Structure-function studies of the mammalian peroxisomal multifunctional enzyme type 2 (MFE-2)

Haapalainen, A. (Antti)

08 November 2002

Abstract Mammalian peroxisomes contain two parallel multifunctional enzymes (MFE), MFE type 1 and MFE type 2 (MFE-2), which are responsible for the degradation of fatty acids. They both catalyze the second and third reactions of the β-oxidation pathway, but through reciprocal stereochemical courses. MFE-2 possesses (2E)-enoyl-CoA hydratase-2 and (3R)-hydroxyacyl-CoA dehydrogenase activities. In addition, the carboxy-terminal part is similar to the sterol carrier protein type 2 (SCP-2). The purpose of this work was to study the structure-function relationship of functional domains of mammalian MFE-2 by recombinant DNA technology, enzyme kinetics and X-ray crystallography. The work started with the identification of conserved regions in MFE-2. This information was utilized when dehydrogenase, hydratase-2 and/or SCP-2-like domain were produced as separate recombinant proteins. Subsequently, both dehydrogenase and SCP-2-like domains were crystallized and their crystal structures were solved. The structure of the dehydrogenase region of rat MFE-2 contains the basic α/β short-chain alcohol dehydrogenase/reductase (SDR) fold and the four-helix bundle at the dimer interface, which is typical of dimeric SDR enzymes. However, the structure has a novel carboxy-terminal domain not seen among the known structures. This domain lines the active site cavity of the neighbouring monomer, reflecting cooperative behaviour within a homodimer. The monomeric SCP-2-like domain of human MFE-2 has the same fold as rabbit SCP-2. The structure includes a hydrophobic tunnel occupied by an ordered Triton X-100 molecule, demonstrating the ligand-binding site. Compared to the unliganded rabbit SCP-2 structure, the position of the carboxy-terminal helix is different. The movement of this helix in the liganded human SCP-2-like domain resulted in the exposure of a peroxisomal targeting signal, suggesting ligand-assisted protein import into peroxisomes. The roles of conserved protic residues in the hydratase-2 region of human MFE-2 were studied by mutating them to alanine. In the first step, the ability of mutated variants to utilize oleic acid in vivo was tested with Saccharomyces cerevisiae fox-2 cells (devoid of endogenous MFE-2). Subsequently, in vitro characterization of the mutant enzymes revealed two amino acid residues, Glu366 and Asp510, vital for hydratase-2 activity. The results indicate that the acid-base catalysis is valid for hydratase-2.

SCP-2

b-oxidation

dehydrogenase

hydratase

SDR

Kinetic and Stoichiometric Modeling of the Metabolism of Escherichia coli for the Synthesis of Biofuels and Chemicals

Cintolesi Makuc, Angela

16 September 2013

This thesis presents the mathematical modeling of two new Escherichia coli platforms with economical potential for the production of biofuels and chemicals, namely glycerol fermentation and the reversal of the β-oxidation cycle. With the increase in traditional fuel prices, alternative renewable energy sources are needed, and the efficient production of biofuels becomes imperative. So far studies have focused on using glucose as feedstock for the production of ethanol and other fuels, but a recent increase in glycerol availability and its consequent decrease in price make it an attractive feedstock. Furthermore, the reversed β-oxidation cycle is a highly efficient mechanism for the synthesis of long-chain products. These two platforms have been reported experimentally in E. coli but their mathematical modeling is presented for the first time here. Because mathematical models have proved to be useful in the optimization of microbial metabolism, two complementary models were used in this study: kinetic and stoichiometric. Kinetic models can identify the control structure within a specific pathway, but they require highly detailed information, making them applicable to small sets of reactions. In contrast, stoichiometric models require only mass balance information, making them suitable for genome-scale modeling to study the effect of adding or removing reactions for the optimization of the synthesis of desired products. To study glycerol fermentation, a kinetic model was implemented, allowing prediction of the limiting enzymes of this process: glycerol dehydrogenase and di-hydroxyacetone kinase. This prediction was experimentally validated by increasing their enzymatic activities, resulting in a two-fold increase in the rate of ethanol production. Additionally, a stoichiometric genome-scale model (GEM) was modified to represent the fermentative metabolism of glycerol, identifying key metabolic pathways for glycerol fermentation (including a new glycerol dissimilation pathway). The GEM was used to identify genetic modifications that would increase the synthesis of desired products, such as succinate and butanol. Finally, glucose metabolism using the reversal β-oxidation cycle was modeled using a GEM to simulate the synthesis of a variety of medium and long chain products (including advanced biofuels). The model was used to design strategies that can lead to increase the productivity of target products.

Studies on the peroxisomal multifunctional enzyme type-1:domain structure with special reference to the hydratase/isomerase fold

Kiema, T.-R. (Tiila-Riikka)

27 November 2001

Abstract The peroxisomal multifunctional enzyme type-1 (perMFE-1) is a monomeric protein of β-oxidation possessing 2-enoyl-CoA hydratase-1, Δ3-Δ 2-enoyl-CoA isomerase, and (3S)-hydroxyacyl-CoA dehydrogenase activities. The amino-terminal part of perMFE-1 shows sequence similarity to mitochondrial 2-enoyl-CoA hydratases (ECH-1) and Δ3-Δ 2-enoyl-CoA isomerases, and belongs to the hydratase/isomerase superfamily. Family members with known structures are either homotrimers or homohexamers. The purpose of this work was to elucidate the structure-function relationship of the rat perMFE-1 with special reference to the hydratase/isomerase fold. The structural adaptations required for binding of a long chain fatty acyl-CoA were studied with rat ECH-1 via co-crystallization with octanoyl-CoA. The crystal structure revealed that the long chain fatty acyl-CoA is bound in an extended conformation. This is possible because, a flexible loop moves aside and opens a tunnel, which traverses the subunit from the solvent space to the intertrimer space. Structural and enzymological studies have shown the importance of Glu144 and Glu164 for the catalysis by ECH-1. In the present work the enzymological properties of Glu144Ala and Glu164Ala variants of ECH-1 were studied. The catalytic activity of hydration was reduced about 2000-fold. It was also demonstrated that rat ECH-1 is capable of catalyzing isomerization. The replacement of Glu164 with alanine reduced the isomerase activity 1000-fold, confirming the role of Glu164 in both the hydratase and isomerase reactions. The structural factors favoring the hydratase over the isomerase reaction were addressed studying the enzymological properties of the Gln162Ala, Gln162Met, and Gln162Leu variants. These mutants had similar enzymatic properties to wild type, thus the catalytic function of the Glu164 side chain in the hydratase and isomerase reaction does not depend on interaction with the Gln162 side chain. The perMFE-1 was divided into five functional domains based on amino acid sequence comparisons with the homologous proteins with known structures. Deletion variants of perMFE-1 showed that the folding of an enzymatically active amino-terminal hydratase/isomerase domain requires stabilizing interactions from the two carboxy-terminal domains of perMFE-1. The last carboxy-terminal domain is also required for the folding of the dehydrogenase part of perMFE-1. The dehydrogenase part of perMFE-1 was crystallized.

2-enoyl-CoA hydratase

3-hydroxyacyl-CoA dehydrogenase

b-oxidation

enoyl-CoA isomerase

protein engineering

Δ³-Δ²-Enoyl-CoA isomerase from the yeast <em>Saccharomyces cerevisiae</em>:molecular and structural characterization

Mursula, A. (Anu)

19 April 2002

Abstract The hydratase/isomerase superfamily consists of enzymes having a common evolutionary origin but acting in a wide variety of metabolic pathways. Many of the superfamily members take part in β-oxidation, one of the processes of fatty acid degradation. One of these β-oxidation enzymes is the Δ3-Δ 2-enoyl-CoA isomerase, which is required for the metabolism of unsaturated fatty acids. It catalyzes the shift of a double bond from the position C3 of the substrate to the C2 position. In this study, the Δ 3-Δ 2-enoyl-CoA isomerase from the yeast Saccharomyces cerevisiae was identified, overexpressed as a recombinant protein and characterized. Subsequently, its structure and function were studied by X-ray crystallography. The yeast Δ 3-Δ 2-enoyl-CoA isomerase polypeptide contains 280 amino acid residues, which corresponds to a subunit size of 32 kDa. Six enoyl-CoA isomerase subunits assemble to form a homohexamer. According to structural studies, the hexameric assembly can be described as a dimer of trimers. The yeast Δ 3-Δ 2-enoyl-CoA isomerase is located in peroxisomes, the site of fungal β-oxidation, and is a necessary prerequisite for the β-oxidation of unsaturated fatty acids; the enoyl-CoA isomerase knock-out was unable to grow on such carbon sources. In the crystal structure of the yeast Δ 3-Δ 2-enoyl-CoA isomerase, two domains can be recognized, the N-terminal spiral core domain for catalysis and the C-terminal α-helical trimerization domain. This overall fold resembles the other known structures in the hydratase/isomerase superfamily. Site-directed mutagenesis suggested that Glu158 could be involved in the enzymatic reaction. Structural studies confirmed this, as Glu158 is optimally positioned at the active site for interaction with the substrate molecule. The oxyanion hole stabilizing the transition state of the enzymatic reaction is formed by the main chain NH groups of Ala70 and Leu126. The yeast Δ 3-Δ 2-enoyl-CoA isomerase hexamer forms by dimerization of two trimers, as in the other superfamily members. An extensive comparison of the five known structures of this family showed that the mode of assembly into hexamers is not a conserved feature of this superfamily, since the distance between the trimers and the orientation of the trimers with respect to each other varied. Marked differences were also detected between the two yeast enoyl-CoA isomerase crystal forms used in this study, one being crystallized at low pH and the other at neutral pH. The results suggest that the yeast Δ 3-Δ 2-enoyl-CoA isomerase could occur as a trimer at low pH.

X-ray crystallography

b-oxidation

enoyl-CoA hydratase

enoyl-CoA isomerase

hydratase/isomerase superfamily