Primary structure of the West Nile flavivirus genome region coding for all nonstructural proteins.

The genome RNA of the flavivirus West Nile (WN) virus has been transcribed into cDNA, the cDNA has been cloned, and the nucleotide sequences coding for the structural proteins have been determined (Castle et al., 1985; Wengler et al., 1985). We have now determined the nucleotide sequence coding for all viral nonstructural proteins which comprises 7929 nucleotides. Together with our earlier sequence analyses these data show that a long open reading frame (ORF) containing 10,290 nucleotides is present on the genome of WN virus. The two largest nonstructural proteins which can be detected in flavivirus-infected cells are the proteins NV5 and NV4 which have an apparent molecular mass of 97,000 and 74,000 Da, respectively. Both proteins were isolated by preparative polyacrylamide gel electrophoresis, and partial amino acid sequences of peptides derived from these proteins were determined. These analyses allow us to localize the nucleotide regions which code for these proteins and show that the region coding for the NV5 protein is located at the 3'-terminus of the long ORF. Together with our earlier analyses these data show that the protein sequences of virus-specific proteins are present on the viral polyprotein translated from the long ORF in the order V2-NV2-V3-(nonstructural proteins of up to 75,000 Da)-NV4-(nonstructural proteins of up to 45,000 Da)-NV5. Our data indicate that virus-specific structural and nonstructural proteins which are synthesized from a single long ORF accumulate in large amounts in infected cells. A possible role of the presence of these molecules, which are associated to cellular membranes, in the accumulation of membrane vesicles which characteristically occurs in flavivirus-infected cells is discussed.

Sequence analysis of the membrane protein V3 of the flavivirus West Nile virus and of its gene.

Flaviviruses contain a large membrane-associated protein V3, having a mol mass of about 50 kDa which is responsible for hemagglutination. We have isolated the V3 protein from the West Nile (WN) flavivirus and determined its amino-terminal amino acid sequence and amino acid sequences of fragments derived from this protein. We have also transcribed parts of the WN virus genome RNA into cDNA and cloned and sequenced this cDNA. The results of these analyses have allowed us to identify the region of the viral genome coding for the V3 protein. In this report we describe the total nucleotide sequence of the genome region coding for the WN virus V3 protein and the amino acid sequence of the V3 protein derived from these analyses. The exact carboxy terminus of the V3 protein has not been determined in these experiments. These analyses have shown that the V3 protein of WN virus does not contain an Asn-X-Ser/Thr sequence which could allow addition of N-linked carbohydrate chains to this protein. In accordance with this finding, analyses of metabolic labeling of the V3 protein using [3H]glucosamine indicate that the WN virus V3 protein is an unglycosylated protein. Together with our earlier analyses these results show that the viral structural proteins are present on the genome RNA in the order 5'-terminus-core protein (V2)-small membrane-associated protein (NV2)-large membrane-associated protein (V3) and describe the nucleotide sequences coding for all WN virus structural proteins identified so far. A hypothesis concerning the processes involved in the synthesis of all viral structural proteins and the probable orientation of these proteins relative to the endoplasmatic reticulum membrane based on the structure of these proteins is discussed.

Sequence analysis of the viral core protein and the membrane-associated proteins V1 and NV2 of the flavivirus West Nile virus and of the genome sequence for these proteins.

Cell-associated flaviviruses contain the two membrane proteins V3 and NV2 besides the viral core protein V2 whereas extracellular viruses do contain V2 protein and the two membrane proteins V3 and V1. Since the V1 protein could not be detected in infected cells it has been suggested that V1 is generated from NV2 by proteolytic cleavage during the release of virus from cells (D. Shapiro, W. E. Brandt, and P. K. Russell (1972), Virology 50, 906-911). We have isolated the viral structural proteins V1, V2, and NV2 from the flavivirus West Nile virus and determined their amino-terminal amino acid sequences and amino acid sequences of peptides derived from these proteins. We have also transcribed parts of the viral genome into cDNA and cloned and sequenced this cDNA. The analyses of the protein structure of V1, V2, and NV2 together with the determination of the amino-terminal sequence of V3 (data not shown) have allowed us to identify the nucleotide region coding for the structural proteins V2, NV2, and V1. The primary structure of this nucleotide sequence is presented in this report. The data show that the amino terminus of the viral core protein V2 is followed by the amino termini of the proteins NV2, V1, and V3, respectively. These data for the first time identify the exact order of all structural proteins of a flavivirus identified so far. Our data strongly support the above-mentioned hypothesis that V1 is derived from NV2 by proteolytic cleavage and furthermore indicate that V1 represents the nonglycosylated carboxy-terminal part of NV2 which contains those sequences which anchor NV2 in the viral membrane. A working hypothesis is presented in which two species of cellular enzymes, signalase(s) removing signal sequences and enzymes involved in cleaving polyproteins after a pair of basic amino acids, do generate the proteins V2, NV2, and V1 from the growing peptide chain synthesized during translation of the 42 S genome RNA which functions as mRNA for these proteins.