Expression of bacteriophage PhiX174 lysis gene E in Staphylococcus carnosus TM300

Abstract Expression of the cloned PhiX174 gene E causes lysis of the Gram-negative bacterium Escherichia coli , which led to the proposal that a two-membrane system is necessary for the protein E lysis function. Gene E was cloned in an E. coli/Bacillus subtilis shuttle vector and expressed in the Gram-positive bacterium Staphylococcus carnosus TM300. Regulated gene E expression had a lethal effect on S. carnosus ; however, no lysis was detected, lending support to the hypothesis.     

Primary structures of the ColE2-P9 and ColE3-CA38 lysis genes

The lysis genes of plasmids ColE2-P9 and ColE3-CA38 were identified by DNA sequencing and electrophoretic analysis of the products of both wild type and artificially introduced ochre mutant genes. The E2 and E3 lysis genes had identical primary structures and were shown to encode 47 amino acids with a calculated molecular weight of 4,861, which is much smaller than that proposed previously for the ColE3-CA38 lysis protein. They are homologous with ColDF13 gene H, except in their 3'-portions. The nine C-terminal amino acids of the E2 and E3 lysis proteins proved to be non-essential for the lysis phenotype.     

Altered temperature induction sensitivity of the lambda pR/cI857 system for controlled gene E expression in Escherichia coli

Cell lysis of Gram-negative bacteria can be efficiently achieved by expression of the cloned lysis gene E of bacteriophage PhiX174. Gene E expression is tightly controlled by the rightward lambda pR promoter and the temperature-sensitive repressor cI857 on lysis plasmid pAW12. The resulting empty bacterial cell envelopes, called bacterial ghosts, are currently under investigation as candidate vaccines. Expression of gene E is stringently repressed at temperatures up to 30 degrees C, whereas gene E expression, and thus cell lysis, is induced at temperatures higher than 30 degrees C due to thermal inactivation of the cI857 repressor. As a consequence, the production of ghosts requires that bacteria have to be grown at 28 degrees C before the lysis process is induced. In order to reflect the growth temperature of pathogenic bacteria in vivo, it seemed favorable to extend the heat stability of the lambda pR promoter/cI857 repressor system, allowing pathogens to grow at 37 degrees C before induction of lysis. In this study we describe a mutation in the lambda pR promoter, which allows stringent repression of gene E expression at temperatures up to 36 degrees C, but still permits induction of cell lysis at 42 degrees C.     

Requirement for a functional host cell autolytic enzyme system for lysis of Escherichia coli by bacteriophage phi X174

Escherichia coli VC30 is a temperature-sensitive mutant which is defective in autolysis. Strain VC30 lyses at 30 degrees C when treated with beta-lactam antibiotics or D-cycloserine or when deprived of diaminiopimelic acid. The same treatments inhibit growth of the mutant at 42 degrees C but do not cause lysis. Strain VC30 was used here to investigate the mechanism of host cell lysis induced by bacteriophage phi X 174. Strain VC30 was transformed with plasmid pUH12, which carries the cloned lysis gene (gene E) of phage phi X174 under the control of the lac operator-promoter, and with plasmid pMC7, which encodes the lac repressor to keep the E gene silent. Infection of strain VC30(pUH12)(pMC7) with phage phi X174 culminated in lysis at 30 degrees C. At 42 degrees C, intracellular phage development was normal, but lysis did not occur unless a temperature downshift to 30 degrees C was imposed. Similarly, induction of the cloned phi X174 gene E with isopropyl-beta-D-thiogalactoside resulted in lysis at 30 degrees C but not at 42 degrees C. Temperature downshift of the induced culture to 30 degrees C resulted in lysis even in the presence of chloramphenicol. These results indicate that host cell lysis by phage phi X174 is dependent on a functional cellular autolytic enzyme system.     

Enhanced reactive lysis of paroxysmal nocturnal hemoglobinuria erythrocytes by C5b-9 does not involve increased C7 binding or cell-bound C3b

The most complement (C)-sensitive type of erythrocytes (E) occurring in paroxysmal nocturnal hemoglobinuria (type III PNH E) have previously been found to exhibit approximately twofold to fourfold greater lysis than normal human E when exposed to isolated human C5b6, C7, C8, and C9 (reactive lysis), in the absence of a known source of C3- or C5-convertases or fluid-phase C3. In further studies on the mechanism of this phenomenon, we now report that C5b6-dependent binding of 125I-C7 to two samples of PNH E (greater than 95% type III) is equal to that found with normal human E at each of several C5b6 inputs tested. Lysis developed by excess C8 and C9, however, was consistently greater for the PNH E. Thus, the exaggerated sensitivity of type III PNH E to reactive lysis cannot be explained by abnormally high uptake of C5b6 or C7 from the fluid phase. Rather, the data indicate that cell-bound C5b67 sites are converted to effective hemolytic sites with greater efficiency on type III PNH E than on normal human E, assuming that the distribution of cell-bound C7 throughout both cell populations is similar. In related studies we have addressed the proposal by other investigators that C3b putatively bound to PNH E in vivo might account for their increased sensitivity to reactive lysis in vitro, by analogy to prior observations on C3b-potentiated reactive lysis of sheep E. The latter hypothesis was made more appealing by the recent discovery that type III PNH E lack an integral membrane protein, decay-accelerating factor (DAF), which in normal E accelerates the decay of membrane-bound C3 convertases. Against this hypothesis, however, is our present finding that preincubation of PNH E with four different goat or rabbit polyclonal antibodies to human C3 failed to inhibit the subsequent reactive lysis of these cells. Under these same conditions, the C3b-dependent increment in reactive lysis of sheep EAC4b3b was abrogated by pretreatment with similar dilutions of these anti-C3 antibodies, generally in association with agglutination. Furthermore, sheep EAC4b3b displayed increased 125I-C7 binding in proportion to augmented lysis, in contrast to the findings with PNH E. Therefore, deficiency of DAF in type III PNH E does not adequately explain their supranormal sensitivity to reactive lysis unless DAF can modulate the terminal lytic steps by a mechanism distinct from its effect on C3 convertase decay. Alternatively, type III PNH E could have a more general abnormality in which DAF deficiency is one manifestation and increased sensitivity to reactive lysis is another.     

Translational efficiency of phi X174 lysis gene E is unaffected by upstream translation of the overlapping gene D reading frame.

The lysis gene E of bacteriophage phi X174 is entirely embedded in gene D. Expression studies of genes D and E in Escherichia coli minicells and lysis times obtained in the presence or absence of D translation showed that the simultaneous expression of gene D does not affect protein E production. Thus, unlike other overlapping gene pairs, gene E expression is independent from the upstream translation of gene D. lacZ fusion studies and primer extension inhibition analysis (toeprinting) revealed an intrinsically weak E ribosome-binding site, which seems to be the major factor determining the low expression rate of the gene and thus proper scheduling of cell lysis.     

Lysis of Escherichia coli by the bacteriophage phi X174 E protein: inhibition of lysis by heat shock proteins.

Lysis of Escherichia coli by the cloned E protein of bacteriophage phi X174 was more rapid than expected when bacteria were shifted from 30 to 42 degrees C at the time of E induction. Since such treatment also induces the heat shock response, we investigated the effect of heat shock proteins on lysis. An rpoH mutant was more sensitive to lysis by E, but a secondary suppressor mutation restored lysis resistance to parental levels, which suggests that the sigma 32 subunit itself did not directly increase lysis resistance. At 30 degrees C, mutants in five heat shock genes (dnaK, dnaJ, groEL, groES, and grpE) were more sensitive to lysis than were their wild-type parents. The magnitude of lysis sensitivity varied with mutation and strain background, with dnaK, dnaJ, and groES mutants consistently exhibiting the greatest sensitivities. Extended protection against lysis occurred when overproduction of heat shock proteins was induced artificially in cells that contained a plasmid with the rpoH+ gene under control of the tac promoter. This protective effect was completely abolished by mutations in dnaK, dnaJ, or groES but not by grpE or groEL mutations. Altered membrane behavior probably explains the contradiction whereby an actual temperature shift sensitized cells to lysis, but production of heat shock proteins exhibited protective effects. The results demonstrate that E-induced lysis can be divided into two distinct operations which may now be studied separately. They also emphasize a role for heat shock proteins under non-heat-shock conditions and suggest cautious interpretation of lysis phenomena in systems where E protein production is under control of a temperature-sensitive repressor.     

Differential susceptibility of type III erythrocytes of paroxysmal nocturnal hemoglobinuria to lysis mediated by complement and perforin

Previous reports have suggested that a 65 kDa membrane protein, termed homologous restriction factor (HRF), in addition to protecting erythrocytes (E) against lysis by homologous complement (C), may also be involved in protecting cytolytic lymphocytes against lysis mediated by a pore-forming protein (PFP/perforin), one of their own lytic mediators. Here, we used HRF-deficient type III E of patients with paroxysmal nocturnal hemoglobinuria (PNH) to study their susceptibility to lysis mediated by homologous C and perforin, and compared it with lysis of HRF-bearing control or PNH type I E. We show that type III E of PNH patients are indeed more susceptible to lysis mediated by homologous C than control or type I E, but they are as susceptible to perforin-mediated lysis as type I E. In addition, all human E (type I or III) tested here are equally susceptible to lysis mediated by either human (homologous) or murine (heterologous) perforin. By immunoblot analysis, we confirm that type III E, in contrast to type I E, were deficient in the 65 kDa HRF. These results support the notion that homologous species restriction is seen in the C- but not in the lymphocyte perforin-system and argue against an active participation of HRF in protecting cells from perforin-mediated lysis.     

Lytic action of cloned phi X174 gene E.

The phi X174 lysis gene E was placed under control of the lac promoter by cloning into the multicopy plasmid pBH20. Other phi X174 gene sequences were removed by nuclease digestion. Expression of gene E was shown to be necessary and sufficient to produce lysis phenomena exhibited by infection with intact phage. Lysis, its inhibition by MgSO4 and spermine, its progression through a spheroplasting stage, and its dependence on an early chloramphenicol-sensitive step were reproduced in clones induced for expression of the E gene product. Escherichia coli clones carrying the E gene not under lac control, and clones under lac control but only minimally induced for gene E expression, exhibited morphological aberrations consistent with the view that the mechanism by which gene E mediates cell lysis is related to host cell division processes.     

Plasmid ColE3 specifies a lysis protein.

Tn5 insertion mutations in plasmid ColE3 were isolated and characterized. Several of the mutants synthesized normal amounts of active colicin E3 but, unlike wild-type colicinogenic cells, did not release measurable amounts of colicin into the culture medium. Cells bearing the mutant plasmids were immune to exogenous colicin E3 at about the same level as wild-type colicinogenic cells. All of these lysis mutants mapped near, but outside of, the structural genes for colicin E3 and immunity protein. Cells carrying the insertion mutations which did not release colicin E3 into the medium were not killed by UV exposure at levels that killed cells bearing wild-type plasmids. The protein specified by the lysis gene was identified in minicells and in mitomycin C-induced cells. A small protein, with a molecular weight between 6,000 and 7,000, was found in cells which released colicin into the medium, but not in mutant cells that did not release colicin. Two mutants with insertions within the structural gene for colicin E3 were also characterized. They produced no colicin activity, but both synthesized a peptide consistent with their map position near the middle of the colicin gene. These two insertion mutants were also phenotypically lysis mutants--they were not killed by UV doses lethal to wild-type colicinogenic cells and they did not synthesize the small putative lysis protein. Therefore, the lysis gene is probably in the same operon as the structural gene for colicin E3.     

Nature of Escherichia coli cell lysis by culture supernatants of Bacillus species.

Escherichia coli cells were found to be sensitive to lysis by the supernatants of a variety of protease-positive Bacillus species when treated at 45 degrees C but not when treated at 37 degrees C. Different E. coli strains manifested different lysis sensitivities when treated at 45 degrees C. When the lysis rates of E. coli cells at various stages of growth were investigated, post-exponential-phase cells were shown to be most sensitive to lysis. The lysis rate was inversely related to cell viability, and susceptibility appeared to be at least partly due to lysis of dead E. coli cells. A close relation was observed between levels of lysis activity and proteolytic activity. A Bacillus subtilis mutant lacking alkaline and neutral protease activity failed to lyse E. coli cells. It was concluded that Bacillus proteases played a major role in the observed E. coli lysis.     

Nature of Escherichia coli cell lysis by culture supernatants of Bacillus species

Escherichia coli cells were found to be sensitive to lysis by the supernatants of a variety of protease-positive Bacillus species when treated at 45 degrees C but not when treated at 37 degrees C. Different E. coli strains manifested different lysis sensitivities when treated at 45 degrees C. When the lysis rates of E. coli cells at various stages of growth were investigated, post-exponential-phase cells were shown to be most sensitive to lysis. The lysis rate was inversely related to cell viability, and susceptibility appeared to be at least partly due to lysis of dead E. coli cells. A close relation was observed between levels of lysis activity and proteolytic activity. A Bacillus subtilis mutant lacking alkaline and neutral protease activity failed to lyse E. coli cells. It was concluded that Bacillus proteases played a major role in the observed E. coli lysis.     

Mouse anti-adenovirus cytotoxic T lymphocytes. Inhibition of lysis by E3 gp19K but not E3 14.7K

Early region E3 of adenovirus (Ad) appears to encode proteins involved in the interaction of the virus with the host immune system. The E3 region 19-kDa glycoprotein (gp19K) binds to class I MHC Ag in the endoplasmic reticulum and inhibits their transport to the cell surface; it has been proposed that this protects virus infected cells from lysis by CTL. We have found that the E3 14.7-kDa protein (14.7K) inhibits lysis of infected cells by TNF, and here we show that it also protects cells from lysis by lymphotoxin, which has been implicated as a mediator of CTL lysis. We have developed a method for producing CTL specific for human Ad2 and Ad5 in mice, in order to test directly which of the genes in the E3 region protect infected cells from lysis by virus specific CTL. The presence of the E3 region inhibits both the induction of Ad-specific CTL in culture and the lysis of infected target cells by these CTL. The inhibition varies between different mouse strains, with almost complete inhibition in C57BL/10 (H-2b) mice, partial inhibition with BALB/c (H-2d) and little or no inhibition with C3H (H-2k); results were similar for Ad2 and Ad5. By using a panel of E3 deletion mutants, inhibition of target cell lysis by Ad5 specific CTL was mapped exclusively to the gp19K gene. The 14.7K gene had no effect on CTL lysis despite its ability to protect cells against lysis by lymphotoxin. gp19K was synthesized abundantly in mouse cells by mutants retaining the gp19K gene; some mutant forms of the protein were synthesized but were nonfunctional. These data support the hypothesis that gp19K can protect Ad infected cells against lysis by virus specific CTL.     

Mutations in the new gene stIII of bacteriophage T4B suppressing the lysis defect of gene stII and a gene e mutant.

Mutations of bacteriophage T4B were found which suppress the lysis defect of both gene stII mutants and gene e mutants. The suppressor mutations belong to a new gene, stIII, of phage T4B. Gene stIII is located on the genetic map of T4B between genes stI and e. stIII mutants sometimes form star plaques on Escherichia coli B. The latent period on E. coli 594, but not E. coli B, is shorter with stIII mutants than that with wild-type phage. The premature lysis of E. coli 594 infected with stIII phage does not depend on the expression of both stII+ and e+ function. StIII allele is dominant over the stIII+ with respect to both the ability to suppress the stII defect and the early lysis of infected E. coli 594 cultures.     

Minimal requirements for inhibition of MraY by lysis protein E from bacteriophage ΦX174

The DNA phage ΦX174 encodes the integral membrane protein E whose expression leads to host cell lysis by inhibition of the peptidoglycan synthesis enzyme MraY. Here we use mutagenesis to characterize the molecular details of the E lysis mechanism. We find that a minimal 18-residue region with the modified wild-type sequences of the conserved transmembrane helix of E is sufficient to lyse host cells and that specific residues within and at the boundaries of this helix are important for activity. This suggests that positioning of the helix in the membrane is critical for interactions with MraY. We further characterize the interaction site of the transmembrane helix with MraY demonstrating E forms a stable complex with MraY. Triggering cell lysis by peptidoglycan synthesis inhibition is a traditional route for antimicrobial strategies. Understanding the mechanism of bacterial cell lysis by E will provide insights into new antimicrobial strategies using re-engineered E peptides.     

Effect of retinol on the hemolysis and lipid peroxidation in vitamin E deficiency

A study on the effect of retinolin vitro on the hemolysis of vitamin E deficient rat red blood cells showed that retinol enhanced the lysis of the E deficient cells as compared to the lysis of normal cells. The lipid peroxidation present during hydrogen peroxide induced lysis of E deficient cells was however markedly inhibited in the presence of retinol without affecting the rate of lysis. In an actively peroxidising system of non-enzymatic lipid peroxidation of rat liver or brain homogenates and of brain lysosomes incubated with human erythrocytes, no lysis was obtained; incorporation of retinol in such systems resulted in lysis but no peroxidation. Hydrogen peroxide generating substances almost completely inhibited the lysis of normal human erythrocytes by retinol, but linoleic acid hydroperoxide and auto-oxidised liver or brain homogenates and ox-brain liposomes increased the lysis. It is concluded that vitamin E deficient erythrocyte hemolysis may be augmented by retinol, an anti-oxidant, having a lytic function without the peroxidation of stromal lipids     

Proton-motive-force-dependent step in the pathway to lysis of Escherichia coli induced by bacteriophage phi X174 gene E product.

We examined the cellular effects after the expression of the cloned lysis gene E of bacteriophage phi X174. Chloramphenicol prevented lysis only when added within the first minute of derepression of E synthesis, indicating that a time lag of several minutes exists between the synthesis of the E protein and the onset of cell lysis. Experiments with protonophores showed the existence of a subsequent step dependent on proton motive force at about 3 to 5 min before lysis.     

The adenovirus E3-14.7K protein is a general inhibitor of tumor necrosis factor-mediated cytolysis

We have previously described a 14,700 m.w. protein (14.7K) encoded by the E3 region of adenovirus that prevents TNF-mediated cytolysis of adenovirus-infected C3HA mouse fibroblasts. In the studies described here we have extended our analysis of TNF cytolysis of C3HA cells and the circumstances under which 14.7K protects these cells from cytolysis. C3HA cells were killed by TNF in the presence of inhibitors of protein synthesis, in the presence of cytochalasin E (which disrupts the microfilaments), and when adenovirus E1A was expressed. As described for other cell types, pretreatment of C3HA cells with TNF prevented cytolysis by TNF plus cycloheximide or TNF plus cytochalasin E, indicating that TNF induces a response that protects against these treatments. Remarkably, when 14.7K was expressed in virus-infected cells, it also prevented TNF-induced lysis whether sensitivity to TNF was induced by inhibition of protein synthesis, disruption of the cytoskeleton by cytochalasin E, or expression of adenovirus E1A. The 14.7K protein also prevented TNF lysis of cells that are spontaneously sensitive to TNF lysis. Thus, 14.7K appears to be a general inhibitor of TNF cytolysis, and as such should be an important tool in unraveling the mechanism of TNF cytolysis. There was one exception; NCTC-929 cells were spontaneously sensitive to TNF lysis and that lysis was not affected by 14.7K even though the protein was made in large quantities and was metabolically stable in these cells. This suggests that there is heterogeneity among TNF-sensitive cell lines. The 14.7K protein was found in both the nuclear and cytosol fractions of TNF resistant as well as all spontaneously sensitive cells suggesting that 14.7K may have more than one site of action within the cell.     

Adenovirus E1A,not human papillomavirus E7, sensitizes tumor cells to lysis by macrophages through nitric oxide- and TNF-alpha-dependent mechanisms despite up-regulation of 70-kDa heat shock protein

Expression of adenovirus (Ad) serotype 2 or 5 (Ad2/5) E1A or human papillomavirus (HPV)16 E7 reportedly sensitizes cells to lysis by macrophages. Macrophages possess several mechanisms to kill tumor cells including TNF-alpha, NO, reactive oxygen intermediates (ROI), and Fas ligand (FasL). E1A sensitizes cells to apoptosis by TNF-alpha, and macrophages kill E1A-expressing cells, in part through the elaboration of TNF-alpha. However, E1A also up-regulates the expression of 70-kDa heat shock protein, a protein that inhibits killing by TNF-alpha and NO, thereby protecting cells from lysis by macrophages. Unlike E1A, E7 does not sensitize cells to killing by TNF-alpha, and the effector mechanism(s) used by macrophages to kill E7-expressing cells remain undefined. The purpose of this study was to further define the capacity of and the effector mechanisms used by macrophages to kill tumor cells that express Ad5 E1A or HPV16 E7. We found that Ad5 E1A, but not HPV16 E7, sensitized tumor cells to lysis by macrophages. Using macrophages derived from mice unable to make TNF-alpha, NO, ROI, or FasL, we determined that macrophages used NO, and to a lesser extent TNF-alpha, but not FasL or ROI, to kill E1A-expressing cells. Through the use of S-nitroso-N-acetylpenicillamine, which releases NO upon exposure to an aqueous environment, E1A was shown to directly sensitize tumor cells to NO-induced death. E1A sensitized tumor cells to lysis by macrophages despite up-regulating the expression of 70-kDa heat shock protein. In summary, E1A, but not E7, sensitized tumor cells to lysis by macrophages. Macrophages killed E1A-expressing cells through NO- and TNF-alpha-dependent mechanisms.