Nano-sandwich composite by kinetic trapping assembly from protein and nucleic acid

Design and preparation of layered composite materials alternating between nucleic acids and proteins has been elusive due to limitations in occurrence and geometry of interaction sites in natural biomolecules. We report the design and kinetically controlled stepwise synthesis of a nano-sandwich composite by programmed noncovalent association of protein, DNA and RNA modules. A homo-tetramer protein core was introduced to control the self-assembly and precise positioning of two RNA–DNA hybrid nanotriangles in a co-parallel sandwich arrangement. Kinetically favored self-assembly of the circularly closed nanostructures at the protein was driven by the intrinsic fast folding ability of RNA corner modules which were added to precursor complex of DNA bound to the protein. The 3D architecture of this first synthetic protein–RNA–DNA complex was confirmed by fluorescence labeling and cryo-electron microscopy studies. The synthesis strategy for the nano-sandwich composite provides a general blueprint for controlled noncovalent assembly of complex supramolecular architectures from protein, DNA and RNA components, which expand the design repertoire for bottom-up preparation of layered biomaterials.     

43 Why G? Aggregation and gelation of GMP with XMP: the plot thickens

GMP alone, among the individual ribonucleotides, exhibits a reversible self-aggregation through hydrogen bonding to form tetrads that are the building blocks of higher order structures. These “G-tetrads” can further associate through π–π stacking to form chiral, columnar aggregates and, at higher monomer concentrations, lyotropic liquid crystalline phases. This alternate pathway for GMP should compete with its incorporation into oligonucleotides, which is why it is difficult to synthesize or amplify highly G-rich RNA or DNA with good efficiency in the absence of natural proteins, such as helicases, that function to unwind the strands. Given this competing pathway for GMP, we can ask if it came to be one of the four ribonucleotides in modern RNA in spite of, or because of, its unique properties. Our hypothesis is that the competition between reversible aggregation and covalent polymerization directed RNA toward sequences that were best suited to life on early earth. We find support in the observation that the same interactions that promote self-assembly of monomeric GMP also promote folding of G-rich RNA and DNA sequences to form inter- and intramolecular G-quadruplex structures. Such sequences are prevalent throughout the biological world and are thought to serve important functions related to genomic stability and gene regulation. G-quadruplex structures are also common motifs in aptamers, which are combinatorially derived DNA or RNA sequences that exhibit highly selective, high-affinity binding to molecular and macromolecular targets. An important consideration for GMP aggregation in a prebiotic RNA World scenario is the effect of other XMP on GMP self-assembly. In this talk, we will focus on the properties of solutions containing mixtures of GMP with AMP, CMP, and UMP. The results show that each nucleotide exerts a different influence on the self-assembly of GMP, raising interesting questions about scenarios on prebiotic Earth that would be consistent with abiotic RNA polymerization.     

Different sequences show similar quaternary interaction stabilities in prohead viral RNA self-assembly

Prohead RNA (pRNA) is an essential component of the self-assembling φ29 bacteriophage DNA packaging motor. Different related species of bacteriophage share only 12% similarity in pRNA sequences. The secondary structure for pRNA is conserved, however. In this study, we present evidence for self-assembly in different pRNA sequences and new measurements of the energetics for the quaternary interactions in pRNA dimers and trimers. The energetics for self-assembly in different pRNA sequences are similar despite very different sequences in the loop-loop interactions. The architecture surrounding the interlocking loops contributes to the stability of the pRNA quaternary interactions, and sequence variation outside the interlocking loops may counterbalance the changes in the loop sequences. Thus, the evolutionary divergence of pRNA sequences maintains not only conservation of function and secondary structure but also stabilities of quaternary interactions. The self-assembly of pRNA can be fine-tuned with variations in magnesium chloride, sodium chloride, temperature, and concentration. The ability to control pRNA self-assembly holds promise for the development of nanoparticle therapeutic applications for this biological molecule. The pRNA system is well suited for future studies to further understand the energetics of RNA tertiary and quaternary interactions, which can provide insight into larger biological assemblies such as viruses and biomolecular motors.     

Evaluation of single-stranded nucleic acids as carriers in the DNA-directed assembly of macromolecules

Current developments in nanosciences indicate that the self-assembly of macromolecules, such as proteins or metallic nanoclusters, can be conveniently achieved by means of nucleic acid hybridization. Within this context, we here report on the evaluation of single-stranded nucleic acids to be utilized as carrier backbones in DNA-directed self-assembly. A microplate solid-phase hybridization assay is described which allows rapid experimental determination of the hybridization efficiencies of various sequence stretches within a given nucleic acid carrier strand. As demonstrated for two DNA fragments of different sequence, the binding efficiencies of several oligonucleotides depend on the formation of specific secondary structure elements within the carrier molecule. A correlation of sequence-specific hybridization capability with modeled secondary structure is also obvious from experiments using the fluorescence gel-shift analysis. Electrophoretic studies on the employment of helper oligonucleotides in the formation of supramolecular conjugates of several oligonucleotide-tagged proteins indicate, that structural constraints can be minimized by disruption of intramolecular secondary structures of the carrier molecule. To estimate the influences of the chemical nature of the carrier, gel-shift experiments are carried out to compare a 170mer RNA molecule with its DNA analogue. Ternary aggregates, containing two protein components bound to the carrier, are formed with a greater efficiency on the DNA instead of the RNA carrier backbone.     

Uniqueness, advantages, challenges, solutions, and perspectives in therapeutics applying RNA nanotechnology

The field of RNA nanotechnology is rapidly emerging. RNA can be manipulated with the simplicity characteristic of DNA to produce nanoparticles with a diversity of quaternary structures by self-assembly. Additionally RNA is tremendously versatile in its function and some RNA molecules display catalytic activities much like proteins. Thus, RNA has the advantage of both worlds. However, the instability of RNA has made many scientists flinch away from RNA nanotechnology. Other concerns that have deterred the progress of RNA therapeutics include the induction of interferons, stimulation of cytokines, and activation of other immune systems, as well as short pharmacokinetic profiles in vivo. This review will provide some solutions and perspectives on the chemical and thermodynamic stability, in vivo half-life and biodistribution, yield and production cost, in vivo toxicity and side effect, specific delivery and targeting, as well as endosomal trapping and escape.     

Gene expression profiling diagnosis through DNA molecular computation

Gene expression profiling is the characterization of cells based on the level of gene activity represented by concentrations of complementary DNA reverse transcribed from messenger RNA. The spectrum of cDNA concentrations, the expression profile, is determined using a DNA microarray. Although this approach is valuable for research, a simpler scheme that would give answers on a shorter time-scale for clinical applications is needed. An Adleman DNA self-assembly computer that would use cDNA as input might be ideal for clinical cell discrimination and a neural network architecture would be appropriate for making the necessary classifications. Preliminary experimental results suggest that expression profiling should be feasible using a DNA neural network that acts directly on cDNA.     

Self-assembly of double-stranded DNA molecules at nanomolar concentrations

Some proteins have the property of self-assembly, known to be an important mechanism in constructing supramolecular architectures for cellular functions. However, as yet, the ability of double-stranded (ds) DNA molecules to self-assemble has not been established. Here we report that dsDNA molecules also have a property of self-assembly in aqueous solutions containing physiological concentrations of Mg2+. We show that DNA molecules preferentially interact with molecules with an identical sequence and length even in a solution composed of heterogeneous DNA species. Curved DNA and DNA with an unusual conformation and property also exhibit this phenomenon, indicating that it is not specific to usual B-form DNA. Atomic force microscopy (AFM) directly reveals the assembled DNA molecules formed at concentrations of 10 nM but rarely at 1 nM. The self-assembly is concentration-dependent. We suggest that the attractive force causing DNA self-assembly may function in biological processes such as folding of repetitive DNA, recombination between homologous sequences, and synapsis in meiosis.     

HIV-1 CAP2NC蛋白的表达及体外自组装

构建并表达HIV-1 CAP2NC蛋白,探索其体外自组装条件。通过PCR技术扩增HIV-1(NL4-3毒株)CAP2NC基因片段,并将其连接到原核表达载体pTO-T7,获得重组质粒pTO-T7-CAP2NC,然后转化至大肠杆菌BL21(DE3)菌株,经疏水层析纯化后获得重组蛋白CAP2NC。SDS-PAGE结果表明,重组蛋白CAP2NC可在大肠杆菌可溶高效表达,经纯化后纯度约为95%。ELISA检测表明重组蛋白CAP2NC可被HIV-1衣壳蛋白特异性单克隆抗体识别,具有较好反应活性。重组蛋白透析后在非原性SDS-PAGE中呈现为多种聚体形式。分子筛排阻层析分析CAP2NC蛋白透析后可进行组装,负染电镜进一步观察显示CAP2NC蛋白在RNA存在条件下,可形成空心管状颗粒,其形态结构与HIV-1病毒衣壳体外自组装形成的类似。上述结果表明HIV-1 CAP2NC蛋白具有体外自组装的性质,为进一步在体外研究非成熟病毒样颗粒结构奠定基础。     

Difference in the mechanism of self-assembly in vitro in tobacco mosaic virus and potato virus X

The effects of 254 nm UV-irradiation of tobacco mosaic virus (TMV) and potato virus X (PVX) RNA preparations on the RNA ability to self-assembly in vitro with the viral coat proteins were studied. It was found that while TMV RNA ability to assemble with the homologous protein is rapidly inactivated by the UV-irradiation, PVX RNA ability to be encapsidated by the PVX coat protein is quite resistant to the irradiation. More than that, the irradiation of TMV RNA with the dose strongly inhibiting its assembly with the homologous protein, did not result in any significant inhibition of this RNA ability to be coated with the PVX protein. The results testify to the profound differences in the mechanisms of RNA-protein interactions in the processes of self-assembly in vitro of tobamoviruses and potexviruses.     

RNA at DNA Double-Strand Breaks: The Challenge of Dealing with DNA:RNA Hybrids

RNA polymerase II is recruited to DNA double-strand breaks (DSBs), transcribes the sequences that flank the break and produces a novel RNA type that has been termed damage-induced long non-coding RNA (dilncRNA). DilncRNAs can be processed into short, miRNA-like molecules or degraded by different ribonucleases. They can also form double-stranded RNAs or DNA:RNA hybrids. The DNA:RNA hybrids formed at DSBs contribute to the recruitment of repair factors during the early steps of homologous recombination (HR) and, in this way, contribute to the accuracy of the DNA repair. However, if not resolved, the DNA:RNA hybrids are highly mutagenic and prevent the recruitment of later HR factors. Here recent discoveries about the synthesis, processing, and degradation of dilncRNAs are revised. The focus is on RNA clearance, a necessary step for the successful repair of DSBs and the aim is to reconcile contradictory findings on the effects of dilncRNAs and DNA:RNA hybrids in HR.     

Development of a nuclear polyhedrosis in cells of Rhynchosciara angelae (Diptera, Sciaridae) and patterns of DNA synthesis in the infected cells

An ultrastructural and autoradiographic study of the infection of cells of Rhynchosciara angelae by a nuclear polyhedrosis virus (RPV) is presented. RPV is a DNA virus and causes a dramatic increase in the volume of the infected cells and in the sizes of chromosomes and their DNA contents. The structure of the nucleoli changes with the infection and the changes are mainly related to an increase of DNA synthesis. The concentration of ribosomes increases in the cytoplasm of the infected cells. Autoradiographic study of the DNA synthesis showed that it varies with the infective process.Four patterns of DNA synthesis, in relation to the host chromosomes and the virus, were disclosed by means of tritiated thymidine incorporation in the infected nuclei. The patterns are: (1) incorporation mainly in the chromosomes, (2) incorporation in the chromosomes and in the nucleoplasm, (3) incorporation only in the nucleoplasm, and (4) incorporation mainly in the chromosomes in dissociation. There is indication of a succession 1→2 and 3→4. The succession of patterns indicates that the virus induces first the increase of synthesis of host cell DNA and RNA. The bulk of the synthesis of viral DNA is evident only after the host cell DNA and RNA machinery is amplified. The aspects of the formation of viral membrane indicate that it is a de novo process in which the membrane material is capable of self-assembly.     

Diel variation of the RNA/DNA ratios in Crassostrea angulata (Lamarck) and Ruditapes decussatus (Linnaeus 1758) (Mollusca: Bivalvia)

The aim of this study was to investigate the effect of time of day on RNA/DNA ratios among fed and starved Crassostrea angulata and Ruditapes decussatus juveniles. Sampling to investigate the day and night condition of juveniles was carried out for 48 h. A highly sensitive method for nucleic acid quantification was applied to bivalves. The results suggest that there is some variation in nucleic acid quantities with the time of the day. For the two species analysed, the RNA/DNA ratio was particularly high during the night and was higher in the fed animals. The results seem to indicate that there is some endogenous rhythm in the production of RNA. If there are diel changes in RNA/DNA ratios, it follows that average RNA/DNA ratios can be unrepresentative if there is any day or night bias in sampling.     

Application of aptamers in diagnostics,drug-delivery and imaging

Aptamers are small, single-stranded oligonucleotides (DNA or RNA) that bind to their target with high specificity and affinity. Although aptamers are analogous to antibodies for a wide range of target recognition and variety of applications, they have significant advantages over antibodies. Since aptamers have recently emerged as a class of biomolecules with an application in a wide array of fields, we need to summarize the latest developments herein. In this review we will discuss about the latest developments in using aptamers in diagnostics, drug delivery and imaging. We begin with diagnostics, discussing the application of aptamers for the detection of infective agents itself, antigens/toxins (bacteria), biomarkers (cancer), or a combination. The ease of conjugation and labelling of aptamers makes them a potential tool for diagnostics. Also, due to the reduced off-target effects of aptamers, their use as a potential drug delivery tool is emerging rapidly. Hence, we discuss their use in targeted delivery in conjugation with siRNAs, nanoparticles, liposomes, drugs and antibodies. Finally, we discuss about the conjugation strategies applicable for RNA and DNA aptamers for imaging. Their stability and self-assembly after heating makes them superior over protein-based binding molecules in terms of labelling and conjugation strategies.     

Counterion charge density determines the position and plasticity of RNA folding transition states

The self-assembly of RNA structure depends on the interactions of counterions with the RNA and with each other. Comparison of various polyamines showed that the tertiary structure of the Tetrahymena ribozyme is more stable when the counterions are small and highly charged. By monitoring the folding kinetics of the ribozyme as a function of polyamine concentration, we now find that the charge density of the counterions determines the positions of the folding transition states. The transition state ensemble (TSE) between U and N moves away from the native state as the counterion valence and charge density increase, as predicted by the Hammond postulate. The TSE is broader and less structured when the RNA is refolded in polyamines rather than Mg2+. That the charge density of the counterions determines the plasticity of the TSE demonstrates the importance of interactions among condensed counterions for the self-assembly of RNA structures. We propose that the major barrier to RNA folding is dominated by entropy changes when counterion charge density is low and enthalpy differences when it is high.     

Use of halogenated precursors for simultaneous DNA and RNA detection by means of immunoelectron and immunofluorescence microscopy.

We have developed a novel approach for in situ labeling and detection of nucleic acids in cultured cells. It is based on in vivo incorporation of chlorouridine (ClU) or iododeoxyuridine (IdU) into Chinese hamster ovary cells with the aim of labeling RNA and DNA, respectively. The halogenated nucleotides are immunolabeled on ultrathin sections with anti-bromodeoxyuridine (BrdU) monoclonal antibodies that specifically react with either IdU or ClU. Furthermore, we combined ClU and IdU incubation to label simultaneously RNA and DNA in the same cell. Both were visualized by means of anti-BrdU antibodies exhibiting strong affinity for one of the two halogenated epitopes. Confocal imaging of interphase nuclei and electron microscopic analysis showed evidence of a partial colocalization of newly synthesized DNA and RNA inside the cell nucleus. RNase and DNase digestion of ultrathin sections after formaldehyde fixation and acrylic resin embedding confirmed the specificity of incorporation. Consequently, this method allows us to differentially label DNA and RNA on the same section. Using short pulses with the precursors, we could show that newly synthesized DNA and RNA both preferentially occur within the perichromatin region at the border of condensed chromatin domains.     

Cytosine, the double helix and DNA self-assembly

DNA self-assembly has crucial implications in reading out the genetic information in the cell and in nanotechnological applications. In a recent paper, self-assembled DNA crystals displaying spectacular triangular motifs have been described (Zheng et al., 2009). The authors claimed that their data demonstrate the possibility to rationally design well-ordered macromolecular 3D DNA lattice with precise spatial control using sticky ends. However, the authors did not recognize the fundamental features that control DNA self-assembly in the lateral direction. By analysing available crystallographic data and simulating a DNA triangle, we show that the double helix geometry, sequence-specific cytosine–phosphate interactions and divalent cations are in fact responsible for the precise spatial assembly of DNA.     

Preparation and properties of recombinant DNA derived tobacco mosaic virus coat protein

Recombinant DNA derived tobacco mosaic virus (vulgare strain) coat protein (r-TMVP) was obtained by cloning and expression in Escherichia coli and was purified by column chromatography, self-assembly polymerization, and precipitation. SDS-PAGE, amino terminal sequencing, and immunoblotting with polyclonal antibodies raised against TMVP confirmed the identify and purity of the recombinant protein. Isoelectric focusing in 8 M urea and fast atom bombardment mass spectrometry demonstrated that the r-TMVP is not acetylated at the amino terminus, unlike the wild-type protein isolated from the tobacco plant derived virus. The characterization of r-TMVP with regard to its self-assembly properties revealed reversible endothermic polymerization as studied by analytical ultracentrifugation, circular dichroism, and electron microscopy. However, the details of the assembly process differed from those of the wild-type protein. At neutral pH, low ionic strength, and 20 degrees C, TMVP forms a 20S two-turn helical rod that acts as a nucleus for further assembly with RNA and additional TMVP to form TMV. Under more acidic conditions, this 20S structure also acts as a nucleus for protein self-assembly to form viruslike RNA-free rods. The r-TMVP that is not acetylated carries an extra positive charge at the amino terminus and does not appear to form the 20S nucleus. Instead, it forms a 28S four-layer structure, which resembles in size and structure the dimer of the bilayer disk formed by the wild-type protein at pH 8.0, high ionic strength, and 20 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Controlling RNA self-assembly to form filaments

Fundamental control over supra-molecular self-assembly for organization of matter on the nano-scale is a major objective of nanoscience and nanotechnology. ‘RNA tectonics’ is the design of modular RNA units, called tectoRNAs, that can be programmed to self-assemble into novel nano- and meso-scopic architectures of desired size and shape. We report the three-dimensional design of tectoRNAs incorporating modular 4-way junction (4WJ) motifs, hairpin loops and their cognate loop–receptors to create extended, programmable interaction interfaces. Specific and directional RNA–RNA interactions at these interfaces enable conformational, topological and orientational control of tectoRNA self-assembly. The interacting motifs are precisely positioned within the helical arms of the 4WJ to program assembly from only one helical stacking conformation of the 4WJ. TectoRNAs programmed to assemble with orientational compensation produce micrometer-scale RNA filaments through supra-molecular equilibrium polymerization. As visualized by transmission electron microscopy, these RNA filaments resemble actin filaments from the protein world. This work emphasizes the potential of RNA as a scaffold for designing and engineering new controllable biomaterials mimicking modern cytoskeletal proteins.