Interaction of rat poly(A)-binding protein with poly(A)- and non-poly(A) sequences is preferentially mediated by RNA recognition motifs 3+4

Vasopressin (VP) mRNA and the non-coding BC200 RNA are sorted to neuronal dendrites. Among proteins interacting specifically with both RNAs is the multifunctional poly(A)-binding protein (PABP) consisting of four RNA recognition motifs (RRMs) and a C-terminal auxiliary domain. The protein/RNA interaction studies presented here reveal that PABPs association with VP- and BC200 RNA is exclusively mediated by RRMs 3+4. Quantitative binding studies with PABP deletion mutants demonstrate preferential binding of RRMs 3+4 even to poly(A)-homopolymers, while RRMs 1+2 exhibit a lower affinity for those sequences. An optimal interaction with both poly(A)- and non-poly(A) sequences is only achieved by full-size PABP.     

Substrate-specific kinetics of Dicer-catalyzed RNA processing

The specialized ribonuclease Dicer plays a central role in eukaryotic gene expression by producing small regulatory RNAs—microRNAs (miRNAs) and short interfering RNAs (siRNAs)—from larger double-stranded RNA (dsRNA) substrates. Although Dicer will cleave both imperfectly base-paired hairpin structures (pre-miRNAs) and perfect duplexes (pre-siRNAs) in vitro, it has not been clear whether these are mechanistically equivalent substrates and how dsRNA binding proteins such as trans-activation response (TAR) RNA binding protein (TRBP) influence substrate selection and RNA processing efficiency. We show here that human Dicer is much faster at processing a pre-miRNA substrate compared to a pre-siRNA substrate under both single and multiple turnover conditions. Maximal cleavage rates (V_max) calculated by Michaelis-Menten analysis differed by more than 100-fold under multiple turnover conditions. TRBP was found to enhance dicing of both substrates to similar extents, and this stimulation required the two N-terminal dsRNA binding domains of TRBP. These results demonstrate that multiple factors influence dicing kinetics. While TRBP stimulates dicing by enhancing the stability of Dicer-substrate complexes, Dicer itself generates product RNAs at rates determined at least in part by the structural properties of the substrate.     

Neuronal BC1 RNA structure: evolutionary conversion of a tRNA(Ala) domain into an extended stem-loop structure

By chemical and enzymatic probing, we have analyzed the secondary structure of rodent BC1 RNA, a small brain-specific non-messenger RNA. BC1 RNA is specifically transported into dendrites of neuronal cells, where it is proposed to play a role in regulation of translation near synapses. In this study we demonstrate that the 5' domain of BC1 RNA, derived from tRNA(Ala), does not fold into the predicted canonical tRNA cloverleaf structure. We present evidence that by changing bases within the tRNA(Ala) domain during the course of evolution, an extended stem-loop structure has been created in BC1 RNA. The new structural domain might function, in part, as a putative binding site for protein(s) involved in dendritic transport of BC1 RNA within neurons. Furthermore, BC1 RNA contains, in addition to the extended stem-loop structure, an internal poly(A)-rich region that is supposedly single stranded, followed by a second smaller stem-loop structure at the 3' end of the RNA. The three distinct structural domains reflect evolutionary legacies of BC1 RNA.     

The BC200 RNA Gene and Its Neural Expression Are Conserved in Anthropoidea (Primates)

The gene encoding BC200 RNA arose from a monomeric Alu element. Subsequently, the RNA had been recruited or exapted into a function of the nervous system. Here we confirm the presence of the BC200 gene in several primate species among the Anthropoidea. The period following the divergence of New World monkeys and Old World monkeys from their common ancestor is characterized by a significantly higher substitution rate in the examined 5′ flanking region than in the BC200 RNA coding region itself. Furthermore, the conservation of CpG dimers in the RNA coding region (200 bp) is drastically increased compared to the 5′ flanking region (∼400 bp) over all 12 species examined. Finally, the brain-specific expression pattern of BC200 RNA and its presence as a ribonucleoprotein particle (RNP) are conserved in Old World and New World monkeys. Our studies indicate that the gene encoding BC200 RNA was created at least 35–55 million years ago and its presence, mode of expression, and association with protein(s) as an RNP are under selective pressure. Received: 1 December 1997 / Accepted: 3 June 1998