Purification of the major UsnRNPs from broad bean nuclear extracts and characterization of their protein constituents

Periodic expression of Sm proteins parallels formation of nuclear Cajal bodies and cytoplasmic snRNP-rich bodies

Small nuclear ribonucleoproteins (snRNPs) play a fundamental role in pre-mRNA processing in the nucleus. The biogenesis of snRNPs involves a sequence of events that occurs in both the nucleus and cytoplasm. Despite the wealth of biochemical information about the cytoplasmic assembly of snRNPs, little is known about the spatial organization of snRNPs in the cytoplasm. In the cytoplasm of larch microsporocytes, a cyclic appearance of bodies containing small nuclear RNA (snRNA) and Sm proteins was observed during anther meiosis. We observed a correlation between the occurrence of cytoplasmic snRNP bodies, the levels of Sm proteins, and the dynamic formation of Cajal bodies. Larch microsporocytes were used for these studies. This model is characterized by natural fluctuations in the level of RNA metabolism, in which periods of high transcriptional activity are separated from periods of low transcriptional activity. In designing experiments, the authors considered the differences between the nuclear and cytoplasmic phases of snRNP maturation and generated a hypothesis about the direct participation of Sm proteins in a molecular switch triggering the formation of Cajal bodies.

Expression in Xenopus oocytes shows that WT1 binds transcripts in vivo, with a central role for zinc finger one

The Wilms' tumour suppressor gene WT1 encodes a protein involved in urogenital development and disease. The salient feature of WT1 is the presence of four 'Krüppel'-type C(2)-H(2) zinc fingers in the C-terminus. Uniquely to WT1, an evolutionarily conserved alternative splicing event inserts three amino acids (KTS) between the third and fourth zinc fingers, which disrupts DNA binding. The ratio of +KTS:-KTS isoforms is crucial for normal development. Previous work has shown that WT1 (+KTS) interacts with splice factors and that WT1 zinc fingers, particularly zinc finger one, bind to RNA in vitro. In this study we investigate the role of zinc finger one and the +KTS splice in vivo by expressing tagged proteins in mammalian cells and Xenopus oocytes. We find that both full-length +/-KTS isoforms and deletion constructs that include zinc finger one co-sediment with ribonucleoprotein particles (RNP) on density gradients. In Xenopus oocytes both isoforms located to the lateral loops of lampbrush chromosomes. Strikingly, only the +KTS isoform was detected in B-snurposomes, but not when co-expressed with -KTS. However, co-expression of the C-terminus (amino acids 233-449, +KTS) resulted in snurposome staining, which is consistent with an in vivo interaction between isoforms via the N-terminus. Expressed WT1 was also detected in the RNA-rich granular component of nucleoli and co-immunoprecipitated with oocyte transcripts. Full-length WT1 was most stably bound to transcripts, followed by the C-terminus; the least stably bound was CTDeltaF1 (C-terminus minus zinc finger one). Expression of the transcription factor early growth response 1 (EGR1), whose three zinc fingers correspond to WT1 zinc fingers 2-4, caused general chromosomal loop retraction and transcriptional shut-down. However, a construct in which WT1 zinc finger one was added to EGR1 mimicked the properties of WT1 (-KTS). We suggest that in evolution, WT1 has acquired the ability to interact with transcripts and splice factors because of the modification of zinc finger one and the +KTS alternative splice.

Chlamydomonas U2, U4 and U6 snRNAs. An evolutionary conserved putative third interaction between U4 and U6 snRNAs which has a counterpart in the U4atac-U6atac snRNA duplex

The spliceosomal UsnRNAs U2, U4 and U6 from the green alga Chlamydomonas reinhardtii (Cre) were sequenced using a combination of RNA and cDNA sequencing methods and were compared to other sequenced UsnRNAs. The lengths of Cre U6 and Cre U2 RNAs are similar to those of their higher plant equivalents. Cre U4 RNA is shorter (139 nt) than its counterpart from higher plants (150-154 nt), and contains stem IV and loop D which are absent, with the exception of the Tetrahymena U4 RNA, from the U4 RNAs of other unicellular organisms studied to date. Base-pairing interactions between U6 and U4 RNAs and between U6 and U2 RNAs, identical to those described for mammalian and yeast systems, are structurally feasible in the Cre system. In addition, based on comparative analyses of the predicted U4/U6 RNA duplex from various species, an evolutionary conserved third putative U6-U4 interaction was found. Interestingly, it can also be formed with the recently discovered U6atac and U4atac RNAs. This is a strong support in favor of the possible biological significance of this third putative interaction. Based on comparative analysis, an extension of the earlier described U6-U2 interaction patterns is also proposed.

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.

Nuclear differentiation in the filamentous caulonema of the moss Funaria hygrometrica

Nuclei from different cell types in plants and animals show many features of differentiation; they differ in shape, volume, structure, ultrastructure and in the distribution of nuclear components. Using the filamentous caulonema of the moss Funaria hygrometrica Hedw. this study records the changes in cytoplasmic organization alongside the reorganization of the interphase nucleus, Events taking place in the meristematic cells at or near the lip of the advancing caulonemal filaments (e.g. acquisition of polarity, tip growth, nuclear and cell division, side branch initiation] are associated with haploid nuclei (1C DXA amount 0.5 pg) that are spherical or slightly oval, with no blocks of condensed chromatin, and a large central nucleolus with a large granular component. Maturation of the caulonemal cells involves wall thickening and pigmentation concomitant with suspension of elongate plastids in linear arrays along endoplasmic strands. Many cells become highly polarized with the majority of the organelles at their apical ends. These eytoplasmic changes are associated with endoreduplication of the genome to about 8C, endoreduplication occurs by amplification of the 1C genome to give nuclei with IC-SC DNA amounts. There is no evidence of differential amplification of the genome. The amplification in the copy number of ribosomal RNA genes is associated with the heterochromatinisation of the genes within the nucleolus. At the same time the nucleolus reduces in volume owing to a diminution of the granular component and all components of the nucleolus become spatial separate. There is an increased nuclear volume associated with endoreduplication and the nucleus elongates causing an increase in the surface area of the nuclear envelope. These major nuclear reorganizations are associated with a stable distribution of the 'D' polypeptide involved in pre-mRNA splicing. Scrutiny of published data suggests that similar differentiation events might be encountered commonly in other organisms. The changing nuclear morphology probably reflects the changing activity of the nucleus and the cell. It might be that nuclear reorganization changes the balance of genes or gene products and the spatial distribution of the component pans to enable the new nuclear functions. These results suggest that nuclear differentiation is a fundamental feature of cell differentiation.

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.

Comparison of the Drosophila melanogaster, human and murine Sm B cDNAs: evolutionary conservation

To analyze the evolutionary stability of the Sm B polypeptides, the cDNA nucleotide (nt) sequence was derived for the Drosophila melanogaster Sm B polypeptide and compared to the cDNAs encoding human and murine Sm B. The three cDNAs were transcribed and translated in reticulocyte lysates followed by analysis of the synthesized proteins by SDS-PAGE. D. melanogaster B migrated at approximately 25 kDa, in comparison to 28 kDa for the murine and human B proteins, although all three proteins were immunoprecipitated by human anti-Sm autoantibodies and by the Y12 anti-Sm murine monoclonal antibody (Y12 mAb). Immunoblots and immunoprecipitations of [35S]methionine-labeled D. melanogaster S2/M3 cells confirmed the smaller size of the D. melanogaster protein, and revealed that B' was absent in this cell line, as in murine cells. In comparison to the 231 amino acids (aa) of human and murine B, the deduced sequence for the D. melanogaster clone was 199 aa (predicted M(r) of 24,598) with two 5-aa deletions and a 19-aa truncation at the 3' end, compared to the other two clones. D. melanogaster protein B shared 65% aa sequence identity with the human and mouse clones, and 80% similarity when conservative aa substitutions were noted. The C-terminal portion of the D. melanogaster protein was the most evolutionarily variable in comparison to the deduced aa sequences for the other two proteins; however, autoantigenic epitopes bound by human anti-Sm antibodies and the Y12 mAb in this region of the protein were conserved across species lines.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection of a plant protein analogous to the yeast spliceosomal protein, PRP8

We have investigated whether a spliceosomal protein analogous to the yeast protein, PRP8, was present in higher plants. A protein with a molecular weight > 200 kDa was detected in Western blots of tobacco (Nicotiana tabacum L.) nuclear extracts with affinity-purified antibodies, raised against four different beta-galactosidase-PRP8 fusion proteins. The < 200 kDa protein was also immunoprecipitated by antibodies against the snRNA-specific trimethylguanosine cap structure and was, therefore, snRNP-associated. The presence of this protein in plants, in addition to yeast, Drosophila and humans, and the conservation of large size and epitopes highlights the importance of PRP8 in pre-mRNA splicing.

Differential expression of U5snRNA gene variants in maize (Zea mays) protoplasts

The small nuclear ribonucleoprotein particles U1, U2, U4/U6 and U5 participate in the removal of introns from pre-messenger RNAs in the nucleus. Three genes encoding U5snRNAs, the RNA moiety of U5snRNPs, have been isolated from maize. As in other plant UsnRNA gene families the three maize U5snRNA genes exhibit sequence variation. Two of the gene variants (MzU5.1 and MzU5.2) are clearly expressed after transfection into maize leaf protoplasts while the third gene variant (MzU5.3) is expressed at very low levels. These different levels of expression cannot be directly correlated with sequence changes in the highly conserved Upstream Sequence Element (USE) required for expression of Arabidopsis UsnRNA genes nor with differential stability of the U5snRNA transcripts. Further sequence elements may therefore have a role in regulating maize UsnRNA gene expression.

Evolutionary conservation of the spliceosomal protein, U2B''

U1 and U2snRNPs play key roles in pre-mRNA splicing. The interactions between the U1 and U2snRNP-specific proteins, U1A, U2A' and U2B'' and their respective UsnRNAs are of interest both to elucidate their roles in splicing, and as models to study RNA-protein interactions. We have cloned a full-length cDNA, encoding U2B'', from potato. This is the first report of a sequence for a plant UsnRNP protein. The plant U2B'' sequence exhibits extensive similarity with the human U2B'' protein at both the DNA and amino acid levels. The evolutionary conservation at the protein level, particularly in sequences implicated in determining specific binding to U2snRNA, suggests conservation of U2B'' function from plants to man. The significance of amino acid substitutions in the RNP-80 motif with respect to U2snRNA binding in plants is discussed.

Sequence and expression of potato U2 snRNA genes

Plant UsnRNA multigene families show a high degree of sequence variation among individual gene members. The potato U2snRNA gene family consists of between twenty-five and forty genes. Four potato U2snRNA gene variants have been isolated. Despite the sequence variation in coding and flanking regions, all maintain the conserved U2snRNA secondary structure and all contain the plant UsnRNA promoter elements: the upstream sequence element (USE) and TATA-like box in the -70 and -30 regions respectively. In RNase A/T1 protection analyses, one of the genes, PotU2-22, protected high levels of full length U2snRNA transcripts in potato leaf, stem, root and tuber RNA. Thus, PotU2-22 or genes with identical coding regions, are highly expressed in these potato organs and therefore represent a major subset of functional U2snRNA genes. Similar expression levels of the PotU2-22 sequence variant were also found in four genetically different potato cultivars and also in tobacco, a species closely related to potato, suggesting conservation of the coding regions of expressed U2snRNA genes. A second gene, PotU2-4, protected very low levels of full length transcripts while a third gene, PotU2-11, was not expressed in the potato organs analysed. The relative expression levels of the gene variants may reflect individual gene differences in, for example, the USE and TATA regulatory elements, or variations in gene copy number.

Molecular analysis of eight U1 RNA gene candidates from tomato that could potentially be transcribed into U1 RNA sequence variants differing from each other in similar regions of secondary structure

From a tomato genomic library we isolated and characterized eight U1 RNA gene candidates (U1.1 to U1.8) all of which possessed the canonical plant U-snRNA transcription signals in their 5' and 3' flanking regions and exhibited nucleotide sequence conservation in the 5' splice site recognition sequence, in the Sm antigen binding site and in Loops B, C, D as well as in Stems III and IV of their coding region. Deviations from the U1 RNA consensus sequence were mainly localized to Loop A and Stems I and II, suggesting that the putative transcripts of the tomato U1.1-U1.8 genes would differ from each other in their capacity of binding to the U1 RNA-specific snRNP proteins.

The AU-rich sequences present in the introns of plant nuclear pre-mRNAs are required for splicing

Plant cells do not in general process the introns of transcripts expressed from introduced vertebrate genes. By studying the processing of model introns in transfected plant protoplasts, we have investigated the special requirements for intron recognition by plant cells. Our results indicate that the requirements for intron recognition in plants are different from those of both metazoa and yeast. A synthetic intron of arbitrary sequence but incorporating splice site consensus sequences and a high proportion of U and A nucleotides, a characteristic feature of plant introns, was efficiently spliced in protoplasts. We have studied the effects of various sequence alterations and conclude that AU-rich sequences are necessary for intron recognition. In addition, we find that the criteria for branch site selection are relaxed, as they are in vertebrates, but a polypyrimidine tract is not necessary.