Bovine papilloma virus plasmids replicate randomly in mouse fibroblasts throughout S phase of the cell cycle

Bovine papilloma virus (BPV) replicates as a multicopy nuclear plasmid in mouse fibroblasts. Using fluorescence activated cell sorting and mitotic selection procedures, we show that the replication of BPV occurs throughout S phase of the cell cycle and that replication is confined to S phase. After one round of chromosomal DNA replication, almost one quarter of BPV plasmids have replicated more than once, while a similar number of plasmids have not replicated at all. While multiple forms of BPV exist in the cell, all forms show the same pattern of replication. These results are consistent with a model in which BPV plasmids are chosen at random for replication throughout, and only during, S phase and support the view that the completion of S phase is a specifically activated event in the cell cycle rather than simply the end of one round of chromosomal DNA replication.     

Bacterial plasmids that carry two functional centromere analogs are stable and are partitioned faithfully

The par genes of unit-copy plasmids P1 and F promote equitable distribution of plasmid copies to daughter cells and can be considered to be functional analogs of eucaryotic centromeres. Composite plasmids were constructed which carry either two functional P1 par regions or one F and one P1 region. Unlike dicentric chromosomes, such plasmids are stably maintained.     

Epstein-Barr virus-derived plasmids replicate only once per cell cycle and are not amplified after entry into cells.

Some possible ways in which replication of plasmids containing the Epstein-Barr virus (EBV) plasmid maintenance origin, oriP, might be controlled were investigated. Virtually all plasmid molecules were found to replicate no more than once per cell cycle, whether replication was observed after stable introduction of the plasmids into cells by drug selection or during the first few cell divisions after introducing the DNA into cells. The presence in the cells of excess amounts of EBNA1, the only viral protein needed for oriP function, did not increase the number of oriP-replicated plasmids maintained by cells under selection. In the cell lines studied, EBNA1 and oriP seem to lack the capacity to override the cellular controls that limit DNA replication to one initiation event per DNA molecule per S phase. The multicopy status of EBV-derived, selectable plasmids appears to result from the initial uptake by cells of large numbers of plasmid molecules, the efficient maintenance of these plasmids, and the pressure of genetic selection against plasmid loss. Other unknown controls must be responsible for the amplification of EBV genomes soon after latent infection of cells.     

FtsZ and bacterial cell division

In this review we describe proteins and supermolecular structures which take part in the division of bacterial cells. FtsZ, a eukaryotic tubulin homolog is a key cell division protein in most prokaryotes. FtsZ, as well as tubulin, is capable of binding and hydrolyzing GTP. The division of a bacterial cell begins with the forming of a so-called divisome. The basis of such a divisome is a contractile ring (Z ring) which encircles the cell about midcell. The Z-ring consists of a bundle of laterally bound protofilaments formed in result of FtsZ polymerization. Z-ring is rigidly bounded to the cytosolic side of the inner membrane with the participation of FtsA, ZipA, FtsW and many other divisome cell division proteins. The ring directs the process of cytokinesis transmitting constriction power to the membrane. The primary structures of the prokaryotic FtsZ family members significantly differ from eukaryotic tubulins except for the sites of GTP binding. There is a high degree of structural homology between these proteins in the region. FtsZ is one of the most conserved proteins in prokaryotes. However, ftsZ genes have not been found in several species of microorganisms with completely sequenced genomes. They include two species of mycoplasmas (Ureaplasma parvum and Mycoplasma mobile), Prostecobacter dejongeii, 10 species of chlamydia and 5 species of archaea. Consequently, these organisms divide without FtsZ participation. The genomes of U. parvum and M. mobile have many open reading frames which encode proteins with unknown functions. A comparison of the primary structures of these hypothetical proteins did not identify any known cell division proteins. We hypothesize that the process of cell division in these organisms should involve proteins similar to FtsZ in function and homologous to FtsZ or other cell division proteins in structure.     

FtsZ and the division of bacterial cell

In this review we have tried to describe proteins and supermolecular structures which take part in the division of bacterial cell. The principal cell division protein of the most of prokaryotes is FtsZ, a homologue of eukaryotic tubulin. FtsZ just as tubulin is capable to bind and hydrolyze GTP. The division of bacterial cell begins with forming of so called divisome. The basis of such divisome is a contractile ring (Z ring); the ring encircles the cell about midcell. Z ring consists of a bundle of laterally bound protofilaments, which have been formed as a result of FtsZ polymerization. Z ring is rigidly bounded to cytozolic side of inner membrane with participation of FtsA, ZipA, FtsW and many other cell division proteins of divisome. The ring directs the process of cytokinesis transmitting power of constriction to membrane. Primary structures of members of the family of prokaryotic FtsZs differ from eukaryotic tubulines significantly except the region, where the site of GTP binding is placed. There is high degree of homology between structures of these proteins in the region. FtsZ is one of the most conservative proteins in prokaryotes, but ftsZ genes have not been found in completely sequenced genomes of several species of microorganisms. There are 2 species of mycoplasmas (Ureaplasma parvum and Mycoplasma mobile), Prostecobacter dejongeii, 10 species of chlamydia and 5 species of archaea among them. So these organisms divide without FtsZ. There are many open reading frames which encode proteins with unknown functions in genomes of U. parvum and M. mobile. The comparison of primary structures of these hypothetical proteins with structures of cell division proteins did not allow researchers to find similar proteins among them. We suppose that the process of cell division of these organisms should recruit proteins with function similar to FtsZ and having homologous with FtsZ or other cell division proteins spatial structures.     

Genomic channeling in bacterial cell division

The bacterial dcw cluster is a group of genes involved in cell division and peptidoglycan synthesis. Comparison of the cluster across several bacterial genomes shows that its gene content and its gene order are conserved in distant bacterial lineages and, moreover, that, being most conserved in rod-shaped bacteria, the degree of conservation relates to bacterial morphology. We propose a model in which the selective pressure to maintain the cluster arises from the need to efficiently coordinate the processes of elongation and septation in rod-shaped bacteria. Gene order in the dcw cluster would be conserved as a result of mechanisms comprising: (i) a limited amount of peptidoglycan precursors required both for septation and elongation of the wall; (ii) co-translational assembly of the protein complexes involved in cell division and in the synthesis of the peptidoglycan precursors; and (iii) alternation in the cellular localization of the assembled complexes to participate either in the synthesis of the septal peptidoglycan and division, or in the synthesis of the lateral wall. The name genomic channeling is proposed for this model as it involves a genomic arrangement that could facilitate the assembly of specific protein complexes and their subsequent conveyance to specific locations in the crowded cytoplasm and the envelope.     

Temperature sensitive replication plasmids are passively distributed during cell division at non-permissive temperature: a new model for replicon duplication and partitioning

Summary To see whether plasmid molecules in bacteria are equally partitioned or randomly distributed at cell division, the segregation properties of temperature sensitive replication mutants of the E. coli plasmid pSC101 were tested at non-permissive temperature. The results support the idea that at least unreplicated molecules are passively distributed and thus the Equipartition Model is unlikely even under physiological conditions if plasmids replicate randomly. Therefore, we developed a new model which involves the Random Replication Hypothesis and assumes that only the two products of the last plasmid replication event are actively partitioned into two daughter cells and the others are randomly distributed. Mathematical studies revealed that the incompatibility segregation rate predicted by this model fits the experimental data.     

Coordinating cell polarity with cell division in space and time

Decisions of when and where to divide are crucial for cell survival and fate, and for tissue organization and homeostasis. The temporal coordination of mitotic events during cell division is essential to ensure that each daughter cell receives one copy of the genome. The spatial coordination of these events is also crucial because the cytokinetic furrow must be aligned with the axis of chromosome segregation and, in asymmetrically dividing cells, the polarity axis. Several recent papers describe how cell shape and polarity are coordinated with cell division in single cells and tissues and begin to unravel the underlying molecular mechanisms, revealing common principles and molecular players. Here, we discuss how cells regulate the spatial and temporal coordination of cell polarity with cell division.     

The bacterial cell cycle: DNA replication, nucleoid segregation, and cell division

Data on the bacterial cell cycle published in the last 10-15 years are considered, with a special stress on studies of nucleoid segregation between dividing cells. The degree of similarity between the eukaryotic mitotic apparatus and the apparatus performing nucleoid separation is discussed.     

CRISPR-Cas systems are widespread accessory elements across bacterial and archaeal plasmids

Many prokaryotes encode CRISPR-Cas systems as immune protection against mobile genetic elements (MGEs), yet a number of MGEs also harbor CRISPR-Cas components. With a few exceptions, CRISPR-Cas loci encoded on MGEs are uncharted and a comprehensive analysis of their distribution, prevalence, diversity, and function is lacking. Here, we systematically investigated CRISPR-Cas loci across the largest curated collection of natural bacterial and archaeal plasmids. CRISPR-Cas loci are widely but heterogeneously distributed across plasmids and, in comparison to host chromosomes, their mean prevalence per Mbp is higher and their distribution is distinct. Furthermore, the spacer content of plasmid CRISPRs exhibits a strong targeting bias towards other plasmids, while chromosomal arrays are enriched with virus-targeting spacers. These contrasting targeting preferences highlight the genetic independence of plasmids and suggest a major role for mediating plasmid-plasmid conflicts. Altogether, CRISPR-Cas are frequent accessory components of many plasmids, which is an overlooked phenomenon that possibly facilitates their dissemination across microbiomes.     

Ruthenium red-induced bundling of bacterial cell division protein, FtsZ

The assembly of FtsZ plays a major role in bacterial cell division, and it is thought that the assembly dynamics of FtsZ is a finely regulated process. Here, we show that ruthenium red is able to modulate FtsZ assembly in vitro. In contrast to the inhibitory effects of ruthenium red on microtubule polymerization, we found that a substoichiometric concentration of ruthenium red strongly increased the light-scattering signal of FtsZ assembly. Further, sedimentable polymer mass was increased by 1.5- and 2-fold in the presence of 2 and 10 microm ruthenium red, respectively. In addition, ruthenium red strongly reduced the GTPase activity and prevented dilution-induced disassembly of FtsZ polymers. Electron microscopic analysis showed that 4-10 microm of ruthenium red produced thick bundles of FtsZ polymers. The significant increase in the light-scattering signal and pelletable polymer mass in the presence of ruthenium red seemed to be due to the bundling of FtsZ protofilaments into larger polymers rather than the actual increase in the level of polymeric FtsZ. Furthermore, ruthenium red was found to copolymerize with FtsZ, and the copolymerization of substoichiometric amounts of ruthenium red with FtsZ polymers promoted cooperative assembly of FtsZ that produced large bundles. Calcium inhibited the binding of ruthenium red to FtsZ. However, a concentration of calcium 1000-fold higher than that of ruthenium red was required to produce similar effects on FtsZ assembly. Ruthenium red strongly modulated FtsZ polymerization, suggesting the presence of an important regulatory site on FtsZ and suggesting that a natural ligand, which mimics the action of ruthenium red, may regulate the assembly of FtsZ in bacteria.     

Crystal structure of the bacterial cell division inhibitor MinC

Bacterial cell division requires accurate selection of the middle of the cell, where the bacterial tubulin homologue FtsZ polymerizes into a ring structure. In Escherichia coli, site selection is dependent on MinC, MinD and MINE: MinC acts, with MinD, to inhibit division at sites other than the midcell by directly interacting with FTSZ: Here we report the crystal structure to 2.2 A of MinC from Thermotoga maritima. MinC consists of two domains separated by a short linker. The C-terminal domain is a right-handed beta-helix and is involved in dimer formation. The crystals contain two different MinC dimers, demonstrating flexibility in the linker region. The two-domain architecture and dimerization of MinC can be rationalized with a model of cell division inhibition. MinC does not act like SulA, which affects the GTPase activity of FtsZ, and the model can explain how MinC would select for the FtsZ polymer rather than the monomer.     

An Arabidopsis homolog of the bacterial cell division inhibitor SulA is involved in plastid division

Plastids have evolved from an endosymbiosis between a cyanobacterial symbiont and a eukaryotic host cell. Their division is mediated both by proteins of the host cell and conserved bacterial division proteins. Here, we identified a new component of the plastid division machinery, Arabidopsis thaliana SulA. Disruption of its cyanobacterial homolog (SSulA) in Synechocystis and overexpression of an AtSulA-green fluorescent protein fusion in Arabidopsis demonstrate that these genes are involved in cell and plastid division, respectively. Overexpression of AtSulA inhibits plastid division in planta but rescues plastid division defects caused by overexpression of AtFtsZ1-1 and AtFtsZ2-1, demonstrating that its role in plastid division may involve an interaction with AtFtsZ1-1 and AtFtsZ2-1.     

Cell division ring, a new cell division protein and vertical inheritance of a bacterial organelle in anammox planctomycetes

Anammox bacteria are members of the phylum Planctomycetes that oxidize ammonium anaerobically and produce a significant part of the atmosphere's dinitrogen gas. They contain a unique bacterial organelle, the anammoxosome, which is the locus of anammox catabolism. While studying anammox cell and anammoxosome division with transmission electron microscopy including electron tomography, we observed a cell division ring in the outermost compartment of dividing anammox cells. In most Bacteria, GTP hydrolysis drives the tubulin-analogue FtsZ to assemble into a ring-like structure at the cell division site where it functions as a scaffold for the molecular machinery that performs cell division. However, the genome of the anammox bacterium ' Candidatus Kuenenia stuttgartiensis' does not encode ftsZ . Genomic analysis of open reading frames with potential GTPase activity indicated a possible novel cell division ring gene: kustd1438, which was unrelated to ftsZ . Immunogold localization specifically localized kustd1438 to the cell division ring. Genomic analyses of other members of the phyla Planctomycetes and Chlamydiae revealed no putative functional homologues of kustd1438, suggesting that it is specific to anammox bacteria. Electron tomography also revealed that the bacterial organelle was elongated along with the rest of the cell and divided equally among daughter cells during the cell division process.     

Adherence, accumulation, and cell division of a natural adherent bacterial population.

Developing dental bacterial plaques formed in vivo on enamel surfaces were examined in specimens from 18 adult volunteers during the first day of plaque formation. An intraoral model placing enamel pieces onto teeth was used to study bacterial plaque populations developing naturally to various cell densities per square millimeter of surface area of the enamel (W. F. Liljemark, C. G. Bloomquist, C. L. Bandt, B. L. Philstrom, J. E. Hinrichs, and L. F. Wolff, Oral Microbiol. Immunol. 8:5-15, 1993). Radiolabeled nucleoside incorporation was used to measure DNA synthesis concurrent with the taking of standard viable cell counts of the plaque samples. Results showed that in vivo plaque formation began with the rapid adherence of bacteria until ca. 12 to 32% of the enamel's salivary pellicle was saturated (ca. 2.5 x 10(5) to 6.3 x 10(5) cells per mm2). The pioneer adherent species were predominantly those of the "sanguis streptococci." At the above-noted density, the bacteria present on the salivary pellicle incorporated low levels of radiolabeled nucleoside per viable cell. As bacterial numbers reached densities between 8.0 x 10(5) and 2.0 x 10(6) cells per mm2, there was a small increase in the incorporation of radiolabeled nucleosides per cell. At 2.5 x 10(6) to 4.0 x 10(6) cells per mm2 of enamel surface, there was a marked increase in the incorporation of radiolabeled nucleosides per cell which appeared to be cell-density dependent. The predominant species group in developing dental plaque films during density-dependent growth was the sanguis streptococci; however, most other species present showed similar patterns of increased DNA synthesis as the density noted above approached 2.5 x 10(6) to 4.0 x 10(6) cells per mm2.     

Synthetic ColE1 plasmids carrying genes for cell division in Escherichia coli.

Clarke and Carbon's collection of 2000 E. coli strains, which harbor ColE1 plasmids carrying small random segments of the E. coli chromosome, was screened for the correction of thermosensitive defects in the processes of cell division and in the synthesis of murein-lipoprotein. The genetic defects examined in this screening were those in partition of daughter nuclei (par), cleavage of cells (fts), determination of a cell shape (rod), and synthesis of murein-lipoprotein (lpo). We found plasmids carrying E. coli chromosomal segments containing ftsB⁺, ftsE⁺,ftsI⁺,ftsM⁺, and parA⁺. However, none was found to transfer ftsA⁺, ftsC⁺, ftsF⁺, ftsG⁺, ftsJ⁺, ftsK⁺, ftsL⁺, parB⁺, rod⁺, and lpo⁺. One of the donor strains transferring a gene that corrected thermosensitive cell cleavage in the ftsI^? mutant overproduced the penicillin-binding protein 3 by ca. 10-fold.     

Apoptotic cells are generated at every division of in vitro cultured T cell lines.

Long- and short-term T cell lines form the backbone of many assays for T cell function and also represent important tools for use in human immunotherapy. Despite much study concerning the requirements for T cell activation and growth in culture there is relatively little information about the kinetics of proliferation and cell death in such cultures. Here we studied these parameters in a long-term CD8(+) T cell line using a tetrameric MHC reagent and the fluorescent dye CFSE. We observed proliferation of the T cells within 24 h of restimulation with antigen and IL-2 and the cells continued to divide once every 12 h on average. Interestingly, a proportion of cells entered apoptosis with each cell division, showing that a degree of programmed cell death occurred constantly in vitro, not merely at the end of the culture period when antigen or the necessary growth factors became limiting. This information should assist in the design of more efficient protocols for generating large numbers of specific T cells for clinical use.