EcoFlex: A Multifunctional MoClo Kit for E. coli Synthetic Biology.

Development of advanced synthetic biology tools is always in demand since they act as a platform technology to enable rapid prototyping of biological constructs in a high-throughput manner. EcoFlex is a modular cloning (MoClo) kit for Escherichia coli and is based on the Golden Gate principles, whereby Type IIS restriction enzymes (BsaI, BsmBI, BpiI) are used to construct modular genetic elements (biological parts) in a bottom-up approach. Here, we describe a collection of plasmids that stores various biological parts including promoters, RBSs, terminators, ORFs, and destination vectors, each encoding compatible overhangs allowing hierarchical assembly into single transcription units or a full-length polycistronic operon or biosynthetic pathway. A secondary module cloning site is also available for pathway optimization, in order to limit library size if necessary. Here, we show the utility of EcoFlex using the violacein biosynthesis pathway as an example.

Glycols modulate terminator stem stability and ligand-dependency of a glycine riboswitch.

The Bacillus subtilis glycine riboswitch comprises tandem glycine-binding aptamers and a putative terminator stem followed by the gcvT operon. Gene expression is regulated via the sensing of glycine. However, we found that the riboswitch behaves in a "glycine-independent" manner in the presence of polyethylene glycol (PEG) and ethylene glycol. The effect is related to the formation of a terminator stem within the expression platform under such conditions. The results revealed that increasing PEG stabilized the structure of the terminator stem. By contrast, the addition of ethylene glycol destabilized the terminator stem. PEG and ethylene glycol have opposite effects on transcription as well as on stable terminator stem formation. The glycine-independency of the riboswitch and the effects of such glycols might shed light on the evolution of riboswitches.

Characterization of a 1,4-disubstituted 1,2,3-triazole binding to T box antiterminator RNA.

The T box riboswitch regulates the transcription of many bacterial genes by structurally responding to cognate non-aminoacylated (uncharged) tRNA. The riboswitch contains multiple conserved RNA elements including a key structural element, the antiterminator, which binds the tRNA acceptor end nucleotides. Previous studies identified a lead 1,4-disubstituted 1,2,3-triazole, GHB-7, that disrupted formation of a tRNA-antiterminator RNA model complex. The affinity and molecular interactions of GHB-7 binding to antiterminator model RNA were characterized as part of a comprehensive T box antiterminator RNA-targeted drug discovery project. In-line probing, UV-monitored thermal denaturation and docking studies all consistently indicated that GHB-7 likely binds to the bulge region of the antiterminator, reduces the flexibility of the bulge nucleotides and, overall, stabilizes the RNA secondary structure. These results begin to elucidate possible mechanisms for ligand-induced inhibition of tRNA binding to T box antiterminator RNA and contribute to the knowledge of how small molecules bind relatively simple RNA structural elements such as bulges.

4,5-Disubstituted oxazolidinones: High affinity molecular effectors of RNA function.

The T box transcription antitermination system is a riboswitch found primarily in Gram-positive bacteria which monitors the aminoacylation of the cognate tRNA and regulates a variety of amino acid-related genes. Novel 4,5-disubstituted oxazolidinones were identified as high affinity RNA molecular effectors that modulate the transcription antitermination function of the T box riboswitch.

Functional dissection of RNA polymerase III termination using a peptide nucleic acid as a transcriptional roadblock.

We have shown previously that a T(10) peptide nucleic acid (PNA) bound to the transcriptional terminator of a Saccharomyces cerevisiae tDNA(Ile)(TAT) gene arrests elongating yeast RNA polymerase (pol) III at a position that precedes by 20 bp the upstream end of the PNA roadblock (Dieci, G., Corradini, R., Sforza, S., Marchelli, R., and Ottonello, S. (2001) J. Biol. Chem. 276, 5720-5725). Here, a PNA-binding cassette was placed at various distances downstream of a functional tDNA(Ile) transcriptional terminator (T(6)) that is not bound by the T(10) PNA, and the effect of the PNA roadblock on RNA 3'-end formation, transcript release, and transcription reinitiation was examined. With a PNA roadblock placed as close as 5 bp downstream of the T(6) terminator, pol III could still reach the termination site and complete pre-tRNA synthesis, implying that the catalytic site-to-front edge (C-F) distance of the polymerase can shorten by >10 bp upon recognition of the terminator element. In addition, transcripts synthesized by a PNA-roadblocked terminating pol III were found to be released from transcription complexes. Interestingly, however, the same roadblock dramatically reduced the rate of transcription reinitiation. Also, when placed 5 bp downstream of a mutationally inactivated terminator element (T(3)GT(2)), the PNA roadblock restored transcription termination, thus indicating that the inactivated terminator is compromised in its ability to cause pol III pausing, but can still induce C-F distance shortening and transcript release. The latter two activities were found to be further impaired in variants of the inactivated terminator bearing fewer than three consecutive T residues (T(2)G(2)T(2) and TG(2)TGT). The data indicate that RNA polymerase pausing, C-F distance shortening, and transcript release are functionally distinguishable features of the termination process and point to the RNA release propensity of pol III as a major determinant of its remarkably high termination efficiency.

Inhibition of RNA polymerase III elongation by a T10 peptide nucleic acid.

The terminator elements of eukaryotic class III genes strongly contribute to overall transcription efficiency by allowing fast RNA polymerase III (pol III) recycling. Being constituted by a run of thymidine residues on the coding strand (a poly(dA) tract on the transcribed strand), pol III terminators are expected to form highly stable triple-helix complexes with oligothymine peptide nucleic acids (PNAs). We analyzed the effect of a T10 PNA on in vitro transcription of three yeast class III genes (coding for two different tRNAs and the U6 small nuclear RNA) having termination signals of at least ten T residues. At nanomolar concentrations, the PNA almost completely inhibited transcription of supercoiled, but not linearized, templates in a sequence-specific manner. The total RNA output of the first transcription cycle was not affected by PNA concentrations strongly inhibiting multiple round transcription. Thus, an impairment of pol III recycling fully accounts for the observed inhibition. As revealed by the size and the state (free or transcription complex-associated) of the RNAs produced in PNA-inhibited reactions, pol III is "roadblocked" by the DNA-PNA adduct before reaching the terminator region. On different templates, the distance between the active site and the leading edge of the arrested polymerase ranged from 10 to 20 base pairs. Given their ability to efficiently block pol III elongation, oligothymine PNAs lend themselves as potential cell growth inhibitors interfering with eukaryotic class III gene transcription.

Interaction of the vaccinia virus nucleoside triphosphate phosphohydrolase I with linear oligonucleotides.

Vaccinia virus nucleoside triphosphate phosphohydrolase I (NPH I) serves as the ATPase activity employed in early gene transcription termination [Deng, L., and Shuman, S. (1998) Genes Dev. 12, 538-546; Christen, L. M., et al. (1998) Virology 245, 360-371]. Since ATPase activity requires binding of single-stranded DNA, a full understanding of the mechanism of oligonucleotide activation is essential for the elucidation of its role in transcription termination. To initiate detailed structure-function studies of NPH I, we undertook combined kinetic and binding analyses of the interaction of linear oligonucleotides with NPH I. In the presence of single-stranded DNA, ATP exhibits complex saturation kinetics. The apparent Km for ATP is independent of DNA concentration, demonstrating that ssDNA binding alters the kcat for the reaction. Linear ssDNA oligonucleotides from 18 to 48 nucleotides in length stimulated activity in a saturatable fashion. As the oligonucleotide length increases, the Kact decreases and the Vmax increases. The increase in affinity is paralleled by an increase in the level of binding as measured by EMSA. The kinetic activation observed for 36-nucleotide ssDNA is dependent upon ATP concentration. At low ATP levels, sigmoidal saturation kinetics are observed, while at saturating ATP levels, near-hyperbolic kinetics are seen, suggesting that NPH I may adopt two conformational states. Linear oligonucleotides 18, 24, and 36 bases in length bind one, two, and three molecules of NPH I maximally, respectively, indicating that the NPH I binding site is no more than 12 bases in length. In contrast, single-stranded RNA does not stimulate ATPase activity, yet RNA binds as well as DNA of a similar length. Both RNA and DNA can be photo-cross-linked to NPH I by UV light. ssDNA and ssRNA cross-compete in UV photo-cross-linking to NPH I, indicating that both oligonucleotides share a common binding site. ssRNA prevents ssDNA activation of ATPase activity, confirming that both oligonucleotides bind to the kinetically important oligonucleotide activation site on NPH I. ssDNA inhibits transcription termination in vitro. Inhibition is overcome by adding NPH I, demonstrating that oligonucleotide inhibition is mediated through NPH I.

Mechanism of inhibition of bacteriophage T7 RNA polymerase by T7 lysozyme.

Bacteriophage T7 lysozyme is known to inhibit transcription by T7 RNA polymerase. Lysozyme present before initiation inhibited the synthesis of long RNA chains but did not inhibit elongation when added shortly after chains were initiated. A combination of gel-shift and transcription assays showed that lysozyme and polymerase form a 1:1 complex that binds promoter DNA and makes abortive transcripts, indicating that lysozyme has little effect on the early steps of transcription. Extension of stalled transcription complexes suggested that a transcribing polymerase becomes resistant to lysozyme inhibition after synthesis of an RNA chain as short as 15 nucleotides. It seems likely that bound lysozyme prevents an initiating polymerase from converting to an elongation complex. This conversion is thought to involve both a conformational change in the polymerase and the binding of nascent RNA. Gel-shift experiments indicated that lysozyme does not interfere with the binding of RNA, so it probably prevents a necessary conformational change in the polymerase. Lysozyme also increased pausing or termination at two sites in lambda DNA and at a site near the right end of the concatemer junction of T7 DNA. If pausing at these sites involves a reversal from the elongation to the initiation conformation, lysozyme may increase pausing or termination by "locking in" the initiation conformation. The arrest of transcription complexes near promoters and near the right end of the concatemer junction almost certainly must relate to lysozyme's ability to stimulate replication, maturation and packaging of T7 DNA during T7 infection.

Identification of the lytic origin of DNA replication in human cytomegalovirus by a novel approach utilizing ganciclovir-induced chain termination.

Infection with human cytomegalovirus in the presence of the antiviral nucleotide analog ganciclovir results in continuing low-level viral DNA synthesis and the accumulation of relatively small fragments of double-stranded progency DNA. These fragments consistently proved to represent amplification of sequences from only one small section of the viral genome (EcoRI-V) lying near the center of the unique L segment. Further mapping revealed that the viral sequences represented in these fragments occurred in gradients of abundance that decreased in both directions from a point near 0.35 to 0.4 map unit. The proportion of amplified sequences increased with both time after infection and dosage of ganciclovir used. We conclude that the primary lytic cycle replication origin of human cytomegalovirus lies within a 3- to 4-kb region immediately upstream and to the right of the promoter for the single-stranded DNA-binding protein (DB140). The amplified origin-containing DNA molecules appeared to arise by continuing rounds of bidirectional initiation on truncated fragments of the genome that were generated as a result of chain termination effects induced by the incorporation of ganciclovir into the viral DNA. Inspection of the DNA sequence in the vicinity of ori-Lyt revealed a large complex upstream region that may be a noncoding intergenic domain and that bears no homology to any previously described herpesvirus origin. This 2.5-kb region includes many duplicated and inverted sequences, together with consensus CRE/ATF and other transcription factor-binding sites, and an interesting set of 23 copies of an interspersed decamer consensus element AAAACACCGT that is also conserved at the equivalent locus in simian cytomegalovirus. This work represents the first identification of an origin domain in a cytomegalovirus genome and is the first demonstration of a bidirectional mechanism for any herpesvirus lytic cycle origin.

rho factor-dependent transcription termination. Interference by a mutant rho.

The rho protein isolated from a strain of Escherichia coli with the rho1 (suA1) mutant allele is defective in interactions with RNA that are coupled to ATP hydrolysis. Here we show that the rho1 allele is partially dominant over wild-type and demonstrate that the mechanism of that dominance is due to an interference of wild-type rho factor function by the defective rho factor. The rho1 mutant protein can inhibit transcription termination and RNA-dependent ATPase activities of normal rho protein. Inhibition of the ATPase activity with excess RNA occurs by exchange of subunits to form hybrid hexamers in which the defective subunits apparently disrupt co-operative interactions essential for wild-type subunit function.

Hormonally induced alterations of chromatin structure in the polyadenylation and transcription termination regions of the chicken ovalbumin gene.

We have studied the chromatin structure of a 16-kb region of the chicken genome containing the 3'-terminal 2 kb of the ovalbumin pre-mRNA coding sequence and the 14-kb segment located immediately downstream from the main mRNA polyadenylation site. Using the indirect end-labelling technique, four major and two minor DNase I-hypersensitive regions were found in the oviduct chromatin, whereas they were not present in liver, kidney or erythrocyte chromatin. The first hypersensitive region (region A) was present in chromatin of oviducts from laying hen and estrogen- or progesterone-stimulated immature chicks, in which the ovalbumin gene is expressed, but not in the chromatin of 'acute withdrawn' chicks where the gene is no longer transcribed. Region A spans 1.3 kb, from 7.2 to 8.5 kb downstream from the ovalbumin gene capsite (position +1), and encompasses the 3' moiety of the last exon including the major polyadenylation signal and polyadenylation site located at +7546 and +7564, respectively. Region A also contains a minor polyadenylation signal present at +7294 and the corresponding polyadenylation site at +7368. Two putative termination sequences at +8445 and +8483 are also found at the 3' extremity of region A in a 170-bp DNA segment within which 90% of the ovalbumin primary transcripts apparently terminate. Two minor hormone-independent DNase I-hypersensitive regions (a1 and a2) located at +8.6 and +8.8 kb are also specific to oviduct chromatin.(ABSTRACT TRUNCATED AT 250 WORDS)

Termination sites of the in vitro DNA synthesis on single-stranded DNA photosensitized by promazines.

Bacteriophage phi X174 and M13 mp9 single-stranded DNA molecules were primed either with restriction fragments or synthetic primers and irradiated with near UV light in the presence of promazine derivatives. These DNAs were used as template for in vitro complementary chain synthesis by Escherichia coli DNA polymerase I large fragment. Chain terminations were observed by denaturing polyacrylamide gel electrophoresis of the synthesis products and localized by comparison with a standard dideoxy sequencing pattern. More than 90% of the chain terminations were mapped exactly one nucleotide before a guanine residue. In addition, photoreaction was shown to occur more predominantly with guanine residues localized in single-stranded parts of the genome. The same guanine residues could also be damaged when the reaction was performed, in the dark, in the presence of the artificially generated promazine cation radicals. Using the BamHI-SmaI adaptor (5'GATCCCCGGG-3'), it was shown that the guanine alteration was a covalent addition of the promazine, or of a cation radical photodegradation product, on the guanine moiety. Kinetics of chlorpromazine photoaddition on single-stranded and double-stranded DNAs were determined.