Showing papers on "Lysis published in 2004"

Improved extraction of PCR-quality community DNA from digesta and fecal samples.

Abstract: Several DNA extraction methods have been reported for use with digesta or fecal samples, but problems are often encountered in terms of relatively low DNA yields and/or recovering DNA free of inhibitory substances. Here we report a modified method to extract PCR-quality microbial community DNA from these types of samples, which employs bead beating in the presence of high concentrations of sodium dodecyl sulfate (SDS), salt, and EDTA, and with subsequent DNA purification by QIA® columns [referred to as repeated bead beating plus column (RBB+C) method]. The RBB+C method resulted in a 1.5- to 6-fold increase in DNA yield when compared to three other widely used methods. The community DNA prepared with the RBB+C method was also free of inhibitory substances and resulted in improved denaturing gradient gel electrophoresis (DGGE) profiles, which is indicative of a more complete lysis and representation of microbial diversity present in such samples.

DNA-containing membrane vesicles of Pseudomonas aeruginosa PAO1 and their genetic transformation potential

Abstract: Natural membrane vesicles (n-MVs) produced by Pseudomonas aeruginosa PAO1 and PAO1 carrying plasmid pAK1900 (p-MVs) were purified and analysed for DNA content. The MVs were isolated by a procedure designed to ensure no cellular contamination from the parent MV-producing cells. Fluorometry analysis revealed that p-MVs were associated with 7·80 ng DNA (20 μg MV protein)−1. PCR analysis using specific primers for pAK1900 sequences and a chromosomal target, oprL, indicated that only plasmid DNA was contained within the lumen of p-MVs after exogenous DNA was digested by DNase. MVs have previously been shown to be capable of fusing into the outer membrane (OM) of PAO1 and Escherichia coli DH5α. Accordingly, p-MVs should deliver the plasmid into the periplasm, where it would only have to by-pass the plasma membrane (PM) for effective transformation. It was speculated that p-MVs should increase transformation efficiency but the data suggested otherwise. p-MVs did not transform PAO1 nor DH5α under a variety of transforming conditions. To characterize p-MVs and to ensure that membrane-encapsulated pAK1900 was not derived from a small proportion of lysed cells within the culture and bound by PM instead of OM, which typically forms n-MVs, the physical and ultrastructural differences between n- and p-MVs were determined. Cryo-transmission electron microscopy (cryo-TEM) revealed that n-MVs and p-MVs closely resembled isolated OM. Buoyant density measurements using isopycnic sucrose gradients on isolated PM, OM, n- and p-MVs demonstrated that isolated OM and n-MVs both fractionated into two bands (ρ=1·240 and 1·260 g ml−1). p-MVs also produced two bands but at two different densities (ρ=1·250 and 1·265 g ml−1) which may be attributed to the presence of DNA. SDS-PAGE showed that p-MVs possessed most major OM proteins and also contained 43·70 nmol 3-deoxy-d-manno-octulosonic acid (KDO) (mg protein)−1 as an LPS marker. The amount of NADH oxidase activity, a PM enzyme, in the p-MVs was barely detectable. These data strongly suggest that p-MVs are OM-based, with little if any PM material associated with them. The possibility of whether exogenous plasmid DNA could enter n-MVs once the vesicles had departed from cells was also tested; surprisingly, a small amount of DNA could. Accordingly, the data suggest that DNA can be taken up by MVs using two separate routes: (1) via a periplasmic route and (2) via an extracellular, exogenous route.

Integration of single cell injection, cell lysis, separation and detection of intracellular constituents on a microfluidic chip.

Abstract: A microfluidic system was developed for the analysis of single biological cells, with functional integration of cell sampling, single cell loading, docking, lysing, and capillary electrophoretic (CE) separation with laser induced fluorescence (LIF) detection in microfabricated channels of a single glass chip. Channels were 12 µm deep and 48 µm wide, with a simple crossed-channel design. The effective separation channel length was 35 mm. During sampling with a cell suspension (cell population 1.2 × 105 cells per mL in physiological salt solution), differential hydrostatic pressure (created by adjusting liquid levels in the four reservoirs) was used to control cell flow exclusively through the channel crossing. Single cell loading into the separation channel was achieved by electrophoretic means by applying a set of potentials at the four reservoirs, counteracting the hydrostatic flow. A special docking (adhering) procedure for the loaded cell was applied before lysis by repeatedly connecting and disconnecting a set of low potentials, allowing precise positioning of the cell within the separation channel. Cell lysis was then effected within 40 ms under an applied CE separation voltage of 1.4 kV (280 V cm−1) within the working electrolyte (pH 9.2 borate buffer) without additional lysates. The docked lysing approach reduced dispersion of released intracellular constituents, and significantly improved the reproducibility of CE separations. Glutathione (GSH) was used as a model intracellular component in single human erythrocyte cells. NDA derivatized GSH was detected using LIF. A throughput of 15 samples h−1, a retention time precision of 2.4% RSD was obtained for 14 consecutively injected cells. The average cellular concentration of GSH in human erythrocytes was found to be 7.2 × 10−4 ± 3.3 × 10−4 M (63 ± 29 amol per cell). The average separation efficiency for GSH in lysed cells was 2.13 × 106 ± 0.4 × 106 plates per m, and was about a factor of 5 higher than those obtained with GSH standards using pinched injection.

Rapid isolation of yeast genomic DNA: Bust n' Grab

Abstract: Mutagenesis of yeast artificial chromosomes (YACs) often requires analysis of large numbers of yeast clones to obtain correctly targeted mutants. Conventional ways to isolate yeast genomic DNA utilize either glass beads or enzymatic digestion to disrupt yeast cell wall. Using small glass beads is messy, whereas enzymatic digestion of the cells is expensive when many samples need to be analyzed. We sought to develop an easier and faster protocol than the existing methods for obtaining yeast genomic DNA from liquid cultures or colonies on plates. Repeated freeze-thawing of cells in a lysis buffer was used to disrupt the cells and release genomic DNA. Cell lysis was followed by extraction with chloroform and ethanol precipitation of DNA. Two hundred ng – 3 μg of genomic DNA could be isolated from a 1.5 ml overnight liquid culture or from a large colony. Samples were either resuspended directly in a restriction enzyme/RNase coctail mixture for Southern blot hybridization or used for several PCR reactions. We demonstrated the utility of this method by showing an analysis of yeast clones containing a mutagenized human β-globin locus YAC. An efficient, inexpensive method for obtaining yeast genomic DNA from liquid cultures or directly from colonies was developed. This protocol circumvents the use of enzymes or glass beads, and therefore is cheaper and easier to perform when processing large numbers of samples.

Detergent Effects of Sodium Deoxycholate Are a Major Feature of an Injectable Phosphatidylcholine Formulation Used for Localized Fat Dissolution

Abstract: Background Phosphatidylcholine injections are becoming an increasingly popular technique to treat localized fat accumulation. This formula is composed primarily of phosphatidylcholine and sodium deoxycholate, a bile salt used to solubilize the natural phospholipid in water. The mechanism through which this injectable phosphatidylcholine formulation causes localized fat reduction is unknown. Objective To investigate the active component and mechanism of action of an injectable phosphatidylcholine formulation in clinical use. Methods Cell viability and cell membrane lysis assays were performed on cell cultures and porcine skin after treatment with the phosphatidylcholine formula, isolated sodium deoxycholate, or common laboratory detergents Triton-X 100 and Empigen BB. In addition, we described the histologic changes after injection of these substances into porcine tissue. Results A significant and comparable loss of cell viability, cell membrane lysis, and disruption of fat and muscle architecture was seen in cell cultures and tissue specimens treated with the phosphatidylcholine formula and isolated sodium deoxycholate. These findings were similar to the effects produced after treatment with laboratory detergents. Conclusions The phosphatidylcholine formula popularly used in subcutaneous injections for fat dissolution works primarily as a detergent causing nonspecific lysis of cell membranes. Our findings suggest that sodium deoxycholate is the major active component responsible for cell lysis. Detergent substances may have a role in eliminating unwanted adipose tissue. It is advised that physicians use caution until adequate safety data are available.

Continuous flow microfluidic device for rapid erythrocyte lysis.

Abstract: Leukocyte isolation from whole blood to study inflammation requires the removal of contaminating erythrocytes. Leukocytes, however, are sensitive to prolonged exposure to hyper/hypoosmotic solutions, temperature changes, mechanical manipulation, and gradient centrifugation. Even though care is taken to minimize leukocyte activation and cell loss during erythrocyte lysis, it is often not possible to completely avoid it. Most procedures for removal of contaminating erythrocytes from leukocyte preparations are designed for bulk processing of blood, where the sample is manipulated for longer periods of time than necessary at the single-cell level. Ammonium chloride-mediated lysis is the most commonly used method to obtain enriched leukocyte populations but has been shown to cause some activation and selective loss of certain cell types. The leukocyte yield and subsequent activation status of residual leukocytes after NH4Cl-mediated lysis have been shown to depend on the time of exposure to the lysis buffer. W...

Cell lysis on a microfluidic CD (compact disc)

Abstract: Cell lysis was demonstrated on a microfluidic CD (Compact Disc) platform. In this purely mechanical lysis method, spherical particles (beads) in a lysis chamber microfabricated in a CD, cause disruption of mammalian (CHO-K1), bacterial (Escherichia coli), and yeast (Saccharomyces cerevisiae) cells. Interactions between beads and cells are generated in the rimming flow established inside a partially filled annular chamber in the CD rotating around a horizontal axis. To maximize bead–cell interactions in the lysis chamber, the CD was spun forward and backwards around this axis, using high acceleration for 5 to 7 min. Investigation on inter-particle forces (friction and collision) identified the following parameters; bead density, angular velocity, acceleration rate, and solid volume fraction as having the most significant contribution to cell lysis. Cell disruption efficiency was verified either through direct microscopic viewing or measurement of the DNA concentration after cell lysing. Lysis efficiency relative to a conventional lysis protocol was approximately 65%. In the long term, this work is geared towards CD based sample-to-answer nucleic acid analysis which will include cell lysis, DNA purification, DNA amplification, and DNA hybridization detection.

Release of DNA into the medium by competent Streptococcus pneumoniae: kinetics, mechanism and stability of the liberated DNA

Abstract: The release of chromosomal DNA into culture media has been reported for several naturally transformable bacterial species, but a direct link between competence development and the liberation of DNA is generally lacking. Based on the analysis of strains with mutations in competence-regulatory genes and the use of conditions favouring or preventing competence, we provide evidence that DNA release is triggered by the induction of competence in Streptococcus pneumoniae. Kinetic analyses revealed that whereas competence was maximal 20 min after addition of competence-stimulating peptide, and then decreased, the amount of liberated DNA continued to increase and reached a maximum in stationary phase, when cells are no longer competent for DNA uptake. These data are not consistent with the proposal that release of DNA by a fraction of the population is coordinated with uptake by the remainder. Moreover, we observed that an unidentified DNase was specifically induced or released in competent cultures, and that together with the major pneumococcal endonuclease, EndA, it could degrade released DNA. Nearby complete abolition of release in a mutant lacking both the major autolysin, LytA, and the autolytic lysozyme, LytC, indicated that DNA liberation occurs by LytA-LytC-dependent cell lysis. These observations suggest that competence-dependent DNA release is one facet of a more general phenomenon of sensitization to autolysis that reaches its maximum in stationary phase.

Principles and reactions of protein extraction, purification, and characterization

Abstract: EXTRACTION OF PROTEIN Preparation of Buffers for Protein Extraction Use of Protease Inhibitors in Protein Extraction Use of Detergents in Protein Extraction Chemical Lysis for Protein Extraction Mechanical Lysis for Protein Extraction Preparation of Extract from Prokaryotes Extraction of Recombinant Protein from Bacteria Preparation of Extracts from Yeast Preparation of Extracts from Eukaryotes Preparation of Extracts from Plants Preparation of Membrane Extracts ESTIMATION OF PROTEIN Ultraviolet Absorption Methods Colorimetric Methods Fluorescent Methods ELECTROPHORETIC ANALYSES OF PROTEIN Driving Force of Electrophoresis Polyacrylamide Gel Electrophoresis (PAGE) Isoelectric Focusing (IEF) Two-Dimensional (2-D) Gel Electrophoresis Western Blotting Capillary Electrophoresis PURIFICATION OF PROTEIN General Consideration and Purification Strategy Non-Chromatographic Purification of Proteins Chromatographic Purification of Proteins ANTIBODIES: STRUCTURES, INTERACTIONS AND PRODUCTION Immune System and Antibody Response Structure of Antibodies Antigen-Antibody Interactions Production oof Antibodies Development of Monoclonal Antibodies Purification of Antibodies ANTIBODY LABELING, ANTIBODY DETECTION AND IMMUNOCHEMICAL TECHNIQUES Methods of Labeling Antibodies Detection of Antibody Binding Immunochemical Techniques: a Wide Range of Sensitive Assays for Detecting and Quantitating (Semi) Antigen-Antibody Reactions Immunoprecipitation Immunohistochemistry Flow Cytometry PURIFICATION OF GLYCOPROTEINS AND ANALYSES OF THEIR OLIGOSACCHARIDES Diagrams and Stereochemistry of Monosaccharides and Oligosaccharides Purification of Glycoproteins Release of Oligosaccharides From Glycoproteins Preparation of Glycopeptides by Proteolytic Cleavage Estimation of Carbohydrates Chromatographic Separation and Detection of Sugars Electrophoretic Separation Glycan Detection/Differentiation by Lectins Analyses of Carbohydrate Linkage

Cell-free synthesis of a functional ion channel in the absence of a membrane and in the presence of detergent.

Abstract: We have investigated the possibility of cell-fee synthesis of membrane proteins in the absence of a membrane and in the presence of detergent. We used the bacterial mechanosensitive channel MscL, a homopentamer, as a model protein. A wide range of nonionic or zwitterionic detergents, Triton X-100, Tween 20, Brij 58p, n-dodecyl ‚-D-maltoside, and CHAPS, were compatible with cell-free synthesis, while n-octyl ‚-D-glucoside and deoxycholate had an inhibitory effect. In vitro synthesis in the presence of Triton X-100 yielded milligram amounts of MscL per milliliter of lysate. Cross-linking experiments showed that the protein was able to oligomerize in detergents. When the purified protein was reconstituted in liposomes and studied by the patch-clamp technique, its activity at the single-molecule level was similar to that of the recombinant protein produced in Escherichia coli. Cell-free synthesis of membrane proteins should prove a valuable tool for the production of membrane proteins whose overexpression in heterologous systems is difficult.

Lactoferricin B inhibits bacterial macromolecular synthesis in Escherichia coli and Bacillus subtilis.

Abstract: Most antimicrobial peptides have an amphipathic, cationic structure, and an effect on the cytoplasmic membrane of susceptible bacteria has been postulated as the main mode of action. Other mechanisms have been reported, including inhibition of cellular functions by binding to DNA, RNA and proteins, and the inhibition of DNA and/or protein synthesis. Lactoferricin B (Lfcin B), a cationic peptide derived from bovine lactoferrin, exerts slow inhibitory and bactericidal activity and does not lyse susceptible bacteria, indicating a possible intracellular target. In the present study incorporation of radioactive precursors into DNA, RNA and proteins was used to demonstrate effects of Lfcin B on macromolecular synthesis in bacteria. In Escherichia coli UC 6782, Lfcin B induces an initial increase in protein and RNA synthesis and a decrease in DNA synthesis. After 10 min, the DNA-synthesis increases while protein and RNA-synthesis decreases significantly. In Bacillus subtilis, however, all synthesis of macromolecules is inhibited for at least 20 min. After 20 min RNA-synthesis increases. The results presented here show that Lfcin B at concentrations not sufficient to kill bacterial cells inhibits incorporation of radioactive precursors into macromolecules in both Gram-positive and Gram-negative bacteria.

Microfluidic chip for high efficiency DNA extraction

Abstract: A high efficiency DNA extraction microchip was designed to extract DNA from lysed cells using immobilized beads and the solution flowing back and forth. This chip was able to increase the extraction efficiency by 2-fold when there was no serum. When serum existed in the solution, the extraction efficiency of immobilized beads was 88-fold higher than that of free beads. The extraction efficiency of the microchip was tested under different conditions and numbers of E. coli cells. When the number of E. coli cells was between 106 and 108 in 25 µl of whole blood, the extraction efficiency using immobilized beads was only slightly higher than that using free beads (100 to 101 fold). When the number of E. coli cells was in the range 104 to 106 in 25 µl of whole blood, the extraction efficiency of immobilized beads was greater than that of the free beads (101 to 102 fold). When the number of E. coli cells was lower, in the range 103 to 104 in 25 µl of whole blood, the extraction efficiency of immobilized beads was much higher than that of the free beads (102 to 103 fold). This study indicated that DNA could be efficiently extracted even when the number of bacterial cells was smaller (105 to 103). This microfluidic extraction chip could find potential applications in rare sample genomic study.

DNA isolation from soil samples for cloning in different hosts

Abstract: Many protocols to extract DNA directly from soil samples have been developed in recent years. We employed two extraction methods which differed in the method of lysis and compared these methods with respect to yield, purity and degree of shearing. The main focus was on the specific isolation of DNA from different microorganisms, especially DNA from actinomycetes, as these cells are very difficult to lyse, in contrast to non-actinomycetes. Thus, we used both methods to isolate DNA from Pseudomonas, Arthrobacter and Rhodococcus and from soil spiked with the respective microorganisms. Both methods rendered high DNA yields with a low degree of shearing, but differed in the type of cells that were lysed. By one protocol (utilizing enzymatic lysis) only DNA from the Gram-negative Pseudomonas strain could be obtained whereas, by the other protocol (utilizing mechanical lysis), all microorganisms that were used could be lysed and DNA extracted from them. Using a combination of both protocols, DNA from those organisms could be obtained selectively. Furthermore, one of the protocols was modified, resulting in higher DNA yield and purity.

Pseudomonas fluorescens infection by bacteriophage ΦS1: the influence of temperature, host growth phase and media

Abstract: The influence of host growth temperature, phase and media, together with the effect of infection temperature on bacteriophage ΦS1 infection of Pseudomonas fluorescens were examined. The rates of cell lysis and phage release were determined and showed that the efficacy of phage infection was optimal with host cells grown and infected at 26 °C. The host physiological state also affected these rates. Infection was dependent on the presence of cell wall proteins with molecular weights of 17.5 ± 1 and 99 ± 5 kDa.

Acylation of SC4 dodecapeptide increases bactericidal potency against Gram-positive bacteria, including drug-resistant strains.

Abstract: We have conjugated dodecyl and octadecyl fatty acids to the N-terminus of SC4, a potently bactericidal, helix-forming peptide 12-mer (KLFKRHLKWKII), and examined the bactericidal activities of the resultant SC4 'peptide-amphiphile' molecules. SC4 peptide-amphiphiles showed up to a 30-fold increase in bactericidal activity against Gram-positive strains (Staphylococcus aureus, Streptococcus pyogenes and Bacillus anthracis), including S. aureus strains resistant to conventional antibiotics, but little or no increase in bactericidal activity against Gram-negative bacteria (Escherichia coli and Pseudomonas aeruginosa). Fatty acid conjugation improved endotoxin (lipopolysaccharide) neutralization by 3- to 6-fold. Although acylation somewhat increased lysis of human erythrocytes, it did not increase lysis of endothelial cells, and the haemolytic effects occurred at concentrations 10- to 100-fold higher than those required for bacterial cell lysis. For insight into the mechanism of action of SC4 peptide-amphiphiles, CD, NMR and fluorescence spectroscopy studies were performed in micelle and liposome models of eukaryotic and bacterial cell membranes. CD indicated that SC4 peptide-amphiphiles had the strongest helical tendencies in liposomes mimicking bacterial membranes, and strong membrane integration of the SC4 peptide-amphiphiles was observed using tryptophan fluorescence spectroscopy under these conditions; results that correlated with the increased bactericidal activities of SC4 peptide-amphiphiles. NMR structural analysis in micelles demonstrated that the two-thirds of the peptide closest to the fatty acid tail exhibited a helical conformation, with the positively-charged side of the amphipathic helix interacting more with the model membrane surface. These results indicate that conjugation of a fatty acid chain to the SC4 peptide enhances membrane interactions, stabilizes helical structure in the membrane-bound state and increases bactericidal potency.

High‐throughput laser‐mediated in situ cell purification with high purity and yield

Abstract: Background Technologies for purification of living cells have significantly advanced basic and applied research in many settings. Nevertheless, certain challenges remain, including the robust and efficient purification (e.g., high purity, yield, and sterility) of adherent and/or fragile cells and small cell samples, efficient cell cloning, and safe purification of biohazardous cells. In addition, existing purification methods are generally open loop and exhibit an inverse relation between cell purity and yield. Methods An automated closed-loop (i.e., employing feedback control) cell purification technology was developed by building upon medical laser applications and laser-based semiconductor manufacturing equipment. Laser-enabled analysis and processing has combined high-throughput in situ cell imaging with laser-mediated cell manipulation via large field-of-view optics and galvanometer steering. Laser parameters were determined for cell purification using three mechanisms (photothermal, photochemical, and photomechanical), followed by demonstration of system performance and utility. Results Photothermal purification required approximately 108 W/cm2 at 523 nm in the presence of Allura Red, resulting in immediate protein coagulation and cell necrosis. Photochemical purification required approximately 109 W/cm2 at 355 nm, resulting in apoptosis induction over 4 to 24 h. Photomechanical purification required more than 1010 W/cm2 independent of wavelength, resulting in immediate cell lysis. Each approach resulted in high efficiency purification (>99%) after a single operation, as demonstrated with eight cell types. An automated closed-loop process to re-image and irradiate remaining targets in situ was implemented, resulting in improved purification (99.5–100%) without decreasing cell yield or affecting sterility in this closed system. Efficient purification was demonstrated with B- and T-cell mixtures over a wide range of contaminating cell percentages (0.1–99%) and cell densities (104-106/cm2). Efficient cloning of 293T cells based on fluorescence with green fluorescent protein after plasmid transfection was also demonstrated. Conclusions In situ laser-mediated purification was achieved with nonadherent and adherent cells on the automated laser-enabled analysis and processing platform. Closed-loop processing routinely enabled greater than 99.5% purity with a greater than 90% cell yield in sample sizes ranging from 101 to 108 cells. Throughput ranged from approximately 103 to 105 total cells/s for contaminating percentages ranging from 99% to 0.1%, respectively. © 2004 Wiley-Liss, Inc.

Sonication to selectively lyse different cell types

Abstract: A sonication apparatus is directed to a microfluidic-based system to automate differential extraction of specific cell types within a mixed sample. The microfluidic-based system includes a sonication module for selective cell lysis, separating means to eliminate centrifugation, high surface area pillar chip modules to purify DNA from a cell lysate, and microfluidic circuitry to integrate the steps in an automated platform.

2D LC/MS analysis of membrane proteins from breast cancer cell lines MCF7 and BT474.

Abstract: Membrane proteins play a central role in the interaction of the cell with its environment and in the function of subcellular organelles. The current study focused on developing a better understanding of the membrane proteome of two well-characterized breast cancer cell lines. Membranes from osmotically lysed BT474 and MCF7 cells were treated with cyanogen bromide followed by a combination of trypsin and Staphylococcus V8 protease to obtain hydrophilic peptides from membrane proteins. The complex peptide mixtures obtained were separated by 2-dimensional liquid chromatography coupled online with a nano-electrospray ionization ion trap mass spectrometer (2D LC/nanoESI-MS). The strong cation exchange column used in the first dimension of the separation was eluted in an automated fashion using a series of salt steps of increasing concentration. Peptides eluted from each of the salt steps were separated using a capillary reversed-phase HPLC column, the output of which was directed through a nano-electrospray fused silica tip into the mass spectrometer. Peptides were fragmented by collision-induced dissociation (CID) and analyzed by data-dependent MS/MS followed by database searching using the Sequest algorithm. Analysis of the data revealed both similarities and expected differences between proteins identified from these cell lines. As demonstrated by others, mRNA and the HER2/neu protein tyrosine kinase-linked receptor in BT474 cells is up regulated compared to its level in MCF7, while the expression of the estrogen receptor alpha is known to be up regulated in MCF7 cells. As expected, our studies showed identification of peptides from HER2 in BT474 while estrogen receptor peptides were detected in the MCF7 line. A total of 604 proteins were identified from BT474 membranes while 313 proteins were found from MCF7. The results are discussed in terms of the known differences in both protein and mRNA expression between these two breast cancer cell lines and also in the context of other known phenotypic differences between these cells.

Display of bacterial lipase on the Escherichia coli cell surface by using FadL as an anchoring motif and use of the enzyme in enantioselective biocatalysis

Abstract: We have developed a novel cell surface display system by employing FadL as an anchoring motif, which is an outer membrane protein involved in long-chain fatty acid transport in Escherichia coli. A thermostable Bacillus sp. strain TG43 lipase (44.5 kDa) could be successfully displayed on the cell surface of E. coli in an active form by C-terminal deletion-fusion of lipase at the ninth external loop of FadL. The localization of the truncated FadL-lipase fusion protein on the cell surface was confirmed by confocal microscopy and Western blot analysis. Lipase activity was mainly detected with whole cells, but not with the culture supernatant, suggesting that cell lysis was not a problem. The activity of cell surface-displayed lipase was examined at different temperatures and pHs and was found to be the highest at 50°C and pH 9 to 10. Cell surface-displayed lipase was quite stable, even at 60 and 70°C, and retained over 90% of the full activity after incubation at 50°C for a week. As a potential application, cell surface-displayed lipase was used as a whole-cell catalyst for kinetic resolution of racemic methyl mandelate. In 36 h of reaction, (S)-mandelic acid could be produced with the enantiomeric excess of 99% and the enantiomeric ratio of 292, which are remarkably higher than values obtained with crude lipase or cross-linked lipase crystal. These results suggest that FadL may be a useful anchoring motif for displaying enzymes on the cell surface of E. coli for whole-cell biocatalysis.

Proposal for molecular mechanism of thionins deduced from physico-chemical studies of plant toxins

Abstract: We propose a molecular model for phospholipid membrane lysis by the ubiquitous plant toxins called thionins. Membrane lysis constitutes the first major effect exerted by these toxins that initiates a cascade of cytoplasmic events leading to cell death. X-ray crystallography, solution nuclear magnetic resonance (NMR) studies, small angle X-ray scattering and fluorescence spectroscopy provide evidence for the mechanism of membrane lysis. In the crystal structures of two thionins in the family, alpha(1)- and beta-purothionins (MW: approximately 4.8 kDa), a phosphate ion and a glycerol molecule are modeled bound to the protein. (31)P NMR experiments on the desalted toxins confirm phosphate-ion binding in solution. Evidence also comes from phospholipid partition experiments with radiolabeled toxins and with fluorescent phospholipids. This data permit a model of the phospholipid-protein complex to be built. Further, NMR experiments, one-dimensional (1D)- and two-dimensional (2D)-total correlation spectroscopy (TOCSY), carried out on the model compounds glycerol-3-phosphate (G3P) and short chain phospholipids, supported the predicted mode of phospholipid binding. The toxins' high positive charge, which renders them extremely soluble (>300 mg/mL), and the phospholipid-binding specificity suggest the toxin-membrane interaction is mediated by binding to patches of negatively charged phospholipids [phosphatidic acid (PA) or phosphatidyl serine (PS)] and their subsequent withdrawal. The formation of proteolipid complexes causes solubilization of the membrane and its lysis. The model suggests that the oligomerization may play a role in toxin's activation process and provides insight into the structural principles of protein-membrane interactions.

Bacillus amyloliquefaciens phage endolysin can enhance permeability of Pseudomonas aeruginosa outer membrane and induce cell lysis

Abstract: To determine the function of the C-terminal region of Bacillus amyloliquefaciens phage endolysin on Pseudomonas aeruginosa lysis, the permeabilization of the outer membrane of P. aeruginosa was analyzed. Glu-15 to His (E15H) and Thr-32 to Glu (T32E) substitutions were introduced into the Bacillus phage endolysin. Neither E15H nor T32E substitution induced enzymatic and antibacterial activities. These two, Glu-15 and Thr-32, were considered to be the active center of the enzyme. The addition of purified E15H and T32E proteins to P. aeruginosa cells induced the release of periplasmic beta-lactamase from the cells, indicating that both proteins enhance permeabilization of the outer membrane. However, the addition of E15H and T32E proteins to P. aeruginosa cells did not induce the release of cytoplasmic ATP from the cells. These results indicate that the antibacterial activity of the endolysin requires both the C-terminal enhancement of the permeabilization of the P. aeruginosa outer membrane and N-terminal enzymatic activity.

Knockout of the alanine racemase gene in Lactobacillus plantarum results in septation defects and cell wall perforation.

Abstract: A stable mutant of Lactobacillus plantarum deficient in alanine racemase (Alr) was constructed by two successive homologous recombination steps. When the mutant was supplemented with D-alanine, growth and viability were unaffected. Surprisingly, deprivation of d-alanine during exponential growth did not result in a rapid and extensive lysis as observed in Alr-deficient strains of Escherichia coli or Bacillus subtilis. Rather, the starved mutant cells underwent a growth arrest and were gradually affected in viability with a decrease in colony forming units over 99% in less than 24 h. Additionally, fluorescent techniques demonstrated a loss of cell envelope integrity in the starved cells. Prolonged d-alanine starvation resulted in cells with an aberrant morphology. Scanning and transmission electron microscopy analyses revealed an increase in cell length, deficiencies in septum formation, thinning of the cell envelope and perforation of the cell wall in the septum region. We discuss the involvement of peptidoglycan hydrolases in these phenotypic defects in the context of the crucial role played by D-alanine in peptidoglycan biosynthesis and teichoic acids substitution.

Identification of membrane-anchoring domains of RLIP76 using deletion mutant analyses.

Abstract: RLIP76 (RALBP1) is a multifunctional transporter involved in signaling and transmembrane movement of solute allocrites, which include glutathione conjugates and several natural product antineoplastic agents [Awasthi, S., et al. (2000) Biochemistry 39, 9327-9334; (2001) Biochemistry 40, 4159-4168]. Our previous studies suggested that the membrane-anchoring domain resides in the N-terminus of RLIP76, despite the lack of identifiable membrane-spanning domains. Amino acid sequence analysis indicated that this region of RLIP76 contains sequences that are similar to those of vector peptides. We, therefore, have studied the effect of a series of deletion mutant proteins on hydrophobicity and transport activity. RLIP76 or one of its derived deletion mutants was expressed in Escherichia coli, and bacteria were lysed and extracted in buffer without or with the nonionic detergent polidocanol. The ratio of RLIP76 in the detergent/aqueous extracts was found to be 2.5 for the wild-type protein, but decreased to 0.7 in the mutant in which amino acids 154-219 were deleted. Deletion of only one segment of this region (amino acids 171-185) alone resulted in a significant decrease in this ratio to 1.0. For the mutants with deletions within the region from amino acid 154 to 219, loss of hydrophobicity correlated with less incorporation of mutants into artificial liposomes, and decreased transport activity toward doxorubicin and dinitrophenyl-S-glutathione. In contrast, deletion of one of the two ATP-binding sites (at amino acids 65-80 or 415-448) or both sites did not affect hydrophobicity but reduced or abrogated transport activity. NSCLC (H358) stably transfected with del171-185 and del154-219 showed that loss of these regions results in a decrease in the extent of membrane association of RLIP76. Confocal laser immunohistochemistry colocalized amino acids 171-185 with her2/neu on the cell surface. Depletion of wild-type RLIP76 using si-RNA directed to this region in cells transfected with del171-185 resulted in the loss of cell surface expression. These finding demonstrate that amino acids 171-185 constitute a cell surface epitope which is necessary for optimal transport of anthracycline and glutathione conjugates by RLIP76, and that this peptide could be a novel target for antineoplastic therapy.

Prm1 Prevents Contact-Dependent Lysis of Yeast Mating Pairs

Abstract: Membrane fusion requires localized destabilization of two phospholipid bilayers, but unrestrained membrane destabilization could result in lysis. prm1 mutant yeast cells have a defect at the plasma membrane fusion stage of mating that typically results in the accumulation of prezygotes that have fingers of membrane-bound cytoplasm projecting from one cell of each pair into its mating partner in the direction of the osmotic gradient between the cells. However, some prm1 mating pairs fuse successfully whereas the two cells in other prm1 mating pairs simultaneously lyse. Lysis only occurs if both mating partners are prm1 mutants. Osmotic stabilization does not protect prm1 mating pairs from lysis, indicating that lysis is not caused by a cell wall defect. prm1 mating pairs without functional mitochondria still lyse, ruling out programmed cell death. No excess lysis was found after pheromone treatment of haploid prm1 cells, and lysis did not occur in mating pairs when prm1 was combined with the fus1 and fus2 mutations to block cell wall remodeling. Furthermore, short (<1 μm) cytoplasmic microfingers indicating the completion of cell wall remodeling appeared immediately before lysis. In combination, these results demonstrate that plasma membrane contact is a prerequisite for lysis. Cytoplasmic microfingers are unlikely to cause lysis since most prm1 mating pairs with microfingers do not lyse, and microfingers were also detected before fusion in some wild-type mating pairs. The lysis of prm1 mutant mating pairs suggests that the Prm1 protein stabilizes the membrane fusion event of yeast mating.

Devices and methods for biomaterial production

Abstract: An apparatus and a method for isolating a biologic product, such as plasmid DNA, from cells. The method involves lysing cells in a controlled manner separate insoluble components from a fluid lysate containing cellular components of interest, followed by membrane chromatographic techniques to purify the cellular components of interest. The process utilizes a unique lysis apparatus, ion exchange and, optionally, hydrophobic interaction chromatography membranes in cartridge form, and ultrafiltration. The process can be applied to any biologic product extracted from a cellular source. The process uses a lysis apparatus, including a high shear, low residence-time mixer for advantageously mixing a cell suspension with a lysis solution, a hold time that denatures impurities, and an air-sparging bubble mixer that gently yet thoroughly mixes lysed cells with a neutralization/precipiation buffer and floats compacted precipitated cellular material.