Nucleotide sequence of yellow fever virus: implications for flavivirus gene expression and evolution.

The sequence of the entire RNA genome of the type flavivirus, yellow fever virus, has been obtained. Inspection of this sequence reveals a single long open reading frame of 10,233 nucleotides, which could encode a polypeptide of 3411 amino acids. The structural proteins are found within the amino-terminal 780 residues of this polyprotein; the remainder of the open reading frame consists of nonstructural viral polypeptides. This genome organization implies that mature viral proteins are produced by posttranslational cleavage of a polyprotein precursor and has implications for flavivirus RNA replication and for the evolutionary relation of this virus family to other RNA viruses.

RNA viruses: genome structure and evolution.

The explosive pace of sequencing of RNA viruses is leading to rapid advances in our understanding of the evolution of these viruses and of the ways in which their genomes are organized and expressed. New insights are coming not only from genomic nucleotide sequence comparisons, but also from direct sequencing of transcribed mRNAs and of RNAs that serve as intermediates in replication.

Neomycin resistance as a dominant selectable marker for selection and isolation of vaccinia virus recombinants.

The antibiotic G418 was shown to be an effective inhibitor of vaccinia virus replication when an appropriate concentration of it was added to cell monolayers 48 h before infection. Genetic engineering techniques were used in concert with DNA transfection protocols to construct vaccinia virus recombinants containing the neomycin resistance gene (neo) from transposon Tn5. These recombinants contained the neo gene linked in either the correct or incorrect orientation relative to the vaccinia virus 7.5-kilodalton gene promoter which is expressed constitutively throughout the course of infection. The vaccinia virus recombinant containing the chimeric neo gene in the proper orientation was able to grow and form plaques in the presence of G418, whereas both the wild-type and the recombinant virus with the neo gene in the opposite polarity were inhibited by more than 98%. The effect of G418 on virus growth may be mediated at least in part by selective inhibition of the synthesis of a subset of late viral proteins. These results are discussed with reference to using this system, the conferral of resistance to G418 with neo as a positive selectable marker, to facilitate constructing vaccinia virus recombinants which contain foreign genes of interest.

Budding of alphaviruses.

The icosahedral structures of alphaviruses and of the external shell of the viral nucleocapsid have been defined to very high resolutions, revealing details of the interactions between the glycoproteins to form trimeric spikes and the nucleocapsid. The structural studies complement biochemical and molecular genetic studies showing that a sequence-specific interaction between the cytoplasmic domains of the glycoproteins and the nucleocapsid drives budding.

Partial nucleotide sequence of the Murray Valley encephalitis virus genome. Comparison of the encoded polypeptides with yellow fever virus structural and non-structural proteins.

The sequence of 5400 bases corresponding to the 5'-terminal half of the Murray Valley encephalitis virus genome has been determined. The genome contains a 5' non-coding region of about 97 nucleotides, followed by a single continuous open reading frame that encodes the structural proteins followed by the non-structural proteins. Amino acid sequence homology between the Murray Valley encephalitis and yellow fever (Rice et al., 1985) polyproteins is 42% over the region sequenced. The start points of the various Murray Valley encephalitis virus-coded proteins have been assigned on the basis of this homology and a consistent set of potential proteolytic cleavage sites identified, the sequences of which are similar in Murray Valley encephalitis and yellow fever. The deduced Murray Valley encephalitis gene order is 5'-C-prM (M)-E-NS1-ns2a-ns2b-NS3-3'. The genome organization of Murray Valley encephalitis and yellow fever appears to be identical and the sizes of the predicted virus-coded proteins similar between the two viruses. Both viruses encode a basic capsid protein followed by three glycoproteins; the glycoproteins appear to have the conventional topology of N terminus outside with a C-terminal membrane-spanning domain. There are conserved glycosylation sites in prM, the precursor to the M protein of the virion, and in NS1, a non-structural protein of uncertain function. The glycosylation sites in E, the major envelope protein of the virion, are not conserved as to position. We predict the existence, in flavivirus-infected cells, of two small, hydrophobic peptides, ns2a and ns2b, which show only limited amino acid sequence homology. Finally, about half of the amino acid sequence of NS3 has been obtained; NS3 is a hydrophilic non-structural protein that shows 55% amino acid sequence similarity between Murray Valley encephalitis and yellow fever over the region sequenced and is probably involved in RNA replication.

The 5'-terminal sequences of the genomic RNAs of several alphaviruses.

The 5'-terminal sequences of the genomic RNAs of several alphaviruses have been determined. The nucleotide sequences at the extreme 5' termini are not highly conserved among the alphaviruses, but a similar stem and loop structure, which begins at the 5' end and utilizes about the first 40 nucleotides, can be formed in each case. Downstream from this structure, beginning about 150 nucleotides from the 5' end, a conserved sequence of 51 nucleotides is found which can form two stable hairpin structures. Examination of the 5'-terminal and 3'-terminal sequences suggests that part of this conserved nucleotide sequence may be involved in cyclization of the RNA. A model is proposed for the function of the 5'-terminal sequences in RNA replication. In addition, sequence homologies among these RNAs strongly support the hypothesis that an AUG codon, which occurs at 60 to 80 nucleotides from the 5' end, depending on the virus, and which may or may not be the first AUG codon, is used for initiation of translation of the non-structural proteins and allows a comparison of the deduced amino acid sequences in the NH2-terminal regions.

Sequence analysis of two mutants of Sindbis virus defective in the intracellular transport of their glycoproteins.

We have sequenced the complementary DNA corresponding to the genes encoding the viral glycoproteins of ts10 and ts23, mutants of Sindbis virus defective in the intracellular transport of their glycoproteins, and of revertants of these mutants. These studies have been augmented by direct amino acid sequencing of the amino-terminal regions of the glycoproteins of several virus strains. By comparing the deduced amino acid sequence with that of Sindbis HR virus, the parental strain of these mutants, and with the sequence of the revertants, we found ts23 to have a double mutation in glycoprotein E1, while ts10 was a single mutant in the same glycoprotein. In each case reversion to temperature insensitivity occurred by changes at the same site as the mutation, in two cases restoring the original amino acid and in the third case substituting an homologous amino acid (arginine in place of lysine). The three mutations were far apart from each other in the protein, suggesting that the three-dimensional conformation is very important for the correct migration of the glycoproteins from the rough endoplasmic reticulum to the plasma membrane. The sequence data also reveal that a number of other changes have occurred in the various virus strains during mutagenesis or passage.

Conserved elements in the 3' untranslated region of flavivirus RNAs and potential cyclization sequences.

We have isolated a cDNA clone after reverse transcription of the genomic RNA of Asibi yellow fever virus whose structure suggests it was formed by self-priming from a 3'-terminal hairpin of 87 nucleotides in the genomic RNA. We have also isolated a clone from cDNA made to Murray Valley encephalitis virus RNA that also appears to have arisen by self-priming from a 3'-terminal structure very similar or identical to that of yellow fever. In addition, 3'-terminal sequencing of the S1 strain of dengue 2 RNA shows that this RNA is also capable of forming a 3'-terminal hairpin of 79 nucleotides. Furthermore, we have identified two 20-nucleotide sequence elements which are present in the 3' untranslated region of all three viruses; one of these sequence elements is repeated in Murray Valley encephalitis and dengue 2 RNA but not in yellow fever RNA. In all three viruses, which represent the three major serological subgroups of the mosquito-borne flaviviruses, the 3'-proximal conserved sequence element, which is found immediately adjacent to the potential 3'-terminal hairpin, is complementary to another conserved domain near the 5' end of the viral RNAs, suggesting that flavivirus RNAs can cyclize (calculated delta G less than -11 kcal; 1 kcal = 4.184 kJ).

Host-cell receptors for Sindbis virus.

Sindbis virus has a very wide host range, infecting many species of mosquitoes and other hematophagous insects and infecting many species of higher vertebrates. We have used two approaches to study host cell receptors used by Sindbis virus to enter cells. Anti-idiotype antibodies to neutralizing antibodies directed against glycoprotein E2 of the virus identified a 63-kDa protein as a putative receptor in chicken cells. In a second approach, monoclonal antibodies identified a 67 kDa protein, believed to be a high affinity laminin receptor, as a putative receptor in mammalian cells and in mosquito cells. We conclude that the virus attains its very wide host range by two mechanisms. In one mechanism, the virus is able to use more than one protein as a receptor. In a second mechanism, the virus utilizes proteins as receptors that are highly conserved across the animal kingdom.

Consumption coagulopathy associated with intrauterine fetal death: the role of heparin therapy.

A gravida with intrauterine fetal death who developed progressive chronic consumption coagulopathy was treated with heparin. When serial fibrinogen levels fell below 100 mg% and the prothrombin time was significantly prolonged, intravenously injected heparin corrected hypofibrinogenemia. A safe delivery followed administration of oxytocin. The authors emphasize the infrequent need for heparin therapy in the majority of cases of the intrauterine fetal death syndrome. Therapeutic guidelines for its use in selected cases are reviewed.