Structure of transcribing mammalian RNA polymerase II.

RNA polymerase (Pol) II produces messenger RNA during transcription of protein-coding genes in all eukaryotic cells. The Pol II structure is known at high resolution from X-ray crystallography for two yeast species. Structural studies of mammalian Pol II, however, remain limited to low-resolution electron microscopy analysis of human Pol II and its complexes with various proteins. Here we report the 3.4 Å resolution cryo-electron microscopy structure of mammalian Pol II in the form of a transcribing complex comprising DNA template and RNA transcript. We use bovine Pol II, which is identical to the human enzyme except for seven amino-acid residues. The obtained atomic model closely resembles its yeast counterpart, but also reveals unknown features. Binding of nucleic acids to the polymerase involves 'induced fit' of the mobile Pol II clamp and active centre region. DNA downstream of the transcription bubble contacts a conserved 'TPSA motif' in the jaw domain of the Pol II subunit RPB5, an interaction that is apparently already established during transcription initiation. Upstream DNA emanates from the active centre cleft at an angle of approximately 105° with respect to downstream DNA. This position of upstream DNA allows for binding of the general transcription elongation factor DSIF (SPT4-SPT5) that we localize over the active centre cleft in a conserved position on the clamp domain of Pol II. Our results define the structure of mammalian Pol II in its functional state, indicate that previous crystallographic analysis of yeast Pol II is relevant for understanding gene transcription in all eukaryotes, and provide a starting point for a mechanistic analysis of human transcription.

A cross-chiral RNA polymerase ribozyme.

Thirty years ago it was shown that the non-enzymatic, template-directed polymerization of activated mononucleotides proceeds readily in a homochiral system, but is severely inhibited by the presence of the opposing enantiomer. This finding poses a severe challenge for the spontaneous emergence of RNA-based life, and has led to the suggestion that either RNA was preceded by some other genetic polymer that is not subject to chiral inhibition or chiral symmetry was broken through chemical processes before the origin of RNA-based life. Once an RNA enzyme arose that could catalyse the polymerization of RNA, it would have been possible to distinguish among the two enantiomers, enabling RNA replication and RNA-based evolution to occur. It is commonly thought that the earliest RNA polymerase and its substrates would have been of the same handedness, but this is not necessarily the case. Replicating D- and L-RNA molecules may have emerged together, based on the ability of structured RNAs of one handedness to catalyse the templated polymerization of activated mononucleotides of the opposite handedness. Here we develop such a cross-chiral RNA polymerase, using in vitro evolution starting from a population of random-sequence RNAs. The D-RNA enzyme, consisting of 83 nucleotides, catalyses the joining of L-mono- or oligonucleotide substrates on a complementary L-RNA template, and similar behaviour occurs for the L-enzyme with D-substrates and a D-template. Chiral inhibition is avoided because the 10(6)-fold rate acceleration of the enzyme only pertains to cross-chiral substrates. The enzyme's activity is sufficient to generate full-length copies of its enantiomer through the templated joining of 11 component oligonucleotides.

Rational design of new materials using recombinant structural proteins: Current state and future challenges.

Sequence-definable polymers are seen as a prerequisite for design of future materials, with many polymer scientists regarding such polymers as the holy grail of polymer science. Recombinant proteins are sequence-defined polymers. Proteins are dictated by DNA templates and therefore the sequence of amino acids in a protein is defined, and molecular biology provides tools that allow redesign of the DNA as required. Despite this advantage, proteins are underrepresented in materials science. In this publication we investigate the advantages and limitations of using proteins as templates for rational design of new materials.

Biomolecular templating of functional hybrid nanostructures using repeat protein scaffolds.

The precise synthesis of materials and devices with tailored complex structures and properties is a requisite for the development of the next generation of products based on nanotechnology. Nowadays, the technology for the generation of this type of devices lacks the precision to determine their properties and is accomplished mostly by 'trial and error' experimental approaches. The use of bottom-up approaches that rely on highly specific biomolecular interactions of small and simple components is an attractive approach for the templating of nanoscale elements. In nature, protein assemblies define complex structures and functions. Engineering novel bio-inspired assemblies by exploiting the same rules and interactions that encode the natural diversity is an emerging field that opens the door to create nanostructures with numerous potential applications in synthetic biology and nanotechnology. Self-assembly of biological molecules into defined functional structures has a tremendous potential in nano-patterning and the design of novel materials and functional devices. Molecular self-assembly is a process by which complex 3D structures with specified functions are constructed from simple molecular building blocks. Here we discuss the basis of biomolecular templating, the great potential of repeat proteins as building blocks for biomolecular templating and nano-patterning. In particular, we focus on the designed consensus tetratricopeptide repeats (CTPRs), the control on the assembly of these proteins into higher order structures and their potential as building blocks in order to generate functional nanostructures and materials.

Templated hierarchical self-assembly of poly(p-aryltriazole) foldamers.

A biomimetic approach has been used for the templated self-assembly of a helical poly(para-aryltriazole) foldamer. The solvophobic folding process yields helices that further self-assemble into long nanotubes (see picture; scale bar: 100 nm). Constructs of controlled length and chirality can be generated by applying a poly(γ-benzyl-l-glutamate) scaffold at the appropriate assembly conditions, mimicking tobacco mosaic virus self-assembly.

Biochemical characterization of enterovirus 71 3D RNA polymerase.

An unusual enterovirus 71 (EV71) epidemic has begun in China since 2008. EV71 RNA polymerases (3D(pol)) showed polymerase activity with an Mn(2+). Little activity was detected with Co(2+), and no activity was detected with Mg(2+), Ca(2+), Cu(2+), Ni(2+), Cd(2+), or Zn(2+). It is a primer-dependent polymerase, and the enzyme functioned with both di- and 10-nucleotide RNA primers. DNA primer, dT15, increased primer activity, similar to other enterovirus 3D(pol). However, EV71 3D(pol) initiated de novo transcription with a poly(C) template and genome RNA. Its RNA binding activity was weak. Terminal nucleotidyl transferase and reverse transcriptase activity were not detected. The Km and Vmax for EV71 3D(pol) were calculated from classic Lineweaver-Burk plots. The Km values were 2.35±0.05 (ATP), 5.40±0.93 (CTP), 1.12±0.10 (GTP) and 2.81±0.31 (UTP), and the Vmax values were 0.00078±0.00005/min (ATP), 0.011±0.0017/min (CTP), 0.050±0.0043/min (GTP) and 0.0027±0.0005/min (UTP). The Km of EV71 3D(pol) was similar to that of foot and mouth disease virus and rhinovirus. Polymerase activity of BrCr-TR strain and a strain from a clinical isolate in Beijing, 2008 were similar, indicating the potential for 3D(pol) as an antiviral drug target.

Traceless enzymatic synthesis of monodispersed hypermodified oligodeoxyribonucleotide polymers from RNA templates.

We have developed a new alternative for enzymatic synthesis of single-stranded hypermodified oligodeoxyribonucleotides displaying four different hydrophobic groups based on reverse transcription from RNA templates catalyzed by DNA polymerases using a set of base-modified dNTPs followed by digestion of RNA by RNases. Using mixed oligodeoxyribonucleotide primers containing a ribonucleotide at the 3'-end, RNase AT1 simultaneously digested the template and cleaved off the primer to release a fully modified oligonucleotide that can be further 3'-labelled with a fluorescent nucleotide using TdT. The resulting hypermodified oligonucleotides could find applications in selection of aptamers or other functional macromolecules.

Template-directed RNA polymerization: the taming of the milieu.

No-bias binding: The abiotic template-directed synthesis of RNA could have been a key process in the origins of life on Earth. Recreating this process in the laboratory has been challenging, yet a combination of strategies has given rise to a synthesis that is both efficient and unbiased against any of the four nucleotides.

Selective aluminum passivation for targeted immobilization of single DNA polymerase molecules in zero-mode waveguide nanostructures.

Optical nanostructures have enabled the creation of subdiffraction detection volumes for single-molecule fluorescence microscopy. Their applicability is extended by the ability to place molecules in the confined observation volume without interfering with their biological function. Here, we demonstrate that processive DNA synthesis thousands of bases in length was carried out by individual DNA polymerase molecules immobilized in the observation volumes of zero-mode waveguides (ZMWs) in high-density arrays. Selective immobilization of polymerase to the fused silica floor of the ZMW was achieved by passivation of the metal cladding surface using polyphosphonate chemistry, producing enzyme density contrasts of glass over aluminum in excess of 400:1. Yields of single-molecule occupancies of approximately 30% were obtained for a range of ZMW diameters (70-100 nm). Results presented here support the application of immobilized single DNA polymerases in ZMW arrays for long-read-length DNA sequencing.

Synergistic Chemo-thermal Therapy of Cancer by DNA-Templated Silver Nanoclusters and Polydopamine Nanoparticles.

Herein, we develop a novel and effective combination nanoplatform for cancer theranostics. Folic acid (FA) is first modified on the photothermal agent of polydopamine (PDA), which possesses excellent near-infrared (NIR) absorbance and thermal conversion features. Temperature-sensitive silver nanoclusters (AgNCs) are then synthesized on the DNA template that also loads the anticancer drug doxorubicin (Dox). After accumulation in cancer cells, PDA generates cytotoxic heat upon excitation of NIR light for photothermal therapy. On the other hand, the temperature increment is able to destroy the template of AgNCs, leading to the fluorescence variation and controlled release of Dox for chemotherapy. The combined nanosystem exhibits outstanding fluorescence tracing, NIR photothermal transduction, as well as chemo drug delivery capabilities. Both in vitro and in vivo results demonstrate excellent tumor growth suppression phenomena and no apparent adverse effects. This research provides a powerful targeted nanoplatform for cancer theranostics, which may have great potential value for future clinical applications.

The basic reproductive ratio of life.

Template-directed polymerization of nucleotides is believed to be a pathway for the replication of genetic material in the earliest cells. We assume that activated monomers are produced by prebiotic chemistry. These monomers can undergo spontaneous polymerization, a system that we call "prelife." Adding template-directed polymerization changes the equilibrium structure of prelife if the rate constants meet certain criteria. In particular, if the basic reproductive ratio of sequences of a certain length exceeds one, then those sequences can attain high abundance. Furthermore, if many sequences replicate, then the longest sequences can reach high abundance even if the basic reproductive ratios of all sequences are less than one. We call this phenomenon "subcritical life." Subcritical life suggests that sequences long enough to be ribozymes can become abundant even if replication is relatively inefficient. Our work on the evolution of replication has interesting parallels to infection dynamics. Life (replication) can be seen as an infection of prelife.

Selfishness versus functional cooperation in a stochastic protocell model.

How to design an "evolvable" artificial system capable to increase in complexity? Although Darwin's theory of evolution by natural selection obviously offers a firm foundation, little hope of success seems to be expected from the explanatory adequacy of modern evolutionary theory, which does a good job at explaining what has already happened but remains practically helpless at predicting what will occur. However, the study of the major transitions in evolution clearly suggests that increases in complexity have occurred on those occasions when the conflicting interests between competing individuals were partly subjugated. This immediately raises the issue about "levels of selection" in evolutionary biology, and the idea that multi-level selection scenarios are required for complexity to emerge. After analyzing the dynamical behaviour of competing replicators within compartments, we show here that a proliferation of differentiated catalysts and/or improvement of catalytic efficiency of ribozymes can potentially evolve in properly designed artificial cells where the strong internal competition between the different species of replicators is somewhat prevented (i.e., by choosing them with equal probability). Experimental evolution in these systems will likely stand as beautiful examples of artificial adaptive systems, and will provide new insights to understand possible evolutionary paths to the evolution of metabolic complexity.

Structural basis for template-independent RNA polymerization.

The 3'-terminal CCA nucleotide sequence (positions 74-76) of transfer RNA is essential for amino acid attachment and interaction with the ribosome during protein synthesis. The CCA sequence is synthesized de novo and/or repaired by a template-independent RNA polymerase, 'CCA-adding enzyme', using CTP and ATP as substrates. Despite structural and biochemical studies, the mechanism by which the CCA-adding enzyme synthesizes the defined sequence without a nucleic acid template remains elusive. Here we present the crystal structure of Aquifex aeolicus CCA-adding enzyme, bound to a primer tRNA lacking the terminal adenosine and an incoming ATP analogue, at 2.8 A resolution. The enzyme enfolds the acceptor T helix of the tRNA molecule. In the catalytic pocket, C75 is adjacent to ATP, and their base moieties are stacked. The complementary pocket for recognizing C74-C75 of tRNA forms a 'protein template' for the penultimate two nucleotides, mimicking the nucleotide template used by template-dependent polymerases. These results are supported by systematic analyses of mutants. Our structure represents the 'pre-insertion' stage of selecting the incoming nucleotide and provides the structural basis for the mechanism underlying template-independent RNA polymerization.

[Forensic analysis of LCN DNA using sample concentration methods followed by miniSTR genotyping].

OBJECTIVE: To optimize low copy number (LCN) DNA analysis methods for forensic STR genotyping. METHODS: Two groups of DNA sample, extracted using either Magnetic bead method or Chelex-100 methods, were previously amplified with a Identifiler PCR Amplification kit, but no genotype was detected. The DNA samples were concentrated using either a drying method or the Microcon-100 method, then amplified using an miniFiler PCR Amplification kit and genotyped. RESULTS: Among the 127 DNA samples, 47 samples, previously extracted using the Magnetic bead method, were genotyped with 36% success rate. Eighty samples, previously extracted using the Chelex-100 method, were genotyped with 30% success rate. CONCLUSION: The application of sample concentration methods and miniFiler kit can improve the success rate of LCN STR analysis.

Structural alteration in isolated rat liver nuclei after removal of template restriction by polyanions.

Specific polyanions release DNA template restrictions for DNA synthesis in isolated rat liver nuclei. The degree to which DNA synthesis is enhanced can be correlated with a spectrum of changes in nuclear structure Each polyanion which is effective in the release of template restriction produces a characteristic alteration in nuclear ultrastructure. Polyanions which have no effect on DNA synthesis do not appear to cause any change in nuclear organization or ultrastructure. Parallel measurements of nuclear DNA release and nuclear volume changes also indicate that template-activating polyanions cause remarkable changes in the structural organization of the treated nuclei. These results indicate that DNA template activation involves direct interactions between polyanions and nuclear constituents and suggest the possibility that naturally occurring polyanions might have a role in the control of gene activity

From micro- to nanofabrication with soft materials.

Soft materials are finding applications in areas ranging from microfluidic device technology to nanofabrication. We review recent work in these areas, discuss the motivation for device fabrication with soft materials, and describe applications of soft materials. In particular, we discuss active microfluidic devices for cell sorting and biochemical assays, replication-molded optics with subdiffraction limit features, and nanometer-scale resonators and wires formed from single-molecule DNA templates as examples of how the special properties of soft materials address outstanding problems in device fabrication.

Thermodynamic analysis of nylon nucleic acids.

The stability and structure of nylon nucleic acid duplexes with complementary DNA and RNA strands was examined. Thermal denaturing studies of a series of oligonucleotides that contained nylon nucleic acids (1-5 amide linkages) revealed that the amide linkage significantly enhanced the binding affinity of nylon nucleic acids towards both complementary DNA (up to 26 degrees C increase in the thermal transition temperature (T(m)) for five linkages) and RNA (around 15 degrees C increase in T(m) for five linkages) compared with nonamide linked precursor strands. For both DNA and RNA complements, increasing derivatization decreased the melting temperatures of uncoupled molecules relative to unmodified strands; by contrast, increasing lengths of coupled copolymer raised T(m) from less to slightly greater than T(m) of unmodified strands. Thermodynamic data extracted from melting curves and CD spectra of nylon nucleic acid duplexes were consistent with loss of stability due to incorporation of pendent groups on the 2'-position of ribose and recovery of stability upon linkage of the side chains.

Polymerization of alpha-hydroxy acids by ribosomes.

Over 30 years ago, Fahnestock and Rich reported intriguing data showing the capability of the ribosome to polymerize phenyllactic acid. Although the polymerization was initiated and terminated randomly on polyuridic acids, the given data convincingly suggested that the generated polymer was composed of an approximately 7:3 mixture of phenyllactic acid and phenylalanine. Despite the fact that Fahnestock's conclusion was very likely correct, there have been no reports to follow up the ribosome-catalyzed polymerization of alpha-hydroxy acids until very recently. At the end of 2007, we reported messenger RNA (mRNA)-directed polyester synthesis by using the new emerging method of genetic-code reprogramming in which alpha-hydroxy acids with various kinds of side-chains are assigned to arbitrarily chosen codons. In this work, we have achieved the ribosomal synthesis of polyesters with the sequence composition and length in a fully controlled manner according to the sequence of mRNA. This Concept article describes the background of the method development and its application to the synthesis of polyesters.

Complexation of single strand telomere and telomerase RNA template polyanions by deoxyribonucleic guanidine (DNG) polycations: plausible anticancer agents.

Cancerous cell immortality is due to relatively high concentrations of telomerase enzyme which maintains telomere sequence during cell division. Deoxyribonucleic guanidine (DNG) is a positively charged DNA analog in which guanidine replaces the phosphordiester linkage of DNA. Mixed sequences of DNG and DNA oligonucleotides are referred to as chimera. Complexation of DNG and chimeric polycations with the complementary negatively charged non-coding telomere single strand d(5'-TTAGGG-3')(n) and the 11-base telomeric RNA template (5'-CUAACCCUAAC-3') in the active site of telomerase has been studied. Calculated by ensemble sampling simulations in GBMV solvent model, we found that binding of complementary DNG hexamer with telomere is favored over that of DNA-telomere by approximately 10(6)-fold and binding of chimera hexamer is favored by approximately 10(4)-fold. Binding of complementary DNG with telomeric RNA is favored by 43 kcal/mol over telomere substrate binding with telomeric RNA.

Metal-ion catalyzed polymerization in the eutectic phase in water-ice: a possible approach to template-directed RNA polymerization.

The emergence of an RNA world requires among other processes the non-enzymatic, template-directed replication of genetic polymers such as RNA or related nucleic acids, possibly catalyzed by metal-ions. The absence of uridilate derivative polymerization on adenine containing templates has been the main issue preventing an efficient template-directed RNA polymerization. We report here the investigation of template-directed RNA polymerization in the eutectic phase in water-ice. In particular, it was found that activated uridilate monomers in the presence of metal-ion catalysts could efficiently elongate RNA hairpins whose 5'-overhangs served as the templating sequence. The same applies for every other pyrimidine and purine nucleobase. Moreover, the initial elongation rates were always higher in the presence of a template complementary to the nucleotide than in systems without proper base-pairing opportunities. These results suggest that a template-directed RNA polymerization catalyzed by metal-ions could be carried out under eutectic phase in water-ice conditions.