Penn researchers discover antimicrobial that thwarts Zika viral entry into human cells

A panel of small molecules that inhibit Zika virus infection, including one that stands out as a potent inhibitor of Zika viral entry into relevant human cell types, was discovered by researchers from the Perelman School of Medicine at the University of Pennsylvania. Publishing in Cell Reports this week, a team led by Sara Cherry, PhD, an associate professor of Microbiology, screened a library of 2,000 bioactive compounds for their ability to block Zika virus infection in three distinct cell types using two strains of the virus.

Zika is an emerging mosquito-borne virus for which there are no vaccines or specific therapeutics. The team used cells lining brain capillaries called endothelium, and cells from placenta, which represent Zika's route across the blood-brain barrier and the transmission path from mother to child, respectively. The third type - a human osteosarcoma cell line - is a generic model cell. They tested a strain of Zika virus currently circulating in human populations in the Americas and another from Africa, which is the original strain identified in 1947.

Using a microscopy-based assay, they identified 38 molecules from the High-throughput Screening Core at Penn, which Cherry directs, that inhibited Zika virus infection in at least one cell type. Roughly half of the 2,000 molecules tested include FDA-approved molecules used to prevent viral replication in infected cells. Co-author David Schultz, PhD, the Core's technical director, was instrumental in providing the infrastructure and expertise for this multi-level screen.

"Overall, the most important finding is that we identified nanchangmycin as a potent inhibitor of Zika virus entry across all cell types tested, including endothelial and placental cells, which are relevant to how Zika may enter the fetus," Cherry said. Nanchangmycin - an antimicrobial indentified in China as part of a natural medicinal products survey -- was also active against other medically relevant viruses, including West Nile, dengue, and chikungunya that use a similar route of entry as Zika.

These viruses enter cells using "clatherin endocytosis." The virus binds with the host cell's outer membrane via a pocket lined with a protein called clatherin. This protein-lined sac containing the sequestered virus pinches off to move deeper into the cytoplasm of the cell where the virus enters to replicate.

Nanchangmycin is a "stepping stone to a new class of anti-virals," Cherry said, because it thwarts this essential mode of entry by viruses like Zika. Future studies will identify the target of this drug and current studies are testing the efficacy of nanchangmycin in animal models of Zika virus infection

Comments

  1. Rose Webster Rose Webster Canada says:

    have the sense that Zika is behaving like a bacteriophage. I believe it is acting in tandem with Wolbachia targeting the gonads.

    Zika is supported 99 percent within the clade shared along with West Nile and St. Louis encephalitis viruses (even though the CDC lumps Zika in with hemorrhagic diseases like dengue and yellow fever).

    Culex mosquitoes in Brazil and China are spreading Zika (which means birds are likely reservoir hosts). These are locations where Wolbachia-infected Aedes mosquito releases have been carried out.

    The presence of a virus facilitates the invasion of Wolbachia (Straub and Telschow, 2015).

    What is likely happening: Wolbachia enters the food chain (unnaturally) from the copepod Mesocyclops longisetus (which prefers to eat Aedes larvae) to small planktivorous fish and sand eels; to terns, gulls, and larger planktivorous fish (such as herring); and so on.

    When these fish or birds die, the Wolbachia can live on in them for (at least) a week. West Nile virus (very similar to Zika) can live 5 days in a dead host. This, I feel, is ample time for Culex mosquitoes to acquire Wolbachia and/or Zika.

    Given their vertical transmission through the female germline and their reproductive manipulations, Wolbachia are expected to reside primarily in the host reproductive tissues (Zug and Hammerstein, 2015).

    My point: If the Zika virus is hitching a ride with Wolbachia, then it will follow it to the human reproductive system.

    I've heard the argument that mammals are "too warm" for Wolbachia to survive but the testes are outside the inner core (to remain cooler). Not only that, Wolbachia is the bacteria emitted by roundworms responsible for river blindness and filariasis. So, once introduced into the blood stream, obviously Wolbachia can thrive.

    Furthermore, UC San Francisco researchers have identified fetal brain tissue cells that are targeted by the Zika virus and determined that azithromycin, a common antibiotic regarded as safe for use during pregnancy, can prevent the virus from infecting these cells.

    As you know, antibiotics work on bacteria, not viruses (re: Wolbachia).

    My latest post:
    More Proof: Wolbachia-Infected Mosquito Releases Might Be Causing the Most Devastating Zika Infections

The opinions expressed here are the views of the writer and do not necessarily reflect the views and opinions of News Medical.
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