in distinct allopolyploids in theSaccharumcomplex. 

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5. One-step genome engineering in bee gut bacterial symbionts

   https://doi.org/10.1128/mbio.01392-24  

   Lariviere, Patrick J; Ashraf, A_H_M Zuberi; Navarro-Escalante, Lucio; Leonard, Sean P; Miller, Laurel G; Moran, Nancy A; Barrick, Jeffrey E (September 2024, mBio)

   Kaltenpoth, Martin (Ed.)

   ABSTRACT Mechanistic understanding of interactions in many host-microbe systems, including the honey bee microbiome, is limited by a lack of easy-to-use genome engineering approaches. To this end, we demonstrate a one-step genome engineering approach for making gene deletions and insertions in the chromosomes of honey bee gut bacterial symbionts. Electroporation of linear or non-replicating plasmid DNA containing an antibiotic resistance cassette flanked by regions with homology to a symbiont genome reliably results in chromosomal integration. This lightweight approach does not require expressing any exogenous recombination machinery. The high concentrations of large DNAs with long homology regions needed to make the process efficient can be readily produced using modern DNA synthesis and assembly methods. We use this approach to knock out genes, including genes involved in biofilm formation, and insert fluorescent protein genes into the chromosome of the betaproteobacterial bee gut symbiontSnodgrassella alvi. We are also able to engineer the genomes of multiple strains ofS. alviand another species,Snodgrassella communis, which is found in the bumble bee gut microbiome. Finally, we use the same method to engineer the chromosome of another bee symbiont,Bartonella apis, which is an alphaproteobacterium. As expected, gene knockout inS. alviusing this approach isrecA-dependent, suggesting that this straightforward procedure can be applied to other microbes that lack convenient genome engineering methods. IMPORTANCEHoney bees are ecologically and economically important crop pollinators with bacterial gut symbionts that influence their health. Microbiome-based strategies for studying or improving bee health have utilized wild-type or plasmid-engineered bacteria. We demonstrate that a straightforward, single-step method can be used to insert cassettes and replace genes in the chromosomes of multiple bee gut bacteria. This method can be used for investigating the mechanisms of host-microbe interactions in the bee gut community and stably engineering symbionts that benefit pollinator health. 

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