Immunodominant domains of the Measles virus hemagglutinin protein eliciting a neutralizing human B cell response.

The most important neutralizing and protective antibodies against Measles virus (MeV) are directed against the hemagglutinin protein (MeV-H). To define the MeV binding domains recognized by human antibodies a set of 10 non-redundant MeV-H-specific monoclonal antibodies (mabs) was used to block their binding in a competition ELISA. Sera from both naturally infected and vaccinated individuals showed similar competition patterns. Two distinct domains were identified as the main target of human antibodies. One domain corresponded to the region of the previously described hemagglutinin noose epitope (HNE, aa 380-400) [35], which is recognized by hemagglutination-inhibiting, neutralizing and protective mabs. The second region is defined by a mab with strong neutralizing but weak hemagglutination-inhibiting activity. Mabs with a strong neutralizing capacity with respect to wild-type viruses seemed to displace more human antibodies than those with a weaker neutralizing activity. Human antibodies seem to react more weakly with the hemagglutinin regions that bind the CD46 and the fusion protein and more strongly with the putative CD150 binding site and the top loops of beta-sheet 2 and 3 of the hemagglutinin.

Neutralizing immunogenicity of transgenic carrot (Daucus carota L.)-derived measles virus hemagglutinin.

Although edible vaccines seem to be feasible, antigens of human pathogens have mostly been expressed in plants that are not attractive for human consumption (such as potatoes) unless they are cooked. Boiling may reduce the immunogenicity of many antigens. More recently, the technology to transform fruit and vegetable plants have become perfected. We transformed carrot plants with Agrobacterium tumefaciens to generate plants (which can be eaten raw) transgenic for an immunodominant antigen of the measles virus, a major pathogen in man. The hemagglutinin (H) glycoprotein is the principle target of neutralizing and protective antibodies against measles. Copy numbers of the H transgene were verified by Southern blot and specific transcription was confirmed by RT-PCR. The H protein was detected by western blot in the membrane fraction of transformed carrot plants. The recombinant protein seemed to have a 8% lower molecular weight than the viral protein. Although this suggests a different glycosylation pattern, proper folding of the transgenic protein was confirmed by conformational-dependent monoclonal antibodies. Immunization of mice with leaf or root extracts induced high titres of IgG1 and IgG2a antibodies that cross-reacted strongly with the measles virus and neutralized the virus in vitro. These results demonstrate that transgenic carrot plants can be used as an efficient expression system to produce highly immunogenic viral antigens. Our study may pave the way towards an edible vaccine against measles which could be complementary to the current live-attenuated vaccine.

Differential antigenicity of recombinant polyepitope-antigens based on loop- and helix-forming B and T cell epitopes.

To investigate a strategy for the design of chimeric antigens based on B cell epitopes (BCEs) we have genetically recombined multiple copies of loop- (L) and helix-forming (H) sequential and protective BCEs of the measles virus hemagglutinin protein (MVH) in a number of high-molecular-weight polyepitope constructs (24.5-45.5 kDa). The BCE cassettes were combined semi-randomly together with a promiscuous T cell epitope (TCE; tt830-844) to yield 13 different permutational constructs. When expressed in mammalian cells, all constructs were detectable by Western blot as distinct bands of predicted molecular weight. Flow cytometry with conformation-specific antibodies revealed the Cys-loop in two [(L(4)T(4))(2) and (L(2)T(2))(4)] and the helix conformation in one [(H(2)T(2))(4)] of the different permutational constructs. The larger constructs, containing 16 epitope cassettes, seemed more likely to express the BCEs in their native conformation than the 8-mers. In the T cell proliferation assay, constructs with a higher copy number of TCEs, such as (L(2)T(2))(4), were more antigenic, as long as tandem repeats were separated by spacers. Since the conformation of even sequential BCEs and the processing of TCEs are both sensitive to their molecular environment it is difficult to predict the antigenic properties of polyepitopes. However, with the permutational approach we have developed several polyepitope constructs [(L(4)T(4))(2), (L(2)T(2))(4), (H(2)T(2))(4)] based on complex sequential BCEs that are antigenic for both T and B cells. Several constructs induced sera that reacted with reporter peptides, demonstrating that the sequential nature of the viral epitopes was conserved in the polyepitopes. Although several sera contained antibodies directed against amino acids critical for neutralization, only one construct induced antibodies that cross-reacted with the virus. Our results show the difficulty of designing chimeric antigens based on B cell epitopes mimicking their antigenic and immunologic properties even when these are sequential in nature.

Evaluation of different measles IgG assays based on recombinant proteins using a panel of low-titre sera.

During the WHO campaign to eradicate measles, accurate discrimination between immune and non-immune individuals will become increasingly important. Due to waning immunity in vaccinated populations, the performance of a measles IgG assay depends mainly on its ability to detect reliably seronegative individuals among many vaccinees with low antibody levels. New serological tests based on recombinant proteins detect only a fraction of the total measles virus (MV) specific antibodies. Therefore, several assays based on recombinant MV-haemagglutinin (ELISA and flow cytometry) or MV-fusion protein (flow cytometry) as well as neutralisatlon and haemagglutination test have been evaluated using a large panel of low-titre and negative sera. Since such an evaluation is highly dependent on threshold values for positivity, the receiver operating characteristic curve analysis was applied. The H-FACS and the H-ELISA showed the best performing characteristics (specificity: 97.4 and 96.1%, respectively; sensitivity: 88.1 and 89.6%, respectively) and may be an alternative to the neutralisation assay. The number of undefined/grey zone sera was significantly lower compared to a commercial whole virus-based ELISA and therefore fewer individuals would be vaccinated unnecessarily.

Evaluation of hemagglutinin protein-specific immunoglobulin M for diagnosis of measles by an enzyme-linked immunosorbent assay based on recombinant protein produced in a high-efficiency mammalian expression system.

Recombinant hemagglutinin (H) of the measles virus (MV) expressed in a mammalian high-expression system based on the Semliki Forest virus replicon was used in an enzyme-linked immunosorbent assay (ELISA) for the detection of specific immunoglobulin M (IgM) and IgG in patients with acute-phase measles. One hundred twelve serum specimens from 70 patients with measles were analyzed. Case definition was based on a commercial IgM ELISA that utilizes MV-infected cells (MV-ELISA) (Enzygnost; Behring Diagnostics); the clinical criteria of the Centers for Disease Control and Prevention (Atlanta, Ga.); and/or the increase in hemagglutinin test titers, neutralization test titers, and levels of MV-specific IgG whenever paired sera were available. The initial time courses of the IgM signal after the onset of rash are similar in the H- and MV-ELISAs. On days 0 to 19, both ELISAs detected IgM in 67 of 68 (98.5%) sera. Average maximal levels of IgM seem to persist, however, about 10 days longer in the MV-ELISA (up to day 25) than in the H-ELISA (day 15). From days 20 to 29 and 30 to 59, the H-ELISA detected only 64.3 (9 of 14) and 19.2% (5 of 26), respectively, of sera that were IgM positive by MV-ELISA. At least up to day 30, the performance of the H-ELISA seemed to be similar to that reported for commercial ELISAs based on whole MV. Our results demonstrate that MV H-specific IgM can be used to diagnose most measles cases from a single serum specimen collected within 19 days after the onset of rash and that the recombinant protein used in this study is suitable for this purpose.

A simplified immunoassay based on measles virus recombinant hemagglutinin protein for testing the immune status of vaccinees.

Simplified tests based on recombinant antigens are considered to be important for monitoring immunity against measles virus (MV). The hemagglutinin protein (H) is the main target for neutralising and protective antibodies. We produced a recombinant MV-H protein, in a high-yield mammalian expression system based on the Semliki Forest virus replicon. The antigenicity of this recombinant protein was investigated with monoclonal antibodies and its suitability for measuring the immune status of vaccinees was tested in a large cohort by ELISA (H-ELISA). The results were evaluated against neutralisation (NT) and hemagglutination inhibition (HI) titers and MV-specific IgG measured in a commercial whole-virus based ELISA (MV-ELISA, Enzygnost). The H-ELISA correlated better with HI (r=0.78) and NT titers (r=0.80), than the MV-ELISA (HI, r=0.58; NT, r=0.59). In contrast to the MV-ELISA, the H-ELISA detected no false-positive sera (P < 0.02) and the number of false-negative sera was significantly lower in the H-ELISA than in the MV-ELISA (4/378 vs. 15/378; P < 0.025). The performance of the H-ELISA did not deteriorate significantly when, instead of background corrected net values, uncorrected raw O.D. values of the H-antigen were considered, or when early time points (30 min) were evaluated. These results demonstrate that the recombinant H-ELISA detects efficiently non-immune individuals among vaccinees, despite their relatively low MV-antibody levels. A simplified format with single value measurements did not result in loss of sensitivity or specificity and its performance compared favorably with commercial ELISAs based on whole virus.

Immunosorbent assay based on recombinant hemagglutinin protein produced in a high-efficiency mammalian expression system for surveillance of measles immunity.

Recombinant hemagglutinin (H) protein of the measles virus (MV) was produced in mammalian cells with a high-yield expression system based on the Semliki Forest virus replicon. Crude membrane preparations of H protein-transfected BHK-21 cells were used to coat microtiter plates to measure specific immunoglobulin G antibodies in 228 serologically defined serum samples mainly from measles late-convalescent adults. The titers by the enzyme-linked immunosorbent assay for the H protein (H-ELISA) closely correlated with neutralization test (NT) titers (R2 = 0.66), hemagglutination inhibition test (HI) titers (R2 = 0.64), with the titers from a certified commercial ELISA based on whole MV-infected cells (MV-ELISA; R2 = 0.45). The correlations described above were better than those of the commercial MV-ELISA titers with the NT (R2 = 0.52) or HI (R2 = 0.48) titers. By using the 2nd International Standard for anti-measles serum, the detection level of the assay corresponds to 215 mIU/ml for undiluted serum, which corresponds to the estimated threshold for protective immunity. The specificity, accuracy, and positive predictive value were, in general, better for the H-ELISA than for a commercial MV-ELISA, independent of whether HI, NT, or HI and NT were used as "gold standards." In contrast, the H-ELISA proved to be slightly less sensitive than the MV-ELISA (sensitivities, 98.6 versus 99.5%, respectively; P was not significant). The assays did not differ significantly in the number of serum samples with positive HI and NT results (n = 212) which measured false negative (H-ELISA, 2 of 212 [0.94%]; MV-ELISA, 1 of 212 [0.47%]), but the H-ELISA detected significantly more measles-susceptible individuals than the MV-ELISA (10 of 11 versus 3 of 11, respectively; P < 0.05) among the individuals whose sera had negative HI and NT results. Our data demonstrate that the H-protein preparation that we describe could be a cost-effective alternative to current whole-virus-based ELISAs for surveillance for immunity to measles and that such an assay could be more efficient in detecting susceptibility to measles. Furthermore, unlike whole MV-based antigens, H-protein would also be suitable for use in the development of a simple field test for the diagnosis of measles.

Minicell-forming mutants of Escherichia coli: suppression of both DicB- and MinD-dependent division inhibition by inactivation of the minC gene product.

We have determined the nucleotide sequence of the minB operon of 10 min mutants of Escherichia coli, characterized by impaired inhibition of polar divisions. These mutants were either sensitive or resistant to the division inhibitor DicB. All the mutations were found to lie in minC or minD, confirming the requirement of both gene products in the process of inhibition of polar sites. Mutations conferring resistance to inhibitor DicB were found exclusively in minC. In agreement with de Boer et al. (P. A. J. de Boer, R. E. Crossley, and L. I. Rothfield, Proc. Natl. Acad. Sci. USA 87:1129-1133, 1990), these results provide evidence that, in addition to promoting division inhibition with MinD, protein MinC acts in concert with DicB to inhibit division by a second, MinD-independent process.

Isolation and mapping of Escherichia coli mutations conferring resistance to division inhibition protein DicB.

Temperature-sensitive dicA mutants of Escherichia coli, dicA1(Ts), are blocked for cell division, owing to derepressed expression of a division inhibition gene, dicB. We isolated mutants which survived a high temperature in the dicA1 background and which survived induced expression of dicB carried by a high-copy-number plasmid. Most of the mutations conferred very slow growth on the cells. Two were mapped to the 90-min cluster of genes involved in translation and transcription, in or very close to gene rpoB. The majority of the other mutations were found to cause variable degrees of minicell formation and to map within or very close to the minB locus. Contrary to these mutations, the canonical min-1 mutation did not confer resistance to DicB.

Genetic evidence that DicF, a second division inhibitor encoded by the Escherichia coli dicB operon, is probably RNA.

The dicB operon of Escherichia coli, which was previously shown to code for a small protein inhibiting cell division, expresses a second inhibitor, DicF. Inhibition by DicF requires the transcription of a short (at the most 65 nucleotides long) stretch of DNA, acts in trans, and does not require the expression of other components of the dicABCF locus. The characteristics of the DNA sequence strongly suggest that division inhibition does not involve the translation of dicF mRNA into protein.

Cell division inhibition gene dicB is regulated by a locus similar to lambdoid bacteriophage immunity loci.

A mutation (dicA1) of a repressor gene located in the terminus region of the Escherichia coli chromosome has previously been shown to lead to temperature-dependent inhibition of division, and to be complemented by plasmids carrying either dicA or an adjacent gene dicC. In this study, operon fusions in the region coding for the division inhibition gene dicB have been used to show that temperature sensitivity does not result from high temperature inactivation of the dicA repressor. Sequence comparisons indicate that dicA and dicC are similar to genes c2 and cro respectively of bacteriophage P22, and carry similarly organized tandem operators, indicating a common evolutionary origin for dicAC and P22 immC. Nevertheless, the consensus half-operator sequence of dicAC, TGTTA-GYYA, differs significantly from that of P22 immC (ATT-TAAGAN). An analysis of the in vivo control of promoters dicAp, dicBp and dicCp placed upstream of malQ shows that the dicAC system is functionally similar to that of an immunity region, with the possible exception of an absence of pairwise cooperative binding. Our results also indicate that the dicA1 mutation causes a switch to permanent control by dicC at all temperatures.