The studies of ParA and ParB dynamics reveal asymmetry of chromosome segregation in mycobacteria

Active segregation of bacterial chromosomes usually involves the action of ParB proteins, which bind in proximity of chromosomal origin (oriC) regions forming nucleoprotein complexes - segrosomes. Newly duplicated segrosomes are moved either uni- or bidirectionally by the action of ATPases - ParA proteins. In Mycobacterium smegmatis the oriC region is located in an off-centred position and newly replicated segrosomes are segregated towards cell poles. The elimination of M. smegmatis ParA and/or ParB leads to chromosome segregation defects. Here, we took advantage of microfluidic time-lapse fluorescent microscopy to address the question of ParA and ParB dynamics in M. smegmatis and M. tuberculosis cells. Our results reveal that ParB complexes are segregated in an asymmetrical manner. The rapid movement of segrosomes is dependent on ParA that is transiently associated with the new pole. Remarkably in M. tuberculosis, the movement of the ParB complex is much slower than in M. smegmatis, but segregation as in M. smegmatis lasts approximately 10% of the cell cycle, which suggests a correlation between segregation dynamics and the growth rate. On the basis of our results, we propose a model for the asymmetric action of segregation machinery that reflects unequal division and growth of mycobacterial cells.

Chromosome Organization and Replisome Dynamics in Mycobacterium smegmatis

John McKinney, Isabella Santi

Subcellular organization of the bacterial nucleoid and spatiotemporal dynamics of DNA replication and segregation have been studied intensively, but the functional link between these processes remains poorly understood. Here we use quantitative time-lapse fluorescence microscopy for single-cell analysis of chromosome organization and DNA replisome dynamics in Mycobacterium smegmatis. We report that DNA replication takes place near midcell, where, following assembly of the replisome on the replication origin, the left and right replication forks colocalize throughout the replication cycle. From its initial position near the cell pole, a fluorescently tagged chromosomal locus (attB, 245 degrees from the origin) moves rapidly to the replisome complex just before it is replicated. The newly duplicated attB loci then segregate to mirror-symmetric positions relative to midcell. Genetic ablation of ParB, a component of the ParABS chromosome segregation system, causes marked defects in chromosome organization, condensation, and segregation. ParB deficiency also results in mislocalization of the DNA replication machinery and SMC (structural maintenance of chromosome) protein. These observations suggest that ParB and SMC play important and overlapping roles in chromosome organization and replisome dynamics in mycobacteria. IMPORTANCE We studied the spatiotemporal organization of the chromosome and DNA replication machinery in Mycobacterium smegmatis, a fast-growing relative of the human pathogen Mycobacterium tuberculosis. We show that genetic ablation of the DNA-binding proteins ParB and SMC disturbs the organization of the chromosome and causes a severe defect in subcellular localization and movement of the DNA replication complexes. These observations suggest that ParB and SMC provide a functional link between chromosome organization and DNA replication dynamics. This work also reveals important differences in the biological roles of the ParABS and SMC systems in mycobacteria versus better-characterized model organisms, such as Escherichia coli and Bacillus subtilis.

American Society for Microbiology2015

Single-cell studies of Mycobacterium smegmatis cell cycle using time-lapse fluorescence microscopy

Joëlle Xiao Yuan Ven

Cell division is one of the most primordial cellular processes and is essential for life propagation. It is composed of crucial events, namely genome duplication, chromosomes segregation and membrane separation. Failure of these processes will have dramatic impacts on the development of any organisms, including cell death, polyploidy, or cell cycle arrest. In the case of bacterial pathogens, blocking cell division efficiently using targeted drugs is of interest to cure bacterial infections. However, despite its ancestral origin, the mechanisms of cell division have diverged amongst organisms. Given its crucial role, as well as the potential therapeutic applications, cell division is an intensive field of research and many aspects are yet to be fully understood. Amongst bacteria, the phyla Proteobacteria and Firmicutes have been intensively studied using their respective model organisms Escherichia coli and Bacillus subtilis. However, there is a paucity of research on cell division in Actinobacteria, the phylum that contains the worldâs leading pathogen, Mycobacterium tuberculosis. In particular, the molecular players involved in the process of chromosome segregation and the timing of cell division have not been fully investigated. In the well-studied bacteria E. coli and B. subtilis the Min system determines the division site localization, while the nucleoid occlusion system (Noc or SlmA, respectively) determines the timing of division. In mycobacteria, however, no homologs for the Min or Noc systems have been identified thus far. However, the partitioning (par) genes are currently thought to be responsible for symmetric chromosome segregation. In addition, FtsK has been identified as a homolog of the B. subtilis protein SpoIIIE, which is responsible for rescuing DNA in the forming septum and pulling it in the forespore during starvation-induced sporulation. Overall, the role and dynamics of DNA, where FtsK might play a role, during mycobacterial cell division, still remain to be uncovered. Current methods to study DNA localization using snapshot microscopy typically utilise DNA dyes, such as DAPI, Hoechst, or SYTO. However, these compounds impair cell growth, preventing the dynamic study of mycobacterial division. To circumvent this shortcoming, I constructed a Mycobacterium smegmatis reporter strain expressing a Dendra2 fusion protein in-frame to the histone-like protein Hlp, and compared it to conventional DNA dyes. Additionally, I characterized FtsK and, for the first time, demonstrated its essentiality in M. smegmatis. As FtsK is essential I adapted a dual repression system to knock down FtsK, which proved to be a synthetic rescue with the par genes deletion. Using a custom-made microfluidic device and long-term time-lapse microscopy, the distribution and dynamics of both Hlp and FtsK fluorescent reporter proteins were followed at the single-cell level. This approach allowed the spatial and temporal characterization of these proteins with respect to other septal genes in wild-type cells as well as in Îpar mutants. Finally, I propose a new model where the par genes are important for chromosome orientation and FtsK is important for chromosome segregation. Altogether, this thesis represents a step forward towards a better understanding of the mechanisms underlying cell division in mycobacteria and in the long-term, a potential source of novel treatments to control the division of M. tuberculosis, for instance by targeting FtsK.

EPFL2019

Role of the methylcitrate cycle in propionate metabolism and detoxification in Mycobacterium smegmatis

John McKinney

Catabolism of odd-chain-length fatty acids yields acetyl-CoA and propionyl-CoA. A common pathway of propionyl-CoA metabolism in micro-organisms is the methylcitrate cycle, which includes the dedicated enzymes methylcitrate synthase (MCS), methylcitrate dehydratase (MCD) and methylisocitrate lyase (MCL). The methylcitrate cycle is essential for propionate metabolism in Mycobacterium tuberculosis. Unusually, M. tuberculosis lacks an MCL orthologue and this activity is provided instead by two isoforms of the glyoxylate cycle enzyme isocitrate lyase (ICL1 and ICL2). These bifunctional (ICL/MCL) enzymes are jointly required for propionate metabolism and for growth and survival in mice. In contrast, the non-pathogenic species Mycobacterium smegmatis encodes a canonical MCL enzyme in addition to ICL1 and ICL2. The M. smegmatis gene encoding MCL (prpB) is clustered with genes encoding MCS (prpC) and MCD (prpD). Here we show that deletion of the M. smegmatis prpDBC locus reduced but did not eliminate MCL activity in cell-free extracts. The residual MCL activity was abolished by deletion of icl1 and icl2 in the DeltaprpDBC background, suggesting that these genes encode bifunctional ICL/MCL enzymes. A DeltaprpB Deltaicl1 Deltaicl2 mutant was unable to grow on propionate or mixtures of propionate and glucose. We hypothesize that incomplete propionyl-CoA metabolism might cause toxic metabolites to accumulate. Consistent with this idea, deletion of prpC and prpD in the DeltaprpB Deltaicl1 Deltaicl2 background paradoxically restored growth on propionate-containing media. These observations suggest that the marked attenuation of ICL1/ICL2-deficient M. tuberculosis in mice could be due to the accumulation of toxic propionyl-CoA metabolites, rather than inability to utilize fatty acids per se.