The broad-host-range plasmid RP4 encodes a highly efficient partitioning system (par) that was previously mapped within the 6.2-kb PstI C fragment. The essential functions were assigned to a region of 2.2 kb between fiwA and IS21 (IS8). On the basis of the nucleotide sequence data of the entire par locus and of in vitro and in vivo expression studies, three distinct loci encoding polypeptides of 9, 18, and 24 kDa were identified. Evidence for the expression of another polypeptide was found. A putative divergent promoter was localized in an intergenic region and is suggested to be responsible for transcription of these genes. It was found that the RP4 par region includes a function resolving plasmid dimers. The 24-kDa polypeptide is considered to function as a resolvase, since its predicted amino acid sequence shows homology to sequences of resolvases of the Tn3 family. Furthermore, palindromes present in the intergenic region containing the divergent promoter resemble repeat structures specific for res sites of Tn3-related transposons. However, it was found that dimer resolution itself was not sufficient for stabilization; additional functions, including the other two polypeptides, seemed to play an important role. These results suggested that RP4 contains a complex stabilization system involving resolution of plasmid dimers during cell division, thus ensuring the delivery of at least one copy to each daughter cell.
Eine neuartige biokatalytische C‐C‐Verknüpfung, die äquivalent zur Friedel‐Crafts‐Alkylierung ist, wird vorgestellt. S‐Adenosyl‐L‐methionin (SAM), der Haupt‐Methyldonor bei Methyltransferase(Mtase)‐katalysierten biologischen Methylierungen, kann Alkylierungen bewirken (siehe Schema). Diese Enzyme akzeptieren nichtnatürliche Cofaktoren und können andere Funktionalitäten als Me auf aromatische Substrate übertragen.
Amine transaminases are frequently used for the production of chiral amines starting from prochiral ketones. These amines can be applied as active pharmaceutical ingredients or drug precursors. However, there are still limitations to the use of amine transaminases when it comes to bulky ketone substrates, such as biaryl ketones. Using data mining, an (R)-selective amine transaminase from Exophiala xenobiotica was identified which naturally converts biaryl ketone substrates to the corresponding amines with up to 85% conversion and excellent enantioselectivity (>99% ee). Its protein crystal structure was obtained with a resolution of 1.52 Å, which enabled us to explain this interesting substrate acceptance. Structure-guided protein engineering resulted in a quintuple variant with increased stability. Moreover, the amino acid exchange T273S increased the activity and broadened the substrate scope enabling conversions of various biaryl ketones with up to >99%. A preparative biotransformation of 1-(4-(pyridin-3-yl)phenyl)ethenone at 75 mM (15 g/L) resulted in 96% of isolated yield of the respective amine.
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