This paper describes a new program SnpSift for filtering differential DNA sequence variants between two or more experimental genomes after genotoxic chemical exposure. Here, we illustrate how SnpSift can be used to identify candidate phenotype-relevant variants including single nucleotide polymorphisms, multiple nucleotide polymorphisms, insertions, and deletions (InDels) in mutant strains isolated from genome-wide chemical mutagenesis of Drosophila melanogaster. First, the genomes of two independently isolated mutant fly strains that are allelic for a novel recessive male-sterile locus generated by genotoxic chemical exposure were sequenced using the Illumina next-generation DNA sequencer to obtain 20- to 29-fold coverage of the euchromatic sequences. The sequencing reads were processed and variants were called using standard bioinformatic tools. Next, SnpEff was used to annotate all sequence variants and their potential mutational effects on associated genes. Then, SnpSift was used to filter and select differential variants that potentially disrupt a common gene in the two allelic mutant strains. The potential causative DNA lesions were partially validated by capillary sequencing of polymerase chain reaction-amplified DNA in the genetic interval as defined by meiotic mapping and deletions that remove defined regions of the chromosome. Of the five candidate genes located in the genetic interval, the Pka-like gene CG12069 was found to carry a separate pre-mature stop codon mutation in each of the two allelic mutants whereas the other four candidate genes within the interval have wild-type sequences. The Pka-like gene is therefore a strong candidate gene for the male-sterile locus. These results demonstrate that combining SnpEff and SnpSift can expedite the identification of candidate phenotype-causative mutations in chemically mutagenized Drosophila strains. This technique can also be used to characterize the variety of mutations generated by genotoxic chemicals.
Regulated proteolysis by the two-component NS2B/ NS3 protease of dengue virus is essential for virus replication and the maturation of infectious virions. The functional similarity between the NS2B/NS3 proteases from the four genetically and antigenically distinct serotypes was addressed by characterizing the differences in their substrate specificity using tetrapeptide and octapeptide libraries in a positional scanning format, each containing 130,321 substrates. The proteases from different serotypes were shown to be functionally homologous based on the similarity of their substrate cleavage preferences. A strong preference for basic amino acid residues (Arg/Lys) at the P1 positions was observed, whereas the preferences for the P2-4 sites were in the order of Arg > Thr > Gln/Asn/Lys for P2, Lys > Arg > Asn for P3, and Nle > Leu > Lys > Xaa for P4. The prime site substrate specificity was for small and polar amino acids in P1 and P3. In contrast, the P2 and P4 substrate positions showed minimal activity. The influence of the P2 and P3 amino acids on ground state binding and the P4 position for transition state stabilization was identified through single substrate kinetics with optimal and suboptimal substrate sequences. The specificities observed for dengue NS2B/NS3 have features in common with the physiological cleavage sites in the dengue polyprotein; however, all sites reveal previously unrecognized suboptimal sequences.Dengue virus is the etiologic agent of dengue fever, dengue hemorrhagic fever, and dengue shock syndrome and is the most prevalent arthropod-transmitted infectious disease in humans. Dengue consists of four closely related but antigenically distinct viral serotypes (DEN1-4), 1 of the genus Flavivirus (1, 2).Following primary infection, lifelong immunity develops that prevents repeated assault by the same serotype but does not provide protection from a virus of a different serotype (3). Dengue diseases are endemic in the tropics and subtropics, and the viruses are maintained in a cycle that involves humans and the Aedes aegypti mosquito. Infection with dengue viruses produces a spectrum of clinical illness ranging from a nonspecific viral syndrome to severe and fatal hemorrhagic disease (1, 2). Currently there is no antiviral drug or vaccine available against dengue viruses, and the pathogenesis of the disease is poorly understood.As with other members of the Flaviviridae family, the genomes of the dengue viruses consist of a positive singlestranded RNA of ϳ10,700 bases in length (4). Co-translational processing and post-translational processing of the polyprotein give rise to three structural proteins and at least seven nonstructural proteins (4). The correct processing of these proteins is essential for virus replication and requires host proteases such as signalase and furin (5) and a two-component viral protease, NS2B/NS3 (4). Previous studies have shown that the N-terminal part of NS3 contains trypsin-like protease domain (6) and that the activity of NS3 was dependent on at least 40 amino ...
Candidate antibacterials are usually identified on the basis of their in vitro activity. However, the apparent inhibitory activity of new leads can be misleading because most culture media do not reproduce an environment relevant to infection in vivo. In this study, while screening for novel anti-tuberculars, we uncovered how carbon metabolism can affect antimicrobial activity. Novel pyrimidine–imidazoles (PIs) were identified in a whole-cell screen against Mycobacterium tuberculosis. Lead optimization generated in vitro potent derivatives with desirable pharmacokinetic properties, yet without in vivo efficacy. Mechanism of action studies linked the PI activity to glycerol metabolism, which is not relevant for M. tuberculosis during infection. PIs induced self-poisoning of M. tuberculosis by promoting the accumulation of glycerol phosphate and rapid ATP depletion. This study underlines the importance of understanding central bacterial metabolism in vivo and of developing predictive in vitro culture conditions as a prerequisite for the rational discovery of new antibiotics.
A series of inhibitors related to the benzoyl-norleucine-lysine-arginine-arginine (Bz-nKRR) tetrapeptide aldehyde was synthesized. When evaluated against the West Nile virus (WNV) NS3 protease, the measured IC(50) ranges from approximately 1 to 200 microM. Concurrently, a modeling study using the recently published crystal structure of the West Nile NS3/NS2B protease complex (pdb code 2FP7) was conducted. We found that the crystal structure is relevant in explaining the observed SAR for this series of tetrapeptides, with the S1 and S2 pockets being the key peptide recognition sites. In general, a residue capable of both pi-stacking and hydrogen bonding is favored in the S1 pocket, while a positively charged residue is preferred in the S2 pocket. This study not only confirms the importance of the NS2B domain in substrate-based inhibitor binding of WNV, it also suggests that the crystal structure would provide useful guidance in the drug discovery process of related Flavivirus proteases, given the high degree of homology.
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