Resistance to trifluoroperazine, a calmodulin inhibitor, maps to the fabD locus in Escherichia coli

A mutant, tfpA1, resistant to the calmodulin inhibitor trifluoroperazine (TFP) at 30°C, was isolated in Escherichia coli. The mutant showed a reduced growth rate at 30°C and was temperature sensitive (ts) at 42°C for growth, forming short filaments. The mutation was mapped to the 24 min region of the chromosome and the gene was cloned by complementation of the is defect. Subsequent subcloning, complementation analysis, marker rescue mapping and sequencing, identified tfpA as fabD, encoding the 35 kDa, malonyl-coenzyme A transacylase (MCT) enzyme, required for the initial step in the elongation cycle for fatty acid biosynthesis. Resistance to TFP may result from altered permeability of the cell envelope, although the mutant remained sensitive to other calmodulin inhibitors and to other antibacterial agents. Alternatively, resistance may be more indirect, resulting from alterations in intracellular Ca⁺⁺ levels which affect the activity of the TFP target in some way.     

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

Summary 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° C compared to 8.6% after 2 h at 45° C). The probability of a minicell producing division in double mutant clones is essentially the same at 30° C and during the initial 2–3 h growth at 45° C at which time lysis begins. Residual division at 45° C is attributable to processes initiated at 30° 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.     

A multicopy suppressor ofnin1-1 of the yeastSaccharomyces cerevisiae is a counterpart of theDrosophila melanogaster diphenol oxidase A2 gene,Dox-A2

NIN1 is an essential gene for growth of the yeastSaccharomyces cerevisiae and was recently found to encode a component of the regulatory subunit of the 26S proteasome. Thenin1-1 mutant is temperature sensitive and its main defect is in G₁/S progression and G₂/M progression at non-permissive temperatures. One of the two multicopy suppressors ofnin1-1, SUN2 (SUppressor of Nin1-1), was found to encode a protein of 523 amino acids whose sequence is similar to those ofDrosophila melanogaster diphenol oxidase A2 and the mouse mast-cell Tum^– transplantation antigen, P91A. The C-terminal half of Sun2p was found to be functional as Sun2p at 25° C, 30° C, and 34° C but not at 37° C. The open reading frame (ORF) of theDrosophila diphenol oxidase A2 gene (Dox-A2) was obtained from a lambda phage cDNA library using the polymerase chain reaction technique. TheDox-A2 ORF driven by theTDH3 promoter complemented the phenotype of a strain deleted forsun2. ThisDox-A2-dependent strain was temperature sensitive and accumulated dumb-bell-shaped cells, with an undivided nucleus at the isthmus, after temperature upshift. This morphology is similar to that ofnin1-1 cells kept at a restrictive temperature. These results suggest thatSUN2 is a functional counterpart ofDox-A2 and that these genes play a pivotal role in the cell cycle in each organism.     

Effect of septum-initiation mutations on sporulation and competent cell formation in Bacillus subtilis

Summary Sporulation and competent cell formation have been studied in four Bacillus subtilis strains, carrying septum-initiation mutations of different loci, div-31, div-341, div-12 and div-355 which exhibit filamentous growth at 45° C. The div-31 mutant was found to be defective in competence development at 30°–40°C whereas the div-12 mutant was affected only slightly. The div-341 and div-355 mutants showed lower competence, particularly at the higher temperatures. The four div mutant strains all showed poor sporulation at higher temperatures compared to the wild-type strain. We propose that some of the initial steps of septation are involved both in sporulation (possibly in forespore septum formation) and in competent cell formation and that these two processes share certain common features distinct from those in vegetative cell division.     

Isolation and initial characterization of a Schizosaccharomyces pombe mutant exhibiting temperature-dependent radiation sensitivity due to a mutation in a previously unidentified rad locus

Summary We have isolated a mutant of the yeast Schizosaccharomyces pombe which exhibits sensitivity to UV light when grown at either 30° or 37°C, as compared to the parental wild-type strain. This increased sensitivity is more pronounced when cells are grown at 37°C. The mutant is also sensitive to 18 MeV electrons at the high temperature. Tetrad analysis of spores generated by crossing the mutant and a Rad⁺ strain revealed that sensitivity to both types of radiation cosegregate 2:2, relative to wild-type resistance, indicating that a single altered chromosomal locus is responsible for the radiation sensitivities observed. In addition, analysis of spores resulting from crosses between the mutant and all other known S. pombe rad mutants indicates that the temperature-dependent sensitivity described in this report is mediated by a mutation in a previously unidentified rad locus.     

The wild-type allele of tonB in Escherichia coli is dominant over the tonB1 allele, encoding TonBQ160K, which suppresses the btuB451 mutation

The entire coding sequence of the tonB gene, except for nine codons at the 3 end, was deleted from the chromosome of Escherichia coli. Introduction of the btuB451 suppressor mutant tonB1 into the chromosome of such a tonB deletion strain showed that the tonB1 allele was active as a suppressor in a single copy at 37° C and 42° C but not at 28° C. No temperature dependence was seen when FepA- or FhuA-dependent activities of the tonB1 gene product (TonB_Q160K) were tested. The btuB451 suppressor activity of tonB1 was inhibited by the simultaneous presence within the cells of the tonB ⁺ allele on a multicopy plasmid. This represents the first case of dominance among different tonB alleles. Inhibition of suppression was abolished by overexpression of the btuB451-encoded receptor protein. Competition for binding of TonB⁺ and TonB_Q150K to ExbB was excluded as the cause of dominance. Based on our data we conclude that competition for binding of TonB ⁺ and TonB_Q160K to the btuB451 gene product is the reason for the observed dominance. The implications of these findings for the mechanism of btuB451 suppression by tonB1 are discussed.     

High-temperature cultivation and 5′ mRNA optimization are key factors for the efficient overexpression of thermostable Deinococcus geothermalis purine nucleoside phosphorylase in Escherichia coli

Overexpression of genes from thermophiles in Escherichia coli is an attractive approach towards the large-scale production of thermostable biocatalysts. However, various factors can challenge efficient heterologous protein expression – one example is the formation of stable 5′ mRNA secondary structures that can impede an efficient translation initiation.In this work, we describe the expression optimization of purine nucleoside phosphorylase from the thermophilic microbe Deinococcus geothermalis in E. coli. Poor expression levels caused by stable secondary 5′ mRNA structure formation were addressed by two different approaches: (i) increasing the cultivation temperature above the range used typically for recombinant protein expression and (ii) optimizing the 5′ mRNA sequence for reduced secondary structures in the translation initiation region.The increase of the cultivation temperature from 30 °C to 42 °C allowed a more than 10-fold increase of activity per cell and optimizing the 5′ mRNA gene sequence further increased the activity per cell 1.7-fold at 42 °C. Thus, the combination of high-temperature cultivation and 5′ sequence optimization is described as an effective approach to overcome poor expression levels resulting from stable secondary 5′ mRNA structure formation. We suggest that this method is especially suitable for improving the expression of proteins derived from thermophiles in E. coli.     

The relation of the genes envA and ftsA in Escherichia coli

Summary The sequence of three genes involved in cell division in E. coli has been determined to be ftsA-envA-azi by three-point transduction experiments. An ftsA envA double mutant strain forms filaments at the restrictive temperature of 42° C, and not chains, but, like the chain forming envA parent strain, is hypersensitive to rifampicin.     

recA Gene dependence of replication of the Escherichia coli chromosome initiated by plasmid pUC13 integrated at predetermined sites

Summary Plasmid pUC13 was used to clone DNA fragments of known sites from the chromosome of Escherichia coli. Each chimeric plasmid was introduced individually into the same dnaA46 mutant strain LC381 and suppressive integration (Sin) strains were selected. By means of cotransduction the null mutation recA56 was then introduced into each Sin strain and growth of each recA56 derivative at 42° C was scored. Strains that failed to grow at 42° C depended upon the recA gene for replication. Three factors were shown to limit the viability of LC381 harboring different chimeric plasmids and affect the degree of recA gene dependence of chromosome replication in the Sin strains at 42° C. It is suggested that these three constraints are the consequence of the organization of the E. coli chromosome, particularly the unique ability of terC to retard the progression of replication forks. Two classes of hypotheses concerning the function of the recA gene are considered.     

DNA supercoiling in a thermotolerant mutant ofEscherichia coli

A spontaneously occurring, nalidixic acid-resistant (Nal^R), thermotolerant (T/r) mutant ofEscherichia coli was isolated. Bacteriophage P1-mediated transduction showed that Nal^R mapped at or neargyr A, one of the two genes encoding DNA gyrase. Expression ofgyrA ⁺ from a plasmid rendered the mutant sensitive to nalidixic acid and to high temperature, the result expected for alleles mapping ingyrA. Plasmid linking number measurements, made with DNA from cells grown at 37° C or shifted to 48° C, revealed that supercoiling was about 12% less negative in the T/r mutant than in the parental strain. Each strain preferentially expressed two different proteins at 48° C. The genetic and supercoiling data indicate that thermo-tolerance can arise from an alteration in DNA gyrase that lowers supercoiling. This eubacterial study, when. coupled with those of archaebacteria, suggests that DNA relaxation is a general aspect of thermotolerance.     

OriC plasmids do not affect timing of chromosome replication in Escherichia coli K12

Summary The variability of the time interval between successive rounds of chromosome replication was estimated by density-shift experiments, by measuring the conversion of heavy DNA to hybrid density and light DNAs upon transfer of a steady-state culture growing in medium with [¹³C]glucose and ¹⁵NH₄Cl to medium with light isotopes. The coefficient of variation (CV%) for the interreplication time of the Escherichia coli K12 chromosome was found to be 17%, i.e. similar to that for interdivision time. The presence of additional copies of oriC in the cell on a high copy number plasmid did not increase the CV of interreplication time. It is concluded that a single rate-limiting event is unlikely to time the initiation of chromosome replication. The regulation of initiation at oriC and the coordination with cell division is discussed.     

Roles of Escherichia coli heat shock proteins DnaK, DnaJ and GrpE in mini-F plasmid replication

Summary A subset of Escherichia coli heat shock proteins, DnaK, DnaJ and GrpE were shown to be required for replication of mini-F plasmid. Strains of E. coli K12 carrying a missense mutation or deletion in the dnaK, dnaJ, or grpE gene were virtually unable to be transformed by mini-F DNA at the temperature (30° C) that permits cell growth. When excess amounts of the replication initiator protein (repE gene product) of mini-F were provided by means of a multicopy plasmid carrying repE, these mutant bacteria became capable of supporting mini-F replication under the same conditions. However, the copy number of a high copy number mini-F plasmid was reduced in these mutant bacteria as compared with the wild type in the presence of excess RepE protein. Furthermore, mini-F plasmid mutants that produce altered initiator protein and exhibit a very high copy number were able to replicate in strains deficient in any of the above heat shock proteins. These results indicate that the subset of heat shock proteins (DnaK, DnaJ and GrpE) play essential roles that help the functioning of the RepE initiator protein in mini-F DNA replication.     

An autecological study of the potentially toxic dinoflagellate Alexandrium affine isolated from Vietnamese waters

The potentially toxic dinoflagellate species Alexandrium affine isolated from Ha Long Bay (Tonkin Gulf), Vietnam was cultured and maintained for morphological, physiological and toxicological studies. Classical morphological examinations including plate pattern were in good agreement with the international nomenclature of the species. The fine structure of A. affine, including morphology of its developmental stages during vegetative and sexual reproduction was found to be typical of other species in the genus. Two general trends in growth of A. Affine from Vietnamese waters were apparent: (1) growth rates were low at low salinities (10 and 15 psu) in all experimental temperatures (21–27 °C); (2) growth rates were high at salinities 25, 30, and 35 psu in all temperatures. There were no significant differences in growth rates at different salinities at low temperature (21 °C), and the most significant difference in growth rate was between high temperature–high salinity and high temperature–low salinity. The optimum temperature and salinity for growth were 24 °C and 30 psu. Maximum division rates per day (0.5–0.7) were at salinities 30 and 35 psu and at temperatures 24 and 27 °C. But the best conditions for division rate were 21 and 24 °C at salinities 30 and 35 psu. Toxicity analyses indicated A. affine to be both toxic and non-toxic at certain times. In the former case, toxicity was very low, 2.28 fmol  per cell; the toxicity component of A. affine was compared with that of A. leei and the mussel Perna viridis including neoSTX, STX, and GTX₁–GTX₄.     

Physiological and genetical studies on a mutant of Salmonella typhimurium which is temperature-sensitive for DNA synthesis

Summary The following evidence supports the view that a temperature-sensitive mutant of Salmonella typhimurium (11 G) is defective in DNA synthesis initiation: a) the increment in DNA synthesis at 38° is abolished by prior completion of rounds of replication at 25°. b) The extent of the increment at 38° is greatly increased by prior growth in the presence of a DNA synthesis inhibitor. c) Density gradient centrifugation demonstrates that the terminal region of the chromosomes is preferentially replicated at 38°. d) Preferential replication of the chromosome origins occurs at 25° after a period at 38°. The parental strain in the presence of a DNA synthesis inhibitor or the mutant at 38° (without inhibitor) show increased sensitivity to the detergent sodium deoxycholate, possibly due to a secondary effect of DNA synthesis inhibition on membrane composition. Strains of 11 G carrying episomes transfer the episomes very poorly at 38° suggesting a rôle for the chromosomal initiation apparatus in episome transfer. Continued cell division of 11 G with the production of DNA-less cells at 38° is not due to the presence of a rec mutation and no secondary mutation responsible for such division has been found. The lesion maps close to leu on the Salmonella chromosome.     

Growth characteristics of flagellated cells of Phaeocystis pouchetii revealed by diel changes in cellular DNA content

The present study reports on effects of different light:dark periods, light intensities, N:P ratios and temperature on the specific growth rate of flagellated cells of Phaeocystis pouchetii in culture. The specific growth rate was estimated by diel changes in cellular DNA content. The cellular DNA content and cell cycle of flagellated cells of P. pouchetii are shown, and the importance of light:dark period in cell division is demonstrated. Diel patterns of the cellular DNA content showed that cell division was confined to the dark period. The cells dealt with more than one division per day by rapid divisions shortly after each other.The specific growth rates (μ_DNA) based on the DNA cell cycle model were in close agreement with specific growth rates (μ_Cell) determined from cell counts. The temperature affected the specific growth rates (multiple regression, p < 0.01) and were higher at 5 °C (μ ≤ 2.2 d⁻¹) than at 10 °C (μ ≤1.6 d⁻¹). Increasing the light:dark period from 12:12 h to 20:4 h affected the specific growth rate of P. pouchetii at the lower temperature tested (5 °C) (multiple regression, p < 0.01), resulting in higher specific growth rates than at 10 °C. At 10 °C, the effect of light:dark period was severely reduced. Neither light nor nutrients could compensate the reduction in specific growth rates caused by elevated temperature. The specific growth rates was not affected by the N:P ratios tested (multiple regression, p = 0.21). The experiments strongly suggest that the flagellated cells have a great growth potential and could play a dominating role in northern areas at increased day length.     

Alexandrium ostenfeldii growth and spirolide production in batch culture and photobioreactor

Growth and spirolide production of the toxic dinoflagellate Alexandrium ostenfeldii (Danish strain CCMP1773) were studied in batch culture and a photobioreactor (continuous cultures). First, batch cultures were grown in 450 mL flasks without aeration and under varying conditions of temperature (16 and 22 °C) and culture medium (L1, f/2 and L1 with addition of soil extract). Second, cultures were grown at 16 °C in 8 L aerated flat-bottomed vessels using L1 with soil extract as culture medium. Finally, continuous cultures in a photobioreactor were conducted at 18 °C in L1 with soil extract; pH was maintained at 8.5 and continuous stirring was applied.This study showed that A. ostenfeldii growth was significantly affected by temperature. At the end of the exponential phase, maximum cell concentration and cell diameter were significantly higher at 16 °C than at 22 °C. In batch culture, maximum spirolide quota per cell (approx. 5 pg SPX 13-desMeC eq cell⁻¹) was detected during lag phase for all conditions used. Spirolide quota per cell was negatively and significantly correlated to cell concentration according to the following equation: y = 4013.9x^−0.858. Temperature and culture medium affected the spirolide profile which was characterized by the dominance of 13,19-didesMeC (29–46%), followed by SPX-D (21–28%), 13-desMeC (21–23%), and 13-desMeD (17–21%).Stable growth of A. ostenfeldii was maintained in a photobioreactor over two months, with maximum cell concentration of 7 × 10⁴ cells mL⁻¹. As in batch culture, maximum spirolide cell quota was found in lag phase and then decreased significantly throughout the exponential phase. Spirolide cell quota was negatively and significantly correlated to cell concentration according to the equation: y = 12,858x^−0.8986. In photobioreactor, spirolide profile was characterized by higher proportion of 13,19-didesMeC (60–87%) and lower proportions of SPX-D (3–12%) and 13-desMeD (1.6–10%) as compared to batch culture.     

New killing system controlled by two genes located immediately upstream of the mukB gene in Escherichia coli

The nucleotide sequence was determined of the region upstream of the mukB gene of Escherichia coli. Two new genes were found, designated kicA and kicB (killing of cell); the gene order is kicB-kicA-mukB. Promoter activities were detected in the regions immediately upstream of kicB and kicA, but not in front of mukB. Gene disruption experiments revealed that the kicA disruptant was nonviable, but the kicB-disrupted mutant and the mutant lacking both the kicB and kicA genes were able to grow. When kicA disruptant cells bearing a temperature-sensitive replication plasmid carrying the kicA ⁺ gene were grown at 30° C and then transferred to 42° C, the mutant cells gradually lost colony-forming ability, even in the presence of a mukB ⁺ plasmid. Rates of protein synthesis, but not of RNA or DNA synthesis, fell dramatically during incubation at 42° C. These results suggested that the kicB gene encodes a killing factor and the kicA gene codes for a protein that suppresses the killing function of the kicB gene product. It was also demonstrated that KicA and KicB can function as a post-segregational killing system, when the genes are transferred from the E. coli chromosome onto a plasmid.     

Study on liquid-holding recovery in DEB-inactivated rad3 mutant of Saccharomyces cerevisiae

Summary Maximal liquid-holding recovery (LHR) of the DEB-treated rad3 mutant occurs at 30° C in buffer supplemented with glucose. Addition of cycloheximide (CHX) to the buffer, the increase in cell density above 2 × 10⁷/ml as well as lowering of temperature during liquid holding (LH) below 27° C decrease considerably the cell capacity for recovery. LHR does not take place at 5° C. No measurable DNA synthesis or degradation occurs in cells held in buffer alone, while addition of 0.02% glucose results in incorporation of radioactivity into DNA both of DEB-treated and control cells. Similarly, protein synthesis was observed only in cultures held in buffer supplemented with glucose. Cells transfered to growth medium directly after treatment complete one round of DNA replication and at least one division cycle, but further DNA replication and cell division are inhibited. Cells placed in growth medium after 5 days LH show an increased rate of DNA replication and cell division. Completion of the first posttreatment round of DNA replication in growth medium abolishes ishes the cell capacity for LHR. DEB treatment results in abnormal cell division of the rad3 mutant, giving colonies consisting of several cells, usually abnormal in shape, held together by common cell walls.     

Effect ofEscherichia coliIHF Mutations on Plasmid p15A Copy Number

Four isogenic strains (himAhimDdouble mutant,himAandhimDsingle mutants, and their wild type counterpart) harboringorip15A plasmid (pACYC184 or pACYC184Amp or pACYC177) show different copy numbers of that plasmid in the early stationary phase of cultivation. The copy number oforip15A plasmid increases about four times in thehimAhimDdouble (65–70 copies per cell) andhimDsingle mutant cells (50–56 copies per cell) and was almost the same inhimAmutant (17–18 copies per cell) and wild type cells (14–16 copies per cell). The results suggest that HimD can form homodimers, which are functionally competent for the regulation oforip15A plasmid copy number. Complementation experiments ofhimAhimDdouble mutant cells using plasmid carryinghimAandhimDgenes (pP_LhiphimA-5) confirm the effect of integration host factor (IHF) absence on increasing the copy number oforip15A plasmid (plasmid producing IHF complemented the defect of IHF mutant). The absence of IHF (usinghimAhimDdouble mutant as host) had no effect on the copy number of the pBR322 (oripMB1) plasmid.     

Studies on the regulation of initiation of chromosome replication in Escherichia coli.

The total initiation frequency of chromosome replication in Escherichia coli is dependent on two factors; the timing or time interval between successive initiations on an individual chromosome (initiation pace) and the number of individual chromosomes which are being replicated per cell. We have examined these parameters in a dnaA^ts, conditionally-lethal, “initiation mutant” of an E. coli K12 strain growing at different permissive temperatures. Our results indicate that at temperatures between 30 and 35 °C the gene product of the dnaA167 allele becomes limiting with respect to the number of replicating chromosomes per cell, which decreases from two at 30 °C to one at 35 °C. However, over this same temperature range it is clear that cell growth is balanced and the initiation pace, as determined from the growth rate, increases with temperature and is indistinguishable from that of the dnaA⁺ parent. These results demonstrate that one can alter the total initiation frequency independently of the initiation pace, indicating the involvement of at least two cellular components in the regulation of initiation. They also suggest that while the dnaA product may be involved in determining the total number of initiation events which can occur per cell per doubling time it does not control the timing or pace at which successive initiation events are triggered on each chromosome, i.e. it is not the “pace-maker” for initiation.