In silico analysis of non-structural protein 12 sequences from SARS-COV-2 found in Manaus, Amazonas, Brazil, reveals mutations linked to higher transmissibility

ZANCHI, FERNANDO B.; FERREIRA, GABRIEL EDUARDO M.; MARIÚBA, LUIS ANDRÉ M.; GLÓRIA, JULIANE C.; NASCIMENTO, VALDINETE A. DO; SOUZA, VICTOR C. DE; CORADO, ANDRÉ DE LIMA G.; NASCIMENTO, FERNANDA O. DO; COSTA, ÁGATHA KÉLLY A. DA; DUARTE, DÉBORA CAMILA G.; SILVA, GEORGE ALLAN V. DA; MEJÍA, MATILDE DEL CARMEN C.; PESSOA, KARINA P.; GONÇALVES, LUCIANA MARA F.; BRANDÃO, MARIA JÚLIA P.; JESUS, MICHELE S. DE; SILVA, MARINEIDE S. DA; COSTA, CRISTIANO F. DA; NAVECA, FELIPE G.

doi:10.1590/0001-3765202420231336

Abstract

The disease coronavirus COVID-19 has been the cause of millions of deaths worldwide. Among the proteins of SARS-CoV-2, non-structural protein 12 (NSP12) plays a key role during COVID infection and is part of the RNA-dependent RNA polymerase complex. The monitoring of NSP12 polymorphisms is extremely important for the design of new antiviral drugs and monitoring of viral evolution. This study analyzed the NSP12 mutations detected in circulating SARS-CoV-2 during the years 2020 to 2022 in the population of the city of Manaus, Amazonas, Brazil. The most frequent mutations found were P323L and G671S. Reports in the literature indicate that these mutations are related to transmissibility efficiency, which may have contributed to the extremely high numbers of cases in this location. In addition, two mutations described here (E796D and R914K) are close and have RMSD that is similar to the mutations M794V and N911K, which have been described in the literature as influential on the performance of the NSP12 enzyme. These data demonstrate the need to monitor the emergence of new mutations in NSP12 in order to better understand their consequences for the treatments currently used and in the design of new drugs.

Key words
coronavirus; COVID 19; Modeling of 3D structures; NSP12; SARS-CoV-2; polymorphism

INTRODUCTION

The emergence of the new coronavirus has brought changes of a magnitude never seen by humans. By September 2023, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) had caused 6,959,316 deaths worldwide, leading to the collapse of the healthcare system in a number of countries due to the need for hospitalization of seriously ill patients (WHO 2023WHO - WORLD HEALTH ORGANIZATION. 2023. Coronavirus (COVID-2019) Dashboard. Available in: <https://covid19.who.int/> Accessed in September 2023.
https://covid19.who.int/... ). In Brazil, 37,796,956 cases and 705,775 deaths were registered by September 2023, with Manaus, Amazonas, being one of the most affected cities (BRASIL - Ministério da Saúde 2023).

During coronavirus replication, RdRp (RNA-dependent RNA polymerase) plays a crucial role in viral genome transcription and replication. This complex is composed of several proteins, including nonstructural protein 12 (NSP12), a catalytic subunit with RdRp activity, along with NSP7 and NSP8, which stimulate the polymerization activity of NSP12. The resulting complex, known as NSP12-NSP7-NSP8, with about 160 kDa, is considered the minimum nucleus necessary for the amplification of viral RNA (Kirchdoerfer & Ward 2019KIRCHDOERFER RN & WARD AB. 2019. Structure of the SARS-CoV nsp12 polymerase bound to nsp7 and nsp8 co-factors. Nat Commun 10.).

Different substances that act on the inhibition of RdRp have been tested for use in the treatment of SARS-CoV-2. Among these is favipiravir, which is a pyrazinecarboxamide derivative that is used against several RNA viruses such as influenza, yellow fever, flaviviruses, among others (Furuta et al. 2009FURUTA Y, TAKAHASHI K, SHIRAKI K, SAKAMOTO K, SMEE DF, BARNARD DL, GOWEN BB, JULANDER JG & MORREY JD. 2009. T-705 (favipiravir) and related compounds: Novel broad-spectrum inhibitors of RNA viral infections. Antiviral Res 82: 95-102., Shiraki & Daikoku 2020SHIRAKI K & DAIKOKU T. 2020. Favipiravir, an anti-influenza drug against life-threatening RNA virus infections. Pharmacol Ther 209: 107512.). With the emergence of new strains of COVID-19, new mutations are being found in different parts of the genome of this microorganism. As the pandemic progressed, the scientific community noticed that there was a significant increase in the frequency of mutations in the genome, reaching around 3,000 mutations in isolates worldwide, with the spike and RdRp genes having the highest mutation rates (Flores-Alanis et al. 2021FLORES-ALANIS A, CRUZ-RANGEL A, RODRÍGUEZ-GÓMEZ F, GONZÁLEZ J, TORRES-GUERRERO CA, DELGADO G, CRAVIOTO A & MORALES-ESPINOSA R. 2021. Molecular Epidemiology Surveillance of SARS-CoV-2: Mutations and Genetic Diversity One Year after Emerging. Pathogens 10: 1-14., Eskier et al. 2021ESKIER D, SUNER A, OKTAY Y & KARAKÜLAH G. 2021. Mutations of SARS-CoV-2 nsp14 exhibit strong association with increased genome-wide mutation load., Mercatelli & Giorgi 2020MERCATELLI D & GIORGI FM. 2020. Geographic and Genomic Distribution of SARS-CoV-2 Mutations. Front Microbiol 11., Koçhan et al. 2021KOÇHAN N, ESKIER D, SUNER A, KARAKÜLAH G & OKTAY Y. 2021. Different selection dynamics of S and RdRp between SARS-CoV-2 genomes with and without the dominant mutations. Infect Genet Evol 91.). Therefore, it is extremely important to continue to monitor these variants, as well as understand the consequences caused in the structure of these proteins, for example, for the design of new antiviral drugs.

In this context, this article aims to analyze the structural changes caused by mutations in NSP12 found in Manaus, Amazonas, Brazil, which were collected during the pandemic caused by the new coronavirus. These mutations have not been previously reported. The modeling and molecular dynamics analyses showed that, although no significant alterations were observed in the structure of NSP12 of these mutants, the positions of the mutations indicate alterations in the mode of action of NSP12 and, consequently, viral replication.

MATERIALS AND METHODS

Between 2020 and 2022, 2,356 samples were collected from patients located in Manaus, Amazonas state, Brazil. This study was approved by the Ethics Committee of the Amazonas State University, under approval number: CAAE: 25430719.6.0000.5016.

The NSP12 gene was sequenced following the protocol described by Nascimento et al. (2020)NASCIMENTO VA ET AL. 2020. Genomic and phylogenetic characterisation of an imported case of SARS-CoV-2 in Amazonas State, Brazil. Mem Inst Oswaldo Cruz 115., with modifications. Gene amplification was obtained using Master Mix Platinum SuperFi II Green PCR, which was confirmed using agarose gel electrophoresis, then precipitated with PEG 8000 and quantified via fluorimetry. NexteraXT DNA was used to construct NGS libraries, and sequencing was done using the MiSeq v2 reagent kit (500 cycles) and MiSeq (Illumina), installed at Fiocruz Amazônia. The Illumina pipeline in BaseSpace was used to convert raw data; cut for quality using BBDuk and assembled using BBMap in Geneious v10.2.6, and using the sequence NC_045512 as the reference. The alignment was performed using MAFFT 7 in Geneious v10.2.6.

A phylogenetic tree was constructed to infer clades using the diversity in NSP12 amino acid sequences. The maximum likelihood method and a JTT matrix-based model (Jones et al. 1992JONES DT, TAYLOR WR & THORNTON JM. 1992. The rapid generation of mutation data matrices from protein sequences. Comput Appl Biosci 8: 275-282.) were used in the MEGA 11 package (Tamura et al. 2021TAMURA K, STECHER G & KUMAR S. 2021. MEGA11: Molecular Evolutionary Genetics Analysis Version 11. Mol Biol Evol 38: 3022-3027.). This analysis involved 236 sequences (including NC_045512.2 from GenBank; Wu et al. 2020WU F ET AL. 2020. A new coronavirus associated with human respiratory disease in China. Nature 2020 579:7798 579: 265-269.) of 923 amino acids and 177 variable positions.

Search models, modeling and structural analysis of the SARS-CoV-2 complex NSP12-NSP7-NSP8-RNA were carried out using Blast software (Camacho et al. 2009CAMACHO C, COULOURIS G, AVAGYAN V, MA N, PAPADOPOULOS J, BEALER K & MADDEN TL. 2009. BLAST+: architecture and applications. BMC bioinformatics 10.), Modeller 10.3 (Eswar et al. 2008ESWAR N, ERAMIAN D, WEBB B, SHEN MY & SALI A. 2008. Protein structure modeling with MODELLER. Methods in molecular biology (Clifton, NJ) 426: 145-159.), Swiss - PDBViewer v4.1 (Kaplan & Littlejohn 2001KAPLAN W & LITTLEJOHN TG. 2001. Swiss-PDB Viewer (Deep View). Briefings in Bioinformatics 2: 195-197.) and UCSF Chimera (Pettersen et al. 2009). The NSP12 sequences of SARS-CoV-2 were obtained by our group and the Wuhan isolate was obtained from GenBank (NC_045512.2) (Wu et al. 2020WU F ET AL. 2020. A new coronavirus associated with human respiratory disease in China. Nature 2020 579:7798 579: 265-269.). In summary, the structure of the SARS-CoV-2 NSP12 complex of NSP12-NSP7-NSP8-RNA (PDB identification code: 7AAP) (Naydenova et al. 2021NAYDENOVA K ET AL. 2021. Structure of the SARS-CoV-2 RNA-dependent RNA polymerase in the presence of favipiravir-RTP. Proceedings of the National Academy of Sciences of the United States of America 118.) was used as a mold. Before modeling the mutations, it was necessary to model the 896-910 and C-terminal regions of the Wuhan NSP12 structure (chain A of 7AAP). Next, the main structures of interest with mutations found in Manaus and reported by Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. were modeled. The classic pipeline of the generation of 1,000 models was applied in the Modeller 10.3 software. After modeling, a common preparation and minimization protocol was applied for the simulation of molecular dynamics in Gromacs 2023.2 (Van Der Spoel et al. 2005VAN DER SPOEL D, LINDAHL E, HESS B, GROENHOF G, MARK AE & BERENDSEN HJC. 2005. GROMACS: fast, flexible, and free. J Comput Chem 26: 1701-1718.). All mutant and wild-type structures (PDB ID: 7AAP) were submitted. The protocol consists of placing each structure in a solvated cubic box with edges 1 nm from the edge of the structural complex. Then, the structures were joined and neutralized with the addition of Na+ ions. Two minimization steps were applied (steepest descent and gradient conjugate) until the complex reached a resistance of less than 1,000 kJ.mol-1.nm^-1. The temperature of the system was then increased from 50 K to 300 K in 5 steps (50 K to 100 K, 100 K to 150 K, 150 K to 200 K, 200 K to 250 K, 250 K to 300 K), and the velocities at each step were reassigned according to the Maxwell-Boltzmann distribution at that temperature. The systems were then subjected to short molecular dynamics with position constraints for a period of 30 ps. Finally, the system was subjected to 20 ps of balance with NVT set plus 20 ps NPT. The quality of all the final models was evaluated using the Procheck software (Yuan et al. 2020YUAN S ET AL. 2020. Nonstructural Protein 1 of SARS-CoV-2 Is a Potent Pathogenicity Factor Redirecting Host Protein Synthesis Machinery toward Viral RNA. Molecular Cell 80: 1055-1066.e6.). All the structures showed structural quality with more than 90% of the amino acids in favorable regions. None of the amino acids were in the prohibited region. All the final structures were superimposed on the Wuhan structure and the RMSDs were calculated. Theinterstructure of the RMSDs of Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. and those from Manaus were compared. Structural positions were observed and analysed using the UCSF Chimera software. In order to compare the structural differences, the structure of SARS-CoV NSP12 (GI: AFM43866.1) was modeled using homology and superimposed on SARS-CoV-2 NSP12 (chain A of the PDB ID: 7AAP).

RESULTS AND DISCUSSION

The NSP12 gene sequences were extracted from the 235 SARS-CoV-2 genomes of samples of COVID-19 patients, which were obtained in Manaus between 2020-2022. The translated sequences contained 923 amino acids and the positions of the sites were determined based on the sequence of the Wuhan NC NC_045512.2 (Wu et al. 2020WU F ET AL. 2020. A new coronavirus associated with human respiratory disease in China. Nature 2020 579:7798 579: 265-269.). Of the 177 variable sites, 38 presented non-unique mutations and in five of them the frequency was higher than 5: P94L (06) and P94S (03); P323L (233) and P323F (1); A529T (2), A529V (02) and A529S (01); G671S (89) and G671C (1); L838I (06) and L838M (1). These mutations can have significant functional implications and the analysis of these mutations provides valuable information for treatment and vaccine development studies, as described by Sahin et al. (2021)SAHIN E, BOZDAYI G, YIGIT S, MUFTAH H, DIZBAY M, TUNCCAN OG, FIDAN I & CAGLAR K. 2021. Genomic characterization of SARS-CoV-2 isolates from patients in Turkey reveals the presence of novel mutations in spike and nsp12 proteins. J Med Virol 93: 6016-6026., who found four new mutations in NSP12 (V111A, H133R, Y453C, M626K).

The main mutations in the dataset (considering Wuhan as the reference) are shown in Figure 1. In position 323, it is possible to observe that the Wuhan reference proline was absent in the studied population, with 233 samples presenting leucine and a single sample presenting leucine/phenylalanine (red bar in Figure 1). The second most frequent occurrence was at position 671, in which glycine was replaced by serine in 89 cases and by cysteine in only one case (dark orange bar in Figure 1, names in blue in the phylogenetic tree of Supplementary Material - Figure S1). This group of samples containing G671S does not comprise a monophyletic cluster (names in blue; Figure S1). Another three sites were presented as polymorphic, but in no more than 3% of the strains. The effect of the distribution of these main mutations on the phylogenetic relationships between the studied lineages is marked by the tendency to cluster the lineages that share these apomorphies into small monophyletic clusters (names in green, orange and red; Figure S1). When working with a ferret model, Kim et al. (2023)KIM SM ET AL. 2023. SARS-CoV-2 variants with NSP12 P323L/G671S mutations display enhanced virus replication in ferret upper airways and higher transmissibility. Cell Reports 42: 113077. observed that the NSP12 P323L or P323L/G671S mutation of SARS-CoV-2 is associated with increased stability of the RdRp complex and enzymatic activity, thus promoting efficient transmissibility. The high incidence of isolates containing these mutations in Manaus, Amazonas, may have contributed to the high number of cases observed in this location. In association with this fact, Manaus did not have a satisfactory lockdown system, which led to one of the largest public health disasters ever seen in the Amazon region. The high circulation of the virus in the region greatly contributed to the appearance of the observed mutations (Taylor 2021TAYLOR L. 2021. Covid-19: Is Manaus the final nail in the coffin for natural herd immunity? BMJ 372., Sabino et al. 2021SABINO EC ET AL. 2021. Resurgence of COVID-19 in Manaus, Brazil, despite high seroprevalence. The Lancet 397: 452-455., Naveca et al. 2021NAVECA FG ET AL. 2021. COVID-19 in Amazonas, Brazil, was driven by the persistence of endemic lineages and P.1 emergence. Nat Med 27: 1230-1238.).

Figure 1
NSP12 positions with more than one mutation found in sequences from Manaus, Amazonas (Brazil). All the columns show positions with more than one mutation compared to the Wuhan strain. Positions with only one mutation were omitted.

After the modeling and minimization process, the structures of the SARS-CoV-2 NSP12-NSP7-NSP8-RNA complexes selected for analysis were superimposed and their deviations compared using the root mean square deviation (RMSD) (Table I). The analyses carried out revealed that the mutations described by Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. present a RMSD that is similar to those described in our study. The most frequent alterations described in the literature (G671S and P323L) included a lower RMSD than those observed in the mutations described in our study and in Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.. Mutations in the sequence of NSP12 can alter its activity, which can lead to an improvement in its synthesis capacity and, consequently, a better adaptation or a higher viral replication rate. Through in vitro experiments, Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. demonstrated that M794V and N911K mutations lead to an increase in viral RNA replication. In Figure 2, we observe that the E796D mutation found in Manaus is close to the M794V mutation; while, in Figure 3, the R914K mutation is close to N911K. Due to its proximity to the catalytic site of RNA polymerization (asparagine triads 618, 760 and 761), these mutations could have a direct influence on enzyme activity. Despite the possible relationship between the E796D and R914K mutations and enzymatic activities, both were singletons in our sample and did not present any cluster or clade formation in the topology of the phylogenetic analysis (red branches in Figure S1).

Figure 2
Overlaps between modeled structural complexes of NSP12-NSP7-NSP8 RNA from SARS-CoV-2 with M794V and E796D mutations in NSP12. Ribbon representation of the NSP12 complex (brown), NSP7 (blue), NSP8 (green) and RNA (red). The amino acid side chains of the Wuhan strain are shown in purple, the M794V mutation of Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. in yellow, and E796D of this study in light green.

Figure 3
Overlaps between modeled structural complexes of NSP12-NSP7-NSP8 RNA from SARS-CoV-2 with N911K and R914K mutations in NSP12. Ribbon representation of the NSP12 complex (brown), NSP7 (blue), NSP8 (green) and RNA (red). The amino acid side chains of the Wuhan strain are shown in purple, the N911K mutation of Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. in yellow, and R914K of this study in light green.

Thumbnail

Table I
RMSD between modeled SARS-CoV-2 NSP12 of NSP12-NSP7-NSP8-RNA complexes with mutations in NSP12.

The RdRp P323L mutation was described by Chand et al. (2020)CHAND GB, BANERJEE A & AZAD GK. 2020. Identification of novel mutations in RNA-dependent RNA polymerases of SARS-CoV-2 and their implications on its protein structure. PeerJ 8., Kannan et al. (2020)KANNAN SR, SPRATT AN, QUINN TP, HENG X, LORSON CL, SÖNNERBORG A, BYRAREDDY SN & SINGH K. 2020. Infectivity of SARS-CoV-2: there Is Something More than D614G? Journal of Neuroimmune Pharmacology 15: 574-577. and Eskier et al. (2020). The latter reported that the P323L mutation (14408C>T) leads to an elevation in the mutation rate, while 15324C>T causes the opposite. Other mutations have also been found in Europe and North America, such as Val473, Arg555 (Mari et al. 2021MARI A ET AL. 2021. Global Genomic Analysis of SARS-CoV-2 RNA Dependent RNA Polymerase Evolution and Antiviral Drug Resistance. Microorganisms 9.) and NSP12 L314P (Ward et al. 2021WARD D, HIGGINS M, PHELAN JE, HIBBERD ML, CAMPINO S & CLARK TG. 2021. An integrated in silico immuno-genetic analytical platform provides insights into COVID-19 serological and vaccine targets. Genome Med 13.), suggesting that the virus is evolving (Pachetti et al. 2020PACHETTI M ET AL. 2020. Emerging SARS-CoV-2 mutation hot spots include a novel RNA-dependent-RNA polymerase variant. J Transl Med 18.). Goldswain et al. (2023)GOLDSWAIN H ET AL. 2023. The P323L substitution in the SARS-CoV-2 polymerase (NSP12) confers a selective advantage during infection. Genome Biol 24: 1-23. noted that P323L is an important contributor in the emergence of variants with transmission advantages. Kim et al. (2023)KIM SM ET AL. 2023. SARS-CoV-2 variants with NSP12 P323L/G671S mutations display enhanced virus replication in ferret upper airways and higher transmissibility. Cell Reports 42: 113077. indicated that the NSP12 P323L OR P323L/G671S mutation of SARS-CoV-2 is associated with an increase in RdRp complex stability and enzyme activity, thus promoting efficient transmissibility. The P323L and G671S mutations are close to NSP8, while the R914K and E796D mutations found in the analyzed isolates from Manaus, as well as M794V and N911K (Miropolskaya et al. 2023MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.) are not close to either the NSP7 or NSP8 protein. This indicates that they are probably not involved in facilitating or preventing the binding of this complex. However, it is still possible that some of the observed mutations can have some influence, either positive or negative, in this process, through disruptions that can break non-covalent interactions between structures that may be essential for the interaction of the complex or alter the folding energy (Gao et al. 2015GAO M, ZHOU H & SKOLNICK J. 2015. Insights into Disease-Associated Mutations in the Human Proteome through Protein Structural Analysis. Structure (London, England: 1993) 23: 1362-1369.). SARS-CoV NSP12 has 95% similarity to SARS-CoV-2 NSP12. In turn, structural overlap of globally aligned residues of the SARS-CoV NSP12 structure over the SARS-CoV-2 NSP12 structure resulted in a low RMSD of 0.583 Å, showing structural conservation of the backbone. However, when considering just the residues of the two loops (Figure S2), the RMSD is approximately 16 Å. This loop is close to the entry and exit channels of the RNA, which suggests that the catalytic mechanism is affected by this difference. This feature was also observed by Gao et al. (2020)GAO Y ET AL. 2020. Structure of the RNA-dependent RNA polymerase from COVID-19 virus. Science (New York, NY) 368: 779-782..

In conclusion, new local mutations were recorded in Manaus. The main mutations P323L and G671S have been reported in other studies as having transmissibility efficiency, which may have contributed to the extremely high numbers of cases in this region. Two other mutations (R914K and E796D) have alterations that have already cited as interfering with replication processes. Their high RMSD values from the modeling suggest that monitoring of SARS-CoV-2 NSP12 variants might include analyzing the influence of non-synonymous amino acid mutations on enzyme structure and activity. This highlights the importance of monitoring SARS-CoV-2 variants, as it may affect the effectiveness of treatment against this disease.

ACKNOWLEDGMENTS

The authors would like to thank the Program for Technological Development in Tools for Health – FIOCRUZf or the use of the nucleotide sequencing facilities at ILMD-Fiocruz Amazônia.

SUPPLEMENTARY MATERIAL

Figures S1, S2.

REFERENCES

BRASIL - MINISTÉRIO DA SAÚDE. 2023. COVID-19 no Brasil. Available in: < https://infoms.saude.gov.br/extensions/covid-19_html/covid-19_html.html> Accessed September 2023.
» https://infoms.saude.gov.br/extensions/covid-19_html/covid-19_html.html
CAMACHO C, COULOURIS G, AVAGYAN V, MA N, PAPADOPOULOS J, BEALER K & MADDEN TL. 2009. BLAST+: architecture and applications. BMC bioinformatics 10.
CHAND GB, BANERJEE A & AZAD GK. 2020. Identification of novel mutations in RNA-dependent RNA polymerases of SARS-CoV-2 and their implications on its protein structure. PeerJ 8.
ESKIER D, SUNER A, OKTAY Y & KARAKÜLAH G. 2021. Mutations of SARS-CoV-2 nsp14 exhibit strong association with increased genome-wide mutation load.
ESWAR N, ERAMIAN D, WEBB B, SHEN MY & SALI A. 2008. Protein structure modeling with MODELLER. Methods in molecular biology (Clifton, NJ) 426: 145-159.
FLORES-ALANIS A, CRUZ-RANGEL A, RODRÍGUEZ-GÓMEZ F, GONZÁLEZ J, TORRES-GUERRERO CA, DELGADO G, CRAVIOTO A & MORALES-ESPINOSA R. 2021. Molecular Epidemiology Surveillance of SARS-CoV-2: Mutations and Genetic Diversity One Year after Emerging. Pathogens 10: 1-14.
FURUTA Y, TAKAHASHI K, SHIRAKI K, SAKAMOTO K, SMEE DF, BARNARD DL, GOWEN BB, JULANDER JG & MORREY JD. 2009. T-705 (favipiravir) and related compounds: Novel broad-spectrum inhibitors of RNA viral infections. Antiviral Res 82: 95-102.
GAO M, ZHOU H & SKOLNICK J. 2015. Insights into Disease-Associated Mutations in the Human Proteome through Protein Structural Analysis. Structure (London, England: 1993) 23: 1362-1369.
GAO Y ET AL. 2020. Structure of the RNA-dependent RNA polymerase from COVID-19 virus. Science (New York, NY) 368: 779-782.
GOLDSWAIN H ET AL. 2023. The P323L substitution in the SARS-CoV-2 polymerase (NSP12) confers a selective advantage during infection. Genome Biol 24: 1-23.
JONES DT, TAYLOR WR & THORNTON JM. 1992. The rapid generation of mutation data matrices from protein sequences. Comput Appl Biosci 8: 275-282.
KANNAN SR, SPRATT AN, QUINN TP, HENG X, LORSON CL, SÖNNERBORG A, BYRAREDDY SN & SINGH K. 2020. Infectivity of SARS-CoV-2: there Is Something More than D614G? Journal of Neuroimmune Pharmacology 15: 574-577.
KAPLAN W & LITTLEJOHN TG. 2001. Swiss-PDB Viewer (Deep View). Briefings in Bioinformatics 2: 195-197.
KIM SM ET AL. 2023. SARS-CoV-2 variants with NSP12 P323L/G671S mutations display enhanced virus replication in ferret upper airways and higher transmissibility. Cell Reports 42: 113077.
KIRCHDOERFER RN & WARD AB. 2019. Structure of the SARS-CoV nsp12 polymerase bound to nsp7 and nsp8 co-factors. Nat Commun 10.
KOÇHAN N, ESKIER D, SUNER A, KARAKÜLAH G & OKTAY Y. 2021. Different selection dynamics of S and RdRp between SARS-CoV-2 genomes with and without the dominant mutations. Infect Genet Evol 91.
MARI A ET AL. 2021. Global Genomic Analysis of SARS-CoV-2 RNA Dependent RNA Polymerase Evolution and Antiviral Drug Resistance. Microorganisms 9.
MERCATELLI D & GIORGI FM. 2020. Geographic and Genomic Distribution of SARS-CoV-2 Mutations. Front Microbiol 11.
MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.
NASCIMENTO VA ET AL. 2020. Genomic and phylogenetic characterisation of an imported case of SARS-CoV-2 in Amazonas State, Brazil. Mem Inst Oswaldo Cruz 115.
NAVECA FG ET AL. 2021. COVID-19 in Amazonas, Brazil, was driven by the persistence of endemic lineages and P.1 emergence. Nat Med 27: 1230-1238.
NAYDENOVA K ET AL. 2021. Structure of the SARS-CoV-2 RNA-dependent RNA polymerase in the presence of favipiravir-RTP. Proceedings of the National Academy of Sciences of the United States of America 118.
PACHETTI M ET AL. 2020. Emerging SARS-CoV-2 mutation hot spots include a novel RNA-dependent-RNA polymerase variant. J Transl Med 18.
PETTERSEN EF, GODDARD TD, HUANG CC, COUCH GS, GREENBLATT DM, MENG EC & FERRIN TE. 2004. UCSF Chimera - A visualization system for exploratory research and analysis. J Comput Chem 25(13): 1605-1612.
SABINO EC ET AL. 2021. Resurgence of COVID-19 in Manaus, Brazil, despite high seroprevalence. The Lancet 397: 452-455.
SAHIN E, BOZDAYI G, YIGIT S, MUFTAH H, DIZBAY M, TUNCCAN OG, FIDAN I & CAGLAR K. 2021. Genomic characterization of SARS-CoV-2 isolates from patients in Turkey reveals the presence of novel mutations in spike and nsp12 proteins. J Med Virol 93: 6016-6026.
SHIRAKI K & DAIKOKU T. 2020. Favipiravir, an anti-influenza drug against life-threatening RNA virus infections. Pharmacol Ther 209: 107512.
TAMURA K, STECHER G & KUMAR S. 2021. MEGA11: Molecular Evolutionary Genetics Analysis Version 11. Mol Biol Evol 38: 3022-3027.
TAYLOR L. 2021. Covid-19: Is Manaus the final nail in the coffin for natural herd immunity? BMJ 372.
VAN DER SPOEL D, LINDAHL E, HESS B, GROENHOF G, MARK AE & BERENDSEN HJC. 2005. GROMACS: fast, flexible, and free. J Comput Chem 26: 1701-1718.
WARD D, HIGGINS M, PHELAN JE, HIBBERD ML, CAMPINO S & CLARK TG. 2021. An integrated in silico immuno-genetic analytical platform provides insights into COVID-19 serological and vaccine targets. Genome Med 13.
WHO - WORLD HEALTH ORGANIZATION. 2023. Coronavirus (COVID-2019) Dashboard. Available in: <https://covid19.who.int/> Accessed in September 2023.
» https://covid19.who.int/
WU F ET AL. 2020. A new coronavirus associated with human respiratory disease in China. Nature 2020 579:7798 579: 265-269.
YUAN S ET AL. 2020. Nonstructural Protein 1 of SARS-CoV-2 Is a Potent Pathogenicity Factor Redirecting Host Protein Synthesis Machinery toward Viral RNA. Molecular Cell 80: 1055-1066.e6.

Publication Dates

Publication in this collection
10 May 2024
Date of issue
2024

History

Received
08 Dec 2024
Accepted
01 Feb 2024

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] BRASIL - MINISTÉRIO DA SAÚDE. 2023. COVID-19 no Brasil. Available in: < https://infoms.saude.gov.br/extensions/covid-19_html/covid-19_html.html> Accessed September 2023.
» https://infoms.saude.gov.br/extensions/covid-19_html/covid-19_html.html

[2] CAMACHO C, COULOURIS G, AVAGYAN V, MA N, PAPADOPOULOS J, BEALER K & MADDEN TL. 2009. BLAST+: architecture and applications. BMC bioinformatics 10.

[3] CHAND GB, BANERJEE A & AZAD GK. 2020. Identification of novel mutations in RNA-dependent RNA polymerases of SARS-CoV-2 and their implications on its protein structure. PeerJ 8.

[4] ESKIER D, SUNER A, OKTAY Y & KARAKÜLAH G. 2021. Mutations of SARS-CoV-2 nsp14 exhibit strong association with increased genome-wide mutation load.

[5] ESWAR N, ERAMIAN D, WEBB B, SHEN MY & SALI A. 2008. Protein structure modeling with MODELLER. Methods in molecular biology (Clifton, NJ) 426: 145-159.

[6] FLORES-ALANIS A, CRUZ-RANGEL A, RODRÍGUEZ-GÓMEZ F, GONZÁLEZ J, TORRES-GUERRERO CA, DELGADO G, CRAVIOTO A & MORALES-ESPINOSA R. 2021. Molecular Epidemiology Surveillance of SARS-CoV-2: Mutations and Genetic Diversity One Year after Emerging. Pathogens 10: 1-14.

[7] FURUTA Y, TAKAHASHI K, SHIRAKI K, SAKAMOTO K, SMEE DF, BARNARD DL, GOWEN BB, JULANDER JG & MORREY JD. 2009. T-705 (favipiravir) and related compounds: Novel broad-spectrum inhibitors of RNA viral infections. Antiviral Res 82: 95-102.

[8] GAO M, ZHOU H & SKOLNICK J. 2015. Insights into Disease-Associated Mutations in the Human Proteome through Protein Structural Analysis. Structure (London, England: 1993) 23: 1362-1369.

[9] GAO Y ET AL. 2020. Structure of the RNA-dependent RNA polymerase from COVID-19 virus. Science (New York, NY) 368: 779-782.

[10] GOLDSWAIN H ET AL. 2023. The P323L substitution in the SARS-CoV-2 polymerase (NSP12) confers a selective advantage during infection. Genome Biol 24: 1-23.

[11] JONES DT, TAYLOR WR & THORNTON JM. 1992. The rapid generation of mutation data matrices from protein sequences. Comput Appl Biosci 8: 275-282.

[12] KANNAN SR, SPRATT AN, QUINN TP, HENG X, LORSON CL, SÖNNERBORG A, BYRAREDDY SN & SINGH K. 2020. Infectivity of SARS-CoV-2: there Is Something More than D614G? Journal of Neuroimmune Pharmacology 15: 574-577.

[13] KAPLAN W & LITTLEJOHN TG. 2001. Swiss-PDB Viewer (Deep View). Briefings in Bioinformatics 2: 195-197.

[14] KIM SM ET AL. 2023. SARS-CoV-2 variants with NSP12 P323L/G671S mutations display enhanced virus replication in ferret upper airways and higher transmissibility. Cell Reports 42: 113077.

[15] KIRCHDOERFER RN & WARD AB. 2019. Structure of the SARS-CoV nsp12 polymerase bound to nsp7 and nsp8 co-factors. Nat Commun 10.

[16] KOÇHAN N, ESKIER D, SUNER A, KARAKÜLAH G & OKTAY Y. 2021. Different selection dynamics of S and RdRp between SARS-CoV-2 genomes with and without the dominant mutations. Infect Genet Evol 91.

[17] MARI A ET AL. 2021. Global Genomic Analysis of SARS-CoV-2 RNA Dependent RNA Polymerase Evolution and Antiviral Drug Resistance. Microorganisms 9.

[18] MERCATELLI D & GIORGI FM. 2020. Geographic and Genomic Distribution of SARS-CoV-2 Mutations. Front Microbiol 11.

[19] MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.

[20] NASCIMENTO VA ET AL. 2020. Genomic and phylogenetic characterisation of an imported case of SARS-CoV-2 in Amazonas State, Brazil. Mem Inst Oswaldo Cruz 115.

[21] NAVECA FG ET AL. 2021. COVID-19 in Amazonas, Brazil, was driven by the persistence of endemic lineages and P.1 emergence. Nat Med 27: 1230-1238.

[22] NAYDENOVA K ET AL. 2021. Structure of the SARS-CoV-2 RNA-dependent RNA polymerase in the presence of favipiravir-RTP. Proceedings of the National Academy of Sciences of the United States of America 118.

[23] PACHETTI M ET AL. 2020. Emerging SARS-CoV-2 mutation hot spots include a novel RNA-dependent-RNA polymerase variant. J Transl Med 18.

[24] PETTERSEN EF, GODDARD TD, HUANG CC, COUCH GS, GREENBLATT DM, MENG EC & FERRIN TE. 2004. UCSF Chimera - A visualization system for exploratory research and analysis. J Comput Chem 25(13): 1605-1612.

[25] SABINO EC ET AL. 2021. Resurgence of COVID-19 in Manaus, Brazil, despite high seroprevalence. The Lancet 397: 452-455.

[26] SAHIN E, BOZDAYI G, YIGIT S, MUFTAH H, DIZBAY M, TUNCCAN OG, FIDAN I & CAGLAR K. 2021. Genomic characterization of SARS-CoV-2 isolates from patients in Turkey reveals the presence of novel mutations in spike and nsp12 proteins. J Med Virol 93: 6016-6026.

[27] SHIRAKI K & DAIKOKU T. 2020. Favipiravir, an anti-influenza drug against life-threatening RNA virus infections. Pharmacol Ther 209: 107512.

[28] TAMURA K, STECHER G & KUMAR S. 2021. MEGA11: Molecular Evolutionary Genetics Analysis Version 11. Mol Biol Evol 38: 3022-3027.

[29] TAYLOR L. 2021. Covid-19: Is Manaus the final nail in the coffin for natural herd immunity? BMJ 372.

[30] VAN DER SPOEL D, LINDAHL E, HESS B, GROENHOF G, MARK AE & BERENDSEN HJC. 2005. GROMACS: fast, flexible, and free. J Comput Chem 26: 1701-1718.

[31] WARD D, HIGGINS M, PHELAN JE, HIBBERD ML, CAMPINO S & CLARK TG. 2021. An integrated in silico immuno-genetic analytical platform provides insights into COVID-19 serological and vaccine targets. Genome Med 13.

[32] WHO - WORLD HEALTH ORGANIZATION. 2023. Coronavirus (COVID-2019) Dashboard. Available in: <https://covid19.who.int/> Accessed in September 2023.
» https://covid19.who.int/

[33] WU F ET AL. 2020. A new coronavirus associated with human respiratory disease in China. Nature 2020 579:7798 579: 265-269.

[34] YUAN S ET AL. 2020. Nonstructural Protein 1 of SARS-CoV-2 Is a Potent Pathogenicity Factor Redirecting Host Protein Synthesis Machinery toward Viral RNA. Molecular Cell 80: 1055-1066.e6.

Structure (NSP12 mutations)	RMSD (Angstrons)				References
Structure (NSP12 mutations)	NSP12 (A)	NSP7 (C)	NSP8 (B and D)	RNA (P and T)	References
Mutations close to the active site
M794V	0.692	0.750	0.755	0.545	Wuhan X Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.
E796D	0.678	0.740	0.743	0.546	Wuhan X this work
M794V X E796D	0.380	0.388	0.372	0.401	Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. X this work
Mutations close to RNA Upstream
N911K	0.692	0.793	0.714	0.524	Wuhan X Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.
R914K	0.683	0.765	0.739	0.568	Wuhan X this work
N911K X R914K	0.373	0.337	0.404	0.291	Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88. X this work
Most-frequent mutations
G671S	0.390	0.388	0.344	0.385	Wuhan X this work and Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.
P323L	0.391	0.370	0.404	0.483	Wuhan X this work and Miropolskaya et al. (2023)MIROPOLSKAYA N, KOZLOV M, PETUSHKOV I, PROSTOVA M, PUPOV D, ESYUNINA D, KOCHETKOV S & KULBACHINSKIY A. 2023. Effects of natural polymorphisms in SARS-CoV-2 RNA-dependent RNA polymerase on its activity and sensitivity to inhibitors in vitro. Biochimie 206: 81-88.

Brasil