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.

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.

Splicing signals and factors in plant intron removal.

Constitutive splicing of the potato invertase mini-exon 2 (9 nt long) requires a branchpoint sequence positioned around 50 nt upstream of the 5' splice site of the adjacent intron and a U(11) element found just downstream of the branchpoint in the upstream intron [Simpson, Hedley, Watters, Clark, McQuade, Machray and Brown (2000) RNA 6, 422-433]. The sensitivity of this in vivo plant splicing system has been used to demonstrate exon scanning in plants, and to characterize plant intronic elements, such as branchpoint and poly-pyrimidine tract sequences. Plant introns differ from their vertebrate and yeast counterparts in being UA- or U-rich (up to 85% UA). One of the key differences in splicing between plants and other eukaryotes lies in early intron recognition, which is thought to be mediated by UA-binding proteins. We are adopting three approaches to studying the RNA-protein interactions in plant splicing. First, overexpression of plant splicing factors and, in particular, UA-binding proteins, in conjunction with a range of mini-exon mutants. Secondly, the sequences of around 65% of vertebrate and yeast splicing factors have high-quality matches to Arabidopsis proteins, opening the door to identification and analysis of gene knockouts. Finally, to discover plant-specific proteins involved in splicing and in, for example, rRNA or small nuclear RNA processing, green fluorescent protein-cDNA fusion libraries in viral vectors are being screened.

Choriocarcinomatous metaplasia of a metachronous adenocarcinoma of the colon.

A second primary colonic adenocarcinoma developed in a 68-year-old man following resection of a rectal adenocarcinoma. Choriocarcinomatous change was found in the metachronous lesion with liver metastases and elevated beta-human choriogonadotrophin (HCG) serum titres.

Expression of intron-containing GUS constructs is reduced due to activation of a cryptic 5' splice site.

An intron-containing beta-glucuronidase (GUS) gene has been used widely in promoter analyses and as a plant transformation marker. Maximal plant gene expression requires accurate and efficient removal of the intron from the expressed pre-mRNA transcripts by splicing. Detailed analysis of splicing of potato ST-LS1 and pea legumin introns from GUS constructs revealed the activation of a cryptic 5' splice site in the GUS coding sequence 4 nt upstream from the authentic intron 5' splice site. About 40% of transcripts utilised the cryptic 5' splice site in tobacco protoplasts, reducing the translational potential of expressed pre-mRNA. The same cryptic splicing event was evident in transgenic tobacco leaves but at reduced levels. Mutations that removed the cryptic 5' splice site are associated with a two-fold enhancement in GUS activity in tobacco protoplasts, highlighting the need for careful examination of introns and their sites of insertion into gene constructs to minimise variability in gene activity and maximise gene expression.

Multiple snoRNA gene clusters from Arabidopsis.

Small nucleolar RNAs (snoRNAs) are involved in precursor ribosomal RNA (pre-rRNA) processing and rRNA base modification (2'-O-ribose methylation and pseudouridylation). In all eukaryotes, certain snoRNAs (e.g., U3) are transcribed from classical promoters. In vertebrates, the majority are encoded in introns of protein-coding genes, and are released by exonucleolytic cleavage of linearized intron lariats. In contrast, in maize and yeast, nonintronic snoRNA gene clusters are transcribed as polycistronic pre-snoRNA transcripts from which individual snoRNAs are processed. In this article, 43 clusters of snoRNA genes, an intronic snoRNA, and 10 single genes have been identified by cloning and by computer searches, giving a total of 136 snoRNA gene copies of 71 different snoRNA genes. Of these, 31 represent snoRNA genes novel to plants. A cluster of four U14 snoRNA genes and two clusters containing five different snoRNA genes (U31, snoR4, U33, U51, and snoR5) from Arabidopsis have been isolated and characterized. Of these genes, snoR4 is a novel box C/D snoRNA that has the potential to base pair with the 3' end of 5.8S rRNA and snoR5 is a box H/ACA snoRNA gene. In addition, 42 putative sites of 2'-O-ribose methylation in plant 5.8S, 18S, and 25S rRNAs have been mapped by primer extension analysis, including eight sites novel to plant rRNAs. The results clearly show that, in plants, the most common gene organization is polycistronic and that over a third of predicted and mapped methylation sites are novel to plant rRNAs. The variation in this organization among gene clusters highlights mechanisms of snoRNA evolution.

Requirements for mini-exon inclusion in potato invertase mRNAs provides evidence for exon-scanning interactions in plants.

Invertases are responsible for the breakdown of sucrose to fructose and glucose. In all but one plant invertase gene, the second exon is only 9 nt in length and encodes three amino acids of a five-amino-acid sequence that is highly conserved in all invertases of plant origin. Sequences responsible for normal splicing (inclusion) of exon 2 have been investigated in vivo using the potato invertase, invGF gene. The upstream intron 1 is required for inclusion whereas the downstream intron 2 is not. Mutations within intron 1 have identified two sequence elements that are needed for inclusion: a putative branchpoint sequence and an adjacent U-rich region. Both are recognized plant intron splicing signals. The branchpoint sequence lies further upstream from the 3' splice site of intron 1 than is normally seen in plant introns. All dicotyledonous plant invertase genes contain this arrangement of sequence elements: a distal branchpoint sequence and adjacent, downstream U-rich region. Intron 1 sequences upstream of the branchpoint and sequences in exons 1, 2, or 3 do not determine inclusion, suggesting that intron or exon splicing enhancer elements seen in vertebrate mini-exon systems are absent. In addition, mutation of the 3' and 5' splice sites flanking the mini-exon cause skipping of the mini-exon, suggesting that both splice sites are required. The branchpoint/U-rich sequence is able to promote splicing of mini-exons of 6, 3, and 1 nt in length and of a chicken cTNT mini-exon of 6 nt. These sequence elements therefore act as a splicing enhancer and appear to function via interactions between factors bound at the branchpoint/U-rich region and at the 5' splice site of intron 2, activating removal of this intron followed by removal of intron 1. This first example of splicing of a plant mini-exon to be analyzed demonstrates that particular arrangement of standard plant intron splicing signals can drive constitutive splicing of a mini-exon.

Characterization of exon skipping mutants of the COP1 gene from Arabidopsis.

The removal of introns from pre-mRNA requires accurate recognition and selection of the intron splice sites. Mutations which alter splice site selection and which lead to skipping of specific exons are indicative of intron/exon recognition mechanisms involving an exon definition process. In this paper, three independent mutants to the COP1 gene in Arabidopsis which show exon skipping were identified and the mutations which alter the normal splicing pattern were characterized. The mutation in cop1-1 was a G-->A change 4 nt upstream from the 3' splice site of intron 5, while the mutation in cop1-2 was a G-->A at the first nucleotide of intron 6, abolishing the conserved G within the 5' splice site consensus. The effect of these mutations was skipping of exon 6. The mutation in cop1-8 was G-->A in the final nucleotide of intron 10 abolishing the conserved G within the 3' splice site consensus and leading to skipping of exon 11. The splicing patterns surrounding exons 6 and 11 of COP1 in these three mutant lines of Arabidopsis provide evidence for exon definition mechanisms operating in plant splicing.

Processing of vertebrate box C/D small nucleolar RNAs in plant cells.

The recent isolation of a number of plant box C/D small nucleolar (sno)RNAs demonstrates the conservation in plants of sequence and structural elements of processed box C/D snoRNAs. Boxes C and D, and terminal inverted repeats are known to be essential for accumulation and processing in vertebrates and yeast. Processing of vertebrate box C/D snoRNAs was examined by expression of various mouse hsc70 intron 5-U14 constructs in tobacco protoplasts. Full-length U14 and internally deleted U14 accumulated in the plant cells. Human U3 and U8 fragments, consistent with processing to internal box C/C' sequences, also accumulated in the plant cells. The similarity of processing behaviour of the vertebrate box C/D constructs in tobacco protoplasts and Xenopus oocytes suggests the mechanism of processing, involving recognition and association of proteins, is conserved in plants.

SPLICE SITE SELECTION IN PLANT PRE-mRNA SPLICING.

The purpose of this review is to highlight the unique and common features of splice site selection in plants compared with the better understood yeast and vertebrate systems. A key question in plant splicing is the role of AU sequences and how and at what stage they are involved in spliceosome assembly. Clearly, intronic U- or AU-rich and exonic GC- and AG-rich elements can influence splice site selection and splicing efficiency and are likely to bind proteins. It is becoming clear that splicing of a particular intron depends on a fine balance in the "strength" of the multiple intron signals involved in splice site selection. Individual introns contain varying strengths of signals and what is critical to splicing of one intron may be of less importance to the splicing of another. Thus, small changes to signals may severely disrupt splicing or have little or no effect depending on the overall sequence context of a specific intron/exon organization.

East meets West: a comparison of eastern block/western aeromedical practices.

Under the auspices of the European Command (EUCOM) Military-to-Military Exchange Program, the authors participated in 13 trips to visit aeromedical facilities of nine Eastern European nations (Albania, Belarus, Bulgaria, Czech Republic, Hungary, Lithuania, Poland, Romania, and Slovakia). In addition, eight of these Eastern European nations visited United States Air Force (USAF) aeromedical facilities. This article highlights the similarities and differences noted between the USAF and Eastern Europe in the practice of aerospace medicine. Flight surgeons from both Eastern Europe and the USAF address issues such as physiologic stresses of flight (acceleration, hypoxia, etc.) and lifestyle stresses (rest, diet, alcohol, cigarettes, etc.). Eastern European Flight Surgeons do not regularly fly. The Eastern European approach to medical standards and screening for aviation applicants is much stricter and more comprehensive than ours. Several of the nations visited had active research programs at their central aeromedical institute emphasizing aircrew selection and retention standards. With the exception of the Czech Republic, Eastern European nations did not routinely grant waivers for chronic medical conditions such as hypertension in aircrew. Soviet-built aircraft had many unique features such as an outside-in attitude indicator and an auto-recovery system.

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.

Epithelioid hemangioendothelioma of the lung.

Light and electron microscopic features of an epithelioid hemangioendothelioma of the lung in a 43-year-old woman are reported. The tumor cells stained for factor VIII-related antigen. A mass excised from the thigh 10 years earlier showed identical appearances.

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.