Project description:The RNase III enzyme, DICER, is instrumental in the production of small RNAs, including miRNAs and siRNAs, by cleaving their precursors, such as pre-miRNAs, shRNAs, and long duplex RNAs. Utilizing High-throughput (HT) cleavage assays, our study delves into the cleavage activity of DICER. We challenge the widely accepted 2-nt loop counting rule in the previous study, revealing a divergent mechanism, the bipartite base pairing rule. This rule directs DICER's cleavage sites via the RNase III domain. Moreover, we demystify the recognition mechanism of the previously identified YCR motif. Building on this understanding, a secondary YCR motif that also influences DICER's cleavage sites has been discovered. We also address a long-debated issue concerning DICER's cleavage sites on long stem RNAs, such as pre-siRNAs or long shRNAs/pre-miRNAs. Our study shows that the dsRBD plays a crucial role in determining the cleavage sites of DICER in long-stem RNAs. In sum, our research provides a comprehensive understanding of several fundamental DICER mechanisms, challenging the long-standing model of the loop counting rule. This newfound knowledge reshapes our understanding of DICER's mechanisms, providing a robust foundation for future studies investigating the vast number of DICER mutations linked to various diseases.

Project description:The RNase III enzyme, DICER, is instrumental in the production of small RNAs, including miRNAs and siRNAs, by cleaving their precursors, such as pre-miRNAs, shRNAs, and long duplex RNAs. Utilizing High-throughput (HT) cleavage assays, our study delves into the cleavage activity of DICER. We challenge the widely accepted 2-nt loop counting rule in the previous study, revealing a divergent mechanism, the bipartite base pairing rule. This rule directs DICER's cleavage sites via the RNase III domain. Moreover, we demystify the recognition mechanism of the previously identified YCR motif. Building on this understanding, a secondary YCR motif that also influences DICER's cleavage sites has been discovered. We also address a long-debated issue concerning DICER's cleavage sites on long stem RNAs, such as pre-siRNAs or long shRNAs/pre-miRNAs. Our study shows that the dsRBD plays a crucial role in determining the cleavage sites of DICER in long-stem RNAs. In sum, our research provides a comprehensive understanding of several fundamental DICER mechanisms, challenging the long-standing model of the loop counting rule. This newfound knowledge reshapes our understanding of DICER's mechanisms, providing a robust foundation for future studies investigating the vast number of DICER mutations linked to various diseases.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The RNase III enzyme, DICER, is instrumental in the production of small RNAs, including miRNAs and siRNAs, by cleaving their precursors, such as pre-miRNAs, shRNAs, and long duplex RNAs. Utilizing High-throughput (HT) cleavage assays, our study delves into the cleavage activity of DICER. We challenge the widely accepted 2-nt loop counting rule in the previous study, revealing a divergent mechanism, the bipartite base pairing rule. This rule directs DICER's cleavage sites via the RNase III domain. Moreover, we demystify the recognition mechanism of the previously identified YCR motif. Building on this understanding, a secondary YCR motif that also influences DICER's cleavage sites has been discovered. We also address a long-debated issue concerning DICER's cleavage sites on long stem RNAs, such as pre-siRNAs or long shRNAs/pre-miRNAs. Our study shows that the dsRBD plays a crucial role in determining the cleavage sites of DICER in long-stem RNAs. In sum, our research provides a comprehensive understanding of several fundamental DICER mechanisms, challenging the long-standing model of the loop counting rule. This newfound knowledge reshapes our understanding of DICER's mechanisms, providing a robust foundation for future studies investigating the vast number of DICER mutations linked to various diseases.

Project description:The catalytic activity of human cytidine deaminase APOBEC3B (A3B) has been correlated with kataegic mutational patterns within multiple cancer types. The molecular basis of how the N-terminal non-catalytic CD1 regulates the catalytic activity and consequently, biological function of A3B remains relatively unknown. Here, we report the crystal structure of a soluble human A3B-CD1 variant and delineate several structural elements of CD1 involved in molecular assembly, nucleic acid interactions and catalytic regulation of A3B. We show that (i) A3B expressed in human cells exists in hypoactive high-molecular-weight (HMW) complexes, which can be activated without apparent dissociation into low-molecular-weight (LMW) species after RNase A treatment. (ii) Multiple surface hydrophobic residues of CD1 mediate the HMW complex assembly and affect the catalytic activity, including one tryptophan residue W127 that likely acts through regulating nucleic acid binding. (iii) One of the highly positively charged surfaces on CD1 is involved in RNA-dependent attenuation of A3B catalysis. (iv) Surface hydrophobic residues of CD1 are involved in heterogeneous nuclear ribonucleoproteins (hnRNPs) binding to A3B. The structural and biochemical insights described here suggest that unique structural features on CD1 regulate the molecular assembly and catalytic activity of A3B through distinct mechanisms.

Project description: Not available

Project description:The selective coupling of G-protein-coupled receptors (GPCRs) to specific G proteins is critical to trigger the appropriate physiological response. However, the determinants of selective binding have remained elusive. Here we reveal the existence of a selectivity barcode (that is, patterns of amino acids) on each of the 16 human G proteins that is recognized by distinct regions on the approximately 800 human receptors. Although universally conserved positions in the barcode allow the receptors to bind and activate G proteins in a similar manner, different receptors recognize the unique positions of the G-protein barcode through distinct residues, like multiple keys (receptors) opening the same lock (G protein) using non-identical cuts. Considering the evolutionary history of GPCRs allows the identification of these selectivity-determining residues. These findings lay the foundation for understanding the molecular basis of coupling selectivity within individual receptors and G proteins.

Project description:Determinants of selectivity in the dicing mechanism

Project description:Determinants of selectivity in the dicing mechanism

Project description:Determinants of selectivity in the dicing mechanism