The protein NS3 of Dengue virus type 2 (DEN-2) is the second largest nonstructural protein specified by the virus and is known to possess multiple enzymatic activities, including a serine proteinase located in the Nterminal region and an NTPase-helicase in the remaining 70% of the protein. The latter region has seven conserved helicase motifs found in all members of the family Flaviviridae. DEN-2 NS3 lacking the proteinase region was synthesized as a fusion protein with glutathione S-transferase in Escherichia coli. The effects of 10 mutations on ATPase and RNA helicase activity were examined. Residues at four sites within enzyme motifs I, II, and VI were substituted, and six sites outside motifs were altered by clustered charged-to-alanine mutagenesis. The mutations were also tested for their effects on virus replication by incorporation into genomic-length cDNA. Two mutations, both in motif I (G198A and K199A) abolished both ATPase and helicase activity. Two further mutations, one in motif VI (R457A,R458A) and the other a clustered charged-to-alanine substitution at R 376 KNGK 380 , abolished helicase activity only. No virus was detected for any mutation which prevented helicase activity, demonstrating the requirement of this enzyme for virus replication. The remaining six mutations resulted in various levels of enzyme activities, and four permitted virus replication. For the two nonreplicating viruses encoding clustered changes at R 184 KR 186 and D 436 GEE 439 , we propose that the substituted residues are surface located and that the viruses are defective through altered interaction of NS3 with other components of the viral replication complex. Two of the replicating viruses displayed a temperature-sensitive phenotype. One contained a clustered mutation at D 334 EE 336 and grew too poorly for further characterization. However, virus with an M283F substitution in motif II was examined in a temperature shift experiment (33 to 37°C) and showed reduced RNA synthesis at the higher temperature.The four serotypes of Dengue virus (types 1 to 4) belong to the family Flaviviridae, which consists of the genera Flavivirus, Pestivirus, and Hepacivirus (52). The dengue virus genome is positive-sense RNA of 11 kb and encodes the proteins C-prM-E-NS1-NS2A-NS2B-NS3-NS4A-NS4B-NS5 in a single open reading frame. Co-and posttranslational polyprotein processing by host and viral proteinases generates three structural proteins, namely, C (capsid), M (membrane associated) and E (envelope), and seven nonstructural (NS) proteins, NS1 through NS5 (reviewed in reference 45). Biochemical functions have been demonstrated for some nonstructural proteins. NS5 possesses RNA-dependent RNA polymerase activity (49). A complex of NS2B and NS3 acts as a chymotrypsin-like serine proteinase; the N-terminal 30% of NS3 is sufficient for this activity (15, 42). The C-terminal 70% of NS3 has seven motifs characteristic of RNA helicases of the DExH subfamily. Recombinant proteins containing the C-terminal helicase region of dengue virus NS3 possess n...
The N-terminal one-third of the NS3 protein of Dengue virus type 2 (DEN-2) complexes with cofactor NS2B to form an active serine proteinase which cleaves the viral polyprotein. To identify sites within NS3 that may interact with NS2B, seven regions within the NS3 proteinase outside the conserved flavivirus enzyme motifs were mutated by alanine replacement. Five sites contained clusters of charged residues and were hydrophilic. Two sites were hydrophobic and highly conserved among flaviviruses. The effects of five mutations on NS2B/3 processing were examined using a COS cell expression system. Four retained significant proteinase activity. Three of these mutations and two more were introduced into genomic-length cDNA and tested for their effects on virus replication. The five mutant viruses showed reduced plaque size and two of the five showed significantly reduced titres. All seven mutations were mapped on the X-ray crystal structure of the DEN-2 NS3 proteinase : three were located at the N terminus and two at the C terminus of the NS2B-binding cleft. Two mutations were at the C terminus of the proteinase domain and one was solvent-exposed. The study demonstrated that charged-to-alanine mutagenesis in the viral proteinase can be used to produce growth-restricted flaviviruses that may be useful in the production of attenuated vaccine strains.
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