Luke M. Jones scite author profile

Viruses are microscopic pathogens capable of causing disease and are responsible for a range of human mortalities and morbidities worldwide. They can be rendered harmless or destroyed with a range of antiviral chemical compounds. Cucurbit[ n ]urils (CB[ n ]s) are a family of macrocycle chemical compounds existing as a range of homologues; due to their structure, they can bind to biological materials, acting as supramolecular “hosts” to “guests”, such as amino acids. Due to the increasing need for a nontoxic antiviral compound, we investigated whether cucurbit[ n ]urils could act in an antiviral manner. We have found that certain cucurbit[ n ]uril homologues do indeed have an antiviral effect against a range of viruses, including herpes simplex virus 2 (HSV-2), respiratory syncytial virus (RSV) and SARS-CoV-2. In particular, we demonstrate that CB[7] is the active homologue of CB[ n ], having an antiviral effect against enveloped and nonenveloped species. High levels of efficacy were observed with 5 min contact times across different viruses. We also demonstrate that CB[7] acts with an extracellular virucidal mode of action via host–guest supramolecular interactions between viral surface proteins and the CB[ n ] cavity, rather than via cell internalization or a virustatic mechanism. This finding demonstrates that CB[7] acts as a supramolecular virucidal antiviral (a mechanism distinct from other current extracellular antivirals), demonstrating the potential of supramolecular interactions for future antiviral disinfectants.

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African Horse Sickness virus: pathogenicity in an IFNAR(-/-) mouse model of infection

Jones

Hawes

Salguero

et al. 2019

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Pathological features of African horse sickness virus infection in IFNAR−/− mice

et al. 2023

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African Horse Sickness (AHS) is a vector-borne viral disease of equids. The disease can be highly lethal with mortality rates of up to 90% in non-immune equine populations. The clinical presentation in the equine host varies, but the pathogenesis underlying this variation remains incompletely understood. Various small animal models of AHS have been developed over the years to overcome the financial, bio-safety and logistical constraints of studying the pathology of this disease in the target species. One of the most successful small animal models is based on the use of interferon-alpha gene knock-out (IFNAR−/−) mice. In order to increase our understanding of African Horse Sickness virus (AHSV) pathogenesis, we characterised the pathology lesions of AHSV infection in IFNAR−/− mice using a strain of AHSV serotype 4 (AHSV-4). We found AHSV-4 infection was correlated with lesions in various organs; necrosis in the spleen and lymphoid tissues, inflammatory infiltration in the liver and brain, and pneumonia. Significant viral antigen staining was only detected in the spleen and brain, however. Together these results confirm the value of the IFNAR−/− mouse model for the study of the immuno-biology of AHSV infections in this particular in vivo system, and its usefulness for evaluating protective efficacy of candidate vaccines in preclinical studies.

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Broad-spectrum extracellular antiviral properties of Cucurbit[n]urils

Jones

Super

Batt

et al. 2022

Preprint

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Viruses are microscopic pathogens capable of causing disease and are responsible for a range of human mortality and morbidity worldwide. They can be rendered harmless or destroyed with a range of antiviral chemical compounds. Cucurbit[n]urils (CB[n]s) are a macrocycle chemical compound existing as a range of homologues; due to their structure they can bind to biological materials, acting as supramolecular host to guests, such as amino acids. Due to the increasing need for a non-toxic antiviral compound, we investigated whether cucurbit[n]urils could act in an antiviral manner. We have found that certain cucurbit[n]uril homologues do indeed have an antiviral effect against a range of viruses, including RSV and SARS-CoV-2. In particular, we demonstrate that CB[7] is the active homologue of CB[n] mixtures, having an antiviral effect against enveloped and non-enveloped species. High levels of efficacy were observed with five-minute contact times across different viruses. We also demonstrate that CB[7] acts with an extracellular virucidal mode of action via host-guest supramolecular interactions between viral surface proteins and the CB[n] cavity, rather than via cell internalisation or a virustatic mechanism. This finding demonstrates that CB[7] acts as a supramolecular virucidal antiviral (a mechanism distinct from other current extracellular antivirals) demonstrating the potential of supramolecular interactions for future antiviral disinfectants.

show abstract

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Luke M. Jones

Broad-Spectrum Extracellular Antiviral Properties of Cucurbit[n]urils

African Horse Sickness virus: pathogenicity in an IFNAR(-/-) mouse model of infection

Pathological features of African horse sickness virus infection in IFNAR−/− mice

Broad-spectrum extracellular antiviral properties of Cucurbit[n]urils

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