Dynamic interplay of ParA with the polarity protein, Scy, coordinates the growth with chromosome segregation in Streptomyces coelicolor (original) (raw)
Related papers
Alignment of multiple chromosomes along helical ParA scaffolding in sporulating Streptomyces hyphae
Molecular Microbiology, 2007
The dynamic, mitosis-like segregation of bacterial chromosomes and plasmids often involves proteins of the ParA (ATPase) and ParB (DNA-binding protein) families. The conversion of multigenomic aerial hyphae of the mycelial organism Streptomyces coelicolor into chains of unigenomic spores requires the synchronous segregation of multiple chromosomes, providing an unusual context for chromosome segregation. Correct spatial organization of the oriC-proximal region prior to septum formation is achieved by the assembly of ParB into segregation complexes (Jakimowicz et al., 2005; J Bacteriol 187: 3572-3580). Here, we focus on the contribution of ParA to sporulation-associated chromosome segregation. Elimination of ParA strongly affects not only chromosome segregation but also septation. In wild type hyphae about to undergo sporulation, immunostained ParA was observed as a stretched double-helical filament, which accompanies the formation of ParB foci. We show that ParA mediates efficient assembly of ParB complexes in vivo and in vitro, and that ATP binding is crucial for ParA dimerization and interaction with ParB but not for ParA localization in vivo. We suggest that S. coelicolor ParA provides scaffolding for proper distribution of ParB complexes and consequently controls synchronized segregation of several dozens of chromosomes, possibly mediating a segregation and septation checkpoint.
Molecular microbiology, 2010
Bacterial chromosome segregation usually involves cytoskeletal ParA proteins, ATPases which can form dynamic filaments. In aerial hyphae of the mycelial bacterium Streptomyces coelicolor, ParA filaments extend over tens of microns and are responsible for segregation of dozens of chromosomes. We have identified a novel interaction partner of S. coelicolor ParA, ParJ. ParJ negatively regulates ParA polymerization in vitro and is important for efficient chromosome segregation in sporulating aerial hyphae. ParJ-EGFP formed foci along aerial hyphae even in the absence of ParA. ParJ, which is encoded by sco1662, turned out to be one of the five actinobacterial signature proteins, and another of the five is a ParJ paralogue. We hypothesize that polar growth, which is characteristic not only of streptomycetes, but even of simple Actinobacteria, may be interlinked with ParA polymer assembly and its specific regulation by ParJ.
Developmental-Stage-Specific Assembly of ParB Complexes in Streptomyces coelicolor Hyphae
Journal of Bacteriology, 2005
In Streptomyces coelicolor ParB is required for accurate chromosome partitioning during sporulation. Using a functional ParB-enhanced green fluorescent protein fusion, we observed bright tip-associated foci and other weaker, irregular foci in S. coelicolor vegetative hyphae. In contrast, in aerial hyphae regularly spaced bright foci accompanied sporulation-associated chromosome condensation and septation.
Journal of Bacteriology, 2006
The Streptomyces coelicolor partitioning protein ParB binds to numerous parS sites in the oriC-proximal part of the linear chromosome. ParB binding results in the formation of large complexes, which behave differentially during the complex life cycle (D. Jakimowicz, B. Gust, J. Zakrzewska-Czerwinska, and K. F. Chater, J. Bacteriol. 187:3572-3580, 2005). Here we have analyzed the transcriptional regulation that underpins this developmentally specific behavior. Analysis of promoter mutations showed that the irregularly spaced complexes present in vegetative hyphae are dependent on the constitutive parABp 1 promoter, while sporulationspecific induction of the promoter parABp 2 is required for the assembly of arrays of ParB complexes in aerial hyphae and thus is necessary for efficient chromosome segregation. Expression from parABp 2 depended absolutely on two sporulation regulatory genes, whiA and whiB, and partially on two others, whiH and whiI, all four of which are needed for sporulation septation. Because of this pattern of dependence, we investigated the transcription of these four whi genes in whiA and whiB mutants, revealing significant regulatory interplay between whiA and whiB. A strain in which sporulation septation (but not vegetative septation) was blocked by mutation of a sporulation-specific promoter of ftsZ showed close to wild-type induction of parABp 2 and formed fairly regular ParB-enhanced green fluorescent protein foci in aerial hyphae, ruling out strong morphological coupling or checkpoint regulation between septation and DNA partitioning during sporulation. A model for developmental regulation of parABp 2 expression is presented.
Open biology, 2016
Bacterial cell division is a highly complex process that requires tight coordination between septum formation and chromosome replication and segregation. In bacteria that divide by binary fission a single septum is formed at mid-cell, a process that is coordinated by the conserved cell division scaffold protein FtsZ. In contrast, during sporulation-specific cell division in streptomycetes, up to a hundred rings of FtsZ (Z rings) are produced almost simultaneously, dividing the multinucleoid aerial hyphae into long chains of unigenomic spores. This involves the active recruitment of FtsZ by the SsgB protein, and at the same time requires sophisticated systems to regulate chromosome dynamics. Here, we show that SepG is required for the onset of sporulation and acts by ensuring that SsgB is localized to future septum sites. Förster resonance energy transfer imaging suggests direct interaction between SepG and SsgB. The beta-lactamase reporter system showed that SepG is a transmembrane ...
bioRxiv (Cold Spring Harbor Laboratory), 2017
Cell division during the reproductive phase of the Streptomyces life-cycle requires tight coordination between synchronous formation of multiple septa and DNA segregation. One remarkable difference with most other bacterial systems is that cell division in Streptomyces is positively controlled by the recruitment of FtsZ by SsgB. Here we show that deletion of ylmD (SCO2081) or ylmE (SCO2080), which lie in operon with ftsZ in the dcw cluster of actinomycetes, has major consequences for sporulationspecific cell division in Streptomyces coelicolor. Electron and fluorescence microscopy demonstrated that ylmE mutants have a highly aberrant phenotype with defective septum synthesis, and produce very few spores with low viability and high heat sensitivity. FtsZ-ring formation was also highly disturbed in ylmE mutants. Deletion of ylmD had a far less severe effect on sporulation. Interestingly, the additional deletion of ylmD restored sporulation to the ylmE null mutant. YlmD and YlmE are not part of the divisome, but instead localize diffusely in aerial hyphae, with differential intensity throughout the sporogenic part of the hyphae. Taken together, our work reveals a function for YlmD and YlmE in the control of sporulation-specific cell division in S. coelicolor, whereby the presence of YlmD alone results in major developmental defects. In unicellular bacteria, cell division divides a mother cell in two identical daughter cells, each containing a single copy of the chromosome. The control of cell division thereby revolves around finding the mid-cell position, and chromosome segregation and septum synthesis are closely coordinated in time and space to avoid DNA damage by the nascent septum. The cell division scaffold is formed by FtsZ, which is a homologue of tubulin 1 and forms a contractile ring (or Z-ring) that mediates the recruitment of the cell division machinery to the division site (reviewed in 2,3). Septum-site selection and Z-ring stabilization are mediated by proteins like FtsA and ZipA 4-6 , ZapA 7 and SepF 8,9. Z-ring (dis-)assembly is thereby actively controlled (reviewed in 10). Streptomycetes are filamentous Gram-positive bacteria that belong to the phylum of Actinobacteria. These bacteria produce over 60% of all known antibiotics and many other bioactive natural products 11,12. Exponential growth of the vegetative hyphae is achieved by apical growth and branching. At this stage of the life cycle, cell division does not affect physical separation of the cells, but instead long syncytial cells are formed that are separated by cross-walls 13. Hence, streptomycetes are model organisms for the study of multicellularity and bacterial morphogenesis 14,15. Most divisome components except FtsZ are not required for vegetative division, presumably reflecting the lack of constriction 16. Spacing between the cross-walls is highly variable, and little is known of the way septum-site selection is controlled. Recently, using cryo-electron tomography, our lab and others showed that intracellular membrane assemblies or cross-membranes are involved in DNA protection during septum synthesis in young vegetative hyphae, suggesting a novel way of cell-division control 17,18. In addition, these multicellular bacteria have a complex cytoskeleton, which among others plays a role in the organization of the tip growth machinery 19,20. Canonical division resulting in cell fission occurs during sporulation-specific cell division, which requires all components of the divisome 16,21. At this stage of the life cycle up to a hundred septa are formed in a short time
Spatial rearrangement of the Streptomyces venezuelae linear chromosome during sporogenic development
Nature Communications, 2021
Bacteria of the genus Streptomyces have a linear chromosome, with a core region and two ‘arms’. During their complex life cycle, these bacteria develop multi-genomic hyphae that differentiate into chains of exospores that carry a single copy of the genome. Sporulation-associated cell division requires chromosome segregation and compaction. Here, we show that the arms of Streptomyces venezuelae chromosomes are spatially separated at entry to sporulation, but during sporogenic cell division they are closely aligned with the core region. Arm proximity is imposed by segregation protein ParB and condensin SMC. Moreover, the chromosomal terminal regions are organized into distinct domains by the Streptomyces-specific HU-family protein HupS. Thus, as seen in eukaryotes, there is substantial chromosomal remodelling during the Streptomyces life cycle, with the chromosome undergoing rearrangements from an ‘open’ to a ‘closed’ conformation.
Nucleic Acids Research, 2013
The linear chromosome of Streptomyces coelicolor contains two paralogous ssb genes, ssbA and ssbB. Following mutational analysis, we concluded that ssbA is essential, whereas ssbB plays a key role in chromosome segregation during sporulation. In the ssbB mutant, $30% of spores lacked DNA. The two ssb genes were expressed differently; in minimal medium, gene expression was prolonged for both genes and significantly upregulated for ssbB. The ssbA gene is transcribed as part of a polycistronic mRNA from two initiation sites, 163 bp and 75 bp upstream of the rpsF translational start codon. The ssbB gene is transcribed as a monocistronic mRNA, from an unusual promoter region, 73 bp upstream of the AUG codon. Distinctive DNA-binding affinities of single-stranded DNA-binding proteins monitored by tryptophan fluorescent quenching and electrophoretic mobility shift were observed. The crystal structure of SsbB at 1.7 Å resolution revealed a common OB-fold, lack of the clamp-like structure conserved in SsbA and previously unpublished S-S bridges between the A/B and C/D subunits. This is the first report of the determination of paralogous singlestranded DNA-binding protein structures from the same organism. Phylogenetic analysis revealed frequent duplication of ssb genes in Actinobacteria, whereas their strong retention suggests that they are involved in important cellular functions.
Journal of bacteriology
Streptomyces are bacteria that resemble filamentous fungi in their hyphal mode of growth and sporulation. In S. coelicolor, the conversion of multigenomic aerial hyphae into chains of unigenomic spores requires synchronized septation accompanied by segregation of tens of chromosomes into prespore compartments. The chromosome segregation is dependent on ParB protein, which assembles into an array of nucleoprotein complexes in the aerial hyphae. Here, we report that nucleoprotein ParB complexes are bound in vitro and in vivo by topoisomerase I - TopA, which is the only topoisomerase I homolog found in S. coelicolor. TopA cannot be eliminated, and its depletion inhibits growth and blocks sporulation. Surprisingly, sporulation in the TopA-depleted strain could be partially restored by deletion of parB. Furthermore, the formation of regularly spaced ParB complexes, which is a prerequisite for proper chromosome segregation and septation during the development of aerial hyphae, has been fo...
2019
The accurate onset of chromosome replication and segregation are fundamental for the survival of the cell. In bacteria, regulation of chromosome replication lies primarily at the initiation step. The bacterial replication initiator DnaA recognizes the origin of replication (ori) and opens this double stranded site allowing for the assembly of the DNA replication machinery. Following the onset of replication initiation, the partitioning protein ParA triggers the onset of chromosome segregation by direct interactions with ParB-bound to the centromere. The subcellular organization of ori and centromere are maintained after the completion of each cell cycle. It remains unclear what triggers the onset of these key chromosome regulators DnaA and ParA. One potential scenario is that the microenvironment of where the onset of replication and segregation take place hosts the regulators that trigger the activity of DnaA and ParA. In order to address this, we analyzed whether the activity of DnaA and ParA are restricted to only one site within the cell. In non-dividing cells of the alpha proteobacterium Caulobacter crescentus, ori and centromere are found near the stalked pole. To test DnaA's ability to initiate replication away from the stalked pole, we engineered a strain where movement of ori was induced in the absence of chromosome replication. Our data show that DnaA can initiate replication of the chromosome independently of the subcellular localization of ori. Furthermore, we discovered that the partitioning protein ParA was functional and could segregate the replicated centromere in the opposite direction from the new pole toward the stalked pole. We showed that the organization of the ParA gradient can be completely reconstructed in the opposite orientation by rearranging the location of the centromere. Our data reveal the high flexibility of the machineries that trigger the onset of chromosome replication and segregation in bacteria. Our work also provides insights into the coordination between replication and segregation with the cellular organization of specific chromosomal loci. .