ABSTRACT

The ongoing outbreak of the existing and mutated strains of coronavirus has been a cause of great concern worldwide. It has posed critical challenges for medical researchers and public health. Though a staggering number of vaccines have been developed, few of which are still under various phases of clinical trials, the development strategy for the COVID-19 therapy is the need of the hour. Heterocyclic moieties are pivotal in the field of medicine. This review covers the different classes of pre-existing drugs constituting various heterocyclic analogs that have been repurposed for the possible treatment of the COVID-19 disease. Moreover, it can also help the pharmaceutical industry to develop a new class of advanced medicine to fight against Covid- 19.

Keywords: Coronavirus; COVID-19; Hydroxychloroquine; Remdesivir; SARS CoV2

Abbreviations: COVID-19: Coronavirus disease of 2019; SARS CoV2: Severe Acute Respiratory Syndrome coronavirus; MERS CoV: Middle East Respiratory Syndrome coronavirus; UK:4. United Kingdom; CoV: Coronavirus; RNA: Ribonucleic Acid; ACE 2: Angiotensin-Converting Enzyme; RdRp: RNA-dependent RNA polymerase; WHO: World Health Organization; LPV/r: Lopinavir/ritonavir; RDV: Remdesivir; RCV: Respiratory Syncytial Virus; NHC: National Health Commission; HCV: Hepatitis C Virus; HIV: Human Immunodeficiency Virus; CQ: Chloroquine; HCQ: Hydroxychloroquine; AZM: Azithromycin; IMP: Importin; IVIg: Intravenous Immunoglobulin; H1N1: Hemagglutinin type 1 and Neuraminidase type 1; GABA: Gamma-Aminobutyric Acid; CNS: Central Nervous System

Introduction

The global pandemic COVID-19 caused by the novel coronavirus named Severe Acute Respiratory Syndrom2 (SARS CoV2) has been a cause of great concern worldwide [1]. To date, no efficient therapy is available to treat this disease completely. Several heterocyclic drug moieties are being repurposed with adequate doses to treat the patients contracted with this virus. Heterocyclic compounds have an immense role in drug discovery and development. Among the various medical applications, heterocyclic compounds play an active role as anti-bacterial, anti- viral, anti-fungal, anti-tumor, and anti-covid-19 agents as well [2]. Coronavirus belongs to the family of viruses having a single stranded-RNA genome and capable of causing mild to severe symptoms of respiratory distress [3] (Figure 1).

The novel coronavirus has 79% similarities in genome sequence with Severe Acute Respiratory Syndrome coronavirus (SARS CoV) and 50% similarities in genome sequence with the Middle East Respiratory Syndrome coronavirus (MERS CoV). The outer part of the virus has spike proteins that bind with Angiotensin- Converting Enzyme 2(ACE 2) of the host cell in the alveolar wall of the respiratory system. SARS CoV2 is endocytosed into the cytoplasm of pneumocyte where uncoating takes place by the lysosomal enzymes and the virus utilizes the host’s RNA-dependent RNA polymerase (RdRp) for viral genome replication [4]. They destroy the pneumocytes resulting in the high release of cytokines that causes systematic manifestations (Figure 2) [5]. The virus transmits through the droplets during respiration and symptoms can occur within 2-14 days. Furthermore, new coronavirus strains B.1.1.7 and B.1.351 have been identified in late 2020 in UK and South Africa, respectively that is more deadly (irrespective of the age, gender, and pre-existing health problems) than the previous circulating version of the coronavirus [6,7]. Reports show that these new strains having certain spike mutations replicate more quickly and spread more readily among humans [8,9]. The overall mortality rate of this disease is about 5.6% that surged up to 14% and more in many countries such as Italy, and the UK [10]. The reported complications include pneumonia, neurological complications, a multi- organ failure that may begin with fever, cold, cough, and fatigue. Senior citizens and patients with hypertensive, diabetic, or immune-compromised conditions are at higher risk [11] (Figure 3). Prominent pharmaceutical treatment options Though no effective treatment therapy has been designed yet, WHO has suggested some previously used drugs (Table 1) [12-18] for the possible treatment for COVID-19. This review represents various antiviral and antimalarial drugs that inhibit the viral replication or the virus entry into the host cells at different levels.

Nucleoside and Nucleotide Analogs

Synthetic analogs of pyrimidines and purines with modified sugar moiety are referred to as nucleoside and nucleotide analogs (Figure 4). These analogs are constantly being evaluated for their antiviral activities with lower toxicity [19].

Galidesivir

The adenosine nucleoside analog Galidesivir is a potential antiviral drug for coronavirus treatment. Galidesivir (BCX4430) displays broad-spectrum antiviral activity against various pathogens including coronavirus. It is a nucleoside RNA polymerase inhibitor that disrupts the process of viral replication. It is metabolized to the active triphosphate form by ellular kinases. The nucleotide binds to the active site of the viral enzyme and gets incorporated into the growing viral RNA-strand leading to the chain termination [20,21]. Galidesivir is currently in the advanced development stage under the Animal Rule to combat multiple potential viral threats including coronavirus. It was safe and well-tolerated in Phase 1 clinical trials against coronavirus by both intravenous and intramuscular routes of administration in healthy subjects. In April 2020, Bio Cryst began enrollment of a randomized, double-blind, placebo-controlled clinical trial to assess the safety and antiviral effects of galidesivir in COVID 19 patients. However, galidesivir is under phase 2 human trial in Brazil and various other places in the world [22] and has not been deemed safe and effective by the FDA.

Ribavirin

It is a guanine nucleoside analog with activity against multiple RNA viruses including respiratory syncytial virus, SARS CoV and MERS CoV. Ribavirin inhibits the RNA- dependent RNA polymerase (RdRp) and hence inhibiting the viral protein synthesis [23]. Ribavirin was used extensively during the 2003 SARS outbreak. In vitro tests showed that ribavirin inhibits the beta coronavirus at higher concentrations [24]. It inhibits the natural guanosine generation by directly inhibiting inosine monophosphate dehydrogenase that is crucial for the production of guanine precursor to guanosine to promote the destabilization of viral RNA [25]. Ribavirin should be administered via intravenous infusion (500mg twice a day) in combination with interferon or LPV/r for up to ten days [26]. Intravenous ribavirin is suggested by China’s NHC for COVID 19 only as an add-on therapy to LPV/r or interferon [27]. Several adverse effects such as hemolytic anemia, leukopenia, fatigue, rash, and gout are generally observed from this medication (Scheme 1).

Viramidine

Viramidine or taribavirin is the most used derivative of ribavirin that shows broad-spectrum antiviral activity and immunomodulatory effects. Viramidine is a 3- carboxamidine prodrug of ribavirin [28,29]. Viramidine has better liver targeting property than ribavirin. Viramidine in combination with other drugs such as interferon is under clinical trial for the treatment of coronavirus disease.

Remdesivir

Remdesivir (RDV) was first developed for the treatment of Ebola virus. It is a phosphoramidate prodrug diastereoisomer (GS-5734)9a of a pyrrolo [1,2] (triazin-4- amino) adenine C - nucleoside analog [30]. Agostini et al. reported that remdesivir can potentially inhibit corona viruses such as SARS CoV1 and MERS CoV in vitro [31], with a half-maximal effective concentration (EC50) of 0.77μM. There are no published studies that justify the reactivity of remdesivir in animal models of SARS CoV2 in vivo. RDV is metabolized to an adenosine nucleoside analog via a number of steps. It is present as a monophosphate form extracellulary and as a triphosphate form intracellularly. The monophosphate form gets phosphorylated to the active nucleoside triphosphate form which is utilized by the viral RNA- dependent RNA polymerase (RdRp) to inhibit the viral replication through delayed chain termination [32,33 ]. Remdesivir possesses broad-spectrum antiviral activity against many viruses like Ebola [34], Nipah [35], and respiratory syncytial virus (RCV) family [36]. The structureactivity relationship studies pointed towards the criticality of the 1’-CN as compared to the unmodified nucleoside. The existence of the 3’-OH group allows the nucleophilic attack on the next coming nucleotide. 1’-CN substituent of remdesivir sterically clashes with RdRp (residue S861) upon further chain elongation (remdesivir + three additional nucleotides) distorting the position of RNA that prevents translocation [37]. Remdesivir is administered via intravenous injection (IV) with a loading dose of 200mg on the first day followed by a 100mg maintenance dose for up to ten days. Reports suggest that during the treatment no adverse effects were observed in association with the IV infusion. Daily administration of 10mg/kg of remdesivir yielded a short plasma half-life of the prodrug but sustained intracellular levels of the triphosphate form [38]. Recently, through a compassionate use indication, remdesivir has supportive evidence for yielding some clinical improvement in COVID 19 patients. Currently, remdesivir is not recommended by WHO and China’s NHC except for the hospitalized severe COVID-19 cases [39,40].

Sofosbuvir

Sofosbuvir is an anti-hepatitis C virus (HCV) drug that is clinically approved and also effective against other positive-strand RNA viruses. There are certain in-silico and in- vitro evidences that prove the effectiveness of sofosbuvir against SARS CoV-2. Sofosbuvir and its derivatives could potentially inhibit the SARS CoV-2 RdRp and it is safe and well-tolerated with daclatasvir at 400mg and 60mg respective doses daily. Sofosbuvir is converted into its nucleoside triphosphate active form through phosphorylation within the host cell. This terminates the RNA replication in the nascent viral genome through competition with the nucleotides of the virus [41]. Clinical trials show that more rapid recovery of COVID-19 patients was observed when dosed with sofosbuvir and daclatasvir in one arm with a significantly higher survival probability when compared with ribavirin in another arm [42]. However, this combination causes severe adverse effects like leucopenia and gastrointestinal disorders (GI). The clinical trials are still in progress to elucidate the antiviral efficacy against SARS CoV-2 (Scheme 2).

Tenofovir

Tenofovir is a reverse transcriptase inhibitor that is active against HIV-1, HIV-2, hepatitis B virus, and coronavirus. The active tenofovir diphosphate form binds to the viral RdRp and inhibits viral replication. It is able to bind tightly with SARS CoV-2 RdRp with binding energy -6.9 kcal/mol and contradicts the polymerase function [43]. Tenofovir in combination with Emtrcitabine could potentially increase its efficiency. However, no complete and conclusive clinical data is available suggestingthe exact mechanism of action of tenofovir and its analogs to treat COVID-19 patients. Common side effects of this antiretroviral drug include nausea, vomiting, diarrhea, headache, pain, back pain and sleep disturbances [44] (Scheme 3).

Protease Inhibitors

Protease Inhibitors (Figure 5) are substances with the ability to inhibit the enzymes’ proteolytic activity. They continue to appear for immediate use in the treatment of SARS CoV2 infections [45,46].

Lopinavir and Ritonavir

Lopinavir and Ritonavir (LPV/r) is a combination protease inhibiter that was firstly approved for the treatment of Human Immunodeficiency Virus (HIV) infections [47]. This combination shows potent antiviral activity against Severe Acute Respiratory Syndrome coronavirus (SARS CoV). Lopinavir binds to the viral protease and prevents the cleavage of Gag-Pol polyprotein, which produces immature non-infectious virus particles. Though Lopinavir does not affect the already infected cells, the main antiviral action of protease inhibitor is to prevent the subsequent infection of cells. Ritonavir is co-administered with Lopinavir to increase the plasma concentration of lopinavir by inhibiting the cytochrome P450 3A (CYP3A) metabolism and thus acts as its pharmacokinetics enhancer [48]. Lopinavir and Ritonavir (LPV/r) are shown to be effective for the treatment of MERS and SARS coronavirus disease [49]. COVID-19 patients receive either LPV/r (400/100) twice a day for 14 days, but this treatment therapy has not demonstrated much benefit to the patients when compared to the patients receiving standard care [50]. Moreover, this combination causes more side effects including nausea, diarrhea, abdominal pain, elevation of liver enzymes, and prolongation of QT and PR intervals [51]. China’s NHC has suggested LPV/r [52], but this combination has no proven clinical efficacy towards COVID-19. So, this combination drug therapy is not recommended by NIH [53].

Pyrazine Analogs

The volatile, nitrogen-containing heterocyclic pyrazines find various applications in the pharmaceutical industries [54]. Pyrazine derivatives (Figure 6) have been well reported as anti- bacterial, anti-diabetic, anti-viral, and anti-cancer agents [55].

Favipiravir

Favipiravir (T-705, 6-fluoro-3-hydroxy pyrazin-2-carboxamide) is a prodrug of a purine nucleotide, which selectively inhibits the RNA-dependent RNA polymerase of the influenza virus [56]. Favipiravir exhibits acidic properties due to the presence of the hydroxyl group [57]. Favipiravir undergoes intracellular phosphor ribosylation to convert into an active form, Favipiravir-RTP (ribofuranosyl-5’-triphosphate) (11), which is recognized as a substrate by RdRp and inhibits the RNA polymerase activity [58]. Favipiravir also inhibits the other pathogenic RNA viral infections, such as flavivirus, arenavirus, bunyavirus, alphavirus, and norovirus Furuta et al. [59]. Less preclinical support has been established for favipiravir to treat SARS CoV 2 compared to remdesivir. The recommended dose of favipiravir is 1200mg to 1800mg every 12 hours [60]. In March 2020, the National Medical Products Administration of China approved favipiravir as the first anti- COVID-19 drug in China, since the clinical trials had demonstrated efficacy with minimum adverse effects.

Aminoquinoline Analogs

Aminoquinolines (Figure 7) are the quinoline derivatives that have inhibitory effects on DNA replication, cytokine production, and chemotaxis [61], Chloroquine (11) and Hydroxychloroquine (12) play a promising role in the management of SARS Cov2 outbreak by increasing the pH and conferring anti-viral effects [62].

Chloroquine

Chloroquine (4-amino quinoline) is a classic anti-malarial and anti- autoimmune drug [63]. CQ can easily diffuse in the cytoplasm across the cell membrane to acidic vesicles in its unprotonated form. On protonation, it gets entrapped in the vesicles. Protonated CQ is not able to diffuse out of the lysosomes or endosomes, and hence remains retained in the cellular compartment with the hydrolases Savarino et al. [64]. Its effect of neutralizing the acidic endosomal pH supports broad-spectrum antiviral activity by blocking the endosome-mediated viral entry at the pre- and post-entry level. It blocks the virus infection and interferes with the glycosylation of cellular receptors of SARS CoV [65]. In Several clinical trials of China, the effectiveness of chloroquine phosphate has been proved against COVID-19. Chloroquine shows anti-viral effects, thus reducing the binding efficiency between ACE2 of host cells and the SARS Cov 2 spike protein [66].

Hydroxychloroquine

Hydroxychloroquine (HCQ) is an analogue of chloroquine and a less toxic metabolite of CQ. It was initially considered as an antimalarial drug that inhibits the entry of virus into the host cell, altering the synthesis of viral proteins [67]. This drug could be toxic and fatal if overdosed. It has several adverse effects such as retinopathy, liver enzyme elevation, blood count changes, alteration in mood, and QTc-prolongation [68]. Both HCQ and CQ could decrease the cytokine production. The mechanism of action of these two scaffolds is similar as both act as a weak base. The beneficial impact of HCQ (200mg three times a day for 10 days) or HCQ + azithromycin (AZM) (500 mg for day 1 followed by 250 mg/day for the next 4 days) on the viral negativity at day 6 was reported in a non-randomized open-label clinical trial in France enrolling COVID-19 patients treated with HCQ or untreated controls [69]. Since the COVID-19 outbreak, these drugs have shown an effective in-vitro antiviral effect on SARS CoV-2, particularly HCQ in combination with azithromycin [70].

Lactone Analog

The cyclic carboxylate esters called lactones (Figure 8) have a huge contribution in the development of antiviral drugs with lower toxicity. A rapid response against COVID-19 was reported when the patients contracted with coronavirus were dosed with the cyclic carboxylate ester (lactone) Ivermectin [71].

Ivermectin

Ivermectin, a macrocyclic lactone belongs to the family of Avermectins. It is a mixture of the two components H2B1a (90%) (13) and H2B1b (10%) (14). The structural difference between these two is the presence of one extra methyl group in Ivermectin B1a [72]. Ivermectin is an antiparasitic agent that shows invitro antiviral activity also against a wide range of viruses [73]. Ivermectin disassociates the preformed importin (IMP) alpha/ beta1 heterodimer which is responsible for the nuclear transport of viral protein cargos that disrupts the immune evasion mechanism of the virus [74,75]. Recent in-vitro studies prove that Ivermectin has the ability to reduce viral RNA up to 5,000-folds after two days of infection with SARS CoV-2 [76].

Indole Analog

Indole derivatives (Figure 9), being diverse in nature, display a wide range of promising biological activities [77,78]. They have been shown effective against the novel coronavirus.

Arbidol (Umifenovir)

Arbidol (approved by Russia and China) is a synthetic antiviral drug used for the treatment of seasonal influenza. It is well-tolerated against SARS CoV with lower toxicity [79]. Arbidol is effective only when given in combination with other antiviral drugs such as LPV/r or interferon. Arbidol targets the S protein/ACE 2 interaction, thus inhibiting the membrane fusion of the viral envelope to the host cell. It particularly focuses on inhibiting the fusion of the virion and the type II pneumocytes [80]. Its major adverse effects include diarrhea, nausea, dizziness, and elevated serum transaminase [81].

Carboxylate Ester Analog

The carboxylic acid functional group (Figure 10) displays promising applications in the pharmaceutical industry as it adds to the hydrophilicity of the drug [82].

Oseltamivir

Oseltamivir is a flu drug that shows antiviral activity against influenza A and B. It inhibits the viral neuraminidase but was ineffective for the COVID-19 patients [83]. The combination of oseltamivir with baloxavir also proved fruitless in curing the patients with coronavirus disease.
However, a doctor’s team reported that if oseltamivir was combined with lopinavir (7) and ritonavir (8), it could improve the conditions of covid 19 patients significantly [84].

Glucose Analog

Glucose analogs provide active anti-covid candidates by mimicking the glucose structure [85].

2-Deoxy-D-Glucose

2-Deoxy-2-Glucose has received much attention these days for its emergent use in anti-covid therapy. It is a non-metabolized analog of glucose [86] that has a hydrogen atom instead of the hydroxyl group at the second carbon position [87]. The mimicking property of 2-DG enables it to naturally exploit the glucose uptake mechanism, a universal characteristic of tumor cells and viruses [88]. SARS CoV-2 operates on the glucose metabolism for its replication and energy requirements [89]. This sugar analog enters the glycolysis cycle partially, interrupts the glucose phosphorylation by creating an inhibitory feedback effect on the hexokinase enzyme [90], causing the depletion of cellular ATP. This results in the inhibition of the cell cycle and hence leads to cell death ceasing the viral replication. So, besides its therapeutic use in seizures, cancer and, viral infections, clinical trials prove its efficient use in the treatment of COVID-19 helping the faster recovery of the hospitalized patients and reducing the dependence on supplemental oxygen. 2-DG is a non-selective and dose-dependent oral administrative drug that can cause several adverse effects on the heart, platelets, adrenal medulla, and neurons [91]. However, the reports showed that its cautious and prescribed use has resulted in the RT-PCR negative conversations in the COVID-19 patients (Figure 11).

Conclusion

Drug discovery is a challenging and time-consuming process. Several drugs have been suggested to treat COVID-19, but no proven studies are available which clarify the evidence to end the pandemic completely. Almost all the pharmaceuticals are under investigation and further researches via clinical trials. Repurposing of the preexisting drugs became an approach as a rapid response measure to the emergent pandemic. This review represents an overview of the current therapeutic drugs involving heterocyclic moieties that are suggested for the treatment of COVID-19 caused by SARS CoV-2. The literature showed that Remdesivir is moderately recommended by the NIH, that inhibits the viral replication and the anti-viral activity of CQ and HCQ has been identified in in-vitro studies though the evidence of these drugs is limited. Furthermore, the clinical trials depicted that the sugar analog 2-Deoxy-D-Glucose proved highly effective in the anti-covid therapy that works by inhibiting the viral replication in the host cell. So, it is anticipated that this glucose analog will bring immense relief to the COVID-19 patients.

Acknowledgement

Authors acknowledge Department of Chemistry, University of Delhi. Authors are thankful to Council for Scientific and Industrial Research, and University Grants Commission for providing fellowships and fundings.

Conflict of Interest

The authors declare that they have no conflict of interest.

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ABSTRACT

The ongoing outbreak of the existing and mutated strains of coronavirus has been a cause of great concern worldwide. It has posed critical challenges for medical researchers and public health. Though a staggering number of vaccines have been developed, few of which are still under various phases of clinical trials, the development strategy for the COVID-19 therapy is the need of the hour. Heterocyclic moieties are pivotal in the field of medicine. This review covers the different classes of pre-existing drugs constituting various heterocyclic analogs that have been repurposed for the possible treatment of the COVID-19 disease. Moreover, it can also help the pharmaceutical industry to develop a new class of advanced medicine to fight against Covid- 19.

Keywords: Coronavirus; COVID-19; Hydroxychloroquine; Remdesivir; SARS CoV2

Abbreviations: COVID-19: Coronavirus disease of 2019; SARS CoV2: Severe Acute Respiratory Syndrome coronavirus; MERS CoV: Middle East Respiratory Syndrome coronavirus; UK:4. United Kingdom; CoV: Coronavirus; RNA: Ribonucleic Acid; ACE 2: Angiotensin-Converting Enzyme; RdRp: RNA-dependent RNA polymerase; WHO: World Health Organization; LPV/r: Lopinavir/ritonavir; RDV: Remdesivir; RCV: Respiratory Syncytial Virus; NHC: National Health Commission; HCV: Hepatitis C Virus; HIV: Human Immunodeficiency Virus; CQ: Chloroquine; HCQ: Hydroxychloroquine; AZM: Azithromycin; IMP: Importin; IVIg: Intravenous Immunoglobulin; H1N1: Hemagglutinin type 1 and Neuraminidase type 1; GABA: Gamma-Aminobutyric Acid; CNS: Central Nervous System