Local anaesthetic induced turbidity increases: implications of interactions with intact bacterial cells and with subcellular fractions

Four local anaesthetics (LAs), amethocaine and procaine (esters) and cinchocaine and lignocaine (amides) have been assessed in terms of their ability to induce turbidity increases in non-growing cells of Escherichia coli suspended in a carbohydrate free defined medium (CFM) or distilled water or in 0.2 M phosphate buffer. Procaine and lignocaine did not induce turbidity increases. The turbidity increase-LA concentration profiles for both amethocaine and cinchocaine are similar in all three systems. Slight variation are discussed in terms of the ionic content of the suspending media. Interactions between LAs and dispersed systems comprising: cell envelope preparations, cytoplasmic contents, lipid depleted cells and cell lipid dispersion, are also described. Transmission electron micrographs of LA treated cells are presented and the use of uranyl acetate as a 'vital' stain is illustrated. Results are discussed in terms of LA lipophilicity and the effectiveness of LAs in precipitating intracellular materials at high concentrations.     

Autophagy activated by tuberin/mTOR/p70S6K suppression is a protective mechanism against local anaesthetics neurotoxicity

The local anaesthetics (LAs) are widely used for peripheral nerve blocks, epidural anaesthesia, spinal anaesthesia and pain management. However, exposure to LAs for long duration or at high dosage can provoke potential neuronal damages. Autophagy is an intracellular bulk degradation process for proteins and organelles. However, both the effects of LAs on autophagy in neuronal cells and the effects of autophagy on LAs neurotoxicity are not clear. To answer these questions, both lipid LAs (procaine and tetracaine) and amide LAs (bupivacaine, lidocaine and ropivacaine) were administrated to human neuroblastoma SH‐SY5Y cells. Neurotoxicity was evaluated by MTT assay, morphological alterations and median death dosage. Autophagic flux was estimated by autolysosome formation (dual fluorescence LC3 assay), LC3‐II generation and p62 protein degradation (immunoblotting). Signalling alterations were examined by immunoblotting analysis. Inhibition of autophagy was achieved by transfection with beclin‐1 siRNA. We observed that LAs decreased cell viability in a dose‐dependent manner. The neurotoxicity of LAs was tetracaine > bupivacaine > ropivacaine > procaine > lidocaine. LAs increased autophagic flux, as reflected by increases in autolysosome formation and LC3‐II generation, and decrease in p62 levels. Moreover, LAs inhibited tuberin/mTOR/p70S6K signalling, a negative regulator of autophagy activation. Most importantly, autophagy inhibition by beclin‐1 knockdown exacerbated the LAs‐provoked cell damage. Our data suggest that autophagic flux was up‐regulated by LAs through inhibition of tuberin/mTOR/p70S6K signalling, and autophagy activation served as a protective mechanism against LAs neurotoxicity. Therefore, autophagy manipulation could be an alternative therapeutic intervention to prevent LAs‐induced neuronal damage.     

Antibacterial activities of zinc oxide nanoparticles against Escherichia coli O157:H7

Aims:  To investigate antibacterial activities of zinc oxide nanoparticles (ZnO NP) and their mode of action against an important foodborne pathogen, Escherichia coli O157:H7.
Methods and Results:  ZnO NP with sizes of 70 nm and concentrations of 0, 3, 6 and 12 mmol l⁻¹ and NP-free solutions were used in antimicrobial tests against E. coli O157:H7. ZnO NP showed increasing inhibitory effects on the growth of E. coli O157:H7 as the concentrations of ZnO NP increased. A complete inhibition of microbial growth was achieved at the concentration level of 12 mmol l⁻¹ or higher. Scanning electron microscopy (SEM), transmission electron microscopy (TEM), and Raman spectroscopy were used to characterize the changes of morphology and cellular compositions of bacterial cells treated with ZnO NP and study the mode of action of ZnO NP against E. coli O157:H7. The intensity of lipid and protein bands in the Raman spectra of bacterial cells increased after exposure to ZnO NP, while no significant changes in nucleic acid bands were observed.
Conclusions:  ZnO NP were found to have antibacterial activity against E. coli O157:H7. The inhibitory effects increase as the concentration of ZnO NP increased. Results indicate that ZnO NP may distort and damage bacterial cell membrane, resulting in a leakage of intracellular contents and eventually the death of bacterial cells.
Significance and Impact of the Study:  These results suggest that ZnO NP could potentially be used as an effective antibacterial agent to protect agricultural and food safety.     

Studies on the Mode of Action of the Phenolic Antibacterial Agent Fentichlor against Staphylococcus aureus and Escherichia coli II. The Effects of Fentichlor on the Bacterial Membrane and the Cytoplasmic Constituents of the Cell

Fentichlor produces rapid and marked damage to cell membranes of Staphylococcus aureus and Escherichia coli causing leakage of 260 nm material and pentose from whole cells, and lysis of spheroplasts of E. coli. Investigations indicate that Fentichlor-induced membrane damage is related to bactericidal activity. Bacteriostatic concentrations of 10 μg/ml or less do not stimulate leakage while at higher concentrations there is a marked relationship between loss of viability and of metabolic pool material released. Drug concentrations producing 99·99% kill within 1 h correspond closely to minimum concentrations required to produce total loss of 260 nm material from the pool. Membrane damage caused by bactericidal concentrations of drug is irreversible and under conditions optimal for enzyme activity additional leakage of 260 nm material resulting from autolytic breakdown of insoluble nucleic acids also occurs. There is no evidence that Fentichlor produces precipitation of cell cytoplasmic constituents.     

Cardiotoxicity of Jamesoni's mamba (Dendroaspis jamesoni) venom and its fractionated components in primary cultures of rat myocardial cells

Summary Primary cultures of spontaneously beating myocardial cells isolated from neonatal rat hearts were used to screen the cardiotoxic effects of Jamesoni's mamba (Dendroaspis jamesoni) venom and components isolated from the venom by gel filtration and ion exchange chromatography. Cardiotoxicity was evaluated on the basis of leakage of lactate dehydrogenase (LDH), changes in morphology, cell membrane lysis, cellular viability, and alterations in spontaneous beating activity. The whole venom caused dose- and time-dependent leakage of LDH, disruption of the cell monolayer, decreases in viability, and inhibition of beating activity. Gel filtration of the venom yielded eight fractions (DjI to DjVIII). DjI (30 μg/ml), DjII (20 μg/ml), and DjV (20 μg/ml) caused significant (P<0.001) leakage of LDH, extensive morphologic damage, and decreases in viability. At lower concentrations DjI to DjVIII caused progressive inhibition of spontaneous beating activity. The main fraction (DjV), which was the most toxic, was further separated into 14 polypeptides (Dj1 to Dj14) by ion-exchange chromatography using Bio-Rex 70. Based on the ability to induce LDH leakage, produce morphologic damage, lyse cell membranes, and arrest beating activity, four categories of polypeptides were identified: cardiotoxins, Dj1 and Dj2; cardiotoxinlike polypeptides, Dj3 to Dj8; less active membrane lytic polypeptides, Dj9 to Dj13; and membrane lytic polypeptide, Dj14. This study was supported in part by the Fulbright Scholar Program (1986–1987) and the Burroughs Wellcome Fund. D. A. is a Burroughs Wellcome Scholar in Toxicology.     

莳萝蒿精油成分分析及抑菌活性机理探究

为了确定莳萝蒿精油的化学成分,并探究其抑菌活性及抑菌机理.该研究采用水蒸气蒸馏法提取莳萝蒿精油,并通过气相色谱-质谱联用法测定其化学成分.采用抑菌圈法、二倍稀释法和生长曲线法测定精油的抑菌活性,采用电导率法和扫描电镜法探究精油的抑菌机理.结果表明:(1)莳萝蒿精油的主要化学成分包括醇类(47.12％)和萜烯类(19.9...     

Involvement of ppGpp, ribosome modulation factor, and stationary phase-specific sigma factor sigma(S) in the decrease in cell viability caused by spermidine.

Accumulation of spermidine in Escherichia coli causes a decrease in cell viability at the late stationary phase of cell growth. The mechanism underlying this effect has been studied. Spermidine accumulation caused an increase in the level of ppGpp and a decrease in ribosome modulation factor (RMF) and stationary phase-specific sigma factor sigma(S), both of which are believed to be involved in cell viability. Transformation of E. coli with the gene for stringent factor, which synthesizes ppGpp, also caused a significant decrease in the levels of RMF and sigma(S) factor and a decrease in cell viability. The results strongly suggest that the accumulation of ppGpp is also involved in the decrease in cell viability and that the sigma(S) factor assists the function of RMF in cell viability.     

The lethal action of 2-phenoxyethanol and its analogues upon Escherichia coli NCTC 5933.

Bactericidal activity has been assessed for a number of glycolmonophenyl ethers towards Escherichia coli NCTC 5933, and the action of one analogue, 2-phenoxyethanol, has been studied in greater detail. For this compound the onset of bactericidal activity towards Escherichia coli occurred at concentrations which also induced considerable increases in drug uptake, marked leakage of cytoplasmic constituents, the cellular penetration of N-tolyl-alpha-napthylamine-8-sulphonic acid, and morphological changes consistent with gross membrane damage. However, temperature coefficients of rates of cellular leakage of low molecular weight cytoplasmic constituents, and rates of kill, were markedly different and suggested that the two phenomena were not integrally related, but that each was a consequence of some other action of the drug. Drug levels considerably below those possessing lethal activity, however, promoted the ready efflux of potassium ions from cells and caused disorganisation of the outer lipopolysaccharide-rich regions of the cell envelope.     

Effects of low electric current (LEC) treatment on pure bacterial cultures

AIMS: This research focused on the effects of low electric current (LEC) on the cell viability and metabolic activity of Escherichia coli and Bacillus cereus. METHODS AND RESULTS: Different LEC intensities at fixed amperage were applied, employing either graphite or copper electrode pairs, and the effects were determined by conventional cultural methods and bioindicators. On E. coli, the LEC with graphite electrodes at 5 and 10 mA led to no significant variation, but at 20 and 40 mA there was increasing inhibition of both the enzymatic activities and growth, and a reduction in ATP content. On B. cereus, similar experiments at the lower amperages did not have any inhibitor effects, however, the 40 mA current stimulated growth, ATP content and some enzymatic activities. The LEC treatment using copper electrodes caused, already at 5 mA, inhibition of bacterial growth and metabolic and enzymatic activities in both E. coli and B. cereus. CONCLUSIONS: On the basis of the obtained results using different amperages and electrodes, we can conclude that E. coli seem to be more sensitive compared with B. cereus. SIGNIFICANCE AND IMPACT OF THE STUDY: The study increases the knowledge on LEC treatment effects on the pure bacterial cultures.     

Ethanol tolerance in bacteria

The adverse effects of ethanol on bacterial growth, viability, and metabolism are caused primarily by ethanol-induced leakage of the plasma membrane. This increase in membrane leakage is consistent with known biophysical properties of membranes and ethanolic solutions. The primary actions of ethanol result from colligative effects of the high molar concentrations rather than from specific interactions with receptors. The ethanol tolerance of growth in different microorganisms appears to result in large part from adaptive and evolutionary changes in cell membrane composition. Different cellular activities vary in their tolerance to ethanol. Therefore, it is essential that the aspect of cellular function under study be specifically defined and that comparisons of ethanol tolerance among systems share this common definition. Growth is typically one of the most sensitive cellular activities to inhibition by ethanol, followed by survival, or loss of reproductive ability. Glycolysis is the most resistant of these three activities. Since glycolysis is an exergonic process, a cell need not be able to grow or remain viable for glycolysis to occur.     

Expression of recombinant EARLI1, a hybrid proline-rich protein of Arabidopsis, in Escherichia coli and its inhibition effect to the growth of fungal pathogens and Saccharomyces cerevisiae

EARLI1 is an Arabidopsis gene with pleiotropic effects previously shown to have auxiliary functions in protecting plants against freezing-induced cellular damage and promoting germinability under low-temperature and salinity stresses. Here we determined whether recombinant EARLI1 protein has anti-fungal activity. Recombinant EARLI1 protein lacking its signal peptide was produced in Escherichia coli BL21(DE3) using isopropyl β-d-1-thiogalactopyranoside (IPTG) induction and the prokaryotic expression vector pET28a. Expression of EARLI1 was analyzed by Western blotting and the protein was purified using affinity chromatography. Recombinant EARLI1 protein was applied to fungal cultures of Saccharomyces cerevisiae, Botrytis cinerea and Fusarium oxysporum, and membrane permeability was determined using SYTOX green. Full-length EARLI1 was expressed in S. cerevisiae from the GAL1 promoter using 2% galactose and yeast cell viability was compared to control cells. Our results indicated that application of recombinant EARLI1 protein to B. cinerea and F. oxysporum could inhibit the growth of the necrotrophic fungi. Besides, addition of the recombinant protein to liquid cultures of S. cerevisiae significantly suppressed yeast growth and cell viability by increasing membrane permeability, and in vivo expression of the secreted form of EARLI1 in S. cerevisiae also had a remarkable inhibition effect on the growth of yeast cells.     

Intraperiplasmic growth of Bdellovibrio bacteriovorus on heat-treated Escherichia coli.

Heat treatment (55 degrees C for 40 min) of cell suspensions in buffer (ca. 3 x 10(9) cells per ml) of Escherichia coli ML35 caused a 4- to 4.5-log loss of cell viability. Similar results were found for several other E. coli strains that were examined. As a result of this heat treatment, 260-nm- and 280-nm-absorbing materials were released into the suspending buffer, along with about 10% of the total cellular radioactivity, when cells uniformly labeled with (14)C were used. In comparison with untreated cells, heat-treated E. coli ML35 cells showed (i) no significant changes in macromolecular composition other than ca. 22% less RNA content, (ii) an increased permeability to o-nitrophenyl-beta-d-galactopyranoside (a compound to which untreated cells are impermeable), (iii) almost complete loss of respiratory potential, and (iv) substantial losses of numerous glycolytic enzyme activities in cell extracts prepared from these cells. Intraperiplasmic development of Bdellovibrio bacteriovorus 109J with heat-treated E. coli ML35 as substrate cells appeared normal when observed microscopically, although bdellovibrio attachment and resultant bdelloplast formation were slightly retarded. No significant changes were observed in cell yields or in the ratios and contents of DNA, RNA, or protein between bdellovibrios harvested from untreated cells and those from heat-treated substrate cells after single-developmental-cycle growth on these cells. The average Y(ATP) values for intraperiplasmic growth on untreated and heat-treated substrate cells were 16.0 and 17.9, respectively. It is concluded that intraperiplasmic bdellovibrio growth on gently heat-treated E. coli substrate cells is very similar to growth on untreated substrate cells, even though the former substrate cells are nonviable and substantially impaired in many metabolic activities.     

Molecular basis for the temperature sensitivity of Escherichia coli pth(Ts)

The gene pth, encoding peptidyl-tRNA hydrolase (Pth), is essential for protein synthesis and viability of Escherichia coli. Two pth mutants have been studied in depth: a pth(Ts) mutant isolated as temperature sensitive and a pth(rap) mutant selected as nonpermissive for bacteriophage lambda vegetative growth. Here we show that each mutant protein is defective in a different way. The Pth(Ts) protein was very unstable in vivo, both at 43 degrees C and at permissive temperatures, but its specific activity was comparable to that of the wild-type enzyme, Pth(wt). Conversely, the mutant Pth(rap) protein had the same stability as Pth(wt), but its specific activity was low. The thermosensitivity of the pth(Ts) mutant, presumably, ensues after Pth(Ts) protein levels are reduced at 43 degrees C. Conditions that increased the cellular Pth(Ts) concentration, a rise in gene copy number or diminished protein degradation, allowed cell growth at a nonpermissive temperature. Antibiotic-mediated inhibition of mRNA and protein synthesis, but not of peptidyl-tRNA drop-off, reduced pth(Ts) cell viability even at a permissive temperature. Based on these results, we suggest that Pth(Ts) protein, being unstable in vivo, supports cell viability only if its concentration is maintained above a threshold that allows general protein synthesis.     

Peptide nucleic acid (PNA) antisense effects in Escherichia coli

Antisense peptide nucleic acid (PNA) can be used to control cell growth, gene expression and growth phenotypes in the bacteria Escherichia coli. PNAs targeted to the RNA components of the ribosome can inhibit translation and cell growth, and PNAs targeted to mRNA can limit gene expression with gene and sequence specificity. In an E. coli cell extract, efficient inhibition is observed when using PNA concentrations in the nanomolar range, whereas micromolar concentrations are required for inhibition in growing cells. A mutant strain of E. coli that is more permeable to antibiotics also is more susceptible to antisense PNAs than the wild type. This chapter details methods for testing the antisense activities of PNA in E. coli. As an example of the specific antisense inhibition possible, we show the effects of an anti-beta-galactosidase PNA in comparison to control PNAs. With improvements in cell uptake, antisense PNAs may find applications as antimicrobial agents and as tools for microbial functional genomics.     

Four sulfhydryl-modifying compounds cause different structural damage but similar functional damage in murine lymphocytes

Four thiol-modifying compounds were used to inhibit murine lymphocyte mitogenesis. The compounds were a copper sulfate/O-phenanthroline complex (CuP) to oxidize surface thiols, N-ethyl maleimide (NEM) to alkylate surface and intracellular thiols, D,L-buthionine-S,R-sulfoximine (BSO) to prevent synthesis of glutathione, and hydrogen peroxide, which reacts with various cellular constituents, including sulfhydryls. Splenic lymphocytes were incubated with one of the four compounds, washed, and then stimulated with the B cell mitogen, LPS, or the T cell mitogen, Con A. In spite of their differing chemical reactivities and differing effects on cell viability, lipids, and total, protein, and non-protein thiols, the four sulfhydryl-modifying compounds had very similar effects on the kinetics and inhibition of lymphocyte growth. All compounds had complex effects on mitogenesis, causing enhanced, delayed, or inhibited tritiated thymidine incorporation. Although the total thiol contents of untreated T cells and B cells were found to be equivalent, the LPS response consistently was inhibited by lower concentrations than the Con A response, suggesting that B cells were more sensitive than T cells to thiol modification. To compare compounds the efficiency of inhibition was determined by functionally relating reductions in mitogenesis with reductions in thiol content of the cells. The compounds differed in inhibitory efficiency; thus, damage to some thiols must be more important than damage to others. CuP ablated mitogenesis with the least change in thiol content. Therefore, surface sulfhydryls appear critical in lymphocyte mitogenesis. With all compounds inhibition of mitogenesis occurred over a very narrow range of thiol content, suggesting that the thiols important in inhibition were few in number relative to the total thiol content of the cell.     

A small molecule FAK kinase inhibitor,GSK2256098, inhibits growth and survival of pancreatic ductal adenocarcinoma cells

Focal adhesion kinase (FAK) hyperactivation is common in pancreatic ductal adenocarcinoma (PDAC). A small molecule, GSK2256098 (GlaxoSmithKline), has been developed to inhibit FAK activity through targeting the phosphorylation site of FAK, tyrosine (Y) 397. We sought to determine whether GSK2256098 inhibition of FAK Y397 phosphorylation attenuates PDAC-associated cell proliferation, motility and survival. Cultured PDAC cells were used as cellular models of GSK2256098-impaired abnormal growth. Western blot analysis, cell viability analysis, clonogenic survival, soft-agar and wound healing assays were performed. The responses of 6 PDAC cell lines in regards to FAK Y397 phosphorylation or activity to GSK2256098 treatments (0.1–10 μM) ranged from low (less than 20% inhibition) to high (more than 90% inhibition). The least and most sensitive cell lines (PANC-1 and L3.6P1) were selected for further analysis. GSK2256098 inhibition of FAK Y397 phosphorylation correlated with decreased levels of phosphorylated Akt and ERK in L3.6P1 cells. GSK2256098 decreased cell viability, anchorage-independent growth, and motility in a dose dependent manner. Current studies demonstrate that small molecule kinase inhibitors targeting FAK Y397 phosphorylation can inhibit PDAC cell growth. Assessments of FAK Y397 phosphorylation in biopsies may be used as a biomarker to select the subgroup of responsive patients and/or monitor the effects of GSK2256098 on FAK-modulated tumor growth during treatment.     

Role of protein synthesis in the survival of carbon-starved Escherichia coli K-12.

In a typical Escherichia coli K-12 culture starved for glucose, 50% of the cells lose viability in ca. 6 days (Reeve et al., J. Bacteriol. 157:758-763, 1984). Inhibition of protein synthesis by chloramphenicol resulted in a more rapid loss of viability in glucose-starved E. coli K-12 cultures. The more chloramphenicol added (i.e., the more protein synthesis was inhibited) and the earlier during starvation it was added, the greater was its effect on culture viability. Chloramphenicol was found to have the same effect on a relA strain as on an isogenic relA+ strain of E. coli. Addition of the amino acid analogs S-2-aminoethylcysteine, 7-azatryptophan, and p-fluorophenylalanine to carbon-starved cultures to induce synthesis of abnormal proteins had an effect on viability similar to that observed when 50 micrograms of chloramphenicol per ml was added at zero time for starvation. Both chloramphenicol and the amino acid analogs had delayed effects on viability, compared with their effects on synthesis of normal proteins. The need for protein synthesis did not arise from cryptic growth, since no cryptic growth of the starving cells was observed under the conditions used. From these and previous results obtained from work with peptidase-deficient mutants of E. coli K-12 and Salmonella typhimurium LT2 (Reeve et al., J. Bacteriol. 157:758-763, 1984), we concluded that a number of survival-related proteins are synthesized by E. coli K-12 cells as a response to carbon starvation. These proteins are largely synthesized during the early hours of starvation, but their continued activity is required for long-term survival.     

Characterization of the yaeL gene product and its S2P-protease motifs in Escherichia coli.

An Escherichia coli open reading frame, yaeL, encodes a predicted homolog of human site-2 protease (S2P), a putative membrane-bound zinc metalloproteinase involved in the proteolytic activation of regulatory factors for sterol biosynthesis and for stress responses. The potential importance of YaeL in processes analogous to the regulated intramembrane proteolysis in E. coli prompted us to characterize it. Cell fractionation and alkaline phosphatase fusion experiments established that YaeL has four transmembrane segments with both termini orienting toward the periplasm. A strain in which a chromosomal disruption of yaeL was combined with arabinose promoter-controlled yaeL on a plasmid enabled us to deplete this protein from the cell. The depletion was found to cause rapid loss of viability, cell elongation and growth cessation. Mutations affecting the HEXXH metalloproteinase motif and those affecting the LDG motif, conserved among S2Ps, abolished the ability of YaeL to support cell growth. These results indicate that YaeL is indispensable in E. coli, and probably functions as a metalloproteinase at the membrane.     

Effects of paraquat on Escherichia coli: differences between B and K-12 strains.

Escherichia coli B and K-12 are equally susceptible to the bacteriostatic effects of aerobic paraquat, but they differed strikingly when the lethality of paraquat was evaluated. E. coli B suffered an apparent loss of viability when briefly exposed to paraquat, whereas E. coli K-12 did not. This difference depended on the ability of the B strain, but not the K-12 strain, to retain internalized paraquat; the B strain was killed on aerobic tryptic soy-yeast extract plates during the incubation which preceded the counting of colonies. This difference in retention of paraquat between strains was demonstrated by delayed loss of viability, by growth inhibition, and by cyanide-resistant respiration after brief exposure to paraquat, washing, and testing in fresh medium. This difference was also shown by using [14C]paraquat. This previously unrecognized difference between E. coli B and K-12 has been the cause of apparently contradictory reports and should lead to some reevaluation of the pertinent literature.