The 5' stem-loop from human U4 snRNA adopts a novel conformation stabilized by G-C and G-U base pairs.

1H NMR and molecular modeling studies of the 5' stem-loop from human U4 snRNA were undertaken to determine the conformation of this stem-loop that is essential for spliceosome formation and pre-mRNA splicing. Sixteen of the 35 nucleotides of this stem-loop are in the loop region and inspection of the loop sequence revealed no decomposition into elements of secondary structure commonly found in other RNA stem-loops. An analysis of possible base pairing interactions for this stem-loop using the methods of Zuker revealed the lowest energy secondary structure for the 16 nucleotide loop consisted of four base pairs at the base of a non-canonical tetraloop (UUUA). This shorter stem-loop was joined to the nine base pair stem by two A residues on the 5' side and a single bulged A on the 3' side. Both stems also had bulged A residues. 1H NMR experiments performed on solutions of the 35 mer stem-loop, the stem region, and the loop region confirmed the 35 mer adopted this secondary structure in solution. A 3D molecular model of this structure consistent with the NMR data was generated to assist in visualization of this novel structure.