Structure and functional relevance of a transcription-regulating sequence involved in coronavirus discontinuous RNA synthesis.

Transmissible gastroenteritis coronavirus (TGEV) genomic RNA transcription generates 5'- and 3'-coterminal subgenomic mRNAs. This process involves a discontinuous step during the synthesis of minus-sense RNA that is modulated by transcription-regulating sequences located at the 3' end of the leader (TRS-L) and also preceding each viral gene (TRS-Bs). TRSs include a highly conserved core sequence (CS) (5'-CUAAAC-3') and variable flanking sequences. It has been previously proposed that TRS-Bs act as attenuation or stop signals during the synthesis of minus-sense RNAs. The nascent minus-stranded RNA would then be transferred by a template switch process to the TRS-L, which acts as the acceptor RNA. To study whether the TRS-L is structured and to determine whether this structure has a functional impact on genomic and subgenomic viral RNA synthesis, we have used a combination of nuclear magnetic resonance (NMR) spectroscopy and UV thermal denaturation approaches together with site-directed mutagenesis and in vivo transcriptional analyses. The results indicated that a 36-nucleotide oligomer encompassing the wild-type TRS-L forms a structured hairpin closed by an apical AACUAAA heptaloop. This loop contains most of the CS and is isolated from a nearby internal loop by a short Watson-Crick base-paired stem. TRS-L mutations altering the structure and the stability of the TRS-L hairpin affected replication and transcription, indicating the requirement of a functional RNA hairpin structure in these processes.

Three-way RNA junctions with remote tertiary contacts: a recurrent and highly versatile fold.

Three-way junction RNAs adopt a recurrent Y shape when two of the helices form a coaxial stack and the third helix establishes one or more tertiary contacts several base pairs away from the junction. In this review, the structure, distribution, and functional relevance of these motifs are examined. Structurally, the folds exhibit conserved junction topologies, and the distal tertiary interactions play a crucial role in determining the final shape of the structures. The junctions and remote tertiary contacts behave as flexible hinge motifs that respond to changes in the other region, providing these folds with switching mechanisms that have been shown to be functionally useful in a variety of contexts. In addition, the juxtaposition of RNA domains at the junction and at the distal tertiary complexes enables the RNA helices to adopt unusual conformations that are frequently used by proteins, RNA molecules, and antibiotics as platforms for specific binding. As a consequence of these properties, Y-shaped junctions are widely distributed in all kingdoms of life, having been observed in small naked RNAs such as riboswitches and ribozymes or embedded in complex ribonucleoprotein systems like ribosomal RNAs, RNase P, or the signal recognition particle. In all cases, the folds were found to play an essential role for the functioning or assembly of the RNA or ribonucleoprotein systems that contain them.

Structure-function analysis of the ribozymes of chrysanthemum chlorotic mottle viroid: a loop-loop interaction motif conserved in most natural hammerheads.

Loop-loop tertiary interactions play a key role in the folding and catalytic activity of natural hammerhead ribozymes. Using a combination of NMR spectroscopy, site-directed mutagenesis and kinetic and infectivity analyses, we have examined the structure and function of loops 1 and 2 of the (+) and (-) hammerheads of chrysanthemum chlorotic mottle viroid RNA. In both hammerheads, loop 1 is a heptanucleotide hairpin loop containing an exposed U at its 5' side and an extrahelical U at its 3'-side critical for the catalytic activity of the ribozyme in vitro and for viroid infectivity in vivo, whereas loop 2 has a key opened A at its 3'-side. These structural features promote a specific loop-loop interaction motif across the major groove. The essential features of this tertiary structure element, base pairing between the 5' U of loop 1 and the 3' A of loop 2, and interaction of the extrahelical pyrimidine of loop 1 with loop 2, are likely shared by a significant fraction of natural hammerheads.