前体mRNA的选择性多聚腺苷酸化与人类疾病

真核细胞的前体mRNA必须经过复杂的加工过程才能成熟,包括5’端加帽、剪接和3’端加工,其中3’加工包括3’端的切割和多聚腺苷酸化.该过程由前体mRNA上的顺式作用元件以及多个蛋白质因子控制.组成哺乳动物前体mRNA3’端加工机器的核心蛋白质复合体有切割和多聚腺苷酸化特异性因子、切割刺激因子、切割因子Ⅰ和切割因子Ⅱ.其他因子包括poly(A)聚合酶、poly(A)结合蛋白、偶对蛋白(symplekin)等.哺乳动物基因通常含有多个ploy(A)位点,选择性多聚腺苷酸化不仅可产生具有不同长度3’UTR的mRNA异构体,还可能改变基因的CDS区.作为真核生物基因表达调控的关键机制,选择性多聚腺苷酸化在细胞生长、增殖和分化中起着重要作用.本文综述了哺乳动物前体mRNA的3’端加工过程,3’端加工机器的组成及功能,探讨了选择性多聚腺苷酸化在多种人类疾病中的作用机制,以期为读者带来一些新的见解.     

A site-specific endonuclease and co-conversion of flanking exons associated with the mobile td intron of phage T4

The product of the td intron open reading frame (ORF) of phage T4 is required for high-frequency transfer of the intervening sequence from intron-plus (In+) to intron-minus (In-) alleles. In vivo studies have demonstrated that the td ORF product targets cleavage of td In- DNA, and that cleavage is correlated with intron inheritance [Quirk et al., Cell 56 (1989) 455-465]. In the present study we show by in vitro synthesis of the td intron ORF product, that the protein possesses endonuclease activity and efficiently cleaves double-stranded DNA at or near the site of intron integration. In addition, we demonstrate that intron insertion is accompanied by co-conversion of the flanking exon sequences. Co-conversion of markers within 50 nt surrounding the site of intron insertion occurred at a high frequency (80-100%), and decreased at greater distance from the intervening sequence. Co-conversion may provide a mechanism for maintaining exon-intron RNA contacts required for accurate splicing of the relocated intron. Cleavage of target DNA by an intron endonuclease and co-conversion of flanking exon sequences are both features associated with mobile introns of eukaryotes, indicating a common mechanism for intron transfer in the eukaryotic and prokaryotic kingdoms.     

Strand specificity of the topoisomerase II mediated double-stranded DNA cleavage reaction

The strand specificity of topoisomerase II mediated DNA cleavage was analyzed at the nucleotide level by characterizing the enzyme's interaction with a strong DNA recognition site. This site was isolated from the promoter region of the extrachromosomal rRNA genes of Tetrahymena thermophila and was recognized by type II topoisomerases from a variety of phylogenetically diverse eukaryotic organisms, including Drosophila, Tetrahymena, and calf thymus. When incubated with this site, topoisomerase II was found to introduce single-stranded breaks (i.e., nicks) in addition to double-stranded breaks in the nucleic acid backbone. Although the nucleotide position of cleavage on both the noncoding and coding strands of the rDNA remained unchanged, the relative ratios of single- and double-stranded DNA breaks could be varied by altering reaction conditions. Under all conditions which promoted topoisomerase II mediated DNA nicking, the enzyme displayed a 3-10-fold specificity for cleavage at the noncoding strand of its recognition site. To determine whether this specificity of topoisomerase II was due to a faster forward rate of cleavage of the noncoding strand or a slower rate of its religation, a DNA religation assay was performed. Results indicated that both the noncoding and coding strands were religated by the enzyme at approximately the same rate. Therefore, the DNA strand preference of topoisomerase II appears to be embodied in the enzyme's forward cleavage reaction.     

Double-stranded DNA cleavage/religation reaction of eukaryotic topoisomerase II: evidence for a nicked DNA intermediate

The DNA cleavage reaction of eukaryotic topoisomerase II produces nicked DNA along with linear nucleic acid products. Therefore, relationships between the enzyme's DNA nicking and double-stranded cleavage reactions were determined. This was accomplished by altering the pH at which assays were performed. At pH 5.0 Drosophila melanogaster topoisomerase II generated predominantly (greater than 90%) single-stranded breaks in duplex DNA. With increasing pH, less single-stranded and more double-stranded cleavage was observed, regardless of the buffer or the divalent cation employed. As has been shown for double-stranded DNA cleavage, topoisomerase II was covalently bound to nicked DNA products, and enzyme-mediated single-stranded cleavage was salt reversible. Moreover, sites of single-stranded DNA breaks were identical with those mapped for double-stranded breaks. To further characterize the enzyme's cleavage mechanism, electron microscopy studies were performed. These experiments revealed that separate polypeptide chains were complexed with both ends of linear DNA molecules generated during cleavage reactions. Finally, by use of a novel religation assay [Osheroff, N., & Zechiedrich, E. L. (1987) Biochemistry 26, 4303-4309], it was shown that nicked DNA is an obligatory kinetic intermediate in the topoisomerase II mediated reunion of double-stranded breaks. Under the conditions employed, the apparent first-order rate constant for the religation of the first break was approximately 6-fold faster than that for the religation of the second break. The above results indicate that topoisomerase II carries out double-stranded DNA cleavage/religation by making two sequential single-stranded breaks in the nucleic acid backbone, each of which is mediated by a separate subunit of the homodimeric enzyme.     

Newly established in vitro system with fluorescent proteins shows that abnormal expression of downstream prion protein-like protein in mice is probably due to functional disconnection between splicing and 3' formation of prion protein pre-mRNA

We and others previously showed that, in some lines of prion protein (PrP)-knockout mice, the downstream PrP-like protein (PrPLP/Dpl) was abnormally expressed in brains partly due to impaired cleavage/polyadenylation of the residual PrP promoter-driven pre-mRNA despite the presence of a poly(A) signal. In this study, we newly established an in vitro transient transfection system in which abnormal expression of PrPLP/Dpl can be visualized by expression of the green fluorescence protein, EGFP, in cultured cells. No EGFP was detected in cells transfected by a vector carrying a PrP genomic fragment including the region targeted in the knockout mice intact upstream of the PrPLP/Dpl gene. In contrast, deletion of the targeted region from the vector caused expression of EGFP. By employing this system with other vectors carrying various deletions or point mutations in the targeted region, we identified that disruption of the splicing elements in the PrP terminal intron caused the expression of EGFP. Recent lines of evidence indicate that terminal intron splicing and cleavage/polyadenylation of pre-mRNA are functionally linked to each other. Taken together, our newly established system shows that the abnormal expression of PrPLP/Dpl in PrP-knockout mice caused by the impaired cleavage/polyadenylation of the PrP promoter-driven pre-mRNA is due to the functional dissociation between the pre-mRNA machineries, in particular those of cleavage/polyadenylation and splicing. Our newly established in vitro system, in which the functional dissociation between the pre-mRNA machineries can be visualized by EGFP green fluorescence, may be useful for studies of the functional connection of pre-mRNA machineries.     

Loss of drug-stimulated topoisomerase II DNA breaks in living cells is different at two unrelated loci

Topoisomerase II (top2) has been implicated in the initial steps of chromosomal translocations leading to leukemias and lymphomas, since it can generate DNA cleavage. To evaluate the effects of chromatin structure on enzyme-mediated cleavage, we determined the kinetics of loss of double-stranded DNA breaks stimulated by top2 poisons in Drosophila melanogaster Kc cells at two genomic regions that differ in chromatin structure. Moreover, cleavage loss was determined at 25°C as well as after heat shock. Kinetics were dependent on the poison, nevertheless, loss rate overall was slow at the histone gene cluster, an active chromatin domain. At the repressed satellite III DNA, loss of cleavage was much faster and complete after 5 min in drug-free medium. In addition, differences were noted among sites that were closely spaced and equally intense. Following heat shock at 37°C, we observed reduced cleavage levels and faster loss of breaks at the histone gene cluster. In vitro reversal could only partially explain the in vivo kinetics. Thus, the chromatin context of DNA breaks might play a role in the loss of top2 DNA breaks. The present findings suggest that irreversible cuts may more likely occur in active than silent loci.     

A novel function for the U2AF 65 splicing factor in promoting pre-mRNA 3'-end processing

Splicing and 3′-end processing (including cleavage and polyadenylation) of vertebrate pre-mRNAs are tightly coupled events that contribute to the extensive molecular network that coordinates gene expression. Sequences within the terminal intron of genes are essential to stimulate pre-mRNA 3′-end processing, although the factors mediating this effect are unknown. Here, we show that the pyrimidine tract of the last splice acceptor site of the human β-globin gene is necessary to stimulate mRNA 3′-end formation in vivo and binds the U2AF 65 splicing factor. Naturally occurring β-thalassaemia-causing mutations within the pyrimidine tract reduces both U2AF 65 binding and 3′-end cleavage efficiency. Significantly, a fusion protein containing U2AF 65, when tethered upstream of a cleavage/polyadenylation site, increases 3′-end cleavage efficiency in vitro and in vivo. Therefore, we propose that U2AF 65 promotes 3′-end processing, which contributes to 3′-terminal exon definition.     

Heterogeneity in mammalian RNA 3′ end formation

Precisely directed cleavage and polyadenylation of mRNA is a fundamental part of eukaryotic gene expression. Yet, 3′ end heterogeneity has been documented for thousands of mammalian genes, and usage of one cleavage and polyadenylation signal over another has been shown to impact gene expression in many cases. Building upon the rich biochemical and genetic understanding of the 3′ end formation, recent genomic studies have begun to suggest that widespread changes in mRNA cleavage and polyadenylation may be a part of large, dynamic gene regulatory programs. In this review, we begin with a modest overview of the studies that defined the mechanisms of mammalian 3′ end formation, and then discuss how recent genomic studies intersect with these more traditional approaches, showing that both will be crucial for expanding our understanding of this facet of gene regulation.     

Analysis of evolution of exon-intron structure of eukaryotic genes

The availability of multiple, complete eukaryotic genome sequences allows one to address many fundamental evolutionary questions on genome scale. One such important, long-standing problem is evolution of exon-intron structure of eukaryotic genes. Analysis of orthologous genes from completely sequenced genomes revealed numerous shared intron positions in orthologous genes from animals and plants and even between animals, plants and protists. The data on shared and lineage-specific intron positions were used as the starting point for evolutionary reconstruction with parsimony and maximum-likelihood approaches. Parsimony methods produce reconstructions with intron-rich ancestors but also infer lineage-specific, in many cases, high levels of intron loss and gain. Different probabilistic models gave opposite results, apparently depending on model parameters and assumptions, from domination of intron loss, with extremely intron-rich ancestors, to dramatic excess of gains, to the point of denying any true conservation of intron positions among deep eukaryotic lineages. Development of models with adequate, realistic parameters and assumptions seems to be crucial for obtaining more definitive estimates of intron gain and loss in different eukaryotic lineages. Many shared intron positions were detected in ancestral eukaryotic paralogues which evolved by duplication prior to the divergence of extant eukaryotic lineages. These findings indicate that numerous introns were present in eukaryotic genes already at the earliest stages of evolution of eukaryotes and are compatible with the hypothesis that the original, catastrophic intron invasion accompanied the emergence of the eukaryotic cells. Comparison of various features of old and younger introns starts shedding light on probable mechanisms of intron insertion, indicating that propagation of old introns is unlikely to be a major mechanism for origin of new ones. The existence and structure of ancestral protosplice sites were addressed by examining the context of introns inserted within codons that encode amino acids conserved in all eukaryotes and, accordingly, are not subject to selection for splicing efficiency. It was shown that introns indeed predominantly insert into or are fixed in specific protosplice sites which have the consensus sequence (A/C)AG|Gt.     

The Conserved Intronic Cleavage and Polyadenylation Site of CstF-77 Gene Imparts Control of 3′ End Processing Activity through Feedback Autoregulation and by U1 snRNP

The human gene encoding the cleavage/polyadenylation (C/P) factor CstF-77 contains 21 exons. However, intron 3 (In3) accounts for nearly half of the gene region, and contains a C/P site (pA) with medium strength, leading to short mRNA isoforms with no apparent protein products. This intron contains a weak 5′ splice site (5′SS), opposite to the general trend for large introns in the human genome. Importantly, the intron size and strengths of 5′SS and pA are all highly conserved across vertebrates, and perturbation of these parameters drastically alters intronic C/P. We found that the usage of In3 pA is responsive to the expression level of CstF-77 as well as several other C/P factors, indicating it attenuates the expression of CstF-77 via a negative feedback mechanism. Significantly, intronic C/P of CstF-77 pre-mRNA correlates with global 3′UTR length across cells and tissues. In addition, inhibition of U1 snRNP also leads to regulation of the usage of In3 pA, suggesting that the C/P activity in the cell can be cross-regulated by splicing, leading to coordination between these two processes. Importantly, perturbation of CstF-77 expression leads to widespread alternative cleavage and polyadenylation (APA) and disturbance of cell proliferation and differentiation. Thus, the conserved intronic pA of the CstF-77 gene may function as a sensor for cellular C/P and splicing activities, controlling the homeostasis of CstF-77 and C/P activity and impacting cell proliferation and differentiation.     

Evidence for Drosophila P element transposase activity in mammalian cells and yeast

Drosophila P element transposase expression is limited to the germline by tissue-specific splicing of one of its three introns. Removal of this intron by mutagenesis in vitro has allowed both P element excision and transposition to be detected in Drosophila somatic tissues. In order to determine if P element transposase can function in other organisms, we have expressed modified P elements either lacking one intron or lacking all three introns in mammalian cells and yeast, respectively. Using an assay for P element excision, we have detected apparent excision events in cultured monkey cells. Furthermore, expression of the complete P element cDNA is lethal to Saccharomyces cerevisiae cells carrying a mutation in the RAD52 gene, indicating that double-stranded DNA breaks are generated, presumably by transposase action.     

Quinolone action against human topoisomerase IIalpha: stimulation of enzyme-mediated double-stranded DNA cleavage

Several important antineoplastic drugs kill cells by increasing levels of topoisomerase II-mediated DNA breaks. These compounds act by two distinct mechanisms. Agents such as etoposide inhibit the ability of topoisomerase II to ligate enzyme-linked DNA breaks. Conversely, compounds such as quinolones have little effect on ligation and are believed to stimulate the forward rate of topoisomerase II-mediated DNA cleavage. The fact that there are two scissile bonds per double-stranded DNA break implies that there are two sites for drug action in every enzyme-DNA cleavage complex. However, since agents in the latter group are believed to act by locally perturbing DNA structure, it is possible that quinolone interactions at a single scissile bond are sufficient to distort both strands of the double helix and generate an enzyme-mediated double-stranded DNA break. Therefore, an oligonucleotide system was established to further define the actions of topoisomerase II-targeted drugs that stimulate the forward rate of DNA cleavage. Results indicate that the presence of the quinolone CP-115,953 at one scissile bond increased the extent of enzyme-mediated scission at the opposite scissile bond and was sufficient to stimulate the formation of a double-stranded DNA break by human topoisomerase IIalpha. These findings stand in marked contrast to those for etoposide, which must be present at both scissile bonds to stabilize a double-stranded DNA break [Bromberg, K. D., et al. (2003) J. Biol. Chem. 278, 7406-7412]. Moreover, they underscore important mechanistic differences between drugs that enhance DNA cleavage and those that inhibit ligation.