Size fractionation of bacterial capsular polysaccharides for their use in conjugate vaccines.

We have developed a chromatographic method suitable for the fractionation of polysaccharides having a negatively charged group. The method permits the removal of all those polysaccharide fragments having a short sequence and which are likely unsuitable for conjugate vaccine construction. The selected polysaccharide fragments can be used to produce glycoconjugate vaccines containing a restricted saccharide polydispersion. We have applied this chromatographic method to three different antigens, Haemophilus influenzae type b and Neisseria meningitidis group A and group C polysaccharides. The method is easily adapted for manufacturing purposes.

Bactericidal monoclonal antibodies that define unique meningococcal B polysaccharide epitopes that do not cross-react with human polysialic acid.

The poor immunogenicity of the Neisseria meningitidis group B polysaccharide capsule, a homopolymer of alpha(2-->8) sialic acid, has been attributed to immunologic tolerance induced by prenatal exposure to host polysialyated glycoproteins. Substitution of N-propionyl (N-Pr) for N-acetyl groups on the meningococcal B polysaccharide, and conjugation of the resulting polysaccharide to a protein carrier, have been reported to yield a conjugate vaccine that elicits protective Abs with minimal autoantibody activity. To characterize the protective epitopes on the derivatized polysaccharide, we isolated 30 anti-N-Pr meningococcal B polysaccharide mAbs. These Abs were heterogeneous with respect to complement-mediated bactericidal activity, fine antigenic specificity, and autoantibody activity as defined by binding to the neuroblastoma cell line, CHP-134, which expresses long-chain a(2-->8)-linked polysialic acid. Eighteen of the Abs could activate complement-mediated bacteriolysis. Seven of these 18 Abs cross-reacted with N-acetyl meningococcal B polysaccharide by ELISA and had strong autoantibody activity. Thus, N-Pr meningococcal B polysaccharide conjugate vaccine has the potential to elicit autoantibodies. However, 7 of the 18 bactericidal mAbs had no detectable autoantibody activity. These Abs may be useful for the identification of molecular mimetics capable of eliciting protective Abs specific to the bacteria, without the risk of evoking autoimmune disease.

Expression of the F glycoprotein gene from human respiratory syncytial virus in Escherichia coli: mapping of a fusion inhibiting epitope.

A cDNA copy of the gene encoding the entire amino acid sequence of the fusion (F) protein of human respiratory syncytial virus (strain A2) was inserted into a bacterial expression vector containing the lambda PR promoter. Upon heat induction, Escherichia coli cells harboring the vector produced a 45-kDa peptide which reacted with rabbit polyclonal antiserum to the native F protein. Expression of the F gene resulted in severe inhibition of bacterial growth, which was overcome by deletion of the DNA sequences encoding the F signal peptide. The region of the F protein which reacted with a virus-neutralizing and fusion-inhibiting monoclonal antibody was probed by expressing cDNA fragments encoding different protein domains in E. coli and testing antibody reactivity by Western blot analysis. Analysis of six fragments yielded an overlapping antibody-reactive region between amino acids 253 and 298. Analysis of reactivity with a cassette of synthetic peptides confirmed that the virus-neutralizing epitope mapped between residues 289 and 298 defined by the amino acid sequence M-S-I-I-K-E-E-V-L-A.

Fatty acid acylation of the fusion glycoprotein of human respiratory syncytial virus.

We describe the covalent attachment of palmitate to the fusion glycoprotein of respiratory syncytial virus and the identification of the attachment site. Labeling of respiratory syncytial virus-infected Vero cells with [3H]palmitate, followed by the purification and subsequent analysis of the fusion glycoprotein in conjunction with polyacrylamide gel electrophoresis, demonstrated that the fatty acid is covalently attached to the F1 subunit of the fusion glycoprotein. The bound palmitate was sensitive to 1 M hydroxylamine at neutral pH. In addition, the release of palmitate label by reduction with sodium borohydride showed that the palmitate is linked to the protein through a thioester bond. Isolation of a radiolabeled peptide from a tryptic digest of the protein and subsequent amino-terminal sequence analysis revealed that the cysteine residue (amino acid residue 550) within the anchor sequence, located at the carboxyl terminus of the F1 subunit, is the covalent attachment site for palmitate.

Purification, cyanogen bromide cleavage, and amino terminus sequencing of class 1 and class 3 outer membrane proteins of meningococci.

Meningococcal class 1 and 3 outer membrane proteins (OMPs) were subjected to cyanogen bromide treatment. The class 3 OMP was found to be resistant to cyanogen bromide, while the class 1 OMP was cut into two main fragments of 25 and 17 kilodaltons. The N-terminal sequences were determined for class 1 and class 3 proteins, which exhibit similarities to one another and to OMP I of gonococci. The C-terminal class 1 OMP fragment bound the bactericidal monoclonal antibodies tested.

Synthetic peptide representing a T-cell epitope of CRM197 substitutes as carrier molecule in a Haemophilus influenzae type B (Hib) conjugate vaccine.

The cross-reactive material (CRM197) of diphtheria toxin is considered to be advantageous as a carrier molecule in the formulation of a Haemophilus influenzae type b conjugate vaccine. In order to more precisely understand the function of the CRM197 in the vaccine, we have begun mapping the T-cell epitopes of the protein. A peptide which represents a segment of the primary sequence of CRM197 has been identified and found to stimulate diphtheria toxoid or CRM197-primed murine T-lymphocytes. In addition, the peptide is capable of priming T-cells in vivo for a subsequent in vitro T-cell response to itself or to the intact CRM197 molecule. The ability of the peptide to replace CRM197 as a carrier molecule was examined by immunizing mice with PRP, PRP-CRM197 conjugate, or PRP covalently coupled to the peptide. Antibodies to PRP were only detected in the PRP-CRM197 or PRP-peptide immunized groups. Both conjugates elicited primary and secondary antibody responses. Thus, a synthetic peptide representing a defined T-cell epitope of CRM197 has been functionally demonstrated based on its ability to act as a carrier molecule in a PRP conjugate vaccine.

Chemical evidence for covalent linkages of a semi-synthetic glycoconjugate vaccine for Haemophilus influenzae type B disease.

We have defined the nature of the covalent linkages in a Haemophilus influenzae type b oligosaccharide-CRM197 conjugate vaccine, designated HbOC. The conjugate was acid hydrolyzed to release a novel amino-acid derivative, N epsilon-(2-hydroxyethyl)lysine (OHEt-Lys), identifiable with an amino-acid analyzer. This amino-acid derivative was formed by reduction of Schiff bases formed between H. influenzae type b oligosaccharides (HbO) and the lysyl epsilon-amino groups of CRM197 (a non-toxic, cross-reactive variant of diphtheria toxin), followed by acid hydrolysis of HbOC. Quantification of OHEt-Lys per CRM197 molecule allowed the determination of a covalency ratio, a useful parameter for evaluating the stoichiometry and consistency of HbOC preparations. Covalent association between HbO and CRM197 was also demonstrated by the coincidence of immunoreactivity of gel-electrophoresed HbOC on a Western blot probed with anti-CRM197 and anti-saccharide antisera.

Purification and characterization of a peptidoglycan-associated lipoprotein from Haemophilus influenzae.

We have purified to homogeneity a peptidoglycan-associated protein from Haemophilus influenzae. Our purification process used differential extraction of cell envelopes with nondenaturing detergents. Solubilization of this protein was accomplished by heating a peptidoglycan-enriched subcellular fraction in the presence of one of several nondenaturing detergents at 55-60 degrees C. The purified protein migrated as a single band, with a Mr approximately 15,000, following sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This protein contains covalently linked fatty acids, is rich in tyrosine, but lacks methionine and tryptophan. Amino acid analysis also revealed the presence of glycerylcysteine, which has been shown to be the site of fatty acylation in other bacterial lipoproteins. Over 87% of the primary structure has been determined by sequencing high pressure liquid chromatography purified fragments derived from several endoproteinase digests. This protein belongs to a family of proteins, known as peptidoglycan associated lipoproteins, which appear to be components of the outer membranes of most Gram-negative bacteria.

Peptides bound to proteosomes via hydrophobic feet become highly immunogenic without adjuvants.

Addition of either a lauroyl or a pentapeptide (FLLAV) hydrophobic foot to the NH2 terminus of a small, synthetic peptide allowed the peptide to hydrophobically complex to meningococcal outer membrane protein proteosomes by simple dialysis. Both conventional and LPS-hyporesponsive mice immunized with these complexes without any adjuvants developed high-titered and persistent anti-peptide IgG. Since proteosomes have been safely given to many people and since important antigenic determinants are generally hydrophilic, this system should be widely applicable to the development of peptide vaccines for human use.

Introduction of Shigella flexneri 2a type and group antigen genes into oral typhoid vaccine strain Salmonella typhi Ty21a.

For protection against dysentery caused by Shigella flexneri 2a, an in vivo-constructed recombinant plasmid with genes specifying the S. flexneri type and group antigens located near the pro (min 6) and his (min 44) chromosomal markers, respectively, was made and transferred to the galE Salmonella typhi strain Ty21a. Strain Ty21a carrying this recombinant plasmid was shown by immunological and biochemical analyses to express the S. flexneri 2a type and group antigens. Mice immunized with this vaccine strain were found to be protected against challenge with virulent S. flexneri 2a, but not significantly against S. typhi challenge, presumably because synthesis of the Shigella antigens interfered with expression of the typhoid antigens. Elimination of the recombinant plasmid from Ty21a allowed this strain to again express typical S. typhi O antigens. Mouse protection against both S. typhi and S. flexneri 2a challenges was achieved with a whole-cell vaccine mixture composed of equal parts of Ty21a and the Ty21a-S. flexneri 2a hybrid strain.

Identification of ester-linked fatty acids of bacterial endotoxins by negative ion fast atom bombardment mass spectrometry.

Negative ion fast atom bombardment mass spectrometry (NI-FAB/MS) was employed to characterize the fatty acids esterified to the lipid A backbone of lipopolysaccharides (LPS) of gram-negative bacteria. LPS and their chemically derived lipid A produced readily detectable fragment ions characteristic of fatty acids. The NI-FAB/MS method is specific, yielding ions indicative of ester- but not of amide-bound fatty acids. The mass spectra of Enterobacteriaceae LPS revealed the presence of lauric (m/z 199), myristic (m/z 227), palmitic (m/z 255), and 3-hydroxymyristic (m/z 243) acids. Pseudomonas aeruginosa LPS gave distinctive fragment ions indicative of 3-hydroxydecanoic (m/z 187), lauric, and 2-hydroxylauric (m/z 215) acids. The Neisseria gonorrhoeae LPS could be distinguished from the others due to the presence of ester-linked 3-hydroxylauric acid. All of the LPS gave abundant ions of m/z 177 and 159, which were derived from diphosphoryl substituents. The use of NI-FAB/MS thus allowed rapid identification of lipid A esterified fatty acids without chemical derivatization or gas chromatographic analysis.

Expression of lipopolysaccharide O antigen in Escherichia coli K-12 hybrids containing plasmid and chromosomal genes from Shigella dysenteriae 1.

The requirement for both plasmid and chromosomal genes in the biosynthesis of Shigella dysenteriae 1 lipopolysaccharide O antigen was demonstrated in Escherichia coli-Shigella hybrids. A 6-megadalton S. dysenteriae 1 plasmid, designated pWR23, was phenotypically tagged with the Tn3 ampicillin-resistance transposon. The tagged plasmid, designated pWR24, was transferred by transformation or conjugal mobilization to a rough E. coli K-12 recipient. Although the resultant hybrids were agglutinated in S. dysenteriae 1 antiserum, they did not remove all of the anti-Shiga agglutinins in absorption experiments. Modified lipid A core structure was detected in these hybrids, but Shiga O antigen was not expressed. When the his+ locus of the S. dysenteriae 1 chromosome was transferred by transduction to E. coli K-12 containing pWR24, complete Shiga O antigen was expressed. Lipopolysaccharide extracted from these hybrids was indistinguishable chemically, electrophoretically, and serologically from native S. dysenteriae 1 lipopolysaccharide.

Heterogeneity of molecular size and antigenic expression within lipooligosaccharides of individual strains of Neisseria gonorrhoeae and Neisseria meningitidis.

We determined the Mr of neisserial lipooligosaccharides (LOS) by using discontinuous sodium dodecyl sulfate-polyacrylamide gel electrophoresis, minimal loading concentrations, and Salmonella isogenic rough mutant LOS as Mr standards. Salmonella LOS were resolved into three components. The migration distance of each component was linearly related to its theoretical Mr (r = 0.99). Neisserial LOS also contained multiple components whose calculated Mr ranged from 3,200 to 7,100. The relative abundance of components and their MrS varied greatly among strains. Meningococcal LOS were composed almost exclusively of two closely migrating components; gonococcal LOS were more heterogeneous. LOS from a gonococcus selected for resistance to a Pseudomonas pyocin contained only a single component that was different from and of intermediate Mr among the three components of the parent strain. A monoclonal antibody directed against the meningococcal L8 LOS epitope was used to determine whether heterogeneity of antigen expression reflected Mr heterogeneity. Single components of the L8 meningococcal LOS and of the LOS of 3 of 19 gonococcal strains bound the monoclonal antibody. Gonococcal LOS components that expressed the L8 epitope were of a similar Mr (4,800). Smaller components of these same LOS did not express the epitope.

Unusual lipopolysaccharide antigens of a Salmonella typhi oral vaccine strain expressing the Shigella sonnei form I antigen.

Salmonella typhi 5076-1C, a potential live, oral vaccine for protection against typhoid fever and Shigella sonnei shigellosis, expresses the S. sonnei form I antigen and normal S. typhi somatic antigens. Polysaccharide antigens of this galactose epimeraseless genetic derivative strain were hot phenol-water extracted from cells grown with (+gal) and without (-gal) galactose. Ultracentrifugation of the aqueous layer from (+gal) cells resulted in a lipopolysaccharide (LPS) pellet having core-linked S. typhi O-antigen but no core-linked form I antigen; the LPS from (-gal) cells lacked O-antigen. The form I antigen, obtained from the supernatant, was purified by alcohol precipitation and ion exchange chromatography. Unlinked form I and S. typhi O-polysaccharide antigens, both present in the (+gal) supernatant, were further separated by gel filtration. Chemical analyses revealed the 5076-1C form I antigen to be a polymer (Mr = 14,000-20,000) having O-disaccharide repeating units comprised of 2-acetamido-4-amino-2, 4,6-trideoxy-D-galactose and 2-acetamido-2-deoxy-L-altruronic acid. Unlike parental S. sonnei form I LPS, the 5076-1C form I antigen lacked core lipid A, had low phosphorus content, and migrated in polyacrylamide gels with lower relative mobility. In contrast to current concepts of LPS assembly, these data indicate that 5076-1C form I antigen is transported to the cell surface without covalent linkage to core lipid A, and exists as a polymerized, antigenic surface entity.

Interactions of lipid a and liposome-associated lipid A with Limulus polyphemus amoebocytes.

Lipid A or lipid A fractions and liposomes containing lipid A were tested for the ability to gel Limulus amoebocyte lysates and for effects on intact Limulus amoebocytes. Liposomes having a relatively low concentration of lipid A did not produce coagulation of lysate and were designated as Limulus-negative, but liposomes having a high concentration of lipid A were Limulus-positive. Limulus-negative liposomes had no effect on intact amoebocytes. Limulus-positive liposomes caused a striking transformation in the appearance of amoebocytes in that the cells sent out long filamentous extensions that formed a tangled network of processes between cells. The filamentous projections were similar to those that have been previously observed in the presence of gram-negative bacteria. We conclude that amoebocytes have the ability to recognize Limulus-positive liposomes, but the lack of activation of Limulus lysate or the absence of amoebocyte recognition does not prove the absence of liposomal lipid A. We also found that individual lipid A fractions were heterogeneous in their ability to gel lysate. Of eight fractions tested, one (fraction 1) had no detectable activity above the background, and the seven others had activity that ranged from 10-fold to 10,000-fold above the background. The heterogeneity of lipid A fractions detected in assays with amoebocyte lysate was consistent with the finding of heterogeneity in other functional assays of lipid A fractions.

A differential labelling model for determining the number of catalytically essential carboxyl groups in fumarase.

We have developed a mathematical model of the nonideal case in which enzymatic activity changes may also result from modification of non-essential groups. As an illustration of this method, the number of essential carboxyl groups in pig heart fumarase (L-malate hydro-lyase, ED 4.2.1.2) was determined by the differential labeling technique. Enzymatic activity was related to the number of modified carboxyl groups according to the model and the results were compatible with the existence of two essential carboxyl groups in fumarase.

Preparation and characterization of detoxified lipopolysaccharide-protein conjugates.

Alkaline treatment of Pseudomonas aeruginosa type 5 lipopolysaccharide (LPS) resulted in reduced toxicity as measured by both the Limulus amoebocyte assay and the rabbit pyrogenicity test. Chemical analysis of the deacylated LPS (D-LPS) revealed that ester-linked fatty acids were removed while the amide-linked fatty acids remained intact. The neutral and amino sugar compositions for native LPS and D-LPS were identical within experimental error. Antigenic determinants for complement-dependent human opsonic antibody were retained under these deacylation conditions. To enhance its immunogenicity, D-LPS was covalently coupled to Pseudomonas pili and the 1,4-diaminobutyl derivatives of Pseudomonas exotoxin A and tetanus toxoid. Quantitative amino sugar analyses revealed that 2.6 and 3.2 mol of D-LPS were covalently bound to aminobutyl Pseudomonas exotoxin A and aminobutyl tetanus toxoid, respectively. Gel electrophoresis data indicated at least 1 mol of D-LPS covalently bound per pilus subunit protein. Initial immunologic data indicated that antibody against D-LPS could be induced when the D-LPS is covalently attached to protein carriers.

Endotoxin-like activities of mycoplasmal lipopolysaccharides (lipoglycans).

Lipoglycans (previously designated lipopolysaccharides) from several species of Acholeplasma and from Thermoplasma acidophilum were examined for endotoxin-like activities as measured by the standard rabbit fever test and the Limulus amoebocyte lysate assay. The lipoglycans from Acholeplasma granularum, Achloplasma laidlawii, Acholeplasma modicum, and Acholeplasma oculi caused a febrile response at concentrations of 1 ng/ml per kg or greater, whereas with control Escherichia coli EC-2 lipopolysaccharides, 6.25 ng/ml per kg was required. Similar results were obtained in the Limulus amoebocyte lysate test. The minimum concentrations in nanograms per milliliter required to stimulate formation of a solid clot were: Acholeplasma axanthum, 0.22; A. granularum, 0.85; A. modicum, 0.51; A. laidlawii, 1.05; A. oculi, 0.74. Standard E. coli 1B lipopolysaccharide required a concentration of 0.125 ng/ml. Thermoplasma lipoglycan was least active, requiring 4.25 ng/ml. Clotting of the Limulus lysate proceeds by the activation by lipopolysaccharide plus Ca(2+) of a proenzyme which cleaves an arginine-lysine peptide bond of the coagulogen. The clotting and amidase activities are inactivated by deoxycholate and can be reactivated by addition of lipopolysaccharide and Ca(2+). As with E. coli 1B lipopolysaccharide, acholeplasmal lipoglycans were shown to restore both clotting and amidase activities of the deoxycholate-inactivated Limulus clotting enzyme. The degree of restoration of amidase activity by mycoplasmal lipoglycans relative to E. coli lipopolysaccharide (1.00) were: A. axanthum, 1.71; A. modicum, 1.22; A. granularum, 0.61; and Thermoplasma, 0.37. The coagulating enzyme, restored with either E. coli lipopolysaccharide or mycoplasmal lipoglycans, was able to react with the synthetic peptide benzoyl-Ile-Glu-(gamma-OCH(3))-Gly-p-nitroaniline (an analog of the coagulogen) or with the purified coagulogen itself to form the clot. The mycoplasmal lipoglycans alone were incapable of promoting these reactions when incubated with the synthetic peptide or with the purified coagulogen, thereby ruling out the contamination of these lipoglycans with proteases capable of cleaving the same Arg-Lys peptide bond of the coagulogen. These results show that acholeplasmal lipoglycans possess endotoxin-like activities. Their passive or active role in disease remains to be established.