1C) [21] and [22]. The originally assembled immature virions are non-infectious, and prM cleavage allows E to adopt the conformational state required for its entry functions, i.e. receptor-binding and acidic-pH-induced membrane fusion after uptake by receptor-mediated endocytosis ( Fig. 2) [23] and [24]. Recently, it was shown that fully immature virions can be rendered infectious in the course of antibody-mediated uptake into Fc-receptor-positive cells through the post-entry cleavage

of prM in the endosome [25]. The possible contribution of completely immature viruses to the infection process remains to be determined. Atomic structures of soluble forms of E (lacking the double transmembrane anchor and about 50 additional amino acids Ribociclib mw in the so-called ‘stem’; Fig. 1A) have been determined for TBEV, DENV, and WNV [26], [27], [28], [29], [30] and [31]. These structures are very similar, being composed of 3 distinct domains (DI, www.selleckchem.com/products/PD-0332991.html DII

and DIII) in an elongated molecule that forms an antiparallel dimer at the surface of mature virions (Fig. 1B). The tip of DII carries a highly conserved loop (Fig. 1B) that functions as an internal fusion peptide and initiates endosomal membrane fusion (Fig. 2) after acid pH-induced dissociation of the E dimer [32], [33] and [34]. Because of its dual role in cell entry – attachment to cellular receptors Rutecarpine and membrane fusion – the E protein is the major target of virus neutralizing antibodies that inhibit these functions and thus prevent infection. There is overwhelming evidence that neutralizing antibodies mediate long-term protection from disease and their measurement therefore provides the best correlate of flavivirus immunity [35]. Epitopes involved in neutralization have been mapped to each of the three domains and to sites all over the exposed surface of E, but evidence from work with mouse monoclonal

antibodies suggests that those against DIII have a higher neutralizing potency than those to other sites of the molecule [35] and [36]. Structural and mutational studies revealed epitopes that are (i) confined to single domains [37] and [38], (ii) located at the junction of domains [38], [39], [40], [41] and [42], (iii) subunit overlapping (i.e. comprise amino acid residues from both monomers in the dimer) [40], [43], [44] and [45] or (iv) dependent on the specific herringbone-like arrangement of E in the virion [46]. Most interestingly, strongly neutralizing antibodies have been identified that gain access to their partially cryptic epitopes through temperature-dependent conformational movements of E at the virion surface [47], indicating that the particle structure may not be as rigid as previously assumed.