Structure of phosphorylated SF1 bound to U2AF65 in an essential splicing factor complex.

The essential splicing factors U2AF65 and SF1 cooperatively bind consensus sequences at the 3' end of introns. Phosphorylation of SF1 on a highly conserved "SPSP" motif enhances its interaction with U2AF65 and the pre-mRNA. Here, we reveal that phosphorylation induces essential conformational changes in SF1 and in the SF1/U2AF65/3' splice site complex. Crystal structures of the phosphorylated (P)SF1 domain bound to the C-terminal domain of U2AF65 at 2.29 Å resolution and of the unphosphorylated SF1 domain at 2.48 Å resolution demonstrate that phosphorylation induces a disorder-to-order transition within a previously unknown SF1/U2AF65 interface. We find by small-angle X-ray scattering that the local folding of the SPSP motif transduces into global conformational changes in the nearly full-length (P)SF1/U2AF65/3' splice site assembly. We further determine that SPSP phosphorylation and the SF1/U2AF65 interface are essential in vivo. These results offer a structural prototype for phosphorylation-dependent control of pre-mRNA splicing factors.

PcrA-mediated disruption of RecA nucleoprotein filaments--essential role of the ATPase activity of RecA.

The essential DNA helicase, PcrA, regulates recombination by displacing the recombinase RecA from the DNA. The nucleotide-bound state of RecA determines the stability of its nucleoprotein filaments. Using single-molecule fluorescence approaches, we demonstrate that RecA displacement by a translocating PcrA requires the ATPase activity of the recombinase. We also show that in a 'head-on collision' between a polymerizing RecA filament and a translocating PcrA, the RecA K72R ATPase mutant, but not wild-type RecA, arrests helicase translocation. Our findings demonstrate that translocation of PcrA is not sufficient to displace RecA from the DNA and assigns an essential role for the ATPase activity of RecA in helicase-mediated disruption of its filaments.

Alternative conformations at the RNA-binding surface of the N-terminal U2AF(65) RNA recognition motif.

The essential pre-mRNA splicing factor, U2 auxiliary factor 65KD (U2AF(65)) recognizes the polypyrimidine tract (Py-tract) consensus sequence of the pre-mRNA using two RNA recognition motifs (RRMs), the most prevalent class of eukaryotic RNA-binding domain. The Py-tracts of higher eukaryotic pre-mRNAs are often interrupted with purines, yet U2AF(65) must identify these degenerate Py-tracts for accurate pre-mRNA splicing. Previously, the structure of a U2AF(65) variant in complex with poly(U) RNA suggested that rearrangement of flexible side-chains or bound water molecules may contribute to degenerate Py-tract recognition by U2AF(65). Here, the X-ray structure of the N-terminal RRM domain of U2AF(65) (RRM1) is described at 1.47 A resolution in the absence of RNA. Notably, RNA-binding by U2AF(65) selectively stabilizes pre-existing alternative conformations of three side-chains located at the RNA interface (Arg150, Lys225, and Arg227). Additionally, a flexible loop connecting the beta2/beta3 strands undergoes a conformational change to interact with the RNA. These pre-existing alternative conformations may contribute to the ability of U2AF(65) to recognize a variety of Py-tract sequences. This rare, high-resolution view of an important member of the RRM class of RNA-binding domains highlights the role of alternative side-chain conformations in RNA recognition.

Multiple U2AF65 binding sites within SF3b155: thermodynamic and spectroscopic characterization of protein-protein interactions among pre-mRNA splicing factors.

Essential, protein-protein complexes between the large subunit of the U2 small nuclear RNA auxiliary factor (U2AF65) with the splicing factor 1 (SF1) or the spliceosomal component SF3b155 are exchanged during a critical, ATP-dependent step of pre-mRNA splicing. Both SF1 and the N-terminal domain of SF3b155 interact with a U2AF homology motif (UHM) of U2AF65. SF3b155 contains seven tryptophan-containing sites with sequence similarity to the previously characterized U2AF65-binding domain of SF1. We show that the SF3b155 domain lacks detectable secondary structure using circular dichroism spectroscopy, and demonstrate that five of the tryptophan-containing SF3b155 sites are recognized by the U2AF65-UHM using intrinsic tryptophan fluorescence experiments with SF3b155 variants. When compared with SF1, similar spectral shifts and sequence requirements indicate that U2AF65 interactions with each of the SF3b155 sites are similar to the minimal SF1 site. However, thermodynamic comparison of SF1 or SF3b155 proteins with minimal peptides demonstrates that formation the SF1/U2AF65 complex is likely to affect regions of SF1 beyond the previously identified, linear interaction site, in a remarkably distinct manner from the local U2AF65 binding mode of SF3b155. Furthermore, the complex of the SF1/U2AF65 interacting domains is stabilized by 3.3 kcal mol-1 relative to the complex of the SF3b155/U2AF65 interacting domains, consistent with the need for ATP hydrolysis to drive exchange of these partners during pre-mRNA splicing. We propose that the multiple U2AF65 binding sites within SF3b155 regulate conformational rearrangements during spliceosome assembly. Comparison of the SF3b155 sites defines an (R/K)nXRW(DE) consensus sequence for predicting U2AF65-UHM ligands from genomic sequences, where parentheses denote residues that contribute to, but are not required for binding.

Site selection in tandem arrays of metal-binding domains.

The metal binding properties of peptides corresponding to metal-binding sites spanning regions that normally function as linkers in tandem arrays of metal-binding domain-containing proteins were examined. For a peptide with two His residues from one TFIIIA-like zinc finger domain, a canonical TFIIIA-like linker, and two Cys residues from an adjacent zinc domain, the dissociation constant for the 1:1 peptide to cobalt(II) was found to be 15 +/- 10 microM, compared with 60 nM for the corresponding zinc finger domains themselves. Peptides overlapping two sets of metal-binding domains from human TRAF (tumor necrosis factor receptor-associated factor) proteins were examined. In one case, the affinity of the presumed metal-binding domain and that for the linker region were comparable, while in the second case, the affinity of the linker peptide was higher than that for the corresponding presumed metal-binding domain peptide. These studies revealed that cobalt(II) affinities in the micromolar range can occur even for peptides that do not correspond to natural zinc-binding domains and that the degree of distinction between authentic metal-binding domains and the corresponding linker-spanning peptides may be modest, at least for single domain peptide models.