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. 2021 Aug 11;39(39):5719–5726. doi: 10.1016/j.vaccine.2021.08.018

Could live attenuated vaccines better control COVID-19?

Shinya Okamura a,b, Hirotaka Ebina a,b,c,
PMCID: PMC8354792  PMID: 34426024

Abstract

In an effort to control the COVID-19 pandemic, large-scale vaccination is being implemented in various countries using anti-SARS-CoV-2 vaccines based on mRNAs, adenovirus vectors, and inactivated viruses. However, there are concerns regarding adverse effects, such as the induction of fever attributed to mRNA vaccines and pre-existing immunity against adenovirus vectored vaccines or their possible involvement in the development of thrombosis. The induction of antibodies against the adenovirus vector itself constitutes another hindrance, rendering boosting vaccinations ineffective. Additionally, it has been questioned whether inactivated vaccines that predominantly induce humoral immunity are effective against newly arising variants, as some isolated strains were found to be resistant to the serum from COVID-19-recovered patients.

Although the number of vaccinated people is steadily increasing on a global scale, it is still necessary to develop vaccines to address the difficulties and concerns mentioned above. Among the various vaccine modalities, live attenuated vaccines have been considered the most effective, since they closely replicate a natural infection without the burden of the disease. In our attempt to provide an additional option to the repertoire of COVID-19 vaccines, we succeeded in isolating temperature-sensitive strains with unique phenotypes that could serve as seeds for a live attenuated vaccine.

In this review article, we summarize the characteristics of the currently approved SARS-CoV-2 vaccines and discuss their advantages and disadvantages. In particular, we focus on the novel temperature-sensitive variants of SARS-CoV-2 that we have recently isolated, and their potential application as live-attenuated vaccines. Based on a thorough evaluation of the different vaccine modalities, we argue that it is important to optimize usage not only based on efficacy, but also on the phases of the pandemic. Our findings can be used to inform vaccination practices and improve global recovery from the COVID-19 pandemic.

Keywords: COVID-19, SARS-CoV-2, Live attenuated vaccine, Vaccine

1. Introduction

In 2019, an infectious disease named coronavirus disease 2019 (COVID-19) emerged in Wuhan, China. Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), a novel coronavirus related to SARS-CoV, was identified as the pathogen responsible for this disease [1]. As of March 2021, more than one hundred million cases and more than two million deaths due to COVID-19 have been reported worldwide [2]. Even those who recover from COVID-19 report long-term sequelae, such as fatigue, loss of taste, and olfactory disorders [3].

SARS-CoV-2 is an enveloped, positive-sense, single-stranded RNA virus of the Betacoronavirus genus, with a genome length of approximately 30 kb. The genome encodes a large polyprotein (ORF1ab), four structural proteins, and several other open reading frames. ORF1ab is cleaved into 16 nonstructural proteins [4]. The structural spike (S) glycoprotein consists of a head subunit S1 and a stalk subunit S2, and forms trimeric structures on the surface of SARS-CoV-2 virions. The receptor-binding domain (RBD) is located in the S1 subunit and facilitates viral attachment to the human angiotensin-converting enzyme 2 (hACE2), the known SARS-COV-2 receptor in humans [5]. Following attachment, the S protein is cleaved by host cell proteases, such as transmembrane serine protease 2 (TMPRSS2) and cathepsin, thereby inducing the fusion of the viral and cell membranes [6], [7], [8]. Because the RBD is critical for cell attachment and entry, it is considered an ideal target for vaccines that trigger the production of neutralizing antibodies [9]. Various types of SARS-CoV-2 vaccines have already been developed and evaluated worldwide (Fig. 1 ). Some of these vaccines, including adenovirus vectored vaccines, mRNA vaccines, and inactivated vaccines, have been approved for clinical use. However, new SARS-CoV-2 variants have recently been detected in the United Kingdom (B.1.1.7), South Africa (B.1.351), Brazil (P.1), the United States (B1.1.429), and India (B.1.617) among other countries [10], [11], [12]. These variants have several amino acid changes in the S protein, some of which are in the RBD.

Fig. 1.

Fig. 1

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SARS-CoV-2 vaccine candidates under development. SARS-CoV-2 infects host cells through the binding of the spike protein with hACE2 that serves as receptor. Therefore, the spike protein is considered a target antigen for vaccine development. Recombinant spike protein, inactivated virus and virus-like particle vaccines are used as protein-based vaccines. Inactivated vaccines are treated with chemical reagents such as formalin and β-propiolactone. These treatments lead to the fixing of proteins or to genome damage (indicated by the dotted line), respectively. Virus-like particles are composed of structural proteins only, and do not contain the viral genome. They are structurally similar to the wild type particles, but the nucleocapsid proteins which bind to the viral genome, are not positioned correctly. Different approaches to deliver the spike-encoding gene into the cells include DNA plasmids, encapsulated RNAs or virus vectors. Moreover, live attenuated viruses can be developed by generating cold-adapted or temperature-sensitive strains, or by codon de-optimization.

B.1.1.7, B.1.351 and P.1 variants have been spreading since the end of 2020. All these variants exhibit an N501Y substitution in the RBD. Deep mutational scanning of this domain has shown that this substitution increases the affinity of the RBD for hACE2, thus increasing the infectivity of the virus [13]. Additionally, there are amino acid substitutions at K417 and E484, such as those detected in the B.1.351 and P.1 variants, which have been reported to change virus antigenicity and to decrease susceptibility to neutralization by sera from recovered COVID-19 patients [14], [15]. Furthermore, the B1.617 variant that was detected in India has been spreading quickly, replacing the B.1.1.7 variant of England as the most abundant strain. [16], [17]. This variant exhibits L452R and E484Q substitutions, in addition to K417N and E484K, which also change the antigenicity and decrease the neutralization susceptibility to sera of infected or vaccinated individuals [18]. Thus, there is a concern as to whether the currently approved vaccines are effective against these SARS-CoV-2 variants.

2. Approved vaccines

2.1. mRNA vaccines

mRNA vaccines have been approved in many countries for emergency use in response to the COVID-19 pandemic, and their efficacy has been confirmed in humans. Therefore, such nucleic acid vaccines are becoming recognized as the mainstay of next-generation vaccines. mRNA vaccines are known to induce a highly effective humoral and cellular immune response because transfected mRNAs express antigen proteins in vivo, and antigen-presenting cells capture the synthesized antigens and present them to CD4+ helper T cells via MHC class II or to CD8+ cytotoxic T cells via MHC class I. Delivery of mRNAs to the cytoplasm of cells for protein expression has been difficult due to their instability. However, introducing several chemical modifications in the nucleotides used for their synthesis has been shown to improve stability and decrease the innate immune response, leading to higher levels of antigen expression [19]. Additionally, encapsulation of RNA within lipid nano particles (LNPs) improves the transfection efficacy and protects RNA from degradation during delivery [20].

Moderna Inc., a pioneering mRNA biotechnology company, started the first clinical trial for a SARS-CoV-2 vaccine in March 2020, and the vaccine’s efficacy was reported to be 94.1% based on a phase III trial [21]. BNT162b2, another mRNA vaccine developed by BioNTech SE, in collaboration with Pfizer Inc., showed 95% efficacy in a phase III clinical trial [22]. These two mRNA vaccines have been approved and are being administered in many countries (Table 1 ).

Table 1.

Approved vaccines.

Developers Efficacy Modality Countries where approved References
Pfizer Inc.
BioNTech SE		 95% mRNA USA, E.U., Canada
Japan and other countries		 [78], [79]
Moderna, Inc 94.1% mRNA USA, E.U., Canada
Japan and other countries		 [80], [81]
AstraZeneca plc 70% Adenovirus vector India, E.U., U.K., Japan and other countries [82]
Johnson & Johnson 66.3% Adenovirus vector USA., E.U
and other countries		 [83]
The Gamaleya Center 92%* Adenovirus vector Russia, Argentina
and other countries		 [84]
CanSino Biologics Inc’s 65.7%* Adenovirus vector China, Mexico
and other countries		 [85]
Sinopharm Group Co., Ltd. 79%* Inactivated virus China
and other countries		 [86]
Sinovac Biotech Ltd. 50% Inactivated virus China
and other countries		 [87]
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*These efficacies were reported on the REUTERS website.

So far, more than three hundred million mRNA vaccine-doses have been inoculated in the Unites States of America only, and their safety has been confirmed [23]. In addition to their efficacy as vaccines, they also possess an advantage in terms of their developmental process. Even if changes in the sequence information of the antigen encoded by the mRNA vaccines are required, non-clinical studies and clinical trials can be executed quickly, because they have been established as a solid vaccine platform. Therefore, mRNA vaccines can be implemented as a first line of defense against emerging infectious diseases in the future.

Although the mRNA vaccines have been demonstrated to be highly efficacious in clinical trials and large-scale inoculations, there are still some concerns, mainly over adverse effects. It has been reported that 58.89% of mRNA-vaccinated healthcare workers experienced fatigue, and 21.99% had fever. These adverse effects may lead to an increase in vaccine hesitancy [24]. Another serious concern related to mRNA vaccines is their specific storage requirements. BioNTech SE and Moderna Inc. guarantee their vaccines’ effectiveness when stored at −80˚C or −30˚C, respectively. Therefore, dedicated freezers are necessary prior to the implementation of a large-scale mRNA vaccination program, in addition to adequate means of transport under the same conditions. Although this does not constitute a major concern in large, wealthy cities, fulfilling these requirements is difficult in rural and less populated areas, and in developing countries. Therefore, it may be difficult to control SARS-CoV-2 infection on a global scale by mRNA vaccination only.

2.2. Adenoviral vectored vaccines

Recombinant viruses are constructed by inserting the coding sequence of an antigen into a viral genome, or by replacing a part of it. Upon infection, the antigen’s coding sequence can be delivered to the cytoplasm or the nucleus of the infected host cell, leading to expression. Adenoviruses are non-enveloped double-stranded DNA viruses, some types of which infect humans and may cause various symptoms such as common cold, pneumonia, encephalitis, or gastroenteritis. Adenoviruses are commonly considered backbone vectors for gene therapy. The deletion of essential genes for replication, such as E2A and DNA polymerase, creates replication-incompetent strains [25], [26], [27] that have already been used in clinical trials. For example, recombinant adenovirus-p53 has been approved and used against human cancers in China [28].

A number of replication-incompetent adenovirus-based SARS-CoV-2 vaccines have been developed and are under evaluation worldwide [29], [30], [31]. Adenovirus vectored vaccines from AstraZeneca Plc, Johnson & Johnson and Gamaleya, and CanSino Biologics were approved and used in clinical settings. These vaccines were reported to induce robust humoral and cellular immune responses, similar to those reported for mRNA vaccines [32]. Therefore, this type of vaccine may be effective against new SARS-CoV-2 variants such as those isolated in India, Brazil, South Africa, and UK. Another advantage this vaccine modality has over mRNA vaccines is its stability, which makes it easier to handle and store.

On the other hand, there are serious concerns about the adverse effects related to adenovirus vectored vaccines. For example, thrombosis was reported after ChAdOx1 nCov-19 vaccination in a range from 1 case per 26,000 to 1 case per 127,000 doses [33]. The mechanism of this effect remains unknown, but some hypotheses were proposed that the vaccination induced platelet-activating antibodies against platelet factor 4, causing symptoms resembling autoimmune heparin-induced thrombocytopenia. Additionally, it was suggested that the transcription of S protein variants enabled alternative splicing events, giving rise to C-terminal truncated soluble forms with the capacity to bind to ACE2-expressing endothelial cells in blood vessels, triggering the development of severe side effects [34], [35]. The European Medicines Agency has already registered thrombosis as a serious disorder, and Denmark has stopped vaccinating with adenovirus vectored vaccines. Additionally, there is another concern that the efficacy might be impaired by pre-existing immunity against other adenoviruses [36]. To avoid this problem, various adenoviruses, such as chimpanzee adenoviruses, have been used for vaccine development. However, people immunized with these vaccines may generate antibodies targeting the vector, thus reducing the efficacy of additional or boosting inoculations.

2.3. Inactivated vaccines

Viruses can be inactivated using chemical reagents, such as formalin and beta-propiolactone, without significantly affecting their antigenicity. Thus, whole virus particles or parts of the virus can be used for vaccines. Aluminum hydroxide adjuvants are commonly added to enhance the immune response induced by this type of vaccine, such as those for influenza virus, Japanese encephalitis, and poliovirus, which are controlled by neutralizing antibodies. Inactivated vaccines for these viruses have been used for a long time in several countries, and are considered to be highly safe [37].

An inactivated SARS-CoV-2 vaccine was first reported in July 2020 [38]. Gao et al. inactivated the virus with beta-propiolactone, and the vaccine candidate was evaluated in mouse, rat, and non-human primate models. This vaccine induced anti-S and anti-RBD antibodies, and the serum from immunized animals showed neutralizing activity. To date, four SARS-CoV-2 inactivated vaccines (Sinopharm, Sinovac, Sinopharm-Wuhan, and Bharat Biotech) have been approved and are being used in China, U.A.E, and India. These inactivated vaccines are treated with β-propiolactone, which damages the genome but not the proteins, so the particles of these vaccines are like the authentic viruses. This similarity may be effective for the induction of highly reactive antibodies, but the lower stability of the unfixed proteins might be a disadvantage over the formalin-treated inactivated vaccines.

In the development of SARS-CoV-2 vaccines, the S protein, especially the RBD, has been used for recombinant protein-based vaccine production. Taking into account the mechanism for SARS-CoV-2 entry into the host, various recombinant protein vaccine candidates have been generated by substituting amino acids or modifying cleavage sites to stabilize the trimeric structure of the S protein [39], [40].

Variants containing E484K or L452R substitutions in the RBD have been reported to be resistant to neutralization by sera from recovered COVID-19 patients [41], [42]. The immune response induced by inactivated vaccines may not be fully effective against the new variants with mutations in the RBD due to their altered antigenicity. Optimization of inactivated SARS-CoV-2 vaccines is therefore required to increase the efficacy against the variants. For example, it may be necessary to update the vaccine seed viruses against several variants every year, or to make a multivalent vaccine. Alternatively, it may be more effective to induce cellular immunity because CD4+ and CD8+T cell responses are known to be critical for recovery from SARS-CoV-2 infection [43], [44]. It was reported that a recombinant protein-based varicella zoster vaccine with AS01B adjuvant, induced cellular immunity [45]. So, by selecting appropriate adjuvants, it may also be possible to develop an inactivated vaccine against SARS-CoV-2 with broad efficacy against mutant strains.

3. Live attenuated vaccines

Known live attenuated vaccines include those against the measles virus, rubella virus, varicella zoster virus, and influenza virus. The strains used for these vaccines were attenuated mainly through adaptation to cold culture conditions, or through non-human animals [46], [47], resulting in viruses with slower proliferation rates in the human body, compared to the wild type virus strains. Regardless of their slow replication, they can induce a strong immune response. For example, the vOka strain of the varicella zoster virus is an example of a live attenuated vaccine obtained from passages in guinea pig embryonic fibroblasts [48]. Furthermore, the influenza virus strains Ann Arbor 60 and 66, were isolated by the passaging of the wild type virus at 25 °C. These strains are used as master donor viruses for live attenuated intranasal influenza vaccines. They can replicate more slowly than the wild type strain at 37 °C and cannot proliferate at 39 °C [49], [50], [51], [52].

To generate a candidate for a SARS-CoV-2 live attenuated vaccine, we isolated temperature-sensitive (TS) mutants from a Japanese clinical isolate, which could replicate at low temperatures (32 °C or 34 °C) but showed impaired proliferation at 37 °C [53]. This phenotype is similar to that of a live attenuated influenza vaccine strain used in clinical settings. Importantly, these TS mutants showed lower pathogenicity than the wild type parent strain in Syrian hamsters. We detected a similar amount of virus in nasal wash specimens from TS- or wild type-infected hamsters, but the virus titer was significantly lower in the lungs of TS-infected hamsters than in those of wild type-infected hamsters. Additionally, TS-infected hamsters generated sufficient neutralizing antibodies to protect them from re-infection with the wild-type virus. Whole genome sequencing of these mutants and analysis of revertant strains suggested that mutations in the nsp3 and nsp14 genes were responsible for the TS phenotype. The mutations in nsp14 were unique ones that, to our knowledge, have not been reported to be associated with a TS phenotype. In contrast, mutations in the nsp3 gene were reported to be responsible for the TS phenotype in mouse hepatitis virus, a coronavirus that infects mice [54]. Seo et al. obtained a cold-adapted SARS-CoV-2 mutant by passaging at cold temperatures [55]. This cold-adapted mutant did not show a well-defined temperature sensitivity, but induced protective immunity in hACE2 transgenic mice and showed lower pathogenicity compared to the wild type virus. Recently, codon de-optimization has been used as a tool to attenuate viruses [56], [57]. One such strain of SARS-CoV-2 is being evaluated in a phase I clinical trial [58].

Live attenuated SARS-CoV-2 vaccine candidates have different characteristics (Fig. 2 ). SARS-CoV-2 wild-type strains spread through droplets and replicate in the upper and lower respiratory tracts and in the lungs. In contrast, cold-adapted and TS mutants cannot do so [53]. Codon de-optimized virus strains proliferate more slowly than the wild-type strain in the human body and in vitro [57]. CODAGENIX Inc. has been constructing and evaluating codon de-optimized SARS-CoV-2 strain [59]. It is considered that these low proliferation rates contribute to the attenuated phenotype, but induce robust humoral and cellular immune responses. The currently used mRNA vaccines and adenovirus vectored vaccines encode only the spike protein, therefore limiting the immune response against only this viral antigen. However, live attenuated vaccines can induce immunity to several viral antigens, enhancing the chances of protection. For example, it was reported that an adenovirus vectored vaccine coding for the nucleocapsid protein was effective in mice and hamsters, suggesting that T-cell responses to this protein might also contribute to protect from infection [60]. The immune response against a variety of antigens generated by live attenuated vaccines may be an advantage over the current mRNA and adenovirus vectored vaccines.

Fig. 2.

Fig. 2

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Live attenuated SARS-CoV-2 vaccine candidates. Cold-adapted mutants replicate more slowly in the lower respiratory tract and lungs, compared to the wild type strain. Temperature-sensitive mutants cannot replicate at these locations. Codon de-optimized mutants show lower proliferation rates than the wild type strain, at any location.

Additionally, intranasal administration of live attenuated SARS-CoV-2 strains may stimulate the production of IgA, which is capable of preventing infection even by variant strains. The live attenuated influenza virus vaccine, an intranasally-administered, cold-adapted strain, induces IgA secretion and CD8+ T cell response [61], [62]. The secreted IgA contributes to cross-protection against different strains of the influenza virus [63]. One study reported that systemic neutralizing antibodies, passively administered or induced by vaccination, could not protect the nasal cavity from SARS-CoV-2 infection [64]. In contrast, mucosal IgA secretion has been reported to enhance SARS-CoV-2 neutralization [65]. Therefore, IgA induction by live attenuated vaccine candidates may contribute to protection against SARS-CoV-2 variants.

Although live attenuated vaccines are among one of the most powerful vaccine modalities, there are several problems related to their use. The most serious problem is that there is a chance of the viruses regaining their toxicity due to mutations after vaccination. A possible solution to this problem is to combine multiple responsible mutations. We have found mutations in different genes, such as nsp3 and nsp14, to be responsible for the temperature sensitivity. Several reverse genetics methods for SARS-CoV-2 have been reported, such as BAC DNA and CPER methods [66], [67]. Using these methods, it is possible to construct strains with various mutations, and thus maintain live attenuation, even when one responsible mutation is replaced by the wild type sequence.

In addition, adverse reactions due to the proliferation of the live attenuated vaccine strains in the nasal cavity should be evaluated. SARS-CoV-2 infection has been associated with the induction of cytokine storm and thrombosis [68], [69]. Moreover, olfactory dysfunction has been reported as a symptom and sequela of COVID-19, although the detailed mechanism underlying it has not yet been investigated [3]. The temperature-sensitive strains that we isolated were able to proliferate in the nasal cavity as the wild-type strain, thereby potentially disrupting the epithelial tissues. Therefore, its effects need to be evaluated in detail.

4. Discussion

Smallpox is one of the most harmful infectious diseases known to affect humans [70]. Jenner isolated a less pathogenic poxvirus and revealed that infection with this virus prevented the development of smallpox [71]. This was the first live attenuated vaccine, and the smallpox virus was eradicated because the vaccine was highly effective and easily preserved, even with the resources available at the time. Similarly, the number of poliovirus cases has decreased by over 99% since the late 1980 s [72], thanks to the use of vaccines. The orally administered vaccine against poliovirus is another live attenuated vaccine used to further reduce global polio case counts after the initial implementation of a policy to use an inactivated vaccine against poliovirus in the 1950 s [73], [74].

Although the live attenuated oral polio vaccine is still used for the global poliovirus eradication program in some countries, it has been eventually replaced by the inactivated vaccine in developed countries. In countries where the live attenuated vaccine is still in use, its drawbacks have become more evident as the number of infected people decreases. The live attenuated virus in the oral polio vaccine is able to replicate in the subject, and thus mutate, giving rise to vaccine-derived polioviruses (VDPV) that can reacquire neurovirulence and cause vaccine-associated paralytic poliomyelitis (PAPP). Although this rarely occurs, this is a serious adverse event and the number of reported cases of VDPV causing PAPP has recently caught the attention of the healthcare system. In order to avoid the occurrence of pathogenic VDPV, next-generation live attenuated viruses with safer and more stable genetic designs have been developed, and their practical implementation is expected [75].

For developing live attenuated SARS-CoV-2 vaccines, we also need to take into account the same issues that cause VDPV. For example, the introduction of multiple mutations, which are responsible for the attenuation mentioned above, is one of the methods to decrease the risk of reversion to a virulent phenotype. In addition, several factors involved in pathogenicity have been identified and described. For example, ORF8 has been reported to be a virulence factor associated with inflammation, and the furin cleavage site of the spike protein is important for virulence as well [76], [77]. The combination of these mutations may contribute to develop safer live attenuated vaccines.

New technologies have been developed and improved since the development of these vaccines, and a wide range of vaccine modalities are currently available. A comprehensive understanding of each type can help policymakers decide which are the most appropriate for a specific stage in a pandemic, such as that of COVID-19 (Fig. 3 ). For example, nucleic acid and recombinant viral vectored vaccines, which are based on an antigen’s coding sequence, can be rapidly developed owing to advances in sequencing technologies. These vaccines should be adequate for the early stages of the pandemic, in combination with immediate social measures, such as lockdowns and containment of infected populations, to minimize or prevent further spread. Live attenuated vaccines take more time to develop because they rely on the amplification and weakening of the pathogenic attributes of the original virus. However, they can induce an immune response similar to that induced by a natural infection targeting several viral antigens, and are thus presumably more effective than the other vaccine types, although further studies are needed to provide the necessary evidence. Therefore, live attenuated vaccines are expected to be one of the most effective vaccines against different variants that may arise. Finally, although inactivated vaccines take longer to produce and may be less effective against variants, they may be a viable vaccine option for boosting immunizations due to their milder side effects, as the one for the seasonal influenza virus.

Fig. 3.

Fig. 3

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Differential vaccine selection for specific pandemic stages. Vaccine characteristics that are optimal for specific pandemic stages are described. Rapidly developed vaccines, such as nucleic acid and recombinant virus vaccines, can impede the rise in cases of infection in the early stages of a pandemic. Humoral and cellular immunity targeting several antigens induced by live attenuated vaccines should be more effective during periods of high morbidity and mortality. After most of the population is immunized, highly safe vaccines, like recombinant protein-based vaccines, would be more appropriate to be administered as boosters.

Overall, a strategy comprising the use of different types of vaccines, depending on the stage of a pandemic outbreak, could help improve control measures against the spread and survival of a pandemic-causing virus in the human population. COVID-19 has put humanity in an unprecedented situation. The acquired information and knowledge gained by testing different vaccine modalities in the COVID-19 pandemic will pave the way for improved and better strategies to combat future pandemics.

mRNAs have demonstrated to be highly effective, but limitations such as the requirement of a particularly strict cold-chain for their preservation, make it difficult to control SARS-CoV-2 infection on a global scale, relying mainly on this vaccine modality. Live attenuated vaccines using strains like the ones we isolated, would add an important modality to complement current ones.

Declaration of Competing Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgements

We appreciate the assistance from Mitsuyo Kosaka (BIKEN). We thank Paola Miyazato (BIKEN) for reviewing the manuscript. We would like to thank Editage (www.editage.com) for English language editing.

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