The neomycin biosynthetic gene cluster of Streptomyces fradiae NCIMB 8233: genetic and biochemical evidence for the roles of two glycosyltransferases and a deacetylase.

An efficient protocol has been developed for the genetic manipulation of Streptomyces fradiae NCIMB 8233, which produces the 2-deoxystreptamine (2-DOS)-containing aminoglycoside antibiotic neomycin. This has allowed the in vivo analysis of the respective roles of the glycosyltransferases Neo8 and Neo15, and of the deacetylase Neo16 in neomycin biosynthesis. Specific deletion of each of the neo8, neo15 and neo16 genes confirmed that they are all essential for neomycin biosynthesis. The pattern of metabolites produced by feeding putative pathway intermediates to these mutants provided unambiguous support for a scheme in which Neo8 and Neo15, whose three-dimensional structures are predicted to be highly similar, have distinct roles: Neo8 catalyses transfer of N-acetylglucosamine to 2-DOS early in the pathway, while Neo15 catalyses transfer of the same aminosugar to ribostamycin later in the pathway. The in vitro substrate specificity of Neo15, purified from recombinant Escherichia coli, was fully consistent with these findings. The in vitro activity of Neo16, the only deacetylase so far recognised in the neo gene cluster, showed that it is capable of acting in tandem with both Neo8 and Neo15 as previously proposed. However, the deacetylation of N-acetylglucosaminylribostamycin was still observed in a strain deleted of the neo16 gene and fed with suitable pathway precursors, providing evidence for the existence of a second enzyme in S. fradiae with this activity.

The role of cep15 in the biosynthesis of chloroeremomycin: reactivation of an ancestral catalytic function.

The gene clusters of several glycopeptides contain genes that encode COG2120 domain zinc-dependent N-acetylglucosaminyl deacetylases. Recently, a COG2120 protein encoded in the chloroeremomycin gene cluster, Cep15, has been postulated to possess nucleotidyltransferase activity. Here, we demonstrate that Cep15 possesses no catalytic activity and does not have a clear role in chloroeremomycin biosynthesis. This result strongly suggests that cep15 and bal2 are evolutionary artifacts and may be pseudogenes. Comparative sequence analysis with the closely related active Orf2* deacetylase (teicoplanin biosynthesis) reveals an asparagine in place of a metal-binding histidine in the "pseudo-active site" of Cep15. Substitution of this histidine by asparagine in Orf2* abolishes deacetylase activity. Remarkably, the Cep15 N164H mutant is an active deacetylase. To our knowledge, this is the first example of reactivating an ancestral enzymatic role for a bacterial protein by point mutagenesis.

FT protein movement contributes to long-distance signaling in floral induction of Arabidopsis.

In plants, seasonal changes in day length are perceived in leaves, which initiate long-distance signaling that induces flowering at the shoot apex. The identity of the long-distance signal has yet to be determined. In Arabidopsis, activation of FLOWERING LOCUS T (FT) transcription in leaf vascular tissue (phloem) induces flowering. We found that FT messenger RNA is required only transiently in the leaf. In addition, FT fusion proteins expressed specifically in phloem cells move to the apex and move long distances between grafted plants. Finally, we provide evidence that FT does not activate an intermediate messenger in leaves. We conclude that FT protein acts as a long-distance signal that induces Arabidopsis flowering.