Completed Bacillus subtilis nucleoid as a doublet structure.

When outgrowing spores of the temperature-sensitive dna initiation mutants of Bacillus subtilis, TsB134 and dna-1, were allowed to undergo a single round of replication by shifting to the restrictive temperature soon after its initiation, both segregating daughter nucleoids appeared as clearly defined doublet structures. The components of each doublet remained together as a discrete pair, even under conditions which resulted in the formation of deoxyribonucleic acid (DNA)-less cells. A doublet nucleoid was also observed at a high frequency when TsB134 spores were allowed to germinate and grow out in the complete absence of DNA synthesis at the permissive temperature. TsB134 spores were foud to contain the usual "haploid" amount of DNA. It is suggested that the doublet nucleoid reflects a folding of a single chromosome into two large domains which resolve from one another under conditions of cell extension in the absence of DNA synthesis.     

Bacterial chromosome segregation: evidence for DNA gyrase involvement in decatenation

Nucleoids isolated from a temperature-sensitive gyrB mutant of E. coli, incubated at restrictive temperatures, exhibit increased sedimentation rates and an abnormal doublet or dumbbell-shaped morphology. Shifting cells from restrictive to permissive temperature prior to nucleoid isolation leads to decreases in the percentage of doublet nucleoids and in nucleoid sedimentation rates. When nucleoids isolated from mutant cells exposed to restrictive temperature are incubated with purified gyrase, the percentage of doublet nucleoids decreases as the total number of nucleoids increases. These results, together with the demonstrated ability of gyrase to decatenate small circular DNA molecules in vitro, suggest that gyrase participates in bacterial chromosome segregation through its decatenating activity.     

Internal structure and dynamics of isolated Escherichia coli nucleoids assessed by fluorescence correlation spectroscopy

The morphology and dynamics of DNA in a bacterial nucleoid affects the kinetics of such major processes as DNA replication, gene expression. and chromosome segregation. In this work, we have applied fluorescence correlation spectroscopy to assess the structure and internal dynamics of isolated Escherichia coli nucleoids. We show that structural information can be extracted from the amplitude of fluorescence correlation spectroscopy correlation functions of randomly labeled nucleoids. Based on the developed formalism we estimate the characteristic size of nucleoid structural units for native, relaxed, and positively supercoiled nucleoids. The degree of supercoiling was varied using the intercalating agent chloroquine and evaluated from fluorescence microscopy images. The relaxation of superhelicity was accompanied by 15-fold decrease in the length of nucleoid units (from approximately 50 kbp to approximately 3 kbp).     

Underlying regularity in the shapes of nucleoids of Escherichia coli: implications for nucleoid organization and partition

The genomic DNA of Escherichia coli is localized in one or a few compact nucleoids. Nucleoids in rapidly grown cells appear in complex shapes; the relationship of these shapes to underlying arrangements of the DNA is of structural interest and of potential importance in gene localization and nucleoid partition studies. To help assess this variation in shape, limited three-dimensional information on individual nucleoids was obtained by DNA fluorescence microscopy of cells as they reoriented in solution or by optical sectioning. These techniques were also applied to enlarged nucleoids within swollen cells or spheroplasts. The resulting images indicated that much of the apparent variation was due to imaging from different directions and at different focal planes of more regular underlying nucleoid shapes. Nucleoid images could be transformed into compact doublet shapes by exposure of cells to chloramphenicol or puromycin, consistent with a preexisting bipartite nucleoid structure. Isolated nucleoids and nucleoids in stationary-phase cells also assumed a doublet shape, supporting such a structure. The underlying structure is suggested to be two subunits joined by a linker. Both the subunits and the linker appear to deform to accommodate the space available within cells or spheroplasts ("flexible doublet" model).     

Nucleoid structure and distribution in thermophilic Archaea.

Nucleoid structure and distribution in thermophilic organisms from the Archaea domain were studied. Combined phase-contrast and fluorescence microscopy of DAPI (4',6-diamidino-2-phenylindole)-stained Sulfolobus acidocaldarius and Sulfolobus solfataricus cells revealed that the nucleoids were highly structured. Different nucleoid distribution within the cells, representing different partition stages, was observed. The conformation of the nucleoids differed between exponentially growing and stationary-phase cells. Also, the stationary-phase cells contained two chromosomes, and the nucleoids occupied a larger part of the interior of the cells than in the exponentially growing cells. The part of the cell cycle during which fully separated nucleoids could be detected was short. Since the postreplication period is long in these organisms, there was a considerable time interval between termination of chromosome replication and completion of nucleoid separation, similar to the G2 phase in eukaryotic cells. The length of the visible cell constriction period was found to be in the same range as that of eubacteria. Finally, cell-cell connections were observed under certain conditions. Possible eubacterial, eukaryotic, and unique features of nucleoid processing and cell division in thermophilic archaea are discussed.     

Cell length, nucleoid separation, and cell division of rod-shaped and spherical cells of Escherichia coli.

By comparing the dimensions and DNA contents of normal rod-shaped Escherichia coli with those of mutants that grow as spheres or ellipsoids, we have determined that two parameters remain unchanged: the DNA/mass ratio and the average cell length (diameter, for spherical cells). In consequence, the average volumes and DNA contents of the spherical mutant cells are about four to six times greater than those of rod-shaped cells growing at a similar rate. In addition, it was found that cells of both rod and sphere forms had approximately the same number of nucleoids (as seen when the DNA was condensed after inhibition of protein synthesis). The nucleoids of the spherical cells therefore consist of four to six completed chromosomes each (polytene nucleoids). We suggest that the attainment of a minimum cell length is necessary for nucleoid separation after chromosome replication and that such a separation is itself a prerequisite for septum formation.     

Delayed nucleoid segregation in Escherichia coli

To study the role of cell division in the process of nucleoid segregation, we measured the DNA content of individual nucleoids in isogenic Escherichia coli cell division mutants by image cytometry. In pbpB(Ts) and ftsZ strains growing as filaments at 42 degrees C, nucleoids contained, on average, more than two chromosome equivalents compared with 1.6 in wild-type cells. Because similar results were obtained with a pbpB recA strain, the increased DNA content cannot be ascribed to the occurrence of chromosome dimers. From the determination of the amount of DNA per cell and per individual nucleoid after rifampicin inhibition, we estimated the C and D periods (duration of a round of replication and time between termination and cell division respectively), as well as the D' period (time between termination and nucleoid separation). Compared with the parent strain and in contrast to ftsQ, ftsA and ftsZ mutants, pbpB(Ts) cells growing at the permissive temperature (28 degrees C) showed a long D' period (42 min versus 18 min in the parent) indicative of an extended segregation time. The results indicate that a defective cell division protein such as PbpB not only affects the division process but also plays a role in the last stage of DNA segregation. We propose that PbpB is involved in the assembly of the divisome and that this structure enhances nucleoid segregation.     

The role of chloroplast membranes in the location of chloroplast DNA during the greening ofPhaseolus vulgaris etioplasts

Summary The location of DNA containing nucleoids has been studied in greening bean (Phaseolus vulgaris L.) etioplasts using electron microscopy of thin sections and the staining of whole leaf cells with the fluorochrome DAPI. At 0 hours illumination a diffuse sphere of cpDNA surrounds most of the prolamellar body. It appears to be made up of a number of smaller nucleoids and can be asymmetric in location. The DNA appears to be attached to the outside of the prolamellar body and to prothylakoids on its periphery. With illumination the nucleoid takes on a clear ring-like shape around the prolamellar body. The maximum development of the ring-like nucleoid at 5 hours illumination is associated with the outward expansion of the prolamellar body and the outward growth of the prothylakoids. At 5 hours the electron transparent areas lie in between the prothylakoids radiating out from the prolamellar body. Between 5 hours and 15 hours observations are consistent with the growing thylakoids separating the nucleoids as the prolamellar body disappears and the chloroplast becomes more elongate. At 15 hours the fully differentiated chloroplast has discrete nucleoids distributed throughout the chloroplast with evidence of thylakoid attachment. This is the SN (scattered nucleoid) distribution ofKuroiwa et al. (1981) and is also evident in 24 hours and 48 hours chloroplasts which have more thylakoids per granum. The changes in nucleoid location occur without significant changes in DNA levels per plastid, and there is no evidence of DNA or plastid replication.The observations indicate that cpDNA partitioning in dividing SN-type chloroplasts could be achieved by thylakoid growth and effectively accomplish DNA segregation, contrasting with envelope growth segregating nucleoids in PS-type (peripheral scattered nucleoids) chloroplasts. The influence of plastid development on nucleoid location is discussed.     

Super-resolution imaging of Escherichia coli nucleoids reveals highly structured and asymmetric segregation during fast growth

Bacterial replication and chromosome segregation are highly organized both in space and in time. However, spatial analysis is hampered by the resolution limit of conventional fluorescence microscopy. In this study, we incubate rapidly-growing Escherichia coli with 5-ethynyl-2′-deoxyuridine (EdU), label the resulting EdU-DNA with photoswitchable fluorophores, and image incorporated molecules with an average experimental precision of 13 nm. During the segregation process, nucleoids develop highly-defined and cell-cycle dependent hetero-structures, which contain discrete DNA fibers with diameters far below the diffraction limit. Strikingly, these structures appear temporally shifted between sister chromosomes, an asymmetry which accumulates for ongoing replication rounds. Moreover, nucleoid positioning and expansion along the bacterial length axis fit into an elongation-mediated segregation model in fast growing E. coli cultures. This is supported by close proximity of the nucleoids to the bacterial plasma membrane, the nature of the observed hetero-structures and recently found interactions of membrane-associated proteins with DNA.     

Genetic and morphological characterization of an Escherichia coli chromosome segregation mutant.

The temperature-sensitive nucleoid segregation mutant of Escherichia coli, PAT32, formerly described as a parA mutant, has been shown to carry a mutation near 66 min on the genetic map. Fine mapping with phages from the collection of Kohara et al. is consistent with its being a parC allele. Observation by fluorescence microscopy revealed the formation, at a nonpermissive temperature, of filaments containing one or two large nucleoids and of normal-size anucleate cells. There was also a significant loss of viability.     

Partitioning, Movement, and Positioning of Nucleoids in Mycoplasma capricolum

The nucleoids in Mycoplasma capricolum cells were visualized by phase-combined fluorescence microscopy of DAPI (4', 6-diamidino-2-phenylindole)-stained cells. Most growing cells in a rich medium had one or two nucleoids in a cell, and no anucleate cells were found. The nucleoids were positioned in the center in mononucleoid cells and at one-quarter and three-quarters of the cell length in binucleoid cells. These formations may have the purpose of ensuring delivery of replicated DNA to daughter cells. Internucleoid distances in binucleoid cells correlated with the cell lengths, and the relationship of DNA content to cell length showed that cell length depended on DNA content in binucleoid cells but not in mononucleoid cells. These observations suggest that cell elongation takes place in combination with nucleoid movement. Lipid synthesis was inhibited by transfer of cells to a medium lacking supplementation for lipid synthesis. The transferred cells immediately stopped dividing and elongated while regular spaces were maintained between the nucleoids for 1 h. After 1 h, the cells changed their shapes from rod-like to round, but the proportion of multinucleoid cells increased. Inhibition of protein synthesis by chloramphenicol induced nucleoid condensation and abnormal positioning, although partitioning was not inhibited. These results suggest that nucleoid partitioning does not require lipid or protein synthesis, while regular positioning requires both. When DNA replication was inhibited, the cells formed branches, and the nucleoids were positioned at the branching points. A model for the reproduction process of M. capricolum, including nucleoid migration and cell division, is discussed.     

Nucleoid partitioning and the division plane in Escherichia coli.

Escherichia coli nucleoids were visualized after the DNA of OsO4-fixed but hydrated cells was stained with the fluorochrome DAPI (4',6-diamidino-2-phenylindole dihydrochloride hydrate). In slowly growing cells, the nucleoids are rod shaped and seem to move along the major cell axis, whereas in rapidly growing, wider cells they consist of two- to four-lobed structures that often appear to advance along axes lying perpendicular or oblique to the major axis of the cell. To test the idea that the increase in cell diameter following nutritional shift-up is caused by the increased amount of DNA in the nucleoid, the cells were subjected to DNA synthesis inhibition. In the absence of DNA replication, the nucleoids continued to move in the growing filaments and were pulled apart into small domains along the length of the cell. When these cells were then transferred to a richer medium, their diameters increased, especially in the region enclosing the nucleoid. It thus appears that the nucleoid motive force does not depend on DNA synthesis and that cell diameter is determined not by the amount of DNA per chromosome but rather by the synthetic activity surrounding the nucleoid. Under the non-steady-state but balanced growth conditions induced by thymine limitation, nucleoids become separated into small lobules, often lying in asymmetric configurations along the cell periphery, and oblique and asymmetric division planes occur in more than half of the constricting cells. We suggest that such irregular DNA movement affects both the angle of the division plane and its position.     

FtsZ ring clusters in min and partition mutants: role of both the Min system and the nucleoid in regulating FtsZ ring localization

To understand further the role of the nucleoid and the min system in selection of the cell division site, we examined FtsZ localization in Escherichia coli cells lacking MinCDE and in parC mutants defective in chromosome segregation. More than one FtsZ ring was sometimes found in the gaps between nucleoids in min mutant filaments. These multiple FtsZ rings were more apparent in longer cells; double or triple rings were often found in the nucleoid-free gaps in ftsI min and ftsA min double mutant filaments. Introducing a parC mutation into the ftsA min double mutant allowed the nucleoid-free gaps to become significantly longer. These gaps often contained dramatic clusters of FtsZ rings. In contrast, filaments of the ftsA parC double mutant, which contained active MinCDE, assembled only one or two rings in most of the large nucleoid-free gaps. These results suggest that all positions along the cell length are competent for FtsZ ring assembly, not just sites at mid-cell or at the poles. Consistent with previous results, unsegregated nucleoids also correlated with a lack of FtsZ localization. A model is proposed in which both the inhibitory effect of the nucleoid and the regulation by MinCDE ensure that cells divide precisely at the midpoint.     

Influence of the nucleoid and the early stages of DNA replication on positioning the division site in Bacillus subtilis

Although division site positioning in rod‐shaped bacteria is generally believed to occur through the combined effect of nucleoid occlusion and the Min system, several lines of evidence suggest the existence of additional mechanisms. Studies using outgrown spores of Bacillus subtilis have shown that inhibiting the early stages of DNA replication, leading up to assembly of the replisome at oriC, influences Z ring positioning. Here we examine whether Z ring formation at midcell under various conditions of DNA replication inhibition is solely the result of relief of nucleoid occlusion. We show that midcell Z rings form preferentially over unreplicated nucleoids that have a bilobed morphology (lowering DNA concentration at midcell), whereas acentral Z rings form beside a single‐lobed nucleoid. Remarkably however, when the DnaB replication initiation protein is inactivated midcell Z rings never form over bilobed nucleoids. Relieving nucleoid occlusion by deleting noc increased midcell Z ring frequency for all situations of DNA replication inhibition, however not to the same extent, with the DnaB‐inactivated strain having the lowest frequency of midcell Z rings. We propose an additional mechanism for Z ring positioning in which the division site becomes increasingly potentiated for Z ring formation as initiation of replication is progressively completed.     

Stochastic nucleoid segregation dynamics as a source of the phenotypic variability in E. coli

Segregation of the replicating chromosome from a single to two nucleoid bodies is one of the major processes in growing bacterial cells. The segregation dynamics is tuned by intricate interactions with other cellular processes such as growth and division, ensuring flexibility in a changing environment. We hypothesize that the internal stochasticity of the segregation process may be the source of cell-to-cell phenotypic variability, in addition to the well-established gene expression noise and uneven partitioning of low copy number components. We compare dividing cell lineages with filamentous cells, where the lack of the diffusion barriers is expected to reduce the impact of other factors on the variability of nucleoid segregation dynamics. The nucleoid segregation was monitored using time-lapse microscopy in live E. coli cells grown in linear grooves. The main characteristics of the segregation process, namely, the synchrony of partitioning, rates of separation, and final positions, as well as the variability of these characteristics, were determined for dividing and filamentous lineages growing under the same conditions. Indeed, the gene expression noise was considerably homogenized along filaments as determined from the distribution of CFP and YFP stochastically expressed from the chromosome. We find that 1) the synchrony of nucleoid partitioning is progressively decreasing during consecutive cell cycles, but to a significantly lesser degree in filamentous than in dividing cells; 2) the mean partitioning rate of nucleoids is essentially the same in dividing and filamentous cells, displaying a substantial variability in both; and 3) nucleoids segregate to the same distances in dividing and filamentous cells. Variability in distances is increasing during successive cell cycles, but to a much lesser extent in filamentous cells. Our findings indicate that the variability of the chromosome segregation dynamics is reduced upon removal of boundaries between nucleoids, whereas the remaining variability is essentially inherent to the nucleoid itself.     

Growth kinetics of individual Bacillus subtilis cells and correlation with nucleoid extension

The growth rate of individual cells of Bacillus subtilis (doubling time, 120 min) has been calculated by using a modification of the Collins-Richmond principle which allows the growth rate of mononucleate, binucleate, and septate cells to be calculated separately. The standard Collins-Richmond equation represents a weighted average of the growth rate calculated from these three major classes. Both approaches strongly suggest that the rate of length extension is exponential. By preparing critical-point-dried cells, in which major features of the cell such as nucleoids and cross-walls can be seen, it has also been possible to examine whether nucleoid extension is coupled to length extension. Growth rates for nucleoid movement are parallel to those of total length extension, except possibly in the case of septate cells. Furthermore, by calculating the growth rate of various portions of the cell surface, it appears likely that the limits of the site of cylindrical envelope assembly lie between the distal tips of the nucleoid; the old poles show zero growth rate. Coupling of nucleoid extension with increase of cell length is envisaged as occurring through an exponentially increasing number of DNA-surface attachment sites occupying most of the available surface.     

The role of MatP,ZapA and ZapB in chromosomal organization and dynamics in Escherichia coli

Despite extensive research over several decades, a comprehensive view of how the Escherichia coli chromosome is organized within the nucleoid, and how two daughter chromosomes segregate has yet to emerge. Here we investigate the role of the MatP, ZapA and ZapB proteins in organizing the replication terminus (Ter) region and in the chromosomal segregation process. Quantitative image analysis of the fluorescently labeled Ter region shows that the replication terminus attaches to the divisome in a single segment along the perimeter of the cell in a MatP, ZapA and ZapB-dependent manner. The attachment does not significantly affect the bulk chromosome segregation in slow growth conditions. With or without the attachment, two chromosomal masses separate from each other at a speed comparable to the cell growth. The separation starts even before the replication terminus region positions itself at the center of the nucleoid. Modeling of the segregation based on conformational entropy correctly predicts the positioning of the replication terminus region within the nucleoid. However, the model produces a distinctly different chromosomal density distribution than the experiment, indicating that the conformational entropy plays a limited role in segregating the chromosomes in the late stages of replication.     

FtsZ and nucleoid segregation during outgrowth of Bacillus subtilis spores.

Spores of a strain of Bacillus subtilis in which ftsZ was under the control of the spac promoter were allowed to germinate and grow out in the presence of increasing concentrations of isopropyl-beta-D-thiogalactopyranoside (IPTG). Over the IPTG concentration range of 0 to 10(-3) M, the level of FtsZ from the time when the first nucleoid segregations were occurring, measured in Western blot (immunoblot) transfer experiments, varied between 15 and 100% of that in the wild type. Septation was completely blocked (for at least several hours) when the amount of FtsZ was < 30% of the wild-type level. At all levels of ftsZ induction, the timing and rate of segregation of nucleoids following the first round of replication were unaltered. It is concluded that FtsZ has no direct role in nucleoid segregation in this situation.     

TFAM knockdown-triggered mtDNA-nucleoid aggregation and a decrease in mtDNA copy number induce the reorganization of nucleoid populations and mitochondria-associated ER-membrane contacts

The correct organization of mitochondrial DNA (mtDNA) in nucleoids and the contacts of mitochondria with the ER play an important role in maintaining the mitochondrial genome distribution within the cell. Mitochondria-associated ER membranes (MAMs) consist of interacting proteins and lipids located in the outer mitochondrial membrane and ER membrane, forming a platform for the mitochondrial inner membrane-associated genome replication factory as well as connecting the nucleoids with the mitochondrial division machinery. We show here that knockdown of a core component of mitochondrial nucleoids, TFAM, causes changes in the mitochondrial nucleoid populations, which subsequently impact ER-mitochondria membrane contacts. Knockdown of TFAM causes a significant decrease in the copy number of mtDNA as well as aggregation of mtDNA nucleoids. At the same time, it causes significant upregulation of the replicative TWNK helicase in the membrane-associated nucleoid fraction. This is accompanied by a transient elevation of MAM proteins, indicating a rearrangement of the linkage between ER and mitochondria triggered by changes in mitochondrial nucleoids. Reciprocal knockdown of the mitochondrial replicative helicase TWNK causes a decrease in mtDNA copy number and modifies mtDNA membrane association, however, it does not cause nucleoid aggregation and considerable alterations of MAM proteins in the membrane-associated fraction. Our explanation is that the aggregation of mitochondrial nucleoids resulting from TFAM knockdown triggers a compensatory mechanism involving the reorganization of both mitochondrial nucleoids and MAM. These results could provide an important insight into pathological conditions associated with impaired nucleoid organization or defects of mtDNA distribution.