key: cord-0721171-yn772ohe
authors: Chaves-Medina, María Juliana; Gómez-Ospina, Juan Camilo; García-Perdomo, Herney Andrés
title: Molecular mechanisms for understanding the association between TMPRSS2 and beta coronaviruses SARS-CoV-2, SARS-CoV and MERS-CoV infection: scoping review
date: 2021-12-25
journal: Arch Microbiol
DOI: 10.1007/s00203-021-02727-3
sha: 53be4d59f44c163b39fe029f44025fd74219870c
doc_id: 721171
cord_uid: yn772ohe

The aim of this scoping review was to identify knowledge gaps and to describe the current state of the research on the association between TMPRSS2 and the essential beta coronaviruses (Beta-CoVs) infection and the molecular mechanisms for this association. We searched MEDLINE (OVID), EMBASE, and the Cochrane Central Register of Controlled Trials (CENTRAL). We included 13 studies. Evidence shows an essential role of TMPRSS2 in Spike protein activation, entry, and spread into host cells. Co-expression of TMPRSS2 with cell surface receptors (ACE2 or DPP4) increased virus entry. This serine protease is involved in the formation of large syncytia between infected cells. TMPRSS2 cleaved the Spike protein of SARS-CoV, SARS-CoV-2, and MERS-CoV, and increased virus propagation. Accumulating evidence suggests that TMPRSS2 is an essential protease for virus replication. We highlighted its critical molecular role in membrane fusion and the impact in viral mRNA replication, then promoting/driving pathogenesis and resistance. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s00203-021-02727-3.

Emerging coronaviruses can constitute a severe threat to human health. The subfamily Coronavirinae within the family Coronaviridae comprises viruses that cause respiratory, neurological, and intestinal symptoms in mammals and birds (Wang et al. 2020a, b) . The severe acute respiratory syndrome coronavirus (SARS-CoV) emerged in 2002 in Southern China. The Middle East respiratory syndrome coronavirus (MERS-CoV), which emerged in Saudi Arabia, was the pathogen responsible for severe respiratory disease outbreaks in 2012 (Huang et al. 2020 ).

On 11 March 2020, WHO declared COVID-19 infection a pandemic, and the number of individuals infected and deaths quickly raised. Then, it is essential to monitor viral evolution, infectivity, transmissibility, and pathogenicity (Wang et al. 2020a, b; Huang et al. 2020; WHO 2020) . The disease affected patients with underlying chronic illness, but documented infections in health care workers indicated human-to-human transmission. Now, it is very established that SARS-CoV-2 is capable of widespread human-tohuman transmission (Wang et al. 2020a, b) . Acute respiratory distress syndrome (ARDS) and shock associate with pulmonary inflammation and extensive lung damage in patients (Wang et al. 2020a, b; Huang et al. 2020) . However, nowadays, we do not entirely understand the pathophysiology of SARS-CoV-2 infection and SARS-CoV and MERS-CoV (Zhu et al. 2020 ).

TMPRSS2 gene encodes a self-membrane protein of 492 amino acids, which anchors to the plasma membrane. It converts to its form through autocatalytic cleavage between Arg255 and Ile256 (Shulla et al. 2011) . After cleavage, the mature proteases are mostly membrane-bound, yet a noticeable portion of them can liberate into the extracellular milieu. TMPRSS2 predominantly expresses in the prostate, lungs, colon, liver, kidneys, and pancreas. Also, it activates protease-activated receptor 2 (PAR-2), a G-protein-coupled receptor, that causes the upregulation of matrix metalloproteinase-2 (MMP-2) and MMP-9, which are critical proteases Communicated by Lorena Tomé-Poderti. in the metastasis of tumor cells. Some reports have shown how this TMPRSS2-mediated pathway allows the spread and pathogenesis of SARS-CoV, demonstrating that infection in the presence of this protease could induce higher concentrations of pro-inflammatory cytokines and cytopathic effects (Shulla et al. 2011; Wang et al. 2020a, b) . Moreover, this enzyme may have an activating effect on the receptor to which some coronaviruses bind, such as human ACE2, which gives it a replication potential in human cells (Wang et al. 2020a, b; Huang et al. 2020) .

This study aimed to identify knowledge gaps and to describe the current state of the research on the association between TMPRSS2 and the essential beta coronaviruses (Beta-CoVs) infection and the molecular mechanisms for this association. Also, to make specific recommendations for future research.

We performed this scoping review according to the recommendations of the Joanna Briggs Institute (Peters et al. 2017 ).

We included theoretical information, in vitro or in vivo studies, studies in animals, or in silico studies assessing the molecular mechanism to determine the association between TMPRSS2 and the betacoronavirus SARS-CoV-2, SARS-CoV, and MERS-CoV infection.

We focused on the molecular mechanisms that explain the association between this serine protease and the infection of this virus.

We did not limit for language or setting.

Studies that did not include information about TMPRSS2 and Spike protein of coronaviruses.

We included studies (human, animal, reviews, systematic reviews, and primary studies) to respond to the two objectives. We searched the literature following medical subject headings (MeSh), Emtree language, Decs, and text words related. We searched MEDLINE (OVID), EMBASE, and the Cochrane Central Register of Controlled Trials (CENTRAL) from inception to nowadays. To ensure literature saturation, we scanned references from relevant articles identified through the search, conferences, thesis databases, Open Grey, Google scholar, and clinicaltrials.gov.

Two researchers reviewed each reference by title and abstract. Then they scanned full-texts of relevant studies, applied pre-specified inclusion and exclusion criteria, and extracted the data. Disagreements were resolved by consensus. Two trained reviewers using a standardized form independently extracted the following information from each article: author, publication year, study design, geographic location (origin), authors' names, title, objectives, methods, virus species, cleavage site, outcomes, funding source, and other key findings.

We descriptively showed the results, trying to respond to the two objectives. Results were also classified under main conceptual categories to facilitate comprehension.

We found 84 studies with the search strategies and three with other sources. After exclusions, we finally included 13 studies (Matsuyama et al. 2010; Matsuyama et al. 2020; Glowacka et al. 2011; Shulla et al. 2011; Shirato et al. 2013; Heurich et al. 2014; Shen et al. 2017; Reinke et al. 2017; Kleine-weber et al. 2018; Iwata-Yoshikawa et al. 2019; Bilinska et al. 2020; Zang et al. 2020; Hoffmann et al. 2020) in the qualitative analysis (Fig. 1) .

Five studies evaluated SARS-CoV (Glowacka et al. 2011; Shulla et al. 2011; Heurich et al. 2014; Reinke et al. 2017; Matsuyama et al. 2020) , two evaluated MERS-CoV (Shirato et al. 2013; Kleine-weber et al. 2018) , two studies evaluated both (Shen et al. 2017; Iwata-Yoshikawa et al. 2019) , and three others evaluated SARS-CoV-2 (Hoffmann et al. 2020; Matsuyama et al. 2020) . Multiple essays were reporting the expression of TMPRSS2 in different cell lines. The authors frequently used 293 T cells, Vero, Vero E6, Caco-2, or Calu-3 cells. For infecting the cells, six studies used a lentiviral vector as plasmids. Also, they used plasmids encoding TMPRSS2, ACE2, or DPP4. For analysis of antigens expression, detection of proteins, quantification of messenger-RNA (mRNA), studies performed western blot and/or Real Time-Polymerase Chain Reaction (RT-qPCR). The authors also used other techniques such as immunohistochemistry, electron microscopy, and next-generation sequence (Table 1) .

We described the molecular mechanisms for the association between TMPRSS2 and beta-CoV infection in the following paragraphs. We described some additional information regarding this topic in Table 2 .

The SARS-CoV spike protein (SARS-S) incorporates into the viral envelope and mediates viral entry into target cells. For this, the surface unit (S1) of SARS-S binds to the cellular receptor angiotensin-converting enzyme 2 (ACE2) and the transmembrane unit (S2), then fuses the viral membrane with a host cell membrane (Reinke et al. 2017; Iwata-Yoshikawa et al. 2019) . Shulla 2011 slightly evidenced TMPRSS2-specific SARS-S cleavage. The resulting fragments are assumed to represent the activated S proteins operating in pseudovirus entry. It can trigger the uptake of virions into host cell endosomes (Shulla et al. 2011) . Spike cleavage by TMPRSS2 takes place in the Golgi or plasma membrane, either during assembly or attachment and release (Shirato et al. 2013) . Glowacka et al. demonstrated that TMPRSS2 cleaved SARS S at multiple sites inducing incomplete SARS-S shedding in cells coexpressing TMPRSS2 and SARS-S.

They also found that TMPRSS2 facilitated trans-cleavage of SARS-S, indicating that it could activate SARS S for membrane fusion (Glowacka et al. 2011 ). According to Matsuyama 2010, as they found that TMPRSS2 affected SARS S attached to receptors at the cell surface but not newly synthesized SARS S (Matsuyama et al. 2010 ). On the other hand, Reinke 2017 found that residue R667 was essential for SARS S cleavage by TMPRSS2 while the same residue was dispensable for S protein activation (Reinke et al. 2017 ).

Shirato 2013 found that cleavage fragments activity was required for viral spread into the host. Also, differential glycosylation of the cleavage products might reflect differential cellular localization of the corresponding cleavage processes. In contrast, TMPRSS2 might process SARS S early after import in the constitutive secretory pathway and before N-glycans are fully processed (Shirato et al. 2013) .

Kleine-Weber et al. described different MERS-CoV spike protein (MERS-S) cleavage sites for each protease as follows: S2′ site (amino acids RSAR) for activating proteases (including TMPRSS2); S1/S2 site (amino acids RSVR) for furin; and AFNH motif for endosomal cysteine protease (Cathepsin B/L). When they evaluated the impact of mutations introduced in these sites, they found that it required an intact S2′ site. In contrast, the cathepsin L site mutation had no impact on S protein-driven entry, and mutation of the S2′ site abrogated MERS S activation by TMPRSS2 (Kleineweber et al. 2018) . Similarly, Shen 2017 described cleavage sites and found that after cleavage of SARS-S, S1 and S2 domains remained noncovalently associated but not disulfide bonds (Shen et al. 2017) .

Recently, Hoffmann et al. showed that priming of SARS-CoV-2 spike protein (SARS-2-S) evidenced several arginine residues at the S1/S2 cleavage site of SARS-2-S but not SARS-S. However, the S2 cleavage site of both was similar (Hoffmann et al. 2020 ).

As mentioned above, studies show that SARS-CoV and SARS-CoV-2 bind to cellular receptor ACE2. Matsuyama 2010 studied the expression of ACE2 using specific antibodies, and they weakly detected ACE2 antigens in uninfected (Matsuyama et al. 2010) . Glowacka et al. also detected intense positive staining of both proteins in type II pneumocytes and alveolar macrophages (Glowacka et al. 2011 ). In Shulla et al. (2011) , TMPRSS2 eliminated fulllength ACE2 in a dose-dependent manner, but ACE2 colocalized to TMPRSS2-containing regions when TMPRSS2 scarce and showed that it required an enzymatic activity of TMPRSS2 for this association. Interestingly, when these two proteins were expressed in separate cells, SARS-CoV entry into host cells was not higher than those expressing one of them. It indicates that the priming of ACE2 by TMPRSS2 was necessary for virus entry (Shulla et al. 2011 ). Heurich 2013 concluded that TMPRSS2 facilitates SARS-CoV infection through cleavage of ACE2, which might promote viral uptake (Heurich et al. 2014) .

The catalytic domain of ACE2 binds to SARS-S with high affinity, and it triggers conformational rearrangements that could increase proteolysis sensitivity. In that sense, arginine and lysine residues within ACE2 amino acids 697-716 are essential for ACE2 cleavage by TMPRSS2.

Augmentation of SARS-S-driven entry requires the processing of ACE2 but not for its activation (Heurich et al. 2014) . It is noteworthy that, according to Hoffmann 2020, most amino acid residues essential for ACE2 binding by SARS-S were conserved in SARS-2-S. In this study, authentic SARS-CoV-2 infected cells expressing ACE2 with high efficiency but not cells without this receptor (p < 0.01) and antiserum against human ACE2 blocked SARS-S-and SARS-2-S-driven entry (p < 0.001) (Hoffmann et al. 2020) .

Some studies show that syncytia formation is more frequent and pronounced between SARS-CoV infected cells (or even SARS-S expressing cells) expressing TMPRSS2 and between MERS-CoV infected cells expressing TMPRSS2 (Matsuyama et al. 2010; Glowacka et al. 2011; Shulla et al. 2011; Shirato et al. 2013) . Interestingly, outcomes from Matsuyama et al. (2010) indicate that TMPRSS2 expression must oppose that of SARS S to induce membrane fusion. Syncytia formation was not induced in cells that did not express TMPRSS2, nor between TMPRSS2 and SARS-S and cells without TMPRSS2. However, large syncytia formed when TMPRSS2 was expressed either in target cells or both in the target and producer cells (Matsuyama et al. 2010) . In that sense, SARS S can be activated for virus-cell and cell-cell fusion when TMPRSS2 is expressed on viral target cells (Glowacka et al. 2011; Shulla et al. 2011 ). Syncytia formation is frequent in cells expressing TMPRSS2 infected with SARS-CoV-2 (Matsuyama et al. 2020 ). 

In general, cells expressing TMPRSS2 were more susceptible to virus entry and spread into host cells. Also, when compared to other serine proteases, TMPRSS2 was more effective in enhancing SARS-S-mediated entry (Glowacka et al. 2011; Shulla et al. 2011; Heurich et al. 2014; Reinke et al. 2017) . TMPRSS2 expression was also associated with increased amounts of viral RNA. Shulla et al. found that SARS N RNA was ninefold more in TMPRSS2-expressing cells, and this RNA translated to generate significantly more N proteins (p < 0.0005) (Shulla et al. 2011) . For the recent SARS-CoV-2, Matsuyama et al. evidenced that viral RNA copies in specimens with cytopathic effects developed within two days were more significant than those in the other specimens. They used Vero E6/TMPRSS2 cells and found more than 100 times higher viral RNA copies than Vero E6, which also showed higher amounts compared to other cell types used (Matsuyama et al. 2020) . In gut epithelial cells, Zang et al. demonstrated that TMPRSS2 alone did not mediate viral infection. However, co-expression of TMPRSS2 with ACE2 resulted in enhanced infectivity, inducing S protein cleavage and exposing the fusion peptide for efficient viral entry (Zang et al. 2020) .

Further analyses using protease inhibitors support these results. In the study performed by Kleine-Weber et al. (2018) , preincubation of Caco-2 cells with protease inhibitors showed that entry driven by MERS S lacking an intact S1/S2 site was dependent on TMPRSS2, indicating a dominant role of TMPRSS2 in MERS-S-driven entry. Reinke et al., also used a serine protease inhibitor and found that it protected rodents from SARS-CoV-induced pathogenesis, while a cysteine protease inhibitor active against cathepsin B/L did not (Reinke et al. 2017) . Finally, Hoffmann et al. used camostat mesylate treatment (a drug active against TMPRSS2) and found a significant reduction in SARS-S-and SARS-2-S-mediated entry into Calu-3 and human lung cells. It also reduced the infection by authentic SARS-CoV-2 into Calu-3 cells. On the other hand, treatment of other cell lines (Caco-2 and Vero-TMPRSS2) partially blocked SARS-2-S-driven entry, but when they added an inhibitor of Cathepsin B/L, complete inhibition was attained (Hoffmann et al. 2020) .

Bilinska et al. used a mouse model and determined whether cells in the olfactory epithelium (OE) express the obligatory receptors for entry of the SARS-CoV-2 virus by using RNAseq, RT-PCR, in situ hybridization, Western blot, and immunocytochemistry. Their mouse model showed that, with older age, amounts of ACE2 protein increased in the OE, as did gene expression of TMPRSS2. Sustentacular cells were identified as the cell type that expressed both SARS-CoV-2 host receptors required for cell entry. Results suggest that the SARS-CoV-2 virus accumulates in sustentacular cells first and, by interfering with their metabolism, affects the function of olfactory receptor neurons (Bilinska et al., 2020) .

As mentioned above, some studies have used Cathepsin B/L inhibitors to study Spike protein-mediated entry under these conditions or even evaluate cleavage by this cysteine protease. Spike protein cleavage and activation by pHdependent cathepsin B/L occurs in the endosome (Reinke et al. 2017) . Studies have shown that inhibition of Cathepsin L decreased virus entry into cells with no expression of TMPRSS2 on the cell surface. Expression of TMPRSS2 could even activate Spike protein and enhance SARS-Smediated entry (Matsuyama et al. 2010; Glowacka et al. 2011; Shulla et al. 2011) . Kleine-Weber et al. found similar results for MERS S in which they introduced mutations into different cleavage sites. They found that mutation of a single arginine within S1/S2 reduced entry into Caco-2 cells by 4.5 to 29.4-fold (p < 0.001). Mutation of any single arginine at the S2′ site had only a minor, statistically significant, effect on S protein-mediated transduction of Vero E6 cells (p < 0.001), and mutation of S2′ abrogated MERS-S activation by TMPRSS2. However, entry mediated by the S protein mutants with inactivated S1/S2 site was rescued by TMPRSS2 in cells previously treated with Cathepsin L inhibitor (Kleine-weber et al. 2018) . For SARS-CoV-2, Hoffmann et al. also evidenced that expression of TMPRSS2 rescued SARS-2-S-driven entry from inhibition of cathepsin B/L. It is noteworthy that this study also reported a residual Spike protein priming by cathepsin B/L in a cell line when camostat mesylate was used. However, S protein priming by TMPRSS2 but not cathepsin B/L is still essential for viral entry into primary target cells and viral spread in the infected host (Hoffmann et al. 2020 ).

Members of the betacoronavirus genus such as SARS-CoV and MERS-CoV have caused significant outbreaks of respiratory disease. It motivates the rapid understanding of virus interactions with human cells and immunopathology. With the novel coronavirus (SARS-CoV-2) outbreak, findings allowed to establish an essential similarity between this and previous Beta-CoVs. In that sense, SARS-S and SARS-2-S share approximately 76% amino acid identity, which makes it essential to know the similarities and differences between the mechanisms of virus entry and spread into host cells (Hoffmann et al. 2020) .

SARS-CoV and SARS-CoV-2 bind to the cell surface receptor ACE2, while MERS-CoV binds to DPP4 (Hoffmann et al. 2020; Zhou et al. 2020) . Studies described two critical mechanisms for host cell entry, depending on the availability of cellular proteases. When TMPRSS2 coexpresses with the target cell's surface receptors, Spike protein can be activated and then induce virus-cell membrane fusion. When cell surface proteases are not expressed, Spike protein binds to the cell surface's receptor, resulting in virions uptake into endosomes. In this case, Spike is cleaved and activated by pH-dependent cysteine protease Cathepsin B/L, initiating virus-endosome membrane fusion and later release of the viral genetic material into the cytosol (Heurich et al. 2014; Shen et al. 2017) .

Immunostaining for TMPRSS2 and ACE2 demonstrated intense positive staining of type II pneumocytes and alveolar macrophages. Similar results were found in severe lesions of lung tissue, and mRNA levels of TMPRSS2 have been detected in lung tissue (Matsuyama et al. 2010 (Matsuyama et al. , 2020 Glowacka et al. 2011; Kleine-weber et al. 2018) . These results show that TMPRSS2 facilitates SARS-CoV infection by cleavage of ACE2, which might promote viral uptake, and cleavage of SARS-S, which activates the S protein for membrane fusion (Heurich et al. 2014 ).

On the other hand, the expression of receptors and proteases requires a specific spatial orientation to allow S protein activation, S protein-mediated entry and spread into cells. If TMPRSS2 is coexpressed with SARS-S in the same cell, cleavage results in SARS-S shedding into the supernatants, where the S protein fragments could function as antibody decoys. If TMPRSS2 expresses on viral target cells, it can activate SARS-S for virus-cell and cell-cell fusion. Also, relevant targets correspond to cells in which both the ACE2 and TMPRSS2 entry factors are present in the same cells simultaneously (Glowacka et al. 2011; Shulla et al. 2011) . The results of the study performed by Bilinska et al., in which older mice expressed increasing levels of ACE2 and TMPRSS2, may explain why animals (and humans) are more susceptible to COVID-19 infection when they reach old age (Bilinska et al. 2020) .

Evidence shows that TMPRSS2 is essential for virus spread into host cells as more significant amounts of viral RNA and/or S protein have been detected in cells expressing this serine protease compared to TMPRSS2negative cells and large syncytia forms when TMPRSS2 is present. This process indicates a significant cytopathic effect. Cell-cell mediated cytotoxicity and viral replication may cause the immune system to develop severe inflammation in response to viral infection (Shirato et al. 2013 ). However, outcomes assessing immune response and the role of TMPRSS2 in immunopathology are unclear.

Iwata-Yoshikawa et al. evaluated the immune response in lung cells and the expression of TMPRSS2. TMPRSS2 shows the proliferation of Th2 profile and contributed to inflammatory reactions after Toll-Like Receptor 3 (TLR3) stimulation without the control of endogenous promoter transcription mRNA of chemokines. It also induced the expression of interleukins and interferons (Iwata-Yoshikawa et al. 2019). Its expression results in a focal inflammatory infiltration around the bronchi and the alveoli. In contrast, the expression TLR3 showed lower viral replication. The fragments produced by the TMPRSS2 do not demonstrate a relationship with long-term isotypes in the adaptative immune response. Also, chemokine, IFN-alpha4, IFN-beta, IL-12, IL-4, and IL-10 and viral mRNA, showed increasing levels daily postinfection with a significant association with the inflammatory pathogenesis (Glowacka et al. 2011; Iwata-Yoshikawa et al. 2019) .

Finally, using drugs to inhibit TMPRSS2 or other proteases such as Cathepsin B/L has allowed determining alternative mechanisms for S protein activation. In that sense, studies demonstrate that virus spread depends on TMPRSS2 activity, but there could be a residual effect of Cathepsin B/L in S protein priming when TMPRSS2 inhibits. This reaction could be explained by using alternative sites for S protein activation by Cathepsin L but not by TMPRSS2 (Matsuyama et al. 2010; Glowacka et al. 2011; Shulla et al. 2011; Reinke et al. 2017; Kleine-weber et al. 2018; Iwata-Yoshikawa et al. 2019; Hoffmann et al. 2020) . Candidate drugs for postexposure prophylaxis of SARS-CoV-2 infection could be clinically proven drugs such as camostat mesilate, preventing virus-host cell entry by inhibiting TMPRSS2. In addition, nafamostat mesilate may also inhibit cell entry of SARS-CoV-2 due to the amino acid sequence homology between Spike proteins of MERS-Cov and SARS-CoV-2. Cell culture experiments with simian Vero E6 cells infected with SARS-CoV-2, was shown to be inhibitive against SARS-CoV-2 infection, suggesting that nafamostat mesilate could prevent SARS-CoV-2 infection (Wang et al. 2020a, b; Mckee et al. 2020 ).

Emerging coronaviruses can constitute a severe threat to human health. Accumulating evidence suggests that TMPRSS2 is an essential protease for virus replication. However, there is a need for further research and many knowledge gaps exist. The expression of TMPRSS2 and the human proteases on Spike protein plays a critical role in initiating and propagating the virus, the transmissibility, and viral tropism and pathogenesis in the lung.

This review highlighted its critical molecular role in membrane fusion and the impact on viral mRNA replication, then promoting/driving pathogenesis and resistance. Many proteases have been discovered, and maybe an intrinsic mechanism leading to the rapid progress of ARDS in patients.

Identifying molecular mechanisms, advancements in virus genomics, and understanding their consequences will be crucial for developing novel therapeutic strategies to overcome the infection in a precision medicine era.

The online version contains supplementary material available at https:// doi. org/ 10. 1007/ s00203-021-02727-3.

Funding The authors had no funding.

Ethical approval This is a scoping review; no ethical approval was needed.

Informed consent No informed consent was needed.

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