Small sequence insertions within the branch point region dictate alternative sites of lariat formation in a yeast intron.

The problem of intron recognition in S. cerevisiae appears to be in part solved by the strong conservation of intron encoded splicing signals, in particular the 5' GUAUGU and the branch point UACUAAC which interact via base pairing with the RNA components of U1 and U2 snRNPs respectively. Nevertheless, the mere presence of such signals is insufficient for splicing to occur. In the S. cerevisiae ACT1 intron, a silent UACUAAC-like sequence (UACUAAG) is located 7 nucleotides upstream of the canonical branch point signal. In order to investigate whether other factors, in addition to the U2-UACUAAC base-pair interactions, affect branch point selection in yeast, we created a cis-competition assay by converting the UACUAAG to a strong branch point signal (UACUAAC). If simply having a canonical UACUAAC sequence were sufficient for lariat formation, a 1:1 ratio in usage of the two signals should have been observed. In this double branch point intron, however, the downstream UACUAAC is utilized preferentially (4:1). Results obtained from the analyses of numerous sequence variants flanking the two UACUAAC sequences, demonstrate that non-conserved sequences in the branch point region are able to define lariat formation. Consequently, we conclude that U2 base-pairing is not the only requirement determining branch point selection in yeast, and local structure in the vicinity of the branch point could play a critical role in its recognition.     

Cooperative interaction of branch signals in the actin intron of Saccharomyces cerevisiae.

In pre-mRNA splicing, specific spliceosomal components recognize key intron sequences, but the mechanisms by which splice sites are selected arenot completely understood. In the Saccharomyces cerevisiae actin intron a silent branch point-like sequence (UACUAAG) is located 7 nt upstream of the canonical sequence. Mutation of the canonicalUACUAAC sequence to UAAUAAC reduces utilization of this signal and activates the cryptic UACUAAG. Splicing-dependent beta-galactosidase assays have shown that these two splice signals cooperate to enhance splicing. Analyses of several variants of this double branch point intron demonstrate that the upstream UACUAAG sequence significantly increases usage of the UAAUAAC as a site of lariat formation. This activation is sequence-specific and unidirectional. However the ability of the UACUAAG signal to activate the downstream branch point is dependent on the presence of a short non-conserved sequence located a few nucleotides upstream of the UACUAAG. Mutation of this sequence leads to the disappearance of the cooperative interactions between the two branch signals. Our results show that this non-conserved sequence and the UACUAAG signal must both be present to achieve activation of the downstream branch point and suggest that a specific structure may be necessary to allow efficient recognition of the UAAUAAC.     

Conserved putative signals in 3' intron junctions in rodents

Several 3' splice signals are known todate. At the 3' splice site an AG doublet is frequently found. Just upstream of the splice site there is a string of 6-11 pyrimidines. More recently it has been found that one of the stages in the splicing process involves formation of a lariat, in which the 5' end of the intron forms a 2'-5' branch with an A residue located 18-37 nucleotides upstream of the 3' splice site. The branching-point consensus is weakly defined and consists of the sequence YNYTRAY, where Y is a pyrimidine, R a purine and N any base. The A in the sixth position is the one with which branching occurs. Here we present the results of extensive searches for additional putative signals around the branching-point consensus and the 3' splice site in rodent nuclear precursor mRNAs. The signals obtained for the over 370 rodent introns are compared with those found in a larger eukaryotic sample containing over 900 nuclear pre-mRNA introns. Of particular interest are GGGA and CCCA. In both analyses GGGA occurs about 60 nucleotides upstream and CCCA is found 3-40 nucleotides downstream from the 3' splice site. A model explaining some of the putative signals discussed here is also proposed. This model involves formation of alternate stem-loop structures around the branching point and 3' splice site. Such signals and structures can possibly aid in protein or nucleoprotein branching point and splice site recognition.     

Conserved Putative Signals in 3′ Intron Junctions in Rodents

Abstract

Several 3′ splice signals are known todate. At the 3′ splice site an AG doublet is frequently found. Just upstream of the splice site there is a string of 6–11 pyrimidines. More recently it has been found that one of the stages in the splicing process involves formation of a lariat, in which the 5′ end of the intron forms a 2′-5′ branch with an A residue located 18–37 nucleotides upstream of the 3′ splice site. The branching-point consensus is weakly defined and consists of the sequence YNYTRAY, where Y is a pyrimidine, R a purine and N any base. The A in the sixth position is the one with which branching occurs. Here we present the results of extensive searches for additional putative signals around the branching-point consensus and the 3′ splice site in rodent nuclear precursor mRNAs. The signals obtained for the over 370 rodent introns are compared with those found in a larger eukaryotic sample containing over 900 nuclear pre-mRNA introns. Of particular interest are GGGA and CCCA In both analyses GGGA occurs about 60 nucleotides upstream and CCCA is found 3–40 nucleotides downstream from the 3′ splice site. A model explaining some of the putative signals discussed here is also proposed. This model involves formation of alternate stem-loop structures around the branching point and 3′ splice site. Such signals and structures can possibly aid in protein or nucleoprotein branching point and splice site recognition.     

Self-splicing of group II introns in vitro: lariat formation and 3' splice site selection in mutant RNAs

Deletion or substitution of the branch A residue in group II intron bl1 significantly reduces splicing activity; yet, residual exon ligation is correct, and lariats have their branch points at the normal distance from the 3' end of the intron. Mutations in the sequence facing the branch point also allow residual lariat formation; however, free 3' exons are generated with false 5' termini, all of which are within a UCACA consensus sequence located upstream or downstream of the normal 3' splice site. These results indicate that both the conserved 3' splice site APy and the spatial arrangements in stem 6 are crucial for correct 3' splice site selection.     

Sequence dependent conformation and local geometry of the conserved branch site sequence element d(TpApCpTpApApC), essential for yeast mRNA splicing, deduced from high resolution 1H-NMR

The conserved sequence element and branch site splice signal d(TpApCpTpApApC) has been synthesized by a solid phase procedure. All the non-exchangeable protons have been assigned using a combination of one-dimensional and two-dimensional 1H-NMR analytical procedures. On the basis of the low NOE intensities in the 1D-NOE and NOESY experiments, the heptamer exists in solution as a random coil. The deoxyribose rings towards the 5' terminus exist predominantly in the S form (2'-endo-3'-exo) while residues on or adjacent to the 2' branch site in the eventual lariat structure [A(6) of TACTAAC] show more N-character (3'endo-2'-exo). In addition unique propeller twisting at contiguous AT base pairs in the consensus 5'-splice site occurs in the region in which there is partial complementarity with the branch splice signal TACTAAC. These subtle structural features, if carried over to the corresponding RNA, may have significance either as a recognition signals or for stereochemical reasons in the formation of the lariat intermediate in the maturation process of mRNA.     

Bimolecular exon ligation by the human spliceosome bypasses early 3' splice site AG recognition and requires NTP hydrolysis

Here we report further characterization of an in vitro assay system for exon ligation by the human spliceosome in which the 3' splice site AG is supplied by a different RNA molecule than that containing the 5' splice and branch sites. By varying the time during splicing reactions when the 3' splice site AG is made available to the splicing machinery, we show that AG recognition need not occur until after lariat formation. Thus an early AG recognition event required for spliceosome formation and lariat formation on some mammalian introns is not required for exon ligation. Depletion/add-back studies and cold competitor challenge experiments reveal that commitment of a 3' splice site AG to exon ligation requires NTP hydrolysis. Because it both physically and kinetically uncouples exon ligation from spliceosome assembly and lariat formation, the bimolecular system will be a valuable tool for further mechanistic analysis of the second step of splicing.     

Mutation of putative branchpoint consensus sequences in plant introns reduces splicing efficiency

Intron lariat formation between the 5' end of an intron and a branchpoint adenosine is a fundamental aspect of the first step in animal and yeast nuclear pre-mRNA splicing. Despite similarities in intron sequence requirements and the components of splicing, differences exist between the splicing of plant and vertebrate introns. The identification of AU-rich sequences as major functional elements in plant introns and the demonstration that a branchpoint consensus sequence was not required for splicing have led to the suggestion that the transition from AU-rich intron to GC-rich exon is a major potential signal by which plant pre-mRNA splice sites are recognized. The role of putative branchpoint sequences as an internal signal in plant intron recognition/definition has been re-examined. Single nucleotide mutations in putative branchpoint adenosines contained within CUNAN sequences in four different plant introns all significantly reduced splicing efficiency. These results provide the most direct evidence to date for preferred branchpoint sequences being required for the efficient splicing of at least some plant introns in addition to the important role played by AU sequences in dicot intron recognition. The observed patterns of 3' splice site selection in the introns studied are consistent with the scanning model described for animal intron 3' splice site selection. It is suggested that, despite the clear importance of AU sequences for plant intron splicing, the fundamental processes of splice site selection and splicing in plants are similar to those in animals.     

Branch point identification and sequence requirements for intron splicing in Plasmodium falciparum

Splicing of mRNA is an ancient and evolutionarily conserved process in eukaryotic organisms, but intron-exon structures vary. Plasmodium falciparum has an extreme AT nucleotide bias (>80%), providing a unique opportunity to investigate how evolutionary forces have acted on intron structures. In this study, we developed an in vivo luciferase reporter splicing assay and employed it in combination with lariat isolation and sequencing to characterize 5' and 3' splicing requirements and experimentally determine the intron branch point in P. falciparum. This analysis indicates that P. falciparum mRNAs have canonical 5' and 3' splice sites. However, the 5' consensus motif is weakly conserved and tolerates nucleotide substitution, including the fifth nucleotide in the intron, which is more typically a G nucleotide in most eukaryotes. In comparison, the 3' splice site has a strong eukaryotic consensus sequence and adjacent polypyrimidine tract. In four different P. falciparum pre-mRNAs, multiple branch points per intron were detected, with some at U instead of the typical A residue. A weak branch point consensus was detected among 18 identified branch points. This analysis indicates that P. falciparum retains many consensus eukaryotic splice site features, despite having an extreme codon bias, and possesses flexibility in branch point nucleophilic attack.     

Functional analysis of the polypyrimidine tract in pre-mRNA splicing.

The polypyrimidine tract is one of the important cis-acting sequence elements directing intron removal in pre-mRNA splicing. Progressive deletions of the polypyrimidine tract have been found to abolish correct lariat formation, spliceosome assembly and splicing. In addition, the polypyrimidine tract can alter 3'-splice site selection by promoting alternative branch site selection. However, there appears to be great flexibility in the specific sequence of a given tract. Not only the optimal composition of the polypyrimidine tract, but also the role of the tract in introns with no apparent polypyrimidine tracts or where changes in the tract are apparently harmless are uncertain. Accordingly, we have designed a series of cis-competition splicing constructs to test the functional competitive efficiency of a variety of systematically mutated polypyrimidine tracts. An RT/PCR assay was used to detect spliced product formation as a result of differential branch point selection dependent on direct competition between two opposing polypyrimidine tracts. We found that pyrimidine tracts containing 11 continuous uridines are the strongest pyrimidine tracts. In such cases, the position of the uridine stretch between the branch point and 3'-splice site AG is unimportant. In contrast, decreasing the continuous uridine stretch to five or six residues requires that the tract be located immediately adjacent to the AG for optimal competitive efficiency. The block to splicing with decreasing polypyrimidine tract strength is primarily prior to the first step of splicing. While lengthy continuous uridine tracts are the most competitive, tracts with decreased numbers of consecutive uridines and even tracts with alternating purine/pyrimidine residues can still function to promote branch point selection, but are far less effective competitors in 3'-splice site selection assays.