Fast kinetics studies of Escherichia coli electrotransformation.

Direct gene transfer is achieved in Escherichia coli by use of square wave electric pulsing. As observed by video monitoring, the field pulse causes bacteria to orientate parallel to the field lines. Rapid kinetic turbidity changes indicate that this process happens quickly. In these circumstances, and in pulsing conditions prone to inducing transformation, only caps are affected by the field. Considerable cytoplasmic ion leakage occurs during the pulse, affecting the interfacial ionic concentration. The pulsing-buffer osmolarity has to be close to that used with protoplasts. Contact between the plasmid and the bacteria can be very short before the pulse but must be present during the pulse. The plasmid remains accessible to externally added DNases up to 5 days after the pulse, suggesting that the transfer step is slow. Electric-field-mediated transfer can be described in two steps: the anchoring process during the pulse, followed by the crossing of the membrane.     

Assessment of Escherichia coli B with enhanced permeability to fluorochromes for flow cytometric assays of bacterial cell function

BACKGROUND: Flow cytometry has become a choice methodology for microbiological research. However, functional cytometric assays in live bacteria are still limited. This is due, in part, to the cell wall impairing penetration of vital dyes in bacteria, thus imposing permeabilization procedures. These manipulations may affect cell physiology, provoke cell aggregation or lysis, and they are time-consuming. Escherichia coli B strains have been used for mutagenic assays because of an altered lipopolysaccharide that provokes increased membrane permeability. We assessed the use of these strains as possible alternatives for flow cytometric assays to avoid the permeabilization steps. METHODS: Suspensions of E. coli K-12 (strain AB1157) and E. coli B (strain WP2 uvrA/pKM101, denoted as strain IC188) were stained with several fluorochromes, including fluorescein isothiocyanate, propidium iodide, Nile Red, bis-(1,3-dibutylbarbituric acid) trimethine oxonol, hydroethidine, and dihydro-dichlorofluorescein diacetate, under basal conditions and following permeabilization, impairment of membrane potential, inhibition of dye efflux pump, and oxidative stress. Fluorescent staining of both strains was compared by epifluorescence microscopy and flow cytometry. RESULTS: The E. coli B strain IC188 exhibited more efficient staining with vital fluorochromes than the E. coli K-12 strain AB1157 and maintained a similar membrane potential. In addition, IC188 showed higher sensitivity than AB1157 to reveal oxidative stress when challenged with prooxidants. CONCLUSIONS: E. coli B strains may be useful for biochemical and toxicological studies based on flow cytometry and fluorescence microscopy.     

DNA unwinding step-size of E. coli RecBCD helicase determined from single turnover chemical quenched-flow kinetic studies

The mechanism by which Escherichia coli RecBCD DNA helicase unwinds duplex DNA was examined in vitro using pre-steady-state chemical quenched-flow kinetic methods. Single turnover DNA unwinding experiments were performed by addition of ATP to RecBCD that was pre-bound to a series of DNA substrates containing duplex DNA regions ranging from 24 bp to 60 bp. In each case, the time-course for formation of completely unwound DNA displayed a distinct lag phase that increased with duplex length, reflecting the transient formation of partially unwound DNA intermediates during unwinding catalyzed by RecBCD. Quantitative analysis of five independent sets of DNA unwinding time courses indicates that RecBCD unwinds duplex DNA in discrete steps, with an average unwinding "step-size", m=3.9(+/-1.3)bp step(-1), with an average unwinding rate of k(U)=196(+/-77)steps s(-1) (mk(U)=790(+/-23)bps(-1)) at 25.0 degrees C (10mM MgCl(2), 30 mM NaCl (pH 7.0), 5% (v/v) glycerol). However, additional steps, not linked directly to DNA unwinding are also detected. This kinetic DNA unwinding step-size is similar to that determined for the E.coli UvrD helicase, suggesting that these two SF1 superfamily helicases may share similar mechanisms of DNA unwinding.     

Electropermeabilization of mammalian cells to macromolecules: control by pulse duration.

Membrane electropermeabilization to small molecules depends on several physical parameters (pulse intensity, number, and duration). In agreement with a previous study quantifying this phenomenon in terms of flow (Rols and Teissié, Biophys. J. 58:1089-1098, 1990), we report here that electric field intensity is the deciding parameter inducing membrane permeabilization and controls the extent of the cell surface where the transfer can take place. An increase in the number of pulses enhances the rate of permeabilization. The pulse duration parameter is shown to be crucial for the penetration of macromolecules into Chinese hamster ovary cells under conditions where cell viability is preserved. Cumulative effects are observed when repeated pulses are applied. At a constant number of pulses/pulse duration product, transfer of molecules is strongly affected by the time between pulses. The resealing process appears to be first-order with a decay time linearly related to the pulse duration. Transfer of macromolecules to the cytoplasm can take place only if they are present during the pulse. No direct transfer is observed with a postpulse addition. The mechanism of transfer of macromolecules into cells by electric field treatment is much more complex than the simple diffusion of small molecules through the electropermeabilized plasma membrane.     

Viability and metabolic capability are maintained by Escherichia coli, Pseudomonas aeruginosa, and Streptococcus lactis at very low adenylate energy charge.

Metabolic regulation by nucleotides has been examined in several bacteria within the context of the adenylate energy charge (EC) concept. The ECs of bacteria capable of only fermentative metabolism (Streptococcus lactis and the ATPase-less mutant Escherichia coli AN718) fell to less than 0.2 under carbon-limiting conditions, but the bacteria were able to step up the EC to greater than 0.8 upon exposure to nutrient sugars. Similarly, nongrowing E. coli 25922, whose EC had been artificially lowered to less than 0.1 by the addition of the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP), was able to immediately step up the EC to 0.8 to 0.9 upon the addition of glucose but was unable to respond to respiratory substrates. The EC of respiring bacteria (E. coli 25922 and Pseudomonas aeruginosa 27853) fell to 0.3 to 0.4 under certain limiting growth conditions, but the bacteria also responded immediately when challenged with succinate to give EC values greater than 0.8. These bacteria could not step up the EC with respiratory substrates in the presence of CCCP. For all bacteria, the loss of the ability to step up the EC was attributable to the loss of nutrient transport function. Mixtures of viable and HOCl-killed E. coli 25922 were able to step up the EC in proportion to the fraction of surviving cells. The data indicate that nucleotide phosphorylation levels are not regulatory in nongrowing bacteria but that the EC step-up achievable upon nutrient addition may be an accurate index of viability.     

Kinetic studies of recA protein binding to a fluorescent single-stranded polynucleotide

Fluorescence spectroscopy was used to investigate the binding of Escherichia coli recA protein to a single-stranded polynucleotide. Poly(deoxy-1,N6-ethenoadenylic acid) was prepared by reaction of chloroacetaldehyde with poly(deoxyadenylic acid). The fluorescence of poly(deoxy-1,N6-ethenoadenylic acid) was enhanced upon recA protein binding. The kinetics of the binding process were studied as a function of several parameters: ionic concentration (KCl and MgCl2), pH, nature of the nucleoside triphosphate [adenosine 5'-triphosphate or adenosine 5'-O-(gamma-thiotriphosphate)], protein and polynucleotide concentrations, polynucleotide chain length, and order of sequential additions. The observed kinetic curves exhibited a lag phase followed by a slow binding process characteristic of a nucleation-elongation mechanism with an additional slow step governing the rate of the association process. The lag phase reflecting the nucleation step was not observed when the protein was first bound to the polynucleotide before addition of adenosine 5'-triphosphate. Adenosine 5'-triphosphate induced a dissociation of the recA protein, which was immediately followed by binding of the recA-adenosine 5'-triphosphate-Mg2+ ternary complex. The origin of this "mnemonic effect" and of the different kinetic steps is discussed with respect to protein conformational changes and aggregation phenomena.     

Recombinant Escherichia coli GMP reductase: kinetic, catalytic and chemical mechanisms, and thermodynamics of enzyme-ligand binary complex formation

Guanosine monophosphate (GMP) reductase catalyzes the reductive deamination of GMP to inosine monophosphate (IMP). GMP reductase plays an important role in the conversion of nucleoside and nucleotide derivatives of guanine to adenine nucleotides. In addition, as a member of the purine salvage pathway, it also participates in the reutilization of free intracellular bases. Here we present cloning, expression and purification of Escherichia coli guaC-encoded GMP reductase to determine its kinetic mechanism, as well as chemical and thermodynamic features of this reaction. Initial velocity studies and isothermal titration calorimetry demonstrated that GMP reductase follows an ordered bi-bi kinetic mechanism, in which GMP binds first to the enzyme followed by NADPH binding, and NADP(+) dissociates first followed by IMP release. The isothermal titration calorimetry also showed that GMP and IMP binding are thermodynamically favorable processes. The pH-rate profiles showed groups with apparent pK values of 6.6 and 9.6 involved in catalysis, and pK values of 7.1 and 8.6 important to GMP binding, and a pK value of 6.2 important for NADPH binding. Primary deuterium kinetic isotope effects demonstrated that hydride transfer contributes to the rate-limiting step, whereas solvent kinetic isotope effects arise from a single protonic site that plays a modest role in catalysis. Multiple isotope effects suggest that protonation and hydride transfer steps take place in the same transition state, lending support to a concerted mechanism. Pre-steady-state kinetic data suggest that product release does not contribute to the rate-limiting step of the reaction catalyzed by E. coli GMP reductase.     

Kinetics of substrate recognition and cleavage by human 8-oxoguanine-DNA glycosylase

Human 8-oxoguanine-DNA glycosylase (hOgg1) excises 8-oxo-7,8-dihydroguanine (8-oxoG) from damaged DNA. We report a pre-steady-state kinetic analysis of hOgg1 mechanism using stopped-flow and enzyme fluorescence monitoring. The kinetic scheme for hOgg1 processing an 8-oxoG:C-containing substrate was found to include at least three fast equilibrium steps followed by two slow, irreversible steps and another equilibrium step. The second irreversible step was rate-limiting overall. By comparing data from Ogg1 intrinsic fluorescence traces and from accumulation of products of different types, the irreversible steps were attributed to two main chemical steps of the Ogg1-catalyzed reaction: cleavage of the N-glycosidic bond of the damaged nucleotide and β-elimination of its 3′-phosphate. The fast equilibrium steps were attributed to enzyme conformational changes during the recognition of 8-oxoG, and the final equilibrium, to binding of the reaction product by the enzyme. hOgg1 interacted with a substrate containing an aldehydic AP site very slowly, but the addition of 8-bromoguanine (8-BrG) greatly accelerated the reaction, which was best described by two initial equilibrium steps followed by one irreversible chemical step and a final product release equilibrium step. The irreversible step may correspond to β-elimination since it is the very step facilitated by 8-BrG.     

Different aa-tRNAs are selected uniformly on the ribosome

Ten E. coli aminoacyl-tRNAs (aa-tRNAs) were assessed for their ability to decode cognate codons on E. coli ribosomes by using three assays that evaluate the key steps in the decoding pathway. Despite a wide variety of structural features, each aa-tRNA exhibited similar kinetic and thermodynamic properties in each assay. This surprising kinetic and thermodynamic uniformity is likely to reflect the importance of ribosome conformational changes in defining the rates and affinities of the decoding process as well as the evolutionary "tuning" of each aa-tRNA sequence to modify their individual interactions with the ribosome at each step.     

Effect of electric field vectoriality on electrically mediated gene delivery in mammalian cells

Electropermeabilization is a nonviral method used to transfer genes into living cells. Up to now, the mechanism is still to be elucidated. Since cell permeabilization, a prerequired for gene transfection, is triggerred by electric field, its characteristics should depend on its vectorial properties. The present investigation addresses the effect of pulse polarity and orientation on membrane permeabilization and gene delivery by electric pulses applied to cultured mammalian cells. This has been directly observed at the single-cell level by using digitized fluorescence microscopy. While cell permeabilization is only slightly affected by reversing the polarity of the electric pulses or by changing the orientation of pulses, transfection level increases are observed. These last effects are due to an increase in the cell membrane area where DNA interacts. Fluorescently labelled plasmids only interact with the electropermeabilized side of the cell facing the cathode. The plasmid interaction with the electropermeabilized cell surface is stable and is not affected by pulses of reversed polarities. Under such conditions, DNA interacts with the two sites of the cell facing the two electrodes. When changing both the pulse polarity and their direction, DNA interacts with the whole membrane cell surface. This is associated with a huge increase in gene expression. This present study demonstrates the relationship between the DNA/membrane surface interaction and the gene transfer efficiency, and it allows to define the experimental conditions to optimize the yield of transfection of mammalian cells.     

The methionine biosynthetic pathway from homoserine in Pseudomonas putida involves the metW, metX, metZ, metH and metE gene products

Biosynthesis of methionine from homoserine in Pseudomonas putida takes place in three steps. The first step is the acylation of homoserine to yield an acyl-L-homoserine. This reaction is catalyzed by the products of the metXW genes and is equivalent to the first step in enterobacteria, gram-positive bacteria and fungi, except that in these microorganisms the reaction is catalyzed by a single polypeptide (the product of the metA gene in Escherichia coli and the met5 gene product in Neurospora crassa). In Pseudomonas putida, as in gram-positive bacteria and certain fungi, the second and third steps are a direct sulfhydrylation that converts the O-acyl-L-homoserine into homocysteine and further methylation to yield methionine. The latter reaction can be mediated by either of the two methionine synthetases present in the cells.     

A Love wave immunosensor for whole E. coli bacteria detection using an innovative two-step immobilisation approach

The efficiency of a monomolecular film of (3-glycidoxypropyl) trimethoxysilane (GPTS) on a shear horizontal guided (Love) acoustic wave immunosensor to detect whole Escherichia coli (E. coli) bacteria is demonstrated. Direct anti-E. coli antibodies grafting onto the sensor surface did not lead to a significant bacteria immobilisation, partially attributed to the SiO2 sensor surface roughness. An innovative method has been set up to get around this difficulty and to detect whole bacteria. It consists in grafting goat anti-mouse antibodies (GAM) onto the sensor surface in a first step and introducing E. coli bacteria mixed with anti-E. coli antibodies onto the sensor in a second step. We describe the characteristics of such a technique like sample preparation time (lower than 30 min) and temperature improvements. A 37 degrees C experimental temperature led to the fastest bacteria binding kinetic, reducing the total analysis time. This method enables to keep the specificity of the antibody/antigen interaction and provides significant results in less than 1h. This leads to a detection threshold of 10(6) bacteria/ml in a 500 microl chamber.     

Generation of buds, swellings, and branches instead of filaments after blocking the cell cycle of Rhizobium meliloti.

Inhibition of cell division in rod-shaped bacteria such as Escherichia coli and Bacillus subtilis results in elongation into long filaments many times the length of dividing cells. As a first step in characterizing the Rhizobium meliloti cell division machinery, we tested whether R. meliloti cells could also form long filaments after cell division was blocked. Unexpectedly, DNA-damaging agents, such as mitomycin C and nalidixic acid, caused only limited elongation. Instead, mitomycin C in particular induced a significant proportion of the cells to branch at the poles. Moreover, methods used to inhibit septation, such as FtsZ overproduction and cephalexin treatment, induced growing cells to swell, bud, or branch while increasing in mass, whereas filamentation was not observed. Overproduction of E. coli FtsZ in R. meliloti resulted in the same branched morphology, as did overproduction of R. meliloti FtsZ in Agrobacterium tumefaciens. These results suggest that in these normally rod-shaped species and perhaps others, branching and swelling are default pathways for increasing mass when cell division is blocked.     

Effects of temperature and ATP on the kinetic mechanism and kinetic step-size for E.coli RecBCD helicase-catalyzed DNA unwinding

The kinetic mechanism by which Escherichia coli RecBCD helicase unwinds duplex DNA was studied using a fluorescence stopped-flow method. Single turnover DNA unwinding experiments were performed using a series of fluorescently labeled DNA substrates containing duplex DNA regions ranging from 24 bp to 60 bp. All or no DNA unwinding time courses were obtained by monitoring the changes in fluorescence resonance energy transfer between a Cy3 donor and Cy5 acceptor fluorescent pair placed on opposite sides of a nick in the duplex DNA. From these experiments one can determine the average rates of DNA unwinding as well as a kinetic step-size, defined as the average number of base-pairs unwound between two successive rate-limiting steps repeated during DNA unwinding. In order to probe how the kinetic step-size might relate to a mechanical step-size, we performed single turnover experiments as a function of [ATP] and temperature. The apparent unwinding rate constant, kUapp, decreases with decreasing [ATP], exhibiting a hyperbolic dependence on [ATP] (K1/2=176(+/-30) microM) and a maximum rate of kUapp=204(+/-4) steps s(-1) (mkUapp=709(+/-14) bp s(-1)) (10 mM MgCl2, 30 mM NaCl (pH 7.0), 5% (v/v) glycerol, 25.0 degrees C). kUapp also increases with increasing temperature (10-25 degrees C), with Ea=19(+/-1) kcal mol(-1). However, the average kinetic step-size, m=3.9(+/-0.5) bp step(-1), remains independent of [ATP] and temperature. This indicates that even though the values of the rate constants change, the same elementary kinetic step in the unwinding cycle remains rate-limiting over this range of conditions and this kinetic step remains coupled to ATP binding. The implications of the constancy of the measured kinetic step-size for the mechanism of RecBCD-catalyzed DNA unwinding are discussed.     

Role of membrane potential on artificial transformation of E. coli with plasmid DNA

The standard method of transformation of Escherichea coli with plasmid DNA involves two important steps: cells are first suspended in 100mM CaCl(2) at 0 degrees C (in which DNA is added), followed by the administration of a heat-pulse from 0 to 42 degrees C for 90s [Cohen, S., Chang, A., Hsu, L., 1972. Nonchromosomal antibiotic resistance in bacteria. Proc. Natl. Acad. Sci. U.S.A., 69, 2110-2114]. The first step makes the cells competent for uptake of DNA and the second step is believed to facilitate the DNA entry into the cells by an unknown mechanism. In this study, the measure of membrane potential of the intact competent cells, at different steps of transformation process, either by the method of spectrofluorimetry or that of flow cytometry, indicates that the heat-pulse step (0-->42 degrees C) heavily decreases the membrane potential. A subsequent cold shock (42-->0 degrees C) raises the potential further to its original value. Moreover, the efficiency of transformation of E. coli XL1 Blue cells with plasmid pUC19 DNA remains unaltered when the heat-pulse step is replaced by the incubation of the DNA-adsorbed competent cells with 10 microM carbonyl cyanide m-chlorophenyl hydrazone (CCCP) for 90s at 0 degrees C. Since the CCCP, a well-known protonophore, reduces membrane potential by dissipating the proton-motive-force (PMF) across E. coli plasma membrane, our experimental results suggest that the heat-pulse step of the standard transformation procedure facilitates DNA entry into the cells by lowering the membrane potential.     

The interaction of arginine- and tryptophan-rich cyclic hexapeptides with Escherichia coli membranes.

Cyclization of R- and W-rich hexapeptides has been found to enhance specifically the antimicrobial activity against Gram-negative Escherichia coli. To gain insight into the role of the bacterial outer membrane in mediating selectivity, we assayed the activity of cyclic hexapeptides derived from the parent sequence c-(RRWWRF) against several E. coli strains and Bacillus subtilis, L-form bacteria, and E. coli lipopolysaccharide (LPS) mutant strains, and we also investigated the peptide-induced permeabilization of the outer and inner membrane of E. coli. Wall-deficient L-form bacteria were distinctly less susceptible than the wild type strain. The patterns of peptide-induced permeabilization of the outer and inner E. coli membranes correlated well with the antimicrobial activity, confirming that membrane permeabilization is a detrimental effect of the peptides upon bacteria. Truncation of LPS had no influence on the activity of the cyclic parent peptide, but the highly active c-(RRWFWR), with three adjacent aromatic residues, required the complete LPS for maximal activity. Furthermore, differences in the activity of the parent peptide and its all-D sequence indicated stereospecific interactions with the LPS mutant strains. We suggest that, depending on the primary sequence of the peptides, either hydrophobic interactions with the fatty acid chains of lipid A, or electrostatic interactions disturbing the polar core region and interference with saccharide-saccharide interactions prevail in the barrier-disturbing effect upon the outer membrane and thereby provide peptide accessibility to the inner membrane. The results underline the importance of tryptophan and arginine residues and their relative location for a high antimicrobial effect, and the activity-modulating function of the outer membrane of E. coli. In addition to membrane permeabilization, the data provided evidence for the involvement of other mechanisms in growth inhibition and killing of bacteria.     

FabG, an NADPH-dependent 3-ketoacyl reductase of Pseudomonas aeruginosa, provides precursors for medium-chain-length poly-3-hydroxyalkanoate biosynthesis in Escherichia coli

Escherichia coli hosts expressing fabG of Pseudomonas aeruginosa showed 3-ketoacyl coenzyme A (CoA) reductase activity toward R-3-hydroxyoctanoyl-CoA. Furthermore, E. coli recombinants carrying the poly-3-hydroxyalkanoate (PHA) polymerase-encoding gene phaC in addition to fabG accumulated medium-chain-length PHAs (mcl-PHAs) from alkanoates. When E. coli fadB or fadA mutants, which are deficient in steps downstream or upstream of the 3-ketoacyl-CoA formation step during beta-oxidation, respectively, were transformed with fabG, higher levels of PHA were synthesized in E. coli fadA, whereas similar levels of PHA were found in E. coli fadB, compared with those of the corresponding mutants carrying phaC alone. These results strongly suggest that FabG of P. aeruginosa is able to reduce mcl-3-ketoacyl-CoAs generated by the beta-oxidation to 3-hydroxyacyl-CoAs to provide precursors for the PHA polymerase.     

Sister chromatid resolution: a cohesin releasing network and beyond

When chromosomes start to assemble in mitotic prophase, duplicated chromatids are not discernible within each chromosome. As condensation proceeds, they gradually show up, culminating in two rod-shaped structures apposed along their entire length within a metaphase chromosome. This process, known as sister chromatid resolution, is thought to be a prerequisite for rapid and synchronous separation of sister chromatids in anaphase. From a mechanistic point of view, the resolution process can be dissected into three distinct steps: (1) release of cohesin from chromosome arms; (2) formation of chromatid axes mediated by condensins; and (3) untanglement of inter-sister catenation catalyzed by topoisomerase II (topo II). In this review article, we summarize recent progress in our understanding the molecular mechanisms of sister chromatid resolution with a major focus on its first step, cohesin release. An emerging idea is that this seemingly simple step is regulated by an intricate network of positive and negative factors, including cohesin-binding proteins and mitotic kinases. Interestingly, some key factors responsible for cohesin release in early mitosis also play important roles in controlling cohesin functions during interphase. Finally, we discuss how the step of cohesin release might mechanistically be coordinated with the actions of condensins and topo II.