We have found that RNase P from HeLa cells specifically and efficiently cleaves hepatitis C virus (HCV) transcripts in vitro. The evidence includes identification of the 5-phosphate polarity of the newly generated termini at position A 2860 as well as immunological and biochemical assays. Active cleavage has been shown in five dominant sequences of HCV "quasispecies" differing at or near the position of cleavage, demonstrating that this is a general property of HCV RNA. During the analysis, a second cleavage event was found in the 3 domain of the internal ribosome entry site. We have found that HCV RNA competitively inhibits pre-tRNA cleavage by RNase P, suggesting that HCV RNA has structural similarities to tRNA. This finding sets HCV apart from other pathogens causing serious human diseases and represents the first description of human RNase P-viral RNA cleavage. Here we discuss the possible meaning of these RNase P-accessible structures built into the viral genome and their possible role in vivo. Moreover, such structures within the viral genome might be vulnerable to attack by therapeutic strategies.
The 9600-base RNA genome of hepatitis C virus (HCV) has an internal ribosome entry site (IRES) in its first 370 bases, including the AUG start triplet at bases 342-344. Structural elements of this and other IRES domains substitute for a 5 terminal cap structure in protein synthesis. Recent work (Nadal, A., Martell, M., Lytle, J. R., Lyons, A. J., Robertson, H. D., Cabot, B., Esteban, J. I., Esteban, R., Guardia, J., and Gomez, J. (2002) J. Biol. Chem. 277, 30606 -30613) has demonstrated that the host pre-tRNA processing enzyme, RNase P, can cleave the HCV RNA genome at a site in the IRES near the AUG initiator triplet. Although this step is unlikely to be part of the HCV life cycle, such a reaction could indicate the presence of a tRNA-like structure in this IRES. Because susceptibility to cleavage by mammalian RNase P is a strong indicator of tRNA-like structure, we have conducted the studies reported here to test whether such tRNA mimicry is unique to HCV or is a general property of IRES structure. We have assayed IRES domains of several viral RNA genomes: two pestiviruses related to HCV, classical swine fever virus and bovine viral diarrhea virus; and two unrelated viruses, encephalomyocarditis virus and cricket paralysis virus. We have found similarly placed RNase P cleavage sites in these IRESs. Thus a tRNA-like domain could be a general structural feature of IRESs, the first IRES structure to be identified with a functional correlate. Such tRNA-like features could be recognized by pre-existing ribosomal tRNAbinding sites as part of the IRES initiation cycle. The hepatitis C virus (HCV)1 is a flavivirus with a singlestranded RNA genome almost 9600 bases in length. HCV produces a chronic infection that can lead to cirrhosis and liver cancer and is the leading cause of liver transplants in the United States and elsewhere (1).The HCV RNA genome lacks a 5袌 cap structure, the signal used by most eukaryotic messages to initiate protein synthesis (1). HCV is nevertheless able to bind cellular ribosomes in the host and to initiate accurate protein translation due to the presence in the first 400 bases of the viral genome of an internal ribosome entry site (IRES). IRESs are found in certain other viral pathogens such as the picornavirus and pestivirus groups (2, 3), and even in rare cases in human cellular RNAs (4, 5). The mechanism by which IRESs function is unknown.Studies in our laboratory and elsewhere (6 -10) on HCV IRES ribosome binding sites have revealed that considerably more sequence is involved in IRES-directed protein synthesis initiation than in its cap-directed counterpart, up to 5-fold more in some cases (6). Jackson (2) has suggested, in light of limited sequence homology among IRES elements, that widely spaced structural elements may be the key to ribosome recognition thereof. For these reasons, Lytle et al. (6) considered several elements of higher order structure that could be responsible for IRES function. So far, however, no structural element with a known affinity for ribosomes has been shown t...
The internal ribosome entry site (IRES) of hepatitis C virus (HCV) RNA contains >300 bases of highly conserved 5'-terminal sequence, most of it in the uncapped 5'-untranslated region (5'-UTR) upstream from the single AUG initiator triplet at which translation of the HCV polyprotein begins. Although progress has been made in defining singularities like the RNA pseudoknot near this AUG, the sequence and structural features of the HCV IRES which stimulate accurate and efficient initiation of protein synthesis are only partially defined. Here we report that a region further upstream from the AUG, stem-loop II of the HCV IRES, also contains an element of local tertiary structure which we have detected using RNase H cleavage and have mapped using the singular ability of two bases therein to undergo covalent intra-chain crosslinking stimulated by UV light. This pre-existing element maps to two non-contiguous stretches of the HCV IRES sequence, residues 53-68 and 103-117. Several earlier studies have shown that the correct sequence between bases 45 and 70 of the HCV IRES stem-loop II domain is required for initiation of protein synthesis. Because features of local tertiary structure like the one we report here are often associated with protein binding, we propose that the HCV stem-loop II element is directly involved in IRES action.
Elements of local tertiary structure in RNA molecules are important in understanding structure-function relationships. The loop E motif, first identified in several eukaryotic RNAs at functional sites which share an exceptional propensity for UV crosslinking between specific bases, was subsequently shown to have a characteristic tertiary structure. Common sequences and secondary structures have allowed other examples of the E-loop motif to be recognized in a number of RNAs at sites of protein binding or other biological function. We would like to know if more elements of local tertiary structure, in addition to the E-loop, can be identified by such common features. The highly structured circular RNA genome of the hepatitis D virus (HDV) provides an ideal test molecule because it has extensive internal structure, a UV-crosslinkable tertiary element, and specific sites for functional interactions with proteins including host PKR. We have now found a UV-crosslinkable element of local tertiary structure in antigenomic HDV RNA which, although differing from the E-loop, has a very similar pattern of sequence and secondary structure to the UV-crosslinkable element found in the genomic strand. Despite the fact that the two structures map close to one another, the sequences comprising them are not the templates for each other. Instead, the template regions for each element are additional sites for potential higher order structure on their respective complementary strands. This wealth of recurring sequences interspersed with base-paired stems provides a context to examine other RNA species for such features and their correlations with biological function.
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