Mechanisms of Bacterial Cell Division

Microbiology - Despite numerous studies, gaps still remain in our understanding of bacterial cell division. This review describes the basic mechanisms responsible for division of the bacterial cell...     

Chemical States of Bacterial Spores: Heat Resistance and Its Kinetics at Intermediate Water Activity

Bacterial spore heat resistance at intermediate water activity, like aqueous and strictly dry heat resistance, is a property manipulatable by chemical pretreatments of the dormant mature spore. Heat resistances differ widely, and survival is prominently nonlogarithmic for both chemical forms of the spore. Log survival varies approximately as the cube of time for the resistant state of Bacillus stearothermophilus spores and as the square of time for the sensitive state. A method for measuring heat resistance at intermediate humidity was designed to provide direct and unequivocal control of water vapor concentration with quick equilibration, maintenance of known spore state, and dispersion of spores singly for valid survivor counting. Temperature characteristics such as z, E(a), and Q(10) cannot be determined in the usual sense (as a spore property) for spores encapsulated with a constant weight of water. Effect on spore survival of temperature induced changes of water activity in such systems is discussed.     

Effect of Cell Moisture on the Thermal Inactivation Rate of Bacterial Spores

Thermal inactivation rates were determined for two strains of Bacillus subtilis var. niger spores after equilibration to various relative humidity (RH) levels. In these tests, small thin stainless-steel squares were each inoculated with a drop of spore suspension and equilibrated to 11, 33, or 85% RH. Following equilibration, the squares were placed on a hot plate preheated to 108, 125, 136, 164, or 192 C for various exposure times and then assayed for surviving organisms. The results revealed that spores of the A strain of B. subtilis were least resistant if preequilibrated to 11% RH and most resistant if preequilibrated to 85% RH. The same trend was obtained at all temperatures except 192 C, at which, no difference was noted, probably because the rapid kill time approaches the heat-up time of the stainless-steel square. The B strain of B. subtilis spores showed an opposite RH effect; that is, the cells preequilibrated to 11% RH were the most resistant. Because the two strains of spores were grown on different media, further studies were conducted at 136 C after subculturing the cells on different media. When the B strain was subcultured on the A strain medium, the pattern was reversed; the cells preequilibrated to low RH were then least resistant. Although it was not possible to reverse these cells to the original pattern by subculturing on the original B strain medium again, the pattern was altered to the point that there was no significant difference in heat resistance of these cells regardless of the preequilibration RH. The same result was obtained when the A strain was grown on the B strain medium; that is, the thermal resistance could not be reversed, but it was altered from the point where the low RH equilibrated cells were least resistant initially to the point where there was no significant difference in any of the cells regardless of what RH was used for preequilibration. The thermal resistance of spores seemed to be dependent on (i) the medium on which the spores are grown, (ii) the RH on which they are exposed before heating, and (iii) some genetic characteristic of the cell.     

The Effects of Centrifugation on Asymmetric Cell Division and Differentiation of Fern Spores

We have investigated the effects of centrifugation on sporepolarity, asymmetric cell division, and rhizoid differentiationin the sensitive fern Onoclea sensibilis L. Centrifugation at10000 g for 30 min produces a random orientation of spores withstratification of the cell contents. After centrifugation atmost early stages of development, the nucleus retains its normalpattern of migration from the centre of the ellipsoidal sporeto the proximal face and then to an end of the spore, withoutregard to the orientation of stratification. This indicatesthat the polarity of the spore is stable to centrifugation.As long as the nucleus migrates to an end of the spore and asymmetriccell division occurs, the small cell differentiates into a rhizoid.The arrangement of large cytoplasmic organelles appears to haveno influence on nuclear migration, asymmetric cell division,or rhizoid differentiation. The only period during developmentwhen centrifugation blocks asymmetric cell division is immediatelypreceding and during mitosis and cytokinesis. Spores centrifugedat this stage do not complete nuclear migration, and symmetriccell division results, with neither cell differentiating intoa rhizoid. The source of the stable polarity of the spore isdiscussed. cell polarity, rhizoid differentiation, centrifugation, Onoclea sensibilis L., sensitive fern, fern spores     

Bacterial Cell Division Regulation: Lysogenization of Conditional Cell Division lon− Mutants of Escherichia coli by Bacteriophage Lambda

The lon⁻ mutants of Escherichia coli grow apparently normally except that, after temporary periods of inhibition of deoxyribonucleic acid synthesis, septum formation is specifically inhibited. Under these conditions, long, multinucleate, nonseptate filaments result. The lon⁻ mutation also creates a defect such that wild-type bacteriophage λ fails to lysogenize lon⁻ mutants efficiently and consequently forms clear plaques on a lon⁻ host. Two lines of evidence suggest that this failure probably results from interference with expression of the λcI gene, which codes for repressor, or with repressor action:-(i) when a lon⁻ mutant was infected with a λcII, cIII, or c Y mutant, there was an additive effect between the lon⁻ mutation and the λc mutations upon reduction of lysogenization frequency; and (ii) lon⁻ mutants permitted the growth of the λcro⁻ mutant under conditions in which the repressor was active. The isolation of λ mutants (λtp) which gained the ability to form turbid plaques on lon⁻ cells is also reported.     

Design of a Microculture Chamber to Observe Cell Division of Bacterial L-Forms in Liquid Medium

A culture chamber is described that permits phase-contrast microscopic observations of the growth of stable L-form cells of Bacillus subtilis 168 in liquid medium.     

Conformation and Segregation of Nucleoids Accompanying Cell Length Extension After Completion of a Single Round of DNA Replication in Germinated and Outgrowing Bacillus subtilis Spores

When germinating spores of the temperature-sensitive DNA initiation mutant of Bacillus subtilis TsB134 are shifted to the restrictive temperature at a time such that just one or two rounds of replication are accomplished, the completed, nonreplicating nucleoids that form eventually adopt a doublet conformation. This conformation has now been observed after fixation by glutaraldehyde or osmium tetroxide, as well as by Formalin as found previously. The doublet was observed in media of different degrees of richness and under both light and electron microscopes. Electron micrographs of serial sections through the doublet were consistent with its formation by the gradual pulling apart of a single mass of DNA into two lobes. A systematic study was made of the effect of the time of shifting from the permissive to the restrictive temperature and of the restrictive temperature used on the number of nucleoids segregating within the outgrowing rod. It was established that the doublet nucleoid behaved as a single unit in replication control and segregation in both rich and poor media. Measurement of the relative position of the two segregating nucleoids within the outgrowing rod after completion of just one round of replication yielded quantitative information on the segregation and cell length extension processes. Segregation was accompanied by cell length extension at approximately equal rates on both sides of each nucleoid. Furthermore, the data were consistent with an exponential increase in such an extension with time over the early and major portion of the period studied, but it was not possible to rule out other models of length extension.     

Dimer Dynamics and Filament Organization of the Bacterial Cell Division Protein FtsA

FtsA is a bacterial actin homolog and one of the core proteins involved in cell division. While previous studies have demonstrated the capability of FtsA to polymerize, little is known about its polymerization state in vivo or if polymerization is necessary for FtsA function. Given that one function of FtsA is to tether FtsZ filaments to the membrane, in vivo polymerization of FtsA imposes geometric constraints and requires a specific polymer curvature direction. Here, we report a series of molecular dynamics simulations probing the structural dynamics of FtsA as a dimer and as a tetrameric single filament. We found that the FtsA polymer exhibits a preferred bending direction that would allow for its placement parallel with FtsZ polymers underneath the cytoplasmic membrane. We also identified key interfacial amino acids that mediate FtsA–FtsA interaction and propose that some amino acids play more critical roles than others. We performed in silico mutagenesis on FtsA and demonstrated that, while a moderate mutation at the polymerization interface does not significantly affect polymer properties such as bending direction and association strength, more drastic mutations change both features and could lead to non-functional FtsA.     

In Vitro Reconstitution of the Initial Stages of the Bacterial Cell Division Machinery

Fission of many prokaryotes as well as some eukaryotic organelles depends on the self-assembly of the FtsZ protein into a membrane-associated ring structure early in the division process. Different components of the machinery are then sequentially recruited. Although the assembly order has been established, the molecular interactions and the understanding of the force-generating mechanism of this dividing machinery have remained elusive. It is desirable to develop simple reconstituted systems that attempt to reproduce, at least partially, some of the stages of the process. High-resolution studies of Escherichia coli FtsZ filaments’ structure and dynamics on mica have allowed the identification of relevant interactions between filaments that suggest a mechanism by which the polymers could generate force on the membrane. Reconstituting the membrane-anchoring protein ZipA on E. coli lipid membrane on surfaces is now providing information on how the membrane attachment regulates FtsZ polymer dynamics and indicates the important role played by the lipid composition of the membrane.     

Bacterial Cell Division Regulation: Characterization of the dnaH Locus of Escherichia coli

The dnaH locus is the fourth gene to be identified as required for deoxyribonucleic acid polymerization in Escherichia coli. A temperature-sensitive mutant defective in this gene exhibited an abrupt decrease in rate of deoxyribonucleic acid synthesis when shifted to 42 C. The locus mapped in the proC-purE region of the chromosome by conjugation and was co-transducible with purE. dnaH(+) is carried on the F'(13) episome and is dominant over the dnaH(-) mutation.     

Bacterial SOS Checkpoint Protein SulA Inhibits Polymerization of Purified FtsZ Cell Division Protein

Cell division of Escherichia coli is inhibited when the SulA protein is induced in response to DNA damage as part of the SOS checkpoint control system. The SulA protein interacts with the tubulin-like FtsZ division protein. We investigated the effects of purified SulA upon FtsZ. SulA protein inhibits the polymerization and the GTPase activity of FtsZ, while point mutant SulA proteins show little effect on either of these FtsZ activities. SulA did not inhibit the polymerization of purified FtsZ2 mutant protein, which was originally isolated as insensitive to SulA. These studies define polymerization assays for FtsZ which respond to an authentic cellular regulator. The observations presented here support the notion that polymerization of FtsZ is central to its cellular role and that direct, reversible inhibition of FtsZ polymerization by SulA may account for division inhibition.     

New Insight into the Thermal Properties and the Biological Behaviour of the Bacterial Spores

The physicochemical properties of spores were studied in relationship of their structure, which was modulated by chemical or genetic methods. The Bacillus subtilis spores were equilibrated at different water activities (from 0.113 to ~1) and investigated by differential scanning calorimetry (DSC). The isothermal sorptions at 25 °C of the native and the modified spores were also used to analyse the DSC results. As already reported in literature, an endothermic peak in DSC was found at about 70 °C, but a previously unreported baseline shift, a ∆Cp step, was also observed at −69 °C. The endothermic peak found at 70 °C was assigned to a material relaxation which corresponded to a structure change from a less mobile state to a more mobile state. The spore cortex material seems to be mainly implicated in this event. The ∆Cp step observed at −69 °C was identified as a glass transition of the water in the spore protoplast. These results showed that at room temperature, the physical state of the components within B. subtilis spores equilibrated at water activity levels below 0.3 was different: The cortex material is in a low mobility state whereas confined structure of protoplast and its internal hydration level allow a certain mobility of water molecules.     

Rates of Growth and Cell Division in the Shoot Apex of Silene During the Transition to Flowering

The growth rates of the shoot apex during and after floral inductionwere measured in Silene, a long-day plant. Plants were inducedto flower with 4 or more long days (LD) but not with 3 longdays or with short days (SD). The rate of increase of cell numberin the apical dome, above the youngest leaf pair, was exponentialand in plants given 3 LD remained the same as in plants in SD.In plants induced to flower with 7 LD, until the end of theinductive period the rate of increase of cell number in theapical dome remained the same as in plants in SD. Only whenthe apex began to enlarge as the first stage in the formationof the flower did the growth rate of the apical dome increase.The rates of increase of cell numbers in the apex correspondedto mean cell generation times of 20 to 33 h for plants in SD,for plants given 3 LD, and during the 7 days of induction forplants given 7 LD, and 6 to 8 h for induced plants when flowerformation was beginning. The distribution of cell division in the apex was examined bytreating plants with colchicine and noting in sections the positionsof the resulting metaphases. In vegetative apices and also inapices undergoing transition to flowering the whole of the apicaldome appeared to consist of cells dividing at a similar rate. The rate of leaf initiation during induction was the same asin vegetative, non-induced plants.     

Variation in the Rate of Cell Division in the Apical Meristem of Sinapis alba During Transition to Flowering

Rates of cell division in the central and the peripheral zonesof vegetative and evoked meristems of Sinapis alba have beenmeasured by accumulation of metaphases after colchicine treatment.The cells of the central zone had a longer cycle than the cellson the flanks of both kinds of meristems. The duration of thecell cycle was shortened in both zones of the meristem duringtransition to flowering. It was shown that the mitotic indicesof the two regions of the meristem were closely comparable totheir rates of cell division and therefore could be consideredrepresentative of the rates of cell division.     

Uptake of and Resistance to the Antibiotic Berberine by Individual Dormant,Germinating and Outgrowing Bacillus Spores as Monitored by Laser Tweezers Raman Spectroscopy

Berberine, an alkaloid originally extracted from the plant Coptis chinensis and other herb plants, has been used as a pharmacological substance for many years. The therapeutic effect of berberine has been attributed to its interaction with nucleic acids and blocking cell division. However, levels of berberine entering individual microbial cells minimal for growth inhibition and its effects on bacterial spores have not been determined. In this work the kinetics and levels of berberine accumulation by individual dormant and germinated spores were measured by laser tweezers Raman spectroscopy and differential interference and fluorescence microscopy, and effects of berberine on spore germination and outgrowth and spore and growing cell viability were determined. The major conclusions from this work are that: (1) colony formation from B. subtilis spores was blocked ~ 99% by 25 μg/mL berberine plus 20 μg/mL INF55 (a multidrug resistance pump inhibitor); (2) 200 μg/mL berberine had no effect on B. subtilis spore germination with L-valine, but spore outgrowth was completely blocked; (3) berberine levels accumulated in single spores germinating with ≥ 25 μg/mL berberine were > 10 mg/mL; (4) fluorescence microscopy showed that germinated spores accumulated high-levels of berberine primarily in the spore core, while dormant spores accumulated very low berberine levels primarily in spore coats; and (5) during germination, uptake of berberine began at the time of commitment (T₁) and reached a maximum after the completion of CaDPA release (T_release) and spore cortex lysis (T_lysis).