The nucleotide at position 480 in the 5 noncoding region of the viral RNA genome plays an important role in directing the attenuation phenotype of the Sabin vaccine strain of poliovirus type 1. In vitro translation studies have shown that the attenuated viral genomes of the Sabin strains direct levels of viral protein synthesis lower than those of their neurovirulent counterparts. We previously described the isolation of pseudorevertant polioviruses derived from transfections of HeLa cells with genome-length RNA harboring an eight-nucleotide lesion in a stem-loop structure (stem-loop V) that contains the attenuation determinant at position 480 (A. A. Haller and B. L. Semler, J. Virol. 66:5075-5086, 1992). This stem-loop structure is a major component of the poliovirus internal ribosome entry site required for initiation of viral protein synthesis. The eight-nucleotide lesion (X472) was lethal for virus growth and gave rise only to viruses which had partially reverted nucleotides within the original substituted sequences. In this study, we analyzed two of the poliovirus revertants (X472R1 and X472R2) for cell-type-specific growth properties. The X472R1 and X472R2 RNA templates directed protein synthesis to wild-type levels in in vitro translation reaction mixtures supplemented with crude cytoplasmic HeLa cell extracts. In contrast, the same X472 revertant RNAs displayed a decreased translation initiation efficiency when translated in a cell-free system supplemented with extracts from neuronal cells. This translation initiation defect of the X472R templates correlated with reduced yields of infectious virus particles in neuronal cells compared with those obtained from HeLa cells infected with the X472 poliovirus revertants. Our results underscore the importance of RNA secondary structures within the poliovirus internal ribosome entry site in directing translation initiation and suggest that such structures interact with neuronal cell factors in a specific manner.
In attenuated Sabin strains, point mutations within stem-loop V of the 5'-non-coding region (NCR) reduce neurovirulence and cell-specific cap-independent translation. The stem-loop V attenuation determinants lie within the highly structured internal ribosome entry site. Although stem-loop V Sabin mutations have been proposed to alter RNA secondary structure, efforts to identify such conformational changes have been unsuccessful. A previously described linker-scanning mutation (X472) modified five nucleotides adjacent to the attenuation determinant at nt 480 [for poliovirus (PV) type 1]. Transfection of X472 RNA generated only pseudo-revertants in HeLa (cervical carcinoma) or SK-N-SH (neuroblastoma) cells. Pseudo-revertants from both cell types contained nucleotide changes within the X472 linker. In addition, some neuroblastoma-isolated revertants revealed second site mutations within the pyrimidine-rich region located approximately 100 nt distal to the original lesion. Enzymatic RNA structure probing determined that the X472 linker substitution did not disrupt the overall conformation of stem-loop V but abolished base pairing adjacent to the attenuation determinant. Our analyses correlated increased base pairing proximal to the stem-loop V attenuation determinant with growth of X472 revertant RNAs (measured by northern blot analysis). Potential roles of second site mutations in the pyrimidine-rich region are discussed. In addition, our enzymatic structure probing results are shown on a consensus secondary structure model for stem-loop V of the PV 5'-NCR.
Five revertants of a linker-scanning mutation adjacent to the stem-loop V attenuation determinant (X472) in the 5' noncoding region of poliovirus RNA were independently isolated from neuroblastoma cells and contained RNAs with seven nucleotide changes in the pyrimidine-rich region. Generation of the identical rare second-site mutations suggests the existence of a replicase-dependent mutagenesis mechanism during poliovirus replication. Enzymatic structure probing of the mutated pyrimidine-rich domain identified secondary structure changes between stem-loops V and VI. A consensus secondary structure model is presented for wild-type stem-loops V and VI and the pyrimidine-rich region located in the 5' noncoding region of poliovirus RNA. A pyrimidine-rich region mutant (X472-R4N) produced large plaques in neuroblastoma cells and small plaques in HeLa cells, but the plaque size differences were not due to cell-type differences in viral translation or RNA replication. Release of X472-R4N from HeLa cells was 10-fold lower than release from neuroblastoma cells, which may explain the small plaque phenotype of X472-R4N in HeLa cells. Wild-type poliovirus was also released more efficiently from neuroblastoma cells (approximately 4-fold increase compared with release from HeLa cells), indicating that poliovirus neurotropism may be influenced by the cell-type efficiency of virus release. Thermal treatment increased the levels of infectious X472-R4N virions but not wild-type virus particles; thus RNA sequence and structural changes in the mutated 5' noncoding region of X472-R4N may have altered RNA-protein interactions necessary for virus infectivity.
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