Melioidosis diagnostic workshop, 2013.

Melioidosis is a severe disease that can be difficult to diagnose because of its diverse clinical manifestations and a lack of adequate diagnostic capabilities for suspected cases. There is broad interest in improving detection and diagnosis of this disease not only in melioidosis-endemic regions but also outside these regions because melioidosis may be underreported and poses a potential bioterrorism challenge for public health authorities. Therefore, a workshop of academic, government, and private sector personnel from around the world was convened to discuss the current state of melioidosis diagnostics, diagnostic needs, and future directions.

Multimerization of hepatitis delta antigen is a critical determinant of RNA binding specificity.

Hepatitis delta virus (HDV) RNA forms an unbranched rod structure that is associated with hepatitis delta antigen (HDAg) in cells replicating HDV. Previous in vitro binding experiments using bacterially expressed HDAg showed that the formation of a minimal ribonucleoprotein complex requires an HDV unbranched rod RNA of at least about 300 nucleotides (nt) and suggested that HDAg binds the RNA as a multimer of fixed size. The present study specifically examines the role of HDAg multimerization in the formation of the HDV ribonucleoprotein complex (RNP). Disruption of HDAg multimerization by site-directed mutagenesis was found to profoundly alter the nature of RNP formation. Mutant HDAg proteins defective for multimerization exhibited neither the 300-nt RNA size requirement for binding nor specificity for the unbranched rod structure. The results unambiguously demonstrate that HDAg binds HDV RNA as a multimer and that the HDAg multimer is formed prior to binding the RNA. RNP formation was found to be temperature dependent, which is consistent with conformational changes occurring on binding. Finally, analysis of RNPs constructed with unbranched rod RNAs successively longer than the minimum length indicated that multimeric binding is not limited to the first HDAg bound and that a minimum RNA length of between 604 and 714 nt is required for binding of a second multimer. The results confirm the previous proposal that HDAg binds as a large multimer and demonstrate that the multimer is a critical determinant of the structure of the HDV RNP.

Hepatitis delta antigen requires a minimum length of the hepatitis delta virus unbranched rod RNA structure for binding.

Hepatitis delta virus (HDV) is a subviral pathogen that increases the severity of liver disease caused by hepatitis B virus. Both the small circular RNA genome and its complement, the antigenome, form a characteristic unbranched rod structure in which approximately 70% of the nucleotides are base paired. These RNAs are associated with the sole virally encoded protein, hepatitis delta antigen (HDAg), in infected cells; however, the nature of the ribonucleoprotein complexes (RNPs) is not well understood. Previous analyses of binding in vitro using native, bacterially expressed HDAg have been hampered by a lack of specificity for HDV RNA. Here, we show that removal of the C-terminal 35 amino acids of HDAg yields a native, bacterially expressed protein, HDAg-160, that specifically binds HDV unbranched rod RNA with high affinity. In an electrophoretic mobility shift assay, this protein produced a discrete, micrococcal nuclease-resistant complex with an approximately 400-nucleotide (nt) segment of HDV unbranched rod RNA. Binding occurred with several segments of HDV RNA, although with various affinities and efficiencies. Analysis of the effects of deleting segments of the unbranched rod indicated that binding did not require one or two specific binding sites within these RNA segments. Rather, a minimum-length HDV RNA unbranched rod approximately 311 nt was essential for RNP formation. The results are consistent with a model in which HDAg binds HDV unbranched rod RNA as multimers of fixed size rather than as individual subunits.

A context-dependent ClpX recognition determinant located at the C terminus of phage Mu repressor.

The bacteriophage Mu immunity repressor is a conformationally sensitive sensor that can be interconverted between forms resistant to and sensitive to degradation by ClpXP protease. Protease-sensitive repressor molecules with an altered C-terminal sequence promote rapid degradation of the wild-type repressor by inducing its C-terminal end to become exposed. Here we determined that the last 5 C-terminal residues (CTD5) of the wild-type repressor contain the motif required for recognition by the ClpX molecular chaperone, a motif that is strongly dependent upon the context in which it is presented. Although attachment of the 11-residue ssrA degradation tag to the C terminus of green fluorescent protein (GFP) promoted its rapid degradation by ClpXP, attachment of 5-27 C-terminal residues of the repressor failed to promote degradation. Disordered peptides derived from 41 and 35 C-terminal residues of CcdA (CcdA41) and thioredoxin (TrxA35), respectively, activated CTD5 when placed as linkers between GFP and repressor C-terminal sequences. However, when the entire thioredoxin sequence was included as a linker to promote an ordered configuration of the TrxA35 peptide, the resulting substrate was not degraded. In addition, a hybrid tag, in which CTD5 replaced the 3-residue recognition motif of the ssrA tag, was inactive when attached directly to GFP but active when attached through the CcdA41 peptide. Thus, CTD5 is sufficient to act as a recognition motif but has requirements for its presentation not shared by the ssrA tag. We suggest that activation of CTD5 may require presentation on a disordered or flexible domain that confers ligand flexibility.