Ribosomal binding sites on poliovirus RNA

Translational efficiency of poliovirus mRNA: mapping inhibitory cis-acting elements within the 5' noncoding region

Poliovirus mRNA contains a long 5' noncoding region of about 750 nucleotides (the exact number varies among the three virus serotypes), which contains several AUG codons upstream of the major initiator AUG. Unlike most eucaryotic mRNAs, poliovirus does not contain a m7GpppX (where X is any nucleotide) cap structure at its 5' end and is translated by a cap-independent mechanism. To study the manner by which poliovirus mRNA is expressed, we examined the translational efficiencies of a series of deletion mutants within the 5' noncoding region of the mRNA. In this paper we report striking translation system-specific differences in the ability of the altered mRNAs to be translated. The results suggest the existence of an inhibitory cis-acting element(s) within the 5' noncoding region of poliovirus (between nucleotides 70 and 381) which restricts mRNA translation in reticulocyte lysate, wheat germ extract, and Xenopus oocytes, but not in HeLa cell extracts. In addition, we show that HeLa cell extracts contain a trans-acting factor(s) that overcomes this restriction.

Comparative sequence analysis of the 5' noncoding region of the enteroviruses and rhinoviruses

A comparative sequence analysis of the 5' noncoding region of a subgroup of the picornaviruses, including the polioviruses, coxsackie B3, and the human rhinoviruses, reveals the conservation of certain features despite the divergence of sequence. In this subgroup, for which nine complete sequences are available, two long stretches of sequence, two pyrimidine-rich regions, and 22 hairpins are conserved. Based on these results, similar secondary structures encompassing the entire 5' noncoding regions of these viruses are predicted. The fact that sequence divergence occurred only in a manner that allowed conservation of these structures implicates a biologically functional role for this region. The possible roles it may have in the picornavirus life cycle are discussed.

Cap-independent translation of poliovirus mRNA is conferred by sequence elements within the 5' noncoding region

Poliovirus polysomal RNA is naturally uncapped, and as such, its translation must bypass any 5' cap-dependent ribosome recognition event. To elucidate the manner by which poliovirus mRNA is translated, we have determined the translational efficiencies of a series of deletion mutants within the 5' noncoding region of the mRNA. We found striking differences in translatability among the altered mRNAs when assayed in mock-infected and poliovirus-infected HeLa cell extracts. The results identify a functional cis-acting element within the 5' noncoding region of the poliovirus mRNA which enables it to translate in a cap-independent fashion. The major determinant of this element maps between nucleotides 320 and 631 of the 5' end of the poliovirus mRNA. We also show that this region (320 to 631), when fused to a heterologous mRNA, can function in cis to render the mRNA cap independent in translation.

Cap-independent translation of poliovirus mRNA is conferred by sequence elements within the 5' noncoding region

Poliovirus polysomal RNA is naturally uncapped, and as such, its translation must bypass any 5' cap-dependent ribosome recognition event. To elucidate the manner by which poliovirus mRNA is translated, we have determined the translational efficiencies of a series of deletion mutants within the 5' noncoding region of the mRNA. We found striking differences in translatability among the altered mRNAs when assayed in mock-infected and poliovirus-infected HeLa cell extracts. The results identify a functional cis-acting element within the 5' noncoding region of the poliovirus mRNA which enables it to translate in a cap-independent fashion. The major determinant of this element maps between nucleotides 320 and 631 of the 5' end of the poliovirus mRNA. We also show that this region (320 to 631), when fused to a heterologous mRNA, can function in cis to render the mRNA cap independent in translation.

Modulation of the expression of poliovirus proteins in reticulocyte lysates

The translation of poliovirus RNA into specific viral proteins in mRNA-dependent reticulocyte lysates (MDLs) was found to be highly dependent on individual lysate preparations. Under optimal conditions, the first polypeptide detected was always P3-1b (formerly NCVP 1b), the product of the 3' portion of the poliovirus genome; the formation of P1-1a (formerly NCVP 1a) followed as shown by time-course and pulse-chase experiments. However, some lysates synthesized little or no P1-1a despite their ability to synthesize P3-1b and to translate normally other cellular and viral mRNAs. When an MDL competent in synthesizing P1-1a was diluted ca. twofold, while maintaining optimal concentrations of salts, tRNA, DTT, creatine phosphate, and amino acids, P1-1a formation was virtually eliminated, while the synthesis of P3-1b, presumably as a consequence of a more downstream initiation, was maintained. The synthesis of P1-1a in a diluted MDL was restored, and P3-1b synthesis suppressed, by the addition of a S10 fraction prepared from uninfected or virus-infected HeLa cells. Nuclease treatment and dialysis of the S10 fraction did not inhibit its activity. These findings indicate that individual MDLs either possess limiting quantities of, or occasionally are deficient in, a factor(s) that promotes the utilization of the presumed 5' proximal initiation site (the AUG at nucleotide position 781-783) and that a homologous factor(s) exists in HeLa cells. The implication of these findings for the strategy of poliovirus replication is discussed.

Poliovirus genome RNA hybridizes specifically to higher eukaryotic rRNAs

The RNA genome of poliovirus hybridizes to 28S and 18S rRNAs of higher eukaryotes under stringent conditions. The hybridization detected by Northern blot analyses is specific since little or no signal was detected for yeast or prokaryotic rRNAs or other major cellular RNAs. Southern blot analysis of DNA clones of mouse rRNA genes leads us to conclude that several regions of 28S rRNA, and at least one region in 18S rRNA, are involved in the hybridization to polio RNA, and that G/C regions are not responsible for this phenomenon. We have precisely mapped one of these hybridizing regions in both molecules. Computer analysis confirms that extensive intermolecular base-pairing (81 out of 104 contiguous bases in the rRNA strand) could be responsible for this one particular site of interaction (polio genome, bases 5075-5250; 28S rRNA, bases 1097-1200). We discuss the possible functional and/or evolutionary significance of this novel type of interaction.

In vitro translation of poliovirus RNA: utilization of internal initiation sites in reticulocyte lysate

The translation of poliovirus RNA in rabbit reticulocyte lysate was examined. Translation of poliovirus RNA in this cell-free system resulted in an electrophoretic profile of poliovirus-specific proteins distinct from that observed in vivo or after translation in poliovirus-infected HeLa cell extract. A group of proteins derived from the P3 region of the polyprotein was identified by immunoprecipitation, time course, and N-formyl-[35S]methionine labeling studies to be the product of the initiation of protein synthesis at an internal site(s) located within the 3'-proximal RNA sequences. Utilization of this internal initiation site(s) on poliovirus RNA was abolished when reticulocyte lysate was supplemented with poliovirus-infected HeLa cell extract. Authentic P1-1a was also synthesized in reticulocyte lysate, indicating that correct 5'-proximal initiation of translation occurs in that system. We conclude that the deficiency of a component(s) of the reticulocyte lysate necessary for 5'-proximal initiation of poliovirus protein synthesis resulted in the ability of ribosomes to initiate translation on internal sequences. This aberrant initiation could be corrected by factors present in the HeLa cell extract. Apparently, under certain conditions, ribosomes are capable of recognizing internal sequences as authentic initiation sites.

Gene order of translation of the flavivirus Kunjin: further evidence of internal initiation in vivo

The rates of inactivation of synthesis of individual virus-specified proteins by ultraviolet radiation provided an estimate of the target sizes of individual viral genes. In a control experiment with Semliki Forest virus, the genes for the structural proteins mapped in the known sequence 5' C-PE2-E1 3', and in accordance with initiation of translation from a single site on 26-S mRNA. Under the same conditions, the inactivation of synthesis of seven Kunjin virus-specified proteins also followed first-order kinetics, but the largest target size was equivalent to only about half the length of the genome. No gene sequence could be deduced using the premise that translation was initiated at a single site. However, genes for the major nonstructural proteins could be mapped in the order 5' P98-P71-P10 3' from a postulated ribosomal attachment site about midway along the RNA. The genes for the structural proteins C and E could then be mapped in a preceding sequence 5'...C-E-GP19-P21 3', with a vacant upstream region sufficient to code for at least one of two flavivirus genes not expressed in these experiments. The implications of the two postulated translational units are discussed in relation to previous data on translation strategy of flaviviruses.