Isolation and characterization of tox mutants of corynebacteriophage beta.

Seventeen nontoxinogenic (tox) mutants of corynebacteriophage beta have been isolated by using a tissue culture screening technique. The mutants fall into four major classes. Two of the classes, I and II, appear to contain missense and nonsense mutants, respectively. However, classes III and IV have not been previously described. Class III mutants produce two proteins (CRMs) seriologically related to diphtheria toxin, but efforts to demonstrate the presence of more than one tox gene have been successful. Class IV mutants are phenotypically CRM-, failing to produce any detectable protein serologically related to diphtheria toxin. Genetic studies indicate that the mutations in class IV strains are not in a gene distinct form the structural gene for toxin, and that the CRM- strains retain at least a portion of that gene. A natural phage isolate, gamma, behaves in a completely parallel fashion to the class IV mutants. The production of tox+ recombinants through recombination of various pairs of tox phage mutants has been demonstrated. The implications of these findings for the natural history of diphtheria are discussed.     

Orientation of the tox gene in the prophage of corynebacteriophage beta.

The orientation of the gene for diphtheria toxin, tox, in the prophage of converting corynebacteriophage beta has been determined. The orientation of tox in prophage and that reported simultaneously by Holmes (1976) for vegetative phage are compatible with the hypothesis that beta phage is inserted into the chromosome of its bacterial host by means of a mechanism similar to that described for lambda phage, and that the phage attachment site lies between the tox and imm genes. The position of three tox mutations that are phenotypically CRM- has also been determined. Relative to the tox-45 mutation, they are located more proximally to the end of the tox structural gene that corresponds to the amino terminal of diphtheria toxin.     

Heat-inducible mutants of corynebacteriophage.

Heat-inducible mutants of temperate cornebacteriophage beta and gamma, called temperature-sensitive repression (tsr) mutants, were isolated and characterized. Lysogens carrying these mutants were induced at 38 degrees C, produced a normal or slightly increased yield of phage, and underwent extensive lysis at this temperature. In some cases mutation to heat inducibility had altered the UV inducibility of the phage, the changes ranging from loss to enhancement of this trait. Complementation tests showed that all five beta-tsr strains had mutated in the same cistron and suggested that these mutations were in the gene responsible for repressor production.     

Prophage genomics.

The majority of the bacterial genome sequences deposited in the National Center for Biotechnology Information database contain prophage sequences. Analysis of the prophages suggested that after being integrated into bacterial genomes, they undergo a complex decay process consisting of inactivating point mutations, genome rearrangements, modular exchanges, invasion by further mobile DNA elements, and massive DNA deletion. We review the technical difficulties in defining such altered prophage sequences in bacterial genomes and discuss theoretical frameworks for the phage-bacterium interaction at the genomic level. The published genome sequences from three groups of eubacteria (low- and high-G+C gram-positive bacteria and gamma-proteobacteria) were screened for prophage sequences. The prophages from Streptococcus pyogenes served as test case for theoretical predictions of the role of prophages in the evolution of pathogenic bacteria. The genomes from further human, animal, and plant pathogens, as well as commensal and free-living bacteria, were included in the analysis to see whether the same principles of prophage genomics apply for bacteria living in different ecological niches and coming from distinct phylogenetical affinities. The effect of selection pressure on the host bacterium is apparently an important force shaping the prophage genomes in low-G+C gram-positive bacteria and gamma-proteobacteria.     

Restriction endonuclease map of corynebacteriophage omega ctox+ isolated from the Park-Williams no. 8 strain of Corynebacterium diphtheriae.

The toxigenic corynebacteriophage omega tox+ was isolated from the hypertoxigenic Park-Williams no. 8 (PW8) strain of Corynebacterium diphtheriae and compared with the toxigenic corynebacteriophage beta tox+. The physical size and host range of both phages were found to be identical. An endonuclease restriction map of omega tox+ was constructed, and the locations of the cohesive ends (cos), phage attachment site (attP), and the diphtheria tox operon were identified. The genome of omega tox+ was found to differ from that of beta tox+ in three regions. In addition, omega tox+ was shown to be integrated into two nontandem corynebacterial phage attachment sites (attB1, attB2) in the PW8 chromosome. The differences in the restriction endonuclease digestion maps of omega tox+ and beta tox+ and the contribution of double lysogeny are discussed in relation to the hypertoxigenicity of the PW8 strain.     

Isolation and partial characterization of a corynebacteriophage beta, tox operator constitutive-like mutant lysogen of Corynebacterium diphtheriae.

We have isolated and partially characterized a beta-phage mutant lysogen of Corynebacterium diphtheriae, C7(betatoxct1+), which is partially insensitive to iron inhibition of diphtheria toxin production. tox expression by C7(betatoxct1+) was found to be partially constitutive. In the presence of concentrations of iron that almost completely inhibit the expression of diphtheria toxin by the wild type, C7(beta), the level of toxin production by C7(betatoxct1+) was found to be at least 25 times that of the parent. The purified tox gene product of C7(betatoxct1+) was immunologically and electrophoretically identical to, and equally as toxic as, diphtheria toxin purified from C7(beta). In addition, the partial N-terminal amino acid sequence was found to be identical to diphtheria toxin. This data strongly suggests that the mutation allowing for the constitutive expression of tox in C7(betatoxct1+) is outside of the structural gene. Furthermore, the constitutive expression of diphtheria toxin was found to be cis dominant in the double lysogen C7(betacrm45+/betatoxct1+). The data presented is consistent with the existence of a tox operator locus.     

Control of corynebacteriophage reproduction by heteroimmune repression.

Corynebacteriophages beta and gamma are closely related but heteroimmune; hence, gamma reproduces in C7(beta). A series of gamma mutants, designated gamma-bin (beta-inhibited), has been isolated. They reproduce in only 2 to 14% of infected C7(beta) cells, and, as a result, plaque with an efficiency of 10(-4) to 10(-5) on this strain. The proportion of C7(beta) cells in which gamma-bin phage can replicate is increased to 30 to 80% when immunity is lifted by UV induction of C7(beta) or by heat induction of C7(beta-tsr3). The gamma-bin mutants carry out a normal vegetative or lysogenic cycle in strain C7 and thus do not appear to be defective in any essential phage function. Infection of C7(beta) by gamma-bin results in cell killing whether the infection is productive or nonproductive. The data support the hypothesis that inhibition of gamma-bin is due to the direct or indirect action of a beta prophage gene. The simplest hypothesis is that gamma-bin phages have sustained mutations in an operator site and that beta repressor now combines with the mutated operator to inhibit normal replication in a significant proportion of infected cells.     

Gene responsible for superinfection exclusion of heteroimmune corynebacteriophage.

Wild-type beta and gamma corynebacteriophages are heteroimmune and infect lysogens of each other productively. Unlike their wild-type counterparts, the bin mutants of each phage are excluded in lysogens carrying the heteroimmune phage. The wild-type phages overcome exclusion by means of the bin gene product which appears to act as an antirepressor. When repression is lifted, exclusion of bin mutants is abolished (N. Groman and M. Rabin, J. Virol. 28:28-33, 1978; J. Virol. 36:526-532, 1980). It has not been clear whether the excluding compound is the immune repressor itself or one whose synthesis is positively regulated by repressor. We have isolated beta exclusion mutants (xcl) that as prophage exhibited normal immune repression but no longer excluded gamma-bin mutants. Furthermore, we have shown that an xcl phage with an active immune repressor acted in trans to continue the positive regulation of exclusion by a second xcl+ prophage whose immune repressor was inactivated. From these results it was concluded that there is a gene distinct from the imm gene which is directly or indirectly responsible for exclusion. The xcl gene, mapped in prophage crosses, was located between imm and bin, that is, in the regulatory region of the phage genome. The simplest hypothesis compatible with the established observations is that beta immune repressor regulates the expression of the xcl and bin genes, the former positively and the latter negatively. It is likely that an analogous regulatory model applies to gamma phage since it has already been shown that both beta and gamma have bin alleles.     

Molecular cloning and expression of gene fragments from corynebacteriophage beta encoding enzymatically active peptides of diphtheria toxin

Two restriction fragments from corynebacteriophage beta vir tox+ that encode peptides similar to diphtheria toxin fragment A and the chain termination fragment, CRM45, have been cloned into Escherichia coli in plasmid pBR322. Clones containing the recombinant plasmids produced gene products that were active in catalyzing the ADP ribosylation of elongation factor 2 and were reactive with diphtheria toxin antiserum. Toxin-related peptides were found primarily in the periplasmic compartment and were degraded to nonimmunoreactive forms within 1 to 2 h of synthesis. The expression of both gene fragments appears to have originated from the diphtheria toxin promoter.     

Purification of interleukin-1 beta converting enzyme, the protease that cleaves the interleukin-1 beta precursor.

We have purified the IL-1 beta converting enzyme from the THP-1 cell line using standard chromatographic techniques and obtained the N-terminal amino acid sequence of this novel protein. After stimulation of THP-1 cells with lipopolysaccharide, hydroxyurea, and silica, the protease was solubilized by multiple freeze/thawing. The protein was purified by ion-exchange chromatography, affinity chromatography on blue agarose, gel filtration, and chromatofocusing. The molecular weight of the protein is approximately 22,000 Da and the pI is between 7.1 and 6.8. The overall yield for this procedure was 16% of the activity found in the initial cell lysates. An antiserum raised against a peptide based on the N-terminus was used to precipitate the protease, confirming our identification of the 22,000-Da protein as the IL-1 beta converting enzyme.     

Interleukin-1 beta converting enzyme requires oligomerization for activity of processed forms in vivo.

Interleukin-1 beta converting enzyme (ICE) is composed of 10' (p10) and 20 kDa (p20) subunits, which are derived from a common 45 kDa precursor. Recent crystallographic studies have shown that ICE exists as a tetramer (p20/p10)2 in the crystal lattice. We provide evidence that the p10 and p20 subunits of ICE associate as oligomers in transfected COS cells. Using intragenic complementation, we show that the activity of a p10/p10 interface mutant defective in autoprocessing can be restored by co-expression with active site ICE mutants. Different active site mutants can also complement each other by oligomerization to form active ICE. These studies indicate that ICE precursor polypeptides may associate in different quaternary structures and that oligomerization is required for autoprocessing. Furthermore, integenic complementation of active site mutants of ICE and an ICE homolog restores autoprocessing activity, suggesting that hetero-oligomerization occurs between ICE homologs.     

Physical mapping of beta-converting and gamma-nonconverting corynebacteriophage genomes

Deoxyribonucleic acids (DNAs) from wild-type and mutant strains of beta-converting and gamma-nonconverting corynebacteriophages were isolated and physically characterized. The data obtained from DNA heteroduplexes, restriction enzyme banding profiles, and restriction maps reinforce the conclusion that beta and gamma phages are very closely related. The major physical differences seen in the DNA heteroduplexes are a small substitution bubble and one or two insertions which are present on the gamma phage genome. The insertions account for the differences in the genome sizes of beta and gamma phages, and with the substitution they are responsible for most of the differences in the restriction endonuclease profiles and maps of the corynebactriophage genomes, two special sites and the DNA fragments carrying them were identified. These were the cohesive (cos) sites and the specific attachment (attP) site of the vegetative phage genome. The behavior of these sites indicated that the transition of phage DNA from the vegetative to the prophage state involves the circularization of vegetative DNA through the cos sites and its integration into the bacterial chromosome via the attP site. The mechanism of corynebacteriophage integration was similar to that employed by Escherichia coli phage gamma. From the data assembled the physical and genetic maps of beta and gamma phage were oriented with respect to one another. The extensive similarity in their maps provides additional confirmation of a close evolutionary relationship.     

Prophage induction and inactivation by UV light.

Analysis of the induction curves for UV light-irradiated Haemophilus influenzae lysogens and the distribution of pyrimidine dimers in a repair-deficient lysogen suggests that one dimer per prophage-size segment of the host bacterial chromosome is necessary as a preinduction event. The close correlations obtained prompted a renewed consideration of the possibility that direct prophage induction occurs when one dimer is stabilized within the prophage genome. The host excision-repair system apparently functions to reduce the probability of "stabilizing" within the prophage those dimers that are necessary for induction and inactivation. The presence of the inducible defective prophage in strain Rd depresses the inducibility of prophage HP1c1.     

Degradation of the Alzheimer's amyloid beta peptide by endothelin converting enzyme

The deposition of β-amyloid (Aβ) peptides in the brain is an early and invariant feature of all forms of Alzheimer's disease (AD). As such, a major focus of AD research has been the elucidation of the mechanisms responsible for the generation of Aβ. As with any peptide, however, the degree of Aβ accumulation is dependent not only on its production, but also on the mechanisms responsible for its removal. In cell-based and in vitro assays we have identified endothelin-converting enzymes (ECEs) as novel Aβ-degrading enzymes that appear to cleave predominately in an intracellular compartment. Overexpression of ECE-1 in cells that lack endogenous ECE activity reduces Aβ accumulation by up to 90%, and this effect is completely reversed by treatment of the cells with phosphoramidon. Additionally, we have shown that recombinant soluble ECE-1 is capable of hydrolyzing synthetic Aβ40 and Aβ42 in vitro at multiple sites, with a favorable kinetic profile. While several enzymes have been identified that can degrade Aβ in vitro , only neprilysin has thus far been reported to influence Aβ accumulation in the brains of knock-out mice. To examine the physiological role of ECE activity on Aβ accumulation in the brain we compared the amount of Aβ in wild-type and ECE-2 null mice. A significant elevation in both Aβ40 and Aβ42 was observed in the ECE-2 null animals compared to their wild-type littermates. These data provide direct evidence of a physiological role for this enzyme in limiting Aβ accumulation in the brain.
Acknowledgements: Supported by Smith Fellowships to C.E. and E.E., a Bursak Fellowship to E.E., and by the Mayo Foundation for Medical Education and Research.     

Prophage P2 does not kill recB bacteria.

$\text{Escherichia}\text{coli}$ carrying a temperature-sensitive $\text{recB}$ mutation and lysogenic for phage P2 was able to grow normally even at 42°C, at which temperature the bacteria are phenotypically $\text{recB}{}^{\mathrm{?}}$. At this temperature, the bacteria were, however, unable to support the growth of λspi^? phages.     

Viral inhibition of inflammation: cowpox virus encodes an inhibitor of the interleukin-1 beta converting enzyme.

Cowpox virus effectively inhibits inflammatory responses against viral infection in the chick embryo. This study demonstrates that one of the viral genes necessary for this inhibition, the crmA gene (a cytokine response modifier gene), encodes a serpin that is a specific inhibitor of the interleukin-1 beta converting enzyme. This serpin can prevent the proteolytic activation of interleukin-1 beta, thereby suppressing an interleukin-1 beta response to infection. However, the modification of this single cytokine response is not sufficient to inhibit inflammatory responses. This suggests that cowpox virus encodes several cytokine response modifiers that act together to inhibit the release of pro-inflammatory cytokines in response to infection. These viral countermeasures to host defenses against infection may contribute significantly to the pathology associated with poxvirus infections.