Abstract
The RNA helicase bad response to refrigeration 2 homolog (BRR2) is required for the activation of the spliceosome before the first catalytic step of RNA splicing. BRR2 represents a distinct subgroup of Ski2-like nucleic acid helicases whose members comprise tandem helicase cassettes. Only the N-terminal cassette of BRR2 is an active ATPase and can unwind substrate RNAs. The C-terminal cassette represents a pseudoenzyme that can stimulate RNA-related activities of the N-terminal cassette. However, the molecular mechanisms by which the C-terminal cassette modulates the activities of the N-terminal unit remain elusive. Here, we show that N- and C-terminal cassettes adopt vastly different relative orientations in a crystal structure of BRR2 in complex with an activating domain of the spliceosomal Prp8 protein at 2.4 Å resolution compared with the crystal structure of BRR2 alone. Likewise, inspection of BRR2 structures within spliceosomal complexes revealed that the cassettes occupy different relative positions and engage in different intercassette contacts during different splicing stages. Engineered disulfide bridges that locked the cassettes in two different relative orientations had opposite effects on the RNA-unwinding activity of the N-terminal cassette, with one configuration enhancing and the other configuration inhibiting RNA unwinding compared with the unconstrained protein. Moreover, we found that differences in relative positioning of the cassettes strongly influence RNA-stimulated ATP hydrolysis by the N-terminal cassette. Our results indicate that the inactive C-terminal cassette of BRR2 can both positively and negatively affect the activity of the N-terminal helicase unit from a distance.
Highlights
The RNA helicase bad response to refrigeration 2 homolog (BRR2) is required for the activation of the spliceosome before the first catalytic step of RNA splicing
To further explore the intercassette flexibility in human BRR2 (hBRR2), we determined the crystal structure of hBRR2 truncation 1 (hBRR2T1) in complex with a hPrp8 Jab1 domain lacking the inhibitory tail, which we had previously shown to be a strong activator of the hBRR2 helicase [29]
Crystals of the hBRR2T1-hJab1⌬Ctail complex diffracted to 2.4 Å resolution, and the structure was solved by molecular replacement using the structure coordinates of isolated hBRR2T1 (PDB entry 4F91) [34] and of the taildeleted hPrp8 Jab1 domain (PDB entry 4KIT) [29] (Table 1)
Summary
Fur Synchrotronstrahlung II; CC, C-terminal cassette; DSF, differential scanning fluorimetry; h, human; hBRR2T1-SS-linear, hBRR2T1-M641C/A1582C; hBRR2T1-SS-rotϩ, hBRR2T1-D534C/N1866C; NC, N-terminal cassette; NEM, N-ethylmaleimide; pre-mRNA, precursor messenger RNA; r.m.s.d., root mean square deviation; RNP, ribonucleoprotein complex; snRNP, small nuclear RNP; snRNA, small nuclear RNA; T1, truncation 1; TFA, trifluoroacetic acid; SF, superfamily; PDB, Protein Data Bank; TLC, thin layer chromatography; FAM, fluorescein amidite We present direct evidence for the ability of the two hBRR2 cassettes to occupy vastly different relative positions and engage in different intercassette interactions in isolation and during different stages of splicing Upon fixing two such relative arrangements by disulfide bridges, we observed opposite effects on RNA/ATP-related activities of the NC. Our results show that the CC can function as an intramolecular cofactor of the NC helicase, which, depending on its relative position and intercassette interactions, can exert positive or negative regulatory effects
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