Individuals suffering from immediate hypersensitivity (type-I allergy) to a particular pollen frequently display intolerance to several foods of plant origin. In this respect, individuals sensitized to birch pollen and/or mugwort pollen frequently display type-I allergic symptoms after ingestion of celery. In this study, we expressed the major allergenic protein of celery, Api g 1, which is responsible for the birch-celery syndrome, in the form of a non-fusion protein. The open reading frame of the cDNA of Api g 1 codes for a protein of 153 amino acids with a molecular mass of 16.2 kDa and 40% identity (60% similarity) to the major allergen of birch pollen, Bet v 1. Furthermore, Api g 1 exhibited similar characteristics to (a) two proteins in parsley induced by fungal infection, (b) the major tree pollen allergens and (c) pathogenesis-related and stress-induced proteins in other plant species. The reactivity of recombinant Api g 1 with IgE antibodies present in sera from celery intolerant patients was comparable to that of the natural celery allergen. Cross-reactivity with Bet v 1 was proven by cross-inhibition experiments, which provides further support for the existence of the birch-celery syndrome and for the suggestion that allergies to some vegetable foods are epiphenomena to allergies caused by inhalation of tree pollen.
Flaviviruses assemble in the endoplasmic reticulum by a mechanism that appears to be driven by lateral interactions between heterodimers of the envelope glycoproteins E and prM. Immature intracellular virus particles are then transported through the secretory pathway and converted to their mature form by cleavage of the prM protein by the cellular protease furin. Earlier studies showed that when the prM and E proteins of tick-borne encephalitis virus are expressed together in mammalian cells, they assemble into membranecontaining, icosahedrally symmetrical recombinant subviral particles (RSPs), which are smaller than whole virions but retain functional properties and undergo cleavage maturation, yielding a mature form in which the E proteins are arranged in a regular T ؍ 1 icosahedral lattice. In this study, we generated immature subviral particles by mutation of the furin recognition site in prM. The mutation resulted in the secretion of two distinct size classes of particles that could be separated by sucrose gradient centrifugation. Electron microscopy showed that the smaller particles were approximately the same size as the previously described mature RSPs, whereas the larger particles were approximately the same size as the virus. Particles of the larger size class were also detected with a wild-type construct that allowed prM cleavage, although in this case the smaller size class was far more prevalent. Subtle differences in endoglycosidase sensitivity patterns suggested that, in contrast to the small particles, the E glycoproteins in the large subviral particles and whole virions might be in nonequivalent structural environments during intracellular transport, with a portion of them inaccessible to cellular glycan processing enzymes. These proteins thus appear to have the intrinsic ability to form alternative assembly products that could provide important clues about the role of lateral envelope protein interactions in flavivirus assembly.Flaviviruses are small enveloped viruses that are assembled intracellularly, apparently by budding into the endoplasmic reticulum (ER) (28). The entire virion, consisting of a nucleocapsid, lipid membrane, and two envelope glycoproteins, prM and E, is then transported through the secretory pathway (32) and, after undergoing posttranslational modifications that include the cleavage of the prM protein, is exported from the cell by exocytosis. Newly synthesized prM and E proteins rapidly associate to form heterodimers (6, 30, 46), which then further associate to organize the envelope into a regular icosahedral structure (8,25,48). The idea that lateral envelope protein interactions play a dominant role in assembly is supported by the observations that ordered membrane-containing subviral particles can be obtained by coexpressing prM and E in the absence of other viral components (4, 9, 19-23, 35, 36, 41) and that subviral particles containing only the envelope proteins are also secreted as a by-product of natural infections (39).Shortly before being released from the cel...
The capsid protein, C, of tick-borne encephalitis virus has recently been found to tolerate deletions up to a length of 16 amino acid residues that partially removed the central hydrophobic domain, a sequence element conserved among flaviviruses which may be crucial for virion assembly. In this study, mutants with deletion lengths of 19, 21, 27, or 30 residues, removing more or all of this hydrophobic domain, were found to yield viable virus progeny, but this was without exception accompanied by the emergence of additional mutations within protein C. These point mutations or sequence duplications were located downstream of the engineered deletion and generally increased the hydrophobicity, suggesting that they may compensate for the loss of the central hydrophobic domain. Two of the second-site mutations, together with the corresponding deletion, were introduced into a wild-type genetic backbone, and the analysis of these "double mutants" provided direct evidence that the viability of the deletion mutant indeed depended on the presence of the second-site mutation. Our results corroborate the notion that hydrophobic interactions of protein C are essential for the assembly of infectious flavivirus particles but rule out the possibility that individual residues of the central hydrophobic domain are absolutely required for infectivity. Furthermore, the double mutants were found to be highly attenuated and capable of inducing a protective immune response in mice at even lower inoculation doses than the previously characterized 16-amino-acid-residue deletion mutant, suggesting that the combination of large deletions and second-site mutations may be a superior way to generate safe, attenuated flavivirus vaccine strains.Tick-borne encephalitis (TBE) virus is a representative of the genus Flavivirus (family Flaviviridae), which also includes several other important human pathogens, such as yellow fever virus, Japanese encephalitis virus, West Nile virus, and the dengue viruses (33). Flaviviruses are small, round, enveloped particles that contain only three structural virus proteins, i.e., the membrane-anchored surface proteins M and E and the capsid protein, C (18). The last is a relatively small protein (approximately 11 kDa) with a large content of positively charged amino acid residues that shows significantly less sequence homology among members of the genus than do the other two structural proteins (21). Nevertheless, a number of characteristics of its amino acid sequence, including the clustering of basic residues in certain sections of the sequence, the presence of two distinctive hydrophobic segments located approximately in the center of the sequence and at the carboxy-terminal end, and a predicted high propensity to adopt a predominantly alpha-helical conformation, are generally maintained among different flaviviruses, suggesting an overall conserved structural and functional organization of protein C (14,18,25).In the absence of protein C, the surface proteins M (which is first synthesized as a precursor prote...
Background: The prevalence of allergy to fruits and vegetables increased with pollinosis over the last 10 years. So far, clusters of hypersensitivity have been established and corroborated by the molecular characterization of individual cross-reacting allergens. Several case studies demonstrated the existence of allergic reactions to fruits of the subfamily Prunoideae (apricots, cherries, plums and peaches). Here, we present the characterization of a major allergen in cherry. Methods: Characterization was performed using IgE immunoblotting and immunoblot inhibition, N-terminal sequencing, mass spectroscopy analysis and PCR-based cDNA cloning. Results: A 23-kD protein was identified as IgE-binding component. As all cherry-extract-reactive sera displayed IgE-binding to this band, it was designated a major allergen from Prunus avium (Pru a 2). Sequencing the corresponding cDNA identified Pru a 2 as a thaumatin-like protein belonging to the group 5 of pathogenesis-related proteins. Conclusions: A thaumatin-like protein in cherry has been identified as a major allergen (Pru a 2). Homologous proteins from the thaumatin family share sequence similarities and should therefore be checked for the capability to elicit an IgE-mediated allergic reaction.
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