Insights into the evolution of mutations in SARS-CoV-2 non-spike proteins.

The COVID-19 pandemic has been driven by the emergence of SARS-CoV-2 variants with mutations across all the viral proteins. Although mutations in the spike protein have received significant attention, understanding the prevalence and potential impact of mutations in other viral proteins is essential for comprehending the evolution of SARS-CoV-2. Here, we conducted a comprehensive analysis of approximately 14 million sequences of SARS-CoV-2 deposited in the GISAID database until December 2022 to identify prevalent mutations in the non-spike proteins at the global and country levels. Additionally, we evaluated the energetics of each mutation to better understand their impact on protein stability. While the consequences of many mutations remain unclear, we discuss potential structural and functional significance of some mutations. Our study highlights the ongoing evolutionary process of SARS-CoV-2 and underscores the importance of understanding changes in non-spike proteins.

Identification and characterization of aurintricarboxylic acid as a potential inhibitor of SARS-CoV-2 PLpro.

As the global health crisis due to evolution of mutations in SARS-CoV-2 continues, it is important to develop several effective antivirals to control the disease. Targeting papain-like protease (PLpro) of SARS-CoV-2 for drug development is a promising strategy due to its dual role in promoting viral replication and dysregulating host immune responses. Here, we screened a library of compounds to find potential inhibitors of PLpro. We find aurintricarboxylic acid (ATA) inhibits PLpro with Ki and IC50 values of 16 µM and 30 µM, respectively. The binding of ATA to PLpro was further characterized using isothermal titration calorimetry, differential scanning fluorimetry, dynamic light scattering and circular dichroism spectrometry. In vitro assays showed the antiviral potential of ATA with IC50 of 50 µM. In vivo efficacy was studied in Syrian hamsters and the results are being discussed.

Molecular and Biochemical Analysis of Duplicated Cytosolic CuZn Superoxide Dismutases of Rice and in silico Analysis in Plants.

Superoxide dismutases (SODs, EC 1.15.1.1) are ubiquitous antioxidant metalloenzymes important for oxidative stress tolerance and cellular redox environment. Multiple factors have contributed toward the origin and diversity of SOD isoforms among different organisms. In plants, the genome duplication events, responsible for the generation of multiple gene copies/gene families, have also contributed toward the SOD diversity. However, the importance of such molecular events on the characteristics of SODs has not been studied well. This study investigated the effects of divergence on important characteristics of two block-duplicated rice cytosolic CuZn SODs (OsCSD1, OsCSD4), along with in silico assessment of similar events in other plants. The analysis revealed heterogeneity in gene length, regulatory regions, untranslated regions (UTRs), and coding regions of two OsCSDs. An inconsistency in the database-predicted OsCSD1 gene structure was also identified and validated experimentally. Transcript analysis showed differences in the basal levels and stress responsiveness of OsCSD1 and OsCSD4, and indicated the presence of two transcription start sites in the OsCSD1. At the amino acid level, the two OsCSDs showed differences at 18 sites; however, both exist as a homodimer, displaying typical CuZn SOD characteristics, and enhancing the oxidative stress tolerance of Escherichia coli cells. However, OsCSD4 showed higher specific activity as well as stability. The comparison of the two OsCSDs with reported thermostable CSDs from other plants identified regions likely to be associated with stability, while the homology modeling and superposition highlighted structural differences. The two OsCSDs displayed heteromeric interaction capability and forms an enzymatically active heterodimer (OsCSD1:OsCSD4) on co-expression, which may have significance as both are cytosolic. In silico analysis of 74 plant genomes revealed the prevalence of block duplications for multiple CSD copies (mostly cytosolic). The divergence and clustering analysis of CSDs suggested the possibility of an ancestral duplication event in monocots. Conserved SOD features indicating retention of SOD function among CSD duplicates were evident in few monocots and dicots. In most other species, the CSD copies lacked critical features and may not harbor SOD function; however, other feature-associated functions or novel functions might be present. These aspects of divergent CSD copies encoding co-localized CSDs may have implications in plant SOD functions in the cytosol and other organelles.

Evaluating Stability and Activity of SARS-CoV-2 PLpro for High-throughput Screening of Inhibitors.

Because of the essential roles of SARS-CoV-2 papain-like protease (PLpro) in the viral polyprotein processing and suppression of host immune responses, it is a crucial target for drug discovery against COVID-19. To develop robust biochemical methodologies for inhibitor screening against PLpro, extensive characterization of recombinant protein is important. Here we report cloning, expression, and purification of the recombinant SARS-CoV-2 PLpro, and explore various parameters affecting its stability and the catalytic activity. We also report the optimum conditions which should be used for high-throughput inhibitor screening using a fluorogenic tetrapeptide substrate.

Thymidylate kinase (TMK) of the photosynthetic, nitrogen-fixing cyanobacterium Nostoc sp. strain PCC7120: Biophysical, biochemical and physiological characterisation.

Thymidylate kinase (TMK/TMPK) is an important enzyme in DNA biosynthesis and catalyses the conversion of dTMP to dTDP. Due to its therapeutic potential, the focus has been on characterizing the TMK proteins of pathogens and human origin, with very little information available on the TMK proteins of photosynthetic organisms and agriculturally important nitrogen-fixing organisms. In this work we report the characterisation of TMK in an evolutionarily ancient organism, cyanobacteria. The TMK protein of the photosynthetic, nitrogen-fixing cyanobacterium Nostoc PCC7120 (AnTMK) was found to have low conformational stability, which related to its low Tm of ~46 °C confirmed by Differential Scanning Fluorimetry (DSF) and Differential Scanning Calorimetry (DSC) techniques. The AnTMK protein exhibited substrate specificity for dTMP and ATP with Km of 20.74 ± 1.47 µM and 20.17 ± 2.96 µM respectively. The enzyme kinetics data and the positive co-operativity observed between dTMP and ATP binding correlated well with the data obtained from Isothermal Titration Calorimetry (ITC). Homology model of the enzyme suggested that the binding mode of substrate nucleotides to the enzyme is conserved. When overexpressed constitutively in Nostoc PCC7120 (Antmk+), it supported faster growth measured in terms of chlorophyll a content under normal growth conditions, but exhibited lower photosynthetic efficiency. Compared to the vector control recombinant Nostoc AnpAM, the Antmk + cells exhibited higher photoinhibition at higher light irradiance with more open reaction centres and lower dissipation of heat, indicative of damage to photosynthetic machinery. This indicated that the TMK is likely to have a significant role in photosynthetic organisms.

Structural insights into SARS-CoV-2 proteins.

The unprecedented scale of the ongoing COVID-19 pandemic has catalyzed an intense effort of the global scientific community to unravel different aspects of the disease in a short time. One of the crucial aspects of these developments is the determination of more than three hundred experimental structures of SARS-CoV-2 proteins in the last few months. These include structures of viral non-structural, structural, and accessory proteins and their complexes determined by either X-ray diffraction or cryo-electron microscopy. These structures elucidate the intricate working of different components of the viral machinery at the atomic level during different steps of the viral life cycle, including attachment to the host cell, viral genome replication and transcription, and genome packaging and assembly of the virion. Some of these proteins are also potential targets for drug development against the disease. In this review, we discuss important structural features of different SARS-CoV-2 proteins with their function, and their potential as a target for therapeutic interventions.

Structural and Functional Characterisation of the Domains of Ubiquitin-Activating Enzyme (E1) of Saccharomyces cerevisiae.

Ubiquitin-activating enzyme (E1) is the first enzyme of the ubiquitination pathway and is required to activate ubiquitin. E1 of Saccharomyces cerevisiae is a large multidomain monomeric protein. There are no studies available on the domains of yeast E1 as independent entities. Four domains of E1 namely, first catalytic cysteine half-domain (FCCH), four-helix bundle (4HB), second catalytic cysteine half-domain (SCCH) and ubiquitin fold domain (UFD) were characterised to understand their structural and functional independence vis-a-vis full length E1. Spectroscopic characterisation using circular dichroism and fluorescence suggested that these domains can act as independent folding units and attain native-like secondary structure. The structural features obtained with the peptides SCCH and FCCH of S. cerevisiae bear a high degree of structural similarity to the corresponding fragments of mouse from literature. Nearly 50% of the residues of the 4HB domain of the S. cerevisiae sample showed helical conformation. They displayed a high degree of conservation when compared with 4HB of mouse with respect to their identity and arrangement. The fragment UFD of yeast formed an α/ß domain as in the whole protein and exhibited 45% homology with that of mouse, showing a similar arrangement of α and ß elements in its secondary structure. Overexpression of the domains in vivo indicated that the SCCH domain and to some extent UFD apparently interfere with cellular functions such as survival under various stresses.

Biochemical and functional characterization of OsCSD3, a novel CuZn superoxide dismutase from rice.

Superoxide dismutases (SODs, EC 1.15.1.1) belong to an important group of antioxidant metalloenzymes. Multiple SODs exist for scavenging of reactive oxygen species (ROS) in different cellular compartments to maintain an intricate ROS balance. The present study deals with molecular and biochemical characterization of CuZn SOD encoded by LOC_Os03g11960 (referred to as OsCSD3), which is the least studied among the four rice isozymes. The OsCSD3 showed higher similarity to peroxisomal SODs in plants. The OsCSD3 transcript was up-regulated in response to salinity, drought, and oxidative stress. Full-length cDNA encoding OsCSD3 was cloned and expressed in Escherichia coli and analyzed for spectral characteristics. UV (ultraviolet)-visible spectroscopic analysis showed evidences of d-d transitions, while circular dichroism analysis indicated high ß-sheet content in the protein. The OsCSD3 existed as homodimer (∼36 kDa) with both Cu2+ and Zn2+ metal cofactors and was substantially active over a wide pH range (7.0-10.8), with optimum pH of 9.0. The enzyme was sensitive to diethyldithiocarbamate but insensitive to sodium azide, which are the characteristics features of CuZn SODs. The enzyme also exhibited bicarbonate-dependent peroxidase activity. Unlike several other known CuZn SODs, OsCSD3 showed higher tolerance to hydrogen peroxide and thermal inactivation. Heterologous overexpression of OsCSD3 enhanced tolerance of E. coli sod double-knockout (ΔsodA ΔsodB) mutant and wild-type strain against methyl viologen-induced oxidative stress, indicating the in vivo function of this enzyme. The results show that the locus LOC_Os03g11960 of rice encodes a functional CuZn SOD with biochemical characteristics similar to the peroxisomal isozymes.

Structural Basis of Why Nelfinavir-Resistant D30N Mutant of HIV-1 Protease Remains Susceptible to Saquinavir.

Although anti-HIV-1 protease drugs nelfinavir (NFV) and saquinavir (SQV) share common functional groups, D30N is a major resistance mutation against NFV but remains susceptible to SQV. We have determined the crystal structure of D30N mutant-tethered HIV-1 protease in complex with SQV to 1.79 Å resolution. Structural analysis showed that SQV forms two direct hydrogen bonds with the main chain atoms of the residues Asp29 and Asp30 that are not observed in the D30N-NFV complex. Apart from maintaining these two main chain hydrogen bonds, the P2-asparagine of SQV forms an additional hydrogen bond to the mutated side chain of the residue 30. These could be the reasons why D30N is not a drug resistance mutation against SQV. This structure supports the previous studies showing that the interactions between a potential inhibitor and backbone atoms of the enzyme are important to maintain potency against drug-resistant HIV-1 protease.

X-ray structure reveals a new class and provides insight into evolution of alkaline phosphatases.

The alkaline phosphatase (AP) is a bi-metalloenzyme of potential applications in biotechnology and bioremediation, in which phosphate monoesters are nonspecifically hydrolysed under alkaline conditions to yield inorganic phosphate. The hydrolysis occurs through an enzyme intermediate in which the catalytic residue is phosphorylated. The reaction, which also requires a third metal ion, is proposed to proceed through a mechanism of in-line displacement involving a trigonal bipyramidal transition state. Stabilizing the transition state by bidentate hydrogen bonding has been suggested to be the reason for conservation of an arginine residue in the active site. We report here the first crystal structure of alkaline phosphatase purified from the bacterium Sphingomonas. sp. Strain BSAR-1 (SPAP). The crystal structure reveals many differences from other APs: 1) the catalytic residue is a threonine instead of serine, 2) there is no third metal ion binding pocket, and 3) the arginine residue forming bidentate hydrogen bonding is deleted in SPAP. A lysine and an aspargine residue, recruited together for the first time into the active site, bind the substrate phosphoryl group in a manner not observed before in any other AP. These and other structural features suggest that SPAP represents a new class of APs. Because of its direct contact with the substrate phosphoryl group, the lysine residue is proposed to play a significant role in catalysis. The structure is consistent with a mechanism of in-line displacement via a trigonal bipyramidal transition state. The structure provides important insights into evolutionary relationships between members of AP superfamily.

Insights into the mechanism of drug resistance: X-ray structure analysis of G48V/C95F tethered HIV-1 protease dimer/saquinavir complex.

The mutation G48V in HIV-1 protease is a major resistance mutation against the drug saquinavir. Recently, G48V mutation is found to co-exist with the mutation C95F in AIDS patients treated with saquinavir. We report here the three-dimensional crystal structure of G48V/C95F tethered HIV-1 protease/saquinavir complex. The structure indicates following as the possible causes of drug resistance: (1) loss of direct van der Waals interactions between saquinavir and enzyme residues PHE-53 and PRO-1081, (2) loss of water-mediated hydrogen bonds between the carbonyl oxygen atoms in saquinavir and amide nitrogen atoms of flap residues 50 and 1050, (3) changes in inter-monomer interactions, which could affect the energetics of domain movements associated with inhibitor-binding, and (4) significant reduction in the stability of the mutant dimer. The present structure also provides a rationale for the clinical observation that the resistance mutations C95F/G48V/V82A occur as a cluster in AIDS patients.

X-ray snapshot of HIV-1 protease in action: observation of tetrahedral intermediate and short ionic hydrogen bond SIHB with catalytic aspartate.

Structural snapshots of each step in the catalytic cycle would help development of inhibitors of human immunodeficiency virus type 1 protease (HIV-1 PR) as effective drugs against HIV/AIDS. We report here one snapshot obtained by determining the structure of enzyme-substrate complex under conditions where the catalytic activity of the enzyme is greatly reduced. The 1.76 A crystal structure shows the oligopeptide substrate, AETFYVDGAA, converted in situ into a gem-diol tetrahedral intermediate (TI). The gem-diol intermediate is neutral and one of the hydroxyl oxygens forms a very short hydrogen bond (2.2 A) with the anionic aspartate of the catalytic dyad, which is monoprotonated. Further, there is no hydrogen atom on the outer oxygen of the neutral aspartate. These two observations provide direct evidence that, in the reaction mechanism, hydrogen bonding between catalytic aspartate and scissile carbonyl oxygen facilitates water attack on the scissile carbon atom. Comparison with the structural snapshot of the biproduct complex involving the same substrate reveals the reorganization of the hydrogen bonds at the catalytic center as the enzymatic reaction progresses toward completion. Accumulation of TI in the crystals provides direct evidence that collapse of TI is the rate-limiting step of hydrolysis.

Catalytic water co-existing with a product peptide in the active site of HIV-1 protease revealed by X-ray structure analysis.

BACKGROUND: It is known that HIV-1 protease is an important target for design of antiviral compounds in the treatment of Acquired Immuno Deficiency Syndrome (AIDS). In this context, understanding the catalytic mechanism of the enzyme is of crucial importance as transition state structure directs inhibitor design. Most mechanistic proposals invoke nucleophilic attack on the scissile peptide bond by a water molecule. But such a water molecule coexisting with any ligand in the active site has not been found so far in the crystal structures. PRINCIPAL FINDINGS: We report here the first observation of the coexistence in the active site, of a water molecule WAT1, along with the carboxyl terminal product (Q product) peptide. The product peptide has been generated in situ through cleavage of the full-length substrate. The N-terminal product (P product) has diffused out and is replaced by a set of water molecules while the Q product is still held in the active site through hydrogen bonds. The position of WAT1, which hydrogen bonds to both the catalytic aspartates, is different from when there is no substrate bound in the active site. We propose WAT1 to be the position from where catalytic water attacks the scissile peptide bond. Comparison of structures of HIV-1 protease complexed with the same oligopeptide substrate, but at pH 2.0 and at pH 7.0 shows interesting changes in the conformation and hydrogen bonding interactions from the catalytic aspartates. CONCLUSIONS/SIGNIFICANCE: The structure is suggestive of the repositioning, during substrate binding, of the catalytic water for activation and subsequent nucleophilic attack. The structure could be a snap shot of the enzyme active site primed for the next round of catalysis. This structure further suggests that to achieve the goal of designing inhibitors mimicking the transition-state, the hydrogen-bonding pattern between WAT1 and the enzyme should be replicated.

Resistance mechanism revealed by crystal structures of unliganded nelfinavir-resistant HIV-1 protease non-active site mutants N88D and N88S.

Nelfinavir is an inhibitor of HIV-1 protease, and is used for treatment of patients suffering from HIV/AIDS. However, treatment results in drug resistant mutations in HIV-1 protease. N88D and N88S are two such mutations which occur in the non-active site region of the enzyme. We have determined crystal structures of unliganded N88D and N88S mutants of HIV-1 protease to resolution of 1.65A and 1.8A, respectively. These structures refined against synchrotron data lead to R-factors of 0.1859 and 0.1780, respectively. While structural effects of N88D are very subtle, the mutation N88S has caused a significant conformational change in D30, an active site residue crucial for substrate and inhibitor binding.

Crystallization and preliminary X-ray crystallographic analysis of PhoK, an extracellular alkaline phosphatase from Sphingomonas sp. BSAR-1.

Alkaline phosphatases (APs) are widely distributed from microbes to humans and are involved in several important biological processes such as phosphate nutrition, signal transduction and pathogenesis. Alkaline phosphatases are also useful in various industrial applications and in recombinant DNA technology. A new AP enzyme from Sphingomonas sp. strain BSAR-1, termed PhoK, has been shown to be useful in uranium bioprecipitation. PhoK was expressed, purified and crystallized. The crystals belonged to space group P4(3)2(1)2 or P4(1)2(1)2, with unit-cell parameters a = b = 87.37, c = 168.16 A, and contained one enzyme molecule in the asymmetric unit. Native diffraction data have been collected to 1.95 A resolution at the ESRF.

Crystallization and preliminary X-ray diffraction analysis of human seminal plasma protein PSP94.

The human seminal plasma protein PSP94 is a small protein of 94 residues that contains ten cysteines. Since its discovery about 25 years ago, several potential biological functions have been reported for this protein. Many PSP94 homologues have also been identified since then from various species, but no crystal structure has been determined to date. PSP94 has been purified from human seminal plasma and crystallized. These crystals diffracted to approximately 2.3 A resolution and belonged to space group P4(1)2(1)2, with unit-cell parameters a = 107.9, b = 107.9, c = 92.1 A. There are four molecules in the asymmetric unit. Structure solution by the heavy-atom method is currently in progress.

X-ray structure of HIV-1 protease in situ product complex.

HIV-1 protease is an effective target for design of different types of drugs against AIDS. HIV-1 protease is also one of the few enzymes that can cleave substrates containing both proline and nonproline residues at the cleavage site. We report here the first structure of HIV-1 protease complexed with the product peptides SQNY and PIV derived by in situ cleavage of the oligopeptide substrate SQNYPIV, within the crystals. In the structure, refined against 2.0-A resolution synchrotron data, a carboxyl oxygen of SQNY is hydrogen-bonded with the N-terminal nitrogen atom of PIV. At the same time, this proline nitrogen atom does not form any hydrogen bond with catalytic aspartates. These two observations suggest that the protonation of scissile nitrogen, during peptide bond cleavage, is by a gem-hydroxyl of the tetrahedral intermediate rather than by a catalytic aspartic acid.

Crystal structure of HIV-1 protease in situ product complex and observation of a low-barrier hydrogen bond between catalytic aspartates.

HIV-1 protease is an effective target for designing drugs against AIDS, and structural information about the true transition state and the correct mechanism can provide important inputs. We present here the three-dimensional structure of a bi-product complex between HIV-1 protease and the two cleavage product peptides AETF and YVDGAA. The structure, refined against synchrotron data to 1.65 A resolution, shows the occurrence of the cleavage reaction in the crystal, with the product peptides still held in the enzyme active site. The separation between the scissile carbon and nitrogen atoms is 2.67 A, which is shorter than a normal van der Waal separation, but it is much longer than a peptide bond length. The substrate is thus in a stage just past the G'Z intermediate described in Northrop's mechanism [Northrop DB (2001) Acc Chem Res 34:790-797]. Because the products are generated in situ, the structure, by extrapolation, can give insight into the mechanism of the cleavage reaction. Both oxygens of the generated carboxyl group form hydrogen bonds with atoms at the catalytic center: one to the OD2 atom of a catalytic aspartate and the other to the scissile nitrogen atom. The latter hydrogen bond may have mediated protonation of scissile nitrogen, triggering peptide bond cleavage. The inner oxygen atoms of the catalytic aspartates in the complex are 2.30 A apart, indicating a low-barrier hydrogen bond between them at this stage of the reaction, an observation not included in Northrop's proposal. This structure forms a template for designing mechanism-based inhibitors.

Observation of a tetrahedral reaction intermediate in the HIV-1 protease-substrate complex.

HIV-1 protease is an effective target for the design of drugs against AIDS. To help this process of drug design, three-dimensional structures have been determined of complexes between HIV-1 protease and a variety of transition-state analogue inhibitors. The true transition state, however, has not been structurally characterized. The crystal structure of the C95M/C1095A HIV-1 protease tethered dimer shows a distinctive feature in which the two flaps of the enzyme are in a 'closed conformation' even in the unliganded state. This unique feature has been utilized here to study the structure of HIV-1 protease complexed to an oligopeptide substrate of amino acid sequence His-Lys-Ala-Arg-Val-Leu*NPhe-Glu-Ala-Nle-Ser (where * denotes the cleavage site, and NPhe and Nle denote p-nitrophenylalanine and norleucine residues respectively). The X-ray structure of the complex refined against 2.03 A (0.203 nm) resolution synchrotron data shows that the substrate is trapped as a tetrahedral reaction intermediate in the crystal. The hydrogen-bonding interactions between the reaction intermediate and the catalytic aspartates are different from those observed previously using transition-state analogues. The reaction intermediate did not dissociate to release the products, possibly due to the inflexibility introduced in the flaps when the enzyme is packed inside crystals.

1.8A X-ray structure of C95M/C1095F double mutant of tethered HIV-1 protease dimer complexed with acetyl pepstatin.

Under the selection pressure of drugs, mutations appear in HIV-1 protease even at the sites, which are conserved in the untreated individuals. Cysteine 95 is a highly conserved residue and is believed to be involved in regulation of HIV-1 protease. In some of the virus isolates from patients undergoing heavy treatment with anti-HIV protease drugs, C95F mutation has appeared. The present study reports 1.8A X-ray structure of C95M/C1095F double mutant of tethered HIV-1 protease dimer complexed with acetyl pepstatin. It is found that in this mutant, dimer interface has become more rigid and that the packing at the interface of terminal and core domains is altered. These alterations may be relevant to C95F mutation conferring drug resistance to HIV-1 protease.