Genes Contributing to Staphylococcus aureus Fitness in Abscess- and Infection-Related Ecologies

ABSTRACT Staphylococcus aureus is a leading cause of both community- and hospital-acquired infections that are increasingly antibiotic resistant. The emergence of S. aureus resistance to even last-line antibiotics heightens the need for the development of new drugs with novel targets. We generated a highly saturated transposon insertion mutant library in the genome of S. aureus and used Tn-seq analysis to probe the entire genome, with unprecedented resolution and sensitivity, for genes of importance in infection. We further identified genes contributing to fitness in various infected compartments (blood and ocular fluids) and compared them to genes required for growth in rich medium. This resulted in the identification of 426 genes that were important for S. aureus fitness during growth in infection models, including 71 genes that could be considered essential for survival specifically during infection. These findings highlight novel as well as previously known genes encoding virulence traits and metabolic pathways important for S. aureus proliferation at sites of infection, which may represent new therapeutic targets

A core microbiome associated with the peritoneal tumors of pseudomyxoma peritonei

Pseudomyxoma peritonei (PMP) is a malignancy characterized by dissemination of mucus-secreting cells throughout the peritoneum. This disease is associated with significant morbidity and mortality and despite effective treatment options for early-stage disease, patients with PMP often relapse. Thus, there is a need for additional treatment options to reduce relapse rate and increase long-term survival. A previous study identified the presence of both typed and non-culturable bacteria associated with PMP tissue and determined that increased bacterial density was associated with more severe disease. These findings highlighted the possible role for bacteria in PMP disease. To more clearly define the bacterial communities associated with PMP disease, we employed a sequenced-based analysis to profile the bacterial populations found in PMP tumor and mucin tissue in 11 patients. Sequencing data were confirmed by in situ hybridization at multiple taxonomic depths and by culturing. A pilot clinical study was initiated to determine whether the addition of antibiotic therapy affected PMP patient outcome. We determined that the types of bacteria present are highly conserved in all PMP patients; the dominant phyla are the Proteobacteria, Actinobacteria, Firmicutes and Bacteroidetes. A core set of taxon-specific sequences were found in all 11 patients; many of these sequences were classified into taxonomic groups that also contain known human pathogens. In situ hybridization directly confirmed the presence of bacteria in PMP at multiple taxonomic depths and supported our sequence-based analysis. Furthermore, culturing of PMP tissue samples allowed us to isolate 11 different bacterial strains from eight independent patients, and in vitro analysis of subset of these isolates suggests that at least some of these strains may interact with the PMP-associated mucin MUC2. Finally, we provide evidence suggesting that targeting these bacteria with antibiotic treatment may increase the survival of PMP patients. Using 16S amplicon-based sequencing, direct in situ hybridization analysis and culturing methods, we have identified numerous bacterial taxa that are consistently present in all PMP patients tested. Combined with data from a pilot clinical study, these data support the hypothesis that adding antimicrobials to the standard PMP treatment could improve PMP patient survival.https://doi.org/10.1186/1750-1172-8-10

Expression of hepatitis delta virus RNA deletions: cis and trans requirements for self-cleavage, ligation, and RNA packaging

The hepatitis delta virus (HDV) genome is a circular, single-stranded, rod-shaped, 1.7-kb RNA that replicates via a rolling-circle mechanism. Viral ribozymes function to cleave replication intermediates which are then ligated to generate the circular product. HDV expresses two forms of a single protein, the small and large delta antigens (delta Ag-S and delta Ag-L), which associate with viral RNA in a ribonucleoprotein (RNP) structure. While delta Ag-S is required for RNA replication, delta Ag-L inhibits this process but promotes the assembly of the RNP into mature virions. In this study, we have expressed full-length and deleted HDV RNA inside cells to determine the minimal RNA sequences required for self-cleavage, ligation, RNP packaging, and virion assembly and to assess the role of either delta antigen in each of these processes. We report the following findings. (i) The cleavage and ligation reactions did not require either delta antigen and were not inhibited in their presence. (ii) delta Ag-L, in the absence of delta Ag-S, formed an RNP with HDV RNA which could be assembled into secreted virus-like particles. (iii) Full-length HDV RNAs were stabilized in the presence of either delta antigen and accumulated to much higher levels than in their absence. (iv) As few as 348 nucleotides of HDV RNA were competent for circle formation, RNP assembly, and incorporation into virus-like particles. (v) An HDV RNA incapable of folding into the rod-like structure was not packaged by delta Ag-L.</jats:p

Relating structure to function in the hepatitis delta virus antigen

Hepatitis delta virus expresses two forms of a single protein, the small (delta Ag-S) and large (delta Ag-L) antigens, which are identical except for an additional 19 residues present at the C terminus of delta Ag-L. While delta Ag-S is required to promote genome replication, delta Ag-L potently inhibits this process and also facilitates packaging of the viral genome by envelope proteins of the helper virus (hepatitis B virus). Regions within the antigens responsible for nuclear localization, RNA binding, and dimerization have been identified, yet it is not clear how these particular activities contribute to the ultimate replication and packaging phenotypes. Here we report the following findings. (i) Although the removal of the nuclear localization signal from either antigen resulted in significant cytoplasmic accumulation, both proteins still had access to the nucleus. As a consequence, no functional defect was observed with either mutant. (ii) The RNA-binding domain, although necessary for delta Ag-S function, could be deleted from delta Ag-L without compromising its ability to either inhibit replication or promote packaging. (iii) In contrast, the coiled-coil dimerization domain was required for both the activation of replication by delta Ag-S and the inhibition of replication by delta Ag-L. This region, with an additional 20 amino acids C-terminal to it, was necessary and sufficient to potently inhibit replication by interacting with the small antigen. (iv) The packaging property of delta Ag-L required a C-terminal Pro/Gly-rich region which is hypothesized to interact with the hepatitis B virus envelope proteins during the assembly process.</jats:p

Intracellular cleavage and ligation of hepatitis delta virus genomic RNA: regulation of ribozyme activity by cis-acting sequences and host factors

During replication, a ribozyme within the genomic RNA of hepatitis delta virus cleaves multimeric precursors to release a unit-length linear intermediate. Intramolecular ligation of this intermediate produces the circular genomic RNA. Although one copy of the ribozyme is reconstituted by such ligation, it does not subsequently cleave and destroy the circular conformation. We have identified cis-acting attenuator sequences that prevent self-cleavage of the circular product by base pairing with and inactivating the ribozyme. Furthermore, we have shown that during the initial processing of the multimeric precursor RNA, host-specific factors activate the ribozyme by preventing its association with the attenuator sequences. Thus, we demonstrate a novel switching mechanism that regulates ribozyme activity inside the cell.</jats:p