Craig G. Simpson

Arabidopsis consensus intron sequences

We have analysed 998 Arabidopsis intron sequences in the EMBL database. All Arabidopsis introns to adhere to the :GU...AG: rule with the exception of 1% of introns with :GC at their 5′ ends. Virtually all of the introns contained a putative branchpoint sequence (YUNAN) 18 to 60 nt upstream of the 3′ splice site. Although a polypyrimidine tract was much less apparent than in vertebrate introns, the most common nucleotide in the region upstream of the 3′ splice site was uridine. Consensus sequences for 5′ and 3′ splice sites and branchpoint sequences for Arabidopsis introns are presented.

Dynamic Behavior of Arabidopsis eIF4A-III, Putative Core Protein of Exon Junction Complex: Fast Relocation to Nucleolus and Splicing Speckles under Hypoxia

Here, we identify the Arabidopsis thaliana ortholog of the mammalian DEAD box helicase, eIF4A-III, the putative anchor protein of exon junction complex (EJC) on mRNA. Arabidopsis eIF4A-III interacts with an ortholog of the core EJC component, ALY/Ref, and colocalizes with other EJC components, such as Mago, Y14, and RNPS1, suggesting a similar function in EJC assembly to animal eIF4A-III. A green fluorescent protein (GFP)-eIF4A-III fusion protein showed localization to several subnuclear domains: to the nucleoplasm during normal growth and to the nucleolus and splicing speckles in response to hypoxia. Treatment with the respiratory inhibitor sodium azide produced an identical response to the hypoxia stress. Treatment with the proteasome inhibitor MG132 led to accumulation of GFP-eIF4A-III mainly in the nucleolus, suggesting that transition of eIF4A-III between subnuclear domains and/or accumulation in nuclear speckles is controlled by proteolysis-labile factors. As revealed by fluorescence recovery after photobleaching analysis, the nucleoplasmic fraction was highly mobile, while the speckles were the least mobile fractions, and the nucleolar fraction had an intermediate mobility. Sequestration of eIF4A-III into nuclear pools with different mobility is likely to reflect the transcriptional and mRNA processing state of the cell.

Cloning and characterization of two subunits of Arabidopsis thaliana nuclear cap-binding complex.

In this report we characterize two Arabidopsis thaliana proteins, named AtCBP20 and AtCBP80, that are homologues of human subunits of a nuclear cap-binding protein complex (CBC). AtCBP20 has a calculated molecular mass of 29.9 kDa, and AtCBP80 is a 96.5 kDa protein. AtCBP20 exhibits 68% identity and 82% similarity to human CBP20. Like its human homologue, AtCBP20 contains a canonical RNA binding domain (RBD) with single RNP2 and RNP1 motifs. In addition to the N-terminal part, which is similar to the human protein, AtCBP20 has a long C-terminus rich in arginine, glycine and aspartate residues. The second subunit of the Arabidopsis cap-binding complex, AtCBP80, shows 28% identity and 50% similarity to its homologue from HeLa cells. The protein contains a MIF4G domain at its N-terminus, the feature characteristic to all analyzed CBP80s. This domain, described also in eIF4G and NMD2 proteins, is thought to be involved in protein-protein and also in protein--RNA interactions. Both proteins AtCBP20 and AtCBP80 are encoded by single-copy genes in the A. thaliana genome. The AtCBP20 gene is located on chromosome V, and the AtCBP80 gene is encoded by chromosome II. Among introns identified in the AtCBP20 gene, we discovered an U12 type intervening sequence (an AT-AC intron). This intron is spliced out very efficiently in plants, but when isolated and tested for splicing in tobacco protoplasts, the efficiency of the U12 intron excision was low. Splicing efficiency of the U12 intron is improved by the addition of exon and intron sequences upstream or downstream of the U12 intron. AtCBP20 and AtCBP80 are constitutively expressed in all examined organs of A. thaliana, including roots, stems, leaves and flowers. Interestingly, the steady-state level of both transcripts seem to be very similar in all tissues analyzed.

Alternative splicing in plants

The impact of AS (alternative splicing) is well-recognized in animal systems as a key regulator of gene expression and proteome complexity. In plants, AS is of growing importance as more genes are found to undergo AS, but relatively little is known about the factors regulating AS or the consequences of AS on mRNA levels and protein function. We have established an accurate and reproducible RT (reverse transcription)-PCR system to analyse AS in multiple genes. Initial studies have identified new AS events confirming that current values for the frequency of AS in plants are likely to be underestimates.

Determinants of Plant U12-Dependent Intron Splicing Efficiency

Factors affecting splicing of plant U12-dependent introns have been examined by extensive mutational analyses in an in vivo tobacco (Nicotiana tabacum) protoplast system using introns from three different Arabidopsis thaliana genes: CBP20, GSH2, and LD. The results provide evidence that splicing efficiency of plant U12 introns depends on a combination of factors, including UA content, exon bridging interactions between the U12 intron and flanking U2-dependent introns, and exon splicing enhancer sequences (ESEs). Unexpectedly, all three plant U12 introns required an adenosine at the upstream purine position in the branchpoint consensus UCCUURAUY. The exon upstream of the LD U12 intron is a major determinant of its higher level of splicing efficiency and potentially contains two ESE regions. These results suggest that in plants, U12 introns represent a level at which expression of their host genes can be regulated.

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.

Expression of intron modified NPT II genes in monocotyledonous and dicotyledonous plant cells

Intron sequences from monocotyledonous and dicotyledonous origin were used to abolish marker gene expression in prokaryotes (Escherichia coli and Agrobacterium tumefaciens) but permit expression in selected eukaryotic systems using the eukaryotic specific splicing mechanism. A 1014 bp maize Shrunken-1 (Sh 1) intron 1 flanked by exon1 and exon2 sequences was cloned into the N-terminal of the NPT II-coding region. Transient gene expression analysis revealed that the modified neomycin phosphotransferase II (NPT II) gene, driven by the cauliflower mosaic virus (CaMV) 35S promoter, is expressed in barley protoplasts, but poorly expressed in tobacco protoplasts. In dicotyledonous cells AU-rich sequences are known to be important for efficient splicing and therefore an attempt was made to improve expression of the NPT II gene, containing the Sh 1 intron 1, in tobacco by increasing the AU content from 57% to 69%. Reverse transcriptase PCR analysis of RNA from transiently expressed NPT II transcripts from tobacco protoplasts revealed that despite the increase in AU-content, NPT II was still poorly expressed. Cryptic splice sites were identified as one possible cause for missplicing of the Sh1 intron 1 in dicots and poor levels of expression. Alternatively, cloning of the 198 bp intron 2 of the potato STLS 1 gene (81% AU) into the N-terminal part of the NPT II-coding region resulted in proper expression of NPT II in tobacco as well as in barley protoplasts and abolished marker gene expression in prokaryotes. The successful insertion of an intron into a selectable marker gene which completely abolishes gene expression in prokaryotes, without affecting expression of chimeric genes in monocotyledonous and dicotyledonous plant cells provides a suitable system to reduce the number of false-positives in transgenic plant production.

U12-Dependent Intron Splicing in Plants

U12-dependent (U12) introns have persisted in the genomes of plants since the ancestral divergence between plants and metazoans. These introns, which are rare, are found in a range of genes that include essential functions in DNA replication and RNA metabolism and are implicated in regulating the expression of their host genes. U12 introns are removed from pre-mRNAs by a U12 intron-specific spliceosome. Although this spliceosome shares many properties with the more abundant U2-dependent (U2) intron spliceosome, four of the five small nuclear RNAs (snRNAs) required for splicing are different and specific for the unique splicing of U12 introns. Evidence in plants so far indicates that splicing signals of plant U12 introns and their splicing machinery are similar to U12 intron splicing in other eukaryotes. In addition to the high conservation of splicing signals, plant U12 introns also retain unique characteristic features of plant U2 introns, such as UA-richness, which suggests a requirement for plant-specific components for both the U2 and U12 splicing reaction. This chapter compares U12 and U2 splicing and reviews what is known about plant U12 introns and their possible role in gene expression.

Amplification of chloroplast DNA using the polymerase chain reaction (PCR): a practical activity for secondary school students

We describe a polymerase chain reaction (PCR) protocol suitable for use in secondary schools and colleges. This PCR protocol can be used to investigate genetic variation between plants. The protocol makes use of primers which are complementary to sequences of nucleotides that are highly conserved across different plant genera. The regions of chloroplast DNA amplified lie between these conserved sequences and are non-coding. These non-coding regions display a high frequency of mutations and show relatively high rates of evolutionary change. Thus it is possible to use the protocol to explore evolutionary relationships between plants. Results from Brassica oleracea can be used to highlight genetic similarity and differences within and across genera. The protocol is robust and is suitable for use either with a thermocycler or a series of water-baths, thus making it accessible for use in most schools and colleges.