key: cord-0764520-fvvufw29
authors: Killick, Richard; Ballard, Clive; Doherty, Patrick; Williams, Gareth
title: Transcription-based drug repurposing for COVID-19
date: 2020-09-25
journal: Virus Res
DOI: 10.1016/j.virusres.2020.198176
sha: 860932a3469a10e71a1502119ac3817e57a5eabf
doc_id: 764520
cord_uid: fvvufw29

We have utilised the transcriptional response of lung epithelial cells following infection by the original Severe Acute Respiratory Syndrome coronavirus (SARS) to identify repositionable drugs for COVID-19. Drugs best able to recapitulate the infection profile are highly enriched for antiviral activity. Nine of these have been tested against SARS-2 and found to potently antagonise SARS-2 infection/replication, with a number now being considered for clinical trials. It is hoped that this approach may serve to broaden the spectrum of approved drugs that should be further assessed as potential anti-COVID-19 agents and may help elucidate how this seemingly disparate collection of drugs are able to inhibit SARS-2 infection/replication.

The COVID-19 pandemic has spawned a global drug development effort. With a vaccine still many months away and novel drugs requiring years to reach the clinic, drug repurposing has J o u r n a l P r e -p r o o f become an attractive alternative. To date the most successful intervention in the pandemic has been the redeployment of dexamethasone for patients in intensive care [1] . Still further effort is needed to identify other approved drugs that can be repositioned against SARS-2.

One approach is based on the observation that the gene expression changes seen in disease states can serve as effective disease descriptors or quantitative phenotypes [2, 3] and drugs can then be repurposed based on an ability to drive expression in the opposite direction [4] [5] [6] [7] [8] [9] .

However, in the case of SARS, transcriptional data are largely limited to the cellular response to infection established in in vitro assays, which is characterised by the up regulation of a cellular viral defence mechanism. The hypothesis behind the present work is that drugs driving these defensive gene expression changes may bolster the cellular response to infection and thus present candidate therapeutics to fight the SARS-2 coronavirus.

In total, 17 infection SARS-associated transcriptional profiles were generated from NCBI GEO deposited expression series, see Sup. Table 1 for details. CMAP [10] profiles were defined as previously described [11] . LINCS profiles were generated based on the deposited dataset series GSE92742 and GSE70138 [12] . LINCS portal of SPIED (www.spied.org.uk) hosts profiles in the form of categorical calls on the up/down status of genes generated based on combining expression data for drug/cell replicates. In the present work the LINCS profiles for different cell types are combined for each drug based on a given gene being assigned an up or down regulated status based on a majority vote across the cell types. See Supplementary file for further Methods details.

A high degree of correlation between the profiles was found, Table S1 Table   S6 .

Ouabain, the most potent of the SARS-2 antagonist, and Digoxin are plant derived toxins used at low concentrations to treat hypertension and cardiac arrhythmia and have been shown to inhibit SARS-2 and MERS replication in the nanomolar range [13, 15] . Both inhibit the sodium/potassium ATPase, or sodium/potassium pump [16, 17] , and CTS antiviral activity has been linked to the ionic changes they induce in the cell being less favourable for viral replication [18, 19] . Low doses of Ouabain also reduce inflammatory cytokine production in LPS treated rats by blocking the nuclear translocation of NF-kB [20] . At low picomolar concentrations Ouabain promotes an interaction between the pump and the Angiotensin Type 1 Receptor (AT1R) [21] . It has also been demonstrated that AT1R directly interacts with ACE2 [22] , the port of entry for the SARS and SARS-2 [23] coronaviruses. It is plausible then that at very low concentrations Ouabain, and by extension Digoxin, cause the internalisation of the pump in complex with AT1R and ACE2, thereby reducing the cell surface expression levels of ACE2 and inhibiting the ability of SARS-2 to enter cells and replicate. The therapeutic range of Ouabain and Digoxin is limited, as at high doses they are extremely toxic. However, the effects outlined above appear to occur at very low concentration, well below toxic levels.

Interestingly, in the LINCS data set there are two molecules with very close homology to the CTSs; witherferin-A, the active ingredient in Ashwagandha, and cucurbitacin, from the squirting cucumber. As these are not FDA approved drugs they have not been tested in in vitro assays but now warrant urgent testing for an ability to inhibit SARS-2 infecting cells.

Interestingly, in response to the recent data on anti-SARS-2 activity [13, 15] C2 pharma (www.c2pharma.com) is opening access to its stocks of Digoxin for trial purposes. There are 4 other CTS like drugs among our top hits, these too should now be assessed for their ability to inhibit SARS-2 infection as a matter of some urgency.

The closely related ipecac root extracts Emetine (our top CMAP and second LINCS hit) and

Cephaeline (3 rd and 35 th respectively) are prescribed as expectorants and at high doses emetics. Of these Emetine has been shown to potently inhibit SARS-2 [14] and has been singled out as a possible COVID-19 therapeutic [24] . Emetine is currently being developed for COVID-19 by Acer Therapeutics (www.acertx.com).

The broad spectrum antiviral Niclosamide [25, 26] has been repurposed three times over its 60 year history and recently been shown to have sub-micromolar potency against SARS-2 [13] . Niclosamide is now in Phase 2 trials for COVID-19 sponsored by Tufts Medical Center (trial reference NCT04399356).

Of the hits unique to LINCS, Homoharringtonine, a protein translation inhibitor, also inhibits SARS-2 replication at low micromolar concentrations [14] . The four unique CMAP hits Terfenadine, an antihistamine, the antimalarial Mefloquine, the antipsychotic Thioridazine and the antianginal Perhexiline have been shown to inhibit SARS-2 replication at low micromolar concentration [13] .

Our data indicate that a seemingly disparate group of nine drugs each able to inhibit SARS-2 infection/replication, a number of which are being considered for trials, are linked though an ability to drive the expression of the SARS infection profile genes. This transcriptional data J o u r n a l P r e -p r o o f point to a common mechanism of action and is likely to reveal the therapeutic potential of drugs with as yet no reported antiviral activity but with well-known safety profiles.

Our data suggest that the other plant based cardiotonic steroids we have identified, for which there are no data concerning their ability to block SARS-2, should be tested as soon as possible, and if effective added to the list of candidate therapeutics.

In conclusion, these findings validate transcription-based repurposing as a rapid and effective means to identify potential treatments for the current COVID-19 pandemic and potentially for other zoonotic coronavirus pandemics that will doubtless inflict mankind in the future.

Autor contributions to 'Transcription-based drug repurposing for COVID-19'. RK and GW conceived the study and wrote the paper. GW did the bioinformatics analysis. PD and CB contributed to the discussion on pharmacology of candidate drugs.

Legends Figure. Transcription-based repurposing candidates. The SARS signature gene expression across the 17 component profiles is shown in the middle. The four common hits that are SARS-2 antagonists are shown at the left with their respective CMAP and LINCS ranks. The hits unique to the two datasets are shown to the right. The structures illustrate the power of transcription profiling to group chemically diverse compounds into a biological activity class.

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