A bacterial bioreporter for the detection of 1,3,5-trinitro-1,3,5-triazinane (RDX).

We report the design, construction, and testing of Escherichia coli-based bioluminescent bioreporters for the detection of 1,3,5-trinitro-1,3,5-triazinane (RDX), one of the most prevalent military-grade explosives in use today. These sensor strains are based on a fusion between the promoter of either the hmp (nitric oxide dioxygenase) or the hcp (a high-affinity nitric oxide reductase) E. coli gene, to the microbial bioluminescence luxCDABEG gene cassette. Signal intensity was enhanced in ∆hmp and ∆hcp mutants, and detection sensitivity was improved when the two gene promoters were cloned in tandem. The Photobacterium leiognathi luxCDABEG reporter genes were superior to those of Aliivibrio fischeri in terms of signal intensity, but in most cases inferior in terms of detection sensitivity, due to a higher background signal. Both sensor strains were also induced by additional nitro-organic explosives, as well as by nitrate salts. Sensitive detection of RDX in a solid matrix (either LB agar or sand) was also demonstrated, with the bioreporters encapsulated in 1.5-mm calcium alginate beads. Lowest RDX concentration detected in sand was 1.67 mg/kg sand. The bioreporter strains described herein may serve as a basis for a standoff detection technology of RDX-based explosive devices, including buried landmines.

Detection of buried explosives with immobilized bacterial bioreporters.

The unchecked dispersal of antipersonnel landmines since the late 19th century has resulted in large areas contaminated with these explosive devices, creating a substantial worldwide humanitarian safety risk. The main obstacle to safe and effective landmine removal is the identification of their exact location, an activity that currently requires entry of personnel into the minefields; to date, there is no commercialized technology for an efficient stand-off detection of buried landmines. In this article, we describe the optimization of a microbial sensor strain, genetically engineered for the remote detection of 2,4,6-trinitrotoloune (TNT)-based mines. This bioreporter, designed to bioluminescence in response to minute concentrations of either TNT or 2,4-dinitotoluene (DNT), was immobilized in hydrogel beads and optimized for dispersion over the minefield. Following modifications of the hydrogel matrix in which the sensor bacteria are encapsulated, as well as their genetic reporting elements, these sensor bacteria sensitively detected buried 2,4-dinitrotoluene in laboratory experiments. Encapsulated in 1.5 mm 2% alginate beads containing 1% polyacrylic acid, they also detected the location of a real metallic antipersonnel landmine under field conditions. To the best of our knowledge, this is the first report demonstrating the detection of a buried landmine with a luminescent microbial bioreporter.

A Bis-Zn2+ -Pyridyl-Salen-Type Complex Conjugated to the ATP Aptamer: An ATPase-Mimicking Nucleoapzyme.

Catalytic nucleic acids consisting of a bis-Zn2+ -pyridyl-salen-type ([di-ZnII 3,5 bis(pyridinylimino) benzoic acid]) complex conjugated to the ATP aptamer act as ATPase-mimicking catalysts (nucleoapzymes). Direct linking of the Zn2+ complex to the 3'- or 5'-end of the aptamer (nucleoapzymes I and II) or its conjugation to the 3'- or 5'-end of the aptamer through bis-thymidine spacers (nucleoapzymes III and IV) provided a set of nucleoapzymes exhibiting variable catalytic activities. Whereas the separated bis-Zn2+ -pyridyl-salen-type catalyst and the ATP aptamer do not show any noticeable catalytic activity, the 3'-catalyst-modified nucleoapzyme (nucleoapzyme IV) and, specifically, the nucleoapzyme consisting of the catalyst linked to the 3'-position through the spacer (nucleoapzyme III) reveal enhanced catalytic features in relation to the analogous nucleoapzyme substituted at the 5'-position (kcat =4.37 and 6.88 min-1 , respectively). Evaluation of the binding properties of ATP to the different nucleoapzyme and complementary molecular dynamics simulations suggest that the distance separating the active site from the substrate linked to the aptamer binding site controls the catalytic activities of the different nucleoapzymes.

Topologies of N6 -adenosine methylation (m6 A) in land plant mitochondria and their putative effects on organellar gene expression.

Mitochondria serve as major sites of ATP production and play key roles in many other metabolic processes that are critical to the cell. As relicts of an ancient bacterial endosymbiont, mitochondria contain their own hereditary material (i.e. mtDNA, or mitogenome) and a machinery for protein biosynthesis. The expression of the mtDNA in plants is complex, particularly at the post-transcriptional level. Following transcription, the polycistronic pre-RNAs undergo extensive modifications, including trimming, splicing and editing, before being translated by organellar ribosomes. Our study focuses on N6 -methylation of adenosine ribonucleotides (m6 A-RNA) in plant mitochondria. m6 A is a prevalent modification in nuclear-encoded mRNAs. The biological significance of this dynamic modification is under investigation, but it is widely accepted that m6 A mediates structural switches that affect RNA stability and/or activity. Using m6 A-pulldown/RNA-seq (m6 A-RIP-seq) assays of Arabidopsis and cauliflower mitochondria, we provide information on the m6 A-RNA landscapes in Arabidopsis thaliana and Brassica oleracea mitochondria. The results show that m6 A targets different types of mitochondrial transcripts, including known genes, mtORFs, as well as non-coding (transcribed intergenic) RNA species. While ncRNAs undergo multiple m6 A modifications, N6 -methylation of adenosine residues with mRNAs seem preferably positioned near start codons and may modulate their translatability.

Aerobic Transformation of 2,4-Dinitrotoluene by Escherichia coli and Its Implications for the Detection of Trace Explosives.

DNT (2,4-dinitrotoluene), a volatile impurity in military-grade 2,4,6-trinitrotoluene (TNT)-based explosives, is a potential tracer for the detection of buried landmines and other explosive devices. We have previously described an Escherichia coli bioreporter strain engineered to detect traces of DNT and have demonstrated that the yqjF gene promoter, the sensing element of this bioreporter, is induced not by DNT but by at least one of its transformation products. In the present study, we have characterized the initial stages of DNT biotransformation in E. coli, have identified the key metabolic products in this reductive pathway, and demonstrate that the main DNT metabolite that induces yqjF is 2,4,5-trihydroxytoluene. We further show that E. coli cannot utilize DNT as a sole carbon or nitrogen source and propose that this compound is metabolized in order to neutralize its toxicity to the cells.IMPORTANCE The information provided in this article sheds new light both on the microbial biodegradability of nitroaromatic compounds and on the metabolic capabilities of E. coli By doing so, it also clarifies the pathway leading to the previously unexplained induction of the E. coli yqjF gene by 2,4-dinitrotoluene, an impurity that accompanies 2,4,6-trinitrotoluene (TNT)-based explosives. Our improved understanding of these processes will serve to molecularly enhance the performance of a previously described microbial bioreporter of buried landmines and other explosive devices, in which the yqjF gene promoter serves as the sensing element.

Backbone cyclic peptide inhibitors of protein kinase B (PKB/Akt).

Elevated levels of activated protein kinase B (PKB/Akt) have been detected in many types of cancer. Substrate-based peptide inhibitors have the advantage of selectivity due to their extensive interactions with the kinase-specific substrate binding site but often lack necessary pharmacological properties. Chemical modifications of potent peptide inhibitors, such as cyclization, may overcome these drawbacks while maintaining potency. We present an extensive structure-activity relationship (SAR) study of a potent peptide-based PKB/Akt inhibitor. Two backbone cyclic (BC) peptide libraries with varying modes of cyclization, bridge chemistry, and ring size were synthesized and evaluated for in vitro PKB/Akt inhibition. Backbone-to-backbone urea BC peptides were more potent than N-terminus-to-backbone amide BC peptides. Several analogues were up to 10-fold more active than the parent linear peptide. Some activity trends could be rationalized using computational surface mapping of the PKB/Akt kinase catalytic domain. The novel molecules have enhanced pharmacological properties which make them promising lead candidates.

QM/MM study of the active species of the human cytochrome P450 3A4, and the influence thereof of the multiple substrate binding.

Cytochrome P450 3A4 is involved in the metabolism of 50% of all swallowed drugs. The enzyme functions by means of a high-valent iron-oxo species, called compound I (Cpd I), which is formed after entrance of the substrate to the active site. We explored the features of Cpd I using hybrid quantum mechanical/molecular mechanical calculations on various models that are either substrate-free or containing one and two molecules of diazepam as a substrate. Mössbauer parameters of Cpd I were computed. Our major finding shows that without the substrate, Cpd I tends to elongate its Fe-S bond, localize the radical on the sulfur, and form hydrogen bonds with A305 and T309, which may hypothetically lead to Cpd I consumption by H-abstraction. However, the positioning of diazepam close to Cpd I, as enforced by the effector molecule, was found to strengthen the NH...S interactions of the conserved I443 and G444 residues with the proximal cysteinate ligand. These interactions are known to stabilize the Fe-S bond, and as such, the presence of the substrate leads to a shorter Fe-S bond and it prevents the localization of the radical on the sulfur. This diazepam-Cpd I stabilization was manifested in the 1W0E conformer. The effector substrate did not influence Cpd I directly but rather by positioning the active substrate close to Cpd I, thus displacing the hydrogen bonds with A305 and T309, and thereby giving preference to substrate oxidation. It is hypothesized that these effects on Cpd I, promoted by the restrained substrate, may be behind the special metabolic behavior observed in cases of multiple substrate binding (also called cooperative binding). This restraint constitutes a mechanism whereby substrates stabilize Cpd I sufficiently long to affect monooxygenation by P450s at the expense of Cpd I destruction by the protein residues.

Structural dynamics of the cooperative binding of organic molecules in the human cytochrome P450 3A4.

Cytochrome P450 3A4 (CYP3A4) is a key enzyme responsible for the metabolism of 50% of all orally administered drugs which exhibit an intriguing kinetic behavior typified by a sigmoidal dependence of the reaction velocity on the substrate concentration. There is evidence for the binding of two substrates in the active site of the enzyme, but the mechanism of this cooperative binding is unclear. Diazepam is such a drug that undergoes metabolism by CYP3A4 with sigmoidal dependence. Metabolism is initiated by hydrogen atom abstraction from the drug. To understand the factors that determine the cooperative binding and the juxtaposition of the C-H bond undergoing abstraction, we carried out molecular dynamics simulations for two enzymatic conformers and examined the differences between the substrate-free and the bound enzymes, with one and two diazepam molecules. Our results indicate that the effector substrate interacts both with the active substrate and with the enzyme, and that this interaction results in side chain reorientation with relatively minor long-range effects. In accord with experiment, we find that F304, in the interface between the active and effector binding sites, is a key residue in the mechanism of cooperative binding. The addition of the effector substrate stabilizes F304 and its environment, especially F213, and induces a favorable orientation of the active substrate, leading to a short distance between the targeted hydrogen for abstraction and the active species of the enzyme. In addition, in one conformer of the enzyme, residue R212 may strongly interact with F304 and counteract the effector's impact on the enzyme.

Does substrate oxidation determine the regioselectivity of cyclohexene and propene oxidation by cytochrome p450?

DFT and QM/MM computations of allylic C-H hydroxylation versus C=C epoxidation in cyclohexene and propene by Compound I of P450cam demonstrate that the relative barriers for the oxidative processes themselves are not good predictors of the observed selectivity. However, a kinetic expression previously developed (Kozuch, S.; Shaik, S. J. Am. Chem. Soc. 2006, 128, 3355) for catalytic cycles under steady-state conditions, predicts, in accord with experiment, that propene will undergo exclusive C=C epoxidation, while cyclohexene will undergo both reactions with a small preference for epoxidation. The model expression for the effective barrier of the cycle forms a general basis for understanding and predicting the selectivity of P450 isozymes.