The attachment of the bacterial chromosome to the cell membrane

The Birth of the Copenhagen School: Personal Recollections at the EMBO Workshop on Bacterial Growth Physiology, 2022

The future of bacterial growth physiology is shining more brightly than ever [...].

Effects of heterologous genome microinjection on the enlargement of Enterococcus faecalis protoplasts

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More than 100 E. faecalis protoplasts were generated and microinjected into heterologous genomic DNAs.

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Protoplast enlargement did not stop but continued after the microinjection.

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Microinjection of genomic DNA into E. faecalis protoplasts frequently induced weakness in enlargement.

The lactic acid bacterium Enterococcus faecalis genomic DNA and seven phylogenetically distant bacterial genomic DNAs were microinjected into 126 enlarged protoplasts of E. faecalis. After the microinjection, a time-lapse observation was performed on how the cells enlarged. Most cells did not stop enlarging. The enlargement patterns were compared with the enlargement of E. faecalis protoplasts not treated by microinjection (control). They were clustered into three groups, with different levels and speeds of protoplast enlargement. The statistical analyses showed that the protoplasts injected by E. faecalis and four of the seven phylogenetically different bacterial genomic DNAs had enlargement patterns significantly different from those of the control. Thus, injected genomic DNAs affected the protoplast enlargement. Most of the affected cells, including the E. faecalis genome, had weakened enlargement.

Special Issue: Role of Bacterial Chromatin in Environmental Sensing, Adaptation and Evolution

A typical bacterial cell is micron-sized and contains a genome several million base pairs in length [...].

Mechanisms for Chromosome Segregation in Bacteria

The process of DNA segregation, the redistribution of newly replicated genomic material to daughter cells, is a crucial step in the life cycle of all living systems. Here, we review DNA segregation in bacteria which evolved a variety of mechanisms for partitioning newly replicated DNA. Bacterial species such as Caulobacter crescentus and Bacillus subtilis contain pushing and pulling mechanisms that exert forces and directionality to mediate the moving of newly synthesized chromosomes to the bacterial poles. Other bacteria such as Escherichia coli lack such active segregation systems, yet exhibit a spontaneous de-mixing of chromosomes due to entropic forces as DNA is being replicated under the confinement of the cell wall. Furthermore, we present a synopsis of the main players that contribute to prokaryotic genome segregation. We finish with emphasizing the importance of bottom-up approaches for the investigation of the various factors that contribute to genome segregation.

Identification of a Potential Membrane-Targeting Sequence in the C-Terminus of the F Plasmid Segregation Protein SopA

Stable maintenance and partitioning of the 'Fertility' plasmid or the F plasmid in its host Escherichia coli require the function of a ParA superfamily of proteins known as SopA. The mechanism by which SopA mediates plasmid segregation is well studied. SopA is a nucleoid-binding protein and binds DNA in an ATP-dependent but sequence non-specific manner. ATP hydrolysis stimulated by the binding of the SopBC complex mediates the release of SopA from the nucleoid. Cycles of ATP-binding and hydrolysis generate an ATPase gradient that moves the plasmid through a chemophoresis force. Nucleoid binding of SopA thus assumes a central role in its plasmid-partitioning function. However, earlier work also suggests that the F plasmid can be partitioned into anucleate cells, thus implicating nucleoid independent partitioning. Interestingly, SopA is also reported to be associated with the inner membrane of the bacteria. Here, we report the identification of a possible membrane-targeting sequence, a predicted amphipathic helix, at the C-terminus of SopA. Molecular dynamics simulations indicate that the predicted amphipathic helical motif of SopA has weak affinity for membranes. Moreover, we experimentally show that SopA can associate with bacterial membranes, is detectable in the membrane fractions of bacterial lysates, and is sensitive to the membrane potential. Further, unlike the wild-type SopA, a deletion of the C-terminal 29 amino acids results in the loss of F plasmids from bacterial cells.

Factors That Affect the Enlargement of Bacterial Protoplasts and Spheroplasts

Cell enlargement is essential for the microinjection of various substances into bacterial cells. The cell wall (peptidoglycan) inhibits cell enlargement. Thus, bacterial protoplasts/spheroplasts are used for enlargement because they lack cell wall. Though bacterial species that are capable of gene manipulation are limited, procedure for bacterial cell enlargement does not involve any gene manipulation technique. In order to prevent cell wall resynthesis during enlargement of protoplasts/spheroplasts, incubation media are supplemented with inhibitors of peptidoglycan biosynthesis such as penicillin. Moreover, metal ion composition in the incubation medium affects the properties of the plasma membrane. Therefore, in order to generate enlarged cells that are suitable for microinjection, metal ion composition in the medium should be considered. Experiment of bacterial protoplast or spheroplast enlargement is useful for studies on bacterial plasma membrane biosynthesis. In this paper, we have summarized the factors that influence bacterial cell enlargement.

Novobiocin inhibits membrane synthesis and vacuole formation of Enterococcus faecalis protoplasts

We demonstrate that plasma membrane biosynthesis and vacuole formation require DNA replication in Enterococcus faecalis protoplasts. The replication inhibitor novobiocin inhibited not only DNA replication but also cell enlargement (plasma membrane biosynthesis) and vacuole formation during the enlargement of the E. faecalis protoplasts. After novobiocin treatment prior to vacuole formation, the cell size of E. faecalis protoplasts was limited to 6 μm in diameter and the cells lacked vacuoles. When novobiocin was added after vacuole formation, E. faecalis protoplasts grew with vacuole enlargement; after novobiocin removal, protoplasts were enlarged again. Although cell size distribution of the protoplasts was similar following the 24 h and 48 h novobiocin treatments, after 72 h of novobiocin treatment there was a greater number of smaller sized protoplasts, suggesting that extended novobiocin treatment may inhibit the re-enlargement of E. faecalis protoplasts after novobiocin removal. Our findings demonstrate that novobiocin can control the enlargement of E. faecalis protoplasts due to inhibition of DNA replication.

DNA replication and cell enlargement of Enterococcus faecalis protoplasts

Protoplasts of Enterococcus faecalis did not divide but enlarged in Difco Marine Broth containing penicillin. Our previous studies have demonstrated that transcription and translation were essential for bacterial cell enlargement. However, it was uncertain whether replication was also essential. In this study, we measured the amount of DNA in E. faecalis cells during the course of enlargement using quantitative polymerase chain reaction. The growth of normally divided cells (native forms) of E. faecalis exhibited a log phase before 6 h of incubation was reached. Although a difference in quantitation cycle (Cq) values between the replication initiation and termination regions was observed in the log phase, it was not present in the stationary growth phase. On the other hand, the amount of DNA in E. faecalis protoplasts increased during the cell enlargement incubation. The difference of Cq values between the protoplasts at 0 and 96 h of incubation was 8–9, indicating that the DNA amount at 96 h was 200–500 times higher than that at 0 h. The Cq values differed between the replication initiation and termination regions, indicating that the replication level was high. When novobiocin, a DNA replication inhibitor, was added to the medium at 24 h of incubation, DNA replication and cell enlargement were almost stopped. Thus, replication plays an important role in the enlargement of E. faecalis protoplasts.

Preferential Localization of the Bacterial Nucleoid

Prokaryotes do not make use of a nucleus membrane to segregate their genetic material from the cytoplasm, so that their nucleoid is potentially free to explore the whole volume of the cell. Nonetheless, high resolution images of bacteria with very compact nucleoids show that such spherical nucleoids are invariably positioned at the center of mononucleoid cells. The present work aims to determine whether such preferential localization results from generic (entropic) interactions between the nucleoid and the cell membrane or instead requires some specific mechanism, like the tethering of DNA at mid-cell or periodic fluctuations of the concentration gradient of given chemical species. To this end, we performed numerical simulations using a coarse-grained model based on the assumption that the formation of the nucleoid results from a segregative phase separation mechanism driven by the de-mixing of the DNA and non-binding globular macromolecules. These simulations show that the abrupt compaction of the DNA coil, which takes place at large crowder density, close to the jamming threshold, is accompanied by the re-localization of the DNA coil close to the regions of the bounding wall with the largest curvature, like the hemispherical caps of rod-like cells, as if the DNA coil were suddenly acquiring the localization properties of a solid sphere. This work therefore supports the hypothesis that the localization of compact nucleoids at regular cell positions involves either some anchoring of the DNA to the cell membrane or some dynamical localization mechanism.

An ImageJ tool for simplified post-treatment of TEM phase contrast images (SPCI)

Tools for taking advantage of phase-contrast in transmission electron microscopy are of great interest for both biological and material sciences studies as shown by the recent use of phase plates and the development of holography. Nevertheless, these tools most often require highly qualified experts and access to advanced equipment that can only be considered after preliminary investigations. Here we propose to address this issue by the development of an ImageJ plugin that allow the retrieval of a phase image by simple numerical treatment applied to two defocused images. This treatment based on Tikhonov regularization requires the adjustment of a single parameter. Moreover, it is possible to use this approach on one-image. Although in that case the retrieved image gives only qualitative information, it is able to enhance the image contrast appropriately. This can be of interest for specimens producing low contrast images under the electron microscopes, such as some frozen hydrated biological samples or those sensible to electron radiation unsuitable for holographic studies.

Chromosome-Membrane Interactions in Bacteria

Prokaryotes, by definition, do not segregate their genetic material from the cytoplasm. Thus, there is no barrier preventing direct interactions between chromosomal DNA and the plasma membrane. The possibility of such interactions in bacteria was proposed long ago and supported by early electron microscopy and cell fractionation studies. However, the identification and characterization of chromosome-membrane interactions have been slow in coming. Recently, this subject has seen more progress, driven by advances in imaging techniques and in the exploration of diverse cellular processes. A number of loci have been identified in specific bacteria that depend on interactions with the membrane for their function. In addition, there is growing support for a general mechanism of DNA-membrane contacts based on transertion-concurrent transcription, translation, and insertion of membrane proteins. This review summarizes the history and recent results of chromosome-membrane associations and discusses the known and theorized consequences of these interactions in the bacterial cell.

Single cell super-resolution imaging of E. coli OmpR during environmental stress

Two-component signaling systems are a major strategy employed by bacteria, and to some extent, yeast and plants, to respond to environmental stress. The EnvZ/OmpR system in E. coli responds to osmotic and acid stress and is responsible for regulating the protein composition of the outer membrane. EnvZ is a histidine kinase located in the inner membrane. Upon activation, it is autophosphorylated by ATP and subsequently, it activates OmpR. Phosphorylated OmpR binds with high affinity to the regulatory regions of the ompF and ompC porin genes to regulate their transcription. We set out to visualize these two-components in single bacterial cells during different environmental stress conditions and to examine the subsequent modifications to the bacterial nucleoid as a result. We created a chromosomally-encoded, active, fluorescent OmpR-PAmCherry fusion protein and compared its expression levels with RNA polymerase. Quantitative western blotting had indicated that these two proteins were expressed at similar levels. From our images, it is evident that OmpR is significantly less abundant compared to RNA polymerase. In cross-sectional axial images, we observed OmpR molecules closely juxtaposed near the inner membrane during acidic and hyposomotic growth. In acidic conditions, the chromosome was compacted. Surprisingly, under acidic conditions, we also observed evidence of a spatial correlation between the DNA and the inner membrane, suggesting a mechanical link through an active DNA-OmpR-EnvZ complex. This work represents the first direct visualization of a response regulator with respect to the bacterial chromosome.

Bacterial chromosome organization and segregation

Bacterial chromosomes are generally approximately 1000 times longer than the cells in which they reside, and concurrent replication, segregation, and transcription/translation of this crowded mass of DNA poses a challenging organizational problem. Recent advances in cell-imaging technology with subdiffraction resolution have revealed that the bacterial nucleoid is reliably oriented and highly organized within the cell. Such organization is transmitted from one generation to the next by progressive segregation of daughter chromosomes and anchoring of DNA to the cell envelope. Active segregation by a mitotic machinery appears to be common; however, the mode of chromosome segregation varies significantly from species to species.

Recombinant protein excretion in Escherichia coli JM103[pUC8]: Effects of plasmid content, ethylenediaminetetraacetate, and phenethyl alcohol on cell membrane permeability

The presence of a high copy number plasmid (pUC8) was found to affect integrity of the cell envelope of Escherichia coli JM103, causing in turn significant release of the plasmid-encoded protein (beta-lactamase). The alterations in cell membrane permeability were evident from the increased susceptibility of recombinant cells to deoxycholic acid and methylene blue, which did not have appreciable effect on plasmid-free cells. The deteriorated cell membrane structure also resulted in a substantial reduction in specific growth rate and mass yield of plasmid-bearing cells. Further enhancement in beta-lactamase excretion was achieved by permeabilizing cell membrane with ethylenediaminetetra-acetate (EDTA) and phenethyl alcohol (PEA). Unlike other commonly used physical and chemical methods for releasing the enzymes accumulated in the cells, application of EDTA and PEA at appropriate concentrations neither led to cell death nor interrupted synthesis of the plasmid-encoded protein. While in situ application of PEA was complicated due to interference with beta-lactamase activity, in situ application of EDTA was found to be an efficient way of releasing the recombinant protein without sacrificing its productivity. The experimental results demonstrate that the presence of EDTA and PEA can substantially reduce the growth rate differential between plasmid-free and plasmid-bearing cells, suggesting possible improvement of plasmid stability by application of these cell membrane-permeabilizing on a periodic basis.

Activity of Lac repressor anchored to the Escherichia coli inner membrane

The transient inactivation of gene regulatory proteins by their sequestration to the cytoplasmic membrane in response to cognate signals is an increasingly recognized mechanism of gene regulation in bacteria. It remained to be shown, however, whether tethering to the membrane per se could be responsible for inactivation, i.e. whether such relocation leads to a spatial separation from the chromosome that results in inactivity or whether other mechanisms are involved. We, therefore, investigated the activity of Lac repressor artificially attached to the Escherichia coli cytoplasmic membrane. We demonstrate that this chimeric protein perfectly represses transcription initiated at the tac operator–promoter present on a plasmid and even in the chromosome. Moreover, this repression is inducible as normal. The data suggest that proteins localized to the inner face of the cytoplasmic membrane in principle have unrestricted access to the chromosome. Thus sequestration to the membrane in terms of physical separation from the chromosome cannot account alone for the inactivation of regulatory proteins. Other mechanisms, like induction of a conformational change or masking of binding domains are required additionally.

Compartmentalization of prokaryotic DNA replication

It becomes now apparent that prokaryotic DNA replication takes place at specific intracellular locations. Early studies indicated that chromosomal DNA replication, as well as plasmid and viral DNA replication, occurs in close association with the bacterial membrane. Moreover, over the last several years, it has been shown that some replication proteins and specific DNA sequences are localized to particular subcellular regions in bacteria, supporting the existence of replication compartments. Although the mechanisms underlying compartmentalization of prokaryotic DNA replication are largely unknown, the docking of replication factors to large organizing structures may be important for the assembly of active replication complexes. In this article, we review the current state of this subject in two bacterial species, Escherichia coli and Bacillus subtilis, focusing our attention in both chromosomal and extrachromosomal DNA replication. A comparison with eukaryotic systems is also presented.

Cellular localization of Type I restriction-modification enzymes is family dependent

Cellular localization of Type I restriction-modification enzymes EcoKI, EcoAI, and EcoR124I-the most frequently studied representatives of IA, IB, and IC families-was analyzed by immunoblotting of subcellular fractions isolated from Escherichia coli strains harboring the corresponding hsd genes. EcoR124I shows characteristics similar to those of EcoKI. The complex enzymes are associated with the cytoplasmic membrane via DNA interaction as documented by the release of the Hsd subunits from the membrane into the soluble fraction following benzonase treatment. HsdR subunits of the membrane-bound enzymes EcoKI and EcoR124I are accessible, though to a different extent, at the external surface of cytoplasmic membrane as shown by trypsinization of intact spheroplasts. EcoAI strongly differs from EcoKI and EcoR124I, since neither benzonase nor trypsin affects its association with the cytoplasmic membrane. Possible reasons for such a different organization are discussed in relation of the control of the restriction-modification activities in vivo.

Unequal access of chromosomal regions to each other in Salmonella: probing chromosome structure with phage lambda integrase-mediated long-range rearrangements

We have investigated the fluidity of the Salmonella chromosome architecture using the phage lambda site-specific recombination system as a probe. We determined how chromosome position affects the extent of integrase-mediated recombination between pairs of inversely oriented att sites at various loci. We also investigated the accessibility of each chromosomal att site to an extrachromosomal partner carried on a low-copy plasmid. Recombination events were assayed by semi-quantitative polymerase chain reaction of the attP product. The extent of recombination between the chromosome and the plasmid was generally higher than intrachromosomal recombination except for two loci, araA::attL and galT::attL, which gave no detectable recombination with any other locus. Based on 20 intervals, we found that chromosomal locations are not equally accessible to each other. Although multiple factors probably affect accessibility, the most important is the specific combination of the end-points used. Neither the size of the intervals nor the accessibility of individual end-points to extrachromosomal sequences is as important. These results suggest that the chromosome is not completely fluid but rather organized in some way, with barriers that limit the movement of DNA within the cell. The nature of the barriers involved in chromosomal organization remains to be determined.

Glom is a novel mitochondrial DNA packaging protein in Physarum polycephalum and causes intense chromatin condensation without suppressing DNA functions

Mitochondrial DNA (mtDNA) is packed into highly organized structures called mitochondrial nucleoids (mt-nucleoids). To understand the organization of mtDNA and the overall regulation of its genetic activity within the mt-nucleoids, we identified and characterized a novel mtDNA packaging protein, termed Glom (a protein inducing agglomeration of mitochondrial chromosome), from highly condensed mt-nucleoids of the true slime mold, Physarum polycephalum. This protein could bind to the entire mtDNA and package mtDNA into a highly condensed state in vitro. Immunostaining analysis showed that Glom specifically localized throughout the mt-nucleoid. Deduced amino acid sequence revealed that Glom has a lysine-rich region with proline-rich domain in the N-terminal half and two HMG boxes in C-terminal half. Deletion analysis of Glom revealed that the lysine-rich region was sufficient for the intense mtDNA condensation in vitro. When the recombinant Glom proteins containing the lysine-rich region were expressed in Escherichia coli, the condensed nucleoid structures were observed in E. coli. Such in vivo condensation did not interfere with transcription or replication of E. coli chromosome and the proline-rich domain was essential to keep those genetic activities. The expression of Glom also complemented the E. coli mutant lacking the bacterial histone-like protein HU and the HMG-boxes region of Glom was important for the complementation. Our results suggest that Glom is a new mitochondrial histone-like protein having a property to cause intense DNA condensation without suppressing DNA functions.

The role of co-transcriptional translation and protein translocation (transertion) in bacterial chromosome segregation

Many recent reviews in the field of bacterial chromosome segregation propose that newly replicated DNA is actively separated by the functioning of specific proteins. This view is primarily based on an interpretation of the position of fluorescently labelled DNA regions and proteins in analogy to the active segregation mechanism in eukaryotic cells, i.e. to mitosis. So far, physical aspects of DNA organization such as the diffusional movement of DNA supercoil segments and their interaction with soluble proteins, leading to a phase separation between cytoplasm and nucleoid, have received relatively little attention. Here, a quite different view is described taking into account DNA-protein interactions, the large variation in the cellular position of fluorescent foci and the compaction and fusion of segregated nucleoids upon inhibition of RNA or protein synthesis. It is proposed that the random diffusion of DNA supercoil segments is transiently constrained by the process of co- transcriptional translation and translocation (transertion) of membrane proteins. After initiation of DNA replication, a bias in the positioning of transertion areas creates a bidirectionality in chromosome segregation that becomes self-enhanced when neighbouring genes on the same daughter chromosome are expressed. This transertion-mediated segregation model is applicable to multifork replication during rapid growth and to multiple chromosomes and plasmids that occur in many bacteria.

Phi29 family of phages

Continuous research spanning more than three decades has made the Bacillus bacteriophage phi29 a paradigm for several molecular mechanisms of general biological processes, such as DNA replication, regulation of transcription, phage morphogenesis, and phage DNA packaging. The genome of bacteriophage phi29 consists of a linear double-stranded DNA (dsDNA), which has a terminal protein (TP) covalently linked to its 5' ends. Initiation of DNA replication, carried out by a protein-primed mechanism, has been studied in detail and is considered to be a model system for the protein-primed DNA replication that is also used by most other linear genomes with a TP linked to their DNA ends, such as other phages, linear plasmids, and adenoviruses. In addition to a continuing progress in unraveling the initiation of DNA replication mechanism and the role of various proteins involved in this process, major advances have been made during the last few years, especially in our understanding of transcription regulation, the head-tail connector protein, and DNA packaging. Recent progress in all these topics is reviewed. In addition to phi29, the genomes of several other Bacillus phages consist of a linear dsDNA with a TP molecule attached to their 5' ends. These phi29-like phages can be divided into three groups. The first group includes, in addition to phi29, phages PZA, phi15, and BS32. The second group comprises B103, Nf, and M2Y, and the third group contains GA-1 as its sole member. Whereas the DNA sequences of the complete genomes of phi29 (group I) and B103 (group II) are known, only parts of the genome of GA-1 (group III) were sequenced. We have determined the complete DNA sequence of the GA-1 genome, which allowed analysis of differences and homologies between the three groups of phi29-like phages, which is included in this review.

Characterization of the bacteriophage phi29-encoded protein p16.7: a membrane protein involved in phage DNA replication

An early expressed operon, located at the right end of the linear bacteriophage phi29 genome, contains open reading frame (ORF)16.7, whose deduced protein sequence of 130 amino acids is conserved in phi29-related phages. Here, we show that this ORF actually encodes a protein, p16.7, which is abundantly and early expressed after infection. p16.7 is a membrane protein, and the N-terminally located transmembrane-spanning domain is required for its membrane localization. The variant p16.7A, in which the N-terminal membrane anchor was replaced by a histidine-tag, was purified and characterized. Purified p16.7A was shown to form dimers in solution. To study the in vivo role of p16.7, a phi29 mutant containing a suppressible mutation in gene 16.7 was constructed. In vivo phage DNA replication was affected in the absence of p16.7, especially at early infection times. Based on the results, the putative role of p16.7 in in vivo phi29 DNA replication is discussed.

Localization of the type I restriction-modification enzyme EcoKI in the bacterial cell

To localise the type I restriction-modification (R-M) enzyme EcoKI within the bacterial cell, the Hsd subunits present in subcellular fractions were analysed using immunoblotting techniques. The endonuclease (ENase) as well as the methylase (MTase) were found to be associated with the cytoplasmic membrane. HsdR and HsdM subunits produced individually were soluble, cytoplasmic polypeptides and only became membrane-associated when coproduced with the insoluble HsdS subunit. The release of enzyme from the membrane fraction following benzonase treatment indicated a role for DNA in this interaction. Trypsinization of spheroplasts revealed that the HsdR subunit in the assembled ENase was accessible to protease, while HsdM and HsdS, in both ENase and MTase complexes, were fully protected against digestion. We postulate that the R-M enzyme EcoKI is associated with the cytoplasmic membrane in a manner that allows access of HsdR to the periplasmic space, while the MTase components are localised on the inner side of the plasma membrane.

A novel DNA-binding protein bound to the mitochondrial inner membrane restores the null mutation of mitochondrial histone Abf2p in Saccharomyces cerevisiae

The yeast mitochondrial HMG-box protein, Abf2p, is essential for maintenance of the mitochondrial genome. To better understand the role of Abf2p in the maintenance of the mitochondrial chromosome, we have isolated a multicopy suppressor (YHM2) of the temperature-sensitive defect associated with an abf2 null mutation. The function of Yhm2p was characterized at the molecular level. Yhm2p has 314 amino acid residues, and the deduced amino acid sequence is similar to that of a family of mitochondrial carrier proteins. Yhm2p is localized in the mitochondrial inner membrane and is also associated with mitochondrial DNA in vivo. Yhm2p exhibits general DNA-binding activity in vitro. Thus, Yhm2p appears to be novel in that it is a membrane-bound DNA-binding protein. A sequence that is similar to the HMG DNA-binding domain is important for the DNA-binding activity of Yhm2p, and a mutation in this region abolishes the ability of YHM2 to suppress the temperature-sensitive defect of respiration of the abf2 null mutant. Disruption of YHM2 causes a significant growth defect in the presence of nonfermentable carbon sources such as glycerol and ethanol, and the cells have defects in respiration as determined by 2,3,5,-triphenyltetrazolium chloride staining. Yhm2p may function as a member of the protein machinery for the mitochondrial inner membrane attachment site of mitochondrial DNA during replication and segregation of mitochondrial genomes.

Cell membrane and chromosome replication in Bacillus subtilis

This review covers studies of the structural and functional roles of the cell membrane on the replication of the Bacillus subtillis chromosome. A particular emphasis is placed on the essential roles of the membrane complex for the in vivo initiation and termination of the chromosome replication. A critical gene complex in B. subtillis for the role of membrane complex is the dnaB operon that most likely consists of four genes (dnaB, dnaI, ORFZ/ORF213, and ORF omega/ORF281). Detailed studies of these genes are currently available only for the dnaB and dnaI genes. The unique feature of the dnaB gene is that temperature-sensitive mutants of this gene simultaneously lose, at the nonpermissive temperature, chromosome attachment at oriC to the membrane as well as the new round of replication initiation at oriC. Further studies on the genes and their products of the dnaB operon are therefore essential for our understanding of the in vivo mechanism of the initiation of chromosome replication and its regulation. The role of the membrane on the termination and segregation of the daughter chromosomes has not been discovered, but an important clue comes from the terminus area of the B. subtillis chromosome being bound to the membrane in a high-salt resistant and DnaB-independent fashion.

Initiation of bacteriophage phi29 DNA replication in vivo: assembly of a membrane-associated multiprotein complex

Initiation of in vitro phage phi29 DNA replication requires the formation of a heterodimer between a free molecule of terminal protein (TP), which acts as primer, and the viral DNA polymerase. We have analyzed membrane vesicles from phi29-infected Bacillus subtilis cells by quantitative immunoblot techniques. During phage DNA synthesis, large amounts of the viral proteins p1 and free TP were recovered in membrane fractions, as well as a low percentage of the total viral DNA polymerase. Interestingly, the amount of DNA polymerase in membrane fractions increased when viral DNA replication was blocked. Both protein p1 and free TP showed affinity for membranes in the absence of viral DNA. The association of protein p1 with membranes was abolished when the C-terminal 43 amino acid residues were deleted. The above results, together with the critical role of protein p1 for in vivo phi29 DNA replication, led us to conclude that a preliminary stage in the initiation of in vivo phi29 DNA replication could be the assembly of a membrane-associated multiprotein complex containing at least protein p1, free TP and DNA polymerase. Membrane-attachment of this complex could be directly mediated by both protein p1 and free TP. The ability of free TP to bind to membranes and to prime phi29 DNA replication would enable a nascent viral DNA molecule to become membrane-associated when its synthesis begins. We postulate that a general function of the TPs covalently linked to linear DNA genomes in prokaryotes might be, in addition to act as primer, to anchor the linear DNA molecule to the bacterial membrane.

SHM1: a multicopy suppressor of a temperature-sensitive null mutation in the HMG1-like abf2 gene

HM, an HMG1-like mitochondrial DNA-binding protein, is required for maintenance of the yeast mitochondrial genome when cells are grown in glucose. To better understand the role of HM in mitochondria, we have isolated several multicopy suppressors of the temperature-sensitive defect associated with an abf2 null mutation (lacking HM protein). One of these suppressors, SHM1, has been characterized at the molecular level and is described herein. SHM1 encodes a protein (SHM1p) that shares sequence similarity to a family of mitochondrial carrier proteins. On glycerol medium, where mitochondrial function is required for growth, shm1 deletion mutants are able to grow whereas shm1 abf2 double mutants are severely inhibited. These results suggest the SHM1p plays an accessory role to HM in the mitochondrion.

The bacterial nucleus: a history

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The replicative origin of the E. coli chromosome binds to cell membranes only when hemimethylated

DNA from the E. coli replicative origin binds with high affinity to outer membrane preparations. Specific binding regions are contained within a 463 bp stretch of origin DNA between positions -46 and +417 on the oriC map. This region of DNA contains an unusually high number of GATC sites, the recognition sequence for the E. coli DNA adenine methylase. We show here that oriC DNA binds to membrane only when it is hemimethylated. The E. coli chromosomal origin is hemimethylated for 8-10 min after initiation of replication, and origin DNA binds to membranes only during this time period. Based on these results, we propose a speculative model for chromosome segregation in E. coli.

Estimating the growth pattern of micro-organisms in distinct stages of the cell cycle

Knowledge of the growth patterns of micro-organisms is required to understand how cell growth and division are controlled and co-ordinated in relation to mechanisms of wall assembly and chromosome duplication. Direct observation, e.g. by time-lapse studies, is usually limited in accuracy by the small size of the cells. Indirect methods have therefore been developed which give estimates of the growth patterns of cells, based on the analysis of distributions of cell size in populations in balanced exponential growth. Previously, we have compared such methods (Burdett & Kirkwood, 1983) and concluded that the most powerful approach is that proposed by Collins & Richmond (1962), in which growth rate is calculated as a function of cell size using size distributions of extant, separating and new-born cells. A limitation of this method has been, however, that it gives only an estimate for the average growth rate of cells at a given size, irrespective of the state of progress of individual cells through the cell cycle. In this paper, we describe an extension to the standard Collins-Richmond procedure which provides separate estimates for the growth pattern of cells in distinct stages of the cell cycle, and we illustrate the method in relation to growth of mononucleate, binucleate and septate cells of Bacillus subtilis. It is demonstrated that this three-stage analysis is clearly superior to the standard method, in that it provides more detailed and probably more realistic information. We also demonstrate how to assess the precision and accuracy of the estimated growth pattern. Generalization of the method to any number of stages and to multiple as well as binary fission is described.

Contribution of new cryomethods to a better knowledge of bacterial anatomy

Electron microscopy has largely contributed to the study of bacterial anatomy. However, as varied alterations can occur during cell preparation, at the level of cell structure and at the molecular level, it is difficult to know to what extent electron micrographs correspond to the true appearance of the living state. The recent development of cryomethods which avoid some of the alterations which may occur during conventional fixation and embedding procedures, has shed new light on bacterial anatomy. These have definitively proved that mesosomes do not exist, but are artefactual structures induced by the fixative. New features of the bacterial "nucleus" relating to its shape and fine structure appeared in thin sections of Gram-positive and Gram-negative bacteria prepared by cryosubstitution. New information has also been obtained on the cell wall structure of different bacterial species.

Membrane protein binding to the origin region of Bacillus subtilis

Binding of membrane proteins extracted from Bacillus subtilis to an 11.6-kilobase region containing the origin of replication was examined by Western blotting (protein blotting) procedures. Two adjacent origin probes in the double-stranded form (spanning a length of 4 kilobases) were found to bind very strongly to a 63-kilodalton (kDa) protein in that they resisted dissociation after a high-concentration salt wash. This region encompasses both a site implicated in initiation in vivo and a gene coding for a DNA gyrase subunit (gyrA). In contrast, flanking origin and nonorigin double-stranded probes were dissociated after washing with a high salt concentration. Another protein of 67 kDa bound less intensely to the putative initiation site but not to the gyrA region. All of the origin and nonorigin probes in the double- or single-stranded form were found to bind nonspecifically to a subset of 10 to 12 proteins of 50 to 60 separated by gel electrophoresis after a low-concentration salt wash. They ranged in size from 14 to over 100 kDa (including 63 kDa). However, in contrast to the double-stranded forms, most of the single-stranded probes resisted dissociation from the protein subset after a high-concentration salt wash.

DNA replication by a DNA-membrane complex extracted from Bacillus subtilis: site of initiation in vitro and initiation potential of subcomplexes

A DNA-membrane complex extracted from Bacillus subtilis was studied further as a model system for initiation of bacterial DNA replication in vitro. Of three subcomplexes purified from the crude complex by a combination of CsCl and sucrose gradient centrifugation, the synthetic capability of only one was inhibited significantly by streptovaricin, a known inhibitor of RNA primer formation. A selective enrichment in the level of this subcomplex was obtained by manipulating a thymine-requiring mutant. The synthetic capabilities of an enriched and nonenriched DNA-membrane complex were compared in the presence and absence of streptovaricin. Although the rate and extent of DNA synthesis per unit of protein were approximately the same in the absence of the antibiotic, there was a much greater inhibition of synthesis shown by the enriched complex in the presence of streptovaricin. Although the amount of DNA present in the putative initiation subcomplex was less than 0.3 to 0.4% of the total DNA present in the crude complex, such DNA, except for a few quantitative differences, was still representative of genomic DNA. Newly synthesized DNA hybridized to specific origin- and non-origin-derived restriction fragments of the B. subtilis genome. However, when an elongation inhibitor (ddCTP) was added, hybridization of such DNA to almost all of the nonorigin fragments disappeared or was reduced drastically, whereas origin region hybridization patterns remained strong. The highest level of hybridization in the origin region occurred with a BamHI (B7) restriction fragment of 5.6 kilobases that has been implicated by others as one site initiation in vivo (N. Ogasawara, M. Seiki, and H. Yoshikawa, Nature (London) 281:702-704, 1979; S. J. Seror-Laurent and G. Henckes, Proc. Natl. Acad. Sci. USA 82:3586-3590, 1985).

Nucleotide sequence of Bacillus subtilis dnaB: a gene essential for DNA replication initiation and membrane attachment

The complete nucleotide sequence of the Bacillus subtilis dnaB gene and its flanking regions was determined. The dnaB gene is essential for both replication initiation and membrane attachment of the origin region of the chromosome and plasmid pUB110. It has been known that there are two different classes (dnaBI and dnaBII) in the dnaB mutants; dnaBI is essential for both chromosome and pUB110 replication, whereas dnaBII is necessary only for chromosome replication. The nucleotide sequence revealed that dnaBI and dnaBII are two functional domains in the single dnaB gene. The mutation sites of two mutants, belonging to dnaBI and dnaBII, respectively, were also determined as substitutions of amino acids. The putative DnaB protein deduced from nucleotide sequence consists of 472 amino acids (55 kDa) with no cysteine residue. A 55-kDa polypeptide produced in an in vitro transcription-translation system was labeled with [35S]methionine but not with [35S]cysteine. The DnaB protein has a highly hydrophobic sequence of 20 amino acids in its N-terminal region, a possible DNA binding site, and two possible ATP binding sites. The dnaBI domain is between the DNA binding site and one of the ATP binding sites; the dnaBII domain is close to the other ATP binding site. Comparison of the amino acid sequence between the "dnaB protein" and those of other dna genes of Escherichia coli showed no homology, suggesting that the dnaB gene of B. subtilis may be analogous to a hitherto undiscovered gene in E. coli.

Asymmetric replication of an oriC plasmid in Escherichia coli

Plasmid pTSO118 containing the Escherichia coli origin of replication, oriC, initiated replication simultaneously with the chromosome when temperature-sensitive host cells were synchronized by temperature shifts. Replicating intermediates of the plasmid as well as of the chromosome were isolated from the outer membrane fraction of the cell. Plasmid DNA with eye structures was enriched when cytosine-1-beta-arabinofuranoside was introduced into the culture during replication. Electron microscopy of the replicating molecules, after digestion with restriction endonucleases, showed that the replication fork proceeds exclusively counter-clockwise towards the unc operon. We conclude that the replication of the oriC plasmid is unidirectional or, if bidirectional, is highly asymmetric.

Replication of plasmid RK2 in vitro by a DNA-membrane complex: evidence for initiation of replication and its coupling to transcription and translation

The following results with an in vitro replication system utilizing a plasmid RK2 DNA-membrane complex indicate that the essential trfA-encoded replication protein of RK2 is present and active in the complex. (i) A complex extracted from a conditional replication mutant of RK2, which contains a temperature-sensitive mutation in trfA, displayed extensive DNA synthesis at the permissive temperature but little activity at the restrictive temperature. A control wild-type RK2 complex showed no inhibition of DNA synthesis at the restrictive temperature. (ii) Analysis of plasmid-encoded proteins revealed that the trfA-specified replication protein and other proteins which may be involved in the replication and maintenance of RK2 are located physically in the complex. Semiconservative plasmid DNA replication by the DNA-membrane complex was indicated by density shift experiments; DNA synthesized in the presence of a heavy-density precursor banded primarily in a heavier-density area of a neutral CsCl density gradient and consisted mostly of heavy- and light-density single-stranded DNA as determined by alkaline CsCl density gradient centrifugation. Plasmid RK2 DNA replication by the DNA-membrane complex appears to be coupled to transcription and translation as indicated by the following results: the inhibitory effects of chloramphenicol on both DNA and protein synthesis by the complex; the stimulation of replication by components normally required for protein synthesis (tRNA and all the common amino acids); the synthesis of RNA and protein by the complex; and the synthesis of specific RK2-encoded proteins.

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.

Proteins tightly bound to DNA and DNA-synthesizing activity of nucleoids from Escherichia coli

Membrane-attached nucleoids were isolated from E. coli and separated from proteins by 2 M NaCl. Disintegration of such nucleoids by ultrasound and subsequent centrifugation resulted in the formation of two fractions: a sediment (fraction I) and a supernatant (fraction II). The protein:DNA ratio of fraction I was equal to 27 and was different from that to fraction II (2.6). More than 70% of the proteins not dissociating at 2 M NaCl and bound to DNA of both fractions were polypeptides with molecular weights (Mw) of 31,000-23,000 daltons (31-23 Kdal). After pulse labelling of the cells with [3H]-thymidine, the specific radioactivity of newly synthesized DNA associated with fraction I was shown to be considerably higher than that of fraction II. The analysis of DNA-synthesizing activities in fractions I and II showed that both nucleoid fractions contained DNA polymerase I. After dissolving the two fractions in 8 M urea - 0.15% sodium dodecylsulphate (SDS) they were chromatographed on hydroxyapatite. DNA-protein complexes were obtained that did not dissociate at 4 M guanidine X HCl - 5 M urea and 1% SDS. The main protein of the complexes was a 31 Kdal polypeptide tightly bound to DNA.

Cell wall and DNA cosegregation in Bacillus subtilis studied by electron microscope autoradiography

Cells of a Bacillus subtilis mutant deficient in both major autolytic enzyme activities were continuously labeled in either cell wall or DNA or both cell wall and DNA. After appropriate periods of chase in minimal as well as in rich medium, thin sections of cells were autoradiographed and examined by electron microscopy. The resolution of the method was adequate to distinguish labeled DNA units from cell wall units. The latter, which could be easily identified, were shown to segregate symmetrically, suggesting a zonal mode of new wall insertion. DNA units could also be clearly recognized despite a limited fragmentation; they segregated asymmetrically with respect to the nearest septum. Analysis of cells simultaneously labeled in cell wall and DNA provided clear visual evidence of their regular but asymmetrical cosegregation, confirming a previous report obtained by light microscope autoradiography (J.-M. Schlaeppi and D. Karamata, J. Bacteriol. 152:1231-1240, 1982). In addition to labeled wall units, electron microscopy of thin sections of aligned cells has revealed fibrillar networks of wall material which are frequently associated with the cell surface. Most likely, these structures correspond to wall sloughed off by the turnover mechanism but not yet degraded to filterable or acid-soluble components.

DNA-protein interactions during replication of genetic elements of bacteria

Specific interactions of DNA with proteins are required for both the replication of deoxyribonucleic acid proper and its regulation. Genetic elements of bacteria, their extrachromosomal elements in particular, represent a suitable model system for studies of these processes at the molecular level. In addition to replication enzymes (DNA polymerases), a series of other protein factors (e.g. topoisomerases, DNA unwinding enzymes, and DNA binding proteins) are involved in the replication of the chromosomal, phage and plasmid DNA. Specific interactions of proteins with DNA are particularly important in the regulation of initiation of DNA synthesis. Association of DNAs with the cell membrane also plays an important role in their replication in bacteria.

Identification of specific restriction fragments associated with a membrane subparticle from Bacillus subtilis

When lysates of Bacillus subtilis were treated with restriction endonucleases EcoRI or HindIII, almost all of the DNA was released from the major plasma membrane fraction that was sedimentable at low speed. However, a very small part of the released DNA, when centrifuged at high speed, appeared to be bound to small membrane fragments. On agarose gels, this material, prepared with either enzyme, contained only a small number of restriction fragments, and the DNA in the sample hybridized with 11 to 12 EcoRI or HindIII fragments of chromosomal DNA. This DNA was used after nick-translation to screen Charon 4A clone banks for phages containing membrane-bound fragments. One of these was studied in detail. Only a part (about 5 kilobases) of the region present in this clone is important in binding the DNA to the membrane subparticle.

Cosegregation of cell wall and DNA in Bacillus subtilis

Cosegregation of cell wall and DNA of a lysis-negative mutant of Bacillus subtilis was examined by continuously labeling (i) cell wall, (ii) DNA, and (iii) both cell wall and DNA. After four to five generations of chase in liquid media it was found by light microscope autoradiography that the numbers of wall segregation units per cell are 29 and 9 in rich and minimal medium, respectively. Under the same conditions the numbers of segregation units of DNA were almost 50% lower: 15 and 5, respectively. Simultaneous labeling of cell wall and DNA (iii) provided figures almost identical to those obtained for cell wall alone, (i), implying cosegregation of the two components. Statistical analysis ruled out their random distribution into daughter cells. Measurements of the positions of grain clusters at the end of the chase period along chains of cells, each derived from a single cell at the beginning of chase, show that cell wall units are localized according to a symmetrical pattern, whereas those of DNA are distributed in an asymmetrical but highly regular way. It appears that of two cell wall units of the same age one only has a strand of DNA attached to it. We present a simple diagrammatic model of cell wall organization and DNA-cell wall association which is compatible with our observations. Finally, we discuss previous experiments pertinent to cosegregation of cell wall and DNA obtained with cells grown on solid media as well as with germinating spores; an explanation for the independent segregation of cell wall and DNA observed in the latter case is advanced.

Binding of the origin of replication of Escherichia coli to the outer membrane

The replication origin of the Escherichia coli chromosome binds with high affinity to outer membrane preparations. This binding requires a 460 bp stretch of origin DNA between positions -40 and 420 of the oriC map. Specific binding can be detected by the use of a membrane filter retention assay in the presence of excess calf thymus DNA. This binding is enhanced by divalent cations and takes place specifically at a few (0.7-3.0) membrane sites per cell. The apparent affinity of origin DNA for membranes is enhanced by two peptides, (55 kilodaltons (kd) and 75 kd), which remain attached to the DNA through treatment with 5.5 M cesium chloride.

Membrane-DNA attachment sites in Streptococcus faecalis cells grown at different rates

The M-band technique was used to assess the number of attachment points of DNA to the cell membrane of Streptococcus faecalis grown at three different rates. Cells were X irradiated in liquid nitrogen and then analyzed simultaneously for the introduction of double-strand breaks into the chromosome and the degree of removal of DNA from the cell membrane (M band). Consideration of the data from these experiments and of the topology of the bacterial chromosome resulted in a reevaluation of former quantitative models. Our results are consistent with a semiquantitative model in which the bacterial chromosome is organized around a core structure. We interpret our data to mean that the core is attached to the membrane and that the complexity of the core changes more drastically with growth rate than does the number of membrane-DNA attachment points. An alternative model in which RNA hybridizes with DNA containing single- and double-strand breaks is also discussed. In any event, the complexity of these interactions precludes a reliable estimate of the number of membrane-DNA attachment sites.