In Silico Investigation of the New UK (B.1.1.7) and South African (501Y.V2) SARS-CoV-2 Variants with a Focus at the ACE2–Spike RBD Interface

SARS-CoV-2 exploits angiotensin-converting enzyme 2 (ACE2) as a receptor to invade cells. It has been reported that the UK and South African strains may have higher transmission capabilities, eventually in part due to amino acid substitutions on the SARS-CoV-2 Spike protein. The pathogenicity seems modified but is still under investigation. Here we used the experimental structure of the Spike RBD domain co-crystallized with part of the ACE2 receptor, several in silico methods and numerous experimental data reported recently to analyze the possible impacts of three amino acid replacements (Spike K417N, E484K, N501Y) with regard to ACE2 binding. We found that the N501Y replacement in this region of the interface (present in both the UK and South African strains) should be favorable for the interaction with ACE2, while the K417N and E484K substitutions (South African strain) would seem neutral or even unfavorable. It is unclear if the N501Y substitution in the South African strain could counterbalance the K417N and E484K Spike replacements with regard to ACE2 binding. Our finding suggests that the UK strain should have higher affinity toward ACE2 and therefore likely increased transmissibility and possibly pathogenicity. If indeed the South African strain has a high transmission level, this could be due to the N501Y replacement and/or to substitutions in regions located outside the direct Spike–ACE2 interface but not so much to the K417N and E484K replacements. Yet, it should be noted that amino acid changes at Spike position 484 can lead to viral escape from neutralizing antibodies. Further, these amino acid substitutions do not seem to induce major structural changes in this region of the Spike protein. This structure–function study allows us to rationalize some observations made for the UK strain but raises questions for the South African strain.     

Possible Link between Higher Transmissibility of Alpha,Kappa and Delta Variants of SARS-CoV-2 and Increased Structural Stability of Its Spike Protein and hACE2 Affinity

The Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) outbreak in December 2019 has caused a global pandemic. The rapid mutation rate in the virus has created alarming situations worldwide and is being attributed to the false negativity in RT-PCR tests. It has also increased the chances of reinfection and immune escape. Recently various lineages namely, B.1.1.7 (Alpha), B.1.617.1 (Kappa), B.1.617.2 (Delta) and B.1.617.3 have caused rapid infection around the globe. To understand the biophysical perspective, we have performed molecular dynamic simulations of four different spikes (receptor binding domain)-hACE2 complexes, namely wildtype (WT), Alpha variant (N501Y spike mutant), Kappa (L452R, E484Q) and Delta (L452R, T478K), and compared their dynamics, binding energy and molecular interactions. Our results show that mutation has caused significant increase in the binding energy between the spike and hACE2 in Alpha and Kappa variants. In the case of Kappa and Delta variants, the mutations at L452R, T478K and E484Q increased the stability and intra-chain interactions in the spike protein, which may change the interaction ability of neutralizing antibodies to these spike variants. Further, we found that the Alpha variant had increased hydrogen interaction with Lys353 of hACE2 and more binding affinity in comparison to WT. The current study provides the biophysical basis for understanding the molecular mechanism and rationale behind the increase in the transmissivity and infectivity of the mutants compared to wild-type SARS-CoV-2.     

Hidden in Plain Sight: Natural Products of Commensal Microbiota as an Environmental Selection Pressure for the Rise of New Variants of SARS-CoV-2

Since the emergence of SARS-CoV-2, little attention has been paid to the interplay between the interaction of virus and commensal microbiota. Here, we used molecular docking and dynamics simulations to study the interaction of some of the known metabolites and natural products (NPs) produced by commensal microbiota with the receptor binding domain (RBD) of the spike glycoprotein of SARS-CoV-2. The results predict that NPs of commensal microbiota such as bile acids and non-ribosomal peptides (NRPs), of which some are siderophores, bind to the wild-type RBD and interfere with its binding to the ACE2 receptor. N501Y mutation, which is present in many of the emerging variants of the virus, abolishes the predicted binding pocket of bile acids and NRPs. Based on these findings, available experimental data showing that bile acids reduce the binding affinity of wild-type RBD to the ACE2 receptor, and the data suggesting that the respiratory tract microbiota affect viral infection we put forward the following proposal: mutations such as N501Y enable the RBD to bind to the ACE2 receptor more effectively in the presence of NPs produced by the respiratory tract bacteria thereby, increasing the infectivity rate of the virus. We hope our data stimulate future works to better understand the interactions of NPs produced by commensal microbiota with respiratory viruses like SARS-CoV-2.     

Preliminary Structural Data Revealed That the SARS-CoV-2 B.1.617 Variant's RBD Binds to ACE2 Receptor Stronger Than the Wild Type to Enhance the Infectivity

The evolution of new SARS-CoV-2 variants around the globe has made the COVID-19 pandemic more worrisome, further pressuring the health care system and immunity. Novel variations that are unique to the receptor-binding motif (RBM) of the receptor-binding domain (RBD) spike glycoprotein, i. e. L452R-E484Q, may play a different role in the B.1.617 (also known as G/452R.V3) variant's pathogenicity and better survival compared to the wild type. Therefore, a thorough analysis is needed to understand the impact of these mutations on binding with host receptor (RBD) and to guide new therapeutics development. In this study, we used structural and biomolecular simulation techniques to explore the impact of specific mutations (L452R-E484Q) in the B.1.617 variant on the binding of RBD to the host receptor ACE2. Our analysis revealed that the B.1.617 variant possesses different dynamic behaviours by altering dynamic-stability, residual flexibility and structural compactness. Moreover, the new variant had altered the bonding network and structural-dynamics properties significantly. MM/GBSA technique was used, which further established the binding differences between the wild type and B.1.617 variant. In conclusion, this study provides a strong impetus to develop novel drugs against the new SARS-CoV-2 variants.     

Characterization of Mutations Causing CYP21A2 Deficiency in Brazilian and Portuguese Populations

Deficiency of 21-hydroxylase enzyme (CYP21A2) represents 90% of cases in congenital adrenal hyperplasia (CAH), an autosomal recessive disease caused by defects in cortisol biosynthesis. Computational prediction and functional studies are often the only way to classify variants to understand the links to disease-causing effects. Here we investigated the pathogenicity of uncharacterized variants in the CYP21A2 gene reported in Brazilian and Portuguese populations. Physicochemical alterations, residue conservation, and effect on protein structure were accessed by computational analysis. The enzymatic performance was obtained by functional assay with the wild-type and mutant CYP21A2 proteins expressed in HEK293 cells. Computational analysis showed that p.W202R, p.E352V, and p.R484L have severely impaired the protein structure, while p.P35L, p.L199P, and p.P433L have moderate effects. The p.W202R, p.E352V, p.P433L, and p.R484L variants showed residual 21OH activity consistent with the simple virilizing phenotype. The p.P35L and p.L199P variants showed partial 21OH efficiency associated with the non-classical phenotype. Additionally, p.W202R, p.E352V, and p.R484L also modified the protein expression level. We have determined how the selected CYP21A2 gene mutations affect the 21OH activity through structural and activity alteration contributing to the future diagnosis and management of CYP21A2 deficiency.     

Identification of two new hydrophobic residues on basic fibroblast growth factor important for fibroblast growth factor receptor binding

Basic fibroblast growth factor (bFGF) is implicated in the pathogenesis of several types of vascular and connective diseases. A key step in the discovery of bFGF receptor antagonists to mitigate these actions is to define the functional epitopes required for receptor binding of the growth factor. Using structure-based site-directed mutagenesis, two critical areas on the bFGF surface for the high affinity receptor binding have already been identified [Springer, B.A., Pantoliano, M.W., Barberal, F.A., Gunyuzlu, P.L., Thompson, L.D., Herblin, W.F., Rosenfeld, S.A. and Book, G.W. (1994) J. Biol. Chem., 269, 26879-26884; Zhu, H.Y., Ramnarayan, K., Anchin, J., Miao, Y., Sereno, A., Millman, L., Zheng, J., Balaji, V.N. and Wolff, M.E. (1995) J. Biol. Chem., 270, 21869-21874; Zhu, H.Y., Anchin, J., Ramnarayan, K., Zheng, J., Kawai, T., Mong, S. and Wolff, M.E. (1997) Protein Engng, 10, 417-421]. According to these studies, one receptor binding site includes two polar residues Glu96 and Asn104 on bFGF whereas the other includes four hydrophobic residues Tyr24, Tyr103, Leu140 and Met142. Using a protein modelling technique, we report here the identification of a new hydrophobic patch on bFGF which includes residues Tyr73, Val88 and Phe93. The role of this area on receptor binding affinity was evaluated by mutating each of these residues individually and determining the mutated protein's (mutein's) receptor binding affinity. In addition, we examined the role of two other hydrophobic residues, Phe30 and Leu138, on bFGF for high-affinity receptor binding. These two residues are the neighbors of the hydrophobic residues Tyr24 and Tyr103, respectively. Replacement of Val88 and Phe93 with alanine reduced the receptor binding affinity about 10- and 80-fold, respectively, compared with wild-type bFGF. In contrast, substitution of Phe30 and Leu138 with alanine has no effect on the receptor binding affinities. We conclude that the newly identified hydrophobic residues, Val88 and Phe93, are crucial for the receptor binding. The present data, together with the previous identification of four hydrophobic residues (Tyr24, Tyr103, Leu140 and Met142), suggests that there are two hydrophobic receptor binding sites on the bFGF surface. Our findings can be employed in the discovery and design of potent bFGF antagonists using computational methods.      

Enhancement of Lipase CAL‐A Selectivity by Protein Engineering for the Hydrolysis of Erucic Acid from Crambe Oil

The aim of this study is to pursue the identification and characterization of different CAL‐A variants displaying higher specificity toward erucic acid than CAL‐A wild type (wt). A careful analysis of the data generated from previously created site‐directed saturation libraries reveals several variants that display a higher preference for the hydrolysis of p‐nitrophenyl (pNP)‐erucate over pNP‐oleate than the wt. The best three candidates (CAL‐A V238D, V238Y, and V286N) are applied in biocatalysis using both Crambe oil and ethyl ester derivatives. When acting on Crambe oil, these CAL‐A variants are as efficient as CAL‐A wt in terms of C22:1 enrichment and product recovery independently of the temperature (enrichment and recovery values between 70–76% and 67–79% at 37 °C, and between 71–73% and 61–75% at 50 °C). In contrast, hydrolysis of Crambe ethyl esters leads to substantially increased accumulations of C22:1 and recovery values (V238Y: 78% enrichment and 92% recovery; V286N: 83% enrichment and 91% recovery) when using CAL‐A V238Y and CAL‐A V286N compared to CAL‐A wt (78% enrichment, 60% recovery) in the free fatty acid fraction. Practical Applications: This study describes the enhancement of lipase CAL‐A selectivity for the isolation and recovery of erucic acid (C22:1) from plant oil or its ethyl ester derivatives. Hence, this approach could represent a more eco‐friendly alternative for its application in processes where the erucic acid is used as building block, such as the production of surfactants or polymers.     

The role of loop 7 in mediating calcineurin regulation

Calcineurin (CN) is a heterodimer protein consisting of a 61kDa catalytic subunit A and a 19 kDa regulatory subunit B. Itplays a critical role in T-cell activation and is involved inmany cellular processes. Regulation of CN is rather complex,including a number of factors such as divalent metal ions (primarilyCa²⁺ and Mn²⁺), calmodulin (CaM) and autoinhibition (AI) segment.Previously, we reported that a loop 7 deletion mutant (V314)in subunit A exhibited high phosphatase activity, although themechanism for the surprising activity enhancement and whetherthe activity change applies to other loop 7 residues were notknown. In order to probe the role of loop 7, we have carriedout extensive mutagenesis experiments, followed by systematicactivity assays under a number of regulatory conditions. Allmutants, including single deletion mutants Y315, N316 and doubledeletion mutant V314Y315, showed increased phosphatase activity.Significantly, activities of the mutants containing the V314deletion, namely V314 and V314Y315, were no longer regulatedby regulatory subunit B. These results, along with the structureanalysis, suggest that loop 7 as a whole plays an importantrole in mediating CN’s regulation through bridging theregulatory subunit and catalytic core and interaction with theAI segment of CN. Received April 30, 2003; revised September 9, 2003; accepted September 12, 2003.     

Enzymatic Beacons for Specific Sensing of Dilute Nucleic Acid**

Enzymatic beacons, or E-beacons, are 1 : 1 bioconjugates of the nanoluciferase enzyme linked covalently at its C-terminus to hairpin forming ssDNA equipped with a dark quencher. We prepared E-beacons biocatalytically using HhC, the promiscuous Hedgehog C-terminal protein-cholesterol ligase. HhC attached nanoluciferase site-specifically to mono-sterylated hairpin oligonucleotides, called steramers. Three E-beacon dark quenchers were evaluated: Iowa Black, Onyx-A, and dabcyl. Each quencher enabled sensitive, sequence-specific nucleic acid detection through enhanced E-beacon bioluminescence upon target hybridization. We assembled prototype dabcyl-quenched E-beacons specific for SARS-CoV-2. Targeting the E484 codon of the virus Spike protein, E-beacons (80×10⁻¹² M) reported wild-type SARS-CoV-2 nucleic acid at ≥1×10⁻⁹ M by increased bioluminescence of 8-fold. E-beacon prepared for the SARS-CoV-2 E484K variant functioned with similar sensitivity. Both E-beacons could discriminate their target from the E484Q mutation of the SARS-CoV-2 Kappa variant. Along with mismatch specificity, E-beacons are two to three orders of magnitude more sensitive than synthetic molecular beacons.     

Detection of Natural Resistance-Associated Substitutions by Ion Semiconductor Technology in HCV1b Positive,Direct-Acting Antiviral Agents-Na?ve Patients

Naturally occurring resistance-associated substitutions (RASs) can negatively impact the response to direct-acting antivirals (DAAs) agents-based therapies for hepatitis C virus (HCV) infection. Herein, we set out to characterize the RASs in the HCV1b genome from serum samples of DAA-naïve patients in the context of the SINERGIE (South Italian Network for Rational Guidelines and International Epidemiology, 2014) project. We deep-sequenced the NS3/4A protease region of the viral population using the Ion Torrent Personal Genome Machine, and patient-specific majority rule consensus sequence summaries were constructed with a combination of freely available next generation sequencing data analysis software. We detected NS3/4A protease major and minor variants associated with resistance to boceprevir (V36L), telaprevir (V36L, I132V), simeprevir (V36L), and grazoprevir (V36L, V170I). Furthermore, we sequenced part of HCV NS5B polymerase using Sanger-sequencing and detected a natural RAS for dasabuvir (C316N). This mutation could be important for treatment strategies in cases of previous therapy failure.     

Synthesis and characterization of the first fluorescent nonpeptide NPY Y1 receptor antagonist

Cyanine-5-labelled neuropeptide Y (NPY) was demonstrated to be an ideal universal fluorescent ligand for the combined investigation of NPY Y(1), Y(2) and Y(5) receptors. With respect to improved stability, detection of receptor subtypes in cells and tissues, and prevention of receptor internalization, small nonpeptidic fluorescent antagonists should be superior. Here we present a set of four fluorescent nonpeptide NPY Y(1) receptor (Y(1)R) antagonists. The highest affinity was obtained by labelling an N(G)-(6-aminohexanoyl)argininamide derived from the Y(1)R antagonist BIBP 3226, with Py-1, a small pyrylium dye. The fluorescent pyridinium-type Y(1)R antagonist, compound 4 had K(i) values of 29 nM and 2.7 nM, which were determined by radioligand binding and flow cytometry under equilibrium conditions, respectively; 4 had a K(b) value of 0.6 nM (Ca(2+) assay). The large Stoke's shift (541 vs. 615 nm) in buffer (PBS, pH 7.4) in the presence of 1% BSA and the red emission (quantum yield 56%) are advantageous with respect to the signal-to-noise ratio. The new probe was successfully used in fluorescence-based binding experiments evaluated by flow cytometry and confocal microscopy; this demonstrates the potential of pyrylium dyes for the preparation of fluorescent ligands that are applicable for the study of G protein-coupled receptors on living cells.     

Anti‐HIV‐1 Peptide Derivatives Based on the HIV‐1 Co‐receptor CXCR4

The human immunodeficiency virus type 1 (HIV‐1) uses CD4 and the co‐receptor CCR5 or CXCR4 in the process of cell entry. The negatively charged extracellular domains of CXCR4 (CXCR4‐ED) interact with positive charges on the V3 loop of gp120, facilitating binding via electrostatic interactions. The presence of highly conserved positively charged residues in the V3 loop suggests that CXCR4‐ED‐derived inhibitors might be broadly effective inhibitors. Synthetic peptide derivatives were evaluated for anti‐HIV‐1 activity. The 39‐mer extracellular N‐terminal region (NT) was divided into three fragments with 10‐mer overlapping sites ( N1 – N3 ), and these linear peptides were synthesized. Peptide N1 contains Met 1–Asp 20 and shows significant anti‐HIV‐1 activity. Extracellular loops 1 and 2 (ECL1 and 2) were mimicked by cyclic peptides C1 and C2 , which were synthesized by chemoselective cyclization. Cyclic peptides C1 and C2 show higher anti‐HIV‐1 activity than their linear peptide counterparts, L1 and L2 . The cytotoxicities of C1 and C2 are lower than those of L1 and L2 . These results indicate that Met 1–Asp 20 segments of the NT and cyclic peptides of ECL1 and ECL2 are potent anti‐HIV‐1 drug candidates.     

Monoclonal Antibodies against Nucleocapsid Protein of SARS-CoV-2 Variants for Detection of COVID-19

Mitigation strategies of the coronavirus disease 2019 (COVID-19) pandemic have been greatly hindered by the continuous emergence of SARS-CoV-2 variants. New sensitive, rapid diagnostic tests for the wide-spectrum detection of viral variants are needed. We generated a panel of 41 monoclonal antibodies against the SARS-CoV-2 nucleocapsid protein (NP) by using mice hybridoma techniques. Of these mAbs, nine exhibited high binding activities and were applied in latex-based lateral flow immunoassays (LFIAs). The LFIAs utilizing NP-mAb-7 and -40 had the best sensitivity and lowest limit of detection: 8 pg for purified NP and 625 TCID₅₀/mL for the authentic virus (hCoV-19/Taiwan/4/2020). The specificity tests showed that the NP-mAb-40/7 LFIA strips did not cross-react with five human coronavirus strains or 20 other common respiratory pathogens. Importantly, we found that 10 NP mutants, including alpha (B.1.1.7), beta (B.1.351), gamma (P.1), and delta (B.1.617.2) variants, could be detected by NP-mAb-40/7 LFIA strips. A clinical study (n = 60) of the NP-mAb-40/7 LFIA strips demonstrated a specificity of 100% and sensitivity of 90% in infected individuals with cycle threshold (Ct) values < 29.5. These anti-NP mAbs have strong potential for use in the clinical detection of SARS-CoV-2 infection, whether the virus is wild-type or a variant of concern.     

Characterization of Novel Pathogenic Variants Causing Pyridox(am)ine 5′-Phosphate Oxidase-Dependent Epilepsy

Several variants of the enzyme pyridox(am)ine 5′-phosphate oxidase (PNPO), responsible for a rare form of vitamin B₆-dependent neonatal epileptic encephalopathy known as PNPO deficiency (PNPOD), have been reported. However, only a few of them have been characterised with respect to their structural and functional properties, despite the fact that the knowledge of how variants affect the enzyme may clarify the disease mechanism and improve treatment. Here, we report the characterisation of the catalytic, allosteric and structural properties of recombinantly expressed D33V, R161C, P213S, and E50K variants, among which D33V (present in approximately 10% of affected patients) is one of the more common variants responsible for PNPOD. The D33V and E50K variants have only mildly altered catalytic properties. In particular, the E50K variant, given that it has been found on the same chromosome with other known pathogenic variants, may be considered non-pathogenic. The P213S variant has lower thermal stability and reduced capability to bind the FMN cofactor. The variant involving Arg161 (R161C) largely decreases the affinity for the pyridoxine 5′-phosphate substrate and completely abolishes the allosteric feedback inhibition exerted by the pyridoxal 5′-phosphate product.     

Small Structural Proteins E and M Render the SARS-CoV-2 Pseudovirus More Infectious and Reveal the Phenotype of Natural Viral Variants

The SARS-CoV-2 pseudovirus is a commonly used strategy that mimics certain biological functions of the authentic virus by relying on biological legitimacy at the molecular level. Despite the fact that spike (S), envelope (E), and membrane (M) proteins together wrap up the SARS-CoV-2 virion, most of the reported pseudotype viruses consist of only the S protein. Here, we report that the presence of E and M increased the virion infectivity by promoting the S protein priming. The S, E, and M (SEM)-coated pseudovirion is spherical, containing crown-like spikes on the surface. Both S and SEM pseudoviruses packaged the same amounts of viral RNA, but the SEM virus bound more efficiently to cells stably expressing the viral receptor human angiotensin-converting enzyme II (hACE2) and became more infectious. Using this SEM pseudovirus, we examined the infectivity and antigenic properties of the natural SARS-CoV-2 variants. We showed that some variants have higher infectivity than the original virus and that some render the neutralizing plasma with lower potency. These studies thus revealed possible mechanisms of the dissemination advantage of these variants. Hence, the SEM pseudovirion provides a useful tool to evaluate the viral infectivity and capability of convalescent sera in neutralizing specific SARS-CoV-2 S dominant variants.     

Dimer Interface in Natural Variant NK1 Is Dispensable for HGF-Dependent Met Receptor Activation

NK1, a splicing variant of hepatocyte growth factor (HGF), binds to and activates Met receptor by forming an NK1 dimer and 2:2 complex with Met. Although the structural mechanism underlying Met activation by HGF remains incompletely resolved, it has been proposed that the NK1 dimer structure participates in this activation. We investigated the NK1 dimer interface’s role in Met activation by HGF. Because N127, V140, and K144 are closely involved in the head-to-tail NK1 dimer formation, mutant NK1 proteins with replacement of these residues by alanine were prepared. In Met tyrosine phosphorylation assays, N127-NK1, V140-NK1, and K144-NK1 showed 8.3%, 23.8%, and 52.2% activity, respectively, compared with wild-type NK1. Although wild-type NK1 promoted cell migration and scattering, N127-NK1, V140-NK1, and K144-NK1 hardly or marginally promoted them, indicating loss of activity of these mutant NK1 proteins to activate Met. In contrast, mutant HGFs (N127-HGF, V140-HGF, and K144-HGF) with the same amino acid replacements as in NK1 induced Met tyrosine phosphorylation and biological responses at levels comparable to those of wild-type HGF. These results indicate that the structural basis responsible for NK1-dependent Met dimer formation and activation differs from, or is at least distinguishable from, the structural basis responsible for HGF-dependent Met activation.     

人细小病毒B19的特性及其与血浆蛋白制品的相关性

人细小病毒B19(B19病毒)是一种直径约为20～25nm的无包膜单链线状DNA病毒,属于细小病毒家族。B19病毒对人类骨髓细胞,特别是红系祖细胞有高度趋向性,易感人群感染B19病毒可引起多种严重疾病,一般通过呼吸道和母婴垂直传播,但通过输注血液和血浆蛋白制品传播也非常普遍,已引起人们的广泛关注。本文对B19病毒的特性及其与血浆蛋白制品的相关性作一综述。     

Role of Conserved Residues and F322 in the Extracellular Vestibule of the Rat P2X7 Receptor in Its Expression,Function and Dye Uptake Ability

Activation of the P2X7 receptor results in the opening of a large pore that plays a role in immune responses, apoptosis, and many other physiological and pathological processes. Here, we investigated the role of conserved and unique residues in the extracellular vestibule connecting the agonist-binding domain with the transmembrane domain of rat P2X7 receptor. We found that all residues that are conserved among the P2X receptor subtypes respond to alanine mutagenesis with an inhibition (Y51, Q52, and G323) or a significant decrease (K49, G326, K327, and F328) of 2′,3′-O-(benzoyl-4-benzoyl)-ATP (BzATP)-induced current and permeability to ethidium bromide, while the nonconserved residue (F322), which is also present in P2X4 receptor, responds with a 10-fold higher sensitivity to BzATP, much slower deactivation kinetics, and a higher propensity to form the large dye-permeable pore. We examined the membrane expression of conserved mutants and found that Y51, Q52, G323, and F328 play a role in the trafficking of the receptor to the plasma membrane, while K49 controls receptor responsiveness to agonists. Finally, we studied the importance of the physicochemical properties of these residues and observed that the K49R, F322Y, F322W, and F322L mutants significantly reversed the receptor function, indicating that positively charged and large hydrophobic residues are important at positions 49 and 322, respectively. These results show that clusters of conserved residues above the transmembrane domain 1 (K49–Y51–Q52) and transmembrane domain 2 (G326–K327–F328) are important for receptor structure, membrane expression, and channel gating and that the nonconserved residue (F322) at the top of the extracellular vestibule is involved in hydrophobic inter-subunit interaction which stabilizes the closed state of the P2X7 receptor channel.