Synthesis of a polymide containing a glucose unit in the main chain

A new type polyamide containing a glucose unit in the main chain has been synthesized by the polymerization of C₁, C₃, C₄ blocked C₆-carboxymethylglucosamine, prepared from chitin. The deblocking procedure gave the water-soluble polyamide, of MW 1.5 × 10⁴, which can be regarded as a model for the recognition site of lectin.     

Laccase immobilization on enzymatically functionalized polyamide 6,6 fibres

Polyamide matrices, such as membranes, gels and non-wovens, have been applied as supports for enzyme immobilization, although in literature the enzyme immobilization on woven nylon matrices is rarely reported. In this work, a protocol for a Trametes hirsuta laccase immobilization using woven polyamide 6,6 (nylon) was developed. A 2⁴ full factorial design was used to study the influence of pH, spacer (1,6-hexanediamine), enzyme and crosslinker concentration on the efficiency of immobilization. The factors enzyme dosage and spacer seem to have played a critical role in the immobilization of laccase onto nylon support. Under optimized working conditions (29 U mL⁻¹ of laccase, 10% of glutaraldehyde, pH = 5.5, with the presence of the spacer), the half-life time attained was about 78 h (18% higher than that of free enzyme), the protein retention was 30% and the immobilization yield was 2%. The immobilized laccase has potential for application in the continuous decolourization of textile effluents, where it can be applied into a membrane reactor.     

Voltametric monitoring of enzyme-mediated indigo reduction in the presence of various fibre materials

A comparative study of enzyme-mediated indigo reduction is presented as an environmentally-friendly alternative to alkaline sodium dithionite reduction. The effect of the mediator 1,8-dihydroxy-9,10-anthraquinone in enzymatic reduction was studied by means of voltammetry, both in the presence and absence of different textile materials (polyamide 6, polyamide 6,6 and cotton), and compared to chemically reduced indigo. It was observed that bio-catalytic formation of leuco indigo and its exhaustion on substrates is inversely proportional to the pH within the range of 7–11. Additionally, substrate coloration was strongly influenced by the mediator, resulting in in situ formation of leuco indigo. This effect was most pronounced for polyamide substrates. The reuse of an enzyme-mediated reduction bath for dyeing was assessed showing that the levelness of the obtained shade was either excellent or good at pH 9 and 11, respectively. The wash, perspiration, and light color fastness properties of all textile materials dyed with enzymatically-reduced indigo were comparable or even better than those obtained with chemically reduced indigo. The use of enzyme-mediated reduction of indigo combined with potential reuse of the reduction bath represents a cost effective and environmentally-friendly dyeing process that can be applied for the dyeing of natural cellulosic and synthetic polyamide fibres.     

Conversion of the nitrogen content in liquid manure into biomass and polyglutamic acid by a newly isolated strain of Bacillus licheniformis

Extensive spreading of liquid manure onto agricultural fields causes eutrophication of ground and surface water and also pollution of the atmosphere due to the high ammonium nitrogen content. A poly(gamma-glutamic acid) (PGA)-producing strain of Bacillus licheniformis was isolated in this study and investigated for its ability to reduce the ammonium nitrogen by converting ammonium into biomass and PGA as depot forms of nitrogen. In batch cultivations swine manure and an optimized mineral salts medium were used for PGA production. For example the cultivation of B. licheniformis strain S2 in liquid manure, which was modified by adding of 18 g citrate and 80 g glycerol l(-1) and exhibited a carbon to nitrogen ratio of 15.5:1, led to severe reduction of the ammonium content from 2.83 to 0.1 g x l(-1) and to the production of 0.16 g PGA and 7.5 g cell dry mass l(-1) within 410 h. Approximately 28% (w/w) of the total nitrogen was converted into cellular biomass, whereas 0.1% (w/w) was used for the production of PGA. In addition, approximately 33% (w/v) of the original ammonium was lost by stripping.     

Effect of single pyrrole replacement with β-alanine on DNA binding affinity and sequence specificity of hairpin pyrrole/imidazole polyamides targeting 5′-GCGC-3′

N-Methylpyrrole (Py)–N-methylimidazole (Im) polyamides are small organic molecules that can recognize predetermined DNA sequences with high sequence specificity. As many eukaryotic promoter regions contain highly GC-rich sequences, it is valuable to synthesize and characterize Py–Im polyamides that recognize GC-rich motifs. In this study, we synthesized four hairpin Py–Im polyamides 1–4, which recognize 5′-GCGC-3′ and investigated their binding behavior with surface plasmon resonance assay. Py–Im polyamides 2–4 contain two, one, and one β-alanine units, replacing the Py units of 1, respectively. The binding affinities of 2–4 to the target DNA increased 430, 390, and 610-fold, respectively, over that of 1. The association and dissociation rates of 2 to the target DNA were improved by 11 and 37-fold, respectively, compared with those of 1. Interestingly, the association and dissociation rates of 3 and 4 were higher than those of 2, even though the binding affinities of 2, 3, and 4 to the target DNA were comparable to each other. The binding affinity of 2 to DNA with a 2 bp mismatch was reduced by 29-fold, compared with that to the matched DNA. Moreover, the binding affinities of 3 and 4 to the same mismatched DNA were reduced by 270 and 110-fold, respectively, indicating that 3 and 4 have greater specificities than 2 and are suitable as DNA-binding modules for engineered epigenetic regulation.     

Modifying the N-terminus of polyamides: PyImPyIm has improved sequence specificity over f-ImPyIm

Seven N-terminus modified derivatives of a previously published minor-groove binding polyamide (f-ImPyIm, 1) were synthesized and the biochemical and biophysical chemistry evaluated. These compounds were synthesized with the aim of attaining a higher level of sequence selectivity over f-ImPyIm (1), a previously published strong minor-groove binder. Two compounds possessing a furan or a benzofuran moiety at the N-terminus showed a footprint of 0.5 μM at the cognate ACGCGT site (determined by DNase I footprinting); however, the specificity of these compounds was not improved. In contrast, PyImPyIm (4) produced a footprint of 0.5 μM but showed a superior specificity using the same technique. When evaluated by thermal melting experiments and circular dichroism using ACGCGT and the non-cognate AAATTT sequence, all compounds were shown to bind in the minor-groove of DNA and stabilize the cognate sequence much better than the non-cognate (except for the non-amido-compound that did not bind either sequence, as expected). PyImPyIm (4) was interesting as the ΔT_m for this compound was only 4 °C but the footprint was very selective. No binding was observed for this compound with a third DNA (non-cognate, ACCGGT). ITC studies on compound 4 showed exothermic binding with ACGCGT and no heat change was observed for titrating the compound to the other two DNA sequences. The heat capacity (ΔC_p) of the PIPI/ACGCGT complex calculated from the hydrophobic interactions and SASA calculations was comparable to the experimental value obtained from ITC (−146 cal mol⁻¹ K⁻¹). SPR results provided confirmation of the sequence specificity of PyImPyIm (4), with a K_eq value determined to be 7.1 × 10⁶ M⁻¹ for the cognate sequence and no observable binding to AAATTT and ACCGGT. Molecular dynamic simulations affirmed that PyImPyIm (4) binds as a dimer in an overlapped conformation, and it fits snugly in the minor-groove of the ACGCGT oligonucleotide. PyImPyIm (4) is an especially interesting molecule, because although the binding affinity is slightly reduced, the specificity with respect to f-ImPyIm (1) is significantly improved.     

Recognition of the unique structure of DNA:RNA hybrids

Targeting nucleic acids using small molecules routinely uses the end products in the conversion pathway of "DNA to RNA, RNA to protein". However, the intermediate processes in this path have not always been targeted. The DNA-RNA interaction, specifically DNA:RNA hybrid formation, provides a unique target for controlling the transfer of genetic information through binding by small molecules. Not only do DNA:RNA hybrids differ in conformation from widely targeted DNA and RNA, the low occurrence within biological systems further validates their therapeutic potential. Surprisingly, a survey of the literature reveals only a handful of ligands that bind DNA:RNA hybrids; in comparison, the number of ligands designed to target DNA is in the thousands. DNA:RNA hybrids, from their scientific inception to current applications in ligand targeting, are discussed.     

2-Aminopurine/cytosine base pair containing oligonucleotides: fluorescence spectroscopy studies on DNA-polyamide binding

Studies on the binding of a triamide f-IPI (1) to its cognate sequence labeled with a 2-aminopurine (2AP or G^∗) group are described. ITC studies showed that f-IPI (1) bound to the cognate site (ACG^∗CGT) with only 3.5-fold lower affinity than binding to the unlabeled DNA (ACGCGT) (K_eq = 2 × 10⁷ and 7 × 10⁷ M⁻¹, respectively). Titration of f-IPI (1) to both sequences gave strong induced bands at 330 nm via circular dichroism studies. The compound also gave comparable ΔT_m values of 5.0 and 7.8 °C, respectively. These techniques also proved that the sequence selectivity of f-IPI (1) was uncompromised, as only limited binding to the non-cognate sequence ACCG^∗GT was observed. Fluorescence studies demonstrated a 2:1 ligand:DNA binding motif as anticipated, and indicated that the limit of detection for this technique was 20 μM DNA concentration. The results demonstrate that 2-aminopurine is a sufficient substitute for guanine in a G·C base pair useful in DNA binding studies.