Targeted proteomics as a tool to detect SARS-CoV-2 proteins in clinical specimens

The rapid, sensitive and specific detection of SARS-CoV-2 is critical in responding to the current COVID-19 outbreak. In this proof-of-concept study, we explored the potential of targeted mass spectrometry (MS) based proteomics for the detection of SARS-CoV-2 proteins in both research samples and clinical specimens. First, we assessed the limit of detection for several SARS-CoV-2 proteins by parallel reaction monitoring (PRM) MS in infected Vero E6 cells. For tryptic peptides of Nucleocapsid protein, the limit of detection was estimated to be in the mid-attomole range (9E-13 g). Next, this PRM methodology was applied to the detection of viral proteins in various COVID-19 patient clinical specimens, such as sputum and nasopharyngeal swabs. SARS-CoV-2 proteins were detected in these samples with high sensitivity in all specimens with PCR Ct values <24 and in several samples with higher CT values. A clear relationship was observed between summed MS peak intensities for SARS-CoV-2 proteins and Ct values reflecting the abundance of viral RNA. Taken together, these results suggest that targeted MS based proteomics may have the potential to be used as an additional tool in COVID-19 diagnostics.

Isolation of herpes simplex virus nucleocapsid DNA

As an inanimate virus, herpes simplex virus type 1 (HSV-1) necessarily encodes all of its functions in its DNA. Isolation of pure viral DNA allows multiple downstream applications, including the creation of recombinant HSV strains, cloning of selected regions, and sequencing of viral DNA. The term nucleocapsid refers to the combination of the viral genome with the enclosing capsid; these viral genomes are necessarily linear and have been packaged for egress, even if they are not yet released from the cell. In contrast, viral DNA that is not associated with capsids may include episomal or concatenated forms and may have modifications such as histones that are added within cells. During this protocol, the viral capsid protects the HSV genome from reagents that strip away and destroy most cellular contaminants. This procedure describes the isolation of viral nucleocapsids and their subsequent dissolution to purify clean, linear HSV DNA.

Detection of antibodies against SARS-Coronavirus using recombinant truncated nucleocapsid proteins by ELISA

Severe acute respiratory syndrome (SARS) is a lifethreatening emerging respiratory disease caused by the coronavirus, SARS-CoV. The nucleocapsid (N) protein of SARS-CoV is highly antigenic and may be a suitable candidate for diagnostic applications. We constructed truncated recombinant N proteins (N1 [1-422 aa], N2 [1- 109 aa], and N3 [110-422 aa]) and determined their antigenicity by Western blotting using convalescent SARS serum. The recombinants containing N1 and N3 reacted with convalescent SARS serum in Western blotting. However, the recombinant with N2 did not. In ELISA using N1 or N3 as the antigens, positive results were observed in 10 of 10 (100%) SARS-CoV-positive human sera. None of 50 healthy sera gave positive results in either assay. These data indicate that the ELISA using N1 or N3 has high sensitivity and specificity. These results suggest that the middle or C-terminal region of the SARS N protein is important for eliciting antibodies against SARS-CoV during the immune response, and ELISA reactions using N1 or N3 may be a valuable tool for SARS diagnosis.

Expression, purification and characterization of full-length RNA-free hepatitis B core particles

The nucleocapsid or core particle of the hepatitis B virus has become one of the favourite recombinant vaccine carriers for foreign peptides, proteins and stimulatory oligonucleotides. The core protein consists of three regions: an N-terminal, a central and a C-terminal region that can accommodate the addition or insertion of the foreign sequences. The protamine-like C-terminal region that binds host RNA randomly during recombinant particle formation is often truncated. It is commonly thought that these truncations do not affect particle assembly. Recent studies have demonstrated that the C-terminal domains mediate a glycosaminoglycan-dependent attachment of nucleocapsids to the plasma membranes of host cells. This interaction might well contribute to the immunogenicity of nucleocapsids. Testing the hypothesis that full-length particles might be safer and superior for the induction of an immune response against the nucleocapsids and inserted sequences, requires the availability of purified particles. In this report, we detail a novel method for the synthesis and purification of full-length core particles essentially free of RNA from Escherichia coli.

[First detection of human metapneumovirus in a child with respiratory syndrome in Hungary]

INTRODUCTION

Human metapneumovirus was identified in 2001 as a respiratory-tract pathogen that has been classified as a new genera in family Paramyxoviridae.

AIMS

Molecular detection of human metapneumovirus in Hungary.

MATERIALS AND METHODS

Human metapneumovirus was identified in nasopharyngeal aspirate amplification of the viral fusion and nucleocapsid genes by reverse transcription-polymerase chain reaction followed by sequencing and phylogenetic analysis.

RESULTS

A 4 years-old girl with chronic respiratory syndrome chronically treated with anti-asthma drugs was admitted to hospital in November 2005 with acute respiratory syndrome and atelectasis. Nasopharyngeal aspirate was negative for common bacteria by culture and for influenza and coronavirus by reverse transcription-polymerase chain reaction. By contrast, specimen was positive by reverse transcription-polymerase chain reaction and was confirmed by sequencing both genes (nucleocapsid and fusion) of human metapneumovirus. Human metapneumovirus (HUN 05-L20) clustered into the subgroup B1 has the closest nucleotide similarity (98%) to JPS03-194 (AY530094) detected in Japan.

CONCLUSIONS

Human metapneumovirus contributes as an etiological agent of acute lower and upper respiratory tract infection especially in winter season in children with bronchiolitis, pneumonia or episodes of asthma exacerbation in Hungary, too.

Structural difference recognized by a monoclonal antibody #404-11 between the rabies virus nucleocapsid (NC) produced in virus infected cells and the NC-like structures produced in the nucleoprotein (N) cDNA-transfected cells

We investigated structural changes in the rabies virus (HEP-Flury strain) nucleocapsid (NC) during the virus replication, for which we used two anti-nucleoprotein (N) monoclonal antibodies (mAbs), #404-11 (specific for a conformation-dependently exposed linear epitope) and #1-7-11 (specific for a conformational epitope which is exposed after the nucleocapsid formation). Both mAbs recognized the N protein of the viral NC, but not of the RNA-free N-P complex. The 1-7-11 and 404-11 epitopes could be mapped to the N-terminal and the C-terminal regions of N protein, respectively. Immunoprecipitation studies demonstrated that treatment of the NC either with the alkaline phosphatase or sodium deoxycholate (DOC) resulted in dissociation of most P proteins from the NC and in the reduced reactivity to mAb #404-11, but not to mAb #1-7-11. NC-like structures produced in the N cDNA-transfected cells displayed strong reactivity to mAb #1-7-11; however, reactivity to mAb #404-11 was very weak. And, coexpression with viral phosphoprotein (P) resulted in little increase in reactivity to mAb #404-11 of the NC-like structures, while the reactivity was significantly increased by cotransfection with P and the viral minigenome whose 3'- and 5'-end structures were derived from the viral genome. From these results, we assume that, although the 404-11 epitope is a linear one, the epitope-containing region is exposed only when N proteins encapsidate properly the viral RNA in collaboration with the P protein. Further, exposure of the 404-11 epitope region might be function-related, and be regulated by association and dissociation of the P protein.

Stability of intracellular influenza virus nucleocapsid protein oligomers

Stability of A/Duck/Ukrainae/63 (H3N8) influenza virus intracellular NP oligomers was studied using reducing agents, denaturants, detergents, salts, various pH and a range of temperatures. The results obtained indicate that influenza virus NP oligomers are noncovalently stabilized, and NP subunits are not linked by disulfide bonds. NP oligomers are thermostable and SDS resistant. Urea and high ionic strength also do not dissociate avian influenza virus intracellular NP oligomers. However, NP oligomers are completely dissociated at pH < 5. The data obtained suggest that hydrophobic bonds together with the electrostatic interactions take part in the stabilization of compact conformation of influenza virus NP oligomers. It was also shown that intrachain disulfides revealed in nascent NPs are reduced in NP subunits of NP oligomers, and this probably contributes to the stability and compactness of the oligomers.

Selection and characterization of peptides specifically binding to HIV-1 psi (ψ) RNA

The packaging of HIV genomic RNA is mediated by a specific interaction between a nucleocapsid (NC) protein and packaging signal (psi, psi) RNA sequence. However, this interaction can be inhibited by the presence of peptides or proteins that specifically bind to the psi sequence. The 125-base-long psi RNA comprises a specific secondary structure that can be recognized by certain peptide sequences. Accordingly, the current study presents a method for selecting such peptides from a phage-displayed peptide library and characterization of resulting peptides in vitro. The RNA was covalently immobilized in a Covalink module using a carbodiimide condensation reaction at its 5'-end, leaving the proper secondary structure exposed and readily accessible. A phage display random peptide library was then screened against the RNA structure, and after five rounds of biopanning, enriched peptide sequences and conserved amino acid frames appeared. One of the enriched peptides was tested and shown to bind to psi RNA in a dose-dependent manner, plus it competed effectively with the NC protein as regards binding with the target RNA.

The phosphorylation of NS protein of wheat rosette stunt virus

The genome of wheat rosette stunt virus (WRSV), a plant rhabdovirus, is a single negative strand RNA. It encodes five viral structural proteins: the glycoprotein (G), the matrix protein (M), the nucleocapsid protein (N), the large protein (L) and the non?structural protein (NS), which was later proved to be a viral structural protein too and existed in a variety of phosphorylation forms in case of vascular stomatitis virus (VSV). In this paper we demonstrated that NS protein of WRSV, either bound with the viral nucleocapsid or expressed in bacteria could be in vitro phosphorylated in presence of viral nucleocapsid. We concluded that the NS protein of WRSV was a phosphorylated protein and it might exist in both phosphorylated and dephosphorylated forms in virions. Our results excluded the possibility that the NS protein could be autophosphorylated. The L protein, the major component of viral RNA dependent RNA polymerase is associated with the protein kinase for phosphorylation of NS protein.

Isolation and characterisation of the rabies virus N degrees-P complex produced in insect cells

When the nucleoprotein (N) of nonsegmented negative-strand RNA viruses is expressed in insect cells, it binds to cellular RNA and forms N-RNA complexes just like viral nucleocapsids. However, in virus-infected cells, N is prevented from binding to cellular RNA because a soluble complex is formed between N and the viral phosphoprotein (P), the N degrees -P complex. N is only released from this complex for binding to newly made viral or complementary RNA. We coexpressed rabies virus N and P proteins in insect cells and purified the N degrees -P complex. Characterisation by gel filtration, polyacrylamide gel electrophoresis, analytical ultracentrifugation, native mass spectroscopy, and electron microscopy showed that the complex consists of one N protein plus two P proteins, i.e., an N degrees -P(2) complex.

Identification of a novel protein associated with envelope of occlusion-derived virus in Spodoptera litura multicapsid nucleopolyhedrovirus

Spodoptera litura multicapsid nucleopolyhedrovirus (SpltMNPV) ORF137 (Splt137) is one of 29 unique SpltMNPV ORFs. Splt137 has the potential to code for a polypeptide of 231 amino acid residues with predicted molecular weight of 27.5 kDa. Computer-assisted analysis of the predicted amino acid sequences of Splt137 protein showed 1 N-glycosylation site and 11 phosphorylation sites. For identification of Spit137, antibody was prepared by immunization of rabbits with purified Splt137 protein produced in Escherichia coli. This antibody was used to analyse Splt137 protein using Western blot. A 36-kDa protein was found both in the infected cells and envelope fractions of occlusion-derived virus (ODV) but could not be detected in the budded virus (BV). Tunicamycin treatment of SpltMNPV infected cells suggested that the 36-kDa protein had undergone N-glycosylation. Our data suggested that Splt137 protein was a novel envelope protein of ODV and might exist as a more complex form of 79-kDa protein in intact ODV. Further, transcriptional analysis with RT-PCR and 5' RACE analysis suggested that Splt137 might perform functions early and late in infection.

Structure of isolated nucleocapsids from venezuelan equine encephalitis virus and implications for assembly and disassembly of enveloped virus

Venezuelan equine encephalitis virus (VEEV) is an important human and equine pathogen in the Americas, with widespread reoccurring epidemics extending from South America to the southern United States. Most troubling, VEEV has been made into a weapon by several countries and is currently restricted by the Centers for Disease Control and Prevention as a potential biological warfare and terrorism agent. To facilitate the development of antiviral compounds, the structure of the nucleocapsid isolated from VEEV has been determined by electron cryomicroscopy and image reconstruction and represents the first three-dimensional structure of a nucleocapsid isolated from a single-stranded enveloped RNA virus. The isolated VEEV nucleocapsid undergoes significant reorganization relative to its structure within VEEV. However, the isolated nucleocapsid clearly exhibits T=4 icosahedral symmetry, and its characteristic nucleocapsid hexons and pentons are preserved. The diameter of the isolated nucleocapsid is approximately 11.5% larger than that of the nucleocapsid within VEEV, with radial expansion being greatest near the hexons. Significantly, this is the first direct structural evidence showing that a simple enveloped virus undergoes large conformational changes during maturation, suggesting that the lipid bilayer and the transmembrane proteins of simple enveloped viruses provide the energy necessary to reorganize the nucleocapsid during maturation.

Identification of a high affinity nucleocapsid protein binding element within the Moloney murine leukemia virus Psi-RNA packaging signal: implications for genome recognition

Murine leukemia virus (MLV) is currently the most widely used gene delivery system in gene therapy trials. The simple retrovirus packages two copies of its RNA genome by a mechanism that involves interactions between the nucleocapsid (NC) domain of a virally-encoded Gag polyprotein and a segment of the RNA genome located just upstream of the Gag initiation codon, known as the Psi-site. Previous studies indicated that the MLV Psi-site contains three stem loops (SLB-SLD), and that stem loops SLC and SLD play prominent roles in packaging. We have developed a method for the preparation and purification of large quantities of recombinant Moloney MLV NC protein, and have studied its interactions with a series of oligoribonucleotides that contain one or more of the Psi-RNA stem loops. At RNA concentrations above approximately 0.3 mM, isolated stem loop SLB forms a duplex and stem loops SL-C and SL-D form kissing complexes, as expected from previous studies. However, neither the monomeric nor the dimeric forms of these isolated stem loops binds NC with significant affinity. Longer constructs containing two stem loops (SL-BC and SL-CD) also exhibit low affinities for NC. However, NC binds with high affinity and stoichiometrically to both the monomeric and dimeric forms of an RNA construct that contains all three stem loops (SL-BCD; K(d)=132(+/-55) nM). Titration of SL-BCD with NC also shifts monomer-dimer equilibrium toward the dimer. Mutagenesis experiments demonstrate that the conserved GACG tetraloops of stem loops C and D do not influence the monomer-dimer equilibrium of SL-BCD, that the tetraloop of stem loop B does not participate directly in NC binding, and that the tetraloops of stem loops C and D probably also do not bind to NC. These surprising results differ considerably from those observed for HIV-1, where NC binds to individual stem loops with high affinity via interactions with exposed residues of the tetraloops. The present results indicate that MLV NC binds to a pocket or surface that only exists in the presence of all three stem loops.

The amino and carboxyl domains of the infectious bronchitis virus nucleocapsid protein interact with 3' genomic RNA

Previous studies indicated that the nucleocapsid (N) protein of infectious bronchitis virus (IBV) interacted with specific sequences in the 3' non-coding region of IBV RNA. In order to identify domains in the N protein that bind to RNA, the whole protein (409 amino acids) and six overlapping fragments were expressed as fusion polypeptides with six histidine-tags. Using gel shift assays, the intact N protein and amino polypeptides, from residues 1 to 171 and residues 1 to 274, and carboxyl polypeptides, extending from residues 203 to 409 and residues 268 to 407, were found to interact with positive-stranded IBV RNA representing the 3' end of the genome. The two 32P-labeled probes that interacted with N and the amino and carboxyl fragments of N were RNA consisting of the IBV N gene and adjacent 3' non-coding terminus, and RNA consisting of the 155-nucleotide sequences at the 3' end of the 504-nt 3' untranslated region. In contrast, the polypeptide fragment from the middle region, residues 101-283, did not interact with these 3' IBV RNAs. The binding site in the amino region of N was either not present or only partially present in the first 91 residues because no interaction with RNA was observed with the polypeptide incorporating these residues. Cache Valley virus N expressed with a histidine tag, bovine serum albumin, and the basic lysozyme protein did not shift the IBV RNA. The lower molarities of the carboxyl fragment compared with residue 1-274 fragment needed for equivalent shifts suggested that the binding avidity for RNA at the carboxyl domain was greater than the amino domain.

Crystals of Rous sarcoma virus capsid protein show a helical arrangement of protein subunits

Crystals of Rous sarcoma virus (RSV) capsid protein diffract X rays to 3.5 A resolution and belong to the monoclinic space group C2 with unit cell parameters a = 374.4 A, b = 128.1 A, c = 200.2 A, and beta = 121.8 degrees. One asymmetric unit of the crystal may contain between 28 and 35 molecules, based on reasonable crystal density assumptions. A self-rotation function and Patterson synthesis suggest that RSV capsid protein crystallizes as a helical array. The determinants of the viral particle morphology are not encoded in the capsid alone. The assembly of a helical array in the crystal reflects the absence of any conformational switching. However, it is expected that the subunit interactions seen in the crystal will be preferred and will relate to those found in the immature or mature virion.

A simple and efficient method for purification of prawn baculovirus DNA

A new method for isolation of prawn baculovirus and subsequent extraction of viral DNA was developed. No density gradient centrifugation, ultracentrifugation or phenol-chloroform extraction steps were involved. Phenylmethylsulfonyl fluoride (PMSF) was used to prevent proteinase degradation, DNase and RNase were used to degrade prawn DNA and RNA respectively. The nucleocapsid was a bacilliform virion, about 58 62 nm in width and 300-350 nm in length as observed by transmission electron microscopy. Intact viral DNA was obtained by lysing nucleocapsids with guanidine hydrochloride and degrading protein with proteinase K. As the viral DNA was digested with restriction endonuclease and separated by electrophoresis, restriction fragments were clearly shown on the agarose gel. The size of the DNA was estimated approximately to be 290 kb. The virus which appeared to be a prawn baculovirus was named prawn white spot baculovirus (PWSBV) due to the white spots which appeared on the inside surface of the crust of infected prawns.

The carboxyl terminus of the human foamy virus Gag protein contains separable nucleic acid binding and nuclear transport domains

The Gag protein of human foamy virus (HFV) lacks Cys-His boxes present in the nucleocapsid (NC) domains of other retroviruses; instead it contains three glycine-arginine-rich motifs (GR boxes). We have expressed the carboxyl end of HFV Gag containing the GR boxes (the NC domain equivalent) and analyzed its nucleic acid binding properties. Our results show that the NC domain of HFV Gag binds with high affinity to both RNA and DNA, in a sequence-independent manner, as determined by filter binding assays. Analysis of a mutant containing a heterologous sequence in place of GR box I indicates that this motif is required for nucleic acid binding and for viral replication. A mutant in GR box II still binds to RNA and DNA in vitro, but virus containing this mutation does not replicate and no nuclear staining of the Gag protein is found in transfected cells. Surprisingly, a revertant from this mutant that completely lacks GR box II and exhibits very little nuclear transport of Gag can readily replicate in tissue culture. This finding thus provides a direct evidence that although the sequences in GR box II can serve as a nuclear transport signal, they are not required for HFV replication and it is unlikely that nuclear localization of Gag protein plays any critical role during viral infection. Taken together, our results suggest that the Gag protein of HFV may be more analogous to the core protein of the hepatitis B virus family than to conventional retroviral Gag protein.