- 1Division of Infectious Diseases and Immunology, Department of Pediatrics, Cedars-Sinai Medical Center, Los Angeles, CA, United States
- 2Department of Biomedical Sciences, Cedars-Sinai Medical Center, Los Angeles, CA, United States
Countries worldwide have confirmed a staggering number of COVID-19 cases, and it is now clear that no country is immune to the SARS-CoV-2 infection. Resource-poor countries with weaker health systems are struggling with epidemics of their own and are now in a more uncertain situation with this rapidly spreading infection. Frontline healthcare workers are succumbing to the infection in their efforts to save lives. There is an urgency to develop treatments for COVID-19, yet there is limited clinical data on the efficacy of potential drug treatments. Countries worldwide implemented a stay-at-home order to “flatten the curve” and relieve the pressure on the health system, but it is uncertain how this will unfold after the economy reopens. Trehalose, a natural glucose disaccharide, is known to impair viral function through the autophagy system. Here, we propose trehalose as a potential preventative treatment for SARS-CoV-2 infection and transmission.
Introduction
The pandemic coronavirus disease 2019 (COVID-19), caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has rapidly expanded around the globe. As of June 5, 2020, the World Health Organization (WHO) has confirmed 6,515,796 cases and reported 387,298 deaths worldwide due to COVID-19. The currently available treatments aim to control symptoms, guarantee tissue perfusion, and avoid multiple organ dysfunction syndrome. This is accomplished through the use of oxygen therapy, mechanical ventilation in respiratory failure cases, and hemodynamic support for managing septic shock (1). Unfortunately, advanced healthcare systems are struggling to keep up with the influx of COVID-19 patients in need of treatment and hospitalization. An increasing concern is the detrimental impact this virus could have in countries with weaker health systems and vulnerable populations. At this time, there is no known U.S. Food and Drug Administration (FDA)-approved treatment that can effectively control SARS-CoV-2 infection and transmission. This review aims to propose trehalose as a prospective prophylactic treatment for COVID-19 containment.
Trehalose (α,α-trehalose), a naturally occurring sugar, is a non-reducing disaccharide with two glucose molecules that functions as an energy source in many organisms. Trehalose is present in various organisms, such as plants, algae, fungi, yeast, bacteria, insects, and other invertebrates. In 2000, the U.S. FDA gave trehalose a generally recognized as safe (GRAS) status (2). Because of its protectant effects against freezing and dehydration, trehalose has become an attractive ingredient in food, health, and pharmaceutical products (2). The optimized production process of trehalose makes it accessible and affordable. Although humans cannot synthesize trehalose, the small intestine can hydrolyze trehalose into two D-glucose molecules by the specific enzyme trehalase. Since the hydrolyzing activity of trehalase is ordinarily low, it causes only a mild increase in blood glucose and insulin levels (3, 4). In contrast, sucrose, a disaccharide composed of glucose and fructose, immediately increases both blood glucose and insulin levels after oral intake (5). On the other hand, unhydrolyzed trehalose can be rapidly absorbed in the bloodstream after oral administration to mice, rats, and macaques, which peaked at ~15 min to 1 h post-dose and continued to be detectable in macaques up to 12 h post-dose (6, 7). The pharmacokinetic data on non-human primates provide a promising incentive for human response to trehalose. In human subjects, the daily intake of 10 g/day trehalose for 12 weeks improved glucose tolerance, decreased the progression to insulin resistance, and decreased systolic blood pressure. Therefore, trehalose can induce systemic benefits that are not associated with an increase in glucose levels and insulin resistance (8). Altogether, these studies support the feasibility and safety of trehalose treatment for the prevention of SARS-CoV-2 infection and transmission.
Since 1925, several studies aimed to understand the chemical and biological properties of trehalose. Trehalose has received attention for its protective properties in neurodegenerative and metabolic diseases (9–12). The protective effects of trehalose were considered to be due to its chemical chaperone properties (13). However, in 2007, trehalose was identified as an autophagy inducer (14). Autophagy, a highly conserved intracellular degradation process, is regulated by the major control complex mammalian target of rapamycin (mTOR) (15, 16). Interestingly, trehalose induces autophagy independent of mTOR (14). In mammalian cell cultures, trehalose treatment can enhance the clearance of denatured huntingtin and denatured α-synuclein, both autophagy substrates associated with Huntington's and Parkinson's diseases, respectively (14). The trehalose effects are dependent on the accumulation of microtubule-associated protein 1A/1B-light chain 3 (LC3) II, which is essential for the formation of autophagosomes from autophagy-related 5 (ATG5) protein complex anchored phagophores (14). However, these are independent of mTOR inhibition, since trehalose does not reduce the phosphorylation levels at specific sites on mTOR substrates, which are reduced by the mTOR inhibitor rapamycin (14). Later, the transcription factor EB (TFEB) was identified to be the primary lysosomal biogenesis regulator, as it induces the expression of several essential genes for this phenomenon (17). When trehalose emerged as an autophagy inducer, some research groups were compelled to use trehalose to demonstrate the role of TFEB. It was observed that trehalose reduced the activity of AKT (protein kinase B), which phosphorylates TFEB (S467A), thus enabling the translocation of TFEB to the nucleus independently of the TFEB inhibitor, mTOR (18). Furthermore, trehalose can activate TFEB and could subsequently promote cross-presentation (18, 19).
In maternal diabetes, repressed autophagy in developing neuroepithelium cells leads to neural tube defects (NTDs) in the developing fetus (20). Trehalose administration restored this autophagy defect and prevented the hyperglycemia-induced NTDs (21). In another in vitro study, trehalose promoted LC3 autophagosome formation in high glucose cultured cells, higher clearance of ubiquitin-binding protein p62, neural stem cell differentiation, mitophagy, and reticulophagy (22). Sanfilippo syndrome or mucopolysaccharidosis (MPS) type III is a neurodegenerative lysosomal storage disorder. A mouse model of MSP III, treated with trehalose, showed neurological improvements associated with the clearance of autophagic vacuoles in neuronal and glial cells, as well as the activation of the TFEB transcription network (23). In a model of myocardial infarction cardiac remodeling, the use of trehalose resulted in an improved outcome in wild-type mice (24). On the other hand, the trehalose administration to mice genetically deficient in Beclin-1, an important protein in autophagy regulation, had no protection (24). Trehalose also increased LC3 and p62 clearance. Conjointly, these results confirmed that trehalose-induced autophagy elicited cardioprotective effects (24). Trehalose administration also inhibited and attenuated high-fat diet-induced atherosclerosis in mice and rabbits, respectively (25–27). Mashhad University of Medical Sciences is now sponsoring an interventional clinical trial to test the beneficial effects of intravenous administration of trehalose (15 g per week for 12 weeks) as an anti-inflammatory agent against vascular inflammation and atherosclerosis (clinicalTrials.gov, NCT 03700424). Peripheral arterial disease (PAD) patients are associated with vascular complications and increased platelet activation. Reduced glucose oxidation, oxidative stress, and autophagy are factors that contribute to reduced blood flow in PAD patients (28). A clinical trial approaching the effects of trehalose on endothelial function, oxidative stress, platelet function, and autophagy in PAD patients is currently active (clinicalTrials.gov, NCT 04061070).
In the context of infectious diseases, autophagy induction is critical for both innate and adaptative immune response development. Although some microorganisms can evade autophagy and even use it as a survival and propagation strategy, autophagy is an effective way to control most of intracellular infections (29). The human immunodeficiency virus (HIV), the pathogen well-known for evading immune responses, is also known for its effects in the autophagy flux (30). HIV increases the number of autophagosomes and impairs autophagosome maturation, thus blocking autophagosome-lysosome fusion (31). Despite the fact that CD4+ T lymphocytes are the predominant target for HIV infection, it is the HIV-infected innate immune cells that make organisms highly susceptible to opportunistic microorganisms, such as non-pathogenic mycobacteria (32). Although autophagic inhibition by 3MA or Beclin-1 siRNA decreased HIV virus production in the Jurkat cell line (31), a recent study has shown that trehalose can restore autophagy impaired by HIV infection in peripheral blood mononuclear cells (PBMCs) in vitro (Table 1) (32). In addition, trehalose post-treatment reduced HIV load in PBMCs from HIV infected patients (32). Antiviral effects of trehalose on other disease-related viruses, such as human cytomegalovirus (HCMV) and varicella-zoster virus (VZV), have been demonstrated in vitro (Table 1). Its mechanism of action lies in its ability to induce autophagy significantly. Trehalose inhibited HCMV viral gene expression and viral spread in multiple cell types (34). Both pre- and post-treatments with trehalose reduced HCMV and VZV replication (35). Interestingly, Clark et al. (2018) reported in HCMV infected cells that trehalose alters the intra-multivesicular bodies (MVBs) virion morphology and redirects the trafficking of viral vacuole maturation through downregulation of Ras-like GTPase 11 (Rab11), a protein involved in the control of endosomal trafficking (Figure 1) (33). In primary mouse cortical cultures infected with the West Nile virus (WNV), trehalose induced robust activation of autophagy indicated by an increase in protein expression of LC3-II; however, activation of autophagy had no significant effect on WNV growth (37) (Table 1). Similar autophagy activation was observed in human primary airway epithelial cells treated with trehalose, but autophagy induction impaired antiviral function against human rhinovirus (HRV) infection (36) (Table 1).
Figure 1. SARS-CoV2 replication and inhibition by trehalose. SARS-CoV-2 gains entry via membrane fusion by binding angiotensin-converting enzyme 2 (ACE2) in the target cell. The virus is then internalized and transported through endosomal compartments. The viral genome is released and used by the host ribosome to synthesize viral RNA polymerase, thus replicating the viral RNA subgenomes. Viral structural proteins are synthesized and anchored into the endoplasmic reticulum (ER). Once the virion is assembled in the ER-Golgi intermediate compartment (ERGIC) and transferred to the autophagosome, it may be released by exocytosis from the amphisome. Coronavirus nonstructural protein 6 (nsp6) and nsp3 promote autophagosome formation but prevent autophagosome-lysosome fusion. (1) Trehalose may promote amphisome-lysosome fusion for virion degradation after the trafficking of viral double-membrane vesicles. (2) Trehalose can also activate transcription factor EB (TFEB) and promote lysosome biogenesis.
The beta-coronaviruses, severe acute respiratory syndrome coronavirus (SARS-CoV) and Middle East respiratory syndrome coronavirus (MERS-CoV), encode viral proteins that impair autophagosome-lysosome fusion, such as the membrane-associated papain-like protease (PLp-TM) (38). Also, coronaviruses replicate in LC3-mediated autophagosome-like double-membrane vesicles in an ATG7-independent manner (39, 40). Since various viruses hijack the autophagic machinery to the benefit of viral replication and virion maturation, regulating cellular autophagy with autophagy modulators such as chloroquine (CQ) or trehalose is of great importance in the treatment of viral diseases (41). In regard to this, coronaviruses express non-structural protein 6 (nsp6) and nsp3 that promote autophagosome formation but prevent autophagosome-lysosome fusion, indicating that autophagy flux induction by trehalose could be beneficial for potential COVID-19 containment (Figure 1) (38, 42). The angiotensin-converting enzyme 2 (ACE2) plays an essential role as a SARS-CoVs receptor to mediate viral entry through endocytosis (Figure 1) (43). Of note, the recently described LC3-associated endocytosis (LANDO), that occurs with the conjugation of LC3 to Rab5+ clathrin+ endosomes containing β-amyloid, is another newly reported important mechanism to clear the exogenous antigens in microglial cells (44). LANDO may be another underestimated LC3-vesicle with the potential for coronaviral replication, which can explain the LC3-dependent and ATG7-independent coronaviral replication observed previously. However, the dichotomy lies in that both LC3-phagosome and LC3-endosome are single-membrane vesicles, while coronaviral replication would occur in double-membrane vesicles (40). So far, there is no known effect of trehalose on LANDO, yet it is clear that trehalose displays autophagy-dependent antiviral activities against different types of viruses.
COVID-19 Therapeutic Strategies, Developments and Challenges
The major strategies to slow down the spread of COVID-19, thus reducing the strenuous demands on healthcare, were to isolate those infected in their household and promote social distancing (45, 46). However, in light of the continuously increasing cases, “stay-at-home” is the measure that many countries are adhering to in order to suppress the spread. New COVID-19 cases are accelerating every minute, and experts do not know how long it will take before this pandemic is under control. Meanwhile, the loss of commerce, trade, tourism, and global supply chains has economic experts grappling on the detrimental effects this virus will have on the world economy for years to come. The global economy predicted a $280 billion loss in the first quarter of the year without urgent global action (47). The United Nations Conference on Trade and Development (UNCTAD) predicts a preliminary $2 trillion shortfall in the global economy (48).
In response to the COVID-19 pandemic, the U.S. FDA continues its work to ensure safe and effective treatments. Potential therapies that are being investigated and developed for the treatment and management of COVID-19 now comprise of numerous antiviral agents, immunotherapies, and vaccines (49). The antiviral nucleotide analog agent remdesivir can inhibit the replication of SARS-CoV and MERS-CoV in multiple in vitro systems, such as primary human airway epithelial cell cultures (50, 51). Remdesivir has shown promising results in rhesus macaques infected with SARS-CoV-2, and the Adaptive COVID-19 Treatment Trial for remdesivir, sponsored by the National Institute of Allergy and Infectious Disease, has been completed (clinicalTrials.gov, NCT 04280705) (52). Based on this trial and the Gilead-sponsored trial (clinicalTrials.gov, NCT 04292899), the U.S. FDA has authorized emergency use of remdesivir for the treatment of COVID-19 (53). Lopinavir/Ritonavir, an HIV protease inhibitor, was found to inhibit SARS-CoV-2 replication in Vero E6 cells (54). Hospitalized COVID-19 patients in Wuhan, China, were treated with the combinational therapy of lopinavir/ritonavir. However, the effect was moderate, and 13% of the patients had to be removed early in the treatment due to adverse side effects (55). New triple antiviral therapy combination of interferon beta-1b, lopinavir-ritonavir, and ribavirin in the treatment of mild to moderate COVID-19 patients was safe and superior to lopinavir-ritonavir treatment alone in alleviating symptoms, shortening the duration of viral shedding, and hospital stay. However, the lack of a placebo group was one of several limitations to this trial (56).
CQ and its structural analog hydroxychloroquine (HCQ), FDA approved drugs used as antimalarial agents with anti-inflammatory and immunomodulatory activities, are another investigational antiviral therapy drugs being redirected and evaluated for COVID-19 treatment. In vitro studies have shown a significant activity of CQ against SARS-CoV-2, SARS-CoV-1, and MERS-CoV (49, 57). CQ is a lysosomotropic agent and inhibits both endosomal and autophagosomal acidification, thereby, impairing the functionality of fused endosomes-lysosomes as well as fused autophagosome-lysosome (autolysosome) (58–60). CQ inhibits coronaviral RNA entry into the cytosol, which is required for viral replication after ACE2-mediated endocytosis (Figure 1) (61). Pre-clinical rationale and evidence moved CQ into the clinical trial phase for the treatment of COVID-19. The FDA approved the emergency use of CQ and HCQ for COVID-19 patients (62). Unfortunately, there is still no large randomized trial that proves these drugs to be effective against the disease. Interestingly, azithromycin and erythromycin, macrolide antibiotics, have specific antiviral effects that can inhibit viral internalization. Oseltamivir-azithromycin combination therapy has been used in randomized clinical trials for the treatment of influenza (63). The French Ministry of Health approved an HCQ-azithromycin open-labeled non-randomized clinical trial on SARS-CoV-2 infected patients and showed promising results in the small sample size study (64). Unfortunately, it has been well-documented that arrhythmias are a potential risk in COVID-19 patients treated with CQ-azithromycin (65, 66).
Remdesivir, lopinavir/ritonavir, CQ, and azithromycin have shown to be effective in inhibiting SARS-CoV-2 replication in vitro. However, the efficacy diminishes when symptomatic patients are treated 1 week after the disease's onset. At this point, the patient may have already transitioned from viral expansion to the inflammatory phase leading to a cytokine storm (67). For instance, during influenza infection, the viral shedding phase peaks 2–3 days after infection (68). A meta-analysis of randomized controlled trials of oseltamivir (Tamiflu) indicates that early treatment of the infection accelerated clinical symptom alleviation and reduced the risks of lower respiratory tract complications, suggesting that antiviral drug treatments have to be timed appropriately (69, 70). Antiviral drug monotherapy might not be sufficient for severe patients with COVID-19, and supplementation with anti-inflammatory drugs would be necessary as a combination therapy (71). Sanofi and Regeneron have announced a Phase 2/3 trial of interleukin-6 (IL-6) inhibitor sarilumab (Kevzara) to ameliorate tissue damage in the lung caused by a “cytokine storm” in patients with COVID-19 infection (clinicalTrials.gov, NCT 04315298) and Swedish Orphan Biovitrum (SOBI) also started Anakinra (IL-1 receptor antagonist) and Emapalumab (Anti-IFN-γ monoclonal antibody) Phase 2/3 trials to test their efficacy to reduce hyper-inflammation and respiratory distress in patients with COVID-19 infection (clinicalTrials.gov, NCT 04324021). Overall, there are more clinical research trials to be made before any of these drugs become available to the public.
Efforts are also underway for the development of vaccines against SARS-CoV-2. Major COVID-19 vaccines under evaluation are whole virus vaccines (adenovirus-vectored vaccine using AdVac and PER.C6 technology by Janssen), recombinant protein subunit vaccines (recombinant nanoparticle technology by Novavax), and nucleic acid vaccines (mRNA vaccine by Moderna/NIH/CEPI) (72). A vaccine developed in a pandemic paradigm will take months to several years to carry from a developmental stage to commercialization (72–74). Therefore, a faster and more affordable approach to COVID-19 containment is necessary. Because of its antiviral properties, availability, and FDA approval, trehalose merits immediate evaluation as a promising preventative treatment for COVID-19.
• Several non-specific antiviral drugs are undergoing clinical trials in only a few designated hospitals. While the SARS-CoV-2 viral shedding timeline is not well-known, antiviral drugs would be more beneficial if administered during the onset of the disease. More accurate and faster diagnostic tests are still underway, as a timely diagnosis is key to the management of COVID-19 (75).
• There are no medications or clear guidelines for asymptomatic or mildly symptomatic patients that test positive (76, 77). These patients must remain isolated at home, which increases the chances of infecting other family members.
• Socio-economic disadvantaged countries with low-quality medical health care systems will be at a disadvantage compared to the U.S. and some European countries that are conducting the latest strategies against COVID-19 (78, 79). New low-cost strategies are desperately needed.
• Vaccine development has started in several countries, but this would take at least 1 year to be available.
• Asymptomatic patients may be receiving false-negative PCR test results, which causes underestimation of COVID-19 positive cases. Thus, it complicates efforts to prevent the spread of the virus within the community (80).
• Current lockdown measures could limit the spread, but may not be sufficient to stop it completely.
Perspective on Trehalose Treatment for Immediate SARS-CoV-2 Containment
To date, the immediate interventions for SARS-CoV-2 transmission have centered on contact tracing, quarantine, and social distancing. Adaptation of these physical distancing measures to mitigate the pandemic has managed to flatten the curve in some countries (81). Cities worldwide have begun to reopen their economy; however, a second wave of COVID-19 cases and deaths is predicted to begin 2–4 weeks after reopening (82). Post-pandemic transmission dynamics of SARS-CoV-2 project recurrent outbreaks during the wintertime and resurgence of this disease may persist for another 3 years (83). Mathematical modeling of various scenarios with one-time social distancing measures has simulated a resurgence of infection when social distancing measures were lifted (83). Thus, additional methods that circumnavigate enforced social distancing and shutting down the economy are needed. Alternatively, the pathways to herd immunity will require either mass vaccination or natural immunization over time. However, the latter approach suggests that a large portion of the population would succumb to the disease (84). The R0, basic reproductive number, represents the transmissibility of infectious agents in a naive population and can vary depending on transmission dynamics (85). As such, the R0 differs across populations. The R0 of SARS-CoV-2 has been reported to range from 1.4 to 6.49 in recent studies from January 2020 – February 2020 (86). With an R0 of 6.49, the population would require 85% of individuals to have immunity to abate the spread of disease, 1 – 1/R0. It is uncertain how long it will take for different populations to acquire herd immunity due to factors of transmission dynamics, such as demography, cultural influences, contact rates, and population density (87). Therefore, targeting individuals who are considered low-risk could build community protection to protect those that are vulnerable and not immune.
We propose trehalose as a practical and affordable safe treatment for the prevention and containment of COVID-19. Trehalose could potentially affect cellular organelles required for viral replication. We would recommend a large community trial comprising of healthy adults, healthcare workers, asymptomatic, and mild symptomatic COVID-19 patients (Figure 2). The Centers for Disease Control (CDC) has recently reported the transmission of SARS-CoV-2 during the presymptomatic stage of the infection; therefore, trehalose treatment as a prophylactic approach would be advisable (88, 89). Family members of patients testing positive for COVID-19 will be recommended to undergo trehalose treatment and stay at home in self-quarantine, as the secondary attack rate of SARS-CoV-2 transmission within a household is 16.3% (Figure 2) (90). Unlike adults, children have a low observed case rate of COVID-19. Children are mostly asymptomatic, or the symptoms are mild to require medical attention unless an underlying health-compromising condition exists (91, 92). More recently, pediatric hospitals are confirming cases of children suffering from a severe Kawasaki-like disease related to COVID-19 (93). This is a significant concern when countries are trying to reopen their education system, and the long term effects of SARS-CoV-2 infection are still unknown in children. Clinical studies on the oral supplementation of trehalose (100 g/day) for the improvement of vascular function has been carried out in healthy adults aged 50–77 years (94). Although trehalose has proven to be safe, it would be inappropriate or approached with caution when evaluating the efficacy of trehalose in seniors and the elderly, as a large number of this population suffer from chronic diseases. By treating healthy adults with trehalose, population-level resistance to the infection will block the chain of transmission. As a result of this treatment, the risk of transmission to seniors and medically compromised individuals will be drastically reduced as they are indirectly protected from the infection (Figure 2) (95). Furthermore, trehalose can activate TFEB and could subsequently promote cross-presentation (18, 19). Therefore, trehalose could have another benefit to accelerate herd immunity against SARS-CoV-2, especially in the phase of encountering a second wave of COVID-19 cases. We believe that this treatment strategy can be more beneficial to countries that do not have the resources to conduct antiviral clinical trials.
Figure 2. Trehalose treatment for fast SARS-CoV-2 containment. Treating healthy adults and asymptomatic patients with trehalose would accelerate community viral containment.
Potential Precautions and the Current Limitations for the Development of Trehalose Treatment
It is important to understand that while there is considerable research on trehalose administration in adults, there is still not sufficient data on its safety in children, adults with health-related issues, and the elderly. We have previously reported that trehalose exacerbated acute respiratory distress syndrome (ARDS) “two-hit” murine model (induced by LPS and mechanical ventilation), while other autophagy activations inhibited ARDS (96). Therefore, trehalose treatment would be inappropriate to treat intensive care patients with severe COVID-19, especially those presenting cytokine storm syndrome or ARDS. For inflammatory cytokines, trehalose has been shown to suppress LPS-induced IL-1β and TNF-α secretion in mouse peritoneal macrophages (97). Our experimental in vitro data shows that trehalose pretreatment inhibited LPS induced IL-6 production in macrophages (unpublished). As in the clinical practice guidelines by the infectious diseases society of America on the management of influenza, early treatment with antiviral medications attenuates symptoms and risk complications. In the same way, trehalose could have a more significant benefit as an anti-inflammatory in the initial phase of the SARS-CoV-2 infection. Treating severe COVID-19 patients in the late stage of the disease would not be sufficient. Instead, other emergency FDA approved pharmaceutical interventions would be more effective. While trehalose could provide significant benefits as an antiviral treatment, studies have shown that dietary trehalose may enhance the virulence of Clostridium difficile (98). In vitro studies on the effects of trehalose on SARS-CoV-2 infection still need to be investigated since some type of viruses can highjack the autophagy system and enhance their replication with trehalose treatment (e.g., HRV) (36). Once confirming the effectivity of trehalose, tests in the rhesus macaque model would be ideal for establishing an appropriate starting dose for human clinical trials. The majority of trehalose administration in adults ranges from 4.8 to 10 g/day. Lung alteration of autophagy has been confirmed with the use of 1 g/kg trehalose to mice, which is equivalent to 4.8 g/day for every 60 kgs in humans (96). A diabetes study used 10 g/day (8), while an acute coronary artery clinical trial used 2.1 g/day (clinicalTrials.gov, NCT 03700424). The dose of 30 g has been used for laxative purposes in healthy females (3). An effective dosage of trehalose per body weight for targeting SARS-CoV-2 and pharmacokinetics of trehalose in human blood remains to be determined. Of note, fasting between 16 and 18 h is also known to activate autophagy; however, it is not a good strategy for viral infection as previously reported (99). Thus, we do not recommend fasting as a prophylactic treatment for COVID-19. Rapamycin, a representative mTOR-dependent autophagy activator, has an immunosuppressive adverse effect that may make it inadequate as a prophylactic treatment of SARS-CoV-2 (15).
As SARS-CoV-2 continues to expand globally, it is crucial to gain knowledge and understanding of its impact on disparate communities. The proposed trehalose treatment could potentially protect those unable to seek more costly therapeutics. With COVID-19 studies and trials ongoing indefinitely and economies suffering, more cost-efficient options should be considered for fast containment. The investigation of safer treatments for viral infections should be a continuous priority, as the COVID-19 pandemic will not be the last of its kind. We suggest trehalose for consideration to public health agencies worldwide.
Author Contributions
DM, VB, AG, and KS made substantial contributions to the conception, writing, and editing of this review.
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Acknowledgments
We thank Dr. T. R. Crother (Cedars-Sinai Medical Center, Los Angeles, CA, USA) for writing assistance. Figure 1 was created with BioRender.com. We thank Dr. Patrick A. Howson (Atuka Inc. and Junaxo Inc., Tronto, ON, Canada) for sharing the experience with blood trehalose measurement.
References
1. Cascella M, Rajnik M, Cuomo A, Dulebohn SC, Di Napoli R. Features, Evaluation and Treatment Coronavirus (COVID-19). Treasure Island, FL: StatPearls (2020).
2. Richards AB, Krakowka S, Dexter LB, Schmid H, Wolterbeek AP, Waalkens-Berendsen DH, et al. Trehalose: a review of properties, history of use and human tolerance, and results of multiple safety studies. Food Chem Toxicol. (2002) 40:871–98. doi: 10.1016/S0278-6915(02)00011-X
3. Oku T, Nakamura S. Estimation of intestinal trehalase activity from a laxative threshold of trehalose and lactulose on healthy female subjects. Eur J Clin Nutr. (2000) 54:783–8. doi: 10.1038/sj.ejcn.1601091
4. Yoshizane C, Mizote A, Yamada M, Arai N, Arai S, Maruta K, et al. Glycemic, insulinemic and incretin responses after oral trehalose ingestion in healthy subjects. Nutr J. (2017) 16:9. doi: 10.1186/s12937-017-0233-x
5. Keyhani-Nejad F, Kemper M, Schueler R, Pivovarova O, Rudovich N, Pfeiffer AF. Effects of palatinose and sucrose intake on glucose metabolism and incretin secretion in subjects with Type 2 diabetes. Diabetes Care. (2016) 39:e38–39. doi: 10.2337/dc15-1891
6. Howson PA, Johnston TH, Ravenscroft P, Hill MP, Su J, Brotchie JM, et al. Beneficial effects of trehalose on striatal dopaminergic deficits in rodent and primate models of synucleinopathy in Parkinson's disease. J Pharmacol Exp Ther. (2019) 369:364–74. doi: 10.1124/jpet.118.255695
7. DeBosch BJ, Heitmeier MR, Mayer AL, Higgins CB, Crowley JR, Kraft TE, et al. Trehalose inhibits solute carrier 2A (SLC2A) proteins to induce autophagy and prevent hepatic steatosis. Sci Signal. (2016) 9:ra21. doi: 10.1126/scisignal.aac5472
8. Mizote A, Yamada M, Yoshizane C, Arai N, Maruta K, Arai S, et al. Daily intake of trehalose is effective in the prevention of lifestyle-related diseases in individuals with risk factors for metabolic syndrome. J Nutr Sci Vitaminol. (2016) 62:380–7. doi: 10.3177/jnsv.62.380
9. Tanaka M, Machida Y, Niu S, Ikeda T, Jana NR, Doi H, et al. Trehalose alleviates polyglutamine-mediated pathology in a mouse model of Huntington disease. Nat Med. (2004) 10:148–54. doi: 10.1038/nm985
10. Arora A, Ha C, Park CB. Inhibition of insulin amyloid formation by small stress molecules. FEBS Lett. (2004) 564:121–5. doi: 10.1016/S0014-5793(04)00326-6
11. Davies JE, Sarkar S, Rubinsztein DC. Trehalose reduces aggregate formation and delays pathology in a transgenic mouse model of oculopharyngeal muscular dystrophy. Hum Mol Genet. (2006) 15:23–31. doi: 10.1093/hmg/ddi422
12. Ganea E. Harding JJ. Trehalose and 6-aminohexanoic acid stabilize and renature glucose-6-phosphate dehydrogenase inactivated by glycation and by guanidinium hydrochloride. Biol Chem. (2005) 386:269–78. doi: 10.1515/BC.2005.032
13. Diamant S, Eliahu N, Rosenthal D, Goloubinoff P. Chemical chaperones regulate molecular chaperones in vitro and in cells under combined salt and heat stresses. J Biol Chem. (2001) 276:39586–91. doi: 10.1074/jbc.M103081200
14. Sarkar S, Davies JE, Huang Z, Tunnacliffe A, Rubinsztein DC. Trehalose, a novel mTOR-independent autophagy enhancer, accelerates the clearance of mutant huntingtin and alpha-synuclein. J Biol Chem. (2007) 282:5641–52. doi: 10.1074/jbc.M609532200
15. Saxton RA, Sabatini DM. mTOR signaling in growth, metabolism, and disease. Cell. (2017) 168:960–76. doi: 10.1016/j.cell.2017.02.004
16. Jung CH, Ro SH, Cao J, Otto NM, Kim DH. mTOR regulation of autophagy. FEBS Lett. (2010) 584:1287–95. doi: 10.1016/j.febslet.2010.01.017
17. Sardiello M, Palmieri M, di Ronza A, Medina DL, Valenza M, Gennarino VA, et al. A gene network regulating lysosomal biogenesis and function. Science. (2009) 325:473–7. doi: 10.1126/science.1174447
18. Palmieri M, Pal R, Nelvagal HR, Lotfi P, Stinnett GR, Seymour ML, et al. Sardiello, mTORC1-independent TFEB activation via Akt inhibition promotes cellular clearance in neurodegenerative storage diseases. Nat Commun. (2017) 8:14338. doi: 10.1038/ncomms14338
19. Samie M, Cresswell P. The transcription factor TFEB acts as a molecular switch that regulates exogenous antigen-presentation pathways. Nat Immunol. (2015) 16:729–36. doi: 10.1038/ni.3196
20. Wang F, Xu C, Reece EA, Li X, Wu Y, Harman C, et al. Protein kinase C-alpha suppresses autophagy and induces neural tube defects via miR-129-2 in diabetic pregnancy. Nat Commun. (2017) 8:15182. doi: 10.1038/ncomms15182
21. Xu C, Li X, Wang F, Weng H, Yang P. Trehalose prevents neural tube defects by correcting maternal diabetes-suppressed autophagy and neurogenesis. Am J Physiol Endocrinol Metab. (2013) 305:E667–78. doi: 10.1152/ajpendo.00185.2013
22. Xu C, Chen X, Sheng WB, Yang P. Trehalose restores functional autophagy suppressed by high glucose. Reprod Toxicol. (2019) 85:51–58. doi: 10.1016/j.reprotox.2019.02.005
23. Lotfi P, Tse DY, Di Ronza A, Seymour ML, Martano G, Cooper JD, et al. Trehalose reduces retinal degeneration, neuroinflammation and storage burden caused by a lysosomal hydrolase deficiency. Autophagy. (2018) 14:1419–34. doi: 10.1080/15548627.2018.1474313
24. Sciarretta S, Yee D, Nagarajan N, Bianchi F, Saito T, Valenti V, et al. Trehalose-induced activation of autophagy improves cardiac remodeling after myocardial infarction. J Am Coll Cardiol. (2018) 71:1999–2010. doi: 10.1016/j.jacc.2018.02.066
25. Stachowicz A, Wisniewska A, Kus K, Kiepura A, Gebska A, Gajda M, et al. The influence of trehalose on atherosclerosis and hepatic steatosis in apolipoprotein e knockout mice. Int J Mol Sci. (2019) 20:1552. doi: 10.3390/ijms20071552
26. Sergin I, Evans TD, Zhang X, Bhattacharya S, Stokes CJ, Song E, et al. Exploiting macrophage autophagy-lysosomal biogenesis as a therapy for atherosclerosis. Nat Commun. (2017) 8:15750. doi: 10.1038/ncomms15750
27. Sahebkar A, Hatamipour M, Tabatabaei SA. Trehalose administration attenuates atherosclerosis in rabbits fed a high-fat diet. J Cell Biochem. (2019) 120:9455–9. doi: 10.1002/jcb.28221
28. Krishna SM, Moxon JV, Golledge J. A review of the pathophysiology and potential biomarkers for peripheral artery disease. Int J Mol Sci. (2015) 16:11294–322. doi: 10.3390/ijms160511294
29. Gomes LC, Dikic I. Autophagy in antimicrobial immunity. Mol Cell. (2014) 54:224–33. doi: 10.1016/j.molcel.2014.03.009
30. Kyei GB, Dinkins C, Davis AS, Roberts E, Singh SB, Dong C, et al. Autophagy pathway intersects with HIV-1 biosynthesis and regulates viral yields in macrophages. J Cell Biol. (2009) 186:255–68. doi: 10.1083/jcb.200903070
31. Wang X, Gao Y, Tan J, Devadas K, Ragupathy V, Takeda K, et al. HIV-1 and HIV-2 infections induce autophagy in Jurkat and CD4+ T cells. Cell Signal. (2012) 24:1414–9. doi: 10.1016/j.cellsig.2012.02.016
32. Sharma V, Makhdoomi M, Singh L, Kumar P, Khan N, Singh S, et al. Trehalose limits opportunistic mycobacterial survival during HIV co-infection by reversing HIV-mediated autophagy block. Autophagy. (2020). doi: 10.1080/15548627.2020.1725374. [Epub ahead of print].
33. Clark AE, Sabalza M, Gordts P, Spector DH. Human cytomegalovirus replication is inhibited by the autophagy-inducing compounds trehalose and SMER28 through distinctively different mechanisms. J Virol. (2018) 92:e02015-17. doi: 10.1128/JVI.02015-17
34. Belzile JP, Sabalza M, Craig M, Clark E, Morello CS, Spector DH. Trehalose, an mTOR-independent inducer of autophagy, inhibits human cytomegalovirus infection in multiple cell types. J Virol. (2016) 90:1259–77. doi: 10.1128/JVI.02651-15
35. Meier JL, Grose C. Variable effects of autophagy induction by trehalose on herpesviruses depending on conditions of infection. Yale J Biol Med. (2017) 90:25–33.
36. Wu Q, Jiang D, Huang C, van Dyk LF, Li L, Chu HW. Trehalose-mediated autophagy impairs the anti-viral function of human primary airway epithelial cells. PLoS ONE. (2015) 10:e0124524. doi: 10.1371/journal.pone.0124524
37. Beatman E, Oyer R, Shives KD, Hedman K, Brault AC, Tyler KL, et al. West Nile virus growth is independent of autophagy activation. Virology. (2012) 433:262–72. doi: 10.1016/j.virol.2012.08.016
38. Chen X, Wang K, Xing Y, Tu J, Yang X, Zhao Q, et al. Coronavirus membrane-associated papain-like proteases induce autophagy through interacting with Beclin1 to negatively regulate antiviral innate immunity. Protein Cell. (2014) 5:912–27. doi: 10.1007/s13238-014-0104-6
39. Reggiori F, Monastyrska I, Verheije MH, Cali T, Ulasli M, Bianchi S, et al. Coronaviruses Hijack the LC3-I-positive EDEMosomes, ER-derived vesicles exporting short-lived ERAD regulators, for replication. Cell Host Microbe. (2010) 7:500–8. doi: 10.1016/j.chom.2010.05.013
40. Maier HJ, Britton P. Involvement of autophagy in coronavirus replication. Viruses. (2012) 4:3440–51. doi: 10.3390/v4123440
41. Ahmad L, Mostowy S, Sancho-Shimizu V. Autophagy-virus interplay: from cell biology to human disease. Front Cell Dev Biol. (2018) 6:155. doi: 10.3389/fcell.2018.00155
42. Cottam EM, Whelband MC, Wileman T. Coronavirus NSP6 restricts autophagosome expansion. Autophagy. (2014) 10:1426–41. doi: 10.4161/auto.29309
43. Li W, Moore MJ, Vasilieva N, Sui J, Wong SK, Berne MA, et al. Angiotensin-converting enzyme 2 is a functional receptor for the SARS coronavirus. Nature. (2003) 426:450–4. doi: 10.1038/nature02145
44. Heckmann BL, Teubner BJW, Tummers B, Boada-Romero E, Harris L, Yang M, et al. LC3-Associated endocytosis facilitates beta-amyloid clearance and mitigates neurodegeneration in murine Alzheimer's disease. Cell. (2019) 178:536–51 e514. doi: 10.1016/j.cell.2019.05.056
45. Lewnard JA, Lo NC. Scientific and ethical basis for social-distancing interventions against COVID-19. Lancet Infect Dis. (2020) 20:631–3. doi: 10.1016/S1473-3099(20)30190-0
46. Malay DS. COVID-19, pandemic, social distancing. J Foot Ankle Surg. (2020) 59:447–8. doi: 10.1053/j.jfas.2020.03.010
47. Ayittey FK, Ayittey MK, Chiwero NB, Kamasah JS, Dzuvor C. Economic impacts of Wuhan 2019-nCoV on China and the world. J Med Virol. (2020) 92:473–5. doi: 10.1002/jmv.25706
48. The Coronavirus Shock: A Story of Another Global Crisis Foretold and Policymaker Should Be Doing About It. UNCTAD (2020). Available online at: https://unctad.org/en/PublicationsLibrary/gds_tdr2019_update_coronavirus.pdf
49. McCreary EK, Pogue JM. COVID-19 treatment: a review of early and emerging options. Open Forum Infect Diseases. (2020). 7. doi: 10.1093/ofid/ofaa105
50. Sheahan TP, Sims AC, Graham RL, Menachery VD, Gralinski LE, Case JB, et al. Broad-spectrum antiviral GS-5734 inhibits both epidemic and zoonotic coronaviruses. Sci Transl Med. (2017) 9:eaal3653. doi: 10.1126/scitranslmed.aal3653
51. Brown AJ, Won JJ, Graham RL, Dinnon KH III, Sims AC, Feng JY, et al. Broad spectrum antiviral remdesivir inhibits human endemic and zoonotic deltacoronaviruses with a highly divergent RNA dependent RNA polymerase. Antiviral Res. (2019) 169:104541. doi: 10.1016/j.antiviral.2019.104541
52. Williamson BN, Feldmann F, Schwarz B, Meade-White K, Porter DP, Schulz J, et al. Clinical benefit of remdesivir in rhesus macaques infected with SARS-CoV-2. Nature. (2020). doi: 10.1038/s41586-020-2423-5
53. Emergency Use Authorization for Remdesivir for Certain Hospitalized COVID-19 Patients. Food and Drug Administration (2020). Available online at: https://www.fda.gov/media/137564/download
54. Choy KT, Wong AY, Kaewpreedee P, Sia SF, Chen D, Hui KPY, et al. Remdesivir, lopinavir, emetine, and homoharringtonine inhibit SARS-CoV-2 replication in vitro. Antiviral Res. (2020) 178:104786. doi: 10.1016/j.antiviral.2020.104786
55. Cao B, Wang Y, Wen D, Liu W, Wang J, Fan G, et al. A trial of lopinavir-ritonavir in adults hospitalized with severe Covid-19. N Engl J Med. (2020) 382:1787–99. doi: 10.1056/NEJMoa2001282
56. Hung IF, Lung K, Tso EY, Liu R, Chung TW, Chu MY, et al. Triple combination of inferferon beta-1b, lopinavir-ritonavir, and ribavirin in the treatment of patients admitted to hospital with COVID-19: an open-label, randomised, phase 2 trial. Lancet. (2020) 395:1695–704. doi: 10.1016/S0140-6736(20)31042-4
57. Wang M, Cao R, Zhang L, Yang X, Liu J, Xu M, et al. Remdesivir and chloroquine effectively inhibit the recently emerged novel coronavirus (2019-nCoV) in vitro. Cell Res. (2020) 30:269–71. doi: 10.1038/s41422-020-0282-0
58. Mauthe M, Orhon I, Rocchi C, Zhou X, Luhr M, Hijlkema KJ, et al. Chloroquine inhibits autophagic flux by decreasing autophagosome-lysosome fusion. Autophagy. (2018) 14:1435–55. doi: 10.1080/15548627.2018.1474314
59. Al-Bari MAA. Targeting endosomal acidification by chloroquine analogs as a promising strategy for the treatment of emerging viral diseases. Pharmacol Res Perspect. (2017) 5:e00293. doi: 10.1002/prp2.293
60. Cao B, Parnell LA, Diamond MS, Mysorekar IU. Inhibition of autophagy limits vertical transmission of Zika virus in pregnant mice. J Exp Med. (2017) 214:2303–13. doi: 10.1084/jem.20170957
61. Burkard C, Verheije MH, Wicht O, van Kasteren SI, van Kuppeveld FJ, Haagmans BL, et al. Coronavirus cell entry occurs through the endo-/lysosomal pathway in a proteolysis-dependent manner. PLoS Pathog. (2014) 10:e1004502. doi: 10.1371/journal.ppat.1004502
62. Emergency Use Authorization for Use of Chloroquine Phosphate or Hydroxychloroquine Sulfate Supllied From the Strategic National Stockpile for Treatmetn of 2019 Coronavirus Disease: Food and Drug Administration (2020). Available online at: https://www.fda.gov/media/136534/download
63. Kakeya H, Seki M, Izumikawa K, Kosai K, Morinaga Y, Kurihara S, et al. Efficacy of combination therapy with oseltamivir phosphate and azithromycin for influenza: a multicenter, open-label, randomized study. PLoS ONE. (2014) 9:e91293. doi: 10.1371/journal.pone.0091293
64. Gautret P, Lagier JC, Parola P, Hoang VT, Meddeb L, Mailhe M, et al. Hydroxychloroquine and azithromycin as a treatment of COVID-19: results of an open-label non-randomized clinical trial. Int J Antimicrob Agents. (2020). doi: 10.1016/j.ijantimicag.2020.105949. [Epub ahead of print].
65. Borba MGS, Val FFA, Sampaio VS, Alexandre MAA, Melo GC, Brito M, et al. Effect of high vs low doses of chloroquine diphosphate as adjunctive therapy for patients hospitalized with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection: a randomized clinical trial. JAMA Netw Open. (2020) e208857. doi: 10.1001/jamanetworkopen.2020.8857
66. Mercuro NJ, Yen CF, Shim DJ, Maher TR, McCoy CM, Zimetbaum PJ, et al. Risk of QT interval prolongation associated with use of hydroxychloroquine with or without concomitant azithromycin among hospitalized patients testing positive for coronavirus disease 2019 (COVID-19). JAMA Cardiol. (2020). doi: 10.1001/jamacardio.2020.1834. [Epub ahead of print].
67. Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, et al. Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet. (2020) 395:497–506. doi: 10.1016/S0140-6736(20)30183-5
68. Carrat F, Vergu E, Ferguson NM, Lemaitre M, Cauchemez S, Leach S, et al. Time lines of infection and disease in human influenza: a review of volunteer challenge studies. Am J Epidemiol. (2008) 167:775–85. doi: 10.1093/aje/kwm375
69. Dobson J, Whitley RJ, Pocock S, Monto AS. Oseltamivir treatment for influenza in adults: a meta-analysis of randomised controlled trials. Lancet. (2015) 385:1729–37. doi: 10.1016/S0140-6736(14)62449-1
70. Uyeki TM, Bernstein HH, Bradley JS, Englund JA, File TM, Fry AM, et al. Clinical practice guidelines by the infectious diseases society of America: 2018 update on diagnosis, treatment, chemoprophylaxis, and institutional outbreak management of seasonal influenzaa. Clin Infect Dis. (2019) 68: e1–47. doi: 10.1093/cid/ciy866
71. Zhang W, Zhao Y, Zhang F, Wang Q, Li T, Liu Z, et al. The use of anti-inflammatory drugs in the treatment of people with severe coronavirus disease 2019 (COVID-19): the perspectives of clinical immunologists from China. Clin Immunol. (2020) 214:108393. doi: 10.1016/j.clim.2020.108393
72. Chen WH, Strych U, Hotez PJ, Bottazzi ME. The SARS-CoV-2 vaccine pipeline: an overview. Curr Trop Med Rep. (2020) 7:61–4. doi: 10.1007/s40475-020-00201-6
73. Dhama K, Sharun K, Tiwari R, Dadar M, Malik YS, Singh KP, et al. COVID-19, an emerging coronavirus infection: advances and prospects in designing and developing vaccines, immunotherapeutics, and therapeutics. Hum Vaccin Immunother. (2020). doi: 10.1080/21645515.2020.1735227. [Epub ahead of print].
74. Lurie N, Saville M, Hatchett R, Halton J. Developing Covid-19 vaccines at pandemic speed. N Engl J Med. (2020) 382:1969–73. doi: 10.1056/NEJMp2005630
75. Carter LJ, Garner LV, Smoot JW, Li Y, Zhou Q, Saveson CJ, et al. Assay techniques and test development for COVID-19 diagnosis. ACS Cent Sci. (2020) 6:591–605. doi: 10.1021/acscentsci.0c00501
76. Nicola M, O'Neill N, Sohrabi C, Khan M, Agha M, Agha R. Evidence based management guideline for the COVID-19 pandemic - review article. Int J Surg. (2020) 77:206–16. doi: 10.1016/j.ijsu.2020.04.001
77. Lai CC, Liu YH, Wang CY, Wang YH, Hsueh SC, Yen MY, et al. Asymptomatic carrier state, acute respiratory disease, and pneumonia due to severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2): Facts and myths. J Microbiol Immunol Infect. (2020) 53:404–12. doi: 10.1016/j.jmii.2020.02.012
78. Hopman J, Allegranzi B, Mehtar S. Managing COVID-19 in low- and middle-income countries. JAMA. (2020) 323:1549–50. doi: 10.1001/jama.2020.4169
79. Otu A, Ebenso B, Labonte R, Yaya S. Tackling COVID-19: can the African continent play the long game? J Glob Health. (2020) 10:010339. doi: 10.7189/jogh.10.010339
80. West CP, Montori VM, Sampathkumar P. COVID-19 testing: the threat of false-negative results. Mayo Clin Proc. (2020) 95:1127–9. doi: 10.1016/j.mayocp.2020.04.004
81. Saez M, Tobias A, Varga D, Barcelo MA. Effectiveness of the measures to flatten the epidemic curve of COVID-19. the case of Spain. Sci Total Environ. (2020) 727:138761. doi: 10.1016/j.scitotenv.2020.138761
82. Yamana T, Sasikiran Kandula SP, Shaman J. Projection of COVID-19 cases and deaths in the US as individual states re-open May 4, 2020. mdRxiv. (2020). doi: 10.1101/2020.05.04.20090670. [Epub ahead of print].
83. Kissler SM, Tedijanto C, Goldstein E, Grad YH, Lipsitch M. Projecting the transmission dynamics of SARS-CoV-2 through the postpandemic period. Science. (2020) 368:860–8. doi: 10.1101/2020.03.04.20031112
84. Randolph HE, Barreiro LB. Herd immunity: understanding COVID-19. Immunity. (2020) 52:737–41. doi: 10.1016/j.immuni.2020.04.012
85. Delamater PL, Street EJ, Leslie TF, Yang Y, Jacobsen KH. Complexity of the basic reproduction number (R0). Emerg Infect Dis. (2019) 25:1–4. doi: 10.3201/eid2501.171901
86. Liu Y, Gayle AA, Wilder-Smith A, Rocklov J. The reproductive number of COVID-19 is higher compared to SARS coronavirus. J Travel Med. (2020) 27:taaa021. doi: 10.1093/jtm/taaa021
87. Anderson RM, May RM. Vaccination and herd immunity to infectious diseases. Nature. (1985) 318:323–9. doi: 10.1038/318323a0
88. Yu X, Yang R. COVID-19 transmission through asymptomatic carriers is a challenge to containment, Influenza. Other Respir Viruses. (2020) 14:474–5. doi: 10.1111/irv.12743
89. Wei WE, Li Z, Chiew CJ, Yong SE, Toh MP, Lee VJ. Presymptomatic transmission of SARS-CoV-2 — Singapore, January 23–March 16, 2020. MMWR Morb Mortal Wkly. (2020) 69:411–5. doi: 10.15585/mmwr.mm6914e1
90. Li W, Zhang B, Lu J, Liu S, Chang Z, Cao P, et al. The characteristics of household transmission of COVID-19. Clin Infect Dis. (2020). doi: 10.1093/cid/ciaa450. [Epub ahead of print].
91. Jiatong S, Lanqin L, Wenjun L. COVID-19 epidemic: disease characteristics in children. J Med Virol. (2020) 92:747–54. doi: 10.1002/jmv.25807
92. Mehta NS, Mytton OT, Mullins EWS, Fowler TA, Falconer CL, Murphy OB, et al. SARS-CoV-2 (COVID-19): what do we know about children? A systematic review. Clin Infect Dis. (2020). doi: 10.2139/ssrn.3558015. [Epub ahead of print].
93. Viner RM, Whittaker E. Kawasaki-like disease: emerging complication during the COVID-19 pandemic. Lancet. (2020) 395:1741–3. doi: 10.1016/S0140-6736(20)31129-6
94. Kaplon RE, Hill SD, Bispham NZ, Santos-Parker JR, Nowlan MJ, Snyder LL, et al. Oral trehalose supplementation improves resistance artery endothelial function in healthy middle-aged and older adults. Aging. (2016) 8:1167–83. doi: 10.18632/aging.100962
95. van Seventer JM, Hochberg NS. Principles of infectious disease: transmission, diagnosis, prevention, and control. Int Encyclopedia Public Health. (2016) 6:22–39. doi: 10.1016/B978-0-12-803678-5.00516-6
96. Nosaka N, Martinon D, Moreira D, Crother TR, Arditi M, Shimada K. Autophagy protects against developing increased lung permeability and hypoxemia by down regulating inflammasome activity and IL-1beta in LPS plus mechanical ventilation-induced acute lung injury. Front Immunol. (2020) 11:207. doi: 10.3389/fimmu.2020.00207
97. Taya K, Hirose K, Hamada S. Trehalose inhibits inflammatory cytokine production by protecting IkappaB-alpha reduction in mouse peritoneal macrophages. Arch Oral Biol. (2009) 54:749–56. doi: 10.1016/j.archoralbio.2009.05.003
98. Collins J, Robinson C, Danhof H, Knetsch CW, van Leeuwen HC, Lawley TD, et al. Dietary trehalose enhances virulence of epidemic Clostridium difficile. Nature. (2018) 553:291–4. doi: 10.1038/nature25178
Keywords: trehalose, SARS-CoV-2, COVID-19, prophylaxis, autophagy
Citation: Martinon D, Borges VF, Gomez AC and Shimada K (2020) Potential Fast COVID-19 Containment With Trehalose. Front. Immunol. 11:1623. doi: 10.3389/fimmu.2020.01623
Received: 16 April 2020; Accepted: 17 June 2020;
Published: 07 July 2020.
Edited by:
Rashika El Ridi, Cairo University, EgyptReviewed by:
Shu Yuan, Sichuan Agricultural University, ChinaDhiraj Kumar, International Centre for Genetic Engineering and Biotechnology, India
Copyright © 2020 Martinon, Borges, Gomez and Shimada. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Kenichi Shimada, a2VuaWNoaS5zaGltYWRhJiN4MDAwNDA7Y3Nocy5vcmc=