基于核酶开关的哺乳细胞内硫胺素焦磷酸荧光生物传感器的建立

硫胺素焦磷酸(Thiamine pyrophosphate,TPP)是维生素B1在细胞内的主要活性形式,也是糖、脂肪酸和氨基酸氧化代谢中重要的辅助因子.在细胞内,利用TPP适配体与天然核酶组装成的人工核酶开关调节靶基因表达,目前仅局限于原核、真菌或植物细胞.本实验将原核生物中筛选的“Switch-on”与“Switch-off"的两种类型的TPP核酶开关,运用重叠延伸PCR的方法构建于增强绿色荧光蛋白(EGFP)报告基因的3'非翻译区(UTR),转染人胚肾上皮细胞(HEK293),通过荧光显微镜和流式细胞仪分析,观察了不同浓度TPP对EGFP表达能力的调控.结果表明,构建的两种“Switch-on”和一种“Switch-off”核酶开关均表现出明显的TPP浓度依赖性,且具有良好的特异性,在150 μmol/L TPP时分别将EGFP的荧光强度提高3.1倍、1.9倍和降低2.3倍.这种构建通过TPP与核酶开关中其适配体的特异性作用直接将TPP浓度的变化转化为报告基因表达的改变,利于通过荧光检测方法实现对哺乳活细胞内代谢物或因子的无标记、无损伤、可视、高效的检测.     

Kinetic Footprinting of an RNA-Folding Pathway Using Peroxynitrous Acid

Following footprints to discover a path is easier with peroxynitrous acid. The folding of the Tetrahymena ribozyme was studied using this readily available reagent to generate hydroxyl radicals for kinetic footprinting studies. The different domains of the ribozyme appear to assemble at different rates following an ordered, hierarchical pathway (see scheme).     

In vitro evolution of a ribozyme that contains 5-bromouridine.

The Tetrahymena group I ribozyme was modified by replacing all 99 component uridine residues with 5-bromouridine. This resulted in a 13-fold reduction in catalytic efficiency in the RNA-catalyzed phosphoester-transfer reaction compared to the behavior of the unmodified ribozyme. A population of 10(13) variant ribozymes was constructed, each containing 5-bromouridine in place of uridine. Five successive 'generations' of in vitro evolution were carried out, selecting for improved phosphoester transferase activity. The evolved molecules exhibited a 27-fold increase in catalytic efficiency compared to the wild-type bromouridine-containing ribozyme, even exceeding that of the wild-type ribozyme in the non-brominated form. Three specific mutations were found to be responsible for this altered behavior. These mutations enhanced activity in the context of 5-bromouridine, but were detrimental in the context of unmodified uridine. The evolved RNAs not only tolerated but came to exploit the presence of the nucleotide analogue in carrying out their catalytic function.     

Chemical synthesis of oligoribonucleotides containing 2-aminopurine: substrates for the investigation of ribozyme function

The chemical synthesis of a fully protected ribonucleoside phosphoramidite, containing 2-aminopurine as the base component, and its incorporation into short oligoribonucleotides as substrates for an engineered ribozyme from Tetrahymena is described.     

A phosphoramidate substrate analog is a competitive inhibitor of the Tetrahymena group I ribozyme

BACKGROUND: Phosphoramidate oligonucleotide analogs containing N3'-P5' linkages share many structural properties with natural nucleic acids and can be recognized by some RNA-binding proteins. Therefore, if the N-P bond is resistant to nucleolytic cleavage, these analogs may be effective substrate analog inhibitors of certain enzymes that hydrolyze RNA. We have explored the ability of the Tetrahymena group I intron ribozyme to bind and cleave DNA and RNA phosphoramidate analogs. RESULTS: The Tetrahymena group I ribozyme efficiently binds to phosphoramidate oligonucleotides but is unable to cleave the N3'-P5' bond. Although it adopts an A-form helical structure, the deoxyribo-phosphoramidate analog, like DNA, does not dock efficiently into the ribozyme catalytic core. In contrast, the ribo-phosphoramidate analog docks similarly to the native RNA substrate, and behaves as a competitive inhibitor of the group I intron 5' splicing reaction. CONCLUSIONS: Ribo-N3'-P5' phosphoramidate oligonucleotides are useful tools for structural and functional studies of ribozymes as well as protein-RNA interactions.     

A role for a single-stranded junction in RNA binding and specificity by the Tetrahymena group I ribozyme

We have investigated the role of a single-stranded RNA junction, J1/2, that connects the substrate-containing P1 duplex to the remainder of the Tetrahymena group I ribozyme. Single-turnover kinetics, fluorescence anisotropy, and single-molecule fluorescence resonance energy transfer studies of a series of J1/2 mutants were used to probe the sequence dependence of the catalytic activity, the P1 dynamics, and the thermodynamics of docking of the P1 duplex into the ribozyme's catalytic core. We found that A29, the center A of three adenosine residues in J1/2, contributes 2 orders of magnitude to the overall ribozyme activity, and double-mutant cycles suggested that J1/2 stabilizes the docked state of P1 over the undocked state via a tertiary interaction involving A29 and the first base pair in helix P2 of the ribozyme, A31·U56. Comparative sequence analysis of this group I intron subclass suggests that the A29 interaction sets one end of a molecular ruler whose other end specifies the 5'-splice site and that this molecular ruler is conserved among a subclass of group I introns related to the Tetrahymena intron. Our results reveal substantial functional effects from a seemingly simple single-stranded RNA junction and suggest that junction sequences may evolve rapidly to provide important interactions in functional RNAs.     

Generalized RNA-directed recombination of RNA

RNA strand exchange through phosphor-nucleotidyl transfer reactions is an intrinsic chemistry promoted by group I intron ribozymes. We show here that Tetrahymena and Azoarcus ribozymes can promote RNA oligonucleotide recombination in either two-pot or one-pot schemes. These ribozymes bind one oligonucleotide, cleave following a guide sequence, transfer the 3' portion of the oligo to their own 3' end, bind a second oligo, and catalyze another transfer reaction to generate recombinant oligos. Recombination is most effective with the Azoarcus ribozyme in a single reaction vessel in which over 75% of the second oligo can be rapidly converted to recombinant product. The Azoarcus ribozyme can also create a new functional RNA, a hammerhead ribozyme, which can be constructed via recombination and then immediately promote its own catalysis in a homogeneous milieu, mimicking events in a prebiotic soup.     

Charge density of divalent metal cations determines RNA stability

RNA molecules are exquisitely sensitive to the properties of counterions. The folding equilibrium of the Tetrahymena ribozyme is measured by nondenaturing gel electrophoresis in the presence of divalent group IIA metal cations. The stability of the folded ribozyme increases with the charge density (zeta) of the cation. Similar scaling is found when the free energy of the RNA folded in small and large metal cations is measured by urea denaturation. Brownian dynamics simulations of a polyelectrolyte show that the experimental observations can be explained by nonspecific ion-RNA interactions in the absence of site-specific metal chelation. The experimental and simulation results establish that RNA stability is largely determined by a combination of counterion charge and the packing efficiency of condensed cations that depends on the excluded volume of the cations.     

Promiscuous catalysis by the tetrahymena group I ribozyme

Catalytic promiscuity, the ability of an enzyme to catalyze alternative reactions, has been suggested to have played an important role in the evolution of new catalytic activities in protein enzymes. Similarly, promiscuous activities may have been advantageous in an earlier RNA world. The Tetrahymena Group I ribozyme naturally catalyzes the site-specific guanosine attack on an anionic phosphate diester and has been shown to also catalyze aminoacyl transfer to water, albeit with a small rate acceleration (<10-fold). This inefficient catalysis could be due to the differences in charge and/or geometry requirements for the two reactions. Herein, we describe a new promiscuous activity of this ribozyme, the site-specific guanosine attack on a neutral phosphonate diester. This alternative substrate lacks the negative charge at the reaction center but, in contrast to the aminoacyl substrate, can undergo nucleophilic attack with the same geometry as the natural substrate. Our results show that the neutral phosphonate reaction is catalyzed about 1 x 106-fold, substantially better than the acyl transfer but far below the normal anionic substrate. We conclude that both charge and geometry are important factors for catalysis of the normal reaction and that promiscuous catalytic activities of ribozymes could have been created or enhanced by reorienting and swapping RNA domains.     

Velocity-independent microfluidic flow cytometry

Pressure-driven flow in microfluidic channels is characterized by a distribution of velocities. This distribution makes it difficult to implement conventional flow cytometry data analysis. We have demonstrated a method to measure velocity as an independent parameter when performing microfluidic flow cytometry. This method allows velocity-independent analysis of particles such as beads or cells, and allows flow cytometry analysis of extended objects, such as long DNA molecules. It allows accurate flow cytometry in transient and nonuniform flows. This general measurement method could be used in the future to measure the velocity of particles in a variety of existing microfluidic devices without the need for changes in their design.     

2'-Fluoro substituents can mimic native 2'-hydroxyls within structured RNA

The ability of fluorine in a C-F bond to act as?a hydrogen bond acceptor is controversial. To test such ability in complex RNA macromolecules, we have replaced native 2'-OH groups with 2'-F and 2'-H groups in two related systems, the Tetrahymena group I ribozyme and the ΔC209 P4-P6 RNA domain. In three cases the introduced 2'-F mimics the native 2'-OH group, suggesting that the fluorine atom can accept a hydrogen bond. In each of these cases the native hydroxyl group interacts with a purine exocyclic amine. Our results give insight about the properties of organofluorine and suggest a possible general biochemical signature for tertiary interactions between 2'-hydroxyl groups and exocyclic amino groups within RNA.     

The shape-shifting quasispecies of RNA: one sequence, many functional folds

E Unus pluribum, or "Of One, Many", may be at the root of decoding the RNA sequence-structure-function relationship. RNAs embody the large majority of genes in higher eukaryotes and fold in a sequence-directed fashion into three-dimensional structures that perform functions conserved across all cellular life forms, ranging from regulating to executing gene expression. While it is the most important determinant of the RNA structure, the nucleotide sequence is generally not sufficient to specify a unique set of secondary and tertiary interactions due to the highly frustrated nature of RNA folding. This frustration results in folding heterogeneity, a common phenomenon wherein a chemically homogeneous population of RNA molecules folds into multiple stable structures. Often, these alternative conformations constitute misfolds, lacking the biological activity of the natively folded RNA. Intriguingly, a number of RNAs have recently been described as capable of adopting multiple distinct conformations that all perform, or contribute to, the same function. Characteristically, these conformations interconvert slowly on the experimental timescale, suggesting that they should be regarded as distinct native states. We discuss how rugged folding free energy landscapes give rise to multiple native states in the Tetrahymena Group I intron ribozyme, hairpin ribozyme, sarcin-ricin loop, ribosome, and an in vitro selected aptamer. We further describe the varying degrees to which folding heterogeneity impacts function in these RNAs, and compare and contrast this impact with that of heterogeneities found in protein folding. Embracing that one sequence can give rise to multiple native folds, we hypothesize that this phenomenon imparts adaptive advantages on any functionally evolving RNA quasispecies.     

Automated RNA tertiary structure prediction from secondary structure and low‐resolution restraints

A novel protocol for all‐atom RNA tertiary structure prediction is presented that uses restrained molecular mechanics and simulated annealing. The restraints are from secondary structure, covariation analysis, coaxial stacking predictions for helices in junctions, and, when available, cross‐linking data. Results are demonstrated on the Alu domain of the mammalian signal recognition particle RNA, the Saccharomyces cerevisiae phenylalanine tRNA, the hammerhead ribozyme, the hepatitis C virus internal ribosomal entry site, and the P4–P6 domain of the Tetrahymena thermophila group I intron. The predicted structure is selected from a pool of decoy structures with a score that maximizes radius of gyration and base–base contacts, which was empirically found to select higher quality decoys. This simple ab initio approach is sufficient to make good predictions of the structure of RNAs compared to current crystal structures using both root mean square deviation and the accuracy of base–base contacts. © 2011 Wiley Periodicals, Inc. J Comput Chem, 2011     

Genetic, genomic and physiological state studies on single-needle bio-electrosprayed human cells

Bio-electrospraying, a non-contact jet-based direct cell engineering approach, was recently pioneered and demonstrated for handling a wide range of primary living cells. In those studies, post-treated cells were biologically assessed in comparison to several controls by way of flow cytometry. Although flow cytometry accurately assesses those viable populations of cells, subtle effects at a sub-cellular level could have been missed. Therefore, in the present study we demonstrate metaphase chromosome breakage studies carried out on single-needle bio-electrosprayed human T-lymphocytes, which are compared with several controls. The results indicate that post-treated T-lymphocytes do not demonstrate any increase in chromosome damage in comparison to control cells. These studies further validate bio-electrospraying as a technique with potential for clinical utility.     

Ribozyme mimics as catalytic antisense reagents

Viral and fungal infections and some cancers may be described as diseases that are characterized by the expression of certain unwanted proteins. They could be termed induced genetic disorders, with induction provided by mutation or infection. A comprehensive method to inactivate injurious genes based on their nucleic acid sequences has the potential to provide effective antiviral and anticancer agents with greatly reduced side effects. We describe a chemical approach to such gene-specific pharmaceutical agents. Our initial efforts have been to develop new chemical reagents that can carry out catalytic destruction of specific mRNA sequences. We chose hydrolysis as a chemical means of destruction, because hydrolysis is compatible with living cells. Our sequence-specific catalytic RNA hydrolysis reagents may be described as functional ribozyme mimics. Reactivity is provided by small-molecule catalysts, such as metal complexes. Specificity is provided by oligonucleotide probes. Here we report initial results on the sequence-specific, hydrolytic cleavage of mRNA from the HIVgag gene, using a ribozyme mimic. The reagent is composed of a terpyridylCu(II) complex for cleavage activity and an oligonucleotide for sequence specificity.     

Recent advances in miniaturized microfluidic flow cytometry for clinical use

This article provides an overview of recent research achievements in miniaturized flow cytometry. The review focuses on chip-based microfluidic flow cytometers, classified by cell transport method, detection technology, and biomedical application. By harnessing numerous ideas and cutting-edge microfabrication technologies, microfluidic flow cytometry benefits from ever-increasing functionalities and the performance levels achieved make it an attractive biomedical research and clinical tool. In this article, we briefly describe an update of recent developments that combine novel microfluidic characteristics and flow cytometry on chips that meet biomedical needs.     

Reduction of an aldehyde by a NADH/Zn2+ -dependent redox active ribozyme

We report here the ability of an alcohol dehydrogenase (ADH) ribozyme to reduce a benzaldehyde. While the ribozyme was initially evolved in vitro based on the activity for the NAD+-dependent oxidation of the benzyl alcohol, we found that this ADH ribozyme is also capable of reducing the aldehyde in the presence of NADH and Zn2+. The rate acceleration gained by ribozyme catalysis was more than 6 orders of magnitude larger than the spontaneous reaction. Although the reversibility of phosphordiester and acyl transfer reactions catalyzed by ribozymes was known, that of other chemical reactions has not been well established. This study has demonstrated the reversibility of a hydride transfer chemistry catalyzed by the ADH ribozyme. Most interestingly, the ribozyme shares many features with the protein ADHs, e.g., reversibility and NADH/Zn2+ dependence.     

Review on recent advances in the analysis of isolated organelles

The analysis of isolated organelles is one of the pillars of modern bioanalytical chemistry. This review describes recent developments on the isolation and characterization of isolated organelles both from living organisms and cell cultures. Salient reports on methods to release organelles focused on reproducibility and yield, membrane isolation, and integrated devices for organelle release. New developments on organelle fractionation after their isolation were on the topics of centrifugation, immunocapture, free flow electrophoresis, flow field-flow fractionation, fluorescence activated organelle sorting, laser capture microdissection, and dielectrophoresis. New concepts on characterization of isolated organelles included atomic force microscopy, optical tweezers combined with Raman spectroscopy, organelle sensors, flow cytometry, capillary electrophoresis, and microfluidic devices.     

The glmS ribozyme tunes the catalytically critical pK(a) of its coenzyme glucosamine-6-phosphate

The glmS ribozyme riboswitch is the first known natural catalytic RNA that employs a small-molecule cofactor. Binding of glucosamine-6-phosphate (GlcN6P) uncovers the latent self-cleavage activity of the RNA, which adopts a catalytically competent conformation that is nonetheless inactive in the absence of GlcN6P. Structural and analogue studies suggest that the amine of GlcN6P functions as a general acid-base catalyst, while its phosphate is important for binding affinity. However, the solution pK(a) of the amine is 8.06 ± 0.05, which is not optimal for proton transfer. Here we used Raman crystallography directly to determine the pK(a)'s of GlcN6P bound to the glmS ribozyme. Binding to the RNA lowers the pK(a) of the amine of GlcN6P to 7.26 ± 0.09 and raises the pK(a) of its phosphate to 6.35 ± 0.09. Remarkably, the pK(a)'s of these two functional groups are unchanged from their values for free GlcN6P (8.06 ± 0.05 and 5.98 ± 0.05, respectively) when GlcN6P binds to the catalytically inactive but structurally unperturbed G40A mutant of the ribozyme, thus implicating the ribozyme active site guanine in pK(a) tuning. This is the first demonstration that a ribozyme can tune the pK(a) of a small-molecule ligand. Moreover, the anionic glmS ribozyme in effect stabilizes the neutral amine of GlcN6P by lowering its pK(a). This is unprecedented and illustrates the chemical sophistication of ribozyme active sites.