A small-molecule SARS-CoV-2 inhibitor targeting the membrane protein (preprint)

The membrane (M) protein of betacoronaviruses is well-conserved and plays a key role in viral assembly. Here, we describe the discovery of JNJ-9676, a novel small molecule targeting the coronaviral (CoV) M protein. JNJ-9676 demonstrates in vitro nanomolar antiviral activity against SARS-CoV2, SARS-CoV, and sarbecovirus strains from bat and pangolin zoonotic origin. Using cryogenic electron microscopy, we determined a novel binding pocket of JNJ-9676 in the M protein's transmembrane domain. Compound binding stabilized the M protein in an altered conformational state between its long- and short-forms, preventing the release of infectious virus. In a pre-exposure Syrian golden hamster model, JNJ-9676 (25 mg/kg BID) showed excellent efficacy illustrated by a significant reduction in viral load and infectious virus in the lung by 3.5 log10 and 4 log10, respectively. Histopathology scores at this dose were reduced to baseline. In a post-exposure hamster model, JNJ-9676 was efficacious at 75mg/kg BID even when added at 48 h post-infection, when peak viral loads were observed. The M protein is an attractive novel antiviral target to block coronavirus replication with JNJ-9676 representing an interesting chemical series towards identifying clinical candidates addressing the current and future CoV pandemics.

Highly potent antisense oligonucleotides (ASOs) targeting the SARS-CoV-2 RNA genome (preprint)

Currently the world is dealing with the third outbreak of the human-infecting coronavirus with potential lethal outcome, cause by a member of the Nidovirus family, the SARS-CoV-2. The severe acute respiratory syndrome coronavirus (SARS-CoV-2) has caused the last worldwide pandemic. Successful development of vaccines highly contributed to reduce the severeness of the COVID-19 disease. To establish a control over the current and newly emerging coronaviruses of epidemic concern requires development of substances able to cure severely infected individuals and to prevent virus transmission. Here we present a therapeutic strategy targeting the SARS-CoV-2 RNA using antisense oligonucleotides (ASOs) and identify locked nucleic acid gapmers (LNA gapmers) potent to reduce by up to 96% the intracellular viral load in vitro. Our results strongly suggest promise of our preselected ASOs for further development as therapeutic or prophylactic anti-viral agents.

Honokiol inhibits SARS-CoV-2 replication in cell culture (preprint)

SUMMARY SARS-CoV-2 emerged in 2019 and since its global spread has caused the death of over 6 million people. There are currently few antiviral options for treatment of COVID-19. Repurposing of known drugs can be a fast route to obtain molecules that inhibit viral infection and/or modulate pathogenic host responses. Honokiol is a small molecule from Magnolia trees, for which several biological effects have been reported,, including anticancer and anti-inflammatory activity. Honokiol has also been shown to inhibit several viruses in cell culture. In this study, we show that honokiol protected Vero E6 cells from SARS-CoV-2-mediated cytopathic effect with an EC50 of 7.8 µM. In viral load reduction assays we observed that honokiol decreased viral RNA copies as well as viral infectious progeny titers. The compound also inhibited SARS-CoV-2 replication in the more relevant A549 cells, expressing ACE2 and TMPRSS2. A time-of-addition assay showed that honokiol inhibited virus replication even when added post infection, suggesting it acts at a post-entry step of the replication cycle. Honokiol was also effective against more recent variants of SARS-CoV-2, including omicron and it inhibited other human coronaviruses as well. Our study suggests that honokiol is an interesting molecule to evaluate in animal studies and clinical trials to investigate its effect on virus replication and pathogenic (inflammatory) host responses.

Efficacy assessment of newly-designed and locally-produced filtering facemasks during the SARS-CoV-2 pandemic. (preprint)

The SARS-CoV-2 pandemic resulted in shortages of production and test capacity of FFP2-respirators. Such facemasks are required to be worn by healthcare professionals when performing aerosol-generating procedures on COVID-19 patients. In response to the high demand and short supply, we designed three models of facemasks that are suitable for local production. As these facemasks should meet the requirements of an FFP2-certified facemask, the newly-designed facemasks were tested on the filtration efficiency of the filter material, inward leakage, and breathing resistance with custom-made experimental setups. In these tests, the locally-produced facemasks were benchmarked against a commercial FFP2 facemask. Furthermore, the protective capacity of the facemasks was tested for the first time with coronavirus-loaded aerosols under physiologically relevant conditions. This multidisciplinary effort resulted in the design and production of facemasks that meet the FFP2 requirements, and which can be mass-produced at local production facilities.

A molecular pore spans the double membrane of the coronavirus replication organelle (preprint)

Coronavirus genome replication is associated with virus-induced cytosolic double-membrane vesicles, which may provide a tailored micro-environment for viral RNA synthesis in the infected cell. However, it is unclear how newly synthesized genomes and mRNAs can travel from these sealed replication compartments to the cytosol to ensure their translation and the assembly of progeny virions. Here, using cellular electron cryo-microscopy, we unveiled a molecular pore complex that spans both membranes of the double-membrane vesicle and would allow export of RNA to the cytosol. A hexameric assembly of a large viral transmembrane protein was found to form the core of the crown-shaped complex. This coronavirus-specific structure likely plays a critical role in coronavirus replication and thus constitutes a novel drug target

A unifying structural and functional model of the coronavirus replication organelle: tracking down RNA synthesis (preprint)

Zoonotic coronavirus (CoV) infections, like those responsible for the current SARS-CoV-2 epidemic, cause grave international public health concern. In infected cells, the CoV RNA-synthesizing machinery associates with modified endoplasmic reticulum membranes that are transformed into the viral replication organelle (RO). While double-membrane vesicles (DMVs) appear to be a pan -coronavirus RO element, studies to date describe an assortment of additional coronavirus-induced membrane structures. Despite much speculation, it remains unclear which RO element(s) accommodate viral RNA synthesis. Here we provide detailed 2D and 3D analyses of CoV ROs and show that diverse CoVs essentially induce the same membrane modifications, including the small open double-membrane spherules (DMSs) previously thought to be restricted to gamma- and delta-CoV infections and proposed as sites of replication. Metabolic labelling of newly-synthesized viral RNA followed by quantitative EM autoradiography revealed abundant viral RNA synthesis associated with DMVs in cells infected with the beta-CoVs MERS-CoV and SARS-CoV, and the gamma-CoV infectious bronchitis virus. RNA synthesis could not be linked to DMSs or any other cellular or virus-induced structure. Our results provide a unifying model of the CoV RO and clearly establish DMVs as the central hub for viral RNA synthesis and a potential drug target in coronavirus infection.