In vivo commitment to splicing in yeast involves the nucleotide upstream from the branch site conserved sequence and the Mud2 protein.

Pre-mRNA splicing is a stepwise nuclear process involving intron recognition and the assembly of the spliceosome followed by intron excision. We previously developed a pre-mRNA export assay that allows the discrimination between early steps of spliceosome formation and splicing per se. Here we present evidence that these two assays detect different biochemical defects for point mutations. Mutations at the 5' splice site lead to pre-mRNA export, whereas 3' splice site mutations do not. A genetic screen applied to mutants in the branch site region shows that all positions in the conserved TACTAAC sequence are important for intron recognition. An exhaustive analysis of pre-mRNA export and splicing defects of these mutants shows that the in vivo recognition of the branch site region does not involve the base pairing of U2 snRNA with the pre-mRNA. In addition, the nucleotide preceding the conserved TACTAAC sequence contributes to the recognition process. We show that a T residue at this position allows for optimal intron recognition and that in natural introns, this nucleotide is also used preferentially. Moreover, the Mud2 protein is involved in the recognition of this nucleotide, thus establishing a role for this factor in the in vivo splicing pathway.     

An RNA conformational change between the two chemical steps of group II self-splicing.

As for nuclear pre-mRNA introns, the splicing pathway of group II self-splicing introns proceeds by two successive transesterifications involving substrates with different chemical configurations. These two reactions have been proposed to be catalysed by two active sites, or alternatively by a single active site rearranging its components to accommodate the successive substrates. Here we show that the structural elements specific for the second splicing step are clustered in peripheral structures of domains II and VI. We show that these structures are not required for catalysis of the second chemical step but, instead, take part in a conformational change that occurs between the two catalytic steps. This rearrangement involves the formation of a tertiary contact between part of domain II and a GNRA tetraloop at the tip of domain VI. The fact that domain VI, which carries the branched structure, is involved in this structural rearrangement and the fact that modifications affecting the structures involved have almost no effect when splicing proceeds without branch formation, suggest that the conformational change results in the displacement of the first-step product out of the active site. These observations give further support to the existence of a single active site in group II introns.     

Metal ion catalysis during the exon-ligation step of nuclear pre-mRNA splicing: extending the parallels between the spliceosome and group II introns

Mechanistic analyses of nuclear pre-mRNA splicing by the spliceosome and group II intron self-splicing provide insight into both the catalytic strategies of splicing and the evolutionary relationships between the different splicing systems. We previously showed that 3'-sulfur substitution at the 3' splice site of a nuclear pre-mRNA has no effect on splicing. We now report that 3'-sulfur substitution at the 3' splice site of a nuclear pre-mRNA causes a switch in metal specificity when the second step of splicing is monitored using a bimolecular exon-ligation assay. This suggests that the spliceosome uses a catalytic metal ion to stabilize the 3'-oxyanion leaving group during the second step of splicing, as shown previously for the first step. The lack of a metal-specificity switch under cis splicing conditions indicates that a rate-limiting conformational change between the two steps of splicing may mask the subsequent chemical step and the metal-specificity switch. As the group II intron, a true ribozyme, uses identical catalytic strategies for splicing, our results strengthen the argument that the spliceosome is an RNA catalyst that shares a common molecular ancestor with group II introns.     

Accurate pre-mRNA splicing using a nuclear extract from Bombyx mori fat body

A cell-free pre-mRNA splicing system was developed from the nuclear extract of Bombyx mori fat bodies. The synthetic pre-mRNA from the cytoplasmic actin gene of B. mori (BmA3 ) was used as a substrate for in vitro splicing. The pre-mRNA was accurately spliced in the nuclear extract prepared from the fat body. Sequencing of the amplicon by RT-PCR revealed that the spliced site in vitro was identical to the site in vivo. We found that a part of the input capped pre-mRNA was accurately spliced after 2h of incubation. In addition, the RT-PCR analysis precisely mapped the branch point to an adenine located at 30 nucleotides before the 3' end of the first intron in BmA3. This system was a first example that differentiated tissue in insects yielded active extracts for in vitro splicing.     

Recognition of the spliceosomal branch site RNA helix on the basis of surface and electrostatic features

We have investigated electrostatic and surface features of an essential region of the catalytic core of the spliceosome, the eukaryotic precursor messenger (pre-m)RNA splicing apparatus. The nucleophile for the first of two splicing reactions is the 2′-hydroxyl (OH) of the ribose of a specific adenosine within the intron. During assembly of the spliceosome's catalytic core, this adenosine is positioned by pairing with a short region of the U2 small nuclear (sn)RNA to form the pre-mRNA branch site helix. The solution structure of the spliceosomal pre-mRNA branch site [Newby,M.I. and Greenbaum,N.L. (2002) Nature Struct. Biol., 9, 958–965] showed that a phylogenetically conserved pseudouridine (ψ) residue in the segment of U2 snRNA that pairs with the intron induces a markedly different structure compared with that of its unmodified counterpart. In order to achieve a more detailed understanding of the factors that contribute to recognition of the spliceosome's branch site helix and activation of the nucleophile for the first step of pre-mRNA splicing, we have calculated surface areas and electrostatic potentials of ψ-modified and unmodified branch site duplexes. There was no significant difference between the total accessible area or ratio of total polar:nonpolar groups between modified and unmodified duplexes. However, there was substantially greater exposure of nonpolar area of the adenine base, and less exposure of the 2′-OH, in the ψ-modified structure. Electrostatic potentials computed using a hybrid boundary element and finite difference nonlinear Poisson–Boltzmann approach [Boschitsch, A.H. and Fenley, M.O. (2004) J. Comput. Chem., 25, 935–955] revealed a region of exceptionally negative potential in the major groove surrounding the 2′-OH of the branch site adenosine. These surface and electrostatic features may contribute to the overall recognition of the pre-mRNA branch site region by other components of the splicing reaction.     

Repositioning of the reaction intermediate within the catalytic center of the spliceosome

Conformational change within the spliceosome is required between the first catalytic step of pre-mRNA splicing, when the branch site attacks the 5' splice site (SS), and the second step, when the 5' exon attacks the 3'SS. Little is known, however, about repositioning of the reaction substrates during this transition. Whereas the 5'SS is positioned for the first step by pairing with the invariant U6 snRNA-ACAGAG site, we demonstrate that this pairing interaction must be disrupted to allow transition to the second step. We propose that removal of the branch structure from the catalytic center is in competition with binding of the 3'SS substrate for the second step. Changes in the relative occupancy of first and second step substrates at the catalytic center alter efficiency of the two steps of splicing, allowing use of suboptimal intron sequences and thereby altering substrate selectivity.     

Sculpting of the spliceosomal branch site recognition motif by a conserved pseudouridine

Pairing of a consensus sequence of the precursor (pre)-mRNA intron with a short region of the U2 small nuclear (sn)RNA during assembly of the eukaryotic spliceosome results in formation of a complementary helix of seven base pairs with a single unpaired adenosine residue. The 2' OH of this adenosine, called the branch site, brings about nucleophilic attack at the pre-mRNA 5' splice site in the first step of splicing. Another feature of this pairing is the phylogenetic conservation of a pseudouridine (psi) residue in U2 snRNA nearly opposite the branch site. We show that the presence of this psi in the pre-mRNA branch-site helix of Saccharomyces cerevisiae induces a dramatically altered architectural landscape compared with that of its unmodified counterpart. The psi-induced structure places the nucleophile in an accessible position for the first step of splicing.     

Probing the structure and function of U2 snRNP with antisense oligonucleotides made of 2'-OMe RNA

We have used oligonucleotides made of 2'-OMe RNA to analyze the role of separate domains of U2 snRNA in the splicing process. We show that antisense 2'-OMe RNA oligonucleotides bind efficiently and specifically to U2 snRNP and demonstrate that masking of two separate regions of U2 snRNA can inhibit splicing by affecting different steps in the spliceosome assembly pathway. Masking the 5' terminus of U2 snRNA does not prevent U2 snRNP binding to pre-mRNA but blocks subsequent assembly of a functional spliceosome. By contrast, masking of U2 sequences complementary to the pre-mRNA branch site completely inhibits binding of pre-mRNA. Hybrid formation at the branch site complementary region also triggers a specific change which affects the 5' terminus of U2 snRNA.     

A spontaneous duplication in U6 spliceosomal RNA uncouples the early and late functions of the ACAGA element in vivo.

U6 RNA enters the spliceosome base paired with U4 RNA, but dissociates from U4 RNA before the catalytic steps of splicing. We have identified a cold-sensitive lethal mutation in U4 RNA (U4-cs1) that blocks the splicing pathway after U4/U6 complex formation, but before the first catalytic step of splicing. Remarkably, selection for suppressors of the cold-sensitive growth of the U4-cs1 strain yielded a tandem duplication of the highly conserved ACAGA sequence of U6 RNA (U6-Dup). The ACAGA sequence plays an essential role in spliceosome assembly and in the second catalytic step of pre-mRNA splicing; one or both of these roles involves direct base pairing to the pre-mRNA 5' splice site. In a U4-cs1/U6-Dup double-mutant strain grown at low temperature, the upstream ACAGA sequence of U6 RNA is required for suppression of the U4 mutation, whereas the downstream ACAGA sequence is required for other essential functions. Based on the sequence requirements for function of the upstream ACAGA element of U6-Dup, we propose that it pairs with the pre-mRNA 5' splice site during incorporation of the U4/U6 complex into the spliceosome and that the subsequent dissociation of U4 RNA exposes the downstream ACAGA sequence, which functions in the catalytic steps. The properties of this mutant U4/U6 complex provide compelling in vivo evidence that U6 RNA normally base pairs with the 5' splice site before disruption of its pairing with U4 RNA.     

Characterization of a U2AF-independent commitment complex (E') in the mammalian spliceosome assembly pathway

Early recognition of pre-mRNA during spliceosome assembly in mammals proceeds through the association of U1 small nuclear ribonucleoprotein particle (snRNP) with the 5' splice site as well as the interactions of the branch binding protein SF1 with the branch region and the U2 snRNP auxiliary factor U2AF with the polypyrimidine tract and 3' splice site. These factors, along with members of the SR protein family, direct the ATP-independent formation of the early (E) complex that commits the pre-mRNA to splicing. We report here the observation in U2AF-depleted HeLa nuclear extract of a distinct, ATP-independent complex designated E' which can be chased into E complex and itself commits a pre-mRNA to the splicing pathway. The E' complex is characterized by a U1 snRNA-5' splice site base pairing, which follows the actual commitment step, an interaction of SF1 with the branch region, and a close association of the 5' splice site with the branch region. These results demonstrate that both commitment to splicing and the early proximity of conserved sequences within pre-mRNA substrates can occur in a minimal complex lacking U2AF, which may function as a precursor to E complex in spliceosome assembly.     

Early organization of pre-mRNA during spliceosome assembly

Intron excision from precursor mRNAs (pre-mRNAs) in eukaryotes requires juxtaposition of reactive functionalities within the substrate at the heart of the spliceosome where the two chemical steps of splicing occur. Although a series of interactions between pre-mRNAs, pre-spliceosomal and spliceosomal factors is well established, the molecular mechanisms of splicing machinery assembly, as well as the temporal basis for organization of the substrate for splicing, remain poorly understood. Here we have used a directed hydroxyl radical probe tethered to pre-mRNA substrates to map the structure of the pre-mRNA substrate during the spliceosome assembly process. These studies indicate an early organization and proximation of conserved pre-mRNA sequences during spliceosome assembly/recruitment and suggest a mechanism for the formation of the final active site of the mature spliceosome.     

Short artificial hairpins sequester splicing signals and inhibit yeast pre-mRNA splicing.

To examine the stability of yeast (Saccharomyces cerevisiae) pre-mRNA structures, we inserted a series of small sequence elements that generated potential RNA hairpins at the 5' splice site and branch point regions. We analyzed spliceosome assembly and splicing in vitro as well as splicing and nuclear pre-mRNA retention in vivo. Surprisingly, the inhibition of in vivo splicing approximately paralleled that of in vitro splicing. Even a 6-nucleotide hairpin could be shown to inhibit splicing, and a 15-nucleotide hairpin gave rise to almost complete inhibition. The in vitro results indicate that hairpins that sequester the 5' splice site have a major effect on the early steps of spliceosome assembly, including U1 small nuclear ribonucleoprotein binding. The in vivo experiments lead to comparable conclusions as the sequestering hairpins apparently result in the transport of pre-mRNA to the cytoplasm. The observations are compared with previous data from both yeast and mammalian systems and suggest an important effect of pre-mRNA structure on in vivo splicing.     

Antisense probes containing 2-aminoadenosine allow efficient depletion of U5 snRNP from HeLa splicing extracts.

RNA duplexes containing the modified base 2-amino-adenine in place of adenine are stabilized through the formation of three hydrogen bonds in 2-amino A.U base pairs. Antisense 2'-O-alkyloligoribonucleotide probes incorporating 2-aminoadenosine are thus able to efficiently affinity select RNP particles which are otherwise inaccessible. This has allowed the efficient and specific depletion of U5 snRNP from HeLa cell nuclear splicing extracts. U5 snRNP is shown to be essential for spliceosome assembly and for both steps of pre-mRNA splicing. The absence of U5 snRNP prevents the stable association of U4/U6 but not U1 and U2 snRNPs with pre-mRNA.     

Nuclear pre-mRNA splicing in the fission yeast Schizosaccharomyces pombe strictly requires an intron-contained, conserved sequence element.

It has recently been argued that pre-mRNA splicing in the fission yeast Schizosaccharomyces pombe may be more similar to splicing in metazoan species than in the budding yeast Saccharomyces cerevisiae. In this report we show that, contrary to this assumption, the conserved sequence element 5'-CTPu APy-3' found in all S. pombe introns 6-18 nucleotides upstream of the 3' splice site is, like the TACTAAC box in S. cerevisiae, indispensable for efficient splicing. The conserved adenine residue of this sequence is used for branch formation and point mutations introduced into the CTPuAPy sequence abolish splicing and seem not to result in the recruitment of cryptic branch sites. We also show that an S. cerevisiae intron is correctly excised in S. pombe whereby the TACTAAC box is used in branch formation.     

Six novel genes necessary for pre-mRNA splicing in Saccharomyces cerevisiae.

We have identified six new genes whose products are necessary for the splicing of nuclear pre-mRNA in the yeast Saccharomyces cerevisiae. A collection of 426 temperature-sensitive yeast strains was generated by EMS mutagenesis. These mutants were screened for pre-mRNA splicing defects by an RNA gel blot assay, using the intron- containing CRY1 and ACT1 genes as hybridization probes. We identified 20 temperature-sensitive mutants defective in pre-mRNA splicing. Twelve appear to be allelic to the previously identified prp2, prp3, prp6, prp16/prp23, prp18, prp19 or prp26 mutations that cause defects in spliceosome assembly or the first or second step of splicing. One is allelic to SNR14 encoding U4 snRNA. Six new complementation groups, prp29-prp34, were identified. Each of these mutants accumulates unspliced pre-mRNA at 37 degrees C and thus is blocked in spliceosome assembly or early steps of pre-mRNA splicing before the first cleavage and ligation reaction. The prp29 mutation is suppressed by multicopy PRP2 and displays incomplete patterns of complementation with prp2 alleles, suggesting that the PRP29 gene product may interact with that of PRP2. There are now at least 42 different gene products, including the five spliceosomal snRNAs and 37 different proteins that are necessary for pre-mRNA splicing in Saccharomyces cerevisiae. However, the number of yeast genes identifiable by this approach has not yet been exhausted.     

Stepwise assembly of a pre-mRNA splicing complex requires U-snRNPs and specific intron sequences

We have investigated the early events of pre-mRNA splicing in vitro by sucrose gradient sedimentation analysis. Time course experiments revealed the assembly, in two steps, of a large (50S) pre-mRNA splicing complex, preceded by formation of two other complexes that sediment at approximately 22S and 35S. Pre-mRNA and the intermediates and products of the in vitro splicing reaction cosediment with the 50S complex, while only pre-mRNA is associated with the 22S and 35S complexes. No splicing is observed in the absence of a 50S complex. Formation of the 50S complex requires ATP, whereas formation of the 22S and 35S complexes does not. U-snRNPs are necessary for assembly of the 35S and the 50S complexes but not for assembly of the 22S complex. Analysis with mutant substrate RNAs demonstrated that a polypyrimidine stretch near the 3' splice site and an intact 5' splice site are absolutely required for splicing complex formation.     

Targeted snRNP depletion reveals an additional role for mammalian U1 snRNP in spliceosome assembly

HeLa cell nuclear splicing extracts have been prepared that are specifically and efficiently depleted of U1, U2, or U4/U6 snRNPs by antisense affinity chromatography using biotinylated 2'-OMe RNA oligonucleotides. Removal of each snRNP particle prevents pre-mRNA splicing but arrests spliceosome formation at different stages of assembly. Mixing extracts depleted for different snRNP particles restores formation of functional splicing complexes. Specific binding of factors to the 3' splice site region is still detected in snRNP-depleted extracts. Depletion of U1 snRNP impairs stable binding of U2 snRNP to the pre-mRNA branch site. This role of U1 snRNP in promoting stable preslicing complex formation is independent of the U1 snRNA-5' splice site interaction.     

Antibodies to hnRNP core proteins inhibit in vitro splicing of human beta-globin pre-mRNA.

In vitro splicing of human beta-globin pre-mRNA can be fully inhibited by treatment of the splicing extract with polyclonal antibodies against hnRNP core proteins prior to the addition of pre-mRNA. Inhibition of the first step in the splicing pathway, cleavage at the 5' splice site and lariat formation, requires more antibodies than inhibition of the second step, cleavage at the 3' splice site and exon ligation. The anti-hnRNP antibodies can also inhibit the splicing reaction after the formation of the active nucleoprotein splicing complex which is known to occur during the initial lag period. Thus, hnRNP core proteins appear to be present in the complex that performs pre-mRNA splicing.     

Recognition of the TACTAAC box during mRNA splicing in yeast involves base pairing to the U2-like snRNA

The U2 snRNP binds to the site of branch formation during splicing of mammalian pre-mRNA in vitro. In Saccharomyces cerevisiae the branch site is within the so-called TACTAAC box (UACUAAC box), an absolutely conserved intron sequence required for splicing. Based on the identification and sequence of a U2 analogue in yeast, a specific base pairing interaction between the UACUAAC box and a highly conserved region of this snRNA can be proposed. To test this hypothesis, we have taken advantage of two mutations constructed previously in the UACUAAC box of an actin-HIS4 fusion. These mutant strains were transformed with stable plasmids bearing U2-like snRNAs into which changes predicted to restore base pairing had been introduced. Allele-specific suppression of biological and biochemical phenotypes was observed in both cases. Recognition of the UACUAAC box thus relies, at least in part, on Watson-Crick base pairing with the yeast U2 analogue.