Piwi proteins are germline-specific Argonautes that associate with small RNAs called Piwi-interacting RNAs (piRNAs), and together with these RNAs are
responsible for transposon silencing and regulation. The PAZ domain of Argonaute proteins recognizes the 3′-end of the RNA, which in the case of piRNAs is invariably modified with a 2′-O-methyl group. The Miwi-PAZ domain binds the last 6 nucleotides of piRNAs without any sequence specificity. The 3′-end ribose is recognized by hydrogen bonds involving the RNA 3′-OH and 2′-O and the carbonyl and amide groups of M382, Bleomycin concentration while the 2′-O-methyl interacts with the M382-CH3ε ( Fig. 1b). Side chains of the β-barrel contact the nucleotides at position −1 to −5 from the 3′-end either through electrostatic interactions with the phosphate backbone or through hydrophobic interactions with the RNA riboses and bases ( Fig. 1a and c). These contacts are sequence independent throughout the entire RNA and explain well the preference of the Miwi-PAZ domain for single-stranded flexible RNAs (KD = 0.9 μM), which can present both bases and riboses to the hydrophobic protein surface,
rather than double-stranded RNAs (KD = 55 μM), which would be accessible only through their charged backbone [13] and [14]. Contemporarily to our work, X-ray crystallography yielded the structure of the Hiwi1-PAZ domain bound to a piRNA mimic [15]. To allow for crystallization, this study used a self-complementary 12 base-pair RNA with 2 nucleotides overhang; this RNA construct www.selleckchem.com/products/AC-220.html is not the physiological target of piRNA-binding domains but rather resembles the secondary structure
of siRNAs. In the crystallographic structure the recognition of the 3′-end nucleotide is similar to that in our NMR structure; however, starting from Vitamin B12 nucleotide −2 from the 3′-end, the artificial double stranded RNA moves away from the protein and does not contact the surface of the β-barrel (Fig. 1d). Crystal packing forces between two RNA duplexes in the unit cell stabilize this structure. Clearly, the absence of contacts between the piRNA nucleotides −2 to −5 and the β-barrel surface is in disagreement with NMR chemical shifts deviations and NOEs, with previous structures of PAZ-domains−RNA complexes and with the conservation of amino acids of the β-barrel surface in Piwi proteins. This example demonstrates the importance of using solution-state NMR to study RNP complexes, in particular those where the flexible RNA is not completely covered by proteins; in crystallographic structures, crystal packing forces together with the use of artificial RNA constructs can lead to distortions in the RNA conformation. Excellent reviews of the NMR methodology to study RNP complexes, together with examples, can be found in [16] and [17].