Carboxyl Methyltransferase Catalysed Formation of Mono- and Dimethyl Esters under Aqueous Conditions: Application in Cascade Biocatalysis

Carboxyl methyltransferase (CMT) enzymes catalyse the biomethylation of carboxylic acids under aqueous conditions and have potential for use in synthetic enzyme cascades. Herein we report that the enzyme FtpM from Aspergillus fumigatus can methylate a broad range of aromatic mono- and dicarboxylic acids in good to excellent conversions. The enzyme shows high regioselectivity on its natural substrate fumaryl-l-tyrosine, trans, trans-muconic acid and a number of the dicarboxylic acids tested. Dicarboxylic acids are generally better substrates than monocarboxylic acids, although some substituents are able to compensate for the absence of a second acid group. For dicarboxylic acids, the second methylation shows strong pH dependency with an optimum at pH 5.5-6. Potential for application in industrial biotechnology was demonstrated in a cascade for the production of a bioplastics precursor (FDME) from bioderived 5-hydroxymethylfurfural (HMF).

A fluorescence study of the binding of poly(1,N6-ethenoadenylic acid) to Escherichia coli initiation factor 3

The binding of initiation Factor 3 (IF3) to poly (1,N6-ethenoadenylic acid) [poly(epsilon A)] was investigated by fluorescence spectroscopy. At low salt concentrations, IF3 evokes an increase in the fluorescence intensity of poly(epsilon A) due to the unstacking of the nucleotide bases. The poly(epsilon A) fluorescence enhancement titrates to an endpoint of 13 +/- 2 nucleotide residues per IF3. The maximum poly(epsilon A) fluorescence enhancement, at lattice saturation, decreases with increasing salt concentration. Even though IF3 does not produce a large fluorescence increase between 75 and 200 mM NaCl concentration, the protein still binds to poly(epsilon A) at these salt concentrations as measured by sedimentation partition chromatography; the value of Kobs for the IF3-poly(epsilon A) interaction is comparable to that of other synthetic polynucleotides. The binding of IF3 to poly(A) at 150 and 200 mM NaCl induces an increase in nucleotide base-base separation as determined by CD, yet IF3-induced disruption of base stacking of poly(epsilon A) at these same salt concentrations is not detected by fluorescence. It is likely that IF3 binds primarily to the phosphate backbone of poly(epsilon A) at low salt concentrations, producing an increase in the fluorescence intensity. But, at higher salt concentrations, the aromatic amino acids intercalate between the nucleotide bases quenching the poly(epsilon A) fluorescence.