Protein synthesis and the release of the replicated chromosome from the cell membrane

Fundamental principles in bacterial physiology-history, recent progress, and the future with focus on cell size control: a review

Bacterial physiology is a branch of biology that aims to understand overarching principles of cellular reproduction. Many important issues in bacterial physiology are inherently quantitative, and major contributors to the field have often brought together tools and ways of thinking from multiple disciplines. This article presents a comprehensive overview of major ideas and approaches developed since the early 20th century for anyone who is interested in the fundamental problems in bacterial physiology. This article is divided into two parts. In the first part (sections 1-3), we review the first 'golden era' of bacterial physiology from the 1940s to early 1970s and provide a complete list of major references from that period. In the second part (sections 4-7), we explain how the pioneering work from the first golden era has influenced various rediscoveries of general quantitative principles and significant further development in modern bacterial physiology. Specifically, section 4 presents the history and current progress of the 'adder' principle of cell size homeostasis. Section 5 discusses the implications of coarse-graining the cellular protein composition, and how the coarse-grained proteome 'sectors' re-balance under different growth conditions. Section 6 focuses on physiological invariants, and explains how they are the key to understanding the coordination between growth and the cell cycle underlying cell size control in steady-state growth. Section 7 overviews how the temporal organization of all the internal processes enables balanced growth. In the final section 8, we conclude by discussing the remaining challenges for the future in the field.

Co-ordinate regulation of the Escherichia coli cell cycle or The cloud of unknowing

A discussion of some aspects of the regulation of chromosome replication, segregation and cell division in Escherichia coli.

Inhibition and restart of initiation of chromosome replication: effects on exponentially growing Escherichia coli cells

Escherichia coli strains in which initiation of chromosome replication could be specifically blocked while other cellular processes continued uninhibited were constructed. Inhibition of replication resulted in a reduced growth rate and in inhibition of cell division after a time period roughly corresponding to the sum of the lengths of the C and D periods. The division inhibition was not mediated by the SOS regulon. The cells became elongated, and a majority contained a centrally located nucleoid with a fully replicated chromosome. The replication block was reversible, and restart of chromosome replication allowed cell division and rapid growth to resume after a time delay. After the resumption, the septum positions were nonrandomly distributed along the length axis of the cells, and a majority of the divisions resulted in at least one newborn cell of normal size and DNA content. With a transient temperature shift, a single synchronous round of chromosome replication and cell division could be induced in the population, making the constructed system useful for studies of cell cycle-specific events. The coordination between chromosome replication, nucleoid segregation, and cell division in E. coli is discussed.

Bacterial growth and division: genes, structures, forces, and clocks

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Membrane enrichment of genetic markers close to the origin and terminus during the deoxyribonucleic acid replication cycle in Bacillus subtilis

A temperature-sensitive Bacillus subtilis initiation mutant was used to achieve one cycle of synchronized deoxyribonucleic acid (DNA) replication. Markers near the origin of replication and the terminus were assayed for association with the cell membrane at intervals during the DNA replication cycle. DNA near the origin and terminus was found to be enriched in the membrane fraction throughout the DNA replication cycle. The magnitude of membrane enrichment or origin and terminus markers varied coincidentally, possibly as a consequence of incubating the cells at 45 degrees C.

Deoxyribonucleic acid-membrane interactions near the origin of replication and initiation of deoxyribonucleic acid synthesis in Escherichia coli

A previously reported salt-sensitive binding of deoxyribonucleic acid (DNA) to the cell envelope in Escherichia coli, involving approximately one site per chromosome near the origin of DNA replication, is rapidly disrupted in vivo by rifampin or chloramphenicol treatment and by amino acid starvation. DNA replication still initiates with this origin-specific binding disrupted, even when the disruption extends over the period of obligatory protein and ribonucleic acid synthesis that must precede initiation after release of cells from amino acid starvation. Thus the origin-associated membrane-DNA interaction is not necessary either for the initiation event itself or for the maturation of a putative initiation apparatus in E. coli.

Identification of a biochemically unique DNA-membrane interaction involving the Escherichia coli origin of replication

DNA-membrane complexes have been obtained from Escherichia coli by using a freeze-thaw lysis procedure that avoids lysozyme and detergents. Complexes made in this manner and containing DNA near the origin of replication are uniquely sensitive to ionic strength, Pronase, and trypsin. There is approximately one such complex per chromosomal origin. The sensitivities suggest that origin-specific binding is mediated by a protein. By using these unique characteristics to distinguish origin-specific complexes from the majority of DNA-membrane binding sites, it was found that the origin-specific binding persists after termination of chromosomal replication.

Characterization of a combined DNA initiation and cell division mutant of Bacillus subtilis

The temperature-sensitive mutation in Bacillus subtilis 168-134ts, a conditional lethal DNA initiation mutant, was transferred to the minicell producing strain, CU 403 div IV-B1, to study he relationship of DNA synthesis to cell division. Markers in the combined mutant were verified by transduction. DNA replication kinetics, genome location by autoradiography, and clonal analysis of cell division patterns during spore outgrowths were investigated. Growth of the double mutant at the restrictive temperature results in an impressive reduction of the percentage cell length covered by DNA grain clusters (60.2% at 30 degrees C compared to 8.6% after 2 h at 45 degress C). The probability of a minicell producing division in double mutant clones is essentially the same at 30 degrees C and during the initial 2-3 h growth at 45 degrees C at which time lysis begins. Residual division at 45 degrees C is attributable to processes initiated at 30 degrees C. The CU 403 div IV-B1, 134ts, double mutant divides about 25% as frequently relative to growth as do wild type CU 403 clones when incubated at permissive temperature. This is approximately 15% greater division suppression than previously found in the CU 403 div IV-B1 mutant strain, and is presumably due to interactions of the mutant gene products both of which affect DNA.

Some properties of a membrane-deoxyribonucleic acid complex isolated from Bacillus subtilis

Membrane-deoxyribonucleic acid (DNA) complexes were isolated from Bacillus subtilis by affinity for magnesium-Sarkosyl crystals. These complexes (M-bands) contained greater than 80% of the total cellular DNA; little of the remaining portion could be recovered in a secondary isolation. Isotopic labeling of the origin of replication showed this region of the chromosome to be closely associated with the cell membrane. Interruption of protein or DNA synthesis did not result in detachment of the chromosome from the membrane. Interruption of ribonucleic acid synthesis by rifampin resulted in a decreased ability to isolate DNA in the M-band. Analysis of attachment of the chromosome to membrane during the cell and replication cycles indicated that the chromosome is not released from the membrane at any time during the cell cycle.

Prokaryotic DNA in nucleoid structure

Recent studies of the structure of the bacterial nucleoid are reviewed. In the past 4 to 5 years results of electron microscopic and physical-chemical investigations of the isolated bacterial nucleoids have greatly advanced our understanding of this comparatively simple chromosome. Evidence for both long-range and short-range conformational organization of the packaged DNA has emerged, and preliminary characterization of the molecular interactions organizing this structure has been accomplished.

Studies of DNA bound RNA molecules isolated from nucleoids of Escherichia coli

Methods are developed for studying RNA molecules bound directly to DNA in bacterial nucleoids. It is found that among the 1000-3000 nascent RNA chains that normally are attached to the DNA via their associated RNA polymerase molecules, 74 +/- 14 chains per nucleoid can be bound differently. These chains unlike the other nascent RNAs remained bound to the DNA after the chromosome was deproteinized and sheared. Sensitive assays using radioactive labels detected no RNA polymerase involved in the RNA-DNA linkage. The linkage was stable at low temperatures, but the RNA separated from the DNA at high temperature. The bound RNA molecules were heterodisperse (weight average length 1200 bases). Pulse-chase experiments and studies of the fate of these RNA molecules in rifampicin treated cells demonstrated that they are nascent RNAs, degraded or released from the DNA in vivo with kinetics similar to that of the total nascent RNA. Hybridization analyses showed that the chains are composed at least in part of nascent rRNA and known mRNA molecules. Some, but not more than 5% of the bound chains, contained sequences of about 300 nucleotides in length, bound to the DNA in an RNase resistant form.

Lipid-F1 nucleohistone interactions

High concentrations of phospholipids determine destabilization of F1 histone-DNA complex at the weight ratios, histone:DNA, 0.8:1 and 1:1, but low concentrations cause only negligible destabilization. Cholesterol at high weight ratios has little effect on nucleohistone stability. Only linolenic acid of the fatty acids used reproduces similar changes in the thermal stability of F1 histone-DNA complex as phospholipids. The type of interaction of phospholipids with the F1 histone-DNA complex is analyzed, and the involvement of phospholipids in DNA replication in vivo is discussed.

Inhibition of cell division in Escherichia coli K-12 by the R-factor R1 and copy mutants of R1

The effect of the copy number of plasmid R1drd-19 on cell division of Escherichia coli K-12 was studied in populations growing as steady-state cultures at different growth rates, the growth rate being varied by use of different carbon sources. The plasmid copy number was also varied by using copy mutants of the R-factor. The mean cell size was larger in populations carrying an R-factor than in R-factorless populations, an effect that was more pronounced at low growth rates and in populations carrying R-factor copy mutants. The increased cell size was due to formation of elongated cells in a fraction of the population and to an increase in the diameter of all cells. The majority of the cells divided at a normal cell length, but the presence of an R-factor caused some cells to elongate, probably by the uncoupling of chromosome replication and cell division. This can be explained as a competition between the chromosome and plasmid replicons for some replication factor(s), presumably acting on both initiation and elongation of replication. The formation of elongated cells was a reversible process, but occasionally some of the elongated cells reached lengths 20 times that of newborn cells. If cell division did not occur at the normal cell size, the septum was not formed until the cell size was four times that of a newborn cell. When an elongated cell divided, it usually formed a polar septum, thus producing a newborn cell of normal cell length. The ability of plasmid-containing cells to omit one cell division but to retain the capacity of dividing one mass doubling later is compatible with a mechanical model for septum formation and cell division.

Inhibition of an early event in the cell division cycle of Escherichia coli by FL1060, an amidinopenicillanic acid

Analysis of exponential and synchronous cultures of Escherichia coli B/r after the addition of FL1060 indicates a block point for division by this agent some 15 to 20 min before the end of the preceding cell division cycle, a time corresponding to the beginning of the C period of the cell division cycle. Morphological examination of FL1060-treated synchronous cultures of E. coli /r was consistent with inhibition by FL1060 of a very early event in the cell division cycle. This event appears to be essential for normal cell surface elongation in a rod configuration. Temporary treatment of synchronous cultures of E. coli B/r with FL1060 resulted in division delay, the extent of which was a function of the duration of exposure to FL1060. However, even after relatively long times of FL1060 treatment the delayed divisions were still synchronous. Although FL1060 had no direct effect on deoxyribonucleic acid (DNA) synthesis, the synchronous delayed division occuring after temporary treatment with FL1060 were accompanied by a delay in the attainment of resistance of cell division to inhibitors of DNA, ribonucleic acid, and protein synthesis. These results suggest aht an FL1060-sensitive event initiates at the beginning of the C period of the cell division cycle of E. coli and is responsible for normal cell elongation. This cell elongation pathway procedes independently of DNA synthesis, but there is an interaction between this pathway and termination of a round of DNA replication in which a normal rod configuration is necessary to allow a signal for cell division to be generated upon completion of DNA replication.