A role for branchpoints in splicing in vivo

The nucleotides immediately surrounding intron/exon junctions of genes transcribed by RNA polymerase B can be derived from 'consensus' sequences for donor and acceptor splice sites by only a few base changes. Studies in vivo have underlined the importance of these junction nucleotides for splicing. In higher eukaryotes, no evidence has been found for specific internal intron sequences involved in splicing. However, the recent discovery that, in vitro, introns are excised in a lariat form where the 5' end of the intron is joined via a 2'-5'-phosphodiester linkage to an A residue (branchpoint acceptor) close to the 3' end of the intron, suggests that internal intron sequences may nonetheless be important for splicing. Indeed, in yeast nuclear genes, the internal sequence 5'-TACTAAC-3' (or close homologue) is essential for splicing in vivo. A proposed consensus sequence for branchpoints in mammalian introns is 5'-CT(A/G)A(C/T)-3'. This sequence resembles the essential yeast internal sequence. Are branchpoints involved in the splicing of introns of higher eukaryotes in vivo? We show here that a branchpoint sequence from a human globin gene (5'-CTGACTCTCTCTG-3') greatly enhances the efficiency of splicing of a 'synthetic' intron in HeLa cells. A mutated branchpoint sequence, 5'-CTCCTCTCTCTG-3', in which the branchpoint acceptor nucleotide A has been deleted and the neighbouring purine G mutated to a C, does not exhibit this enhancing capability. We conclude that branchpoints have an important function in the splicing process in vivo.     

A test for intron function in the yeast actin gene

Many eukaryotic genes contain intervening sequences (IVS), but the rationale for their existence remains a mystery. Previous studies done in our laboratory demonstrated that the intron in a yeast tRNATyr gene, SUP6, does have a function. We used the same approach to determine the role of introns in nuclear genes encoding messenger RNAs. A single actin gene with one intron exists in Saccharomyces cerevisiae. The level of actin in yeast appears to be crucial to viability: either too much or too little actin inhibits growth. Therefore, small effects on synthesis of actin protein resulting from the removal of the actin gene intron would be expected to cause measurable changes in cell growth. In the present study, an intron-deleted actin gene was constructed in vitro and was used to replace the single resident actin gene in a haploid strain. Analysis of the cells carrying the intron-deleted actin gene shows that the intervening sequence is not essential for actin gene expression.     

中国四个小型猪品种生长激素基因克隆测序及分子进化研究

研究对中国四个小型猪五指山猪、贵州香猪、滇南小耳猪和藏猪的生长激素基因(pGH,porcine growth hormone)进行了克隆测序及构建分子进化树,考察该激素对小型猪体型的影响。通过筛选合适的引物,采用PCR技术,扩增了四个小型猪品种的pGH基因全序列,并对其进行了克隆测序分析。4个小型猪品种pGH基因全长为2006bp,包括5个外显子和4个内含子,CDS全长为648bp。将4个品种小型猪和长白猪、雅南猪、内江猪进行了核苷酸序列比对,共有63处发生了变异,变异率为2.9%,其中外显子有12处变异,全部为转换;内含子有51处发生了变异,包括转换、颠换和缺失。聚类结果基本符合其地方猪种的地理位置分布原则。     

Structure of the human immune interferon gene

Sequence determination of cloned cDNAs and genes of the three classes of interferon (IFN-alpha, -beta and -gamma) has revealed more than a dozen members of the human IFN-alpha gene family and a single gene for IFN-beta. These genes are found on chromosome 9 and contain no introns. We recently reported that the 146-amino acid sequence of mature IFN-gamma deduced from the nucleotide sequence of a cloned cDNA was quite unrelated to those of the other IFNs, and that the gene for IFN-gamma contains at least one intron. We now describe the isolation, characterization and DNA sequence of the human IFN-gamma gene. It contains three introns, a repetitive DNA element, and is not highly polymorphic. All our evidence to date and the present data suggest that this is the only gene for IFN-gamma and that the resolution of IFN-gamma into two components is probably the result of post-translational processing of the protein.     

Mechanism of recognition of the 5' splice site in self-splicing group I introns

Group I introns include many mitochondrial ribosomal RNA and messenger RNA introns and the nuclear rRNA introns of Tetrahymena and Physarum. The splicing of precursor RNAs containing these introns is a two-step reaction. Cleavage at the 5' splice site precedes cleavage at the 3' splice site, the latter cleavage being coupled with exon ligation. Following the first cleavage, the 5' exon must somehow be held in place for ligation. We have now tested the reactivity of two self-splicing group I RNAs, the Tetrahymena pre-rRNA and the intron 1 portion of the Neurospora mitochondrial cytochrome b (cob) pre-mRNA, in the intermolecular exon ligation reaction (splicing in trans) described by Inoue et al. The different sequence specificity of the reactions supports the idea that the nucleotides immediately upstream from the 5' splice site are base-paired to an internal, 5' exon-binding site, in agreement with RNA structure models proposed by Davies and co-workers and others. The internal binding site is proposed to be involved in the formation of a structure that specifies the 5' splice site and, following the first step of splicing, to hold the 5' exon in place for exon ligation.     

Unusual sequences in the murine immunoglobulin mu-delta heavy-chain region

The delta heavy (H) chain of mouse immunoglobulin D (IgD) is unusual both in its structure and in its differential expression relative to immunoglobulin M (IgM; reviewed in ref. 1). The region of DNA between IgM and IgD H-chain constant-region genes is probably implicated in this control. So far only fragments of the area have been sequenced. Now, however, we present the complete sequence as well as the sequence of the introns of the C delta gene. We have found several interesting features (Fig. 1), including an open reading frame (ORF) between Cmu and C delta which encodes 146 amino acids that might represent a previously unsuspected domain-like protein; three blocks of simple repetitive sequences; a 162-base pair (bp) unique-sequence inverted repeat; and a domain-like pseudogene in the large intron of C delta. We have not found, however, any sequence 5' of C delta resembling the switch (S) recombination sequences associated with class switching in other heavy chains. Moreover, we have determined the 3' deletion end point of an IgD-producing myeloma and find no sequences reminiscent of switch sites nearby.     

Nucleotide sequence of the rat skeletal muscle actin gene

The actins constitute a family of highly conserved proteins found in all eukaryotic cells. Their conservation through a very wide range of taxonomic groups and the existence of tissue-specific isoforms make the actin genes very interesting for the study of the evolution of genes and their controlling elements. On the basis of amino acid sequence data, at least six different mammalian actins have been identified (skeletal muscle, cardiac muscle, two smooth muscle actins and the cytoplasmic beta- and gamma-actins). Rat spleen DNA digested by the EcoRI restriction enzyme contains at least 12 different fragments with actin-like sequences but only one which hybridized, in very stringent conditions, with the skeletal muscle cloned cDNA probe. Here we describe the sequence of the actin gene in that fragment. The nucleotide sequence codes for two amino acids, Met-Cys, preceding the known N-terminal Asp of the mature protein. There are five small introns in the coding region and a large intron in the 5'-untranslated region. Comparison of the structure of the rat skeletal muscle actin gene with available data on actin genes from other organisms shows that while the sequenced actin genes from Drosophila and yeast have introns at different locations, introns located at codons specifying amino acids 41, 121, 204 and 267 have been preserved at least from the echinoderm to the vertebrates. A similar analysis has been done by Davidson. An intron at codon 150 is common to a plant actin gene and the skeletal muscle acting gene.     

Introns in higher plant genes

The intron is an important component of eukaryotic gene. Extensive studies have been conducted to get a better understanding of its structure and function. This paper presents a brief review of the structure and function of introns in higher plant genes. It is shown that higher plant introns possess structural properties shared by all eukaryotic introns, however, they also exhibit a striking degree of diversity. The process of intron splicing in higher plant genes involves interaction between multiple cis-acting elements and trans-acting factors, such as 5′ splicing site, 3′ splicing site and many protein factors. The process of intron splicing is an important level at which gene expression is regulated. Especially alternative splicing of intron can regulate time and space of gene expression. In addition, some introns in higher plant genes also regulate gene expression by affecting the pattern of gene expression, enhancing the level of gene expression and driving the gene expression.     

Translational control of intron splicing in eukaryotes

Most eukaryotic genes are interrupted by non-coding introns that must be accurately removed from pre-messenger RNAs to produce translatable mRNAs. Splicing is guided locally by short conserved sequences, but genes typically contain many potential splice sites, and the mechanisms specifying the correct sites remain poorly understood. In most organisms, short introns recognized by the intron definition mechanism cannot be efficiently predicted solely on the basis of sequence motifs. In multicellular eukaryotes, long introns are recognized through exon definition and most genes produce multiple mRNA variants through alternative splicing. The nonsense-mediated mRNA decay (NMD) pathway may further shape the observed sets of variants by selectively degrading those containing premature termination codons, which are frequently produced in mammals. Here we show that the tiny introns of the ciliate Paramecium tetraurelia are under strong selective pressure to cause premature termination of mRNA translation in the event of intron retention, and that the same bias is observed among the short introns of plants, fungi and animals. By knocking down the two P. tetraurelia genes encoding UPF1, a protein that is crucial in NMD, we show that the intrinsic efficiency of splicing varies widely among introns and that NMD activity can significantly reduce the fraction of unspliced mRNAs. The results suggest that, independently of alternative splicing, species with large intron numbers universally rely on NMD to compensate for suboptimal splicing efficiency and accuracy.     

Isolation of tomato proteinase inhibitor Ⅱ gene and the function of its intron

The genomic DNA sequence of tomato proteinase inhibitor Ⅱ gene (named tin2i, whose accession number in GenBank is AF007240) was isolated by PCR techniques. The intron sequence (TPI), with a length of 109 bp, owns typical structures of GT/AG dinucleotides at both ends and high content of AT base pairs which accounts for 80.7% of the total nucleotides. As shown by recombination experiment, the TPI sequence could efficiently promote the expression of the reporter gene gusA and this effect was independent of the position and orientation of the intron, thus showing its role as an enhancer. Such experiments as gel retardation assays, GUS histochemical staining and GUS fluorometric assays further demonstrated that TPI sequence maybe has promoter-like activity.     

A tertiary interaction that links active-site domains to the 5' splice site of a group II intron

Group II introns are self-splicing RNAs that are commonly found in the genes of plants, fungi, yeast and bacteria. Little is known about the tertiary structure of group II introns, which are among the largest natural ribozymes. The most conserved region of the intron is domain 5 (D5), which, together with domain 1 (D1), is required for all reactions catalysed by the intron. Despite the importance of D5, its spatial relationship and tertiary contacts to other active-site constituents have remained obscure. Furthermore, D5 has never been placed directly at a site of catalysis by the intron. Here we show that a set of tertiary interactions (lambda-lambda') links catalytically essential regions of D5 and D1, creating the framework for an active-site and anchoring it at the 5' splice site. Highly conserved elements similar to components of the lambda-lambda' interaction are found in the eukaryotic spliceosome.     

Isolation of tomato proteinase inhibitor II gene and the function of its intron

The genomic DNA sequence of tomato proteinase inhibitor II gene (named tin2i, whose accession number in GenBank is AF007240) was isolated by PCR techniques. The intron sequence (TPI), with a length of 109 bp, owns typical structures of GT/AG dinucleotides at both ends and high content of AT base pairs which accounts for 80.7% of the total nucleotides. As shown by recombination experiment, the TPI sequence could efficiently promote the expression of the reporter gene gusA and this effect was independent of the position and orientation of the intron, thus showing its role as an enhancer. Such experiments as gel retardation assays, GUS histochemical staining and GUS fluorometric assays further demonstrated that TPI sequence maybe has promoter-like activity.     

Human U2 snRNA can function in pre-mRNA splicing in yeast

The removal of introns from messenger RNA precursors requires five small nuclear RNAs (snRNAs), contained within ribonucleoprotein particles (snRNPs), which complex with the pre-mRNA and other associated factors to form the spliceosome. In both yeast and mammals, the U2 snRNA base pairs with sequences surrounding the site of lariat formation. Binding of U2 snRNP to the highly degenerate branchpoint sequence in mammalian introns is absolutely dependent on an auxiliary protein, U2AF, which recognizes a polypyrimidine stretch adjacent to the 3' splice site. The absence of this sequence motif in yeast introns has strengthened arguments that the two systems are fundamentally different. Deletion analyses of the yeast U2 gene have confirmed that the highly conserved 5' domain is essential, although the adjacent approximately 950 nucleotides can be deleted without any phenotypic consequence. A 3'-terminal domain of approximately 100 nucleotides is also required for wild-type growth rates; the highly conserved terminal loop within this domain (loop IV) may provide specific binding contacts for two U2-specific snRNP proteins. We have replaced the single copy yeast U2 (yU2) gene with human U2 (hU2), expecting that weak or no complementation would provide an assay for cloning additional splicing factors, such as U2AF. We report here that hU2 can complement the yeast deletion with surprising efficiency. The interactions governing spliceosome assembly and intron recognition are thus more conserved than previously suspected. Paradoxically, the conserved loop IV sequence is dispensable in yeast.     

A 3' splice site-binding sequence in the catalytic core of a group I intron

Ribozymes use specific RNA-RNA interactions for substrate binding and active-site formation. Self-splicing group I introns have approximately 70 nucleotides constituting the core, a region containing sequences and structures indispensable for catalytic function. The catalytic core must interact with the substrates used for the two steps of the self-splicing reaction, that is, guanosine, the 5'-splice-site helix (P1) and the 3' splice site. Mutational evidence suggests that core sequences near segment J6/7 that joins the base-paired stems P6 and P7, and the bulged base of P7(5'), participate in binding guanosine substrate, but nothing is known about the interactions between the core, the 5'-splice-site helix and the 3' splice site. On the basis of comparative sequence data, it has been suggested that two specific bases in the catalytic core of group I introns might form a binding sequence for the 3' splice site. Here we present genetic evidence that such a binding site exists in the core of the Tetrahymena large subunit ribosomal RNA intron. We demonstrate that this pairing, termed P9.0, is functionally important in the exon ligation step of self-splicing, but is not itself responsible for 3'-splice-site selection.     

菊花‘千手观音’LEAFY基因转录区基因组克隆和结构分析

LEAFY(LFY)基因在植物花发育过程中具有重要作用,不仅控制着花序分生组织向花分生组织的转变,而且控制着开花时间.通过基因组PCR扩增,获得了菊花‘千手观音’LFY同源基因序列.序列分析表明该基因包括2个内含子和3个外显子.其内含子1的2个序列长短不同,差异明显.2个内含子与甘菊的LFY同源基因DFL相比都表现出了丰富的变异性.其外显子推测的氨基酸序列与甘菊DFL的氨基酸序列相似性达99%.系统进化分析表明‘千手观音’的LFY同源基因与所有的菊属植物的LFY基因在树的同一枝上,且距双子叶植物的距离近于单子叶或裸子植物.Southern杂交表明,‘千手观音’基因组中LFY同源基因以两个拷贝形式存在.     

Spontaneous shuffling of domains between introns of phage T4

The three self-splicing introns in phage T4 (in the td, sunY and nrdB genes) (Fig. 1a) each have the conserved group I catalytic RNA core structure (Fig. 1b), out of which is looped an open reading frame. Although the core sequences are very similar (approximately 60% identity), the open reading frames seem to be unrelated. Single crossover recombination events between homologous core sequences in the closely linked td and nrdB introns have led to 'exon shuffling. Here we describe spontaneous double crossovers between the unlinked td and sun Y introns that result in shuffling of an intron structure element, P7.1 (refs 3 and 4). The intron domain-switch variants were isolated as genetic suppressors of a splicing-defective P7.1 deletion in the td intron. This unprecedented example of suppression through inter-intron sequence substitution indicates that the introns are in a state of genetic flux and implies the functional interchangeability of the two analogous but nonidentical P7.1 elements. The implications of such recombination events are discussed in the light of the evolution of the introns themselves as well as that of their host genomes.     

Intron-dependent evolution of chicken glyceraldehyde phosphate dehydrogenase gene

The function of introns in the evolution of genes can be explained in at least two ways: either introns appeared late in evolution and therefore could not have participated in the construction of primordial genes, or RNA splicing and introns existed in the earliest organisms but were lost during the evolution of the modern prokaryotes. The latter alternative allows the possibility of intron participation in the formation of primordial genes before the divergence of modern prokaryotes and eukaryotes. Blake suggested that evidence for intron-facilitated evolution of a gene might be found by comparing the borders of functional protein domains with the placement of introns. We therefore examined glyceraldehyde phosphate dehydrogenase (GAPDH), a glycolytic enzyme, because it is the first protein for which the following data are available: X-ray crystallographic studies demonstrating structurally independent protein 'domains' which were highly conserved during the divergence of prokaryotes and eukaryotes; and a study of genomic organization which mapped introns in the gene. Sequencing of the chicken GAPDH gene revealed 11 introns. We report here that sites of three of the introns (IV, VI and XI) correspond closely with the borders of the NAD-binding, catalytic and helical tail domains of the enzyme, supporting the hypothesis that introns did have a role in the evolution of primitive genes. In addition, other biochemical and structural data were used to construct a model of the intron-mediated assembly of the GAPDH gene that explains the existence of 10 introns.     

Cleavage of 5' splice site and lariat formation are independent of 3' splice site in yeast mRNA splicing

Analysis of messenger RNA splicing in yeast and in metazoa has led to the identification of an RNA molecule in a lariat conformation. This structure has been found as an mRNA splicing intermediate in vitro and identical molecules have been identified in vivo. Lariat formation involves cleavage of the precursor at the 5' splice site (5' SS) and the formation of a 2'-5' phosphodiester bond between the guanosine residue at the 5' end of the intron and an adenosine within the intron. The yeast branchpoint is located within the absolutely conserved TACTAAC box (that is, the last A of the TACTAAC box is the site of formation of the 2'-5' phosphodiester bond with the 5' end of the intron)3,4. Moreover, efficient 5' SS cleavage and lariat formation require proper sequences at the 5' splice junction and within the TACTAAC box. Here we demonstrate that 5' SS cleavage and lariat formation take place in vitro in the absence of the 3' SS and much of the 3' junction. These results are discussed in light of possible differences between yeast and metazoan mRNA splicing.