Isolation and characterization of Corynebacterium diphtheriae nontandem double lysogens hyperproducing CRM197.

Phage beta 197tox-, which codes for CRM197, a nontoxic protein immunochemically indistinguishable from diphtheria toxin, was UV induced from a culture of the C7(beta 197)tox- strain. A total of 191 C7(beta 197)tox- lysogens were isolated and selected according to the halo produced on TYE agar containing antidiphtheria toxin serum and were further characterized by Southern blots of their chromosomal DNA. Most of the isolates turned out to be monolysogens, but some tandem and nontandem double lysogens were also found. The nontandem double lysogens were stable and capable of giving high yields of CRM197, up to threefold higher than monolysogens. They are, therefore, suitable for large-scale industrial production.     

Regulation of toxinogenesis in Corynebacterium diphtheriae. I. Mutations in bacteriophage beta that alter the effects of iron on toxin production

Diphtherial toxin is produced in maximal yields by Corynebacterium diphtheriae (C7(beta tox+) only when iron is present in growth-limiting amounts. Toxin production is markedly decreased under high-iron conditions. We studied the role of the bacteriophage beta genome in this apparent regulation of toxin production by iron. Using a passive immune hemolysis assay to detect toxin antigen production in individual plaques, we identified rare phage mutants that were toxinogenic in high-iron medium. Lysogenic derivatives of C. diphtheriae C7 harboring such phage mutants were constructed. The lysogens were compared with wild-type strain C7(beta) for their ability to produce toxin in deferrated liquid medium containing varying amounts of added iron. Quantitative tests for extracellular toxin were performed by competitive-binding radioimmunoassays. We identified phenotypically distinct mutant strains that produced slightly, moderately, or greatly increased yields of toxin antigen under high-iron conditions. The toxin produced by the mutant lysogens was biologically active and immunochemically indistinguishable from wild-type toxin. Complementation experiments demonstrated that the phage mutation designated tox-201 had a cis-dominant effect on the expression of the toxin structural gene of phage beta. The characteristics of the tox-201 mutation suggest that it defines a regulatory locus of phage beta that is involved in control of toxinogenesis by iron in C. diphtheriae.     

Isolation and characterization of extragenic suppressor strains of Corynebacterium diphtheriae.

The isolation and characterization of two different nonsense suppressor strains of Corynebacterium diphtheriae C7 sup+(-)tox- are described. Appropriate lysogens of these strains with corynephage beta, carrying known class II tox premature polypeptide chain termination mutations [C7sup-1(betatox-30) and C7sup-2(betatox-45)], each produce a 62,000-dalton polypeptide with nicotinamide adenine dinucleotide: elongation factor-2 adenosine diphosphate ribosyltransferase activity in addition to a chain-terminated polypeptide of 30,000 or 45,000 daltons, respectively. In addition, purified protein of 62,000 daltons, resulting from the suppression of the nonsense mutations tox-30 and tox-45, will react with antisera purified against the terminal 17,000 daltons of the toxin molecule and are immunologically identical to toxin by radial immunodiffusion. The suppression pattern of lysogenic derivatives of C7sup-1(-)tox- and C7sup-2(-)tox- with other class II and III mutants of corynephage beta was determined.     

Integration of corynebacteriophages beta tox+, omega tox+, and gamma tox- into two attachment sites on the Corynebacterium diphtheriae chromosome.

The bacterial attachment sites of independently isolated Corynebacterium diphtheriae strains C7s and (belfanti)1030 lysogenic for corynebacteriophages beta tox+, omega tox+, and gamma tox- were determined by Southern blot analysis. Both corynebacterial strains contained two distinct bacterial attachment sites (attB1 and attB2). We found that infection by any of the three closely related corynebacteriophages may give rise to single, double, and triple lysogens. In the case of toxigenic C. diphtheriae strains C7s(beta tox+) and C7s(omega tox+), the final yields of diphtheria toxin produced under optimal conditions were equivalent and varied by one-, two-, or threefold depending upon the number of integrated prophage.     

High-yield production of diphtheria toxin mutants by high-density culture of C7(β)tox+ strains grown in a non-deferrated medium

A high-density growth approach was utilized to produce mutated diphtheria toxin from two strains of Corynebacterium diphtheria: C7 ()^{(tox-201, tox-9)} and C7 ()^(tox-107). The cross-reacting mutants (CRM) of the diphtheria toxin are CRM9 and CRM107; both of them carry the mutation in their binding site and, as a result, have 1/300 of the systemic toxicity of the wild-type diphtheria toxin. Since iron inhibits diphtheria toxin production, the traditional approach has been to grow the bacteria in a very low iron concentration. The procedure described here involved the use of a modified, non-deferrated, growth medium that provided fast and high-density growth of the bacteria, and which, when associated with simultaneous depletion of glucose and iron, enhanced the toxin production. Oxygen-enriched air was supplied to enable the bacteria to grow to a cell density giving an absorbance of 70 at 600 nm (15–20 g/l dry weight). The maximum toxin concentration in the culture supernatant was 150 mg/l. The CRM products, which remained stable following microfiltration and ultrafiltration, could be easily purified using a two-step chromatography procedure.     

Single mutation in the A domain of diphtheria toxin results in a protein with altered membrane insertion behavior

The insertion of the A domain of diphtheria toxin into model membranes has been shown to be both pH- and temperature-dependent (Hu and Holmes (1984) J. Biol. Chem. 259, 12226-12233). In this report, the insertion behavior of two mutant proteins of diphtheria toxin, CRM197 and CRM9, was studied and compared to that of wild-type toxin. Results indicated that both CRM197 and CRM9 resembled toxin with respect to the pH-dependence of binding to negatively-charged liposomes at room temperature. However, CRM197 differed from toxin with respect to both the pH- and temperature-dependence of fragment A insertion; fragment A197 inserts more readily into the bilayer at 0 degrees C and low pH or at neutral pH and room temperature than does wild type fragment A under these same conditions. This result indicates that the single amino acid substitution in the A domain of CRM197 facilitates entry of fragment A197 into the membrane, suggesting that CRM197 may be conformationally distinct from native toxin. In fact, the fluorescence spectra of CRM197 and wild-type toxin as well as their respective tryptic peptide patterns indicate that, at pH 7, CRM197 more closely resembles the acid form of wild-type toxin than the native form of toxin. These data suggest that CRM197 may be naturally in a more 'insertion-competent' conformation. In contrast, the mutation in the B domain of CRM9 which results in a 1000-fold decrease in binding affinity for plasma membrane receptors apparently does not cause a change in either the insertion of fragment A9 or the lipid-binding properties of CRM9 relative to toxin.     

Influence of Transformability on the Formation of Superinfection Double Lysogens in Haemophilus influenzae

Superinfection of growing (nontransformable) cells of defectively lysogenic strains of Haemophilus influenzae with wild-type or with mutant phage HP1 resulted in a number of double lysogens and a small number of monolysogens with altered prophage. The double lysogens were identified by analysis of their monolysogenic segregants and by examining their deoxyribonucleic acid in certain test crosses. The results indicate that the majority had been formed by insertion of the infecting phage genome within the resident prophage. Superinfection of transformable bacteria gave rise to cells with altered prophages (presumably transformants) and to double lysogens which had gained or lost wild-type prophage loci.     

Mechanism of non-tandem integration of prophage phi 80 into the chromosome of the wild-type Escherichia coli

We studied the ability of lambda, phi 80 and their hybrid lambda att80 to lysogenize homoimmune monolysogens and examined the prophage locations on the chromosome of the resulting polylysogens. We observed an effective integration of phi 80 and lambda att80, in contrast to lambda, into the host chromosome, exclusively, at the attachment sites that were not occupied by the resident prophage (nontandem). Besides, the lambda att80 (int+) prophage was observed to ensure effective nontandem integration of a homoimmune int mutant DNA. Hence, we inferred that the expression of the int gene in the phi 80 prophage is constitutive, cI-independent and results in nontandem integration of the homoimmune prophage. The validity of this inference has been supported experimentally: (i) the only lysogen that was found to contain a phi 80 tandem was highly unstable (spontaneous segregation of monolysogens occurred 6-7 times more frequently than with the lambda tandem); (ii) an int inactivating mutation stabilized the phi 80 tandem; as a result, the int mutant has the frequency of tandem integration as high as that of lambda, while no nontandem integration was observed. A hypothesis is proposed which accounts for the instability of the phi 80 tandems and explains the relation between this phenomenon and the prophage ability to integrate into secondary attachment sites in the presence of the primary (normal) one.     

Binding properties of diphtheria toxin to cells are altered by mutation in the fragment A domain

CRM197, CRM176, and CRM228 are products of single or multiple missense mutations in the diphtheria toxin gene. CRM197 differs from wild-type toxin in 1 amino acid residue of the fragment A region, and also CRM176 and CRM228 have amino acid substitution(s) in fragment A. We compared the binding properties of CRM197 to toxin-sensitive Vero cells with those of diphtheria toxin and other CRMs. Nicked CRM197 is about 50 times more effective than intact CRM197 in inhibiting the action of diphtheria toxin on sensitive cells, as shown by inhibition of diphtheria toxin cytotoxicity or inhibition of binding of 125I-diphtheria toxin. The binding of native toxin or other CRMs was not significantly affected by nicking. Moreover, the binding of CRM197 to cells was unaffected by ATP, although ATP clearly inhibits binding of diphtheria toxin, CRM176, and CRM228. Two kinds of hybrid protein were formed using fragment B of CRM197: one with fragment A of diphtheria toxin and one with fragment A of CRM228. ATP inhibited the binding of these hybrid proteins. Furthermore, the affinities of these hybrid proteins for diphtheria toxin-sensitive cells were the same as that of native toxin. Thus, it was concluded that the altered binding properties of CRM197 were due to alteration of fragment A and what the interaction of diphtheria toxin with ATP involves both fragments. The results also suggest that fragment A plays a role in diphtheria toxin-receptor interaction.     

Restriction endonuclease map of the nontoxigenic corynephage gamma c and its relationship to the toxigenic corynephage beta c.

Clear-plaque-forming mutant gamma tox- corynephages were isolated independently from nontoxigenic lysogenic Corynebacterium diphtheriae strains C7s(gamma tox-) and C4(gamma tox-). A physical map was constructed by using restriction endonucleases BamHI, EcoRI, HindIII, and KpnI. A comparison of nontoxigenic gamma c with toxigenic corynephage beta c revealed large areas of homology, including common regions for cohesive ends (cos) and attachment sites (att). Localization of the att sites on the beta prophage and correlation of the physical and genetic maps defined the orientation of the diphtheria tox operon. Diphtheria tox sequence homologies were mapped on gamma c by hybridizing 32P-labeled diphtheria tox mRNA to restriction fragments of gamma c DNA. Two regions of heterogeneity between phages beta c and gamma c were localized and these regions accounted for the 3-kilobase larger molecular size of gamma c compared with beta c. One change occurs near the tox promoter and may explain the nontoxigenic phenotype of corynephage gamma tox-.     

Molecular Cloning,Structural Modeling and the Production of Soluble Triple-Mutated Diphtheria Toxoid (K51E/G52E/E148K) Co-expressed with Molecular Chaperones in Recombinant <Emphasis Type="Italic">Escherichia coli</Emphasis>

CRM197 is a diphtheria toxin (DT) mutant (G52E) which has been used as a carrier protein for conjugate vaccines. However, it still possesses cytotoxicity toward mammalian cells. The goal of this project was to produce a non-toxic and soluble CRM197EK through introduction of triple amino acid substitutions (K51E/G52E/E148K) in Escherichia coli. The expression of CRM197EKTrxHis was optimized and co-expressed with different molecular chaperones. The soluble CRM197EKTrxHis was produced at a high concentration (97.33 ± 17.47 μg/ml) under the optimal condition (induction with 0.1 mM IPTG at 20 °C for 24 h). Cells containing pG-Tf2, expressing trigger factor and GroEL-GroES, accumulated the highest amount of soluble CRM197EKTrxHis at 111.24 ± 10.40 μg/ml after induction for 24 h at 20 °C. The soluble CRM197EKTrxHis still possesses nuclease activity and completely digest λDNA at 25 and 37 °C with 8- and 4-h incubation, respectively. Molecular modeling of diphtheria toxin, CRM197 and CRM197EK indicated that substitutions of two amino acids (K51E/E148K) may cause poor NAD binding, consistent with the lack of toxicity. Therefore, CRM197EK might be used as a new potential carrier protein. However, further in vivo study is required to confirm its roles as functional carrier protein in conjugate vaccines.     

The amino-acid sequence of two non-toxic mutants of diphtheria toxin: CRM45 and CRM197.

The amino-acid sequences of two diphtheria toxin-related, non-toxic proteins, CRM45 and CRM197 , were deduced from the complete sequence of their genes: tox 45 and tox 197. CRM45 lacks the last 149 C-terminal amino-acid residues, but is otherwise identical to diphtheria toxin: a single C----T transition introduces an "ochre" (TAA) termination signal in tox 45, after the codon for threonine-386. A single G----A transition was also found in tox 197, leading to the substitution of glycine-52, present in the wild-type toxin, with glutamic acid in CRM197 . This aminoacid change is responsible for the loss of the NAD:EF2 ADP-ribosyltransferase activity in CRM197 , due most probably to an alteration of the NAD+ binding site.     

Saccharomyces cerevisiae spheroplasts are sensitive to the action of diphtheria toxin.

Diphtheria toxin kills spheroplasts of Saccharomyces cerevisiae but not the intact yeast cells. After 2 h of exposure to ca. 10(-7) M toxin, less than 1% of spheroplasts were able to regenerate into intact cells. The same high levels of toxin inhibited the rate of protein synthesis by more than 90% within 1 h, whereas RNA and DNA synthesis were not inhibited until 4 h or exposure. Both killing and protein synthesis inhibition were dependent on toxin concentration. The nature of the toxin-cell interaction was also studied by using fragments of intact toxin and mutant toxin proteins. Neither toxin fragment A nor CRM45 nor CRM197 affected spheroplasts, but CRM197 and ATP prevented the inhibitory action of intact toxin. These results suggest that toxin acts on S. cerevisiae spheroplasts in much the same manner as it acts on sensitive mammalian cells.     

白喉毒素突变体CRM197在大肠杆菌中表达纯化及性质研究

CRM197是一种白喉毒素突变体,作为载体蛋白广泛用于疫苗开发。将合成的CRM197基因片段克隆到表达载体pET25b中,转化大肠杆菌BL21(DE3),经IPTG诱导,CRM197获得高效表达,达到菌体总蛋白的20%。目的蛋白主要以包涵体形式存在,变性、复性后经DEAE阴离子交换、S-100分子筛纯化获得纯度高于95%的CRM197样品,用该蛋白样品免疫新西兰大白兔,免疫兔血清中检测到特异性抗体应答。急性毒性试验中,每只豚鼠皮下注射200μgCRM197纯化样品,未出现明显毒性反应症状,与之相比较,注射后48h内,20ng白喉毒素阳性对照组动物全部死亡。结果表明,利用本试验的表达策略,CRM197得到高效表达,并且具有良好的免疫原性和安全性,为其进一步生产及应用奠定基础。     

Phage-transposon interaction: the cip locus of prophage D3112 responsible for the inhibition of integration and transposition of related phage B39 of Pseudomonas aeruginosa

Bacterial cells lysogenic for D3112, a transposable Pseudomonas aeruginosa phage restrict the growth of a related heteroimmune B39 phage. The lysogens are divided into two different types PAO(D3112). In the lysogens of the type I the efficiency of B39 growth only decreases slightly, the lysogens of the type II restricting completely the growth of this phage (e.o.p. is less than 10(-7). As shown by the results of Southern hybridization experiments, lysogens of the type I are monolysogens, while those of the type II are double or polylysogens. Restriction of B39 in PAO(D3112) is caused by expression of a locus in the D3112 genome. The locus has been termed as cip (control of interaction of phages). The cip locus was mapped at the interval 1.3-2.45 kb of the D3112 physical map using different deletion derivatives of D3112. Expression of cip only takes place in the prophage state and not during the phage lytic development. When expressed, cip affects the early steps in the growth of B39 lowering the level of integration and transposition processes; the effect is not dependent on the way of initiation of the lytic cycle (through prophage induction or infection).     

Murine red blood cells as efficient carriers of three bacterial antigens for the production of specific and neutralizing antibodies.

Three bacterial toxoids, CRM 197 (mutagenized diphtheria toxin), tetanus toxoid (formaldehyde-treated tetanus toxin), and PT-9K/129G (double mutant of pertussin toxin) were encapsulated within red blood cells (RBCs) of B6D2F1 and Balb/C mice according to a mild procedure based on hypotonic dialysis-isotonic resealing that yielded undamaged RBCs. The toxoid-loaded RBCs were injected intravenously in order to immunize animals and their effects were compared to those of identical amounts (30-95 micrograms per mouse subdivided into multiple injections) of the corresponding free toxoids injected intravenously in saline. Sera from treated mice were collected and tested for titers of specific antibodies against each of the three antigens and also for titers of neutralizing antibodies, i.e., affording protection from toxic effects induced by the corresponding native toxins. In all experiments, significant seroconversion was observed with both immunization systems. Titers of both specific and neutralizing antibodies against CRM 197 and tetanus toxoid were several-fold higher upon immunization with the RBC-encapsulated toxoids, than with the free toxoids. These differences were not due to qualitatively different recognition patterns of antigenic determinants by the two types of sera. Conversely, intravenous immunization with pertussis toxoid either as RBC-encapsulated or as free antigen elicited a comparably high production of specific and of neutralizing antibodies. These data demonstrate that properly engineered RBCs behave as natural carriers and possibly adjuvants for antigens of vaccinal interest.     

Prophage map of converting corynebacteriophage beta.

A prophage map for corynebacteriophage beta consisting of seven markers has been constructed and compared with the vegetative map. The mapping system utilizes heteroimmune double lysogens and capitalizes on the fact that these double lysogens are very unstable and throw off monolysogenic segregants. The prophage map, produced by characterizing the recombinant phage in these monolysogenic segregants, appears to be a cyclic permutation of the vegetative map with the gene for toxin at one end of the prophage map and the gene for phage immunity at the other. This permutation is in accord with the Campbell model for insertion of lambda phage if a site between the toxin and immunity genes in the vegetative map is designated as the phage attachment site. The position of the gene for toxin in the prophage map suggests that converting phages may have originated as specialized transducing phages for this gene.