On February 9, 2018, the World Health Organization (WHO) announced the Blueprint list of priority diseases, including Middle East respiratory syndrome (MERS) and Severe Acute Respiratory Syndrome (SARS), as well as Disease X, for research and development in emergency contexts. Disease X would be a new disease with an epidemic or pandemic potential caused by an unknown pathogen (www.who.int/activities/prioritizing-diseases-for-research-and-development-in-emergency-context). At that time, we believed that the first Disease X could be a transmissible infectious disease caused by a novel coronavirus originated from bats. This supposition was based on a live SARS-related coronavirus (SARSr-CoV), designated SARSr-CoV-WIV1, isolated from bat fecal samples in Vero E6 cells. It had 99.9% whole genome sequence identity to that of SARSr-CoV-Rs3367 identified from Chinese horseshoe bats and another novel strain, SARSr-CoV-RsSHC014, both of which could utilize human, civet and Chinese horseshoe bat angiotensin converting enzyme II (ACE2) as the host cell receptor for infecting human, civet and Chinese horseshoe bat target cells (Ge et al. 2013; Cui et al. 2019). This evidence prompted us to accelerate our efforts to develop viral fusion inhibitors and neutralizing antibodies with broad-spectrum inhibitory activity against divergent human coronaviruses and SARSr-CoVs (Zeng et al.2017; Xia et al. 2019).

On 31 December 2019, the Wuhan Municipal Health Commission reported that 27 cases of unexplained pneumonia linked to the wholesale Huanan Seafood Market in Wuhan had been identified and hospitalized. By then, the investigation had not found significant human-to-human transmission and no medical personnel infected (www.sciencemag.org/news/2020/01/novel-human-virus-pneumonia-cases-linked-seafood-market-china-stir-concern). Based on the announcement of the World Health Organization, as noted above, the Wuhan pneumonia caused by an unknown etiology should be recognized as the first Disease X.

Soon after that, the pathogen causing Wuhan pneumonia was identified as a novel coronavirus, denoted 2019-nCoV by WHO (https://www.who.int/emergencies/diseases/novel-coronavirus-2019), with 79.5% and 96% whole genome sequence identity to SARS-CoV and bat coronavirus SARSr-CoV-RaTG13, respectively, suggesting 2019-nCoV’s potential bat origin (Zhou et al. 2020). However, no name for the pneumonia caused by 2019-nCoV infection has been provided by WHO or by the International Committee on Taxonomy of Viruses (ICTV) so far. Accordingly, some researchers decided to denote this novel coronavirus as “novel coronavirus-infected pneumonia (NCIP)” in their publication (Li et al. 2020). However, in the generally accepted lexicon, one would then have to write “novel coronavirus-infected pneumonia coronavirus (NCIP-CoV)”, which could be an awkward construct. Most reporters and media are still calling it “Wuhan pneumonia”, but this terminology is detrimental to Wuhanese already facing lockdown and economic loss. The obvious dilemmas call for a renaming of the disease and virus causing the disease, one that is both lexicographically and taxonomically appropriate (news.ifeng.com/c/7tf2GFqwL4a).

Jiang and colleagues recently suggested renaming NCIP as “pneumonia-associated respiratory syndrome (PARS)” and 2019-nCoV as “PARS coronavirus (PARS-CoV)” (Jiang et al.2020a, b) in order to retain terminology equivalent to that of SARS-CoV, which was based on the facts that (1) the novel coronavirus causing the pneumonia outbreak in Wuhan is rapidly becoming well known worldwide, (2) most patients suffer from pneumonia, (3) the pneumonia caused by 2019-nCoV is much less severe than that caused by SARS-CoV, and (4) the case-fatality rate (CFR) of patients with 2019-nCoV infection is much lower than that of individuals with SARS-CoV infection. However, several experts in the coronavirus field have expressed their concern that the term PARS seems to exclude associated respiratory syndrome arising from other etiologies of pneumonia. Therefore, we herein propose the following alternative terminology: “transmissible acute respiratory syndrome (TARS)” and “TARS-CoV” for the virus, similar to SARS-CoV, since 2019-nCoV is one of the most transmissible coronaviruses identified so far. Although the estimated R0 (~ 2.6) of 2019-nCoV (Zhao et al.2020) is generally in line with that of SARS (R0: 2–5), it is much higher than that of MERS (R0: < 1) (Chen et al.2020). In addition, the number of 2019-nCoV-infected patients via human-to-human transmission is at least 3- and 10-fold higher than that of SARS-CoV- and MERS-CoV-infected patients, respectively. On 5 February 2020, the New Coronavirus Infection Pneumonia Diagnosis and Treatment Plan (trial version 5) published by the National Health Commission of the People’s Republic of China indicated that the routes of transmission via aerosols and digestive tract were also possible, even though 2019-nCoV is, thus far, known to be primarily transmitted through respiratory droplets and contacts (m.chinanews.com/wap/detail/sp/sp/shipin/cns/2020/02-05/news9080314.shtml), rendering the virus even more transmissible or infectious. Please be aware that WHO may not take our suggestion and ICTV should make the final decision about renaming 2019-nCoV, as they did for naming MERS-CoV in 2013 (de Groot et al. 2013).

As of 8 February, 34,953 confirmed cases of 2019-nCoV infection and 725 deaths have been reported in China and 24 other countries (http://en.nhc.gov.cn/2020-02/08/c_76358.htm). This outbreak of 2019-nCoV infection has posed a serious threat to global public health, thus calling for the development of therapeutic and prophylactic strategies (Jiang et al.2020a, b).

Based on the previous experience in the research and development of virus fusion inhibitors against HIV, SARS-CoV, and MERS-CoV (Jiang et al.1993; Liu et al. 2004; Lu et al. 2014), Jiang and colleagues have recently developed a pan-CoV fusion inhibitor, EK1 peptide, with potent inhibitory activity against infection by 5 human coronaviruses tested, including SARS-CoV, MERS-CoV, and 3 bat-SARSr-CoVs (Xia et al. 2019). EK1 peptide could protect hDPP4-transgenic mice or regular mice treated with EK1 via intranasal application before or after challenge with MERS-CoV or hCoV-OC43, respectively. Most recently, Jiang and colleagues showed that EK1 peptide and the peptide derived from the HR2 domain in spike (S) protein of 2019-nCoV (2019-nCoV-HR2P) could effectively inhibit 2019-nCoV pseudovirus infection and S protein-mediated cell–cell fusion (Xia et al. 2020), indicating that either EK1 or 2019-nCoV-HR2P could be promising candidates to be developed for prevention and treatment of infection by 2019-nCoV, SARS-CoV, and possibly other emerging and reemerging coronaviruses in the future.

Jiang and colleagues have previously shown that the receptor-binding domain (RBD) in S protein of SARS-CoV contains at least 6 conformation-dependent neutralizing epitopes that can induce potent neutralizing antibody response and protection of immunized animals against SARS-CoV infection (Du et al.2009, 2016). Interestingly, we have previously demonstrated that antibodies induced by SARS-CoV S-RBD could cross-neutralize infection by bat SARSr-CoVs, including bat-SARSr-CoV-W1V1 and bat-SARSr-CoV-SHC014 (Zeng et al.2017). Most recently, we have shown that one SARS-CoV S-RBD-specific monoclonal antibody, CR3022, could potently bind with 2019-nCoV S-RBD, using different probative assays (Tian et al.2020). These results suggest that the SARS-CoV S-RBD-based vaccine candidate should be tested for its in vitro and in vivo efficacy in inducing neutralizing antibody responses and protection of animals against 2019-nCoV infection. If it works, the already developed RBD-based anti-SARS vaccine candidate has sufficient potential to go to clinical studies for the prevention of 2019-nCoV infection.