Abstract
The SARS-CoV-2 virus has spread worldwide to cause a full blown pandemic since 2020. To date, several promising synthetic therapeutics are repurposed and vaccines through different stages of clinical trials were approved and being administered, but still the efficacy of the drugs and vaccines are yet to be decoded. This article highlights the importance of traditional medicinal plants and the phytomolecules derived from them, which possess in vitro antiviral and anti-CoV properties and further explores their potential as inhibitors to molecular targets of SARS-CoV-2 that were evaluated by in silico approaches. Botanicals in traditional medicinal systems have been investigated for anti-SARS-CoV-2 activity through in silico and in vitro studies. However, information linking structure of phytomolecules to their antiviral activity is limited. Most phytomolecules with anti-CoV activity were studied for inhibition of the human ACE2 receptor through which the virus enters host cells, and non-structural proteins 3CLpro and PLpro. Although the proteases are ideal anti-CoV targets, information on plant-based inhibitors for the CoV structural proteins, e.g., spike, envelope, membrane, nucleocapsid required further investigations. In absence of scientific evaluations through in vitro and biocompatibility studies, plant-based antivirals fall short as treatment options. Plant-based anti-SARS-CoV-2 therapeutics can be promising alternatives to their synthetic counterparts as they are economical and bear fewer chances of toxicity, side effects, and viral resistance. Our review could provide a systematic overview of the potential phytomolecules which can be repurposed and subjected to further modes of experimental evaluation to qualify for use in treatment and prophylaxis of SARS-CoV-2 infections.
Introduction
Coronaviruses, a genus of the Coronaviridae family, are enveloped viruses with a large plus-strand RNA genome commonly associated with respiratory or enteric infections in human, mammal, fish, and avian hosts [1, 2]. CoVs were initially known to be enzootic, causing disease only in animals hosts, although few CoVs have crossed the animal-human species barrier and progressed to cause zoonoses in humans. The novel corona virus disease, COVID-19, caused by SARS-CoV-2 virus started as an endemic flu type epidemic, causing pneumonia, in December 2019 in the Hubei province of China with Wuhan city as the epicenter of the infection. Presently, the virus has spread as a full blown pandemic across the globe manifesting major clinical symptoms such as dry cough, fever, diarrhea, breathlessness, and fatigue, with many patients developing dyspnea and lymphopenia. The disease progression is associated with complications such as respiratory distress syndrome, acute cardiac injury, and RNaemia [3]. Although vaccines and antivirals for treatments are being fast-tracked by regulatory agencies in various countries, their effects in the long term will not be known yet. To date, no perfect therapeutics have been approved against any human-infecting coronaviruses and all their variants [4, 5]. The susceptibility of populations to SARS-CoV-2 is presently under investigation. Older people and people with pre-existing disease conditions such as asthma, hypertension, heart disease, and diabetes are at higher risks of developing severe illness as a result of infection [6]. However, COVID-19 has slain more people than any other coronaviruses, such as, SARS-CoV and MERS-CoV [7]. In the course of running preventive measures, countries remain administratively crippled and grapple with fear of their economy sliding down, their citizenry losing jobs coupled with the anxiety of losing human lives at mass scale. Viral diseases pose high risks to the human health on account of the highly mutative nature of the viral genomes, making it difficult to control transmission and in coming forward with effective interventions [8]. Despite constant advances in the drug discovery process and discovery of novel antiviral agents, most treatments for viral diseases include synthetic drugs of which action is non-specific for particular viruses [9]. While synthetic antivirals help in bringing the infection under control, they could cause undesirable side effects coupled with their inability in changing the course of induced viral complications. Developed inefficiency of the antivirals is attributed to the limited effective life span of synthetic antivirals, caused by problems of latency and recurrence in immune-compromised hosts [10].
Demand for alternative sources of antivirals has led to a revived interest in investigating natural, plant-based sources, which have advantages of being much less expensive, having better patient tolerance, and fewer or no side effects. In India, traditional medicines have been practiced through ages. India, like China, has a diverse medicinal plant system that has diverse sources of therapeutic agents, which have proved useful for combating viral disorders. Plant-based formulations to treat historic epidemics have been previously reported in the case of CoV, influenza, and dengue viruses [11]. Medicinal plants exert antiviral effects and enhance the immune system. Indian medicinal plants have been widely studied for a range of therapeutic applications and their use in medicines since ancient times. Listed in Ayurveda, Siddha, and Unani medicine systems in India, their investigations can be the key to alleviate pathologies caused by viruses and in overcoming the limitations of existing antivirals. Several studies on the antiviral activity of plants against different CoVs, and other enveloped viruses that cause diseases in humans have been reported. In view of the present pandemic, our review aims to focus on the potential phytomolecules that can be repurposed as inhibitors for molecular targets of SARS-CoV-2 and its variants by making use of the information obtained through previously conducted investigations.
Biology of Coronaviruses-Extrapolating Known Data to Determine Pathogenesis of SARS-CoV-2
Coronaviruses belong to the order Nidovirales, family Coronaviridaeand sub-family Coronavirinae. Their genome size is approximately 26–32 kb, which is the largest known size for RNA viruses [12] and are associated with a GC content of 32–43% [2]. SARS-CoV, MERS-CoV, and SARS-CoV-2 belong to betacoronaviruses and are further classified under the Sarbecovirus subgenera. The recently emerged SARS-CoV-2 virus possesses 79.5% identity to SARS-CoV, 51.8% to MERS-CoV, and 96.2% identity to bat (i.e., order Chiroptera) CoV [13, 14]. Phylogenetic analysis, using the publicly available SARS-CoV-2 sequences yielded 86.9% sequence identity with previously published sequence of bat SARS-like CoV, while Simplot analysis yielded 96% identity with that of bat CoV isolate RaTG13, suggesting a probable origin from bats [2]. Major structural proteins (e.g., spike, nucleocapsid, envelope, and membrane) and non-structural proteins of CoV play significant roles in attachment to host cells and in pathogenesis. Structural proteins are encoded by one-third of the genome at the 3′ end, while two-thirds of the genome at the 5′ end contain two ORFS (1&2). The non-structural proteins Mpro (Chymotrypsin-like protease or 3CLpro) and Papain-like protease (PLpro), produce 16 mature non-structural proteins, which further produce accessory proteins responsible for viral replication and transcription [2].
Spike protein is the first of the structural proteins involved in mediating attachment of virus to the receptors on host cell, and is responsible for causing subsequent fusion between viral and host cell membranes and finally allows viral entry into the host cell. Enhanced binding affinity between the spike glycoprotein of SARS-CoV and hACE2 receptor accounts for the increased transmissibility and disease severity observed in humans,, suggesting that it can spread as efficiently as demonstrated by the number of human–human transmission events. However, SARS-CoV-2 is unique due to the presence of a furin cleave site at the S1/S2 boundary [5], which could largely affect its infective and transmissible characteristics. The nucleocapsid protein has a supposed role in viral assembly and budding, and is responsible for binding to CoV RNA genome, which is stabilized by binding to membrane protein. The nucleocapsid protein also mediates in the CoV replication cycle. Membrane protein along with the envelope protein makes up the viral envelope, whose interaction has been reported to suffice for production and release of virus-like particles. The envelope protein is the smallest major structural protein whose role is extremely significant as its absence impedes viral production and maturation [12]. Among the non-structural proteins, the active site of Mpro has been identified to be highly conserved among CoVs with several shared common features [14]. Homology of Mpro has been evidenced in its primary amino acid sequence as well its tertiary structure [15]. It is interesting to note that Mpro does not possess a human homolog, thus making it an ideal antiviral target [14].
The present genomic data suggests that SARS-CoV-2 bears sequence identity to SARS-CoV to an extent that the therapeutics investigated for it can be repurposed and repositioned for the treatment of SARS-CoV-2. Although the pathogenesis and exact biology of SARS-CoV-2 is yet to be determined, the present knowledge pertaining to SARS-CoV and MERS-CoV can provide important clues for the present and future research efforts into the investigation of SARS-CoV-2.
Antiviral Approaches
Potential Antiviral and Immunomodulatory Phytomolecules
Use of medicinal plants in prevention and treatment of respiratory viral infections is an age-old practice owing to their immune stimulation and inflammation modulating effects in addition to exhibiting antiviral properties. In SARS-CoV-2 infections, lung damage and respiratory insufficiency are most often caused by the inflammatory injury to alveolar capillaries due to the generalized cytokine storm, chemokines, and inflammatory cytokines. An important strategy to protect lung damage from effects of viral infection could be to explore antiviral plants reported to possess inhibitory activity against known pathogenic viruses, which also possess immune modulatory properties thereby acting as enhanced therapeutic agents [16]. Search for medicinal plants with reported antiviral and immune modulatory (e.g., anti-inflammatory, controlling cytokine production, and immune boosting) properties will serve as mode of treatment and prophylaxis for SARS-CoV-2 infection by directing the immune system to control the inflammatory response to the invading virus and inhibiting viral propagation in the cells. We have conducted an overview of reported plant-based antivirals proven to inhibit pathogenic viruses, use of the plants in traditional medicinal systems, and their associated immune modulatory effects that produce a controlled immune response against enveloped and respiratory disease causing viral pathogens previously recorded (Table 1). The phytomolecules such as baicalin, rhein, chebulagic acid, glycyrrhizin, betulinic acid, and andrographolide have demonstrated anti-viral activity against enveloped and respiratory disease causing viruses such as HIV, dengue, HSV, IAV. Although phytomolecules such as glycyrrhizin, baicalin, rhein, and betulinic acid have been studied for inhibition of coronaviruses, data on uses of the source plants of the aforementioned phytomolecules in traditional medicinal systems have also been collated and will be critical for investigating the plants for symptomatic treatment of SARS-CoV-2 infected patients. The medicinal plants listed can be explored for possessing specific inhibitory and immune regulatory properties and repurposing for use against SARS-CoV-2.
Table 1.
Phytomolecule | Class of compound | Source plant | Traditional uses of source plant | Anti-viral activity of phytomolecule | Immunomodulatory activity of phytomolecule aiding in anti-viral activity |
---|---|---|---|---|---|
Baicalin | Flavonoid | Scutellaria baicalensis Georgi | Used in TCM as an anti-pyretic [62], and for the treatment of pharyngitis, pneumonia, and upper respiratory infections [63] | Enveloped viruses—dengue (DENV) influenza virus, A/PR/8/34 (H1N1) [64] | In vitro inhibition of chemokine binding to human leukocytes, induction of IFN-γ critical for innate, and adaptive immunity against viral pathogens [65] |
Rhein | Anthraquinone | Rheum palmatum L | Prescribed in TCM for the treatment of cough, jaundice, and hepatitis [66] | IAV [67] | Activation of TLR4, Akt, p38, JNK MAPK, and NF-κB pathways [67] |
Chebulagic acid, punicalagin | Tannin | Terminalia chebula Retz | Fruits commonly used to treat digestive disorders, chronic cough, sore throat, and asthma [68], used for recovery from acute respiratory infections | IAV, HIV-1 [69], HSV-1, RSV, HCV, CMV [70] | COX-LOX dual inhibitor, increased IL-2, IL-10 TNF-α, antioxidant enzyme levels, elevated T and B cell proliferation [71] |
Andrographolide | Terpenoid | Andrographis paniculata (Burm.f.) Wall. ex Nees | Used for treatment of upper respiratory infections, bronchitis, inflammation [72] | DENV-2 and DENV-4 strains in vitro, HSV, HBV, HCV, HIV, CHIKV [73] | Effective enhancement of cytotoxic T cells, natural killer (NK) cells, phagocytosis, antibody-dependent cell-mediated cytotoxicity (ADCC) [74], significant stimulation of antibodies, and delayed type hypersensitivity (DTH) response [75], increased proliferation of lymphocytes, and production of IL-2, TNF-α, and CD marker expression |
Glycyrrhizin | Terpene | Glycyrrhiza glabra L | Used in TCM for treatment of respiratory tract disorders, cough, asthma, sore throat [76], eliminating phlegm, and providing cough relief [77] | Influenza A virus, H5N1, H1N1, hepatitis C virus, HIV, rotavirus, Newcastle disease virus [78] | Upregulated expression of CD40, CD86, MHC-II maturation markers on dendritic cells, enhanced production of IL-2 by dendritic cells, IFN-γ, IL-10, and enhanced allogeneic T cell proliferation, reduction in IL-4 production, stimulation of endogenous interferon production, elevated anti-oxidant status, and decreased incidence of free-radical induced lipid peroxidation [79, 80] |
Betulinic acid | Terpene | Ziziphus jujuba Mill.and Syzigium claviflorum (Roxb.) Wall.ex A.M.Cowan & Cowan | Used in treatment of respiratory infections | HSV-2, HIV-1, IAV in vitro [81] | Increased levels of TNF-α from peritoneal macrophages, IL-12, CD4 +, and lymphocyte population along with enhanced thymus and spleen indices, decreased levels of IL-10 and TGF-β along with increased IgG production. Downregulation of IFN-γ levels [82, 83] |
Plants/Phytomolecules Reported to Possess Antiviral Activity Against CoV
Inhibitors of Various CoV In Vitro
Dried roots and rhizomes of Glycyrrhiza glabra L. contain bioactive phytomolecules glycyrrhizin (triterpine) and 18 β glycyrrhetinic acid (aglycone) [17, 18]. Although the exact mechanism by which these molecules exert their antiviral activity is unknown, adsorption and penetration of SARS-CoV was inhibited during the early stages of the viral replication cycle. Glycyrrhizin has the ability to interfere with viral signal transduction and resulting in up-regulation of NO production, which also has antiviral properties, thus exerting immunomodulatory and protective activity [19]. Immunomodulatory effects of glycyrrhizin could be established by its use in the treatment of chronic viral infections along with L-cysteine and glycine. Antiviral activity against SARS-CoV was demonstrated by active principles from plants, e.g., ginsenoside Rb1 from Panax ginseng C.A. Mey, aescin from horse chestnut tree Aesculus hippocastanum L., and reserpine from Rauwolfia sp. P.ginseng is widely used in TCM for treatment of spontaneous sweating and fever, atrophic lung disease and phlegm, shortness of breath, and providing nourishing and immune-enhancing effects among many other uses [20, 21].
Flavonoid catechin isolated from Eleutherococcus senticosus (Rupr. & Maxim.) Maxim. demonstrated anti-CoV activity, while the alkaloids cepharanthine and isoquinoline isolated from Stephania cephalantha Hayata and flavonoid baicalin isolated from S. baicalensis displayed effective anti-SARS-CoV activity in vitro [10, 22]. Plant extracts using whole plant of Artemisia annua L., leaf of Pyrrosia lingua (Thunb.) Farw., root of Lindera aggregate (Sims) Kosterm., and the phytomolecule lycorine from Lycoris radiata (L′He´r.) Herb.demonstrated significant anti-SARS-CoV activity in vitro [23]. Plant extracts of Artemisia annua L. inhibited feline coronavirus and SARS-CoV-2 in vitro, with its activity attributed to artemisinin and other flavonoids present in the extract [24, 25]. Phytomolecules UDA (U d agglutinin) from the plant Urtica dioica L, represented a moderately active antiviral lectin with increased therapeutic utility by specifically interacting with oligomers at the core of glycans and homologous envelope proteins of SARS-CoV. In an in vivo experiment, UDA was able to protect mice against lethal infection, protect against weight loss, and decreased lung pathology scores. However, it did not reduce lung viral titres [26].
A number of plant extracts and associated phytomolecules exhibited antiviral activity against the viruses other than SARS-CoV, e.g., MERS-CoV, HCoV-229E murine coronavirus. Resveratrol (trans-3’, 5, 4’-trihydroxystilbene), abundant in plants such as grape (Vitis vinifera L.), huzhang (Polygonum cuspidatum Siebold & Zucc.), and cranberry (Vaccinium macrocarpon Aiton), inhibited viral growth of MERS-CoV. The phytomolecule was able to prolong cellular survival after viral infection and resulted in decreased expression of nucleocapsid protein in a dose-dependent manner [27]. Silvestrol, a type of flavagline from the genus Aglaia, was identified to be an eIF4A (DEAD box RNA helicase) inhibitor. Silvestrol displayed antiviral activity against MERS-CoV and HCoV-229E by inhibition of formation of viral replication or transcription complexes [28]. Antiviral activity of saikosaponins A, B2, C, and D was reported against HCoV-229E by inhibition of viral attachment and penetration [29]. Quercetin, one of the most widely reported phytomolecules, inhibited propagation of murine coronavirus possibly by inhibiting H+-ATPase of lysosomal membrane and inhibition of viral coat protein removal [30]. Anti-SARS-CoV, MERS-CoV, and anti-HCoV229E activity was conducted by the commercial plant extract Echinoforce, derived from Echinacea purpurea (L.) Moench [31]. The phytomolecules with antiviral activity against coronaviruses were recorded in Table 2.
Table 2.
Phytomolecules | Class of compound | Source plant | Antiviral activity against CoV | References |
---|---|---|---|---|
Glycyrrhizin | Terpene | Glycyrrhiza glabra | SARS-CoV | [17] |
ginsenoside Rb1 | Triterpene saponin | Panax ginseng | SARS-CoV | [84] |
Aescin | Saponin | Aesculus hippocastanum | SARS-CoV | [84] |
Aurintricarboxylic acid | Polyarmoatic carboxylic acid derivative | SARS-CoV | [85] | |
Reserpine | Alkaloid | Rauwolfia sp. | SARS-CoV | [84] |
Catechin | Flavonoid | Eleutherococcus senticosus | CoV | [10] |
Cepharanthine and isoquinoline | Alkaloid | Stephania cepharantha | SARS-CoV | [10] |
Baicalin | Flavonoid | Scutellaria baicalensis | SARS-CoV | [22] |
Lycorine | Alkaloid | Lycoris radiata | SARS-CoV | [23] |
Alpha-hederin (glycyrrhizin derivative) | Triterpenoid saponin | Glycyrrhiza glabra | SARS-CoV | [86] |
UDA | Lectin | Urtica dioica | SARS-CoV | [26] |
Resveratrol | Polyphenol | Vitis vinifera, Polygonum cuspidatum and Vaccinium macrocarpon | MERS-CoV | [27] |
Silvestrol | Benzofuran | Aglaia spp. |
MERS-CoV, HCoV-229E |
[28] |
Saikosaponins A, B2, C, D | Triterpene glycosides | Bupleurum spp. | HCoV-229E | [29] |
Theaflavins | Tannins | Black tea | Bovine coronavirus | [10] |
Quercetin | Flavonoid | Murine coronavirus | [30] | |
Echinoforce | Echinacea purpurea |
SARS-CoV, MERS-CoV, HCoV-299E |
[31] |
Inhibitors of SARS-CoV Structural Proteins
Potent anti-SARS-CoV activity was demonstrated by phytomolecule luteolin found in the plant used in TCM, e.g., Perilla frutescens (L.) Britt, which is traditionally used for treatment of asthma, cough, flu, cold, phlegm, stuffy nose, and headache [32]. Luteolin bound to S2 subunit of the precursor of spike protein and blocked viral entry by interfering with the viral-host cell fusion process. Mannose-specific plant lectins from Galanthus nivalis L., and Allium porrum L. are promising anti-SARS-CoV agents. The anti-SARS-CoV activity of mannose-specific plant lectins could be attributed to their ability to bind with mannose type glycans which form 2 of the 4 N-glycosylation sites in SARS-CoV spike protein [33]. The anthraquinone emodin from plants of Genus Rheum and Polygonum block spike protein and ACE interaction in a dose-dependent manner [34]. Griffithsin, isolated from the red alga Griffithsia sp. is a 12.7 kDa protein, which inhibits SARS-CoV viral entry both in vitro and in vivo by binding specifically to the spike glycoprotein [35]. Spike protein mediated binding and entry of SARS-CoV-2 was inhibited in vitro by a novel polyphenol brazilin as well as phytomolecules theaflavin-3,3 digallate and cucurmin [36]. We examined details of phytomolecules that exhibited inhibitory properties of the SARS-CoV structural proteins (Table 3).
Table 3.
SARS-CoV structural protein inhibitors | ||||
---|---|---|---|---|
Phytomolecule | Class of compound | Target protein | Source plant | References |
Luteolin | Flavonoid | Spike | [22] | |
Mannose-specific lectins | Lectin | Spike | Galanthus nivalis, Hippeastrum hybrid, and Allium porrum | [33] |
Emodin | Anthraquinone | Spike | Genus Rheum and Polygonum | [34] |
Griffithsin | Protein | Spike | Griffithsia sp. (red alga) | [35] |
Inhibitors of SARS-CoV Non-structural Proteins
The plant extract of Houttuynia cordata Thunb., traditionally used in India to treat fever and cough [37], demonstrated effective inhibition of 3CLpro and RdRp in vitro. Upon further investigation, the immunostimulatory effect of the extract was identified. In uninfected cells, the extract prevented infection by virus by stimulating proliferation of CD4+ helper T cells and CD8+ cytotoxic T cells. In infected cells, the extract caused inhibitory effect against viral replication by hindering the activity of pivotal viral enzymes [38]. Root of Isatis indigotica Fortune ex Lindl., which is traditionally used in China for treatment of viral diseases, e.g., influenza, hepatitis, and encephalitis [39], was used to effectively inhibit SARS-CoV 3CLpro due to the activity of its constituent phytomolecules, indigo, sinigrin, and β-sitosterol. Since 3CLpro is a chymotrypsin-like protease, the established activity of indigo as a chymotrypsin inhibitor is justified [40]. Root of I.indigotica was patented as an herbal drug and the decoction was recommended by the National Health Commission of China in its treatment plan for SARS-CoV-2 in 2020 [41]. Other phytomolecules that exhibit inhibition against 3CLpro include amentoflavone isolated from Torreya nucifera (L.) Siebold & Zucc., myricetin, and scutellarein [29]. Ethyl acetate fractions of heartwood of Chamaecyparis obtusa var. formosana (Hayata) Hayata yielded active components, ferruginol, and savinin, while ethyl acetate fractions of heartwood of Juniperus formosana Hayata yielded active constituents, betulonic acid, and forskolin. Among the aforesaid phytmolecules, betulonic acid and savinin demonstrated most effective competitive inhibition of 3CLpro [42]. 3CLpro inhibitory properties were demonstrated by 4 quinone-methide triterpenes from the plant Tripterygium regelii Sprague & Takeda [43]. Herbal extracts of rhizome Cibotium barometz (L.) J.Sm. and Dioscorea batatas Decne., seeds of Gentiana scabra Bunge and Cassia tora L. as well as stem with leaves of Taxillus chinensis (DC.) Danser inhibited SARS-CoV. Herbal extract derived from the rhizome of D. batatas, which exerted antiviral activity through inhibition of 3CLpro was considered highly potent [44].
PLprotease of coronaviruses is an important target for antivirals as it is a significant non-structural protein that catalyzes its own release and liberation of other non-structural proteins from the polyprotein, without which the virus-mediated RNA replication could not occur. PLpro also cleaves ubiquitin chains and causes deISGylation, thus highlighting its role in modifying host immune response to viruses. PLpro inhibitors have been widely reported from different plant sources. Natural compounds exhibiting PLpro inhibition include diaryl heptanoids, tanshinones, flavonoids, and cinnamic amides. These compounds form the base from which PLpro inhibitors can be derived. Novel, active flavonoids from the TCM plant Paulownia tomentosa Steud. were reported to inhibit PLpro of SARS-CoV due to the presence of a 3,4-dihydro-2H pyran moiety. The flavonoids possessed a geranylated structure and were named tomentin A, B, C, D, E; of which tomentin B produced highest activity against PLpro. Other flavonoids from P.tomentosa, which displayed significant inhibition, include 3′-O-methyldiplacol, 4′-O-methyldiplacone, mimulone, and diplacone [45]. Tannic acid, theaflavin-3′-gallate, and theaflavin-3′,3′-digallate from black tea leaves demonstrated anti-SARS-CoV activity by inhibition of PLpro [10]. Xanthoangelol E was found to be one of the most active principles from the plant Angelica keiskei (Miq.) Koidz. Along with Xanthoangelol E, Xanthoangelol F, D, B, G, isobavachalcone, 4-hydroxyderricin, and Xanthokeistal demonstrated notable inhibition of PLpro of SARS-CoV [46]. The active principles from A.keiskei were able to inhibit the activity of 3CLpro and PLpro, thus, exhibiting anti-SARS-CoV activity through multiple mechanisms. Plant-based inhibitors of non-structural CoV proteins were analyzed and listed in Table 4. Docking studies demonstrated withanoside from the source plant Withania somnifera (L.) Dunal inhibited 3CLpro and spike proteins of SARS-CoV-2 [47]. The inhibition was brought about by increase in IFN-γ response and anti-inflammatory activities by decreasing IL-1, IL-6, and TNF-α levels [48]. The SARS-CoV-2 3CLpro protein was also inhibited by Tinosponone from Tinospora cordifolia (Willd.) Miers [49] by modulation of cytokine production levels and activation of immune effector cells [48].
Table 4.
Phytomolecule | Class of compound | Source plant | References |
---|---|---|---|
SARS-CoV 3CLpro or Mpro inhibitors | |||
Indigo, Sinigrin, and β-sitosterol | Isatis indigotica | [40] | |
Amentoflavone | Flavonoids | Torreya nucifera | [43] |
Ferruginol and savinin | Terpenoid and lignin | Chamaecyparis obtusa var. formosana | [44] |
Betulonic acid and Forskolin | Terpene | Juniperus formosana | [44] |
SARS-CoV PLpro inhibitors | |||
Tomentin B | Coumarin | Paulownia tomentosa | [45] |
Xanthoangelol E | Chalcone | Angelica keiskei | [46] |
Theaflavin-3′,3′-digallate | Tannin | Black tea | [10] |
Inhibitors of SARS-CoV-2 Target Receptor-ACE2
The angiotensin converting enzyme II (ACE2) is a membrane bound enzyme located in the heart, kidney, vascular system, and digestive tracts. Studies on binding of SARS-CoV-2 to human cells have demonstrated highest affinity of the virus toward human ACE2 receptor, which serves as the key bridge used by the virus for transmission between humans. Despite a 72% structural similarity of the spike glycoprotein RBD between SARS-CoV and SARS-CoV-2, RBD of the latter demonstrated higher interaction with the ACE2 receptor, which could explain the higher rates of transmissibility of SARS-CoV-2 compared to SARS-CoV. Understanding the importance of the receptor in facilitating viral entry into human cells, several studies have led to the discovery and repurposing of inhibitors of ACE2 receptor. The inhibitors function by altering the binding site of the virus on ACE2, thereby blocking virus-host cell interaction and virus binding. Although ACE2 inhibitors are potential agents to prevent SARS-CoV-2 infection, it is important to investigate if inhibition of ACE2 activity could impair recovery from infection [50] and identify if alternate anti-inflammatory and antioxidant pathways are activated. Plants such as Allium sativum L., Cerasus avium L., Alcea digitata (Boiss.) Alef, and Rubia tinctorum L. have been reported to possess anti-ACE2 activity and can be explore for inhibition of ACE2 in SARS-CoV-2 [51]. Specific phytomolecules have been reported to inhibit ACE2 receptor, which serve as potent anti-SARS-CoV-2 agents (Table 5). The flavonoid class of compounds has yielded a maximum number of phytomolecules which demonstrated ACE2 inhibition. It is to be noted that phytomolecules, such as, luteolin, quercetin, rhein, glycyrrhizin, and emodin [52], which have demonstrated anti-CoV activity through inhibition of structural and non-structural proteins have also displayed ACE2 inhibition. Details of phytomolecules highlighted in this study could throw light on plant-based therapeutics, which would have heightened anti-SARS-CoV-2 potential by means of inhibition of binding to human receptor ACE2 and inhibition of viral protein targets.
Table 5.
Phytomolecule | Class of compound | Method of assessing activity | References |
---|---|---|---|
Kaempferol | Flavonoid | In vitro | [52] |
Quercetin | Flavonoid | In vitro | [52] |
Apigenin | Flavonoid | In vitro | [87] |
Baicalin | Flavonoid | In silico | [88] |
Scutellarin | Flavonoid | In silico | [88] |
Glycyrrhizin | Terpenoid | In silico | [88] |
Curcumin | Cucurminoid | In silico | [89] |
Emodin | Anthraquinone | In vitro | [90] |
Caffeic acid | Phenolic acid | In vitro | [91] |
Nicotinamine | Peptide | In vitro | [92] |
In Silico Approach for Repurposing Reported Antiviral Phytomolecules
In wake of the COVID-19 pandemic, several in silico studies have been reported screening synthetic drugs and phytochemicals, as attempts to bring to light the possible compounds that can act as efficient COVID-19 inhibitors. Computational studies help to identify potential compounds and speed up the process of making effective therapeutics available to meet the need of the hour. Drug repurposing ensures that the identified compounds have established safety profiles, and eliminated possibilities of harmful side effects. Repurposing of FDA-approved drugs and those under clinical trials for SARS-CoV and MERS-CoVs would be a favorable strategy for development of therapeutics for COVID-19 [53]. Currently, phase III clinical trials of a few drugs specific to RdRp (RNA-dependent RNA Polymerase) or 3CLpro is in progress. Need to consider repurposing of drugs for major structural proteins of COVID-19, e.g., spike and Mpro, assumes critical importance.
Although prime focus of in silico studies is placed on repurposing FDA-approved synthetic drugs, phytochemicals were also screened for in silico docking to SARS-CoV-2 targets. It is understood that most synthetic drugs used as antivirals have toxic side effects in the long run, and considering the potential of plant-based antivirals several in silico studies focusing on repurposing bioactive phytomolecules have been conducted. Phytochemicals listed in TCM were screened in silico and active phytomolecules including myricitrin, methyl rosmarinate, and amaranthin were identified as 3CLpro inhibitors of SARS-CoV-2 [54]. In silico approach was used to identify FDA-approved antiviral compounds and phytochemicals active against Mpro of COVID-19 through virtual screening. Andrographolide, a small molecule from the medicinal plant Andrographis paniculata (Burm.f.) Wall. ex Nees was identified to possess in silico inhibitory activity against Mpro of SARS-CoV-2 [55]. Andrographolide docked successfully on the site of inhibition of Mpro of COVID-19 and possessed highly soluble and remarkable pharmacodynamic properties. The in silico binding occurred with high accuracy and alignment occurred with Lipinski’s rule, thus making it a potential candidate for use in a therapeutic drug against COVID-19. In silico studies, such as, molecular docking, target analysis, toxicity prediction, and ADME prediction using computational biology established andrographolide from A. paniculata as a potential inhibitor of the main protease of SARS-COV-2 (3CLpro or Mpro). Computational approaches also predict that andrographolide may have good solubility, pharmacodynamics property, and target accuracy, thus making it a promising compound to pursue with in biochemical and cell-based assays, and to explore its potential for use against COVID-19. In silico analysis also yielded successful docking of andrographolide against the inhibitor region of the main protease of SARS-CoV-2 virus with docking score of -3.09 kcal/mol. The docking score showed effective binding when compared to synthetic compounds when they are docked against Mpro protein, e.g., disulfiram, tideglusib, and shikonin with the results of -46.16, -61.79, and -17.35 kcal/mol, respectively. The binding scores were higher when compared with the recently proposed combination of three drugs, namely, lopinavir, ostelmivir, and ritonavir whose binding scores were − 4.1, − 4.65, and − 5.11, respectively. This implied that the affinity was lower. The drug ability feasibility parse is weighed upon several criteria apart from the binding scores alone where andrographolide has an advantage as it is a natural molecule and satisfies Lipinski’s rule significantly.
Network Ethnopharmacology Approach to Identify Effects of Traditional Medicines
Any drug, whether synthetic or natural, will possess inherent limitations when its action is directed toward a single target [56]. Bioactive phytomolecules in herbal formulations can modulate multiple targets in a living cell, which can be elucidated by the network ethnopharmacology approach. The approach provides a system-level understanding to the pathogenesis of a disease and the mechanism of action of herbal formulations on the disease. Network pharmacological studies are based on examining biological systems and monitoring their information pathway responses after systematic perturbation [57]. Mathematical models are used to define the structure and response of a system to a particular perturbation. Possible interactions of bioactive phytomolecules with molecular targets of disease networks can be defined by molecular docking-based network ethnopharmacology, which was used to study ayurvedic formulations in assessing the potential of Triphala in multiple disease management through multi bioactive-multi-target interactions [56]. Many diseases are caused by malfunction of multiple genes and the effect of products of faulty genes which disturb biological processes. Systems biology and network analysis show that diseases sharing biological processes could be treated by the same drug [58]. Such approach will be essential when devising herbal formulations to treat patients who are infected by COVID-19 with detected comorbidities, since it is a multi-compound, multi-target approach to deal with multifactorial diseases [56].
Network ethnopharmacology was used to identify the holistic mechanism of action of herbal formulations against viral diseases [56, 58]. Role of TCM in treatment of COVID-19 was elucidated using network pharmacology analysis. Its effectiveness and possible molecular mechanism of TCM formulations were analyzed [59]. Using the method, herbal formulations were identified to directly suppress replication of viruses by targeting different key proteins in viral life cycle and to indirectly regulate host defense system. The method was useful to resist viral infection and alleviate symptoms of upper respiratory tract infections [58]. Bioactive compounds in herbal formulations have complicated interactions with cellular targets, thus making network ethnopharmacology a promising tool to elucidate multi-component, multi-target properties of traditional medicinal plants in treatment of COVID-19. Network ethnopharmacology can be used to determine the mechanism of pharmacological action, safety, toxicity and side effects of herbal formulations, and phytomolecules that can be repurposed.
Challenges in Development of Phytotherapeutics
Phytomolecules have established their potential as promising antiviral agents against CoVs including the SARS-CoV-2 and its variants. The traditional folklore knowledge, transmitted from generation to generation, was attributed to the therapeutic indications of medicinal plants. However, due to the lack of scientific evaluation of in vitro studies, biocompatibility studies, ADMET profiling, dosage, pharmacokinetics, and elucidation of their mode of action, plant-based antivirals fall short as effective treatment options. If investigations along these lines can be carried out with the support agencies, such as the Ministry of AYUSH of the Indian government, which has been diligently attempting to provide funds for creating medicinal plant databases along with biomedical applications, development of a robust repository to tap significant data on viral diseases could be facilitated. Whole plant extracts or the molecules isolated from them, and purified, could serve the purpose of investigating repurposing. However, scaling up the process in case of plants that are rare and endangered species (RET) could be one major challenge in the course of exploring plant-based antivirals. This challenge, however, could be overcome by adopting tissue culture methods to meet demands of producing plant-based therapeutics. Very often, the plant extracts on the whole demonstrate antiviral activity instead of a single phytomolecule; in such cases, purity of the extract, dose determination and formulation could become inherent challenges. In a realistic scenario, a mixture of phytomolecules might also be able to produce an enhanced synergistic antiviral effect as opposed to using individual phytomolecules. The holistic effect of mixture of phytomolecules or the individual action of a single phytomolecule can be studied through network ethnopharmacology analysis to elucidate the mechanism of action and the safety profile of the herbal formulations. Further investigations in this aspect can help to characterize the pharmacological profile of plant-based antivirals and enhance the scientific basis for their use in treating the disease.
Discussion and Conclusion
Through our review, phytomolecules demonstrating in vitro, in vivo, or in silico activity against coronaviruses in general as well as against ACE2 receptor, the structural and non-structural targets were recorded. The record is aimed to provide a holistic overview of the phytomolecules that can be used as starting points to for investigation of plant-based therapeutics for SARS-CoV-2. We identified the major class of compounds reported as inhibitors of specific SARS-CoV-2 molecular targets (Table 6). Phytomolecules from different classes of compounds and from a wide variety of plant families may have significant biomedical values as antivirals. With advancements in medicinal chemistry, structures of bioactive phytomolecules have been extensively studied and elucidated. However, with regard to their role as antivirals, limited number of investigations have been conducted to link the structure of phytomolecules to their antiviral activities. Deeper analysis on the structure–activity relationships of reported plant compounds and the role of specific functional groups in effecting viral inhibition can be considered as study points for the future of plant-based discovery of antivirals. Research studies during the years 2000s and 2010s involving investigation of plant sources as anti-SARS-CoV agents were focused on the inhibition of the non-structural proteins, 3CLpro and PLpro and spike and membrane structural proteins. Although these proteins are effective and ideal antiviral targets, there are gaps in information on plant-based interventions as inhibitors for alternative protein targets, e.g., envelope, nucleocapsid, and enzymes such as RNA-dependent RNA polymerase (RdRp) and hemagglutinin esterase (HE). Numerous studied have emerged highlighting the potential anti-viral activity of phytomolecules mediated through inhibition of ACE2 receptor, thereby preventing virus attachment to host cell. Citing the critical importance of structural proteins and ACE inhibitors in CoV and SARS-CoV-2 infections, efforts to identify potent phytomolecules that play dual role of ACE2 inhibition and inhibition of SARS-CoV-2 protein targets can be taken up to bridge the knowledge gap. The onset of pandemic saw a rise in publication of innumerable in silico studies that screened through libraries of phytomolecules and identified binding ability with molecular targets of SARS-CoV-2. More number of in vitro studies and plant therapy-based clinical trials are required to further validate the data obtained through in silico studies which can pave way for systematic use of phytotherapy for SARS-CoV-2 treatment.
Table 6.
Phytomolecule | Class of compound | SARS-CoV-2 target | References |
---|---|---|---|
Amentoflavone | Flavone | GLN493, SER494, and GLY496 AAR | [93] |
Baicalin | Flavone | Mpro pocket 2 | [94] |
Bismahanine | Alkaloid | GLU406 (Spike protein) | [93] |
Coagulins and Withanolides | Triterpenoids | AAR (Spike protein) | [93] |
Curcumin | Polyphenols | Helicase pocket 32 | [94] |
Farnesol | Terpenoid | Spike pocket10 | [94] |
Graecunin E | Saponins | THR415 and GLN493 AAR (Spike protein) | [93] |
Kamalachalcone C | Chalcone | GLN493, GLN492, ARG403, and GLU406 AAR | [93] |
Pseudojervine | Alkaloid | AARs GLN493, GLY496 and SER494 of spike protein | [93] |
Theaflavin | Catechins | Spike pocket 19 | [94] |
Urosolic acid | Terpenoid | Nsp14 pocket 2 | [94] |
The highly infectious and transmissive nature of SARS-CoV-2 has led to catastrophic ramifications on the polity and economies of various countries. Importance of finding workable solutions could not be overemphasized. Although the genome of SARS-CoV-2 has been mapped and its biology as well as etiology have been elucidated, the mechanism of zoonotic spillover of the virus causing it to result in this global pandemic is still being investigated. The first resort to treatment included several synthetic antimalarial and anti-HIV drugs being repurposed. Challenges of vaccine development against viruses will ever remain open. Examples of HIV, influenza, SARS-CoV, MERS-CoV, among several others, testify to the challenges. Vaccine against viruses offer limited degree of cross protection mainly due to extensive diversity among the antigenic variants. Besides, not all CoV genes are recombinant molecules. The complete genome sequence of HCoV-NL63 indicated that this virus was not a recombinant, but rather a new group 1 Coronavirus [60]. Human population density causes particular problems in exemplification of early mutation and structural changes due to large variations. The second surge in COVID-19 testifies to this fact amply. The extensive diversity was observed even among the strains belonging to the same phylogenetic sub-cluster [2]. With the emergence and re-emergence of new and old viral infections constantly posing a growing challenge to the survival of mankind [61], there is a constant demand for novel antiviral agents that are more economical, accessible and bear fewer chances of toxicity and viral resistance.
However, the toxic side effects exerted by synthetic drugs can be circumvented using plant-based-natural therapeutics. With studies conducted by investigating plant-based therapeutics for CoV treatment spanning over two decades, a promising plant-based cure for SARS-CoV-2 may see the light if characterized by in silico, in vitro, in vivo studies with special emphasis on its biocompatibility studies elucidating its pharmacological and toxicological profiles. In developing countries, community practice of using local medicines and drug formulations clearly evinced improved immunity against viruses. Chinese pharmacopeia, one of the most traditional yet well founded traditional medicinal practice, which established the TCM system, has been an important part of Chinese citizenry health system for centuries and is supported by the national government. However, lack of scientific validations have created suspicion on the usage of certain wild animals and plants in the TCM. In India, traditional medicinal practice systems, e.g., Ayurveda, Unani, and Siddha prescribe several traditional medicines against viral diseases, particularly for boosting immunity. Acetogenin, a compound found in papaya leaf helps in preventing disease such as malaria and dengue. Medical practitioners recommend administering papaya leaf extract, which is commercially marketed, in capsules as effective cures for dengue. Papain and alkaloids are nutrients, which act as strong antioxidants, and in turn, enhance the body’s immunity. During the current outbreak of SARS-CoV-2, the Indian government had recommended the public to take “kadha” which contains a wide spectrum of plant-based extracts and dry spices. In Tamil Nadu state, the government, in fight against COVID-19, freely distributed to public, Kabasura kudineer, an herbal formulation, which contains T.chebula as one of its important herbal constituents. However, systematic scientific validations for most of their derived phytomolecules are yet to be conducted. Systematic research in phytomolecular pathways of acting on enveloped protein molecules and potential of preferential binding to the receptor cells in the humans could result in searching robust answers to combating deadly viruses with the significant benefits of minimizing the side effects. Since in practice, plant-based drugs and immunity boosters use a broad combination, computation approaches through in silico approach can produce high accuracy in determining individual pathway mechanisms.
The research outcomes of phytomolecular investigations using the in silico approach, in vitro and in vivo approaches have potential to create a new health development regime not for the humans alone, but also for the domestic and wild animals in India and across the world. Deaths of Asiatic lions (Panthera leo leo) in few zoos in India recently due to suspected COVID-19 have raised issue of zoonotic intensity in Asian big cats (ABC). One or two of those Asiatic lions had also tested positive to the canine distemper virus that might have created comorbidity like medical situations. Phytomolecular approach to improving immune response in ABCs could be a distinct possibility using the network pharmacology pathway and in silico analytics.
Further research in this respect will be able to address the present gaps in identifying plant-based interventions as inhibitors for the structural proteins such as spike, envelope, membrane, and nucleocapsid. Advancements in this research could provide significant tools in epidemiology and could be effectively used in treatments and prophylaxis. With the growing interests of the public and governments, across the world, in improving human and animals’ immunity to the lethal viruses, e.g., SARS-CoV-2, investments in resources, time and money, on phytomolecular research could have direct and long term bearing on securing human and animals’ health protection regime.
Author Contribution
Data collection and Writing of manuscript: VC. Content development and Editing: SKN. Data analysis, Editing and Formatting: KGN. Conceptualization and Drafting: JJ. Overall correction and supervision: WA.
Funding
This research did not receive any specific Grant from funding agencies in the public, commercial, or nonprofit sectors.
Declarations
Conflict of interest
The authors declare that there are no conflicts of interest.
Footnotes
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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