Biocatalytic potential of laccase-like multicopper oxidases from Aspergillus niger

Background

The integration of biotechnology into chemical manufacturing has been recognized as a key technology to build a sustainable society. However, the practical applications of biocatalytic chemical conversions are often restricted due to their complexities involving the unpredictability of product yield and the troublesome controls in fermentation processes. One of the possible strategies to overcome these limitations is to eliminate the use of living microorganisms and to use only enzymes involved in the metabolic pathway. Use of recombinant mesophiles producing thermophilic enzymes at high temperature results in denaturation of indigenous proteins and elimination of undesired side reactions; consequently, highly selective and stable biocatalytic modules can be readily prepared. By rationally combining those modules together, artificial synthetic pathways specialized for chemical manufacturing could be designed and constructed.

Results

A chimeric Embden-Meyerhof (EM) pathway with balanced consumption and regeneration of ATP and ADP was constructed by using nine recombinant E. coli strains overproducing either one of the seven glycolytic enzymes of Thermus thermophilus, the cofactor-independent phosphoglycerate mutase of Pyrococcus horikoshii, or the non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase of Thermococcus kodakarensis. By coupling this pathway with the Thermus malate/lactate dehydrogenase, a stoichiometric amount of lactate was produced from glucose with an overall ATP turnover number of 31.

Conclusions

In this study, a novel and simple technology for flexible design of a bespoke metabolic pathway was developed. The concept has been testified via a non-ATP-forming chimeric EM pathway. We designated this technology as “synthetic metabolic engineering”. Our technology is, in principle, applicable to all thermophilic enzymes as long as they can be functionally expressed in the host, and thus would be potentially applicable to the biocatalytic manufacture of any chemicals or materials on demand.

     

A virus-inducible tobacco gene encoding a glycine-rich protein shares putative regulatory elements with the ribulose bisphosphate carboxylase small subunit gene

cDNA to an mRNA that is strongly induced in Samsun NN tobacco after tobacco mosaic virus (TMV) infection or salicylic acid treatment was used to probe a genomic blot and to screen a genomic library. The mRNA corresponds to a family of approximately eight genes, four of which were cloned. The sequence of the genes and flanking DNA in two clones was determined. One gene was found to contain an intron of 555 bp; S1-nuclease mapping studies indicated that this gene is expressed. The other gene is interrupted by an intron of 1,954 bp and is probably not expressed after TMV infection. The genes encode a protein of 109 amino acids with a putative N-terminal signal peptide of 26 amino acids. The protein contains a high proportion of glycine (25%) and charged amino acids (29%), suggesting that it may be a cell wall component. A comparison of the upstream sequences of the genes encoding the glycine-rich protein and the pathogenesis-related protein 1a showed only limited homology, although both genes are TMV- and salicylic acid-inducible. However, the upstream sequence of the glycine-rich protein gene contains a 64-bp inverted repeat that occurs in a similar position in the tobacco ribulose bisphosphate carboxylase small subunit gene.     

Complete sequence of the gene encoding the largest subunit of RNA polymerase I of Trypanosoma brucei

We have set out to clone the trypanosomal gene encoding the largest subunit of RNA polymerase I. We screened a genomic library with a synthetic oligonucleotide probe encoding an eleven amino acid sequence motif, YNADFDGDEMN, which has been found in all eukaryotic RNA polymerase largest subunit genes analyzed so far. We isolated the Trp11 locus and determined the complete sequence of the gene encoded within this locus. The deduced amino acid sequence contains the highly conserved RNA polymerase domains as well as the previously identified RNA polymerase I-specific hydrophilic insertions. Therefore, the gene most closely resembles the largest subunit of RNA polymerase I.