Release of nascent trp mRNA from the operon DNA in chloramphenicol-treated cells of Escherichia coli.

Summary A synergistic effect of combined UV and -ray exposure was observed for inactivation of wild-type Schizosaccharomyces pombe. A recombinational repair process, known to be important in restitution of damage induced by both radiations, appears to be involved; a radiation-sensitive mutant defective in this repair pathway showed essentially no synergistic interaction between UV and -rays.Recovery from the synergistic effect of pre-exposure in wild-type cells did not display the expected fast -recovery and slow UV-recovery kinetics previously observed for regain of resistance to further exposure to the same radiation. Rather, UV-irradiated cells recovered quickly from synergistic inactivation on subsequent -exposure, while -irradiated cells recovered UV-resistance slowly. Recovery from synergism thus appears to reflect the nature of the second, and not the initial, radiation.AECL Reference No. 6154     

Characteristics of the nascent and non-nascent small DNA molecules found in Escherichia coli

We have purified nascent DNA molecules from Escherichia coli pulse-labeled with 5-bromo[6-3H]deoxyuridine by repeated chromatography on nitrocellulose and isopycnic centrifugation in CsCl. The nascent molecules were labeled with 32P either at their 5' ends using polynucleotide kinase or at their 3' ends using terminal transferase. Compared to the non-nascent DNA of normal density, the nascent dense DNA contained a higher proportion of molecules terminated at their 5' ends with ribonucleotides. Exposure of the dense DNA to alkali generated 5' OH termini quantitatively equivalent to the number of molecules bearing 5' ribonucleotides. Experiments designed (1) to detect structures at the 5' ends of phosphatase-treated nascent DNA molecules that caused them to be resistant to hydrolysis by spleen exonuclease or (2) to detect polypeptides that were associated covalently with small DNA molecules and could be iodinated with the Bolton-Hunter reagent did not yield positive results. We conclude that many, if not all, of the intermediates in E. coli DNA replication are initiated with one or more ribonucleotides. The nascent molecules are outnumbered by small non-nascent DNA molecules in the cell, many of which appear to become slightly longer when cells are pulsed with thymidine. Many of the non-nascent DNA molecules behave as if they were self-complementary or crosslinked.     

Different in vivo localization of the Escherichia coli proteins CspD and CspA

Neisseria cuniculi produces the restriction enzyme NcuI which is an isoschizomer of MboII. We have demonstrated that NcuI recognizes a pentanucleotide sequence (5'-GAAGA-3'/3'-CTTCT-5'), and cleaves the DNA 8 and 7 nucleotides downstream from the recognition site leaving a single 3'-protruding nucleotide. We have purified this enzyme to electrophoretic homogeneity using a four-step chromatographic procedure. NcuI endonuclease is a monomeric protein with a M(r)=48,000+/-1000 under denaturing conditions. The properties of NcuI are consistent with those for MboII, the position of the cleavage site being identical and the pH profile and divalent cation requirements being similar. Moreover, NcuI cross-reacts strongly with anti-MboII serum suggesting the presence of similar antigenic determinants. We have determined the sequence of 20 N-terminal amino acids for NcuI and concluded that this sequence is identical to the N-terminal portion of the MboII enzyme.     

Size distribution and molecular polarity of nascent DNA in a temperature-sensitive dna G mutant of Escherichia coli

Summary In the dna G t.s. strain BT 308, made lysogenic for the phage , nascent DNA was labelled by short pulses of ³H-thymidine, isolated and separated as a function of size by alkaline sucrose gradient sedimentation. The molecular polarity of the labelled DNA was then determined by hybridization to the separated strands of DNA.At 30° C, strand r DNA, made in the direction opposite that of fork movement, is synthesized in the form of short pieces. The first observable consequences of a shift to 42° C are the preferential inhibition of strand r synthesis and the small amount of strand r DNA which is made is recovered in long pieces of DNA rather than in short fragments. This indicates that the t.s. product, in strain BT 308, may be involved in the synthesis of the strand growing in the direction opposite that of replication fork movement.Newly synthesized strand l DNA, made in the same direction as replication fork movement, is found in long pieces in wild-type bacteria; it is found in pieces of intermediate size in strain BT 308 at 30° C as well as at 42° C. This indicates additional differences in the replication machinery between strain BT 308 and wild-type bacteria.     

Translocation of nascent non-signal sequence protein in heated Escherichia coli

Exposure of Escherichia coli to heat resulted in 1) selective inhibition of protein synthesis, 2) synthesis of heat shock proteins, and 3) altered subcellular distribution of newly synthesized proteins. Either 5 min or 1 h at 48 degrees C increases outer membrane proteins of Coomassie Blue-stained gels. After 1 h, there was a loss of stained proteins from the soluble fraction. Much greater changes in the distribution of radiolabeled (newly synthesized) proteins were observed, with marked increases in the number of outer membrane protein species and a corresponding loss of soluble fraction proteins. Three major species of radiolabeled proteins from heat-treated cells remain in the soluble fraction; these proteins have apparent Mr 56,000, 69,200, and 79,400. Cells were labeled with L-[35S] methionine at either 37 or 48 degrees C and chased with non-radiolabeled methionine before a temperature shift to either 48 or 37 degrees C, respectively. Only proteins synthesized at elevated temperature participated in translocation. It is suggested that heat disordering of membrane lipids promotes interlipidic connections between the inner and outer membrane providing pathways for protein movement to the outer membrane and may be the mechanism whereby a cell quickly responds to environmental temperature stress. The response does not require but may trigger synthesis of mRNA.     

Modeling of Escherichia coli Endonuclease V structure in complex with DNA

Endonuclease V (EndoV) is a metal-dependent DNA repair enzyme involved in removal of deaminated bases (e.g., deoxyuridine, deoxyinosine, and deoxyxanthosine), with pairing specificities different from the original bases. Homologs of EndoV are present in all major phyla from bacteria to humans and their function is quite well analyzed. EndoV has been combined with DNA ligase to develop an enzymatic method for mutation scanning and has been engineered to obtain variants with different substrate specificities that serve as improved tools in mutation recognition and cancer mutation scanning. However, little is known about the structure and mechanism of substrate DNA binding by EndoV. Here, we present the results of a bioinformatic analysis and a structural model of EndoV from Escherichia coli in complex with DNA. The structure was obtained by a combination of fold-recognition, comparative modeling, de novo modeling and docking methods. The modeled structure provides a convenient tool to study protein sequence-structure-function relationships in EndoV and to engineer its further variants.     

Mechanism of DNA chain growth: XV. RNA-linked nascent DNA pieces in Escherichia coli strains assayed with spleen exonuclease

A new method for the detection and assay of RNA-linked nascent DNA pieces has been developed. The method relies on selective degradation by spleen exonuclease of radioactive 5′-OH terminated DNA produced from the pulse-labelled nascent pieces upon alkaline hydrolysis. Analysis with this method in wild type Escherichia coli has shown relatively high proportions of the RNA-linked molecules after shorter pulses and in the smaller pieces, supporting the transient nature of the RNA attachment to the nascent pieces. The RNA-linked nascent DNA pieces are accumulated by both E. coli polAex1 (defective in 5′ → 3′ exonuclease of DNA polymerase I) and E. coli polA12 and polA1 (defective in polymerase of DNA polymerase I), suggesting the requirement of the concerted action of both 5′ → 3′ exonuclease and polymerase of DNA polymerase I for the removal of the RNA attached to the nascent pieces. Most of the nascent DNA pieces accumulated by E. coli ligts7 (defective in DNA ligase) are not linked to RNA, as expected from the direct role of DNA ligase in joining of the pieces. The analysis also has shown that a large portion of the nascent DNA pieces present in the cell under the normal steady-state conditions are not linked to RNA and that the level of the RNA-free DNA pieces is also increased in polA mutants. These findings suggest that the removal of RNA from the nascent pieces is a relatively rapid process and the joining reaction is a rate-limiting step that requires the concurrent action of DNA polymerase and DNA ligase.     

Imaging OmpR localization in Escherichia coli

We have used a fusion of GFP to the response regulator OmpR to image the spatial distribution of OmpR in live cells of Escherichia coli. We observed foci of increased OmpR-GFP fluorescence that appear to be due to interactions with the histidine kinase EnvZ. We also observed colocalization of OmpR-GFP with clusters of plasmids carrying OmpR binding sites, which enabled us to develop a simple method for imaging the binding of OmpR to DNA in live cells. We used the peak fluorescence intensity within cells to quantify the extent of OmpR-GFP localization either due to interactions with EnvZ or due to binding DNA. With these assays we compared the effects of osmolarity and procaine, both of which are believed to modulate EnvZ activity. Our results suggest that, at least under our growth conditions, procaine activates EnvZ-OmpR signalling whereas osmolarity has, at best, a weak effect on the EnvZ-OmpR system.     

Plasmid R1 is present as clusters in the cells of Escherichia coli

Fluorescence microscopy was used to determine the location(s) of the replication origin of plasmid R1 in exponentially growing cells of Escherichia coli. The number of oriR1 foci per cell was smaller than the number of R1 copies per cell and was found to be the same for a copA mutant of R1 and for the wild-type plasmid. The intensities of individual foci were stronger for the cop mutant than for the wild type. We interpreted these results to imply that the plasmid DNA molecules were localized in small groups/clusters, a result that seems contrary to the earlier observations that plasmid R1 replicates randomly and segregates as a single-copy unit. The implications for the quantitative behavior of plasmid R1 in stability, incompatibility tests, replication, and partition experiments are discussed.     

Stochastic assembly of chemoreceptor clusters in Escherichia coli

Chemoreceptors and cytoplasmic chemotaxis proteins in Escherichia coli form clusters that play a key role in signal processing. These clusters localize at cell poles and at specific positions along the cell body which correspond to future division sites, but the details of cluster formation and the mechanism of cluster distribution remain unclear. Here, we used fluorescence microscopy to investigate how the numbers and sizes of receptor clusters depend on the expression level of chemotaxis proteins and on the cell length. We show that the average cluster number saturates at high levels of protein expression at approximately 3.7 clusters per cell, well below the number of available positioning sites. Correspondingly, distances between clusters in filamentous cells saturate at an average of 1 mum but, even at saturating expression levels, individual cluster numbers and distances show a broad distribution around the mean. Our data imply a stochastic mode of cluster assembly, where a defined average interval between clusters along the cell body arises from competition between nucleation of new clusters and growth of existing clusters. Upon subsequent anchorage to defined lateral sites, clusters grow with rates that inversely depend on their size, and become polar upon several rounds of cell division.     

Repair of oxidized iron-sulfur clusters in Escherichia coli

The [4Fe-4S]2+ clusters of dehydratases are rapidly damaged by univalent oxidants, including hydrogen peroxide, superoxide, and peroxynitrite. The loss of an electron destabilizes the cluster, causing it to release its catalytic iron atom and converting the cluster initially to an inactive [3Fe-4S]1+ form. Continued exposure to oxidants in vitro leads to further iron release. Experiments have shown that these clusters are repaired in vivo. We sought to determine whether repair is mediated by either the Isc or Suf cluster-assembly systems that have been identified in Escherichia coli. We found that all the proteins encoded by the isc operon were critical for de novo assembly, but most of these were unnecessary for cluster repair. IscS, a cysteine desulfurase, appeared to be an exception: although iscS mutants repaired damaged clusters, they did so substantially more slowly than did wild-type cells. Because sulfur mobilization should be required only if clusters degrade beyond the [3Fe-4S]1+ state, we used whole cell EPR to visualize the fate of oxidized enzymes in vivo. Fumarase A was overproduced. Brief exposure of cells to hydrogen peroxide resulted in the appearance of the characteristic [3Fe-4S]1+ signal of the oxidized enzyme. When hydrogen peroxide was then scavenged, the enzyme activity reappeared within minutes, in concert with the disappearance of the EPR signal. Thus it is unclear why IscS is required for efficient repair. The iscS mutants grew poorly, allowing the possibility that metabolic defects indirectly slow the repair process. Our data did indicate that damaged clusters decompose beyond the [3Fe-4S]1+ state in vivo when stress is prolonged. Under the conditions of our experiments, mutants that lacked other repair candidates--Suf proteins, glutathione, and NADPH: ferredoxin reductase--all repaired clusters at normal rates. We conclude that the mechanism of cluster repair is distinct from that of de novo assembly and that this is true because mild oxidative stress does not degrade clusters in vivo to the point of presenting an apoenzyme to the de novo cluster-assembly systems.     

Expression of orthopoxvirus DNA sequences in Escherichia coli cells]

We observed the expression of recombinant plasmids genes containing ectromelia virus DNA fragments in E. coli minicells. Using plasmids with vaccinia or ectromelia viruses DNA fragments inserted upstream of lacZ gene we showed that certain orthopoxvirus genome fragments carry out a promoter-like function in bacterial cells.     

Repair of ozone-induced DNA lesions in Escherichia coli B cells

Alkaline sucrose gradient sedimentation indicates that ozone can produce DNA single- and double-strand breaks in wild-type E. coli and ozone-sensitive mutant MQ1844(ozrB). Another type of DNA damage repaired only by the ozrB gene product may also be responsible for the killing effect of ozone on E. coli cells.     

Timing of Z-ring localization in Escherichia coli

Bacterial cell division takes place in three phases: Z-ring formation at midcell, followed by divisome assembly and building of the septum per se. Using time-lapse microscopy of live bacteria and a high-precision cell edge detection method, we have previously found the true time for the onset of septation, τ(c), and the time between consecutive divisions, τ(g). Here, we combine the above method with measuring the dynamics of the FtsZ-GFP distribution in individual Escherichia coli cells to determine the Z-ring positioning time, τ(z). To analyze the FtsZ-GFP distribution along the cell, we used the integral fluorescence profile (IFP), which was obtained by integrating the fluorescence intensity across the cell width. We showed that the IFP may be approximated by an exponential peak and followed the peak evolution throughout the cell cycle, to find a quantitative criterion for the positioning of the Z-ring and hence the value of τ(z). We defined τ(z) as the transition from oscillatory to stable behavior of the mean IFP position. This criterion was corroborated by comparison of the experimental results to a theoretical model for the FtsZ dynamics, driven by Min oscillations. We found that τ(z) < τ(c) for all the cells that were analyzed. Moreover, our data suggested that τ(z) is independent of τ(c), τ(g) and the cell length at birth, L(0). These results are consistent with the current understanding of the Z-ring positioning and cell septation processes.