Project description:Borrelia burgdorferi, a causative agent of Lyme disease, contains the most segmented bacterial genome known to date, with one linear chromosome and over twenty plasmids. How this unusually complex genome is organized, and whether and how the different replicons interact are unclear. We recently demonstrated that B. burgdorferi is polyploid and the copies of the chromosome and plasmids are regularly spaced in each cell, which is critical for faithful segregation of the genome to daughter cells. Regular spacing of the chromosome is regulated by two separate partitioning systems (parBS and parAZ) and the structural maintenance of chromosomes (SMC) protein. Here, using chromosome conformation capture (Hi-C), we characterized the conformation of the B. burgdorferi genome and the interactions between the replicons. We uncovered that although the linear chromosome lacks contacts between the two replication arms, the two telomeres are in frequent contact. Moreover, several plasmids specifically interact with the chromosome oriC region, and a subset of plasmids interact with each other more than with others. We found that SMC and the SMC-like MksB protein mediate long-range interactions on the chromosome, but they minimally affect plasmid-chromosome or plasmid-plasmid interactions. Finally, we found that disruption of the two partition systems leads to chromosome restructuring, correlating with the mis-positioning of chromosome oriC. Altogether, this study revealed the conformation of a complex genome and analyzed the contribution of the partition systems and SMC family proteins to this organization. This work expands the understanding of the organization and maintenance of multipartite bacterial genomes.

Project description:In the majority of bacterial species, the tripartite ParAB-parS system, composed of an ATPase (ParA), a DNA-binding protein (ParB), and its target parS sequence(s), assists in the chromosome partitioning. ParB forms large nucleoprotein complexes at parS(s), located in the vicinity of oriC, which after replication are subsequently relocated by ParA to polar positions. It was shown that ParB-parS complexes are loading platforms for structural maintenance of chromosome (Smc) proteins, which juxtapose the two arms of the circular chromosome. In this work, we characterized the Pseudomonas aeruginosa ParB interactions with DNA in the absence of Smc and interaction with the cognate ParA using chromatin immunoprecipitation-sequencing (ChIPseq). We show that in strains lacking Smc or strains with disturbed ParB-ParA interactions (ParA L84K or ParB G11A mutations) ParB is able to bind and spread around parS1-4 cluster and still binds to half-parS sites. Comparison of the ratio between the number of ChIP-seq reads mapping to region around parS1-4 with those mapping to ChIPseq peaks containing half-parSs indicate no major effect of the twod factors on the extent of ParB spreading, thus suggesting that the mechanisms controlling ParB association with the DNA do not involve interaction with cognate ParA partner and Smc.

Project description:SMC complexes, loaded at ParB-parS sites, are key mediators of chromosome organization in bacteria. ParA/Soj proteins interact with ParB/Spo0J in a pathway involving ATP-dependent dimerization and DNA binding, leading to chromosome segregation and SMC loading. In Bacillus subtilis, ParA/Soj also regulates DNA replication initiation, and along with ParB/Spo0J is involved in cell cycle changes during endospore formation. The first morphological stage in sporulation is the formation of an elongated chromosome structure called an axial filament. We now show that a major redistribution of SMC complexes drives axial filament formation, in a process regulated by ParA/Soj. Unexpectedly, this regulation is dependent on monomeric forms of ParA/Soj that cannot bind DNA or hydrolyse ATP. These results reveal a new role for ParA/Soj proteins in the regulation of SMC dynamics in bacteria, and yet further complexity in the web of interactions involving chromosome replication, segregation, and organization, controlled by ParAB and SMC.

Project description:Hi-C analysis of the chromosome organization during sporulation in Streptomyces venezuelae. The experiment includes the effect of ParA, ParB, SMC, and HupS proteins on the chromosome structure.

Project description:We studied the binding of SMC protein to Streptomyces venezuelae chromosome during development of aerial hyphae (14 hour of growth) using SMC-FLAG protein. Additionally investigated the role of ParB protein in SMC DNA binding using parB deletion strain.

Project description:Chromosome segregation in Pseudomonas aeruginosa is assisted by the tripartite ParAB-parS system, composed of an ATPase (ParA), a DNA-binding protein (ParB), and its target parS sequence(s). ParB forms a nucleoprotein complex around four parSs (parS1-parS4), which is positioned within the cell by ParA. Remarkably, ParB of P. aeruginosa binds to multiple heptanucleotides (half-parSs) scattered in the genome. In this work we analysed the transcriptome of P. aeruginosa with mutated 25 half-parSs forming the strongest ParB ChIP-seq peaks. Inactivation of ParB binding to even a small fraction of these sites modulated the gene expression, however this effect is most likely indirect. Overall this work suggests complex relation between ParB binding to genome and P. aeruginosa transcriptome.

Project description:Borrelia burgdorferi, the causative agent of Lyme disease, is transmitted to vertebrate hosts by Ixodes ticks. As it moves from tick to host, B. burgdorferi must adapt to survive in a vastly different environment. During the tick bloodmeal, which lasts several days, B. burgdorferi is primed for mammalian infection, growing increasingly virulent as it senses cues from its surroundings in the tick. This conditioning is dependent on key transcriptional regulators; however, the downstream transcriptional changes occurring inside of the tick that promote B. burgdorferi transmission and infection are poorly understood due to technical difficulties in sequencing the B. burgdorferi transcriptome from inside of ticks. We developed a protocol to enrich and sequence B. burgdorferi from inside the tick, and we measured global transcriptional changes occurring in feeding ticks. We identified 192 genes that change expression twofold over the course of the tick bloodmeal, which were predominantly located on the plasmids of the genome. The majority of the upregulated genes encode proteins found at the cell envelope or proteins of unknown function, including 45 upregulated genes encoding outer surface lipoproteins. These genes that increase during feeding are candidates for future functional studies, which can help identify new targets for methods that aim to control the spread of Lyme disease.

Project description:Borrelia burgdorferi, the causative agent of Lyme disease, is transmitted to vertebrate hosts by Ixodes ticks. As it moves from tick to host, B. burgdorferi must adapt to survive in a vastly different environment. During the tick bloodmeal, which lasts several days, B. burgdorferi is primed for mammalian infection, growing increasingly virulent as it senses cues from its surroundings in the tick. This conditioning is dependent on key transcriptional regulators; however, the downstream transcriptional changes occurring inside of the tick that promote B. burgdorferi transmission and infection are poorly understood due to technical difficulties in sequencing the B. burgdorferi transcriptome from inside of ticks. We developed a protocol to enrich and sequence B. burgdorferi from inside the tick, and we measured global transcriptional changes occurring in feeding ticks. We identified 192 genes that change expression twofold over the course of the tick bloodmeal, which were predominantly located on the plasmids of the genome. The majority of the upregulated genes encode proteins found at the cell envelope or proteins of unknown function, including 45 upregulated genes encoding outer surface lipoproteins. These genes that increase during feeding are candidates for future functional studies, which can help identify new targets for methods that aim to control the spread of Lyme disease.

Project description:Chromosomes readily unlink from one another and segregate to daughter cells during cell division highlighting a remarkable ability of cells to organize long DNA molecules. SMC complexes mediate chromosome folding by DNA loop extrusion. In most bacteria, SMC complexes start loop extrusion at the ParB/parS partition complex formed near the replication origin. Whether they are recruited by recognizing a specific DNA structure in the partition complex or a protein component is unknown. By replacing genes in Bacillus subtilis with orthologous sequences from Streptococcus pneumoniae, we show that the three subunits of the bacterial Smc complex together with the ParB protein form a functional module that can organize and segregate chromosomes when transplanted into another organism. Using chimeric proteins and chemical cross-linking, we find that ParB binds to the Smc subunit directly. We map a binding interface to the Smc joint and the ParB CTP-binding domain. Structure prediction indicates how the ParB clamp presents DNA to the Smc complex to initiate DNA loop extrusion.

Project description:Chromosomes readily unlink from one another and segregate to daughter cells during cell division highlighting a remarkable ability of cells to organize long DNA molecules. SMC complexes mediate chromosome folding by DNA loop extrusion. In most bacteria, SMC complexes start loop extrusion at the ParB/parS partition complex formed near the replication origin. Whether they are recruited by recognizing a specific DNA structure in the partition complex or a protein component is unknown. By replacing genes in Bacillus subtilis with orthologous sequences from Streptococcus pneumoniae, we show that the three subunits of the bacterial Smc complex together with the ParB protein form a functional module that can organize and segregate chromosomes when transplanted into another organism. Using chimeric proteins and chemical cross-linking, we find that ParB binds to the Smc subunit directly. We map a binding interface to the Smc joint and the ParB CTP-binding domain. Structure prediction indicates how the ParB clamp presents DNA to the Smc complex to initiate DNA loop extrusion.