Two (betaalpha)(8)-barrel enzymes of histidine and tryptophan biosynthesis have similar reaction mechanisms and common strategies for protecting their labile substrates

Mimicking enzyme evolution by generating new (betaalpha)8-barrels from (betaalpha)4-half-barrels

Gene duplication and fusion events that multiply and link functional protein domains are crucial mechanisms of enzyme evolution. The analysis of amino acid sequences and three-dimensional structures suggested that the (betaalpha)8-barrel, which is the most frequent fold among enzymes, has evolved by the duplication, fusion, and mixing of (betaalpha)4-half-barrel domains. Here, we mimicked this evolutionary strategy by generating in vitro (betaalpha)8-barrels from (betaalpha)4-half-barrels that were deduced from the enzymes imidazole glycerol phosphate synthase (HisF) and N'[(5'-phosphoribosyl)formimino]-5-aminoimidazole-4-carboxamide-ribonucleotide isomerase (HisA). To this end, the gene for the C-terminal (betaalpha)4-half-barrel (HisF-C) of HisF was duplicated and fused in tandem to yield HisF-CC, which is more stable than HisF-C. In the next step, by optimizing side-chain interactions within the center of the beta-barrel of HisF-CC, the monomeric and compact (betaalpha)8-barrel protein HisF-C*C was generated. Moreover, the genes for the N- and C-terminal (betaalpha)4-half-barrels of HisF and HisA were fused crosswise to yield the chimeric proteins HisFA and HisAF. Whereas HisFA contains native secondary structure elements but adopts ill-defined association states, the (betaalpha)8-barrel HisAF is a stable and compact monomer that reversibly unfolds with high cooperativity. The results obtained suggest a previously undescribed dimension for the diversification of enzymatic activities: new (betaalpha)8-barrels with novel functions might have evolved by the exchange of (betaalpha)4-half-barrel domains with distinct functional properties.

Interconverting the Catalytic Activities of (βα)8-barrel Enzymes from Different Metabolic Pathways: Sequence Requirements and Molecular Analysis

The (betaalpha)(8)-barrel enzymes N'-[(5'-phosphoribosyl)formimino]-5-aminoimidazole-4-carboxamide ribonucleotide isomerase (tHisA) and imidazole glycerol phosphate synthase (tHisF) from Thermotoga maritima catalyze two successive reactions in the biosynthesis of histidine. In both enzymes, aspartate residues at the C-terminal end of beta-strand 1 (Asp8 in tHisA and Asp11 in tHisF) and beta-strand 5 (Asp127 in tHisA and Asp130 in tHisF) are essential for catalytic activity. It was demonstrated earlier that in tHisA the substitution of Asp127 by valine (tHisA-D127V) generates phosphoribosylanthranilate isomerase (TrpF) activity, a related (betaalpha)(8)-barrel enzyme participating in tryptophan biosynthesis. It is shown here that in tHisF the corresponding substitution of Asp130 by valine (tHisF-D130V) also generates TrpF activity. To determine the effectiveness of individual amino acid exchanges in these conversions, each of the 20 standard amino acid residues was introduced at position 127 of tHisA and 130 of tHisF by saturation random mutagenesis. The tHisA-D127X and tHisF-D130X variants with TrpF activity were identified by selection in vivo, and the proteins purified and characterized. The results obtained show that removal of the negatively charged carboxylate side-chain at the C-terminal end of beta-strand 5 is sufficient to establish TrpF activity in tHisA and tHisF, presumably because it allows the binding of the negatively charged TrpF substrate, phosphoribosylanthranilate. In contrast, the double mutants tHisA-D8N+D127V and tHisF-D11N+D130V did not show detectable activity, demonstrating that the aspartate residues at the C-terminal end of beta-strand 1 are essential for catalysis of the TrpF reaction. The ease with which TrpF activity can be established on both the tHisA and tHisF scaffolds supports the evolutionary relationship of these three enzymes and highlights the functional plasticity of the (betaalpha)(8)-barrel enzyme fold.

Understanding the importance of protein structure to nature's routes for divergent evolution in TIM barrel enzymes

It is widely agreed that new enzymes evolve from existing ones through the duplication of genes encoding existing enzymes followed by sequence divergence. While evolution is an inherently random process, studies of divergently related enzymes have shown that the evolution of new enzymes follows one of three general routes in which the substrate specificity, reaction mechanism, or active site architecture of the progenitor enzyme is reused in the new enzyme. Recent developments in structural biology relating to divergently related (beta/alpha)8 enzymes have brought new insight into these processes and have revealed that conserved structural elements play an important role in divergent evolution. These studies have shown that, although evolution occurs as a series of random mutations, stable folds such as the (beta/alpha)8 barrel and structural features of the active sites of enzymes are frequently reused in evolution and adapted for new catalytic purposes.

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

We report the occurrence of an isomerase with a putative (betaalpha)(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 (betaalpha)(8)-barrels.