Effects of some platinum IV complexes on cell division of Escherichia coli.

A comparison was made of the effects of cis-tetrachlorodiaminoplatinum (IV) (cis-TCDPt), rans-TCDPt), and hexachloroplatinum (HCP) on growth and cell division of Escherichia coli strains D21 and D22. At or below 40 microgram/mL, cis-TCDPt inhibited cell division but not growth, DNA, or protein synthesis, although areas of increased electron density could be demonstrated in treated cells. In contrast, 40 microgram/mL of trans-TCDPt or HCP inhibited growth. Trans-TCDPt-treated cells developed condensed nucleoids; HCP-treated cells showed no obvious cytological changes to correlate with growth inhibition. Combination of cis-TCDPt with nalidixic acid, both at one-half the lowest filament-forming concentrations, resulted in formation of filaments, suggesting an additive effect. Combination of cis-TCDPt followed by ampicillin on E. coli B/r resulted in single bulges near the center of the filaments. Cis-TCDPt could therefore inhibit an initial step in the septation sequence, possibly at the level of the regulation of the hydrolytic enzymes. Whether cis-TCDPt exerts its effect by interreaction with DNA or with a membrane target is still uncertain.     

The mechanism of action of platinum(IV) complexes in ovarian cancer cell lines

The reduction potentials, lipophilicities, cellular uptake and cytotoxicity have been examined for two series of platinum(IV) complexes that yield common platinum(II) complexes on reduction: cis-[PtCl(4)(NH(3))(2)], cis,trans,cis-[PtCl(2)(OAc)(2)(NH(3))(2)], cis,trans,cis-[PtCl(2)(OH)(2)(NH(3))(2)], [PtCl(4)(en)], cis,trans-[PtCl(2)(OAc)(2)(en)] and cis,trans-[PtCl(2)(OH)(2)(en)] (en=ethane-1,2-diamine, OAc=acetate). As previously reported, the reduction occurs most readily when the axial ligand is chloride and least readily when it is hydroxide. The en series of complexes are marginally more lipophilic than their ammine analogues. The presence of axial chloride or acetate ligands results in a slighter higher lipophilicity compared with the platinum(II) analogue whereas hydroxide ligands lead to a substantially lower lipophilicity. The cellular uptake is similar for the platinum(II) species and their analogous tetrachloro complexes, but is substantially lower for the acetato and hydroxo complexes, resulting in a correlation with the reduction potential. The activities are also correlated with the reduction potentials with the tetrachloro complexes being the most active of the platinum(IV) series and the hydroxo being the least active. These results are interpreted in terms of reduction, followed by aquation reducing the amount of efflux from the cells resulting in an increase in net uptake.     

Induction of cell division in a temperature-sensitive division mutant of Escherichia coli by inhibition of protein synthesis.

Synchronous cells of the thermosensitive division-defective Escherichia coli strain MACI (divA) divided at the restrictive temperature (42 degrees C) if they were allowed to grow at 42 degrees C for a certain period before protein synthesis was inhibited by adding chloramphenicol (CAP) or rifampicin. The completion of chromosome replication was not required for such divA-independent division. Synchronous cells of strain MACI divided in the presence of an inhibitor of DNA synthesis, nalidixic acid, if they were shifted to 42 degrees C and CAP or rifampicin was added after some time; cells of the parent strain MC6 (div A+) treated in the same way did not divide. These data suggest that coupling of cell division to DNA synthesis depends on the divA function. The ability to divide at 42 degrees C, whether or not chromosome termination was allowed, was directly proportional to the mean cell volume of cultures at the time of CAP addition, suggesting that cells have to be a certain size to divide under these conditions. The period of growth required for CAP-induced division had to be at the restrictive temperature; when cells were grown at 30 degrees C, in the presence of nalidixic acid to prevent normal division, they did not divide on subsequent transfer to 42 degrees C followed, after a period, by protein synthesis inhibition. A model is proposed in which the role of divA as a septation initiator gene is to differentiate surface growth sites by converting a primary unregulated structure, with the capacity to make both peripheral wall and septum, to a secondary structure committed to septum formation.     

Escherichia coli mraR gene involved in cell growth and division.

The mraR gene, which has a coding frame of 363 bp and lies close to and upstream of the ftsI gene of Escherichia coli, is involved in both cell division and cell lysis. It is thought to function in regulating the two distinct steps of the cell cycle, as two different one-base mutations in this unique gene caused different phenotypical changes in the cell. Comparison of nucleotide sequences of the mutant type mraR DNAs with the wild type suggested that filamentation of the cell was caused by a mutation in the putative start codon, whereas lysis of the cell was caused by a mutation which led to a change of one internal glutamate residue to lysine.     

Reversibility of SOS-associated division inhibition in Escherichia coli.

In Escherichia coli the SOS response, induced by DNA-damaging treatments, includes two systems of cell division inhibition, SfiA and SfiC, which are thought to prevent cell division by interacting with the division protein FtsZ. It is shown here that SfiA-mediated division inhibition is readily reversible, even in the absence of de novo protein synthesis, suggesting that functional FtsZ molecules can be recovered from SfiA-FtsZ complexes. The action of SfiC, on the other hand, is essentially irreversible; induction by expression of the recA (Tif) mutation for 60 min results in division inhibition that continues for at least 180 min after the end of the induction period. An excess of the presumed target molecule FtsZ, furnished by a multicopy plasmid, suppresses the action of SfiA but not SfiC. Simultaneous induction of SfiA and SfiC results in irreversible division inhibition, showing that SfiC is epistatic to SfiA. The irreversibility of SfiC action is most readily accounted for by assuming that the SfiC product, unlike SfiA, is stable. The reversibility of SfiA action is slower in a lon mutant, in which the SfiA protein is partially stabilized. From the kinetics of division resumption in the absence of protein synthesis, we estimated the in vivo half-life of the SfiA protein to be 10 min in a lon+ strain and 170 min in a lon mutant.     

Detection of DNA strand breaks in Escherichia coli treated with platinum(IV) antitumor compounds

DNA strand breaks were observed in bacteria treated with Pt(IV) but not Pt(II) antitumor compounds by two methods. First, compounds which cause DNA strand breaks produced an SOS induction signal which was detected by a rapid bacterial assay. In addition, the capacity of these compounds to cut DNA in vivo was directly measured by agarose gel electrophoresis of pBR322 DNA extracted from bacteria treated with these drugs. cis-Diamminetetrachloroplatinum(IV) (cis-DTP) and cis-dichloro-trans-dihydroxo-cis-bis(isopropylamine)-platinum(IV) (iproplatin) produced strand breaks in both assays while cis-diamminedichloroplatinum(II) (cisplatin) did not. These results indicate that Pt(IV) antitumor complexes may cause DNA damage in vivo which is not produced by Pt(II) compounds.     

Inhibition of peroxidase, trypsin, and alpha-chymotrypsin by platinum (II) and platinum (IV) complexes

Effects of various complexes of platinum (II) and platinum (IV) on activities of trypsin, alpha-chymotrypsin, and peroxidase were compared. The platinum (II) complexes were found to inhibit these enzymes, though with variable efficiency. The platinum (IV) complexes at concentrations < or = 0.2 mM efficiently inhibited peroxidase but had no effect on the proteases. An enzymatic assay was developed to measure the most effective peroxidase inhibitor (cisplatin) at concentrations of 5-50 microM in the presence of fivefold excess of its isomer (transplatin).     

The effect of ionic strength on melting of DNA modified by platinum(II) complexes

Thermal denaturation of calf thymus DNA modified by antitumor cis-diamminedichloroplatinum(II) (cis-DDP) and by two related Pt(II) compounds which had been shown to be clinically inefective, viz. trans-diamminedichloroplatinum(II) (trans-DDP) or monodentate diethylenetriaminechloroplatinum(II) chloride {[Pt(dien)Cl)]Cl}, was studied by monitoring changes of absorbance at 260 nm. The melting of DNA platinated to different levels was investigated in neutral media containing varying concentrations of Na⁺. It has been shown that the ionic strength has a strong influence on the character and magnitude of changes in the melting temperature of DNA (T_m) induced by the platination. The modification of DNA by either platinum complex used in this work results in an increase of T_m if DNA melting is measured in media containing low Na⁺ concentrations (ca. 1 mM). This effect is reversed at higher Na⁺ concentrations. The concentration of Na⁺ at which this reversal occurs is, however, markedly lower for DNA modified by cis-DDP than for DNA modified by the other two platinum complexes. These results have been iterpreted to mean that at least three factors affect the thermal stability of DNA modified by the platinum(II) complexes: stabilization effects of the positive charge on the platinum moiety and of interstrand cross-links, and a destabilization effect of conformational distortions in DNA. Thus, in order to compare and interpret the melting behavior of DNA modified by different compounds, a great attention has to be paid to the composition of the medium in which the melting experiments are carried out.     

A new cell division operon in Escherichia coli

Summary At 76 min on theE. coli genetic map there is a cluster of genes affecting essential cellular functions, including the heat shock response and cell division. A combination ofin-vivo andin-vitro genetic analysis of cell division mutants suggests that the cell division genefts E is the second gene in a 3 gene operon. A cold-sensitive mutant, defective in the third gene, is also unable to divide at the restrictive temperature, and we designate this new cell division genefts X. Another cell division gene,fts S, is very close to, but distinct from, the 3 genes of the operon. Thefts E product is a 24.5 Kd polypeptide which shows strong homology with a small group of proteins involved in transport. Both thefts E product and the protein coded by the first gene (fts Y) in the operon have a sequence motif found in a wide range of heterogeneous proteins, including the Ras proteins of yeast. This common domain is indicative of a nucleotide-binding site.     

The cellular distribution and oxidation state of platinum(II) and platinum(IV) antitumour complexes in cancer cells

The cellular distribution of platinum in A2780 ovarian cancer cells treated with cisplatin and platinum(IV) complexes with a range of reduction potentials has been examined using elemental analysis (synchrotron radiation-induced X-ray emission). The cellular distribution of platinum(IV) drugs after 24 h is similar to that of cisplatin, consistent with the majority of administered platinum(IV) drugs being reduced. Micro-X-ray absorption near-edge spectra of cells treated with cisplatin and platinum(IV) complexes confirmed the reduction of platinum(IV) to platinum(II). In cells treated, the most difficult to reduce complex, cis,trans,cis-[PtCl₂(OH)₂(NH₃)₂], platinum(IV) was detected in the cells along with platinum(II). The observations are in accordance with the relative ease of reduction of the platinum(IV) complexes used and support the requirement of reduction for activation of platinum(IV) complexes.Abbreviations en ethane-1,2-diamine - GM growth medium - PBS phosphate buffered saline - RPMI Roswell Park Memorial Institute - SRIXE synchrotron radiation-induced X-ray emission - XAFS X-ray absorption fine structure - XANES X-ray absorption near-edge spectroscopy     

Novel mechanism of cell division inhibition associated with the SOS response in Escherichia coli.

Certain Escherichia coli strains were shown to possess a novel system of cell division inhibition, called the SfiC+ phenotype. SfiC+ filamentation had a number of properties similar to those of sfiA-dependent division inhibition previously described: (i) both are associated with the SOS response induced by expression of the recA(Tif) mutation, (ii) both are associated with cell death, (iii) both are amplified in mutants lacking the Lon protease, and (iv) both are suppressed by sfiB mutations. SfiC+ filamentation and sfiA-dependent division inhibition differed in (i) the physiological conditions under which loss of viability is observed, (ii) the extent of amplification in lon mutants, (iii) their genetic regulation (SfiC+ filamentation is not under direct negative control of the LexA repressor), and (iv) their genetic determinants (SfiC+ filamentation depends on a locus, sfiC+, near 28 min on the E. coli map and distinct from sfiA).     

Indole prevents Escherichia coli cell division by modulating membrane potential

Indole is a bacterial signalling molecule that blocks E. coli cell division at concentrations of 3-5mM. We have shown that indole is a proton ionophore and that this activity is key to the inhibition of division. By reducing the electrochemical potential across the cytoplasmic membrane of E. coli, indole deactivates MinCD oscillation and prevents formation of the FtsZ ring that is a prerequisite for division. This is the first example of a natural ionophore regulating a key biological process. Our findings have implications for our understanding of membrane biology, bacterial cell cycle control and potentially for the design of antibiotics that target the cell membrane.     

The inhibition of cell division in Saccharomyces cerevisiae (Meyen) by carbon dioxide

A specific inhibiting effect of CO² on cell division in Saccharomycescerevisiae (Meyen) was shown. Two strains of S. cerevisiae weregrown in chemically-defined media in specially-designed pressurechambers equipped with sensitive pressure-measuring devices.The chambers were pressurized with 40 psi of N₂ or CO₂. Inhibitionof cell division and of production of new buds was not causedby N₂ but was caused by CO₂ when either endogenously producedor added. In contrast, metabolic production of CO₂ was unaffectedby endogenously-produced pressures which totally inhibited celldivision. Bud formation and new-cell formation (cell division) were almosttotally inhibited by 40 psi of added CO₂ when compared withaerated cultures. The DNA content per cell, however, was nearlytwice as great in the CO₂-treated cultures as in the controls.Thus inhibition of cell division in S. cerevisiae must occurby some mechanism other than by inhibition of DNA replication. (Received January 5, 1971; )     

Localization of the Escherichia coli cell division protein FtsI (PBP3) to the division site and cell pole

FtsI, also known as penicillin-binding protein 3, is a transpeptidase required for the synthesis of peptidoglycan in the division septum of the bacterium, Escherichia coli . FtsI has been estimated to be present at about 100 molecules per cell, well below the detection limit of immunoelectron microscopy. Here, we confirm the low abundance of FtsI and use immunofluorescence microscopy, a highly sensitive technique, to show that FtsI is localized to the division site during the later stages of cell growth. FtsI was also sometimes observed at the cell pole; polar localization was not anticipated and its significance is not known. We conclude (i) that immunofluorescence microscopy can be used to localize proteins whose abundance is as low as approximately 100 molecules per cell; and (ii) that spatial and temporal regulation of FtsI activity in septum formation is achieved, at least in part, by timed localization of the protein to the division site.