key: cord-0999706-08zf7161
authors: Ryan, Kathryn A.; Bewley, Kevin R.; Fotheringham, Susan A.; Brown, Phillip; Hall, Yper; Marriott, Anthony C.; Tree, Julia A.; Allen, Lauren; Aram, Marilyn J.; Brunt, Emily; Buttigieg, Karen R.; Cavell, Breeze E.; Carter, Daniel P.; Cobb, Rebecca; Coombes, Naomi S.; Godwin, Kerry J.; Gooch, Karen E.; Gouriet, Jade; Halkerston, Rachel; Harris, Debbie J.; Humphries, Holly E.; Hunter, Laura; Ho, Catherine M. K.; Kennard, Chelsea L.; Leung, Stephanie; Ngabo, Didier; Osman, Karen L.; Paterson, Jemma; Penn, Elizabeth J.; Pullan, Steven T.; Rayner, Emma; Slack, Gillian S.; Steeds, Kimberley; Taylor, Irene; Tipton, Tom; Thomas, Stephen; Wand, Nadina I.; Watson, Robert J.; Wiblin, Nathan R.; Charlton, Sue; Hallis, Bassam; Hiscox, Julian A.; Funnell, Simon; Dennis, Mike J.; Whittaker, Catherine J.; Catton, Michael G.; Druce, Julian; Salguero, Francisco J.; Carroll, Miles W.
title: Dose-dependent response to infection with SARS-CoV-2 in the ferret model: evidence of protection to re-challenge
date: 2020-05-29
journal: bioRxiv
DOI: 10.1101/2020.05.29.123810
sha: 50c3cb38513abfe5a5ba5aa3208c2ab44a673579
doc_id: 999706
cord_uid: 08zf7161

In December 2019 an outbreak of coronavirus disease (COVID-19) emerged in Wuhan, China. The causative agent was subsequently identified and named severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) which rapidly spread worldwide causing a pandemic. Currently there are no licensed vaccines or therapeutics available against SARS-CoV-2 but numerous candidate vaccines are in development and repurposed drugs are being tested in the clinic. There is a vital need for authentic COVID-19 animal models to further our understanding of pathogenesis and viral spread in addition to pre-clinical evaluation of candidate interventions. Here we report a dose titration study of SARS-CoV-2 to determine the most suitable infectious dose to use in the ferret model. We show that a high (5×106 pfu) and medium (5×104 pfu) dose of SARS-CoV-2 induces consistent upper respiratory tract (URT) viral RNA shedding in both groups of six challenged animals, whilst a low dose (5×102 pfu) resulted in only one of six displaying signs of URT viral RNA replication. The URT shedding lasted up to 21 days in the high dose animals with intermittent positive signal from day 14. Sequential culls revealed distinct pathological signs of mild multifocal bronchopneumonia in approximately 5-15% of the lung, observed on day 3 in high and medium dosed animals, with presence of mild broncho-interstitial pneumonia on day 7 onwards. No obvious elevated temperature or signs of coughing or dyspnoea were observed although animals did present with a consistent post-viral fatigue lasting from day 9-14 in the medium and high dose groups. After virus shedding ceased, re-challenged ferrets were shown to be fully protected from acute lung pathology. The endpoints of URT viral RNA replication in addition to distinct lung pathology and post viral fatigue were observed most consistently in the high dose group. This ferret model of SARS-CoV-2 infection presents a mild clinical disease (as displayed by 80% of patients infected with SARS-CoV-2). In addition, intermittent viral shedding on days 14-21 parallel observations reported in a minority of clinical cases.

Study Design. Ferrets were challenged intranasally with 1ml of Victoria/1/2020 26 119 SARS-CoV-2 at three different titres representing a high, medium and low dose (Table   120 1). A high titre stock of challenge virus was prepared (passage 3), and quality control 121 sequencing showed it was identical to the original stock received from the Doherty 122 Institute and did not contain a commonly reported 8 amino acid deletion in the furin 123 cleavage site 27 . Following the initial challenge, a re-challenge with the high dose 124 (5x10 6 PFU) took place at day 28 post challenge (pc). The four (two per group) 125 remaining ferrets in groups 2 and 3 were re-challenged via the same, intranasal, route 126 and 1ml volume alongside a control group of two naïve control ferrets (group 5).

127 128 Viral Shedding following challenge. Viral RNA was detected in the nasal wash of 129 6/6 ferrets in the high dose group from day 1 pc and continued to be detected at 130 varying levels until day 20 pc (Fig. 1a) . The peak in viral RNA shedding was seen 131 between day 2 and 4 pc for all ferrets in the high dose group. Following a decline in 132 viral RNA (2/2 animals) to below the limit of quantification at day 13 pc, an increase 133 was seen at days 16 and 18, with a measurement in viral RNA for one ferret (4.75x10 4 134 copies/ml) just above the limit of quantification at day 16 pc and a viral load of 1.1x10 6 135 copies/ml in the other ferret at day 18 pc. Both Group 1 survivors were euthanised on 136 day 21 at which point no viral RNA was detected in their nasal washes. In the medium dose group 6/6 ferrets also had detectable viral RNA in nasal washes 139 from day 1 pc. The peak of viral RNA shedding was more variable in the medium dose 140 group, with some ferrets peaking at days 2 to 3 pc (4/6) and others peaking at days 5 141 to 6 pc (2/6). A decline was then seen until day 11 pc where viral RNA levels fell below 142 the limit of quantification, but viral RNA was still detected. By day 16 no more viral 143 RNA was detected. Quantifiable viral RNA was only found in the nasal wash of 1/6 144 ferrets in the low challenge dose group. This ferret was euthanised on day 5 pc. No 145 other ferrets in the low dose group were found to shed quantifiable viral RNA in their 146 nasal wash.

A similar trend in the titre of viral RNA detected in nasal wash samples was observed 149 in the throat swabs samples during the first week after challenge (Fig. 1b) . The Detection of viral RNA in the rectal swabs was found to be variable across the different 156 dose groups (Fig 1c. ). The highest viral RNA load was observed in a ferret in the high 157 dose group but there was a less consistent pattern of RNA detection which did not 158 continue past day 7 pc. In the medium dose group, 4/6 ferrets were found to have 159 detectable viral RNA in their rectal swabs between day 2 and 8 pc. No viral RNA was 160 detected in any of the rectal swabs collected from the low dose group following 161 challenge.

Page 9 of 39 163 Viral RNA was detected at quantifiable levels in the bronchoalveolar lavage (BAL) of 164 each ferret euthanised (scheduled) on day 3 pc from the high dose (1/1) and medium 165 dose (1/1) groups (Fig. 1d ). Viral RNA was detected but not quantified for ferrets 166 across all three challenge groups at day 5 and 7 pc. There was no viral RNA detected Table 2 . At day 9 pc 179 all 3/3 ferrets in the high dose group showed reduced activity, a similar observation 180 was made in the medium dose group but later on day 10 pc. Reduced activity was 181 accompanied by ruffled fur, a sign that the ferrets were not grooming regularly. By Table 3 . At day 28 pc, these ferrets and two naïve control 253 animals were challenged intranasally with the high dose of SARS-Cov-2 (5x10 6 pfu). to stay above quantifiable levels in the naïve control group, although they began to fall 259 at day 8 post re-challenge (Fig. 4a) . Similar results were seen in the throat swab and 260 rectal swabs (data not shown), with reduced viral shedding seen in the re-challenged 261 animals. Animals in the re-challenged medium and low dose groups exhibited weight 262 loss from baseline that was not seen at initial challenge for any of the animals in any 263 of the challenge groups (Fig. 4b) . Re-challenged animals also experienced increased 264 clinical observations of lethargy and ruffled fur that was not observed at such an early 265 stage in the initial challenge ( Table 2 ). In contrast, the two previously naïve control 266 animals did not experience weight loss below baseline after infection and they did not 267 suffer the same level of clinical observation as the re-challenged animals (Fig 4b) . the 're-challenge' (Fig. 4f) . This parallels the absence of pathology observed in the 281 two naïve sentinel ferrets euthanised at day 20 pc. showed that the response to the virus appears to be higher on re-challenge. On day 28 pc the remaining ferrets in the low (n=2) and medium (n=2) groups were 441 re-challenged with 5x10 6 pfu by the intranasal route. Additional naïve control ferrets 442 (n=2) were also challenged on day 28, to provide a re-challenge control. All 6 animals 443 were monitored for clinical signs and one ferret from each group was euthanised on 444 day 33 and the remaining animals were euthanised on day 36. Throat and rectal swabs were processed, and aliquots stored in viral transport media 457 (VTM) and AVL at -80C until assay. CoV-2 NC_045512.2, with quantification between 1 x 10 1 and 1 x 10 7 copies/µl.

Positive samples detected below the limit of quantification were assigned the value of 505 6 copies/µl, whilst undetected samples were assigned the value of ≤ 2 copies/µl, 506 equivalent to the assays limit of detection. 

Origin and evolution of pathogenic coronaviruses

Development of animal models against emerging 634 coronaviruses: From SARS to MERS coronavirus

Genomic characterisation and epidemiology of 2019 novel 637 coronavirus: implications for virus origins and receptor binding

WHO. Report of the WHO-China Joint Mission on Coronavirus Disease

Transmission and Pathogenesis of Swine-Origin

A(H1N1) Influenza Viruses in Ferrets and Mice

Influenza virus aerosol exposure and analytical system for 648 ferrets

Induction and relief of nasal congestion 651 in ferrets infected with influenza virus

Ferret Influenza Virus Pathogenesis and Transmission Models

Cellular immune response to human influenza viruses differs 657 between H1N1 and H3N2 subtypes in the ferret lung

Heterosubtypic cross-protection correlates with cross-660 reactive interferon-gamma-secreting lymphocytes in the ferret model of 661 influenza

Animal models for influenza virus 664 pathogenesis, transmission, and immunology

Ferrets as a Novel Animal Model for Studying Human 667

Respiratory Syncytial Virus Infections in Immunocompetent and 668

Animal models of respiratory syncytial virus infection

Infection of mice, ferrets, and rhesus macaques with a clinical 672 mumps virus isolate

Ferrets Infected with Bundibugyo Virus or Ebola Virus 675

Recapitulate Important Aspects of Human Filovirus Disease

Modeling Ebola Virus Transmission Using Ferrets

Moving Forward: Recent Developments for the Ferret 680

The Nature of Exposure Drives Transmission of Nipah 683 Viruses from Malaysia and Bangladesh in Ferrets. PLOS Neglected Tropical 684 Diseases 10

Evaluation of modified 686 vaccinia virus Ankara based recombinant SARS vaccine in ferrets

The SARS-CoV ferret model in an infection-challenge study

Pathology of Experimental SARS Coronavirus 691 Infection in Cats and Ferrets

Severe acute respiratory syndrome coronavirus infection 694 in vaccinated ferrets

A new coronavirus associated with human respiratory disease in 697

Return of the Coronavirus: 2019-nCoV

Isolation and rapid sharing of the 2019 novel coronavirus

CoV-2) from the first patient diagnosed with COVID-19 in Australia

Characterisation of the transcriptome and proteome of 704 SARS-CoV-2 using direct RNA sequencing and tandem mass spectrometry 705 reveals evidence for a cell passage induced in-frame deletion in the spike 706 glycoprotein that removes the furin-like cleavage site. bioRxiv

Virological assessment of hospitalized patients with COVID-709 2019

Covid-19: WHO and South Korea investigate reconfirmed cases

SARS virus infection of cats and ferrets

Human monoclonal antibody as prophylaxis for SARS 715 coronavirus infection in ferrets

Immunization with Modified Vaccinia Virus Ankara-Based 718

Recombinant Vaccine against Severe Acute Respiratory Syndrome Is 719 Associated with Enhanced Hepatitis in Ferrets

SARS-CoV-2 productively infects human gut enterocytes

Susceptibility of ferrets, cats, dogs, and other domesticated animals 724 to SARS-coronavirus 2

Infection and Rapid Transmission of SARS-CoV-2 in Ferrets

Reinfection could not occur in SARS-CoV-2 infected rhesus 729 macaques. bioRxiv

Immunization with SARS Coronavirus Vaccines Leads to 732

Pulmonary Immunopathology on Challenge with the SARS Virus

A double-inactivated severe acute respiratory syndrome 735 coronavirus vaccine provides incomplete protection in mice and induces 736 increased eosinophilic proinflammatory pulmonary response upon challenge

Low Dose Influenza Virus Challenge in the Ferret Leads to 739

Increased Virus Shedding and Greater Sensitivity to Oseltamivir

Metagenomic Nanopore Sequencing of Influenza Virus 742

Direct from Clinical Respiratory Samples

Diagnostic methods in clinical virology

of the groups during specific days post challenge and post re-challenge. Activity in 774 ferrets was scored as follows; 0 = alert and playful, 1 = alert, playful when stimulated

Ruffled fur was given a 776 score of 1. Activity scores of 1 were given to ferrets during the initial challenge. Upon 777 re-challenge ferret activity was recorded as 1 or 2 indicating increased lethargy in 778 ferrets following re-challenge

Group 1, H&E staining. Mild epithelial cell necrosis 782 (arrows) and minimal inflammatory cell infiltration within the epithelium. (b) Nasal 783 cavity, day 3 pc, Group 1, SARS-CoV-2 viral RNA detection

Presence of viral RNA in abundant ciliated epithelia cells from the nasal cavity 785 mucosa. (c) Lung, day 5 pc, Group 1, H&E staining. Moderate bronchopneumonia with 786 neutrophil and macrophage inflammatory infiltrate within the bronchiolar lumina 787 (arrow)

SARS-CoV-2 viral RNA detection (RNAScope staining). Presence of viral 789 RNA in type II pneumocyte (arrow). (e) Lung, day 21 pc

Bronchiole with mild inflammatory infiltration in the lumina (arrow) and attenuation of