用ribozyme抑制增殖细胞核抗原的表达对HaLa细胞增殖的影响

增殖细胞核抗原(PCNA)是DNA聚合酶δ的辅助蛋白,它是细胞染色体DNA复制所必需的。人工设计的ribozyme具有可特异地切割PCNA mRNA的性质,将此ribozyme的自修剪体内表达质粒导入HeLa细胞,从细胞总RNA中分离相应部分能在体外切割靶RNA片段,证明此表达质粒在细胞内能表达出有活性的ribozyme分子。与对照相比,导入ribo-zyme表达质粒的HeLa细胞进入S期的时间从12 h推迟到20 h,而突变ribozyme的对照表明反义抑制对细胞进入S期的影响较小(推迟到15 h)。证明该ribozyme能有效抑制He-La细胞DNA复制,同时亦证明PCNA对于细胞DNA复制及细胞周期进程的重要性。     

Trans-splicing of a mutated glycosylasparaginase mRNA sequence by a group I ribozyme deficient in hydrolysis.

RNA reprogramming represents a new concept in correcting genetic defects at the RNA level. However, for the technique to be useful for therapy, the level of reprogramming must be appropriate. To improve the efficiency of group I ribozyme-mediated RNA reprogramming, when using the Tetrahymena ribozyme, regions complementary to the target RNA have previously been extended in length and accessible sites in the target RNAs have been identified. As an alternative to the Tetrahymena model ribozyme, the DiGIR2 group I ribozyme, derived from a mobile group I intron in rDNA of the myxomycete Didymium iridis, represents a new and attractive tool in RNA reprogramming. We reported recently that the deletion of a structural element within the P9 domain of DiGIR2 turns off hydrolysis at the 3' splice site (side reaction) without affecting self-splicing [Haugen, P., Andreassen, M., Birgisdottir, A.B. & Johansen, S.D. (2004) Eur. J. Biochem. 271, 1015-1024]. Here we analyze the potential of the modified ribozyme, deficient in hydrolysis at the 3' splice site, for application in group I ribozyme-mediated trans-splicing of RNA. The improved ribozyme catalyses both cis-splicing and trans-splicing in vitro of a human glycosylasparaginase mRNA sequence with the same efficiency as the original DiGIR2 ribozyme, but without detectable levels of the unwanted hydrolysis.     

Improved polymerase ribozyme efficiency on hydrophobic assemblies

During an early step in the evolution of life, RNA served both as genome and as catalyst, according to the RNA world hypothesis. For self-replication, the RNA organisms must have contained an RNA that catalyzes RNA polymerization. As a first step toward recapitulating an RNA world in the laboratory, a polymerase ribozyme was generated previously by in vitro evolution and design. However, the efficiency of this ribozyme is about 100-fold too low for self-replication because of a low affinity of the ribozyme to its primer/template substrate. To improve the substrate interactions by colocalizing ribozyme and substrate on micelles, we attached hydrophobic anchors to both RNAs. We show here that the hydrophobic anchors led to aggregates with the expected size of the corresponding micelles. The micelle formation increased the polymerization yield of full-length products by 3- to 20-fold, depending on substrates and reaction conditions. With the best-characterized substrate, the improvement in polymerization efficiency was primarily due to reduced sequence-specific stalling on partially extended substrates. We discuss how, during the origin of life, micellar ribozyme aggregates could have acted as precursors to membrane-encapsulated life forms.     

Nucleotide synthetase ribozymes may have emerged first in the RNA world

Though the "RNA world" hypothesis has gained a central role in ideas concerning the origin of life, the scenario concerning its emergence remains uncertain. It has been speculated that the first scene may have been the emergence of a template-dependent RNA synthetase ribozyme, which catalyzed its own replication: thus, "RNA replicase." However, the speculation remains uncertain, primarily because of the large sequence length requirement of such a replicase and the lack of a convincing mechanism to ensure its self-favoring features. Instead, we propose a nucleotide synthetase ribozyme as an alternative candidate, especially considering recent experimental evidence suggesting the possibility of effective nonenzymatic template-directed synthesis of RNA. A computer simulation was conducted to support our proposal. The conditions for the emergence of the nucleotide synthetase ribozyme are discussed, based on dynamic analysis on a computer. We suggest the template-dependent RNA synthetase ribozyme emerged later, perhaps after the emergence of protocells.     

The dawn of the RNA World: Toward functional complexity through ligation of random RNA oligomers

A main unsolved problem in the RNA World scenario for the origin of life is how a template-dependent RNA polymerase ribozyme emerged from short RNA oligomers obtained by random polymerization on mineral surfaces. A number of computational studies have shown that the structural repertoire yielded by that process is dominated by topologically simple structures, notably hairpin-like ones. A fraction of these could display RNA ligase activity and catalyze the assembly of larger, eventually functional RNA molecules retaining their previous modular structure: molecular complexity increases but template replication is absent. This allows us to build up a stepwise model of ligation-based, modular evolution that could pave the way to the emergence of a ribozyme with RNA replicase activity, step at which information-driven Darwinian evolution would be triggered.     

Single VS ribozyme molecules reveal dynamic and hierarchical folding toward catalysis

Non-coding RNAs of complex tertiary structure are involved in numerous aspects of the replication and processing of genetic information in many organisms; however, an understanding of the complex relationship between their structural dynamics and function is only slowly emerging. The Neurospora Varkud Satellite (VS) ribozyme provides a model system to address this relationship. First, it adopts a tertiary structure assembled from common elements, a kissing loop and two three-way junctions. Second, catalytic activity of the ribozyme is essential for replication of VS RNA in vivo and can be readily assayed in vitro. Here we exploit single molecule FRET to show that the VS ribozyme exhibits previously unobserved dynamic and heterogeneous hierarchical folding into an active structure. Readily reversible kissing loop formation combined with slow cleavage of the upstream substrate helix suggests a model whereby the structural dynamics of the VS ribozyme favor cleavage of the substrate downstream of the ribozyme core instead. This preference is expected to facilitate processing of the multimeric RNA replication intermediate into circular VS RNA, which is the predominant form observed in vivo.     

Hammerhead ribozymes selectively suppress mutant type I collagen mRNA in osteogenesis imperfecta fibroblasts

Ribozymes are a promising agent for the gene therapy of dominant negative genetic disorders by allele-specific mRNA suppression. To test allele-specific mRNA suppression in cells, we used fibroblasts from a patient with osteogenesis imperfecta (OI). These cells contain a mutation in one α1(I) collagen allele which both causes the skeletal disorder and generates a novel ribozyme cleavage site. In a preliminary in vitro assay, ribozymes cleaved mutant RNA substrate whereas normal substrate was left intact. For the studies in cell culture we generated cell lines stably expressing active (AR) and inactive (IR) ribozymes targeted to mutant α1(I) collagen mRNA. Quantitative competitive RT–PCR analyses of type I collagen mRNA, normalized to β-actin expression levels, revealed that the level of mutant α1(I) collagen mRNA was significantly decreased by ~50% in cells expressing AR. Normal α1(I) collagen mRNA showed no significant reduction when AR or IR was expressed from the pHβAPr-1-neo vector and a small (10–20%) but significant reduction when either ribozyme was expressed from the pCI.neo vector. In clonal lines derived from cells expressing AR the level of ribozyme expression correlated with the extent of reduction in the mutant:normal α1(I) mRNA ratio, ranging from 0.33 to 0.96. Stable expression of active ribozyme did not affect cell viability, as assessed by growth rates. Ribozyme cleavage of mutant mRNA results in a reduction in mutant type I collagen protein, as demonstrated by SDS–urea–PAGE. This is the first report of ribozymes causing specific suppression of an endogenous mutant mRNA in cells derived from a patient with a dominant negative genetic disorder.     

One RNA plays three roles to provide catalytic activity to a group I intron lacking an endogenous internal guide sequence

Catalytic RNA molecules possess simultaneously a genotype and a phenotype. However, a single RNA genotype has the potential to adopt two or perhaps more distinct phenotypes as a result of differential folding and/or catalytic activity. Such multifunctionality would be particularly significant if the phenotypes were functionally inter-related in a common biochemical pathway. Here, this phenomenon is demonstrated by the ability of the Azoarcus group I ribozyme to function when its canonical internal guide sequence (GUG) has been removed from the 5′ end of the molecule, and added back exogenously in trans. The presence of GUG triplets in non-covalent fragments of the ribozyme allow trans-splicing to occur in both a reverse splicing assay and a covalent self-assembly assay in which the internal guide sequence (IGS)-less ribozyme can put itself together from two of its component pieces. Analysis of these reactions indicates that a single RNA fragment can perform up to three distinct roles in a reaction: behaving as a portion of a catalyst, behaving as a substrate, and providing an exogenous IGS. This property of RNA to be multifunctional in a single reaction pathway bolsters the probability that a system of self-replicating molecules could have existed in an RNA world during the origins of life on the Earth.     

RNase P ribozyme inhibits cytomegalovirus replication by blocking the expression of viral capsid proteins

By linking a guide sequence to the catalytic RNA subunit of RNase P (M1 RNA), we constructed a functional ribozyme (M1GS RNA) that targets the overlapping mRNA region of two human cytomegalovirus (HCMV) capsid proteins, the capsid scaffolding protein (CSP) and assemblin, which are essential for viral capsid formation. The ribozyme efficiently cleaved the target mRNA sequence in vitro. Moreover, a reduction of >85% in the expression of CSP and assemblin and a reduction of 4000-fold in viral growth were observed in the HCMV-infected cells that expressed the functional ribozyme. In contrast, there was no significant reduction in viral gene expression and growth in virus-infected cells that either did not express the ribozyme or produced a ‘disabled’ ribozyme carrying mutations that abolished its catalytic activity. Characterization of the effects of the ribozyme on the HCMV lytic replication cycle further indicates that the expression of the functional ribozyme specifically inhibits the expression of CSP and assemblin, and consequently blocks viral capsid formation and growth. Our results provide the direct evidence that RNase P ribozymes can be used as an effective gene-targeting agent for antiviral applications, including abolishing HCMV growth by blocking the expression of the virus-encoded capsid proteins.     

A ribonucleopeptide world at the origin of life

The structural flexibility of RNA and its ability to store genetic information has led scientists to postulate that RNA could be the key molecule for the development of life on Earth, further leading to formulate the RNA world hypothesis that received a lot of success and acceptance after the discoveries of the last thirty‐five years. Despite its highly structural and functional significance, the difficulty in synthesizing the four nucleobases that form the RNA polymer from the same primordial soup, its low stability, and limited catalytic repertoire, make the RNA world hypothesis less convincing even though it remains the best explanation for the origin of life. An increasing number of scientists are becoming more supportive of a more realistic approach explaining the appearance of life. In this review, I propose an enhanced explanation for the appearance of life supported by recent discoveries and theories. Accordingly, amino acids and peptides associated with RNA (e.g., ribonucleopeptides) might have existed at the onset of RNA and might have played an important role in the continuous development of self‐sustaining biological systems. Therefore, in this review, I cover the most recent and relevant scientific investigations that propose a better understanding of the ribonucleopeptide world hypothesis and the appearance of life. Finally, I propose two hypotheses for a primitive translation machinery (PTM) that might have been formed of either a T box ribozyme or a ribopolymerase.     

The emergence of ribozymes synthesizing membrane components in RNA-based protocells

A significant problem of the origin of life is the emergence of cellular self-replication. In the context of the “RNA world”, a crucial concern is how the RNA-based protocells could achieve the ability to produce their own membrane. Here we show, with the aid of a computer simulation, that for these protocells, there would be “immediately” a selection pressure for the emergence of a ribozyme synthesizing membrane components. The ribozyme would promote the enlargement of cellular space and favor the incoming (by permeation) of RNA's precursors, thus benefit the replication of inner RNA, including itself. Via growth and division, protocells containing the ribozyme would achieve superiority and spread in the system, and meanwhile the ribozyme would spread in the system. The present work is inspiring because it suggests that the transition from molecular self-replication to cellular self-replication might have occurred naturally (and necessarily) in the origin of life, leading to the emergence of Darwinian evolution at the cellular level.     

Replication of an RNA ligase ribozyme under alternating temperature condition

Self-replication process of the RNA ligase ribozyme molecules was investigated by using the modified RNA ligase ribozyme under alternating temperature condition that enhances turnover rate of the RNA ligation reaction. In our experiment, the RNA ligase ribozyme system mainly undergoes a cross-catalytic replication process, in which two ribozymes catalyze each other's synthesis from a total of four RNA substrates under alternating temperature condition, resulting in time-dependent accumulation of additional copies of the starting ribozymes in a reaction mixture. The present study demonstrates that cross-catalytic replication in nucleic acids system can be efficiently devised under the alternating temperature condition.