MECHANISM AND RESISTANCE STUDIES OF SARS-CoV-2 MPRO INHIBITOR POMOTRELVIR (PBI-0451)

Background: The unprecedented scale of the COVID-19 pandemic and rapid evolution of SARS-CoV-2 variants underscores the need for broadly active inhibitors with a high barrier to resistance. The coronavirus main protease (Mpro) is an essential viral enzyme required for viral polyprotein processing and is highly conserved across human coronaviruses. Pomotrelvir (PBI-0451) is a novel Mpro inhibitor currently completing phase 2 clinical trial. Here we describe the mechanism of action, broad activity against SARS-CoV-2 clinical isolates, combination studies with other SARS-CoV-2 inhibitors and favorable resistance profile of pomotrelvir. Method(s): The kinetic parameters of pomotrelvir Mpro inhibition and its interaction with nirmaltrevir were determined in a kinetic protease assay. The IC50s of pomotrelvir on mutant Mpro proteins were measured in an endpoint Mpro assay. Combination studies of pomotrelvir with remdesivir and molnupiravir were carried out in A549-hACE2 cells infected with SARS-CoV-2 NLuc virus. Activity against SARS-CoV-2 clinical variants was assessed by infection of A549-ACE2-TMPRSS2 cells followed by immunostaining of the viral nucleocapsid protein. Result(s): Pomotrelvir is a potent competitive inhibitor of SARS-CoV-2 Mpro (Ki =2.7 nM). Binding of pomotrelvir and the Mpro inhibitor nirmatrelvir to the active site is mutually exclusive. In the SARS-CoV-2 NLuc assay, pomotrelvir is additive when combined with remdesivir or molnupiravir, two nucleoside analogs targeting viral RNA synthesis. When the effect of Mpro substitutions previously selected in a resistance study of pomotrelvir were analyzed in an enzyme assay, only Mpro-N133H showed a significant increase in IC50 (45-fold). The catalytic efficiency of Mpro-N133H is reduced by 10-fold and the recombinant virus SARSCoV-2 (WA1) -N133H is not viable, suggesting that N133H has lower replicative fitness. Lastly, pomotrelvir exhibits broad activity against all SARS-CoV-2 clinical isolates tested to date, including five omicron variants. Conclusion(s): PBI-0451 is a potent competitive inhibitor of SARS-CoV-2 Mpro and is broadly active against SARS-CoV-2 clinical isolates including omicron variants. Results from inhibitor interaction studies support the potential combination of pomotrelvir with remdesivir and molnupiravir but not nirmatrelvir. Enzymatic characterization of in vitro selected pomotrelvir resistant variants indicates they either confer no resistance or have reduced fitness.

SARS-CoV-2 Nsp13 Catalytic Efficiency is Regulated by ATP: Mg2+ Stoichiometry and Functional Cooperativity Among Nsp13 Molecules

Coronavirus disease 19 (COVID-19) is a highly contagious and lethal disease caused by the SARS-CoV-2 positive-strand RNA virus. Nonstructural protein 13 (Nsp13) is the highly conserved ATPase/helicase required for replication of the SARS-CoV-2 genome which allows for the infection and transmission of COVID-19. We biochemically characterized the purified recombinant SARS-CoV-2 Nsp13 helicase protein expressed using a eukaryotic cell-based system and characterized its catalytic functions, focusing on optimization of its reaction conditions and assessment of functional cooperativity among Nsp13 molecules during unwinding of duplex RNA substrates. These studies allowed us to carefully determine the optimal reaction conditions for binding and unwinding various nucleic acid substrates. Previously, ATP concentration was suggested to be an important factor for optimal helicase activity by recombinant SARS-CoV-1 Nsp13. Apart from a single study conducted using fixed concentrations of ATP, the importance of the essential divalent cation for Nsp13 helicase activity had not been examined. Given the importance of the divalent metal ion cofactor for ATP hydrolysis and helicase activity, we assessed if the molar ratio of ATP to Mg2+ was important for optimal SARS-CoV-2 Nsp13 RNA helicase activity. We determined that Nsp13 RNA helicase activity was dependent on ATP and Mg2+ concentrations with an optimum of 1 mM Mg2+ and 2 mM ATP. Next, we examined Nsp13 helicase activity as a function of equimolar ATP:Mg2+ ratio and determined that helicase activity decreased as the equimolar concentration increased, especially above 5 mM. We determined that Nsp13 catalytic functions are sensitive to Mg2+ concentration suggesting a regulatory mechanism for ATP hydrolysis, duplex unwinding, and protein remodeling, processes that are implicated in SARS-CoV-2 replication and proofreading to ensure RNA synthesis fidelity. Evidence is presented that excess Mg2+ impairs Nsp13 helicase activity by dual mechanisms involving both allostery and ionic strength. In addition, using single-turnover reaction conditions, Nsp13 unwound partial duplex RNA substrates of increasing doublestranded regions (16-30 base pairs) with similar kinetic efficiency, suggesting the enzyme unwinds processively in this range under optimal reaction conditions. Furthermore, we determined that Nsp13 displayed sigmoidal behavior for helicase activity as a function of enzyme concentration, suggesting that functional cooperativity and oligomerization are important for optimal activity. The observed functional cooperativity of Nsp13 protomers suggests the essential coronavirus RNA helicase has roles in RNA processing events beyond its currently understood involvement in the SARS-CoV-2 replication-transcription complex (RTC), in which it was suggested that only one of the two Nsp13 subunits has a catalytic function, whereas the other has only a structural role in complex stability. Altogether, the intimate regulation of Nsp13 RNA helicase by divalent cation and protein oligomerization suggests drug targets for modulation of enzymatic activity that may prove useful for the development of novel anti-coronavirus therapeutic strategies. This work was supported by the Intramural Training Program, National Institute on Aging (NIA), NIH, and a Special COVID-19 Grant from the Office of the Scientific Director, NIA, NIH.Copyright © 2023 The American Society for Biochemistry and Molecular Biology, Inc.

SARS-CoV-2 USES ENDOSOMAL MEMBRANES TO BUILD REPLICATION ORGANELLES

Background: The health emergency caused by the COVID-19 pandemic has evidenced that the frequency of spillover episodes of viruses infecting bats to other species, including humans, has significantly increased compared to previous decades. Besides SARS-CoV-2, six other human coronaviruses (NL63, 229E, OC43, HKU1, SARS-CoV and MERS-CoV) emerged in the 20th and 21st century, most likely because of cross-species transmission events from bats. While many of these coronaviruses cause mild respiratory infections, MERS-CoV, SARS-CoV and SARS-CoV-2 can cause severe respiratory distress, particularly in immunocompromised individuals. However, unlike SARS-CoV and MERS-CoV, SARS-CoV-2 is highly contagious, very stable, with many person-to-person transmissions, which can occur even before individuals exhibit any symptoms. While vaccines are readily available, the emergence of new SARS-CoV-2 variants along with the increasing incidence of individuals developing long COVID urge to develop antivirals specific to treat COVID-19. To reach this goal, we need to have a working knowledge of the host-SARS-CoV-2 interactions to identify targets for therapeutic intervention. Method(s): Following that rationale, we focused on understanding how SARSCoV- 2 generates replication organelles (ROs). All coronaviruses need to remodel cellular membranes to create these structures to allow the active replication and transcription of their genome. Due to their relevance for virus replication, disabling RO formation represents a promising strategy to fight SARS-CoV-2. However, the biogenesis mechanism, the origin, and type of these replication organelles are still a major focus of debate. To identify the cellular membranes that SARS-CoV-2 uses to generate ROs we used multiple cell lines and primary cells that were evaluated by fluorescence microscopy, genetic engineering, compounds that specifically inhibit cellular processes, and immunoprecipitation assays to validate protein-protein interactions. We also used RT-qPCR to assess viral genome replication. Result(s): SARS-CoV-2 uses the viral protein NSP6 to remodel endosomal membranes juxtaposed to the ER to generate replication organelles. Specifically, the virus depends on Clathrin, COPB1, and Rab5 for efficient SARSCoV- 2 RNA synthesis. Conclusion(s): Uncovering the origins and mechanism(s) by which SARS-CoV-2 assembles ROs opens new avenues to develop strategies to interfere with RO biogenesis and halt virus replication.

Phytomedicines for Covid-19: Opportunities and Obstacles

COVID-19 is a disease caused by SARS-CoV-2 that can trigger respiratory tract infection. Due to its tendency to affect the upper respiratory tract (sinuses, nose and throat) or lower respiratory tract (windpipe and lungs), this disease is life-threatening and affects a large number of populations. This virus's unique and complex nature enhances the scope to look into the direction of herbal plants and their constituents for its prevention and treatment. The herbal remedies can have preventive as well as therapeutic actions. This review focuses on various aspects of using herbal medicines for COVID-19, as herbal constituents may also have adverse effects. Various studies revealed that some medicinal plants show life-threatening adverse effects, so selecting plants, and their related studies should be appropriate and strategic. This article includes various factors that should be considered before herbal drug use in COVID-19 patients. These are clinical trials, safety, molecular mechanism, and self-medication, which have been elaborated. This article also discusses the targets of covid-19 and different coronavirus strains. As before, treatment diagnosis of the disease is very important. Various patents have been filed and granted for its proper diagnosis so that its treatment can be easy.Copyright © 2022 Society of Pharmaceutical Sciences and Research. All rights reserved.

A Review: Zinc as an Antivirus Alternative Treatment for Herpes Simplex Virus Infection

This study aimed to review zinc's effectiveness as an antivirus in treating herpes simplex virus infection. The authors use international journals published from 2000-2022, and use search engines such as Google Scholar, PubMed, and Science Direct with the keywords "zinc and herpes simplex virus". The herpes simplex virus that often causes symptoms in humans are HSV type 1 and type 2. The lesions appear as vesicles which then rupture into ulcers. Zinc is one of the most abundant nutrients or metals in the human body besides iron. Studies about the effects of zinc on HSV have shown that it has the function of inhibiting the viral life cycle. HSV attaches to the host cells to replicate and synthesize new viral proteins. Zinc can inhibit this process by depositing on the surface of the virion and inactivating the enzymatic function which is required for the attachment to the host cell, disrupting the surface glycoprotein of the viral membrane so it could not adhere and carry out the next life cycle, it can also inhibit the function of DNA polymerase that works for viral replication in the host cell. This article showed that zinc has effectiveness as an antivirus against the herpes simplex virus, therefore, patients infected with HSV can be treated with zinc as an alternative to an antivirus drug.Copyright © 2022 The Authors. Published by Innovare Academic Sciences Pvt Ltd.

The Emergence of Novel Coronavirus Disease, Global Treatment Update and its Containment Strategies in Overpopulated Countries: A Review

The ongoing pandemic of the novel coronavirus SARS-CoV-2 (COVID-19) has created a major challenge for the public health worldwide. The reported cases indicate that the outbreak is more widespread than initially assumed. Around 18 million people have been infected with 689,000 reported deaths (August 2020;the number is increasing daily);with a high mutation rate, this virus poses an even more serious threat worldwide. The actual source of COVID-19 is still un-clear;even if the initial reports link it to the Chinese seafood wet market in Wuhan, other animals such as birds, snakes, and many small mammals including bats are also linked with this novel coro-navirus. The structure of the COVID-19 shows distinctive proteins among which spike proteins have a pivotal role in host cell attachment and virus-cell membrane fusion in order to facilitate virus infection. Currently, no specific antiviral treatment or vaccine is available. Various drug can-didates, including SARS-CoV and MERS-CoV protease inhibitors, neuraminidase inhibitors, RNA synthesis inhibitors, ACE2 inhibitors and lungs supportive therapy, are under trials. Cell-based therapy also appeared with remarkable treatment possibilities. In this article, we endeavored to succinctly cover the current and available treatment options, including pharmaceuticals, cell-based therapy, and traditional medicine. We also focused on the extent of damages by this novel coron-avirus in India, Pakistan, and Bangladesh;the strategies adopted and the research activities initiat-ed so far by these densely populated countries (neighboring China) are explained in this review.Copyright © 2021 Bentham Science Publishers.

Remdesivir (GS-5734) for COVID-19 Treatment: Past and Recent Updates

Background: SARS-CoV-2 is a pandemic now, and several measures have been taken by countries to prevent, control, and treat the disease. WHO has been working meticulously and has been providing up to date information and statistics on incidences and death. Several broad--spectrum anti-viral drugs are available and have been used in the past to fight against the viral out-break. Recently remdesivir, an experimental prodrug from Gilead Sciences, has been found to be a potential drug to be used as a therapy to treat COVID-19. Objective(s): Here, we have reviewed several previous findings from the literature and present an up to date information on remdesivir. Result(s): Remdesivir was initially invented for use against Ebola virus treatment and has proved ef-fective against different strains of Ebola, Nipah, and other strains of coronaviruses. Clinical trials with remdesivir for COVID-19 patients have begun, and several off label use of remdesivir have been reported recently. Currently, the drug seems to have an effect against the SARS-CoV-2 virus, with side effects among a few patients. Although the results are not conclusive, they are partly promising. This review provides past and recent updates on the use of remdesivir. Conclusion(s): From the review, we conclude that the drug remdesivir is known to exhibit its mechanism of action by terminating the RNA synthesis, and it is a potential drug against the novel coron-avirus.Copyright © 2021 Bentham Science Publishers.

Feasibility of targeted antiviral therapy for acute respiratory viral infections in the COVID-19 pandemic.

The aim of this study was to analyze the efficacy and safety of using etiotropic therapy with favipiravir and molnupiravir that can selectively bind and inhibit not only SARS-CoV-2 proteins but also other RNA-containing pathogens of acute respiratory diseases. High transmission of pathogens, the risk of becoming chronic, frequent complications, cases of co-infection with several pathogens, which can lead to a more severe course of the disease, insufficient vaccination effectiveness, all this requires additional strategies for both prevention and treatment of acute respiratory viral infections. RNA-dependent RNA polymerase (RdRp), which has no equivalent in human cells, is involved in RNA synthesis and is an excellent therapeutic target for diseases caused by RNA viruses, including SARS-CoV-2. The long process of drug development and the "reuse" of drugs approved for other indications or successfully tested in terms of safety and tolerability pose the challenge of rapid establishment of an effective drug, including for the treatment of severe cases of COVID-19. Copyright © 2022, Dynasty Publishing House.

Omicron and Delta variant spike protein mutations comparison and their interaction with ACE2 receptor

The current outbreak of coronavirus-associated disease characterized as coronavirus disease 19 (COVID-19) marked its existence in late 2019. Since then, it has been a concern for human health and safety. Coronaviruses (CoVs) are known to cause a wide range of diseases;out of which common cold and pneumonia occur in human beings. In this review, we elaborate on the basic characteristics, structure, variants mutations and the pathological attributes of SARS-CoV 2. We also discuss the interaction of the viral proteins with the host cell receptor known as the ACE2 receptor and various therapeutics for the treatment of disease.

Current therapeutic strategies to combat coronavirus disease 2019

Coronavirus disease 2019 (COVID-19) is a disease caused by the novel coronavirus called severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). The name coronavirus was derived from their crown-like spikes that exist on their exterior. Coronaviruses have been classified into four main subcategories, namely, alpha, beta, gamma, and delta coronaviruses. SARS-CoV-2 belongs to the beta subgrouping and is one of the seventh coronaviruses to date infecting humans. At present, no vaccine or specific therapeutic agents have been approved for the treatment. Therefore, in the absence of particular vaccines or therapeutic agents for the treatment of SARS-CoV-2, “repurposed” FDA-approved drugs are in use to treat COVID-19 patients. This chapter selectively highlights the most current pharmacotherapeutic agents prescribed for the treatment of severe cases of COVID-19 patients. These agents include antiviral drugs, antibiotics, systemic corticosteroids, antiinflammatory drugs, and neuraminidase inhibitors including RNA synthesis inhibitors, convalescent plasma therapy, and traditional herbal medicines. © 2022 Elsevier Inc. All rights reserved.

Alternative role of motif B in template dependent polymerase inhibition

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) relies on the central molecular machine RNA-dependent RNA polymerase (RdRp) for the viral replication and transcription. Remdesivir at the template strand has been shown to effectively inhibit the RNA synthesis in SARS-CoV-2 RdRp by deactivating not only the complementary UTP incorporation but also the next nucleotide addition. However, the underlying molecular mechanism of the second inhibitory point remains unclear. In this work, we have performed molecular dynamics simulations and demonstrated that such inhibition has not directly acted on the nucleotide addition at the active site. Instead, the translocation of Remdesivir from +1 to-1 site is hindered thermodynamically as the post-Translocation state is less stable than the pre-Translocation state due to the motif B residue G683. Moreover, another conserved residue S682 on motif B further hinders the dynamic translocation of Remdesivir due to the steric clash with the 1′-cyano substitution. Overall, our study has unveiled an alternative role of motif B in mediating the translocation when Remdesivir is present in the template strand and complemented our understanding about the inhibitory mechanisms exerted by Remdesivir on the RNA synthesis in SARS-CoV-2 RdRp. © 2022 Chinese Physical Society.

Recombination in Positive-Strand RNA Viruses.

RNA recombination is a major driver of genetic shifts tightly linked to the evolution of RNA viruses. Genomic recombination contributes substantially to the emergence of new viral lineages, expansion in host tropism, adaptations to new environments, and virulence and pathogenesis. Here, we review some of the recent progress that has advanced our understanding of recombination in positive-strand RNA viruses, including recombination triggers and the mechanisms behind them. The study of RNA recombination aids in predicting the probability and outcome of viral recombination events, and in the design of viruses with reduced recombination frequency as candidates for the development of live attenuated vaccines. Surveillance of viral recombination should remain a priority in the detection of emergent viral strains, a goal that can only be accomplished by expanding our understanding of how these events are triggered and regulated.

Prospectus of advanced nanomaterials for antiviral properties

Viral hazards have suddenly increased in the form of the century's biggest pandemic through COVID-19. However, viruses are also associated with other human diseases, the severity of which range from the mild common cold to deleterious cancers and HIV. Conventional anti-viral therapies that have been developed to mitigate deleterious viral effects have not stood the test of time owing to their numerous limitations. This has burdened the research community worldwide with the challenging task of discovering advanced anti-viral strategies to overcome the limitations being faced. In this regard, fortunately, metal and inorganic nanoparticles offer respite as they exhibit tremendous anti-viral potential and are considered a powerful weapon against viral intrusions. Metal nanoparticles of various metals such as silver, gold, and copper have not only successfully attenuated the infectivity of malignant viruses (HIV, HSV, HINI, etc.) in in vitro conditions and in vivo conditions (mainly silver and zinc oxide nanoparticles) but have also successfully overcome the limitations faced by conventional anti-viral therapies. Acting in a resistance insensitive, age and co-morbidity independent and low cytotoxic manner, metal nanoparticles can successfully inhibit viral entry and other viral development processes. In the light of the mechanisms and advantages offered by metal nanoparticles, it is suggested to consider their usage in actual clinical practice rather than as an alternate therapy. Further, considering the mechanisms exhibited by metal nanoparticles to deprive the viral load, we anticipate that the current pandemic (COVID-19) can be treated to some extent via the aid of metal nanoparticles. The successful implication of the hypothesized mechanisms can offer abating strategies to combat the current pandemic and open new avenues to cope with future pandemics. In this prospective, we provide the frontiers and current scenario of various classes of nanoparticles being explored for antiviral activities.

Sindbis Macrodomain Poly-ADP-Ribose Hydrolase Activity Is Important for Viral RNA Synthesis.

ADP-ribosylation is a highly dynamic posttranslational modification frequently studied in stress response pathways with recent attention given to its role in response to viral infection. Notably, the alphaviruses encode catalytically active macrodomains capable of ADP-ribosylhydrolase (ARH) activities, implying a role in remodeling the cellular ADP-ribosylome. This report decouples mono- and poly-ARH contributions to macrodomain function using a newly engineered Sindbis virus (SINV) mutant with attenuated poly-ARH activity. Our findings indicate that viral poly-ARH activity is uniquely required for high titer replication in mammalian systems. Despite translating incoming genomic RNA as efficiently as WT virus, mutant viruses have a reduced capacity to establish productive infection, offering a more complete understanding of the kinetics and role of the alphavirus macrodomain with important implications for broader ADP-ribosyltransferase biology. IMPORTANCE Viral macrodomains have drawn attention in recent years due to their high degree of conservation in several virus families (e.g., coronaviruses and alphaviruses) and their potential druggability. These domains erase mono- or poly-ADP-ribose, posttranslational modifications written by host poly-ADP-ribose polymerase (PARP) proteins, from undetermined host or viral proteins to enhance replication. Prior work determined that efficient alphavirus replication requires catalytically active macrodomains; however, which form of the modification requires removal and from which protein(s) had not been determined. Here, we present evidence for the specific requirement of poly-ARH activity to ensure efficient productive infection and virus replication.

Overview of Methods for Large-Scale RNA Synthesis

In recent years, it has become clear that RNA molecules are involved in almost all vital cellular processes and pathogenesis of human disorders. The functional diversity of RNA comes from its structural richness. Although composed of only four nucleotides, RNA molecules present a plethora of secondary and tertiary structures critical for intra and intermolecular contacts with other RNAs and ligands (proteins, small metabolites, etc.). In order to fully understand RNA function it is necessary to define its spatial structure. Crystallography, nuclear magnetic resonance and cryogenic electron microscopy have demonstrated considerable success in determining the structures of biologically important RNA molecules. However, these powerful methods require large amounts of sample. Despite their limitations, chemical synthesis and in vitro transcription are usually employed to obtain milligram quantities of RNA for structural studies, delivering simple and effective methods for large-scale production of homogenous samples. The aim of this paper is to provide an overview of methods for large-scale RNA synthesis with emphasis on chemical synthesis and in vitro transcription. We also present our own results of testing the efficiency of these approaches in order to adapt the material acquisition strategy depending on the desired RNA construct.

Analysis of a crucial interaction between the coronavirus nucleocapsid protein and the major membrane-bound subunit of the viral replicase-transcriptase complex.

The coronavirus nucleocapsid (N) protein comprises two RNA-binding domains connected by a central spacer, which contains a serine- and arginine-rich (SR) region. The SR region engages the largest subunit of the viral replicase-transcriptase, nonstructural protein 3 (nsp3), in an interaction that is essential for efficient initiation of infection by genomic RNA. We carried out an extensive genetic analysis of the SR region of the N protein of mouse hepatitis virus in order to more precisely define its role in RNA synthesis. We further examined the N-nsp3 interaction through construction of nsp3 mutants and by creation of an interspecies N protein chimera. Our results indicate a role for the central spacer as an interaction hub of the N molecule that is partially regulated by phosphorylation. These findings are discussed in relation to the recent discovery that nsp3 forms a molecular pore in the double-membrane vesicles that sequester the coronavirus replicase-transcriptase.

Coronavirus RNA Synthesis Takes Place within Membrane-Bound Sites.

Infectious bronchitis virus (IBV), a gammacoronavirus, is an economically important virus to the poultry industry, as well as a significant welfare issue for chickens. As for all positive strand RNA viruses, IBV infection causes rearrangements of the host cell intracellular membranes to form replication organelles. Replication organelle formation is a highly conserved and vital step in the viral life cycle. Here, we investigate the localization of viral RNA synthesis and the link with replication organelles in host cells. We have shown that sites of viral RNA synthesis and virus-related dsRNA are associated with one another and, significantly, that they are located within a membrane-bound compartment within the cell. We have also shown that some viral RNA produced early in infection remains within these membranes throughout infection, while a proportion is trafficked to the cytoplasm. Importantly, we demonstrate conservation across all four coronavirus genera, including SARS-CoV-2. Understanding more about the replication of these viruses is imperative in order to effectively find ways to control them.

Structure-function analysis of the nsp14 N7-guanine methyltransferase reveals an essential role in Betacoronavirus replication.

As coronaviruses (CoVs) replicate in the host cell cytoplasm, they rely on their own capping machinery to ensure the efficient translation of their messenger RNAs (mRNAs), protect them from degradation by cellular 5' exoribonucleases (ExoNs), and escape innate immune sensing. The CoV nonstructural protein 14 (nsp14) is a bifunctional replicase subunit harboring an N-terminal 3'-to-5' ExoN domain and a C-terminal (N7-guanine)-methyltransferase (N7-MTase) domain that is presumably involved in viral mRNA capping. Here, we aimed to integrate structural, biochemical, and virological data to assess the importance of conserved N7-MTase residues for nsp14's enzymatic activities and virus viability. We revisited the crystal structure of severe acute respiratory syndrome (SARS)-CoV nsp14 to perform an in silico comparative analysis between betacoronaviruses. We identified several residues likely involved in the formation of the N7-MTase catalytic pocket, which presents a fold distinct from the Rossmann fold observed in most known MTases. Next, for SARS-CoV and Middle East respiratory syndrome CoV, site-directed mutagenesis of selected residues was used to assess their importance for in vitro enzymatic activity. Most of the engineered mutations abolished N7-MTase activity, while not affecting nsp14-ExoN activity. Upon reverse engineering of these mutations into different betacoronavirus genomes, we identified two substitutions (R310A and F426A in SARS-CoV nsp14) abrogating virus viability and one mutation (H424A) yielding a crippled phenotype across all viruses tested. Our results identify the N7-MTase as a critical enzyme for betacoronavirus replication and define key residues of its catalytic pocket that can be targeted to design inhibitors with a potential pan-coronaviral activity spectrum.

CoV-er all the bases: Structural perspectives of SARS-CoV-2 RNA synthesis.

The ongoing Covid-19 pandemic has spurred research in the biology of the nidovirus severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2). Much focus has been on the viral RNA synthesis machinery due to its fundamental role in viral propagation. The central and essential enzyme of the RNA synthesis process, the RNA-dependent RNA polymerase (RdRp), functions in conjunction with a coterie of viral-encoded enzymes that mediate crucial nucleic acid transactions. Some of these enzymes share common features with other RNA viruses, while others play roles unique to nidoviruses or CoVs. The RdRps are proven targets for viral pathogens, and many of the other nucleic acid processing enzymes are promising targets. The purpose of this review is to summarize recent advances in our understanding of the mechanisms of RNA synthesis in CoVs. By reflecting on these studies, we hope to emphasize the remaining gaps in our knowledge. The recent onslaught of structural information related to SARS-CoV-2 RNA synthesis, in combination with previous structural, genetic and biochemical studies, have vastly improved our understanding of how CoVs replicate and process their genomic RNA. Structural biology not only provides a blueprint for understanding the function of the enzymes and cofactors in molecular detail, but also provides a basis for drug design and optimization. The concerted efforts of researchers around the world, in combination with the renewed urgency toward understanding this deadly family of viruses, may eventually yield new and improved antivirals that provide relief to the current global devastation.

Allosteric Activation of SARS-CoV-2 RNA-Dependent RNA Polymerase by Remdesivir Triphosphate and Other Phosphorylated Nucleotides.

The catalytic subunit of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) RNA-dependent RNA polymerase (RdRp) Nsp12 has a unique nidovirus RdRp-associated nucleotidyltransferase (NiRAN) domain that transfers nucleoside monophosphates to the Nsp9 protein and the nascent RNA. The NiRAN and RdRp modules form a dynamic interface distant from their catalytic sites, and both activities are essential for viral replication. We report that codon-optimized (for the pause-free translation in bacterial cells) Nsp12 exists in an inactive state in which NiRAN-RdRp interactions are broken, whereas translation by slow ribosomes and incubation with accessory Nsp7/8 subunits or nucleoside triphosphates (NTPs) partially rescue RdRp activity. Our data show that adenosine and remdesivir triphosphates promote the synthesis of A-less RNAs, as does ppGpp, while amino acid substitutions at the NiRAN-RdRp interface augment activation, suggesting that ligand binding to the NiRAN catalytic site modulates RdRp activity. The existence of allosterically linked nucleotidyl transferase sites that utilize the same substrates has important implications for understanding the mechanism of SARS-CoV-2 replication and the design of its inhibitors. IMPORTANCEIn vitro interrogations of the central replicative complex of SARS-CoV-2, RNA-dependent RNA polymerase (RdRp), by structural, biochemical, and biophysical methods yielded an unprecedented windfall of information that, in turn, instructs drug development and administration, genomic surveillance, and other aspects of the evolving pandemic response. They also illuminated the vast disparity in the methods used to produce RdRp for experimental work and the hidden impact that this has on enzyme activity and research outcomes. In this report, we elucidate the positive and negative effects of codon optimization on the activity and folding of the recombinant RdRp and detail the design of a highly sensitive in vitro assay of RdRp-dependent RNA synthesis. Using this assay, we demonstrate that RdRp is allosterically activated by nontemplating phosphorylated nucleotides, including naturally occurring alarmone ppGpp and synthetic remdesivir triphosphate.