Cloning and characterization of a ribosomal protein L24 from Hemaphysalis longicornis eggs

A fragment of ribosomal protein L24 was obtained from the complementary deoxyribonucleic acid (cDNA) library of Haemaphysalis longicornis eggs. The complete sequence of the clone was subsequently obtained using rapid amplification of the cDNA ends (RACE). Ribosomal protein L24 from H. longicornis had a high percentage similarity to this protein from different species. Conserved domains were also identified in RpL24. Real-time polymerase chain reaction (PCR) analysis showed that this gene is expressed in various tissues and different developmental stages of H. longicornis. Furthermore, HLL24 is mostly expressed in ovaries and salivary glands compared with other tissues in partially fed adult female ticks, and the expression level of HLL24 is significantly lower in eggs and larvas than in other developmental stages. RpL24 was also cloned from Haemaphysalis qinghaiensis and Hyalomma anatolicum anatolicum ticks, respectively. Comparison of their amino acid sequences revealed difference only in several amino acids. A vaccine based on the HLL24 recombinant protein could not protect rabbits against H. longicornis.     

Functional and antigenic domains of the dengue-2 virus nonstructural glycoprotein NS-1

The gene coding for the nonstructural glycoprotein of dengue-2 virus was cloned, sequenced, and expressed in Escherichia coli. There was about 70% conservation at the amino acid level with dengue serotypes 1 and 4 suggesting an important common function for this protein. Conserved hydrophobic domains were found both before the amino-terminus and at the carboxy-terminus, consistent with transmembrane roles. Evidence for at least partial translocation of NS-1 through the inner membrane of E. coli was found. Also conserved were two signals for N-linked glycosylation located near the middle of NS-1. Various regions of NS-1 were tested for antigenicity with mouse and rabbit polyclonal and mouse monoclonal antibodies. The mouse polyclonal antibodies, made against a crude dengue-infected mouse brain immunogen, reacted most strongly with N-terminal regions of NS-1, whereas, the rabbit antiserum, made against purified NS-1 protein, reacted strongest with C-terminal regions. These findings suggest that immunogen presentation or species differences could be important. Although most of the monoclonals appeared to be unreactive in Western blots with expressed NS-1 proteins, two appeared to react strongly; the region from amino acid (a.a.) 273 to a.a. 346 was required for antibody binding. This region, located adjacent to the two conserved C-terminal hydrophobic domains, is highly charged and contains 5 of the 10 conserved cysteine residues of NS-1.     

The role of conserved arginine and proline residues in enterovirus VP1 protein

BackgroundHigh diversity of VP1 protein among enteroviruses has been a barrier in developing universally effective antiviral drugs. To maintain structure stability during evolution, several residues of VP1 protein of enteroviruses are conserved. Therefore, investigation of highly conserved residues in VP1 protein may provide information for antiviral drug candidates against enteroviruses.MethodsTo identify highly conserved amino acid sequences of the VP1 in enterovirus genus, the Consurf and CABS-flex 2.0 web software were applied. Through the combination with secondary structure information, we focused on conserved amino acids of VP1 property analysis.ResultsMost conserved residues of VP1 were in the interior and interacted with VP2, VP3 and VP4 capsid proteins. Structure of EV-A71 (PDB code 4AED) showed conserved residues were at hydrophobic pocket and close to the junction between the loop and β-barrel. Interestingly, arginine was the most common conserved residue of VP1. Proline was the second most common conserved residue and was found in the loop and β-barrel intersection areas. VP1 protein flexibility was associated with the secondary structure. Conserved residues of VP1 in β-barrel showed significantly low flexibility.ConclusionThrough large scale sequence analysis, we identified the amino acid distribution and location of conserved residues in VP1. This knowledge can be extrapolated for the Enterovirus genus and may contribute to developing the potential compound as an anti-enteroviral agent.     

Primary structure of the large (L) RNA segment of nephropathia epidemica virus strain H?lln?s B1 coding for the viral RNA polymerase

The L RNA segment of the nephropathia epidemica virus (NEV) strain H?lln?s B1 was characterized by molecular cloning of the corresponding cDNA and subsequent determination of the DNA nucleotide sequence. The L RNA segment is 6550 nucleotides long with complementarity of 20 bases at the 3' and 5' termini. The viral messenger sense RNA contains one major open reading frame (ORF) with a coding capacity of 2156 amino acid residues encoding a protein with a calculated molecular weight of 246 kDa and an IEP of pH 7.4. Comparison of the deduced amino acid sequences from NEV hantavirus and Bunyamwera virus (BWV) L segment messenger sense RNAs, revealed a high degree of diversity (overall amino acid identity, 17%). However, three clusters of 30-40% amino acid identity were detected. One of these domains, containing an Asp-Asp motif found in many RNA polymerases, also shares amino acid sequence homology with the PB1 polymerase component of influenza type A. These results indicate that the L RNA segment of the NEV codes for the viral RNA-dependent RNA polymerase. The data presented here complete our previous studies on the characterization of the NEV genome by cDNA sequencing of the viral M and S RNA segments.     

The amino acid sequence of murine p53 determined from a c-DNA clone

A c-DNA clone containing the complete sequence information for the murine p53 protein, from embryonal carcinoma cells, has been isolated. The nucleotide sequence of this clone reveals an open reading frame encoding a protein of 390 amino acids with a molecular weight of 43,364 Da. The NH2-terminal domain of this protein is acidic whereas the carboxyl terminus is rich in basic amino acid residues. These terminal domains are separated by a proline-rich, hydrophobic run of amino acids. Proline comprises approximately 10% of the total amino acid residues. Two tryptic peptides, derived from p53 protein radiolabeled with either methionine or proline, were purified and the position of these labeled residues in the peptide was determined. The positions of three methionine and five proline residues in these two peptides matched the amino acid sequence of the predicted open reading frame determined from the c-DNA clone.     

Sequence analysis of the large polymerase (L) protein of the US strain of avian metapneumovirus indicates a close resemblance to that of the human metapneumovirus

The complete nucleotide sequence of the large polymerase (L) protein of the avian metapneumovirus subgroup C strain Colorado was determined. The L protein gene of avian pneumovirus Colorado isolate (APV-C) was 6173 nucleotides in length from the gene-start to the gene-end and encoded a polypeptide of 2005 amino acids in length. The length of the L protein of APV-C was exactly the same as that of human metapneumovirus (hMPV) and one amino acid longer than the L protein of APV subgroup A. The L protein of APV-C showed 80% amino acid identity with the L protein of hMPV, but only 64% amino acid identity with the L protein of APV-A. The nucleotide and deduced amino acid sequences were compared with the corresponding sequences of eleven other paramyxoviruses. All six domains characteristic of paramyxovirus L proteins were also observed in the L protein of APV-C. All the polymerase core motifs in domain III were conserved to nearly 100% in the metapneumoviruses. Similarly, the putative ATP-binding motif in domain VI was completely conserved among the metapneumoviruses and differed in length, by one intermediate residue, from other paramyxoviruses. Phylogenetic analysis of the different L proteins also revealed a closer relationship between APV-C and hMPV.     

The N-terminal 33 amino acid domain of Siva-1 is sufficient for nuclear localization

Siva-1 induces apoptosis in multiple pathological processes and plays an important role in the suppression of tumor metastasis, protein degradation, and other functions. Although many studies have demonstrated that Siva-1 functions in the cytoplasm, a few have found that Siva-1 can relocate to the nucleus. In this study, we found that the first 33 amino acid residues of Siva-1 are required for its nuclear localization. Further study demonstrated that the green fluorescent protein can be imported into the nucleus after fusion with these 33 amino acid residues. Other Siva-1 regions and domains showed less effect on Siva-1 nuclear localization. By site-mutagenesis of all of these 33 amino acid residues, we found that mutants of the first 1-18 amino acids affected Siva-1 nuclear compartmentalization but could not complete this localization independently. In summary, we demonstrated that the N-terminal 33 amino acid residues were sufficient for Siva-1 nuclear localization, but the mechanism of this translocation needs additional investigation.     

Use of site-specific mutagenesis and monoclonal antibodies to map regions of CD46 that interact with measles virus H protein.

Researchers at our laboratory have been dissecting the binding domains of the receptor for the Edmonston laboratory strain of measles virus (CD46) through site-specific mutagenesis. We initially substituted most of the hydrophilic amino acids in the two external short consensus regions (SCRI and SCRII) of CD46 with the amino acid alanine [Hsu et al. (1997) J. Virol. 71:6144-6154] and found that the glutamic-arginine residues at positions 58 and 59 were particularly sensitive to change. Here we consider the roles of hydrophobic amino acids in the binding between measles virus H protein and CD46. Hydrophobic amino acids in the SCRI and SCRII domains of CD46 were systematically replaced with serine. The effects of these changes were monitored through the interaction of Sf9 insect cells expressing the H protein and mouse OST-7 cells synthesizing the mutant CD46 molecules. Binding was quantified through a colorimetric assay for beta-galactosidase that was also produced by the insect cells. Our results indicate that E45, Y54, 58E/R59, Y68, F69, Y101, I102, R103, D104, and Y117 seem to be critical residues for the binding of CD46 to measles virus H protein. The hydrophilic amino acid R59 in SCR1 and hydrophobic residues Y101, I102, and Y117 in SCR2 seem to be especially important for interaction between H protein and CD46. In addition, we mapped the antigenic epitopes of five monoclonal antibodies that are known to inhibit the binding between H protein and CD46. Three of these antibodies recognized regions in SCR1, and two reacted with amino acids in SCR2. For the most part, the determinants recognized by the monoclonal antibody corresponded to the amino acids that were most sensitive to change in the binding process. The SCR1 and SCR2 domains of CD46 were modeled from an analogous region in another complement regulatory protein, factor H, whose three-dimensional structure has been previously reported. Amino acids implicated in binding seem to lie on one planar face of the SCR1 and SCR2 domains. These studies serve as a prelude to understanding the structural interactions that occur between CD46 and the measles virus H protein.     

Antigenic Structure of the Nucleocapsid Protein of Porcine Reproductive and Respiratory Syndrome Virus

A collection of 12 monoclonal antibodies (MAbs) raised against porcine reproductive and respiratory syndrome (PRRS) virus was used to study the antigenic structure of the virus nucleocapsid protein (N). The full-length N gene, encoded by open reading frame 7, was cloned from the Canadian PRRS virus, PA-8. Deletions were introduced into the N gene to produce a series of nine overlapping protein fragments ranging in length from 25 to 112 amino acids. The individual truncated genes were cloned as glutathione S-transferase fusions into a eukaryotic expression vector downstream of the T7 RNA polymerase promoter. HeLa cells infected with recombinant vaccinia virus expressing T7 RNA polymerase were transfected with plasmid DNA encoding the N protein fragments, and the antigenicity of the synthesized proteins was analyzed by immunoprecipitation. Based on the immunoreactivities of the N protein deletion mutants with the panel of N-specific MAbs, five domains of antigenic importance were identified. MAbs SDOW17, SR30, and 5H2.3B12.1C9 each identified independent domains defined by amino acids 30 to 52, 69 to 123, and 37 to 52, respectively. Seven of the MAbs tested specifically recognized the local protein conformation formed in part by the amino acid residues 52 to 69. Furthermore, deletion of 11 amino acids from the carboxy terminus of the nucleocapsid protein disrupted the epitope configuration recognized by all of the conformation-dependent MAbs, suggesting that the carboxy-terminal region plays an important role in maintaining local protein conformation.     

Comparison of the primary structure of the 25 kDa ookinete surface antigens of Plasmodium falciparum and Plasmodium gallinaceum reveal six conserved regions

The gene encoding the 25 kDa ookinete surface antigen (Pgs25) of Plasmodium gallinaceum has been cloned using an oligonucleotide probe directed against one of the EGF-like domains of the P. falciparum 25 kDa ookinete surface antigen (Pfs25). The Pgs25 gene codes for a polypeptide of 215 amino acids, two amino residues less than Pfs25. The deduced amino acid sequence contains a putative signal sequence at the amino-terminus, four tandemly repeated EGF-like domains, and a hydrophobic region at the carboxyl-terminus. By comparing Pgs25 with Pfs25, six conserved regions, consisting of six or more amino acid residues, have been identified. Most of the conserved regions are outside EGF-like core consensus sequences. The most striking conservation is the spacing of the cysteines.     

Roles of the hinge region and the DNA binding domain of the bovine papillomavirus type 1 E2 protein in initiation of DNA replication

The bovine papillomavirus (BPV-1) E2 protein is the regulator of extrachromosomal replication of papillomaviruses. The mutants with C-terminal truncations and in-frame internal deletions were constructed to study the role of structural domains of E2 in the initiation of DNA replication. We show that the replication initiation function of E2 is absolutely dependent on the ability of the protein to bind to DNA. Our study also confirms the borders of the functional domains of the E2 protein; residues 1-192 form the activation domain and residues 310-410 the DNA binding-dimerization domain. Some critical length and flexibility, but not the particular amino acid sequence between these two functional domains is required for the activity of the protein to support replication. The hinge region, including the major phosphorylation sites of E2, is also dispensable for the mediation of attachment of the BPV1 genome to the mitotic chromosomes.     

Conserved aromatic residues as determinants in the folding and assembly of immunoglobulin variable domains

Detailed analysis of amino acid distribution, focusing on the “framework” regions of both heavy- and light-chain variable immunoglobulin (Ig) domains, distinguished those conserved sequence elements shared by both heavy-chain (VH) and light-chain (VL) domains from those conserved determinants unique to either VH or VL domains alone. Mapping of conserved chemical functionality onto characterized PDB structures showed the analogous placement and utilization of shared determinants in VH and VL structures that are generally similar. Identical Arginine–Aspartic acid ion-pairs located symmetrically on the lateral surfaces of VH and VL domains, respectively, as well as paired glutamine residues that constitute a central contact site between VH and VL domains represent clearly shared molecular features. Three sites of shared aromaticity were found localized to symmetrical sites lining the inaccessible interface of the VH–VL duplex, suggesting an expanded role for strategically conserved aromatic residues from a postulated determinant of individual Ig domain folding to now implicate conserved aromatic sites in the subsequent multi-subunit assembly of native antibody superstructure. Differential domain-specific conservation, representing evolutionary diversification and molecular asymmetry between heavy- and light-chain variable domains was limited, but included amino acids from each functional class and must be evaluated with regard to their possible involvement in heterologous aspects of IgV protein structure–function.     

Molecular cloning and nucleotide sequence of a pestivirus genome, noncytopathic bovine viral diarrhea virus strain SD-1.

Genomic RNA of noncytopathic (NCP) bovine viral diarrhea virus (BVDV) strain SD-1 was extracted directly from serum obtained from a persistently infected animal. cDNA was synthesized and amplified by polymerase chain reaction (PCR) before cloning. The complete genomic nucleotide sequence was determined by sequencing at least two different clones from independent PCR reactions. The 5' and 3' end sequences of the SD-1 genome was determined from 5'-3' ligation clones. The complete genome sequence was comprised of 12,308 nucleotides containing one large open reading frame which encodes an amino acid sequence of 3898 residues with a calculated molecular weight of 438 kDa. In contrast to cytopathic (CP) BVDV strain NADL, which contains a cellular RNA insert of 270 nucleotides and CP BVDV strain Osloss, which has an inserted ubiquitin RNA sequence of 228 nucleotides, the NCP strain SD-1 had no insertion along the genome. Sequence comparison with other pestiviruses revealed that the overall nucleotide sequence homologies of SD-1 are 88.6% with NADL, 78.3% with Osloss, 67.1% with HoCV Alfort, and 67.2% with HoCV Brescia. The overall deduced amino acid sequence homologies of SD-1 are 92.7% with NADL, 86.2% with Osloss, 72.5% with HoCV Alfort, and 71.2% with HoCV Brescia. The most conserved nucleotide and amino acid sequences are located in the 5' untranslated region (5'UTR) and nonstructural protein p80 region, respectively. The viral glycoproteins, particularly gp53, and nonstructural proteins p54 and p58 have the lowest homology comparing both nucleotide and amino acid sequences between SD-1 and other pestiviruses. Extensive analyses of amino acid sequences for the viral structural proteins and nonstructural protein p54 regions from five pestiviruses led to the identification of four conserved domains (designated as C1, C2, C3, C4) and three highly variable domains (designated as V1, V2, V3) within this region. The C1, C2, and C3 domains are located in the capsid protein p14, glycoprotein gp48, and gp25, respectively. The C4 domain is located in the junction between gp53 and p54. Interestingly, out of three variable domains, two (V1, V2) are located in the same glycoprotein gp53. The third variable domain is located in the nonstructural protein p54.     

Nucleotide sequence of the avian influenza virus A/fowl plague/Rostock/34 segment 1 encoding the PB2 polypeptide

The nucleotide sequence of segment 1 of fowl plague virus (A/FPV/Rostock/34) was determined from a DNA copy inserted at the Pst I site of pBR322. Segment 1 is 2341 nucleotides long and encodes a highly basic protein of 759 amino acid residues (PB2). This protein forms part of the viral polymerase complex and is involved in the recognition of cap structures and endonucleolytic cleavage of eukaryotic mRNAs. Comparisons made between segment 1 of fowl plague virus and three human strains of influenza virus show approximately 85% nucleotide sequence homology and 94% homology between amino acid sequences.     

Identification of a new region in the vesicular stomatitis virus L polymerase protein which is essential for mRNA cap methylation

The vesicular stomatitis virus (VSV) L polymerase protein possesses two methyltransferase (MTase) activities, which catalyze the methylation of viral mRNA cap structures at the guanine-N7 and 2'-O-adenosine positions. To identify L sequences required for the MTase activities, we analyzed a host range (hr) and temperature-sensitive (ts) mutant of VSV, hr8, which was defective in mRNA cap methylation. Sequencing hr8 identified five amino acid substitutions, all residing in the L protein. Recombinant VSV were generated with each of the identified L mutations, and the presence of a single G1481R substitution in L, located between conserved domains V and VI, was sufficient to produce a dramatic reduction (about 90%) in overall mRNA methylation. Cap analysis showed residual guanine-N7 methylation and reduced 2'-O-adenosine methylation, identical to that of the original hr8 virus. When recombinant viruses were tested for virus growth under conditions that were permissive and nonpermissive for the hr8 mutant, the same single L mutation, G1481R, was solely responsible for both the hr and ts phenotypes. A spontaneous suppressor mutant of the rG1481R virus that restored both growth on nonpermissive cells and cap methylation was identified and mapped to a single change, L1450I, in L. Site-directed mutagenesis of the region between domains V and VI, amino acids 1419-1672 of L, followed by the rescue of recombinant viruses identified five additional virus mutants, K1468A, R1478A/D1479A, G1481A, G1481N, and G1672A, that were all hr and defective in mRNA cap methylation. Thus, in addition to the previously characterized domain VI [Grdzelishvili, V.Z., Smallwood, S., Tower, D., Hall, R.L., Hunt, D.M., Moyer, S.A., 2005. A single amino acid change in the L-polymerase protein of vesicular stomatitis virus completely abolishes viral mRNA cap methylation. J. Virol. 79, 7327-7337; Li, J., Fontaine-Rodriguez, E.C., Whelan, S.P., 2005. Amino acid residues within conserved domain VI of the vesicular stomatitis virus large polymerase protein essential for mRNA cap methyltransferase activity. J. Virol. 79, 13373-13384], a new region between L amino acids 1450-1481 was identified which is critical for mRNA cap methylation.