The effect of lysozyme on DNA—Membrane association in Escherichia coli

In vitro PCR verification that lysozyme inhibits nucleic acid replication and transcription

Lysozyme can kill bacteria by its enzymatic activity or through a mechanism involving its cationic nature, which can facilitate electrostatic interactions with the viral capsid, the negatively charged parts of nucleic acids, and polymerase, so binding to nucleic acids may be another biological function of lysozyme. Here, PCR was used as a research tool to detect the effects of lysozyme on the replication and transcription of nucleic acids after treatment in different ways. We found that lysozyme and its hydrolysate can enter cells and inhibit PCR to varying degrees in vitro, and degraded lysozyme inhibited nucleic acid replication more effectively than intact lysozyme. The inhibition of lysozyme may be related to polymerase binding, and the sensitivity of different polymerases to lysozyme is inconsistent. Our findings provide a theoretical basis for further explaining the pharmacological effects of lysozyme, such as antibacterial, antiviral, anticancer, and immune regulatory activities, and directions for the development of new pharmacological effects of lysozyme and its metabolites.

Electrorelease of Escherichia coli nucleoids

Bacterial chromosome is assembled and folded into one or several nucleoids, depending on the metabolic status of the cell. Development of reliable nucleoid isolation protocols has always been an objective for researchers. A rapid and reproducible procedure for isolation of E. coli nucleoids is described here, while the cell envelope is maintained. Membrane dispersions and vesicles were prepared by lysozyme-EDTA treatment with subsequent rupture of the spheroplasts by electric field. Under these conditions the yield of electroreleased nucleoids was around 90%. The extent of DNA-envelope contacts was determined by light microscopy employing phase contrast and fluorescence modes.

Isolation of the Escherichia coli nucleoid

Numerous protocols for the isolation of bacterial nucleoids have been described based on treatment of cells with sucrose-lysozyme-EDTA and subsequent lysis with detergents in the presence of counterions (e.g., NaCl, spermidine). Depending on the lysis conditions both envelope-free and envelope-bound nucleoids could be obtained, often in the same lysate. To investigate the mechanism(s) involved in compacting bacterial DNA in the living cell, we wished to isolate intact nucleoids in the absence of detergents and high concentrations of counterions. Here, we compare the general lysis method using detergents with a procedure involving osmotic shock of Escherichia coli spheroplasts that resulted in nucleoids free of envelope fragments. After staining the DNA with DAPI (4',6-diamidino-2-phenylindole) and cell lysis by either isolation procedure, free-floating nucleoids could be readily visualized in fluorescence microscope preparations. The detergent-salt and the osmotic-shock nucleoids appeared as relatively compact structures under the applied ionic conditions of 1 M and 10 mM, respectively. RNase treatment caused no dramatic changes in the size of either nucleoid.

Lysozyme association with nucleic acids

Lysozyme is well known for the ability to hydrolyze the cell wall of bacteria. Based on the similarity of structure between lysozyme and histones as seen from the results of X-ray crystal structure determinations, we have postulated that binding to nucleic acids may be another biological function of lysozyme. We have therefore begun a systematic study of the interactions of lysozyme and related molecules with nucleic acids, and present here a preliminary report. Binding to DNA and RNA has been demonstrated from gel electrophoresis, enzyme activity, and coprecipitation studies. We suggest that this function of lysozyme will provide an explanation why Lee-Huang et al. (1999) [Proc. Natl. Acad. Sci. USA 96, 2678-2681] were able to call lysozyme a "killer protein" against the AIDS virus, and may provide a new avenue of research on AIDS therapy.

Isolation and characterization of spermidine nucleoids from Escherichia coli

Nucleoids isolated from Escherichia coli at low salt concentrations in the presence of spermidine (Kornberg et al., Proc. Natl. Acad. Sci. USA, 71, 3189-3193 (1974)) retain large amounts of protein and RNA and are, thus, potentially useful in structural and other studies. However, these preparations have neither been visualized nor extensively characterized with regard to their protein and other components. We have investigated this type of nucleoid preparation and here supply both light and electron microscope appearances and a description of the DNA-associated proteins. Light microscopy is used to follow the stages of nucleoid release and to demonstrate characteristically rounded nucleoids after chloramphenicol treatment of the cells from which the nucleoids were isolated. The nucleoids are "envelope-associated" particles. Electron microscopy shows an irregular central core that is partially covered with small, membranous vesicles. A significant fraction of the nucleoids have a characteristic doublet/dumbbell-shaped appearance by light microscopy. The nucleoids contain large amounts of protein and RNA in addition to DNA. The DNA and RNA are rendered acid-soluble by very low levels of nucleases, indicating an open structure. A small group of proteins, including H-NS, FIS, HU, and RNA polymerase, is released from the particles upon enzymatic digestion of the DNA.

The chemistry of lysozyme and its use as a food preservative and a pharmaceutical

The chemistry and use of lysozyme as a food preservative and a pharmaceutical are reviewed. Lysozyme inhibits the growth of deleterious organisms, thus prolonging shelf life. Chemicals used to improve the preservative effect of lysozyme and those that inhibit the enzyme are discussed, along with the stability of lysozyme in various chemical environments. Lysozyme has been used to preserve fresh fruits and vegetables, tofu bean curd, seafoods, meats and sausages, potato salad, cooked burdock with soy sauce, and varieties of semihard cheeses such as Edam, Gouda, and some Italian cheeses. Lysozyme added to infant-feeding formulas makes them more closely resemble human milk. Lysozyme has been used clinically in the treatment of periodontitis, administered in chewing gum, and implemented to prevent tooth decay. It has also been administered to patients suffering from cancer for its analgesic effect and has been used as a potentiating agent in antibiotic therapy.

Interactions between phage lambda replication proteins, lambda DNA and minicell membrane

Gentle methods for minicell lysis and lysate fractionation have been elaborated: lysis by T4 lysozyme without detergents, and fractionation by equilibrium sedimentation in a metrizamide density gradient, both at low ionic strength. In the lysates of phage-lambda-infected minicells the lambda DNA, trapped at a prereplicative step [Witkiewicz, H. and Taylor, K. (1979) Biochim. Biophys. Acta 564, 31-36], appeared in two peaks of different buoyant densities: as a membrane-bound and a free lambda DNA. The covalently-closed-circular form of lambda DNA appeared exclusively in the membrane fraction. The lambda-coded proteins, synthesized in lambda-infected minicells, appeared in two major fractions: as membrane-bound and as free proteins, and in one minor fraction, bound with free lambda DNA. Neither lambda protein engaged in the initiation of DNA replication was present in the fraction of free proteins: the P-gene product was membrane-associated, and the O-gene product formed a complex with free lambda DNA. The effect of high ionic strength (KCl) and of detergents (Triton X-100 and sarcosyl) on the binding of replication proteins with lambda DNA and with the membrane was studied. The non-ionic detergent, Triton X-100 caused displacement of a part of lambda DNA from the membrane to the free lambda DNA peak; both lambda replication proteins were bound with free lambda DNA. The binding of the O protein with lambda DNA was relatively stable, but was destroyed by the ionic detergent, sarcosyl.

Escherichia coli mut T1. II. Consequences of modification on the association of DNA with the cell membrane

1. Two isogenic strains of Escherichia coli, K-12 which differ by mutator gene character (mut T1) have been studied. This characteristic caused introduction of a high frequency of undirectional transversions, A-T leads to -CG, into the DNA of the strain harboring it. 2. It had been previously shown that the presence of this gene is accompanied by an alteration of a cell membrane component. Now, the nuclease susceptibility of DNA associated with membrane/DNA/DNA polymerase complexes is reported. DNA of mut T1 membranes is more sensitive towards exogenous nuclease than DNA of membrane complexes from the wild type mut+ strain. 3. Auto-digestion of this DNA by endogenous nuclease associated with the membrane complex is, also, more severe in preparations derived from mut T1 than from the wild-type strain, mut+, but to a lesser extent than observed with exogenous nucleases. 4. Nuclease susceptibility of mut+ membrane bound DNA is markedly influenced by the growth state of the cell. The nuclease susceptibility of membrane bound DNA from mut T1 cells, however, shows no differences between stationary and log states. 5. These differential sensitivities may be due to conformational changes in the membrane introduced as a pleiotrophic consequence of an altered membrane protein. A pertinent role of this protein in a modified replication/repair complex is an attractive suggestion, especially in the context of the mutator character of this strain.

Identification of a biochemically unique DNA-membrane interaction involving the Escherichia coli origin of replication

DNA-membrane complexes have been obtained from Escherichia coli by using a freeze-thaw lysis procedure that avoids lysozyme and detergents. Complexes made in this manner and containing DNA near the origin of replication are uniquely sensitive to ionic strength, Pronase, and trypsin. There is approximately one such complex per chromosomal origin. The sensitivities suggest that origin-specific binding is mediated by a protein. By using these unique characteristics to distinguish origin-specific complexes from the majority of DNA-membrane binding sites, it was found that the origin-specific binding persists after termination of chromosomal replication.

Envelope-associated folded chromosomes for Escherichia coli: variations under different physiological conditions

The folded chromosome of Escherichia coli has been investigated under various lysis and physiological conditions. A new gradient system was devised that allows excellent separation between unlysed cells and envelope-associated and envelope-free chromosomes. Isotope incorporation experiments showed that the fraction often called "membrane-bound nucleoids" contains cell wall in addition to nucleic acids, membranes, and proteins. The amount of lysozyme added and the lysozyme digestion time were found to be important when comparing the rate of sedimentation of envelope-associated chromosomes obtained under various physiological conditions. Amino acid-starved cells were found to be much harder to lyse with lysozyme than exponentially grown cells, The difference in sedimentation coefficient of envelope-associated chromosomes described earlier (Ryder and Smith, 1974) was not detected when the latter two types of cells had been given equivalent, but not identical, lysozyme treatment such that detergent-mediated lysis proceeded at the same rate. Analysis of pulse- and uniformly labeled chromosomes from amino acid-starved cultures revealed no preferential labeling of either envelope-associated or -released nucleoids. Nor was there a difference in sedimentation coefficient between uniform and pulse-labeled envelope-associated nucleoids. These results are in disagreement with the models for chromosome replication of Worcel and Burgi (1974) and Ryder and Smith (1974), respectively. Growing cells on carbon sources poorer than glucose demonstrated that the replicating chromosomes sediment faster than the bulk of envelope-associated nucleoids. The slower the growth rate, the greater this difference became. An alternative hypothesis regarding chromosome replication and its association with the cell envelope is presented.

Progress in the resolution of the cytoplasmic membrane DNA initiation complex of Escherichia coli

The attachment of the bacterial chromosome to the cytoplasmic membrane in Escherichia coli was studied. The initiator DNA was specifically labeled and the outer and cytoplasmic membranes were separated in a step sucrose gradient. The labeled DNA was localized mainly in the cytoplasmic membrane fraction. The DNA . cytoplasmic membrane complex was isolated from cells uniformly labeled with [Me-3H]thymidine, solubilized with deoxycholate and chromatographed on Sepharose 4B. A high percent of the labeled DNA was excluded in the void volume but a small fraction eluted associated with the second protein elution peak. The isolation of such a DNA . cytoplasmic membrane protein complex, suggests useful strategies for future studies about the molecular components of the initiation complex in E. coli.

Enhanced uptake of donor DNA by Ca2+ treated Escherichia coli cells

The first steps in E. coli transformation have been studied. It was found that the cells attain the ability of enhanced uptake of donor exogenous DNA upon Ca2+ treatment. At saturating DNA concentrations the cells were capable to take up irreversibly about 6-10(8) dalton of donor DNA per cell (if to assume that all the cells are competent). About 75% of this DNA was found to be attached to the cytoplasmic membrane. Employing Poisson approximation for distribution of the donor-marker DNA molecules on recipient cells it was found that the efficiency of a marker recombination and expression is about 2-10(-5). The first steps in E. coli transformation have been studied. It was found that the cells attain the ability of enhanced uptake of donor 0exogenous