Assembly and maturation of the bacteriophage lambda procapsid: gpC is the viral protease.

Viral capsids are robust structures designed to protect the genome from environmental insults and deliver it to the host cell. The developmental pathway for complex double-stranded DNA viruses is generally conserved in the prokaryotic and eukaryotic groups and includes a genome packaging step where viral DNA is inserted into a pre-formed procapsid shell. The procapsids self-assemble from monomeric precursors to afford a mature icosahedron that contains a single "portal" structure at a unique vertex; the portal serves as the hole through which DNA enters the procapsid during particle assembly and exits during infection. Bacteriophage lambda has served as an ideal model system to study the development of the large double-stranded DNA viruses. Within this context, the lambda procapsid assembly pathway has been reported to be uniquely complex involving protein cross-linking and proteolytic maturation events. In this work, we identify and characterize the protease responsible for lambda procapsid maturation and present a structural model for a procapsid-bound protease dimer. The procapsid protease possesses autoproteolytic activity, it is required for degradation of the internal "scaffold" protein required for procapsid self-assembly, and it is responsible for proteolysis of the portal complex. Our data demonstrate that these proteolytic maturation events are not required for procapsid assembly or for DNA packaging into the structure, but that proteolysis is essential to late steps in particle assembly and/or in subsequent infection of a host cell. The data suggest that the lambda-like proteases and the herpesvirus-like proteases define two distinct viral protease folds that exhibit little sequence or structural homology but that provide identical functions in virus development. The data further indicate that procapsid assembly and maturation are strongly conserved in the prokaryotic and eukaryotic virus groups.

Developmental validation of the PowerPlex 16 HS System: an improved 16-locus fluorescent STR multiplex.

STR multiplexes remain the cornerstone of genotyping forensic samples. The PowerPlex 16 HS System contains the core CODIS loci: D3S1358, D5S818, D7S820, D8S1179, D13S317, D16S539, D18S51, D21S11, CSF1PO, FGA, TH01, TPOX, and vWA. Additional loci amplified in the multiplex reaction are the sex-determinant locus, amelogenin, and two pentanucleotide STR loci, Penta D and Penta E. The PowerPlex 16 HS System is an updated version of the PowerPlex 16 System; while the primers and dyes remain unchanged, it introduces an enhanced buffer system that includes hot-start Taq DNA polymerase and ensures robust performance. Due to the modification of the reaction mix, a multi-laboratory developmental validation study was completed to document performance capabilities and limitations for the revised assay. Data within this validation was generated by eight laboratories and served as the basis for the following conclusions: genotyping of single-source samples was consistent across a large range of template DNA concentrations with most laboratories obtaining complete profiles at 62.5pg. Mixture analyses showed that over 90% of minor alleles were detected at 1:9 ratios. Optimum amplification cycle number was ultimately dependent on the sensitivity of the detection instrument and could be adjusted to accommodate a range of DNA template concentrations. Reaction conditions including volume and annealing temperature as well as the concentrations of primers, Taq DNA polymerase, and magnesium were shown to be optimal and able to withstand moderate variations without affecting multiplexed STR amplification. Finally, data from non-probative samples and concordance studies showed consistent results when comparing the PowerPlex 16 HS System with the PowerPlex 16 System as well as other commercially available systems.