A new concept of biocatalytic synthesis of acrylic monomers for obtaining water-soluble acrylic heteropolymers.

Rhodococcus strains were designed as model biocatalysts (BCs) for the production of acrylic acid and mixtures of acrylic monomers consisting of acrylamide, acrylic acid, and N-alkylacrylamide (N-isopropylacrylamide). To obtain BC strains, we used, among other approaches, adaptive laboratory evolution (ALE), based on the use of the metabolic pathway of amide utilization. Whole genome sequencing of the strains obtained after ALE, as well as subsequent targeted gene disruption, identified candidate genes for three new amidases that are promising for the development of BCs for the production of acrylic acid from acrylamide. New BCs had two types of amidase activities, acrylamide-hydrolyzing and acrylamide-transferring, and by varying the ratio of these activities in BCs, it is possible to influence the ratio of monomers in the resulting mixtures. Based on these strains, a prototype of a new technological concept for the biocatalytic synthesis of acrylic monomers was developed for the production of water-soluble acrylic heteropolymers containing valuable N-alkylacrylamide units. In addition to the possibility of obtaining mixtures of different compositions, the advantages of the concept are a single starting reagent (acrylamide), more unification of processes (all processes are based on the same type of biocatalyst), and potentially greater safety for personnel and the environment compared to existing chemical technologies.

A Set of Active Promoters with Different Activity Profiles for Superexpressing Rhodococcus Strain.

Rhodococcus bacteria are a promising platform for biodegradation, biocatalysis, and biosynthesis, but the use of rhodococci is hampered by the insufficient number of both platform strains for expression and promoters that are functional and thoroughly studied in these strains. To expand the list of such strains and promoters, we studied the expression capability of the Rhodococcus rhodochrous M33 strain, and the functioning of a set of recombinant promoters in it. We showed that the strain supports superexpression of the target enzyme (nitrile hydratase) using alternative inexpensive feedings-acetate and urea-without growth factor supplementation, thus being a suitable expression platform. The promoter set included Ptuf (elongation factor Tu) and Psod (superoxide dismutase) from Corynebacterium glutamicum ATCC13032, Pcpi (isocitrate lyase) from Rhodococcus erythropolis PR4, and Pnh (nitrile hydratase) from R. rhodochrous M8. Activity levels, regulation possibilities, and growth-phase-dependent activity profiles of these promoters were studied in derivatives of the M33 strain. The activities of the promoters were significantly different (Pcpi < Psod ≪ Ptuf < Pnh), covering 103-fold range, and the most active Pnh and Ptuf produced up to a 30-50% portion of target protein in soluble intracellular proteins. On the basis of the mRNA quantification and amount of target protein, the production level of Pnh was positioned close to the theoretical upper limit of expression in a bacterial cell. A selection method for the laboratory evolution of such active promoters directly in Rhodococcus was also proposed. Concerning regulation, Ptuf could not be regulated (2-fold change), while others were tunable (6-fold for Psod, 79-fold for Pnh, and 44-fold for Pcpi). The promoters possessed four different activity profiles, including three with peak of activity at different growth phases and one with constant activity throughout the growth phases. Ptuf and Pcpi did not change their activity profile under different growth conditions, whereas the Psod and Pnh profiles changed depending on the growth media. The results allow flexible construction of Rhodococcus strains using the studied promoters, and demonstrate a valuable approach for complex characterization of promoters intended for biotechnological strain construction.

In vivo metal selectivity of metal-dependent biosynthesis of cobalt-type nitrile hydratase in Rhodococcus bacteria: a new look at the nitrile hydratase maturation mechanism?

This study highlights the effect of heavy metal ions on the expression of cobalt-containing nitrile hydratase (NHase) in Rhodococcus strains, which over-produce this enzyme. Both metal-dependent derepression of transcription and maturation of NHase were considered. We demonstrated that nickel ions can derepress the NHase promoter in several Rhodococcus strains. The cblA gene of a cobalt-dependent transcriptional repressor was shown to be indispensable for nickel-mediated derepression. As for maturation, we showed that nickel ions could not replace cobalt ions during the synthesis of active NHase. We also revealed that the amount of ß-subunit decreased during NHase expression without added cobalt. We showed this using three variants of NHase in vivo synthesis: by using nickel- or urea-induced synthesis in cblA+ strains, and by using metal-independent constitutive synthesis in cblA- strains. In all cases, we found that the amount of ß-subunit was significantly lower than the amount of α-subunit. In contrast, equimolar amounts of both subunits were synthesized after growth in the presence of added cobalt. Nickel did not affect NHase synthesis in mixtures with cobalt. This suggests that the metal selectivity in cblA-dependent regulation of NHase transcription was too low to discriminate between cobalt and nickel, but the selectivity of the NHase maturation mechanism was high enough to do so. Moreover, we can assume that the ß-subunit is more subject to proteolytic degradation without the addition of cobalt, than the α-subunit. This indicates that cobalt ions presumably play an unknown role in the stability of the ß-subunit in vivo.

New cblA gene participates in regulation of cobalt-dependent transcription of nitrile hydratase genes in Rhodococcus rhodochrous.

Rhodococcus strains are important biocatalysts used for biotechnological production of acrylamide catalysed by a nitrile hydratase (NHase) containing cobalt. This metalloenzyme is present at high intracellular concentrations representing up to 50% of the soluble proteins in Rhodococcus rhodochrous M8 strain. Cobalt ions were formerly reported to be essential for the synthesis of the NHase subunits, encoded by nhmBA structural genes in R. rhodochrous M8. To understand the regulatory mechanisms enabling high expression of the NHase structural genes by cobalt, two reporter genes coding for an acylamidase from Rhodococcus erythropolis TA37 and a nitrilase from Alcaligenes denitrificans C-32 were fused to the nhmBA promoter. It was shown that cobalt-dependent regulation of transcription occurs independently of another regulatory genes, nhmCD, involved in substrate-dependent regulation of transcription. Cobalt ions led to an increase (up to five-fold) in transcription of reporter genes correlated with synthesis of corresponding enzymes in R. rhodochrous recombinant strains. This led to identification of a new transcriptional regulator from the ArsR family, named CblA. Using a cblA mutant strain, it was established that CblA acted as a repressor by preventing transcription of the NHase operon promoter in the absence of cobalt ions.