Restriction in the cleavage activity of hammerhead ribozymes ensures ongoing evolution in prebiotic RNA world

Self-cleaving infectious RNAs found in many plant viruses and viroids can also cleave intrans and form hammerhead type secondary structure. It has been observed that the cleavage site must contain the triplet GUC. Also, in other cases, the sequence XUY holds good where X = A, C, G, U and Y = A, C, U but not G. The high electronegative nature of guanosine holds the key to its resistance to cleavage which does not allow hybrid formation between the ribozyme and substrate strands. Guanosine resistance to cleavage might have been the starting thrust for the evolution of a translational initiation codon from XUG. A hypothesis is proposed in this regard and its evolutionary consequences are discussed briefly. Presented at the National Symposium on Evolution of Life.     

Development of strategies for conditional RNA interference

BACKGROUND: RNA interference (RNAi) represents a powerful tool with which to undertake sequence-dependent suppression of gene expression. Synthesized double-stranded RNA (dsRNA) or dsRNA generated endogenously from plasmid or viral vectors can be used for RNAi. For the latter, polymerase III promoters which drive ubiquitous expression in all tissues have typically been adopted. Given that dsRNA molecules must contain few 5' and 3' over-hanging bases to maintain potency, employing polymerase II promoters to drive tissue-specific expression of RNAi may be problematic due to potential inclusion of nucleotides 5' and 3' of siRNA sequences. METHODS: To circumvent this, polymerase II promoters in combination with cis-acting hammerhead ribozymes and short-hairpin RNA sequences have been explored as a means to generate potent dsRNA molecules in tissues defined by the promoter in use. RESULTS: The novel constructs evaluated in this study produced functional siRNA which suppressed the enhanced green fluorescent protein (eGFP) both in vitro and in vivo (in mice). Additionally, the constructs did not appear to elicit a significant type-1 interferon response compared to traditional H1-transcribed shRNA. CONCLUSIONS: Given the potential 'off-target' effects of dsRNAs, it would be preferable in many cases to limit expression of dsRNA to the tissue of interest and moreover would significantly augment the resolution of RNAi technologies. Notably, the system under evaluation in this study could readily be adapted to achieve this objective.     

Secondary structure prediction of interacting RNA molecules

Computational tools for prediction of the secondary structure of two or more interacting nucleic acid molecules are useful for understanding mechanisms for ribozyme function, determining the affinity of an oligonucleotide primer to its target, and designing good antisense oligonucleotides, novel ribozymes, DNA code words, or nanostructures. Here, we introduce new algorithms for prediction of the minimum free energy pseudoknot-free secondary structure of two or more nucleic acid molecules, and for prediction of alternative low-energy (sub-optimal) secondary structures for two nucleic acid molecules. We provide a comprehensive analysis of our predictions against secondary structures of interacting RNA molecules drawn from the literature. Analysis of our tools on 17 sequences of up to 200 nucleotides that do not form pseudoknots shows that they have 79% accuracy, on average, for the minimum free energy predictions. When the best of 100 sub-optimal foldings is taken, the average accuracy increases to 91%. The accuracy decreases as the sequences increase in length and as the number of pseudoknots and tertiary interactions increases. Our algorithms extend the free energy minimization algorithm of Zuker and Stiegler for secondary structure prediction, and the sub-optimal folding algorithm by Wuchty et al. Implementations of our algorithms are freely available in the package MultiRNAFold.     

The RNA World and Its Evolution

This paper develops Belozersky’s early idea of the precedence of RNA in the origin of life on the Earth. Based on the current knowledge of the functional omnipotence of RNA, three new mechanisms are considered that could be critical for the origin and evolution of the ancient RNA world: (1) the reaction of spontaneous transesterification of polyribonucleotides in aqueous media, which has been recently discovered by A.B. Chetverin and colleagues and could result in elongation of short initial oligoribonucleotides and generate sequence variants for further selection; (2) compartmentation of functional RNA ensembles in the form of mixed molecular colonies on moist mineral surfaces, in the absence of membranes and other envelopes; and (3) systematic exponential enrichment of an RNA population with “ functionally the best” molecules due to alternating dissolution of the colonies upon flooding and formation of new colonies upon drying in ancient pools (“primordial natural SELEX”).__________Translated from Molekulyarnaya Biologiya, Vol. 39, No. 4, 2005, pp. 550–556.Original Russian Text Copyright © 2005 by Spirin.     

Thermodynamics of RNA melting,one base pair at a time

The melting of base pairs is a ubiquitous feature of RNA structural transitions, which are widely used to sense and respond to cellular stimuli. A recent study employing solution nuclear magnetic resonance (NMR) imino proton exchange spectroscopy provides a rare base-pair-specific view of duplex melting in the Salmonella FourU RNA thermosensor, which regulates gene expression in response to changes in temperature at the translational level by undergoing a melting transition. The authors observe “microscopic” enthalpy–entropy compensation—often seen “macroscopically” across a series of related molecular species—across base pairs within the same RNA. This yields variations in base-pair stabilities that are an order of magnitude smaller than corresponding variations in enthalpy and entropy. A surprising yet convincing link is established between the slopes of enthalpy–entropy correlations and RNA melting points determined by circular dichroism (CD), which argues that unfolding occurs when base-pair stabilities are equalized. A single AG-to-CG mutation, which enhances the macroscopic hairpin thermostability and folding cooperativity and renders the RNA thermometer inactive in vivo, spreads its effect microscopically throughout all base pairs in the RNA, including ones far removed from the site of mutation. The authors suggest that an extended network of hydration underlies this long-range communication. This study suggests that the deconstruction of macroscopic RNA unfolding in terms of microscopic unfolding events will require careful consideration of water interactions.     

A theoretical study of substituent effects on tautomerism of 2-hydroxybenzimidazoles

The geometries, relative stabilities of some 4(7) and 5(6) substituted 2-hydroxybenzimidazole derivatives were calculated with full geometry optimization using AM1 and PM3 in aqueous phase. With the exception of molecules 4, 6 and 7 for all the 4(7) and 5(6) substituted 2-hydroxybenzimidazole derivatives the 3H and keto forms were found to be favored.     

RNA的选择性加工对果蝇性别决定的作用

ＲＮＡ的选择性加工是真核生物基因表达调控的重要方式之一,同一种ｍＲＮＡ前体通过ＲＮＡ的选择性拼接可产生几种不同的ｍＲＮＡ,从而翻译出不同的蛋白质。ＲＮＡ的选择性加工对真核生物的发育调控是非常重要的,本文概述其在果蝇（Ｄｒｏｓｏｐｈｉｌａ）的性别决定过...     

表观遗传因素在RNA剪接过程中的作用

RNA剪接是真核生物基因表达过程中的重要环节,增加了蛋白质的多样性和基因表达的可调节性. 日益增多的研究表明,RNA剪接并不是独立的生物过程.RNA Ⅱ型聚合酶(RNA polymerase-Ⅱ, RNA Pol Ⅱ)、核小体定位和组蛋白修饰等因素都与RNA剪接过程密切相关.阐明RNA Pol Ⅱ、核小体定位和组蛋白修饰等因素在RNA剪接过程中的作用,将为剪接位点的准确识别和剪接调控机制的研究提供新思路.本文综述了RNA Pol Ⅱ、核小体定位和组蛋白修饰等因素对RNA剪接的影响以及它们在RNA剪接过程中的调控作用.     

A semiempirical study of the prototropic tautomerism of hypoxanthine

The total and relative energies, bond order matrices and localized MOs for the eight possible tautomers of hypoxanthine (HYP) have been calculated, with full geometry optimization, using both AM1 and MNDO methods. The AM1 relative energies show that HYP(9,1), HYP(7,1) and HYP (9,10) are the predominant species at room temperature, the two former being in larger concentration that the latter. The calculated IR spectra for these species agree well with the reported spectrum in an isolated matrix, which has been interpreted in terms of the presence of these three tautomeric forms. The MNDO method does not predict the right order, and the more stable tautomer would be HYP(9,10). The calculated structure for the HYP(9,1) species shows that the molecule is essentially planar. The bond distances compare well with those of hypoxanthine hydrochloride and guanine and also correlate well with the calculated bond orders. The proton affinities for the three more stable tautomers have also been calculated. For HYP(9,1) the prefered site of protonation is N7, whereas for HYP(7,1) the protonation occurs rather at N9. These results agree well with¹⁵N and¹³C NMR studies in DMSO.     

Inhibition of gene expression with ribozymes

Summary 1. Ribozymes can be designed to cleavein trans, i.e. several substrate molecules can be turned over by one molecule of the catalytic RNA. Only small molecular weight ribozymes, or small ribozymes, are discussed in this review with particular emphasis on the hammerhead ribozyme as this has been most widely used for the inhibition of gene expression by cleavage of mRNAs.2. Cellular delivery of the ribozyme is of crucial importance for the success of inhibition of gene expression by this methodology. Two modes of delivery can be envisaged, endogenous and exogenous delivery. Of the former several variants exist, depending on the vector used. The latter is still in its infancy, even though chemical modification has rendered such ribozymes resistant against degradation by serum nucleases without impairment of catalytic efficiency.3. Various successful applications of ribozymes for the inhibition of gene expression are discussed, with particular emphasis on HIV1 and cancer targets. These examples demonstrate the promise of this methodology.     

RNA molecules with conserved catalytic cores but variable peripheries fold along unique energetically optimized pathways

Functional and kinetic constraints must be efficiently balanced during the folding process of all biopolymers. To understand how homologous RNA molecules with different global architectures fold into a common core structure we determined, under identical conditions, the folding mechanisms of three phylogenetically divergent group I intron ribozymes. These ribozymes share a conserved functional core defined by topologically equivalent tertiary motifs but differ in their primary sequence, size, and structural complexity. Time-resolved hydroxyl radical probing of the backbone solvent accessible surface and catalytic activity measurements integrated with structural-kinetic modeling reveal that each ribozyme adopts a unique strategy to attain the conserved functional fold. The folding rates are not dictated by the size or the overall structural complexity, but rather by the strength of the constituent tertiary motifs which, in turn, govern the structure, stability, and lifetime of the folding intermediates. A fundamental general principle of RNA folding emerges from this study: The dominant folding flux always proceeds through an optimally structured kinetic intermediate that has sufficient stability to act as a nucleating scaffold while retaining enough conformational freedom to avoid kinetic trapping. Our results also suggest a potential role of naturally selected peripheral A-minor interactions in balancing RNA structural stability with folding efficiency.     

Isostericity and tautomerism of base pairs in nucleic acids

The natural bases of nucleic acids form a great variety of base pairs with at least two hydrogen bonds between them. They are classified in twelve main families, with the Watson–Crick family being one of them. In a given family, some of the base pairs are isosteric between them, meaning that the positions and the distances between the C1′ carbon atoms are very similar. The isostericity of Watson–Crick pairs between the complementary bases forms the basis of RNA helices and of the resulting RNA secondary structure. Several defined suites of non-Watson–Crick base pairs assemble into RNA modules that form recurrent, rather regular, building blocks of the tertiary architecture of folded RNAs. RNA modules are intrinsic to RNA architecture are therefore disconnected from a biological function specifically attached to a RNA sequence. RNA modules occur in all kingdoms of life and in structured RNAs with diverse functions. Because of chemical and geometrical constraints, isostericity between non-Watson–Crick pairs is restricted and this leads to higher sequence conservation in RNA modules with, consequently, greater difficulties in extracting 3D information from sequence analysis. Nucleic acid helices have to be recognised in several biological processes like replication or translational decoding. In polymerases and the ribosomal decoding site, the recognition occurs on the minor groove sides of the helical fragments. With the use of alternative conformations, protonated or tautomeric forms of the bases, some base pairs with Watson–Crick-like geometries can form and be stabilized. Several of these pairs with Watson–Crick-like geometries extend the concept of isostericity beyond the number of isosteric pairs formed between complementary bases. These observations set therefore limits and constraints to geometric selection in molecular recognition of complementary Watson–Crick pairs for fidelity in replication and translation processes.     

功能RNA分子的构建、表达及其在基因功能鉴定中的应用

人工构建的siRNAs、aptazymes、maxizymes以及intramers等功能RNA分子,可以在mRNA或蛋白质水平上调控基因的功能.功能RNA分子可在活体内或转基因模式动、植物中抑制目标基因的表达,使目标基因和蛋白质功能丧失,进而引起表型变异.胞内表达的活性RNAs可作为有效的研究工具应用于基因及其编码蛋白的功能鉴定,并在药物开发和人类疾病治疗上有潜在的应用前景.