Colicin E2 production and release by Escherichia coli K12 and other Enterobacteriaceae

Previous work has shown that Escherichia coli K12 ColE2+ cells undergo a form of partial lysis and exhibit increases in lysophosphatidylethanolamine (lysoPE) and free fatty acid content due to activation of phospholipase A when induced to produce and release colicin E2. The increase in lysoPE content was assumed to be essential for efficient colicin release. These same characteristics are also presented by some natural ColE2+ isolates, and by other representatives of the Enterobacteriaceae after transformation with derivatives of a ColE2 plasmid. However, Salmonella typhimurium strains carrying ColE2 plasmids released colicin without partial lysis and without increasing their lysoPE content. A previously undetected minor phospholipid, which appeared in these and other strains only when they were induced to produce colicin, may be an important factor in colicin release. In ColE2+ E. coli K12, production of this new lipid was dependent on phospholipase A activation following expression of the ColE2 lysis gene. Some other ColE2+ strains did not respond to induction of colicin production in the same way as ColE2+ E. coli K12. These strains were less sensitive to inducer (mitomycin C) or unable to produce increased amounts of colicin in response to induction, or unable to degrade colicin once it was released. In general, the results suggest that colicin release occurs by the same or similar processes in the various strains tested, and support the continued use of E. coli K12 as the model strain for studying the mechanisms of colicin release.     

Amount of Colicin Release in Escherichia coli Is Regulated by Lysis Gene Expression of the Colicin E2 Operon

The production of bacteriocins in response to worsening environmental conditions is one means of bacteria to outcompete other microorganisms. Colicins, one class of bacteriocins in Escherichia coli, are effective against closely related Enterobacteriaceae. Current research focuses on production, release and uptake of these toxins by bacteria. However, little is known about the quantitative aspects of these dynamic processes. Here, we quantitatively study expression dynamics of the Colicin E2 operon in E. coli on a single cell level using fluorescence time-lapse microscopy. DNA damage, triggering SOS response leads to the heterogeneous expression of this operon including the cea gene encoding the toxin, Colicin E2, and the cel gene coding for the induction of cell lysis and subsequent colicin release. Advancing previous whole population investigations, our time-lapse experiments reveal that at low exogenous stress levels all cells eventually respond after a given time (heterogeneous timing). This heterogeneous timing is lost at high stress levels, at which a synchronized stress response of all cells 60 min after induction via stress can be observed. We further demonstrate, that the amount of colicin released is dependent on cel (lysis) gene expression, independent of the applied exogenous stress level. A heterogeneous response in combination with heterogeneous timing can be biologically significant. It might enable a bacterial population to endure low stress levels, while at high stress levels an immediate and synchronized population wide response can give single surviving cells of the own species the chance to take over the bacterial community after the stress has ceased.     

DNA Degradation in Escherichia coli 15 T-L- Induced by Fast Proton Bombardment

DNA degradation and its temperature dependence as a function of linear energy transfer were studied in Excherichia coli using fast proton irradiation as the initiating agent. The data indicate that radiation-induced DNA degradation can proceed by two processes. The first, or fast component, begins immediately after irradiation with ⁶⁰Co γ-rays or with fast protons at doses less than 10¹⁰ protons/cm². The rate is high and involves a maximum of about 50% degradation. It is elicited more efficiently by protons of high linear energy transfer. The second, or slow component, results from higher doses of fast proton bombardment. There is a delay between irradiation and the initiation of this slower component, but 100% of the DNA complement is degraded. The data indicate that both processes are enzyme-mediated, the first probably by normal DNA-related activity and the second by DNAase activity.     

Bacteriophage T4 Inhibits Colicin E2-Induced Degradation of Escherichia coli Deoxyribonucleic Acid I. Protein Synthesis-Dependent Inhibition

The deoxyribonucleic acid (DNA) of Escherichia coli B is converted by colicin E2 to products soluble in cold trichloroacetic acid; we show that this DNA degradation (hereafter termed solubilization) is subject to inhibition by infection with bacteriophage T4. At least two modes of inhibition may be differentiated on the basis of their sensitivity to chloramphenicol. The following observations on the inhibition of E2 by phage T4 in the absence of chloramphenicol are described: (i) Simultaneous addition to E. coli B of E2 and a phage mutated in genes 42, 46, and 47 results in a virtually complete block of the DNA solubilization normally induced by E2; the mutation in gene 42 prevents phage DNA synthesis, and the mutations in genes 46 and 47 block a late stage of phage-induced solubilization of host DNA. (ii) This triple mutant inhibits equally well when added at any time during the E2-induced solubilization. (iii) Simultaneous addition to E. coli B of E2 and a phage mutated only in gene 42 results in extensive DNA solubilization, but the amount of residual acid-insoluble DNA (20 to 25%) is more characteristic of phage infection than of E2 addition (5% or less). (iv) denA mutants of phage T4 are blocked in an early stage (endonuclease II) of degradation of host DNA; when E2 and a phage mutated in both genes 42 and denA are added to E. coli B, extensive solubilization of DNA occurs with a pattern identical to that observed upon simultaneous addition of E2 and the gene 42 mutant. (v) However, delaying E2 addition for 10 min after infection by this double mutant allows the phage to develop considerable inhibition of E2. (vi) Adsorption of E2 to E. coli B is not impaired by infection with phage mutated in genes 42, 46, and 47. In the presence of chloramphenicol, the inhibition of E2 by the triple-mutant (genes 42, 46, and 47) still occurs, but to a lesser extent.     

Methylation-mediated regulation of E2F1 in DNA damage-induced cell death

E2F1 promotes DNA damage-induced apoptosis and the post-translational modifications of E2F1 play an important role in the regulation of E2F1-mediated cell death. Here, we found that Set9 and LSD1 regulate E2F1-mediated apoptosis upon DNA damage. Set9 methylates E2F1 at lysine 185, a conserved residue in the DNA-binding domain of E2F family proteins. The methylation of E2F1 by Set9 leads to the stabilization of E2F1 and up-regulation of its proapoptotic target genes p73 and Bim, and thereby induces E2F1-mediated apoptosis in response to genotoxic agents. We also found that LSD1 demethylates E2F1 at lysine 185 and reduces E2F1-mediated cell death. The identification of the methylation/demethylation of E2F1 by Set9/LSD1 suggests that E2F1 is dynamically regulated by epigenetic enzymes in response to DNA damage.     

Mutagenic DNA repair in Escherichia coli. VII. Constitutive and inducible manifestations.

Incubation of E. coli WP2 in the presence of chloramphenicol (CAP) for 90 min before and 60 min after γ-irradiation had no effect on the induction of Trp⁺ mutations. Bacteria that had been treated with CAP for 90 min prior to UV irradiation showed normal or near normal yields of induced mutations to streptomycin or colicin E2 resistance. Most of these mutations lost their photoreversibility (indicating “fixation”) during continued incubation with CAP for a further 60 min after irradiation, during which time neither protein nor DNA synthesis was detectable. It is suggested that CAP-sensitive protein synthesis is not required for mutagenic (error-prone) repair of lesions in pre-existing DNA, arguing against an inducible component in this repair.In contrast the frequency of UV-induced mutations to Trp⁺ (largely at suppressor loci) was drastically reduced by CAP pretreatment, confirming the need for an active replication fork for UV-mutagenesis at these loci. It is known from the work of others that CAP given after UV abolishes mutagenesis at these loci. We conclude that CAP-sensitive protein synthesis (consistent with a requirement for an inducible function) is necessary for mutagenic repair only in newly-replicated DNA (presumably at daughter strand gaps) and not in pre-existing DNA. The data are consistent with but do not prove the hypothesis that CAP-sensitive and insensitive modes of mutagenesis reflect minor differences in the operation of a single basic mutagenic repair system.     

Structure and Sites of Phosphorylation of 14-3-3 Protein: Role in Coordinating Signal Transduction Pathways

The 14-3-3 family are homo- and heterodimeric proteins whose biological role has been unclear for some time, although they are now gaining acceptance as a novel type of adaptor protein that modulates interactions between components of signal transduction pathways, rather than by direct activation or inhibition. It is becoming apparent that phosphorylation of the binding partner and possibly also the 14-3-3 proteins may regulate these interactions. 14-3-3 isoforms interact with a novel phosphoserine (Sp) motif on many proteins, RSX_1,2SpXP. The two isoforms that interact with Raf-1 are phosphorylated in vivo on Ser185 in a consensus sequence motif for proline-directed kinases. The crystal structure of 14-3-3 indicates that this phosphorylation could regulate interaction of 14-3-3 with its target proteins. We have now identified a number of additional phosphorylation sites on distinct mammalian and yeast isoforms.     

14-3-3蛋白与植物细胞信号转导

14-3-3蛋白通过直接蛋白质-蛋白质相互作用对植物代谢关键酶、质膜H^＋ -ATP酶等发挥广泛调节作用。越来越多证据显示14-3-3蛋白通过与转录因子和其他信号分子结合参与调控植物细胞信号转导。对植物细胞中14-3-3蛋白调控信号转导途径,尤其是植物细胞对胁迫响应的调控机制进行了综述。     

Fusicoccin and its receptors

Purified preparations of FC receptors from maize, obtained under non-denaturing conditions, showed in SDS-PAGE two doublets of proteins with an apparent molecular mass of 30 and 90 kDa. In this paper the isolation of the 30 kDa protein, its identification as a 14-3-3-like protein, as well as its immunological detection in partially-purified FC-receptor preparations from bean and spinach are described. The 14-3-3 proteins have biochemical properties consistent with potential signalling roles, and their presence in highly purified FC-receptor preparations suggests that they may be involved in FC- signal transduction. Photoaffinity labelling experiments demonstrating that the protein at 90 kDa binds FC are also presented. The evidence presented taken as a whole, suggests the occurrence in maize of a protein complex for FC perception and signal transduction.     

香菇C91-3菌丝发酵液提取蛋白抗小鼠宫颈癌U14的初步探讨

目的 探讨香菇C91-3菌丝发酵液提取蛋白对小鼠宫颈癌的作用.方法 观察香菇C91-3菌丝发酵液提取蛋白对小鼠宫颈癌U14荷瘤小鼠生存期的影响和对体外培养的小鼠宫颈癌U14细胞的抑杀作用.结果 香菇C91-3菌丝发酵液提取蛋白能明显延长小鼠宫颈癌U14荷瘤小鼠的生存期并能对体外培养的小鼠宫颈癌U14细胞有直接抑杀作用.结论 香菇C91-3菌丝发酵液提取蛋白对机体有调节、增强机体免疫系统功能的作用.     

Identification of Closely Linked Loci Controlling Ultraviolet Sensitivity and Refractivity to Colicin E2 in Escherichia coli

Mutants (phenotypic symbol Ref-II) refractory to colicin E2 have been isolated in several strains of Escherichia coli K-12, and a refII locus has been mapped 1 to 2 min counter clockwise to thr. A small number of Ref-II mutants are also ultraviolet (UV)-sensitive and the uv(s) locus in one such strain has been mapped close to the refII locus near thr. The Ref-II mutation alone does not affect recombinant formation in F(-) strains, but the Ref-II, UV(s) strains behave in many respects like Rec(-) mutants, giving reduced recombination frequencies in crosses with male strains. It is suggested that the refII and uv(s) loci correspond to closely linked if not identical genes, concerned in some way in the activity of one or more deoxyribonucleases, and that the Ref-II, UV(s) mutants arise as the pleiotropic expression of a single gene or of a deletion or polar mutation affecting linked genes.     

Plasmid Replication and the Induced Synthesis of Colicins E1 and E2 in Escherichia coli

Induction of colicins E1 and E2 in Escherichia coli occurs when plasmid synthesis has been inhibited either by nalidixic acid or by lack of deoxyribonucleic acid polymerase I. Moreover, colicin E1 and E2 synthesis induced by mitomycin C and exposure to chloramphenicol is not associated with a large increase in circular plasmid deoxyribonucleic acid. The mean plasmid content of cells in populations having a low spontaneous frequency of colicin-producing cells because of growth at low temperature or because of the presence of recA(-) or crp(-) alleles, is not significantly different to that in wild-type cells grown at 37 C.     

The Escherichia coli adenylyl cyclase complex: stimulation by GTP and other nucleotides.

Escherichia coli cells permeabilized by treatment with low concentrations of toluene contain an adenylyl cyclase activity that can be stimulated 3.6-7.6-fold by GTP. The stimulatory effect of GTP is maximal at concentrations of the nucleotide in the physiological range (above 0.7 mM). Studies of the dependence of velocity on substrate (ATP) concentration indicate that the velocity vs. substrate plots are sigmoid in the absence of GTP but hyperbolic in the presence of GTP, suggesting an allosteric regulatory site that can be occupied by either ATP or GTP. Replacement of ATP by AMPPNP as substrate results in velocity vs. substrate plots that are hyperbolic in the absence or presence of GTP, although GTP increases the Vmax by a factor of 2.2; these findings indicate that AMPPNP specifically occupies the substrate site and GTP exclusively occupies the regulatory site. A test of the capacity of other guanine nucleotides to stimulate adenylyl cyclase activity showed that 2'-deoxy-GTP was almost as effective as GTP, but that GDP, GMP, ppGpp, and 3',5'-cGMP were not stimulatory effectors; GTP-gamma-S and GMPPNP stimulated adenylyl cyclase activity but to a lesser degree than did GTP. In addition to the previous indication that ATP can occupy the regulatory site on adenylyl cyclase, it was found that CTP and UTP were potent stimulators. Thus, all the naturally occurring RNA precursor nucleoside triphosphates are capable of stimulating adenylyl cyclase activity. In contrast, PPPi inhibits adenylyl cyclase activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Colicin Tolerance Induced by Ampicillin or Mutation to Ampicillin Resistance in a Strain of Escherichia coli K-12

A mutant (G11el) of Escherichia coli selected as being resistant to ampicillin and showing signs of an envelope defect was also found to be tolerant to colicins E2 and E3. The colicin tolerance of G11el could be partially repressed by Mg(2+) ions. Transition from tolerance to sensitivity and vice versa by shifting the concentration of Mg(2+) in the growth medium required several generations. This indicated that synthesis of new envelope material was needed for transition. Previous physiological results have indicated a change in the envelope lipopolysaccharide (LPS) of G11el. However, chemical analyses revealed no differences in carbohydrate composition between LPS from G11el and its parent strain G11al. Genetic experiments showed that the mutation in G11el is located at about 20 min on the E. coli K-12 chromosome. The mutation was dominant over wild type in partial diploids with the mutation located on the episome. Because colicin tolerance was the most striking phenotypic effect as a result of mutation in the actual locus, this gene will be named tolD until the exact gene product is known. Spheroplasts formed from G11al and G11el by ethylenediaminetetraacetate-lysozyme treatment did not adsorb colicin E2; however, penicillin spheroplasts of G11al and G11el were tolerant to colicin E2. Thus, colicin tolerance can be induced biochemically. It is suggested that colicin tolerance often is a secondary consequence of a change in the cell envelope.     

Degradation of Escherichia coli chromosomal and plasmid DNA in serum

Incubation of serum-sensitive [3H]thymidine labelled Escherichia coli PC2166 (RSF1030) and E. coli AM1281 (pBR322) harbouring small plasmids (mol. wt 5.5 X 10(6) and 2.6 X 10(6] in serum resulted in killing of 99.9% of the bacteria within 15 min and in the release of 85% of the radioactivity into the medium after 1 h incubation. The fate of chromosomal and plasmid DNA during incubation of the bacteria in serum was analysed by measurement of the amount of DNA-associated radioactivity, by TCA precipitation, by agarose gel electrophoresis and by the capacity of DNA to transform competent acceptor bacteria. Chromosomal DNA and high molecular weight plasmid DNA were rapidly degraded after 1 h incubation of bacteria in serum. However, low molecular weight plasmid DNA was virtually unaffected and remained physicochemically as well as biologically intact during up to 4 h of incubation of bacteria in serum.     

ADAM22 plays an important role in cell adhesion and spreading with the assistance of 14-3-3

Cellular adhesion plays important roles in a variety of biological processes. The ADAM family contains disintegrin-like and metalloproteinase-like domains which potentially have cell adhesion and protease activities. Recent studies suggest that the interaction between 14-3-3zeta and ADAM22cyt can regulate cell adhesion and spreading, therefore it has a potential role in neural development and function. 14-3-3 family has seven highly conserved members that regulate various cellular functions. Using yeast two-hybrid method, we identified that ADAM22cyt bound some other 14-3-3 family members. The interaction was further confirmed by in vitro protein pull-down assay and co-immunoprecipitation. We also found that the overexpression of exogenous ADAM22 in HEK293 cells could significantly enhance cell adhesion and spreading, compared with the truncated ADAM22 lack of 14-3-3 binding motifs. These results strongly demonstrated a functional role for ADAM22/14-3-3 in cell adhesion and spreading.     

Reduction of Escherichia coli O157:H7 Populations in Cattle by Addition of Colicin E7-Producing E. coli to Feed

A cattle trial using artificially inoculated calves was conducted to determine the effect of the addition of colicinogenic Escherichia coli strains capable of producing colicin E7 (a 61-kDa DNase) to feed on the fecal shedding of serotype O157:H7. The experiment was divided into three periods. In period 1, which lasted 24 days, six calves were used as controls, and eight calves received 10⁷ CFU of E. coli (a mixture of eight colicinogenic E. coli strains) per g of feed. Both groups were orally inoculated with nalidixic acid-resistant E. coli O157:H7 strains 7 days after the treatment started. In periods 2 and 3, the treatment and control groups were switched, and the colicinogenic E. coli dose was increased 10-fold. During period 3, which lasted as long as period 1, both groups were reinoculated with E. coli O157:H7. The numbers of E. coli O157:H7 were consistently greater in the control groups during the three periods, but comparisons within each time period determined a statistically significant (P < 0.05) difference only at day 21 of period 1. However, when the daily average counts were compared between the period 1 control group and the period 3 treatment group that included the same six animals, an overall reduction of 1.1 log₁₀ CFU/g was observed, with a maximum decrease of 1.8 log₁₀ CFU/g at day 21 (overall statistical significance, P = 0.001). Serotype O157:H7 was detected in 44% of the treatment group's intestinal tissue samples and in 64% of those from the control group (P < 0.04). These results indicated that the daily addition of 10⁸ CFU of colicin E7-producing E. coli per gram of feed could reduce the fecal shedding of serotype O157:H7.