In vivo analysis of plant pre-mRNA splicing using an autonomously replicating vector

Interactions of SR45, an SR-like protein, with spliceosomal proteins and an intronic sequence: insights into regulated splicing

SR45 is a serine/arginine-rich (SR)-like protein with two arginine/serine-rich (RS) domains. We have previously shown that SR45 regulates alternative splicing (AS) by differential selection of 5' and 3' splice sites. However, it is unknown how SR45 regulates AS. To gain mechanistic insights into the roles of SR45 in splicing, we screened a yeast two-hybrid library with SR45. This screening resulted in the isolation of two spliceosomal proteins, U1-70K and U2AF(35) b that are known to function in 5' and 3' splice site selection, respectively. This screen not only confirmed our prior observation that U1-70K and SR45 interact, but also helped to identify an additional interacting partner (U2AF(35) ). In vitro and in vivo analyses revealed an interaction of SR45 with both paralogs of U2AF(35) . Furthermore, we show that the RS1 and RS2 domains of SR45, and not the RNA recognition motif (RRM) domain, associate independently with both U2AF(35) proteins. Interaction studies among U2AF(35) paralogs and between U2AF(35) and U1-70K revealed that U2AF(35) can form homo- or heterodimers and that U2AF(35) proteins can associate with U1-70K. Using RNA probes from SR30 intron 10, whose splicing is altered in the sr45 mutant, we show that SR45 and U2AF(35) b bind to different parts of the intron, with a binding site for SR45 in the 5' region and two binding regions, each ending with a known 3' splice site, for U2AF(35) b. These results suggest that SR45 recruits U1snRNP and U2AF to 5' and 3' splice sites, respectively, by interacting with pre-mRNA, U1-70K and U2AF(35) and modulates AS.

Splice site requirements and switches in plants

Intron sequences in nuclear pre-mRNAs are excised with either the major U2 snRNA-dependent spliceosomal pathway or the minor U12 snRNA-dependent spliceosomal pathway that exist in most eukaryotic organisms. While the predominant dinucleotides bordering each of these types of introns and the catalytic mechanism used in their excision are conserved in plants and animals, several features aiding in the recognition of plant introns are distinct from those in animals and yeast. Along with their short length, high AU content and high variation in their 5' and 3' splice sites and branchpoint consensus sequences are the most prominent characteristics of plant introns. Detailed surveys of site-directed mutant introns tested in vivo and chemically induced and naturally mutant introns analyzed in planta emphasize the effects of changing individual nucleotides in these splice site consensus sequences and highlight a number of noncanonical dinucleotides that are functional in plant systems.

Independent expression of Rep and RepA and their roles in regulating bean yellow dwarf virus replication

Bean yellow dwarf virus (BeYDV) is a mastrevirus specific for dicotyledenous hosts. It contains four ORFs encoding a movement protein, a coat protein, and two Rep gene products, Rep and RepA, which are encoded by two overlapping ORFs. In this study, the roles of Rep and RepA in regulating replication of the BeYDV-based replicon were investigated by uncoupling them and placing Rep and RepA each under constitutive promoter control. Constitutive expression of both Rep and RepA supported replication and enhanced gene expression. When a reporter plasmid containing the Rep gene in the context of its native promoter was supplemented with additional Rep protein, replication was enhanced but the increase in gene expression was found to be more modest. Furthermore, expression of constitutively expressed RepA alone was found to reduce replication of this reporter construct as well as delay BeYDV replication in general. The effect of a RepA mutant with an altered retinoblastoma-related-protein binding motif on the efficiency of BeYDV replication was also examined. This mutant was found to severely diminish replication efficiency. Finally, the relationship of BeYDV coat protein to virus replication and reporter gene expression was investigated. Addition of coat protein increased accumulation of single-stranded DNA and had a detrimental effect on reporter gene expression.

Intronic and exonic sequences modulate 5' splice site selection in plant nuclei

Pre-mRNA transcripts in a variety of organisms, including plants, Drosophila and Caenorhabditis elegans, contain introns which are significantly richer in adenosine and uridine residues than their flanking exons. Previous analyses using exonic and intronic replacements between two nonequivalent 5'splice sites in the 469 nt long rbcS3A intron 1 provided the first evidence indicating that, in both tobacco and Drosophila nuclei, 5'splice site selection is strongly influenced by the position of that site relative to the AU transition point between exon and intron. To differentiate between two potential models for 5'splice site recognition, we have expressed a completely different set of intronic and exonic replacement constructs containing identical 5'splice sites upstream of beta-conglycinin intron 4 (115 nt). Mutagenesis and deletion of the upstream 5'splice site demonstrate that intronic AU-rich sequences function by promoting recognition of the most upstream 5'splice site rather than by masking the downstream 5'splice site. Sequence insertions define a role for AG-rich exonic sequences in plant pre-mRNA splicing by demonstrating that an AG-rich element is capable of promoting downstream 5'splice site recognition. We conclude that AU-rich intronic sequences, AG-rich exonic sequences and the 5'splice site itself collectively define 5'intron boundaries in dicot nuclei.

Interactions across exons can influence splice site recognition in plant nuclei

In vivo analyses of cis-acting sequence requirements for pre-mRNA splicing in tobacco nuclei have previously demonstrated that the 5' splice sites are selected by their position relative to AU-rich elements within plant introns and by their degree of complementarity to the U1 small nuclear RNA. To determine whether the presence of adjacent introns affects 5' splice site recognition in plant nuclei, we have analyzed the in vivo splicing patterns of two-intron constructs containing 5' splice site mutations in the second intron. These experiments indicated that the splice site selection patterns in plant nuclei are defined primarily by sequences within the intron (intron definition) and secondarily by weak interactions across exons (exon definition). The effects of these secondary interactions became evident only when mutations in the downstream 5' splice site decreased its functionality and differed depending on the availability of cryptic splice sites close to the mutant site. In beta-conglycinin chimeric transcripts containing multiple cryptic 5' splice sites, the presence of an intact upstream intron significantly increased splicing at the downstream 5' splice sites in a polar fashion without activating exon skipping. In a natural beta-conglycinin transcript, which does not contain cryptic 5'splice sites, mutation of the first nucleotide of the downstream intron activated an array of noncanonical 5' and 3' splice sites and some exon skipping.

Splicing of precursors to mRNA in higher plants: mechanism, regulation and sub-nuclear organisation of the spliceosomal machinery

The removal of introns from pre-mRNA transcripts and the concomitant ligation of exons is known as pre-mRNA splicing. It is a fundamental aspect of constitutive eukaryotic gene expression and an important level at which gene expression is regulated. The process is governed by multiple cis-acting elements of limited sequence content and particular spatial constraints, and is executed by a dynamic ribonucleoprotein complex termed the spliceosome. The mechanism and regulation of pre-mRNA splicing, and the sub-nuclear organisation of the spliceosomal machinery in higher plants is reviewed here. Heterologous introns are often not processed in higher plants indicating that, although highly conserved, the process of pre-mRNA splicing in plants exhibits significant differences that distinguish it from splicing in yeast and mammals. A fundamental distinguishing feature is the presence of and requirement for AU or U-rich intron sequence in higher-plant pre-mRNA splicing. In this review we document the properties of higher-plant introns and trans-acting spliceosomal components and discuss the means by which these elements combine to determine the accuracy and efficiency of pre-mRNA processing. We also detail examples of how introns can effect regulated gene expression by affecting the nature and abundance of mRNA in plants and list the effects of environmental stresses on splicing. Spliceosomal components exhibit a distinct pattern of organisation in higher-plant nuclei. Effective probes that reveal this pattern have only recently become available, but the domains in which spliceosomal components concentrate were identified in plant nuclei as enigmatic structures some sixty years ago. The organisation of spliceosomal components in plant nuclei is reviewed and these recent observations are unified with previous cytochemical and ultrastructural studies of plant ribonuleoprotein domains.

In vivo analysis of intron processing using splicing-dependent reporter gene assays

The mechanisms of intron recognition and processing have been well-studied in mammals and yeast, but in plants the biochemistry of splicing is not known and the rules for intron recognition are not clearly defined. To increase understanding of intron processing in plants, we have constructed new pairs of vectors, pSuccess and pFail, to assess the efficiency of splicing in maize cells. In the pFail series we use translation of pre-mRNA to monitor the amount of unspliced RNA. We inserted an ATG codon in the Bz2 (Bronze-2) intron in frame with luciferase: this construct will express luciferase activity only when splicing fails. In the pSuccess series the spliced message is monitored by inserting an ATG upstream of the Bz2 intron in frame with luciferase: this construct will express luciferase activity only when splicing succeeds. We show here, using both the wild-type Bz2 intron and the same intron with splice site mutations, that the efficiency of splicing can be estimated by the ratio between the luciferase activities of the vector pairs. We also show that mutations in the unique U-rich motif inside the intron can modulate splicing. In addition, a GC-rich insertion in the first exon increases the efficiency of splicing, suggesting that exons also play an important role in intron recognition and/or processing.

AU-rich intronic elements affect pre-mRNA 5' splice site selection in Drosophila melanogaster

cis-spliced nuclear pre-mRNA introns found in a variety of organisms, including Tetrahymena thermophila, Drosophila melanogaster, Caenorhabditis elegans, and plants, are significantly richer in adenosine and uridine residues than their flanking exons are. The functional significance of this intronic AU richness, however, has been demonstrated only in plant nuclei. In these nuclei, 5' and 3' splice sites are selected in part by their positions relative to AU-rich elements spread throughout the length of an intron. Because of this position-dependent selection scheme, a 5' splice site at the normal (+1) exon-intron boundary having only three contiguous consensus nucleotides can compete effectively with an enhanced exonic site (-57E) having nine consensus nucleotides and outcompete an enhanced site (+106E) embedded within the AU-rich intron. To determine whether transitions from AU-poor exonic sequences to AU-rich intronic sequences influence 5' splice site selection in other organisms, alleles of the pea rbcS3A1 intron were expressed in Drosophila Schneider 2 cells, and their splicing patterns were compared with those in tobacco nuclei. We demonstrate that this heterologous transcript can be accurately spliced in transfected Drosophila nuclei and that a +1 G-to-A knockout mutation at the normal splice site activates the same three cryptic 5' splice sites as in tobacco. Enhancement of the exonic (-57) and intronic (+106) sites to consensus splice sites indicates that potential splice sites located in the upstream exon or at the 5' exon-intron boundary are preferred in Drosophila cells over those embedded within AU-rich intronic sequences. In contrast to tobacco, in which the activities of two competing 5' splice sites upstream of the AU-rich intron are modulated by their proximity to the AU transition point, D. melanogaster utilizes the upstream site which has a higher proportion of consensus nucleotides. The enhanced version of the cryptic intronic site is efficiently selected in D. melanogaster when the normal +1 site is weakened or discrete AU-rich elements upstream of the +106E site are disrupted. Selection of this internal site in tobacco requires more drastic disruption of these motifs. We conclude that 5' splice site selection in Drosophila nuclei is influenced by the intrinsic strengths of competing sites and by the presence of AU-rich intronic elements but to a different extent than in tobacco.

AU-rich intronic elements affect pre-mRNA 5' splice site selection in Drosophila melanogaster

cis-spliced nuclear pre-mRNA introns found in a variety of organisms, including Tetrahymena thermophila, Drosophila melanogaster, Caenorhabditis elegans, and plants, are significantly richer in adenosine and uridine residues than their flanking exons are. The functional significance of this intronic AU richness, however, has been demonstrated only in plant nuclei. In these nuclei, 5' and 3' splice sites are selected in part by their positions relative to AU-rich elements spread throughout the length of an intron. Because of this position-dependent selection scheme, a 5' splice site at the normal (+1) exon-intron boundary having only three contiguous consensus nucleotides can compete effectively with an enhanced exonic site (-57E) having nine consensus nucleotides and outcompete an enhanced site (+106E) embedded within the AU-rich intron. To determine whether transitions from AU-poor exonic sequences to AU-rich intronic sequences influence 5' splice site selection in other organisms, alleles of the pea rbcS3A1 intron were expressed in Drosophila Schneider 2 cells, and their splicing patterns were compared with those in tobacco nuclei. We demonstrate that this heterologous transcript can be accurately spliced in transfected Drosophila nuclei and that a +1 G-to-A knockout mutation at the normal splice site activates the same three cryptic 5' splice sites as in tobacco. Enhancement of the exonic (-57) and intronic (+106) sites to consensus splice sites indicates that potential splice sites located in the upstream exon or at the 5' exon-intron boundary are preferred in Drosophila cells over those embedded within AU-rich intronic sequences. In contrast to tobacco, in which the activities of two competing 5' splice sites upstream of the AU-rich intron are modulated by their proximity to the AU transition point, D. melanogaster utilizes the upstream site which has a higher proportion of consensus nucleotides. The enhanced version of the cryptic intronic site is efficiently selected in D. melanogaster when the normal +1 site is weakened or discrete AU-rich elements upstream of the +106E site are disrupted. Selection of this internal site in tobacco requires more drastic disruption of these motifs. We conclude that 5' splice site selection in Drosophila nuclei is influenced by the intrinsic strengths of competing sites and by the presence of AU-rich intronic elements but to a different extent than in tobacco.

Plant pre-mRNA splicing and splicing components

Pre-mRNA splicing or the removal of introns from precursor messenger RNAs depends on the accurate recognition of intron sequences by the plant splicing machinery. The major components of this machinery are small nuclear ribonucleoprotein protein particles (snRNPs) which consist of snRNAs and snRNP proteins. We have analysed various aspects of intron sequence and structure in relation to splice site selection and splicing efficiency and we have cloned snRNA genes and a gene encoding the snRNP protein, U2B". In the absence of an in vitro splicing system for plants, transient expression in protoplasts and stable plant transformations have been used to analyse splicing of intron constructs. We aim to address the function of the UsnRNP-specific protein, U2B", via the production of transgenic plants expressing antisense U2B" transcripts and epitope-tagged U2B" protein. In addition, we have cloned genes encoding other proteins which potentially interact with RNA, such as RNA helicases, and strategies involving transgenic plants are being developed to analyse their function.

3' splice site selection in dicot plant nuclei is position dependent

In contrast to mammalian and yeast systems, the mechanism for intron recognition and splice site selection in plant pre-mRNAs is poorly understood. Splice site sequences and putative branchpoint sequences are loosely conserved in plant introns compared with other eukaryotes. Perhaps to compensate for these variations, plant introns are significantly richer in adenosine and uridine residues than are their adjacent exons. To define elements critical for 3' splice site selection in dicotyledonous plant nuclei, pre-mRNA transcripts containing intron 3 of the maize Adh1 gene were expressed in Nicotiana benthamiana nuclei by using an autonomously replicating plant expression vector. Using a series of intron rearrangements which reposition the 3' intron-exon border, we demonstrate that the normal 3' splice site is defined in a position-dependent manner and that cryptic 3' splice sites within the intron are masked by the presence of a functional downstream 3' splice site. Disruption of the AU-rich elements upstream from the normal 3' splice site indicates that multiple AU elements between -66 and -6 cooperatively define the 3' boundary of the intron. These results are consistent with a model for plant intron recognition in which AU-rich elements spread throughout the length of the intron roughly define the intron boundaries by generating strong AU transition points. Functional 3' splice sites located downstream from these AU-rich sequences are preferentially selected over sites embedded within them.

3' splice site selection in dicot plant nuclei is position dependent

In contrast to mammalian and yeast systems, the mechanism for intron recognition and splice site selection in plant pre-mRNAs is poorly understood. Splice site sequences and putative branchpoint sequences are loosely conserved in plant introns compared with other eukaryotes. Perhaps to compensate for these variations, plant introns are significantly richer in adenosine and uridine residues than are their adjacent exons. To define elements critical for 3' splice site selection in dicotyledonous plant nuclei, pre-mRNA transcripts containing intron 3 of the maize Adh1 gene were expressed in Nicotiana benthamiana nuclei by using an autonomously replicating plant expression vector. Using a series of intron rearrangements which reposition the 3' intron-exon border, we demonstrate that the normal 3' splice site is defined in a position-dependent manner and that cryptic 3' splice sites within the intron are masked by the presence of a functional downstream 3' splice site. Disruption of the AU-rich elements upstream from the normal 3' splice site indicates that multiple AU elements between -66 and -6 cooperatively define the 3' boundary of the intron. These results are consistent with a model for plant intron recognition in which AU-rich elements spread throughout the length of the intron roughly define the intron boundaries by generating strong AU transition points. Functional 3' splice sites located downstream from these AU-rich sequences are preferentially selected over sites embedded within them.

Factors affecting authentic 5' splice site selection in plant nuclei

To define elements critical for 5' splice selection in dicot plant nuclei, wild-type and mutant transcripts containing the first intron of the pea rbcS3A gene were expressed in vivo by using an autonomously replicating plant expression vector. Mutations within the normal 5' splice site (+1) of this intron demonstrate that 5' splice sites at the normal exon-intron boundary having only limited agreement with a 5' splice site consensus sequence can be spliced quite effectively in dicot nuclei. Inactivation of the normal 5' splice site occurs only by point mutations of the G at position +1 of the intron (+1G) or +2U or by multiple mutations at other positions and results in the activation of three cryptic 5' splice sites in the adjacent exon and intron. cis competition of cryptic sites having consensus 5' splice site sequences with the normal 5' splice site demonstrates that cryptic splice sites in the exon, but not the intron, can compete to some extent with the normal site. Replacement of the sequences between the cryptic and normal 5' splice sites with heterologous exon or intron sequences demonstrates that the 5' boundary of this plant intron is defined by its position relative to the AU transition point between exon and intron. These results suggest that potential 5' splice sites upstream of the AU transition point are accessible for recognition by the plant pre-mRNA splicing machinery and that those downstream in the AU-rich intron are masked from recognition.

Factors affecting authentic 5' splice site selection in plant nuclei

To define elements critical for 5' splice selection in dicot plant nuclei, wild-type and mutant transcripts containing the first intron of the pea rbcS3A gene were expressed in vivo by using an autonomously replicating plant expression vector. Mutations within the normal 5' splice site (+1) of this intron demonstrate that 5' splice sites at the normal exon-intron boundary having only limited agreement with a 5' splice site consensus sequence can be spliced quite effectively in dicot nuclei. Inactivation of the normal 5' splice site occurs only by point mutations of the G at position +1 of the intron (+1G) or +2U or by multiple mutations at other positions and results in the activation of three cryptic 5' splice sites in the adjacent exon and intron. cis competition of cryptic sites having consensus 5' splice site sequences with the normal 5' splice site demonstrates that cryptic splice sites in the exon, but not the intron, can compete to some extent with the normal site. Replacement of the sequences between the cryptic and normal 5' splice sites with heterologous exon or intron sequences demonstrates that the 5' boundary of this plant intron is defined by its position relative to the AU transition point between exon and intron. These results suggest that potential 5' splice sites upstream of the AU transition point are accessible for recognition by the plant pre-mRNA splicing machinery and that those downstream in the AU-rich intron are masked from recognition.

Expression of maize Adh1 intron mutants in tobacco nuclei

In vivo and in vitro gene transfer experiments have suggested that the elements mediating intron recognition differ in mammalian, yeast and plant nuclei. Differences in the sequence dependencies, which also exist between dicotyledonous and monocotyledonous nuclei, have prevented some monocot introns from being spliced in dicot nuclei. To locate elements which modulate efficient recognition of introns in dicot nuclei, the maize Adh1 gene has been expressed in full-length and single intron constructs in Nicotiana benthamiana nuclei using an autonomously replicating plant expression vector. Quantitative PCR-Southern analyses indicate that the inefficient splicing of the maize Adh1 intron 1 (57% AU) in these dicot nuclei can be dramatically enhanced by increasing the degree of U1 snRNA complementarity at the 5' splice site. This indicates that the 5' splice site plays a significant role in defining the splicing efficiency of an intron in dicot nuclei and that, most importantly, the remainder of this monocot intron contains no elements which inhibit its accurate recognition in dicot nuclei. Deletions in intron 3 (66% AU) which effectively move the 3' boundary between AU-rich intron and GC-rich exon sequences strongly activate a cryptic upstream splice site; those which do not reposition this boundary activate a downstream cryptic splice site. This suggests that 3' splice site selection in dicot nuclei is extremely flexible and not dependent on strict sequence requirements but rather on the transition points between introns and exons. Our results are consistent with a model in which potential splice sites are selected if they are located upstream (5' splice site) or downstream (3' splice site) of AU transition points and not if they are embedded within AU-rich sequences.

Geminiviruses: plant viral vectors

Geminiviruses are being used as convenient autonomously replicating vectors for foreign gene amplification in plants. Using tissue culture techniques, they have been adapted for the analysis of the regulation of gene expression in a wide range of hosts, including both mono- and dicotyledonous species. In monocotyledonous plants that are particularly recalcitrant to transformation, geminivirus symptom-induction has been used as a sensitive marker for DNA uptake.

Efficient splicing of an AU-rich antisense intron sequence

For successful splicing in dicot plants the only recognised intron requirements are 5' and 3' splice sites and AU-rich sequences. We have investigated further the importance of AU-rich elements by analyzing the splicing of an AU-rich antisense intron sequence. Activation of cryptic splice sites on either side of the AU-rich sequence permitted the efficient removal of this essentially non-intron sequence by splicing. This splicing event not only confirms the importance of AU-rich sequences but also has implications for the evolution of interrupted genes and the expression of heterologous genes in transgenic plants.

Information contents and dinucleotide compositions of plant intron sequences vary with evolutionary origin

The DNA sequence composition of 526 dicot and 345 monocot intron sequences have been characterized using computational methods. Splice site information content and bulk intron and exon dinucleotide composition were determined. Positions 4 and 5 of 5' splice sites contain different statistically significant levels of information in the two groups. Basal levels of information in introns are higher in dicots than in monocots. Two dinucleotide groups, WW (AA, AU, UA, UU) and SS (CC, CG, GC, GG) have significantly different frequencies in exons and introns of the two plant groups. These results suggest that the mechanisms of splice-site recognition and binding may differ between dicot and monocot plants.