Nucleotide sequence of a Sendai virus genome region covering the entire M gene and the 3'' proximal 1013 nucleotides of the F gene.

We determined the sequence of the 2,138 nucleotides in the Sendai virus genome just following the 3' proximal 3,686 nucleotides which we had previously reported (Nucleic Acids Res. 11, 7317-7330, 1983). This covers the entire third gene of 1,173 nucleotides and the 3' proximal 1,013 nucleotides of the fourth gene. Like the NP and P+C genes, both the third and fourth genes start from consensus sequence R1 (3'-UCCCAC(or UA)UUUC) at the 3' end and the third gene terminates with consensus sequence R2 (3'-AUUCUUUUU) at the 5' end. The third gene was identified as M, and the deduced 348 amino acids indicated that the M protein is rich in basic residues and has hydrophobic domains near the C-terminal. The fourth gene, although sequencing is not complete yet, was identified as F, since a large open reading frame found in the gene contains the characteristic sequence of 20 amino acids located at the N-terminal of the F1 protein. Analyses of the amino acid sequence suggested that the structure of the F gene product is NH2-signal peptide-F2-F1-COOH.     

Sequence of 3,687 nucleotides from the 3' end of Sendai virus genome RNA and the predicted amino acid sequences of viral NP, P and C proteins.

The sequence of 3,687 nucleotides from the 3' end of the Sendai virus genome (Z strain) was determined by a molecular cloning technique followed by rapid sequence analysis. Two large open reading frames, one consisting of 1,572 nucleotides and the other of 1,704 nucleotides, were observed in the region, that is OP-1 and OP-2 from the 3' end of the genome. The amino acid sequences of the gene products were predicted from the observed sequence. Determination of amino acid compositions of viral proteins, P, HN, Fo, NP and M, led us to conclude that NP and P are the gene products of OP-1 and OP-2, respectively. An additional open reading frame consisting of 612 nucleotides (OP-3) was discovered in the 3' most proximal region of OP-2. The predicted product of OP-3 was considered to be viral non-structural protein C. The leader sequence of 51 nucleotides at the 3' terminal of the genome and consensus sequences at 3' and 5' ends of each gene for proteins NP and P were identified.     

Nucleotide sequence of the bovine parainfluenza 3 virus genome: the genes of the F and HN glycoproteins.

By analysing complementary DNA clones constructed from genomic RNA of bovine parainfluenza 3 virus (BPIV3), we determined the nucleotide sequence of the region containing the entire F and HN genes. Their deduced amino acid sequences showed about 80% homologies with those of human parainfluenza 3 virus (HPIV3), about 45% with those of Sendai virus, and about 20% with those of SV5 and Newcastle disease virus (NDV), indicating, together with the results described in the preceding paper on the NP, P, C and M proteins of BPIV3, that BPIV3, HPIV3 and Sendai virus constitute a paramyxovirus subgroup, and that BPIV3 and HPIV3 are very closely related. The F and HN proteins of all these viruses, including SV5 and NDV, however, were shown to have protein-specific structures as well as short but well-conserved amino acid sequences, suggesting that these structures and sequences are related to the activities of these glycoproteins.     

Functional analysis of the internal translation initiation site of foot-and-mouth disease virus.

Mutagenesis of the large untranslated sequence at the 5' end of the genome of foot-and-mouth disease virus revealed that a region of approximately 450 nucleotides preceding the open reading frame of the viral polyprotein is involved in the regulation of translation initiation at two internal start sites. Variations in two domains of this region reduced the translation efficiency up to 10-fold, whereas an intermediate segment seemed to be less essential. A pyrimidine-rich sequence preceding the start codon was most sensitive in that conversion of single pyrimidine residues to purines decreased the translation efficiency strongly. The data are in agreement with a recently proposed general structural model for the internal ribosome entry site of the cardiovirusaphthovirus subgroup of picornaviruses (E. V. Pilipenko, V. M. Blinov, B. K. Chernov, T. M. Dmitrieva, and V. I. Agol, Nucleic Acids Res. 17:5701-5711, 1989). They suggest, however, that this model represents only a core structure for the internal entry of ribosomes and that foot-and-mouth disease virus and other members of the picornaviruses need additional regulatory RNA elements for efficient translation initiation.     

Matrix genes of measles virus and canine distemper virus: cloning, nucleotide sequences, and deduced amino acid sequences.

The nucleotide sequences encoding the matrix (M) proteins of measles virus (MV) and canine distemper virus (CDV) were determined from cDNA clones containing these genes in their entirety. In both cases, single open reading frames specifying basic proteins of 335 amino acid residues were predicted from the nucleotide sequences. Both viral messages were composed of approximately 1,450 nucleotides and contained 400 nucleotides of presumptive noncoding sequences at their respective 3' ends. MV and CDV M-protein-coding regions were 67% homologous at the nucleotide level and 76% homologous at the amino acid level. Only chance homology was observed in the 400-nucleotide trailer sequences. Comparisons of the M protein sequences of MV and CDV with the sequence reported for Sendai virus (B. M. Blumberg, K. Rose, M. G. Simona, L. Roux, C. Giorgi, and D. Kolakofsky, J. Virol. 52:656-663; Y. Hidaka, T. Kanda, K. Iwasaki, A. Nomoto, T. Shioda, and H. Shibuta, Nucleic Acids Res. 12:7965-7973) indicated the greatest homology among these M proteins in the carboxyterminal third of the molecule. Secondary-structure analyses of this shared region indicated a structurally conserved, hydrophobic sequence which possibly interacted with the lipid bilayer.     

Nucleotide sequence of the 5'' noncoding region and part of the gag gene of mouse mammary tumor virus; identification of the 5'' splicing site for subgenomic mRNAs

We have determined the sequence of the first 1371 nucleotides at the 5' end of the genome of mouse mammary tumor virus using molecularly cloned proviral DNA of the GR virus strain. The most likely initiation codon used for the gag gene of mouse mammary tumor virus is the first one, located 312 nucleotides from the 5' end of the viral RNA. The 5' splicing site for the subgenomic mRNA's is located approximately 288 nucleotides downstream from the 5' end of the viral RNA. From the DNA sequence the amino acid sequence of the N-terminal half of the gag precursor protein, including p10 and p21, was deduced (353 amino acids).     

Five pseudoknots are present at the 204 nucleotides long 3'' noncoding region of tobacco mosaic virus RNA.

The 104 nucleotides long 3' terminal region of TMV RNA was shown previously to contain two pseudoknotted structures (Rietveld et al. (1984), EMBO J. 3, 2613-2619). We here present evidence for the occurrence, within the 204 nucleotides long 3' noncoding region, of another highly structured domain located immediately adjacent to the tRNA-like structure of 95 nucleotides (Joshi et al. (1985) Nucleic Acids Res. 13, 347-354). A model for the three-dimensional folding of this region, containing three more pseudoknots, is proposed on the basis of chemical modification and enzymatic digestion. The existence of these three consecutive pseudoknots was supported by sequence comparisons with the RNA from the related tobamoviruses TMV-L, CcTMV and CGMMV. Coaxial stacking of the six double helical segments involved gives rise to the formation of a 25 basepair long quasi-continuous double helix. The results show that the three-dimensional folding of the 3' non-translated region of tobamoviral RNAs is largely maintained by the formation of five pseudoknots. The organisation of this region in the RNA of the tobamovirus CcTMV suggests that recombinational events among aminoacylatable plant viral RNAs have to be considered.     

Nucleotide sequence of the herpes simplex virus type 2 thymidine kinase gene.

We have determined the complete nucleotide sequence of the thymidine kinase gene of herpes simplex virus (HSV) type 2 strain 333. The sequence of the thymidine kinase gene exhibits an open translational reading frame of 1,128 nucleotides encoding a protein of 376 amino acids. The DNA sequence was compared with that of the HSV type 1 thymidine kinase gene from strain MP (S. L. McKnight, Nucleic Acids Res. 8:5949-5964, 1980) and from strain CL 101 (M. J. Wagner, J. A. Sharp, and W. C. Summers, Proc. Natl. Acad. Sci. U.S.A. 78:1441-1445, 1981) to assess the extent of intra- and intertypic variation for one viral gene. The nucleotides encoding the structural gene varied 1.7% between the two HSV type 1 strains and 19% between HSV type 1 and HSV type 2, which translated to differences in the amino acid sequence of the two proteins of 1.9 and 27%, respectively. The DNA encoding the 5' regulatory sequences appeared to be more conserved than the DNA coding for the structural gene, and the DNA at the 3' end of the gene was the least homologous.     

Sendai virus M protein binds independently to either the F or the HN glycoprotein in vivo.

We have analyzed the mechanism by which M protein interacts with components of the viral envelope during Sendai virus assembly. Using recombinant vaccinia viruses to selectively express combinations of Sendai virus F, HN, and M proteins, we have successfully reconstituted M protein-glycoprotein interaction in vivo and determined the molecular interactions which are necessary and sufficient to promote M protein-membrane binding. Our results showed that M protein accumulates on cellular membranes via a direct interaction with both F and HN proteins. Specifically, our data demonstrated that a small fraction (8 to 16%) of M protein becomes membrane associated in the absence of Sendai virus glycoproteins, while > 75% becomes membrane bound in the presence of both F and HN proteins. Selective expression of M protein together with either F or HN protein showed that each viral glycoprotein is individually sufficient to promote efficient (56 to 73%) M protein-membrane binding. Finally, we observed that M protein associates with cellular membranes in a time-dependent manner, implying a need for either maturation or transport before binding to glycoproteins.     

Kissing of the two predominant hairpin loops in the coxsackie B virus 3' untranslated region is the essential structural feature of the origin of replication required for negative-strand RNA synthesis.

Higher-order RNA structures in the 3' untranslated region (3'UTR) of enteroviruses are thought to play a pivotal role in viral negative-strand RNA synthesis. The structure of the 3'UTR was predicted by thermodynamic calculations using the STAR (structural analysis of RNA) computer program and experimentally verified using chemical and enzymatic probing of in vitro-synthesized RNA. A possible pseudoknot interaction between the 3D polymerase coding sequence and domain Y and a "kissing" interaction between domains X and Y was further studied by mutational analysis, using an infectious coxsackie B3 virus cDNA clone (domain designation as proposed by E. V. Pilipenko, S. V. Maslova, A. N. Sinyakov, and V.I. Agol (Nucleic Acids Res. 20:1739-1745, 1992). The higher-order RNA structure of the 3'UTR appeared to be maintained by an intramolecular kissing interaction between the loops of the two predominant hairpin structures (X and Y) within the 3'UTR. Disturbing this interaction had no effect on viral translation and processing of the polyprotein but exerted a primary effect on viral replication, as was demonstrated in a subgenomic coxsackie B3 viral replicon, in which the capsid P1 region was replaced by the luciferase gene. Mutational analysis did not support the existence of the pseudoknot interaction between hairpin loop Y and the 3D polymerase coding sequence. Based on these experiments, we constructed a three-dimensional model of the 3'UTR of coxsackie B virus that shows the kissing interaction as the essential structural feature of the origin of replication required for its functional competence.     

Sequence determination of the Sendai virus HN gene and its comparison to the influenza virus glycoproteins

The nucleotide sequence of the Sendai virus (SV) HN (hemagglutinin-neuraminidase) gene was determined. The deduced primary structure of the protein showed only one hydrophobic domain likely to represent the transmembrane region, but at its N terminus. Since the SV F protein is anchored in the membrane at its C terminus, the two SV glycoproteins are thus membrane-anchored in opposite orientations, similar to the two influenza virus (FLU) glycoproteins. Amino acid sequence comparisons of the SV HN and the FLU HA and NA proteins revealed homologies between 100 amino acids of the hemagglutinin region of the FLU HA protein and the C terminus of the SV HN, and between 200 amino acids of the neuraminidase region of the FLU NA and the central region of SV HN. Alignment of the neuraminidase, hemagglutinin, and fusion regions shared by these glycoproteins suggest the structure of a possible ancestral gene.     

Critical Role of the Fusion Protein Cytoplasmic Tail Sequence in Parainfluenza Virus Assembly

Interactions between viral glycoproteins, matrix protein and nucleocapsid sustain assembly of parainfluenza viruses at the plasma membrane. Although the protein interactions required for virion formation are considered to be highly specific, virions lacking envelope glycoprotein(s) can be produced, thus the molecular interactions driving viral assembly and production are still unclear. Sendai virus (SeV) and human parainfluenza virus type 1 (hPIV1) are highly similar in structure, however, the cytoplasmic tail sequences of the envelope glycoproteins (HN and F) are relatively less conserved. To unveil the specific role of the envelope glycoproteins in viral assembly, we created chimeric SeVs whose HN (rSeVhHN) or HN and F (rSeVh(HN+F)) were replaced with those of hPIV1. rSeVhHN grew as efficiently as wt SeV or hPIV1, suggesting that the sequence difference in HN does not have a significant impact on SeV replication and virion production. In sharp contrast, the growth of rSeVh(HN+F) was significantly impaired compared to rSeVhHN. rSeVh(HN+Fstail) which expresses a chimeric hPIV1 F with the SeV cytoplasmic tail sequence grew similar to wt SeV or rSeVhHN. Further analysis indicated that the F cytoplasmic tail plays a critical role in cell surface expression/accumulation of HN and F, as well as NP and M association at the plasma membrane. Trafficking of nucelocapsids in infected cells was not significantly affected by the origin of F, suggesting that F cytoplasmic tail is not involved in intracellular movement. These results demonstrate the role of the F cytoplasmic tail in accumulation of structural components at the plasma membrane assembly sites.     

Translation of human hepatitis C virus RNA in cultured cells is mediated by an internal ribosome-binding mechanism.

The human hepatitis C virus (HCV) contains a long 5' noncoding region (5' NCR). Computer-assisted and biochemical analyses suggest that there is a complex secondary structure in this region that is comparable to the secondary structures that are found in picornaviruses (E.A. Brown, H. Zhang, L.-H. Ping, and S.M. Lemon, Nucleic Acids Res. 20:5041-5045, 1992). Previous in vitro studies suggest that the HCV 5' NCR plays an important role during translation (K. Tsukiyama-Kohara, N. Iizuka, M. Kohara, and A. Nomoto, J. Virol. 66:1476-1483, 1992). Dicistronic and monocistronic expression vectors, in vitro translation, RNA transfections, and deletion mutagenesis studies were utilized to demonstrate unambiguously that the HCV 5' NCR is involved in translational control. Our data strongly support the conclusion that an internal ribosome entry site exists within the 5' noncoding sequences proximal to the initiator AUG. Furthermore, our results suggest that the HCV genome is translated in a cap-independent manner and that the sequences immediately upstream of the initiator AUG are essential for internal ribosome entry site function during translation.     

Effect of mutations and deletions in a bicistronic mRNA on the synthesis of influenza B virus NB and NA glycoproteins.

The mRNA derived from influenza B virus RNA segment 6 is functionally bicistronic and encodes the NB and NA glycoproteins in different, overlapping reading frames. NB protein synthesis is initiated at the 5'-proximal AUG codon, and 4 nucleotides downstream there is a second AUG codon which is used to initiate NA protein synthesis. The nucleotide sequence context of the first AUG codon conforms closely with the established 5'-CC(A/G)CCAUGG-3' consensus sequence (M. Kozak, Nucleic Acids Res. 15:8125-8148, 1987), which should favor initiation of NB protein synthesis at this site, yet NB and NA are found to accumulate in approximately equal amounts in infected cells. To determine the features important for allowing initiation at the second 5'-proximal AUG codon, we made changes in the 5'-terminal region of the mRNA, including deletions, insertions, and site-specific mutations. The recombinant DNA molecules were expressed in eucaryotic cells, and the accumulation of NB and NA was quantitated. The data indicate that changes in the immediate sequence around the first AUG codon do not make a large difference in the amounts of NB and NA that accumulate, but that when the first AUG codon is displaced from its normal position it is now quite efficient at preventing downstream initiation events. In addition, the data indicate that an element of the B/NB/NA mRNA 5' untranslated leader region acts in cis to enhance the expression of NB and NA.     

The rule of six, a basic feature for efficient replication of Sendai virus defective interfering RNA.

The addition of the hepatitis delta virus genomic ribozyme to the 3' end sequence of a Sendai virus defective interfering RNA (DI-H4) allowed the reproducible and efficient replication of this RNA by the viral functions expressed from cloned genes when the DI RNA was synthesized from plasmid. Limited nucleotide additions or deletions (+7 to -7 nucleotides) in the DI RNA sequence were then made at five different sites, and the different RNA derivatives were tested for their abilities to replicate. Efficient replication was observed only when the total nucleotide number was conserved, regardless of the modifications, or when the addition of a total of 6 nucleotides was made. The replicated RNAs were shown to be properly enveloped into virus particles. It is concluded that, to form a proper template for efficient replication, the Sendai virus RNA must contain a total number of nucleotides which is a multiple of 6. This was interpreted as the need for the nucleocapsid protein to contact exactly 6 nucleotides.