Assembly of Ebola virus matrix protein VP40 is regulated by latch-like properties of N and C terminal tails.

The matrix protein VP40 coordinates numerous functions in the viral life cycle of the Ebola virus. These range from the regulation of viral transcription to morphogenesis, packaging and budding of mature virions. Similar to the matrix proteins of other nonsegmented, negative-strand RNA viruses, VP40 proceeds through intermediate states of assembly (e.g. octamers) but it remains unclear how these intermediates are coordinated with the various stages of the life cycle. In this study, we investigate the molecular basis of synchronization as governed by VP40. Hydrogen/deuterium exchange mass spectrometry was used to follow induced structural and conformational changes in VP40. Together with computational modeling, we demonstrate that both extreme N and C terminal tail regions stabilize the monomeric state through a direct association. The tails appear to function as a latch, released upon a specific molecular trigger such as RNA ligation. We propose that triggered release of the tails permits the coordination of late-stage events in the viral life cycle, at the inner membrane of the host cell. Specifically, N-tail release exposes the L-domain motifs PTAP/PPEY to the transport and budding complexes, whereas triggered C-tail release could improve association with the site of budding.

Structural characterization of distinct alpha3N and alpha5 metal sites in the cyanobacterial zinc sensor SmtB.

SmtB is required for Synechococcus to effect a response to toxic concentrations of Zn(II) and other heavy metals. Direct binding of inducing metal ions to SmtB transcriptionally derepresses the expression of SmtA, a prokaryotic class II metallothionein. Homodimeric SmtB binds one Zn(II) or Co(II) per monomer in a cysteine thiolate-containing site in a tetrahedral coordination geometry [VanZile, M. L., et al. (2000) Biochemistry 39, 11818-11829]. In this report, characterization of a set of cysteine substitution mutants of SmtB reveals that SmtB homodimer binds Zn(II) or Co(II) in one of two mutually exclusive metal binding sites, termed alpha3N and alpha5, with very high equilibrium affinities. Both sites are characterized by similar affinities for Co(II) (K(Co) approximately equal to 2-5 x 10(9) M(-1)), while the Zn(II) affinities are at least 20-fold different (K(Zn)(alpha)(3N) > or = 10(13) M(-1); K(Zn)(alpha)(5) approximately equal to 5 x 10(11) M(-1)). Co(II) bound exclusively at the alpha5 sites is capable of rapid equilibration between the alpha3N and alpha5 sites upon reduction of the mixed disulfides in S-methylated SmtB. These results suggest that the alpha3N or alpha5 metal sites might play distinct roles in this Zn(II)-sensing protein, systematically investigated in the following paper [VanZile, M. L., Chen, X., and Giedroc, D. P. (2002) Biochemistry 41, 9776-9786]. Since both the alpha3N and alpha5 sites are present in many members of the SmtB/ArsR family of metal sensor proteins, the presence of these two metal binding sites may explain some of the functional diversity in metal responses across this family of proteins.

Allosteric negative regulation of smt O/P binding of the zinc sensor, SmtB, by metal ions: a coupled equilibrium analysis.

The Synechococcus PCC 7942 smt operon is responsible for cellular resistance to excess zinc and consists of two divergently transcribed genes, smtB and smtA. SmtB is the Zn(II)-sensing metal-regulated repressor of the system and binds to a 12-2-12 imperfect inverted repeat in the smtA O/P region. Using fluorescence anisotropy to monitor SmtB-smt O/P multiple equilibria, we show that four SmtB homodimers bind to a 40 bp oligonucleotide containing a single 12-2-12 inverted repeat. The binding affinities of the first two dimers are very tight (K(int) = 2.9 x 10(9) M(-1)) with the affinities of the third and fourth dimers lower by approximately 10- and approximately 30-fold, respectively. A single monomer equivalent of Zn(II), Cd(II), or Co(II) promotes disassembly of the oligomeric complex to a mixture of (P(2)).D and (P(2))(2).D SmtB dimer-DNA complexes with the intrinsic affinity of all SmtB homodimers for DNA greatly reduced by approximately 500-2000-fold. Substitution or derivatization of cysteines which comprise the alpha3N metal binding site (Cys14 and Cys61) [VanZile, M. L., et al. (2002) Biochemistry 41, 9765-9775] has no effect on allosteric negative regulation by Zn(II); in contrast, H106Q SmtB, harboring a single zinc-liganding substitution in the alpha5 metal binding site, is refractory to zinc-induced disassembly of SmtB-DNA complexes. The alpha5 metal binding sites are therefore regulatory for Zn(II) sensing in vitro and in vivo, while the high-affinity alpha3N sites play some other role. This finding for SmtB is the opposite of that previously determined for Staphylococcus aureus pI258 CadC, a Pb(II)/Cd(II)/Bi(III) sensor [Busenlehner, L. S., et al. (2002) J. Mol. Biol. 319, 685-701], thus providing insight into the origin of functional metal ion selectivity in this family of metal sensor proteins.