Cell division of the Escherichia coli lon- mutant

Inactivation of Cell Division Protein FtsZ by SulA Makes Lon Indispensable for the Viability of a ppGpp0 Strain of Escherichia coli

The modified nucleotides (p)ppGpp play an important role in bacterial physiology. While the accumulation of the nucleotides is vital for adaptation to various kinds of stress, changes in the basal level modulates growth rate and vice versa. Studying the phenotypes unique to the strain lacking (p)ppGpp (ppGpp(0)) under overtly unstressed growth conditions may be useful to understand functions regulated by basal levels of (p)ppGpp and its physiological significance. In this study, we show that the ppGpp(0) strain, unlike the wild type, requires the Lon protease for cell division and viability in LB. Our results indicate the decrease in FtsZ concentration in the ppGpp(0) strain makes cell division vulnerable to SulA inhibition. We did not find evidence for SOS induction contributing to the cell division defect in the ppGpp(0) Δlon strain. Based on the results, we propose that basal levels of (p)ppGpp are required to sustain normal cell division in Escherichia coli during growth in rich medium and that the basal SulA level set by Lon protease is important for insulating cell division against a decrease in FtsZ concentration and conditions that can increase the susceptibility of FtsZ to SulA.

IMPORTANCE

The physiology of the stringent response has been the subject of investigation for more than 4 decades, with the majority of the work carried out using the bacterial model organism Escherichia coli. These studies have revealed that the accumulation of (p)ppGpp, the effector of the stringent response, is associated with growth retardation and changes in gene expression that vary with the intracellular concentration of (p)ppGpp. By studying a synthetic lethal phenotype, we have uncovered a function modulated by the basal levels of (p)ppGpp and studied its physiological significance. Our results show that (p)ppGpp and Lon protease contribute to the robustness of the cell division machinery in E. coli during growth in rich medium.

Thymine Starvation and Single-Strand Breaks in Chromosomal Deoxyribonucleic acid of Escherichia coli

Single-strand breaks, as measured by the McGrath and Williams procedure, occur in chromosomal deoxyribonucleic acid of Escherichia coli cells during thymine starvation.

Proteolysis and modulation of the activity of the cell division inhibitor SulA in Escherichia coli lon mutants

Intracellular accumulation of the inducible cell division inhibitor SulA is modulated by proteases that ensure its degradation, namely, the Lon protease and another ATP-dependent protease(s). Lon- cells are UV sensitive because SulA is stable. We asked whether these ATP-dependent proteases are more active when lon cells are grown at high temperature or in synthetic medium since these conditions decrease the UV sensitivity of lon cells. We found that these growth conditions have no direct effect on Lon-independent degradation of SulA. They may, instead, decrease the SulA-FtsZ interaction.

The Escherichia coli cell division mutation ftsM1 is in serU

The ftsM1 mutation is believed to be in a gene implicated in the regulation of cell division in Escherichia coli because it displayed the lon mutation phenotypes. In this study, we show that this mutation is located in serU, a gene which codes for tRNA(Ser)2, and has the phenotypes of the serU allele supH. Both ftsM1 and supH suppressed the leuB6 and ilvD145 missense mutations, and both conferred temperature and UV light irradiation sensitivity to the harboring cells. Cells which carried the ftsM1 mutation or the supH suppressor had very low colony-forming abilities on salt-free L agar, and this phenotype was almost completely abolished by the presence of plasmids bearing the ftsZ+ gene. Furthermore, sensitivity of the mutant cells to UV irradiation was also markedly diminished when they carried a ftsZ+-bearing plasmid. These results suggest that supH-containing cells have reduced FtsZ activities, in accordance with their displaying the phenotypes of the lon mutant cells. The possibility that ftsM1 (supH) is functionally involved in the biosynthesis of a specific protein which affects cell division is discussed.

Regulation of cell division in Escherichia coli K-12: probable interactions among proteins FtsQ, FtsA, and FtsZ

In Escherichia coli, the FtsQ, FtsA, and FtsZ proteins are believed to play essential roles in the regulation of cell division. Of the three proteins, FtsZ has received the most attention, particularly because of its interactions with SfiA. Double mutants which carry mutations located in the ftsQ, ftsA, or ftsZ gene in combination with the lon-1 mutation were constructed. In the presence of the lon-1 mutation, which is known to stabilize SfiA, the ftsQ1 mutant cells were not capable of forming colonies on a rich agar medium, whereas mutant cells harboring either one of the mutations grew well on this medium. Examination of lon-1 fts double-mutant cells for sensitivity to UV light revealed that those carrying the ftsA10 allele were resistant. It was also observed that in the presence of a multicopy plasmid containing a wild-type ftsZ gene, the ftsQ1 mutant filamented markedly following a nutritional shift-up and that the division rate of ftsZ84 mutant cells was slightly reduced when they harbored a wild-type ftsQ-containing plasmid. The possibility that the Fts proteins are interacting with one another and forming a molecular complex is discussed.

Identification of new cell division genes in Escherichia coli by using extragenic suppressors

To facilitate the analysis of the cell division control apparatus in Escherichia coli, we studied extragenic suppressor mutations of a previously characterized temperature-sensitive division mutation, ftsM1. Cells of strain GD40 which harbor this mutation were spread on agar plates and incubated at 42 degrees C, and the surviving cells were analyzed for the presence of a suppressor mutation. One group of suppressed mutants had acquired a new mutation which, by conjugation, was found to be located in the 30- to 40-min region of the E. coli genetic map. The other group comprised revertants carrying a suppressor which appeared to map between thr and leu. This suppressor gene, called sftA, was cloned with a mini-Mu-derived in vivo cloning system by selection for suppression of temperature sensitivity in GD40 cells. Subsequent subcloning of a fragment of the chromosomal DNA from the mini-Mu plasmid into pBR325 resulted in the delineation of the suppressor gene on a 1.8-kilobase XhoI-PvuI fragment. A strain, CV514, which does not express the temperature sensitivity phenotype of the ftsM1 mutation, was found to harbor a natural suppressor of this mutation. UV sensitivity, another known phenotype of the ftsM1 mutation, was also corrected by the presence of the sftA suppressor in the cell. Thus, the characterization of extragenic suppressors may allow the identification of new genes involved in the control of cell division.

Regulation of cell division in Escherichia coli: properties of new ftsZ mutants

Cells of Escherichia coli which produce high levels of the sfiA protein are UV-sensitive and filament extensively. It has been postulated that the sfiA protein is a division inhibitor which interacts with the ftsZ protein (formerly called sfiB or sulB) leading to cell division arrest. Under certain conditions, a similar division inhibition is observed with cells harboring a mutationally altered tsM allele, another division gene which was postulated to code for a division inhibitor or a controlling effector thereof (Drapeau et al. (1984). In this communication, we report on the properties of ftsZ mutants isolated under conditions which brought no selective pressure. These mutants have either an increased sensitivity to UV irradiation or filament drastically following a nutritional shift-up, or both, or even cannot grow in a rich medium. They presumably possess a ftsZ protein which responds more readily to the inhibitory action of the wild type sfiA or the mutationally altered tsM1 protein since the phenotypic expressions associated with the mutations are not observed in the presence of the sfiA11 mutation or are amplified when the ftsZ mutant cells harbor the tsM1 allele. These results further support earlier suggestions that sfiA modulates ftsZ activity and establish tsM as an additional regulatory element thereof. In addition, it is shown that E. coli strain B is a naturally occurring ftsZ mutant.

Regulation and SOS induction of division inhibition in Escherichia coli K12

When Escherichia coli is subjected to treatments that damage DNA or perturb DNA replication considerable cell filamentation occurs. It has been postulated that this phenomenon is associated with the presence of a division inhibitor induced coordinately with the SOS functions. The role of this induction would be to delay septation during DNA repair to prevent the formation of DNAless cells. In this communication, we present evidence for such a division inhibitor based on the properties of a division mutant which is hyperactive in the septation delay. Cells of this mutant filament extensively after a nutritional shift-up, have drastically reduced colony-forming abilities on a rich medium but not on a minimal medium following treatment with ultraviolet radiation and, are deficient in the lysogenization of phage lambda; phenotypes which are characteristic of but expressed to a much lower extent in another type of division mutant called Ion. Cells harboring the division mutation plus either one of the lexA mutant alleles, spr-51 or tsl-1, are filamentous suggesting that they are permanently derepressed for division inhibition. These results are in agreement with models that assign the regulation of cell division to a division inhibitor which is regulated by the lexA repressor protein.

Role of the sfiA-dependent cell division regulation system in Escherichia coli

Several authors have suggested that the SOS-associated (sfiA-dependent) system of division inhibition, normally induced by perturbations of DNA replication, also regulates steady-state (unperturbed) cell division. The present work shows that mean cell mass is identical in sfiA+ and sfiA mutant cultures during steady-state growth, that mass adjustment is identical after shift up, that sfiA expression is not induced by shift up, and that a sfiA mutation does not cause aberrant chromosome segregation.

ATP hydrolysis-dependent protease activity of the lon (capR) protein of Escherichia coli K-12

Mutations in the lon (capR) gene result in multiple phenotypes, one of which is the failure to degrade abnormal and normal proteins (Deg-). Previous work with partially purified preparations showed that the lon (capR) gene product is a 94,000-dalton polypeptide with an affinity for nucleic acids. The lon (capR) protein has now been highly purified and is demonstrated to have an ATP-dependent protease activity. The enzyme hydrolyzed 3H-labeled alpha-casein into trichloroacetic acid-soluble forms in Tris buffer containing Mg2+ and ATP. The reaction has a pH optimum of 8.5 and ATP was the preferred nucleotide. CTP and UTP could substitute for ATP (75% and 67%, respectively) but GTP, ADP, AMP, cyclic AMP, and PPi could not. Proteolysis by the lon (capR) protein required ATP hydrolysis. Nonhydrolyzable analogs of ATP and CTP did not promote casein cleavage. When low concentrations of ATP were used, proteolysis stopped as the ATP pool was depleted. Casein stimulated lon (capR) ATPase activity, and the products were ADP and inorganic phosphate in equimolar amounts. No protein kinase activity was detected. The DNA-binding activity, present in partially pure preparations, was retained in the purified protein. The gene product purified from a lon nonsense mutant that exhibits the Deg- phenotype (capR9), lacked both the ATP-dependent protease and ATPase activities, though it retained DNA-binding activity. Absence of an ATP-dependent protease activity could account for many of the pleiotropic effects observed in lon mutants.

Cloning of gene lon (capR) of Escherichia coli K-12 and identification of polypeptides specified by the cloned deoxyribonucleic acid fragment

A mutation in the lon (capR) gene of Escherichia coli K-12 results in overproduction of capsular polysaccharide and increased sensitivity to ultraviolet and ionizing radiations. The lon (capR) gene deoxyribonucleic acid was cloned from a new F' factor. The new plasmids, designated pBZ201 and pBZ203, (i) contained an additional 8.2-megadalton (Md) EcoRI fragment that had the same mobility as one of the EcoRI fragments of the F', and (ii) conferred repression of capsular polysaccharide synthesis and repression of sensitivity to ultraviolet radiation in a bacterial transformation experiment with capR mutant recipient strains. A capR9 mutant plasmid, pBZ201M9, was also isolated and conferred expression of mucoidy and ultraviolet sensitivity to a capR(+) (lon(+)) strain, indicating that the capR9 allele was dominant. Plasmids pBZ201M80, pBZ201M9-INSA, and pBZ201M9-INSB were characterized by transformation as containing recessive capR mutant alleles. Heteroduplex analyses and agarose gel electrophoresis of restriction endonuclease digests of plasmid DNA preparations revealed that (i) pBZ201M9-INSA and pBZ201M9-INSB each contains a 0.5-Md insertion (probably IS1) in the cloned DNA fragment at the same site, and (ii) pBZ201 and pBZ203, both capR(+) plasmids, contain the same 8.2-Md fragment cloned in opposite orientations with respect to the cloning vehicle, pSC101. Plasmid-specified polypeptides were determined by using strain CSR603 maxicells containing each plasmid. Two new polypeptides were coded by the lon(+) (capR(+)) 8.2-Md DNA fragment: Z1, 94 kilodaltons (94K), and Z2, 67K. The maxicells containing recessive capR mutant plasmids were deficient only in synthesis of the 94K polypeptide, and the dominant (capR9) mutant plasmid specified 5 to 10 times more of the 94K polypeptide than the maxicells containing the capR(+) plasmid. Other data indicated that the capR9-specified "94K polypeptide" was not identical to the capR(+)-specified "94K polypeptide." Thus the altered mutant polypeptide was synthesized in increased quantities, suggesting a defective mode of autogenous regulation for the capR9 polypeptide and effective autogenous regulation of the capR(+) polypeptide.

Dissociation of tsl-tif-induced filamentation and recA protein synthesis in Escherichia coli K-12

In Escherichia coli, expression of the tif-1 mutation (in the recA gene) induces the "SOS response" at 40 degrees C, including massive synthesis of the recA(tif) protein, cell filamentation, appearance of new repair and mutagenic activities, and prophage induction. Expression of the tsl-1 mutation (in the lexA gene) induces massive synthesis of the recA protein and cell filamentation at 42 degrees C, although other SOS functions are not induced. In this paper we show that the septation inhibition induced in tif and tsl strains at 42 degrees C is not due to the presence of a high concentration of recA protein since (i) no recA mutants (</=10(-8)) were isolated among thermoresistant nonfilamenting revertants of a tif-1 tsl-1 strain, (ii) in a tsl-1 zab-53 strain, only the low basal level of recA protein was synthesized at 42 degrees C, yet cell division was inhibited, and (iii) in a tsl-1 recA99 (amber) strain, no recA protein could be detected at 42 degrees C, yet cell division was inhibited. Among suppressors of tsl-tif-induced lethality are mutations at a locus which we call infB, located in the 66- to 83-min region. The infB1 mutation confers a highly pleiotropic phenotype, which is suggestive of a regulatory defect; it suppressed tsl-tif-induced filamentation but not recA protein synthesis, it did not suppress ultraviolet-induced filamentation (in a lon derivative), and it reduced but did not abolish tif-mediated induction of lambda prophage and bacterial mutagenesis. The dissociation of tsl-tif-induced septation inhibition and recA protein synthesis in the tif-1 tsl-1 infB1 strain suggests that the control of SOS filamentation may not be strictly identical to the control of recA protein synthesis.

Gene lon and plasmid inheritance in Escherichia coli K-12

Lon- mutants of Escherichia coli K-12 are deficient in the inheritance of F-plasmids by conjugation. This deficiency is distinct from the conjugation deficiency caused by overproduction of capsular polysaccharide which decreases donor-recipient pair formation.

Coordinate regulation by iron of the synthesis of phenolate compounds and three outer membrane proteins in Escherichia coli

The biosynthesis of the low-molecular-weight iron carrier enterochelin and of three outer membrane polypeptides appears to be coordinately regulated by the amount of cell-associated iron in Escherichia coli K-12. Measurements of iron acquisition made throughout the growth cycle in iron-deficient media indicate that a very rapid accumulation of iron occurs in the first 2 h of growth; there is comparatively little iron uptake during exponential growth, which results in a gradual decrease in the cellular iron content with each generation. When this level falls below 400 ng of iron per mg (dry weight) of cells, there is a simultaneous onset of synthesis of the three outer membrane polypeptides and of enterochelin. This coordinate regulation was also observed in cells able to transport iron actively using only citrate as an iron-carrier.

Genetic control of radiation sensitivity and DNA repair in Neurospora

Radiation sensitivity in the fungus Neurospora crassa is under the control of at least eight distinct loci and is also affected by cytoplasmic factors. Although radiation-sensitive mutants which affect inter- or intragenic meiotic recombination have not been isolated, mutants which are defective in the repair of pyrimidine dimers have been found. Evidence from both mutational and biochemical studies shows that Neurospora has an excision-repair system for pyrimidine dimers which is very similar to the one found in Escherichia coli. Wild-type strains excise dimers, but two mutants, uvs2 and upr1, are UV sensitive and excision defective. Like the E. coli excision-defective mutants, the Neurospora mutants show a greatly increased frequency of UV-induced mutation at low UV doses, and they do not affect recombination. However, they differ from the E. coli mutants in being significantly more sensitive to ionizing radiation than wild-type strains. A third mutant, uvs6, resembles the DNA polymerase-I-negative mutants of E. coli. It is sensitive to both UV and X-irradiation, has a wild-type pattern of UV-induced mutation, and increases spontaneous deletion frequencies. Its polymerases have not been examined. The high frequency of UV-induced mutation in excision-defective strains suggests that a "mutation prone" system of DNA repair exists in Neurospora. This is supported by the ppoperties of the uvs3 strain, which shows no UV-induced mutation. Like postreplication-repair-defective E. coli mutants, it is UV and ionizing radiation sensitive and sensitive to both monofunctional and bifunctional alkylating agents. This mutant is sterile. As expected, the double mutant uvs3 upr1 strain is much more sensitive to UV than either single-mutant strain. Two other loci, muc2 and gs6, may affect DNA repair. Mutations at the five remaining loci, uvs1, uvs4, uvs5, gs3, and gs20, lead to a constellation of properties unlike those of any DNA-repair-deficient E. coli mutant. The occurrence of these mutations could mean that other DNA repair systems exist in Neurospora, or, like the lon mutants of E. coli, they might indicate that cell sensitivity to radiation damage can be increases in other ways.

Control of cell division in bacteria

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Review lecture on the growth and form of a bacterial cell

The size, shape and composition of cells in cultures of bacteria maintained in steady states of exponential growth depend on the cultural conditions employed. Important factors influencing these parameters are the growth rate of the culture and the transit time of replication forks from one end of a chromosome to the other. The considerable progress which has been made in the last ten years in elucidating the rules governing the form and composition of cells of Escherichia coli as a function of growth rate and transit time is outlined in the Review.

Bacterial cell division regulation: lysogenization of conditional cell division lon - mutants of Escherichia coli by bacteriophage

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

Ultraviolet-sensitive mutator strain of Escherichia coli K-12

An ultraviolet (UV)-sensitive mutator gene, mutU, was identified in Escherichia coli K-12. The mutation mutU4 is very close to uvrD, between metE and ilv, on the E. coli chromosome. It was recessive as a mutator and as a UV-sensitive mutation. The frequency of reversion of trpA46 on an F episome was increased by mutU4 on the chromosome. The mutator gene did not increase mutation frequencies in virulent phages or in lytically grown phage lambda. The mutU4 mutation predominantly induced transitional base changes. Mutator strains were normal for recombination and host-cell reactivation of UV-irradiated phage T1. They were normally resistant to methyl methanesulfonate and were slightly more sensitive to gamma irradiation than Mut(+) strains. UV irradiation induced mutations in a mutU4 strain, and phage lambda was UV-inducible. Double mutants containing mutU4 and recA, B, or C were extremely sensitive to UV irradiation; a mutU4 uvrA6 double mutant was only slightly more sensitive than a uvrA6 strain. The mutU4 uvrA6 and mutU4 recA, B, or C double mutants had mutation rates similar to that of a mutU4 strain. Two UV-sensitive mutators, mut-9 and mut-10, isolated by Liberfarb and Bryson in E. coli B/UV, were found to be co-transducible with ilv in the same general region as mutU4.

Bacterial cell division regulation: physiological effects of crystal violet on Escherichia coli lon + and lon - strains

The Escherichia coli lon(-) mutants apparently are defective in the ability to recommence cell division after temporary periods of deoxyribonucleic acid (DNA) synthesis inhibition. They are also more susceptible to cell division inhibition by the basic dye, crystal violet (CV), than are lon(+) strains. In enriched broth, the lon(+) strain continued to grow and divide in the presence of CV, but lon(-) cell division was inhibited and filamentous growth resulted. In a supplemented minimal medium containing CV, lon(-) cell division was only temporarily inhibited. There was no detectable specific effect on DNA synthesis, although CV slowed the rate of mass increase in both media. Trichloroacetic acid-insoluble lipid synthesis was preferentially inhibited in both lon(+) and lon(-) strains. In CV-containing enriched broth, diaminopimelic acid incorporation into trichloroacetic acid-insoluble compounds occurred at a rate greater than the rate of mass increase in both lon(+) and lon(-) strains. In a CV-containing supplemented minimal medium, diaminopimelic acid was incorporated to a greater extent by lon(-) cells than by lon(+) cells.