Synergistic Antiviral Effects of Metal Oxides and Carbon Nanotubes.

In this research, the synergistic antiviral effects of carbon nanotubes (CNTs) and metal oxides (MO) in the form of novel hybrid structures (MO-CNTs) are presented. Raw CNTs, Ni(OH)2, Fe2O3 and MnO2, as well as Ni(OH)2-CNT, Fe2O3-CNT and MnO2-CNT were explored in this study against Escherichia. coli MS2 bacteriophage, which was used as a virus surrogate. The nano particles were synthesized and characterized using field emission scanning electron microscopy (FESEM), energy-dispersive X-ray spectroscopy (EDS), transmission electron microscopy (TEM), particle size analysis, Fourier-transform infrared spectroscopy (FTIR) and X-ray diffraction (XRD). Kinetic parameters such as the LD50 (lethal dose to kill 50% of the population), T50 and T80 (time taken to kill 50% and 80% of the population), SGR (specific growth rate) and IRD (initial rate of deactivation of the population) were also studied to examine the antiviral efficacy of these nanomaterials. Among all the nanomaterials, Ni(OH)2-CNT was the most effective antiviral agent followed by Fe2O3-CNT, MnO2-CNT, raw CNTs, Ni(OH)2, Fe2O3 and MnO2. When comparing the metal oxide-CNTs to the raw CNTs, the average enhancement was 20.2%. The average antiviral activity enhancement of the MO-CNTs were between 50 and 54% higher than the MO itself. When compared to the raw CNTs, the average enhancement over all the MO-CNTs was 20.2%. The kinetic studies showed that the LD50 of Ni(OH)2-CNT was the lowest (16µg/mL), which implies that it was the most toxic of all the compounds studied. The LD50 of Ni(OH)2, Fe2O3 and MnO2 were 17.3×, 14.5× and 10.8× times greater than their corresponding hybrids with the CNTs. The synergistic mechanism involved the entrapment of phage viruses by the nano structured CNTs leading to structural damage along with toxicity to phage from the release of MO ions. The metal oxide-CNT nano hybrids developed in this project are promising candidates in applications such as antiviral coatings, nanocomposites, adsorbents and as components of personal protection gears.

Applications of Bacillus subtilis Protein Display for Medicine, Catalysis, Environmental Remediation, and Protein Engineering.

Bacillus subtilis spores offer several advantages that make them attractive for protein display. For example, protein folding issues associated with unfolded polypeptide chains crossing membranes are circumvented. In addition, they can withstand physical and chemical extremes such as heat, desiccation, radiation, ultraviolet light, and oxidizing agents. As a result, the sequence of the displayed protein can be easily obtained even under harsh screening conditions. Next, immobilized proteins have many economic and technological advantages. They can be easily separated from the reaction and the protein stability is increased in harsh environments. In traditional immobilization methods, proteins are expressed and purified and then they are attached to a matrix. In contrast, immobilization occurs naturally during the sporulation process. They can be easily separated from the reaction and the protein stability is increased in harsh environments. Spores are also amenable to high-throughput screening for protein engineering and optimization. Furthermore, they can be used in a wide array of biotechnological and industrial applications such as vaccines, bioabsorbants to remove toxic chemicals, whole-cell catalysts, bioremediation, and biosensors. Lastly, spores are easily produced in large quantities, have a good safety record, and can be used as additives in foods and drugs.

Investigation of the donor and acceptor range for chiral carboligation catalyzed by the E1 component of the 2-oxoglutarate dehydrogenase complex.

The potential of thiamin diphosphate (ThDP)-dependent enzymes to catalyze C-C bond forming (carboligase) reactions with high enantiomeric excess has been recognized for many years. Here we report the application of the E1 component of the Escherichia coli 2-oxoglutarate dehydrogenase multienzyme complex in the synthesis of chiral compounds with multiple functional groups in good yield and high enantiomeric excess, by varying both the donor substrate (different 2-oxo acids) and the acceptor substrate (glyoxylate, ethyl glyoxylate and methyl glyoxal). Major findings include the demonstration that the enzyme can accept 2-oxovalerate and 2-oxoisovalerate in addition to its natural substrate 2-oxoglutarate, and that the tested acceptors are also acceptable in the carboligation reaction, thereby very much expanding the repertory of the enzyme in chiral synthesis.

Assignment of function to histidines 260 and 298 by engineering the E1 component of the Escherichia coli 2-oxoglutarate dehydrogenase complex; substitutions that lead to acceptance of substrates lacking the 5-carboxyl group.

The first component (E1o) of the Escherichia coli 2-oxoglutarate dehydrogenase complex (OGDHc) was engineered to accept substrates lacking the 5-carboxylate group by subjecting H260 and H298 to saturation mutagenesis. Apparently, H260 is required for substrate recognition, but H298 could be replaced with hydrophobic residues of similar molecular volume. To interrogate whether the second component would allow synthesis of acyl-coenzyme A derivatives, hybrid complexes consisting of recombinant components of OGDHc (o) and pyruvate dehydrogenase (p) enzymes were constructed, suggesting that a different component is the "gatekeeper" for specificity for these two multienzyme complexes in bacteria, E1p for pyruvate but E2o for 2-oxoglutarate.

Laboratory evolution of a soluble, self-sufficient, highly active alkane hydroxylase.

We have converted cytochrome P450 BM-3 from Bacillus megaterium (P450 BM-3), a medium-chain (C12-C18) fatty acid monooxygenase, into a highly efficient catalyst for the conversion of alkanes to alcohols. The evolved P450 BM-3 exhibits higher turnover rates than any reported biocatalyst for the selective oxidation of hydrocarbons of small to medium chain length (C3-C8). Unlike naturally occurring alkane hydroxylases, the best known of which are the large complexes of methane monooxygenase (MMO) and membrane-associated non-heme iron alkane monooxygenase (AlkB), the evolved enzyme is monomeric, soluble, and requires no additional proteins for catalysis. The evolved alkane hydroxylase was found to be even more active on fatty acids than wild-type BM-3, which was already one of the most efficient fatty acid monooxgenases known. A broad range of substrates including the gaseous alkane propane induces the low to high spin shift that activates the enzyme. This catalyst for alkane hydroxylation at room temperature opens new opportunities for clean, selective hydrocarbon activation for chemical synthesis and bioremediation.

Engineering CotA Laccase for Acidic pH Stability Using Bacillus subtilis Spore Display.

Bacillus subtilis spores can be used for protein display to engineer protein properties. This method overcomes viability and protein-folding concerns associated with traditional protein display methods. Spores remain viable under extreme conditions and the genotype/phenotype connection remains intact. In addition, the natural sporulation process eliminates protein-folding concerns that are coupled to the target protein traveling through cell membranes. Furthermore, ATP-dependent chaperones are present to assist in protein folding. CotA was optimized as a whole-cell biocatalyst immobilized in an inert matrix of the spore. In general, proteins that are immobilized have advantages in biocatalysis. For example, the protein can be easily removed from the reaction and it is more stable. The aim is to improve the pH stability using spore display. The maximum activity of CotA is between pH 4 and 5 for the substrate ABTS (ABTS = diammonium 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonate). However, the activity dramatically decreases at pH 4. The activity is not significantly altered at pH 5. A library of approximately 3,000 clones was screened. A E498G variant was identified to have a half-life of inactivation (t1/2) at pH 4 that was 24.8 times greater compared with wt-CotA. In a previous investigation, a CotA library was screened for organic solvent resistance and a T480A mutant was found. Consequently, T480A/E498G-CotA was constructed and the t1/2 was 62.1 times greater than wt-CotA. Finally, E498G-CotA and T480A/E498G-CotA yielded 3.7- and 5.3-fold more product than did wt-CotA after recycling the biocatalyst seven times over 42 h.

Fluorescence activated cell sorting for enzymatic activity.

Directed evolution is a reliable method for protein engineering and as a tool for investigating structure/function relationships. A key for a successful directed evolution experiment is oftentimes the screen. Fluorescence activated cell sorting (FACS) is powerful high-throughput screening approach to isolate and identify mutants from large protein libraries. FACS has been successful in isolating proteins with improved or altered binding affinity. However, FACS screening for mutants with enhanced catalytic activity has been met with limited success. This review focuses on the FACS screening of protein libraries for enzymatic activity.

Colorimetric high-throughput assay for alkene epoxidation catalyzed by cytochrome P450 BM-3 variant 139-3.

Cytochrome P450 BM-3 variant 139-3 is highly active in the hydroxylation of alkanes and fatty acids (AGlieder, ET Farinas, and FH Arnold, Nature Biotech 2002;20:1135-1139); it also epoxidizes various alkenes, including styrene. Here the authors describe a colorimetric, high-throughput assay suitable for optimizing this latter activity by directed evolution. The product of styrene oxidation by 139-3, styrene oxide, reacts with the nucleophile gamma-(4-nitrobenzyl)pyridine (NBP) to form a purple-colored precursor dye, which can be monitored spectrophotometrically in cell lysates. The sensitivity limit of this assay is 50-100 microM of product, and the detection limit for P450 BM-3 139-3 is ~0.2 microM of enzyme. To validate the assay, activities in a small library of random mutants were compared to those determined using an NADPH depletion assay for initial turnover rates.

Photoinduced DNA Cleavage Reactions by Designed Analogues of Co(III)-Bleomycin: The Metalated Core Is the Primary Determinant of Sequence Specificity.

A 2,4'-bithiazole group has been covalently attached to the Co(III) complex of a designed ligand PMAH that mimics the metal-binding locus of the antitumor drug bleomycin (BLM). The deprotonated PMA(-) ligand binds Co(III) via five nitrogens located in primary and secondary amines, a pyrimidine and an imidazole ring, and a peptide moiety. The 2,4'-bithiazole group is tethered to the [Co(PMA)](2+) unit via an imidazole that is connected to the bithiazole moiety with a (CH(2))(3) spacer. The structure of this hybrid analogue, namely, [Co(PMA)(Bit)]Cl(2) (7, Bit = 2'-methyl-2,4'-bithiazole-4-carboxamido-N'-(3-propyl)imidazole) has been established by spectroscopic techniques. 7 promotes photocleavage of DNA at micromolar concentrations. Unlike simpler analogues like [Co(PMA)(H(2)O)](2+) and [Co(PMA)Cl)](+) which induce random DNA cleavage upon UV illumination, 7 exhibits sequence specificity in the DNA photocleavage reaction. Intriguing is to note that 7 exhibits the same 5'GG-N3' sequence preference as another hybrid analogue [Co(PMA)(Int-A)]Cl(2) (6, Int-A = acridine-9-carboxamido-N'-(3-propyl)imidazole) that contains an acridine moiety as the DNA-binding group. The observed sequence specificity of 6 and 7 therefore does not reflect the sequence preferences of the DNA-binding groups (acridine and bithiazole). The results indicate that the metalated core of the hybrid analogues, i.e., the [Co(PMA)](2+) unit is the key factor in determining their sequence specificity.

Bacillus subtilis spore display of laccase for evolution under extreme conditions of high concentrations of organic solvent.

Protein libraries were displayed on the spore coat of Bacillus subtilis, and this method was demonstrated as a tool for directed evolution under extreme conditions. Escherichia coli, yeast, and phage display suffer from protein folding, and viability issues. On the other hand, spores avoid folding concerns by the natural sporulation process, and they remain viable under harsh chemical and physical environments. The naturally occurring B. subtilis spore coat protein, CotA, was evolved for improved activity under conditions of high organic solvent concentrations. CotA is a laccase, which is a copper-containing oxidase enzyme. A CotA library was expressed on the spore coat, and ∼ 3000 clones were screened at 60% dimethyl sulfoxide (DMSO). A Thr480Ala variant (Thr480Ala-CotA) was identified that was 2.38-fold more active than the wild-type CotA. In addition, Thr480Ala-CotA was more active with different concentrations of DMSO ranging from 0 to 70%. The mutant was also found to be more active compared with the wild-type CotA in different concentrations of methanol, ethanol, and acetonitrile.

Directed evolution of CotA laccase for increased substrate specificity using Bacillus subtilis spores.

Directed evolution is an effective strategy to engineer and optimize protein properties, and microbial cell-surface display is a successful method to screen protein libraries. Protein surface display on Bacillus subtilis spores is demonstrated as a tool for screening protein libraries for the first time. Spore display offers advantages over more commonly utilized microbe cell-surface display systems, which include gram-negative bacteria, phage and yeast. For instance, protein-folding problems associated with the expressed recombinant polypeptide crossing membranes are avoided. Hence, a different region of protein space can be explored that previously was not accessible. In addition, spores tolerate many physical/chemical extremes; hence, the displayed proteins are "preimmobilized" on the inherently inert spore surface. Immobilized proteins have several advantages when used in industrial processes. The protein stability is increased and separations are simplified. Finally, immobilized proteins can be used in a wide array of simple device applications and configurations. The substrate specificity of the enzyme CotA is narrowed. CotA is a laccase and it occurs naturally on the outer coat of B. subtilis spores. A library of CotA genes were expressed in the spore coat, and it was screened for activity toward ABTS [diammonium 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonate)] over SGZ (4-hydroxy-3,5-dimethoxy-benzaldehyde azine). A mutant CotA was found to be 120-fold more specific for ABTS. This research demonstrates that B. subtilis spores can be a useful platform for screen protein libraries.

Narrowing laccase substrate specificity using active site saturation mutagenesis.

The laccase CotA from Bacillus subtilis was converted from a generalist, an enzyme with broad specificity, to a specialist, an enzyme with narrowed specificity. Laccases are members of the multicopper oxidase family and have many applications in biotechnology. To date, it has not been demonstrated that substrate specificity can be tapered for a laccase. Wild-type CotA oxidizes ABTS (ABTS = diammonium 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonate) and SGZ (SGZ = 4-hydroxy-3,5- dimethoxy-benzaldehyde azine), and it was engineered for increased specificity for ABTS by combining rational and directed evolution approaches. The wild-type was evolved by simultaneously randomizing 19 amino acids found in the substrate-binding pocket. A mutant was identified that had a catalytic efficiency, (k(cat)/K(M))(ATBS) / (k(cat)/K(M))(SGZ), 7.0 times greater when compared to the wild-type after one round of screening. This illustrates that the substrate-binding pocket is highly evolvable for specificity.