Francisco Barona-Gomez

Occurrence of a putative ancient-like isomerase involved in histidine and tryptophan biosynthesis

We report the occurrence of an isomerase with a putative (βα)8‐barrel structure involved in both histidine and trypto‐phan biosynthesis in Streptomyces coelicolor A3(2) and Mycobacterium tuberculosis HR37Rv. Deletion of a hisA homologue (SCO2050) putatively encoding N ′‐[(5′‐phosphoribosyl)‐formimino]‐5 amino‐imidazole‐4‐carboxamide ribonucleotide isomerase from the chromosome of S. coelicolor A3(2) generated a double auxotrophic mutant for histidine and tryptophan. The bifunctional gene SCO2050 and its orthologue Rv1603 from M. tuberculosis complemented both hisA and trpF mutants of Escherichia coli. Expression of the E. coli trpF gene in the S. coelicolor mutant only complemented the tryptophan auxo‐trophy, and the hisA gene only complemented the histidine auxotrophy. The discovery of this enzyme, which has a broad‐substrate specificity, has implications for the evolution of metabolic pathways and may prove to be important for understanding the evolution of the (βα)8‐barrels.

Regio- and stereodivergent antibiotic oxidative carbocyclizations catalysed by Rieske oxygenase-like enzymes

Oxidative cyclizations, exemplified by the biosynthetic assembly of the penicillin nucleus from a tripeptide precursor, are arguably the most synthetically-powerful implementation of C-H activation reactions in Nature. Here we show that Rieske oxygenase-like enzymes mediate regio and stereodivergent oxidative cyclizations to form 10- and 12-membered carbocyclic rings in the key steps of the biosynthesis of the antibiotics streptorubin B and metacycloprodigiosin, respectively. These reactions represent the first examples of oxidative carbocyclizations catalyzed by non-heme iron-dependent oxidases and define a novel type of catalytic activity for Rieske enzymes. A better understanding of how these enzymes achieve such remarkable regio and stereocontrol in the functionalization of unactivated hydrocarbon chains will greatly facilitate the development of selective manmade C-H activation catalysts.

Insights into the evolution of enzyme substrate promiscuity after the discovery of (βα)8 isomerase evolutionary intermediates from a diverse metagenome

BackgroundCurrent sequence-based approaches to identify enzyme functional shifts, such as enzyme promiscuity, have proven to be highly dependent on a priori functional knowledge, hampering our ability to reconstruct evolutionary history behind these mechanisms. Hidden Markov Model (HMM) profiles, broadly used to classify enzyme families, can be useful to distinguish between closely related enzyme families with different specificities. The (βα)8-isomerase HisA/PriA enzyme family, involved in L-histidine (HisA, mono-substrate) biosynthesis in most bacteria and plants, but also in L-tryptophan (HisA/TrpF or PriA, dual-substrate) biosynthesis in most Actinobacteria, has been used as model system to explore evolutionary hypotheses and therefore has a considerable amount of evolutionary, functional and structural knowledge available. We searched for functional evolutionary intermediates between the HisA and PriA enzyme families in order to understand the functional divergence between these families.ResultsWe constructed a HMM profile that correctly classifies sequences of unknown function into the HisA and PriA enzyme sub-families. Using this HMM profile, we mined a large metagenome to identify plausible evolutionary intermediate sequences between HisA and PriA. These sequences were used to perform phylogenetic reconstructions and to identify functionally conserved amino acids. Biochemical characterization of one selected enzyme (CAM1) with a mutation within the functionally essential N-terminus phosphate-binding site, namely, an alanine instead of a glycine in HisA or a serine in PriA, showed that this evolutionary intermediate has dual-substrate specificity. Moreover, site-directed mutagenesis of this alanine residue, either backwards into a glycine or forward into a serine, revealed the robustness of this enzyme. None of these mutations, presumably upon functionally essential amino acids, significantly abolished its enzyme activities. A truncated version of this enzyme (CAM2) predicted to adopt a (βα)6-fold, and thus entirely lacking a C-terminus phosphate-binding site, was identified and shown to have HisA activity.ConclusionAs expected, reconstruction of the evolution of PriA from HisA with HMM profiles suggest that functional shifts involve mutations in evolutionarily intermediate enzymes of otherwise functionally essential residues or motifs. These results are in agreement with a link between promiscuous enzymes and intragenic epistasis. HMM provides a convenient approach for gaining insights into these evolutionary processes.

Enzyme evolution beyond gene duplication: A model for incorporating horizontal gene transfer.

Understanding the evolution of enzyme function after gene duplication has been a major goal of molecular biologists, biochemists and evolutionary biologists alike, for almost half a century. In contrast, the impact that horizontal gene transfer (HGT) has had on the evolution of enzyme specialization and the assembly of metabolic networks has just started to being investigated. Traditionally, evolutionary studies of enzymes have been limited to either the function of enzymes in vitro, or to sequence variability at the population level, where in almost all cases the starting conceptual framework embraces gene duplication as the mechanism responsible for the appearance of genetic redundancy. Very recently, we merged comparative phylogenomics, detection of selection signals, enzyme kinetics, X-ray crystallography and computational molecular dynamics, to characterize the sub-functionalization process of an amino acid biosynthetic enzyme prompted by an episode of HGT in bacteria. Some of the evolutionary implications of these functional studies, including a proposed model of enzyme specialization independent of gene duplication, are developed in this commentary.

Expression, purification and preliminary crystallographic analysis of phosphoribosyl isomerase (PriA) from Streptomyces coelicolor

The priA gene encoding the enzyme phosphoribosyl isomerase from Streptomyces coelicolor, a novel bifunctional enzyme involved in both histidine and tryptophan biosynthesis, was heterologously expressed and purified in Escherichia coli as an N-terminal His-tag fusion. The purified recombinant enzyme was crystallized using the hanging-drop method in 1.50 M ammonium sulfate and 100 mM sodium citrate pH 4.8. Crystals were obtained of up to 0.05 x 0.05 x 0.3 mm in size. A full data set to 2 A resolution was collected at the ESRF beamline ID14-1 and space group P3(1,2)21 was assigned, with unit-cell parameters a = 65.1, c = 104.7 A.

Multicopy proC in Streptomyces coelicolor A3(2) Elicits a Transient Production of Prodiginines, while proC Deletion Does Not Yield a Proline Auxotroph

The last step of proline biosynthesis is typically catalysed by the enzyme Δ1-pyrroline-5-carboxylate reductase, encoded by the proC gene. Complete genome sequencing of Streptomyces coelicolor, a soil-dwelling Gram-positive bacterium that uses proline as a precursor for synthesis of prodiginine, revealed a single copy of this gene. Unexpectedly, disruption of this proC homologue (Sco3337) in S. coelicolor M145 yielded a prototrophic strain, yet the reductase activity of Sco3337 was confirmed by complementation of an Escherichia coli proC mutant. Multicopy proC within different genetic contexts elicited a transient production of prodiginines, which showed differential production kinetics of the two most common forms of this natural product produced by S. coelicolor, i.e. streptorubin B (cyclic) and undecylprodigiosin (linear). The metabolic and evolutionary implications of these observations are discussed.