Defensins are an effector component of the innate immune system with broad antimicrobial activity. Humans express two types of defensins, α- and β-defensins, which have antiviral activity against both enveloped and non-enveloped viruses. The diversity of defensin-sensitive viral species reflects a multitude of antiviral mechanisms. These include direct defensin targeting of viral envelopes, glycoproteins, and capsids in addition to inhibition of viral fusion and post-entry neutralization. Binding and modulation of host cell surface receptors and disruption of intracellular signaling by defensins can also inhibit viral replication. In addition, defensins can function as chemokines to augment and alter adaptive immune responses, revealing an indirect antiviral mechanism. Nonetheless, many questions regarding the antiviral activities of defensins remain. Although significant mechanistic data is known for α-defensins, molecular details for β-defensin inhibition are mostly lacking. Importantly, the role of defensin antiviral activity in vivo has not been addressed due to the lack of a complete defensin knockout model. Overall, the antiviral activity of defensins is well established as are the variety of mechanisms by which defensins achieve this inhibition; however, additional research is needed to fully understand the role of defensins in viral pathogenesis.
Organoids mirror in vivo tissue organization and are
powerful tools to investigate the development and cell biology of the small
intestine. However, their application for the study of host-pathogen
interactions has been largely unexplored. We have established a model using
microinjection of organoids to mimic enteric infection, allowing for direct
examination of pathogen interactions with primary epithelial cells in the
absence of confounding variables introduced by immune cells or the commensal
microbiota. We investigated the impact of Paneth cell α-defensin
antimicrobial peptides on bacterial growth. We demonstrate that organoids form a
sealed lumen which contains concentrations of α-defensins capable of
restricting growth of multiple strains of Salmonella enterica
serovar Typhimurium for at least 20 h post-infection. Transgenic expression of
human defensin 5 (HD5) in mouse organoids lacking functional murine
α-defensins partially restored bacterial killing. We also found that
organoids from NOD2−/− mice were not
impaired in α-defensin expression or antibacterial activity. This model
is optimized for the study of non-invasive bacteria, but can be extended to
other enteric pathogens and is amenable to further genetic manipulation of both
the host and microbe to dissect this critical interface of host defense.
Background:The molecular basis for human ␣-defensin 5 (HD5) binding to non-enveloped viruses is unknown. Results: Residues critical for virus binding and antiviral activity were identified by mutational analysis. Conclusion: Multimerization, hydrophobicity, and specific arginine residues dictate HD5 antiviral activity. Significance: These studies inform the role of enteric ␣-defensins in immunity against non-enveloped viruses.
Background
The lack of biomarkers that are predictive of safety is a critical gap in the development of microbicides. The present experiments were designed to evaluate the predictive value of in vitro models of microbicide safety.
Methods
Changes in the epithelial barrier were evaluated by measuring transepithelial electrical resistance (TER) after exposure of human epithelial cells to candidate microbicides in a dual-chamber system. The significance of observed changes was addressed by challenging cultures with human immuodeficiency virus (HIV) and measuring the ability of virus to cross the epithelium and infect target T cells cultured in the lower chamber.
Results
Exposure to nonoxynol-9 (N-9) or cellulose sulfate (CS), but not 9-[2-(phosphonomethoxy)propyl]adenine (also referred to as tenofovir) or PRO2000, resulted in a rapid and sustained reduction in TER and a marked increase in HIV infection of T cells cultured in the lower chamber. Moreover, CS triggered nuclear factor κB activation in peripheral blood mononuclear cells and increased HIV replication in chronically infected U1 cells.
Conclusions
Epithelial barrier disruption and enhanced viral replication may have contributed to the increased risk of HIV acquisition observed in phase 3 trials of N-9 and CS. Expansion of in vitro safety testing to include these models would provide a more stringent preclinical assessment of microbicide safety and may prove to be more predictive of clinical outcomes.
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