Composition and three-dimensional EM structure of double affinity-purified, human prespliceosomal A complexes.

Little is known about the higher-order structure of prespliceosomal A complexes, in which pairing of the pre-mRNA's splice sites occurs. Here, human A complexes were isolated under physiological conditions by double-affinity selection. Purified complexes contained stoichiometric amounts of U1, U2 and pre-mRNA, and crosslinking studies indicated that these form concomitant base pairing interactions with one another. A complexes contained nearly all U1 and U2 proteins plus approximately 50 non-snRNP proteins. Unexpectedly, proteins of the hPrp19/CDC5 complex were also detected, even when A complexes were formed in the absence of U4/U6 snRNPs, demonstrating that they associate independent of the tri-snRNP. Double-affinity purification yielded structurally homogeneous A complexes as evidenced by electron microscopy, and allowed for the first time the generation of a three-dimensional structure. A complexes possess an asymmetric shape (approximately 260 x 200 x 195 angstroms) and contain a main body with various protruding elements, including a head-like domain and foot-like protrusions. Complexes isolated here are well suited for in vitro assembly studies to determine factor requirements for the A to B complex transition.

Functional spliceosomal A complexes can be assembled in vitro in the absence of a penta-snRNP.

Two different models currently exist for the assembly pathway of the spliceosome, namely, the traditional model, in which spliceosomal snRNPs associate in a stepwise, ordered manner with the pre-mRNA, and the holospliceosome model, in which all spliceosomal snRNPs preassemble into a penta-snRNP complex. Here we have tested whether the spliceosomal A complex, which contains solely U1 and U2 snRNPs bound to pre-mRNA, is a functional, bona fide assembly intermediate. Significantly, A complexes affinity-purified from nuclear extract depleted of U4/U6 snRNPs (and thus unable to form a penta-snRNP) supported pre-mRNA splicing in nuclear extract depleted of U2 snRNPs, whereas naked pre-mRNA did not. Mixing experiments with purified A complexes and naked pre-mRNA additionally confirmed that under these conditions, A complexes do not form de novo. Thus, our studies demonstrate that holospliceosome formation is not a prerequisite for generating catalytically active spliceosomes and that, at least in vitro, the U1 and U2 snRNPs can functionally associate with the pre-mRNA, prior to and independent of the tri-snRNP. The ability to isolate functional spliceosomal A complexes paves the way to study in detail subsequent spliceosome assembly steps using purified components.

Protein composition and electron microscopy structure of affinity-purified human spliceosomal B complexes isolated under physiological conditions.

The spliceosomal B complex is the substrate that undergoes catalytic activation leading to catalysis of pre-mRNA splicing. Previous characterization of this complex was performed in the presence of heparin, which dissociates less stably associated components. To obtain a more comprehensive inventory of the B complex proteome, we isolated this complex under low-stringency conditions using two independent methods. MS2 affinity-selected B complexes supported splicing when incubated in nuclear extract depleted of snRNPs. Mass spectrometry identified over 110 proteins in both independently purified B complex preparations, including approximately 50 non-snRNP proteins not previously found in the spliceosomal A complex. Unexpectedly, the heteromeric hPrp19/CDC5 complex and 10 additional hPrp19/CDC5-related proteins were detected, indicating that they are recruited prior to spliceosome activation. Electron microscopy studies revealed that MS2 affinity-selected B complexes exhibit a rhombic shape with a maximum dimension of 420 A and are structurally more homogeneous than B complexes treated with heparin. These data provide novel insights into the composition and structure of the spliceosome just prior to its catalytic activation and suggest a potential role in activation for proteins recruited at this stage. Furthermore, the spliceosomal complexes isolated here are well suited for complementation studies with purified proteins to dissect factor requirements for spliceosome activation and splicing catalysis.

U2 snRNA-protein contacts in purified human 17S U2 snRNPs and in spliceosomal A and B complexes.

The 17S U2 snRNP plays an essential role in branch point selection and catalysis during pre-mRNA splicing. Much remains to be learned about the molecular architecture of the U2 snRNP, including which proteins contact the functionally important 5' end of the U2 snRNA. Here, RNA-protein interactions within immunoaffinity-purified human 17S U2 snRNPs were analyzed by lead(II)-induced RNA cleavage and UV cross-linking. Contacts between the U2 snRNA and SF3a60, SF3b49, SF3b14a/p14 and SmG and SmB were detected. SF3b49 appears to make multiple contacts, interacting with the 5' end of U2 and nucleotides in loops I and IIb. SF3a60 also contacted different regions of the U2 snRNA, including the base of stem-loop I and a bulge in stem-loop III. Consistent with it contacting the pre-mRNA branch point adenosine, SF3b14a/p14 interacted with the U2 snRNA near the region that base pairs with the branch point sequence. A comparison of U2 cross-linking patterns obtained with 17S U2 snRNP versus purified spliceosomal A and B complexes revealed that RNA-protein interactions with stem-loop I and the branch site-interacting region of U2 are dynamic. These studies provide important insights into the molecular architecture of 17S U2 snRNPs and reveal U2 snRNP remodeling events during spliceosome assembly.