Enoyl-CoA hydratase

enoyl-Coenzyme A, hydratase/3-hydroxyacyl Coenzyme A dehydrogenase
Identifiers
Symbol	EHHADH
Alt. symbols	ECHD
Entrez	1962
HUGO	3247
OMIM	607037
RefSeq	NM_001966
UniProt	Q08426
Other data
EC number	4.2.1.17
Locus	Chr. 3 q26.3-q28

Template:Chembox header\| Enoyl-CoA Hydratase: active site and substrate File:Enzyme hexamer.png
Crystal structure of Enoyl-CoA Hydratase from a Rat
Active Site	Orange
Substrate	Red

Enoyl-CoA hydratase is an enzyme that hydrates the double bond between the second and third carbons on acyl-CoA. This enzyme, also known as crotonase, is essential to metabolizing fatty acids to produce both acetyl CoA and energy.^[1] Note the crystal structure at right of enoyl-coa hydratase from a rat. The crystal structure shows a hexamer formation (not universal, but human enzyme is also hexameric), which leads to the efficiency of this protein. This enzyme has been discovered to be highly efficient, and allows our bodies to metabolize fatty acids into energy very quickly. In fact this enzyme is so efficient that the rate is equivalent to that of diffusion-controlled reactions.^[2]

Biological Significance: Metabolism

Enoyl-CoA hydratase catalyzes the second step in the breakdown of fatty acids or the second step of β-oxidation in fatty acid metabolism shown below. Fatty acid metabolism is how our bodies turn fats or lipids into energy. When fats come into our bodies, they are generally in the form of triacyl-glycerols. These must be broken down in order for the fats to pass into our bodies. When that happens, three fatty acids are released.

In fatty acid metabolism, fatty acids are changed into fatty acyl-CoA. To do this, the carboxylate which occupies one end of the fatty acid is changed into a thioester by substituting coenzyme A for the hydroxyl group. Next the fatty acyl-CoA is oxidized and broken down into an acetyl-CoA molecule and another acyl-CoA. The acetyl CoA is then sent to the citric acid cycle while the remaining acyl-CoA is broken down further into acetyl-CoAs. The complete breakdown of a fatty acid not only generates acetyl-CoA molecules, but it also generates energy in the form of NADH. This NADH goes on to be converted into ATP which can be used in other reactions.^[3]

Template:Chembox header\| Active Site Orientation
File:Active site orientation.png

Leucine metabolism

Leucine metabolism in humans

Diagram of leucine, HMB, and isovaleryl-CoA metabolism in humans

L-Leucine

Branched-chain amino
acid aminotransferase

Muscle: α-Ketoisocaproate (α-KIC)

Liver: α-Ketoisocaproate (α-KIC)

Branched-chain α-ketoacid
dehydrogenase (mitochondria)

KIC-dioxygenase
(cytosol)

Isovaleryl-CoA

β-Hydroxy
β-methylbutyrate
(HMB)

Excreted
in urine
(10–40%)

HMB-CoA

β-Hydroxy β-methylglutaryl-CoA
(HMG-CoA)

β-Methylcrotonyl-CoA
(MC-CoA)

β-Methylglutaconyl-CoA
(MG-CoA)

CO₂

O₂

CO₂

H₂O

CO₂

H₂O

(liver)
HMG-CoA
lyase

Enoyl-CoA hydratase

Isovaleryl-CoA
dehydrogenase

β-Hydroxybutyrate
dehydrogenase

Unknown
enzyme

The image above contains clickable links

Human metabolic pathway for HMB and isovaleryl-CoA relative to L-leucine.^[4]^[5]^[6] Of the two major pathways, L-leucine is mostly metabolized into isovaleryl-CoA, while only about 5% is metabolized into HMB.^[4]^[5]^[6]

Mechanism

Enoyl-CoA hydratase (ECH) is used in β-oxidation to add a hydroxyl group and a proton to the unsaturated β-carbon on a fatty-acyl CoA. The enzyme functions by providing two glutamate residues as catalytic acid and base. The two amino acids hold a water molecule in place, allowing it to attack in a syn addition to an α-β unsaturated acyl-CoA at the β-carbon. The α-carbon then grabs another proton, which completes the formation of the beta-hydroxy acyl-CoA.

It is also known from experimental data that no other sources of protons reside in the active site. This means that the proton which the α-carbon grabs is from the water that just attacked the β-carbon. What this implies is that the hydroxyl group and the proton from water are both added from the same side of the double bond, a syn addition. This allows the enzyme to make an S stereoisomer from 2-trans-enoyl-CoA and an R stereoisomer from the 2-cis-enoyl-CoA. This is made possible by the two glutamate residues which hold the water in position directly adjacent to the α-β unsaturated double bond, as seen in figure 1. This configuration requires that the active site for this enzyme is extremely rigid, to hold the water in a very specific configuration with regard to the acyl-CoA. The data for a mechanism for this reaction is not conclusive as to whether this reaction is concerted or occurs in consecutive steps. If occurring in consecutive steps, the intermediate is identical to that which would be generated from an E1cb elimination reaction.^[7] Both mechanisms are shown below.

Template:Chembox header\| Reaction Mechanisms
Figure 2: Both Mechanisms	Figure 3: Concerted Mechanism
	File:Chimera mechanism.gif

The enzyme is mechanistically similar to fumarase.

It is classified as EC 4.2.1.17.

References

↑ Bahnson, Brian J., Vernon E. Anderson, and Gregory A. Petsko. "Structural Mechanism of Enoyl-CoA Hydratase: Three Atoms From a Single Water are Added in Either an E1cb Stepwise or Concerted Fashion." Biochemistry 41 (2002): 2621-2629. SciFinder Scholar. 2 December 2007.
↑ TEngel, Christian K., Tiila R. Kiema, J. Kalervo Hiltunen, and Rik K. Wierenga. "The Crystal Structure of Enoyl-CoA Hydratase Complexed with Octanoyl-CoA Reveals the Structural Adaptations Required for Binding of a Long Chain Fatty Acid-CoA Molecule." Journal of Molecular Biology 275 (1998): 847-859. SciFinder Scholar. 2 December 2007.
↑ Nelson, David L., and Michael M. Cox. Lehninger Principles of Biochemistry. 4th ed. New York: W. H. Freeman and Company, 2005. 637-643.
↑ ^4.0 ^4.1 Wilson JM, Fitschen PJ, Campbell B, Wilson GJ, Zanchi N, Taylor L, Wilborn C, Kalman DS, Stout JR, Hoffman JR, Ziegenfuss TN, Lopez HL, Kreider RB, Smith-Ryan AE, Antonio J (February 2013). "International Society of Sports Nutrition Position Stand: beta-hydroxy-beta-methylbutyrate (HMB)". Journal of the International Society of Sports Nutrition. 10 (1): 6. doi:10.1186/1550-2783-10-6. PMC 3568064. PMID 23374455.
↑ ^5.0 ^5.1 Zanchi NE, Gerlinger-Romero F, Guimarães-Ferreira L, de Siqueira Filho MA, Felitti V, Lira FS, Seelaender M, Lancha AH (April 2011). "HMB supplementation: clinical and athletic performance-related effects and mechanisms of action". Amino Acids. 40 (4): 1015–1025. doi:10.1007/s00726-010-0678-0. PMID 20607321. HMB is a metabolite of the amino acid leucine (Van Koverin and Nissen 1992), an essential amino acid. The first step in HMB metabolism is the reversible transamination of leucine to [α-KIC] that occurs mainly extrahepatically (Block and Buse 1990). Following this enzymatic reaction, [α-KIC] may follow one of two pathways. In the first, HMB is produced from [α-KIC] by the cytosolic enzyme KIC dioxygenase (Sabourin and Bieber 1983). The cytosolic dioxygenase has been characterized extensively and differs from the mitochondrial form in that the dioxygenase enzyme is a cytosolic enzyme, whereas the dehydrogenase enzyme is found exclusively in the mitochondrion (Sabourin and Bieber 1981, 1983). Importantly, this route of HMB formation is direct and completely dependent of liver KIC dioxygenase. Following this pathway, HMB in the cytosol is first converted to cytosolic β-hydroxy-β-methylglutaryl-CoA (HMG-CoA), which can then be directed for cholesterol synthesis (Rudney 1957) (Fig. 1). In fact, numerous biochemical studies have shown that HMB is a precursor of cholesterol (Zabin and Bloch 1951; Nissen et al. 2000).
↑ ^6.0 ^6.1 Kohlmeier M (May 2015). "Leucine". Nutrient Metabolism: Structures, Functions, and Genes (2nd ed.). Academic Press. pp. 385–388. ISBN 978-0-12-387784-0. Retrieved 6 June 2016. Energy fuel: Eventually, most Leu is broken down, providing about 6.0kcal/g. About 60% of ingested Leu is oxidized within a few hours ... Ketogenesis: A significant proportion (40% of an ingested dose) is converted into acetyl-CoA and thereby contributes to the synthesis of ketones, steroids, fatty acids, and other compounds
Figure 8.57: Metabolism of L-leucine
↑ Bahnson, Brian J., Vernon E. Anderson, and Gregory A. Petsko. "Structural Mechanism of Enoyl-CoA Hydratase: Three Atoms From a Single Water are Added in Either an E1cb Stepwise or Concerted Fashion." Biochemistry 41 (2002): 2621-2629. SciFinder Scholar. 2 December 2007.

External links

Enoyl-CoA+Hydratase at the US National Library of Medicine Medical Subject Headings (MeSH)

[1] Bahnson, Brian J., Vernon E. Anderson, and Gregory A. Petsko. "Structural Mechanism of Enoyl-CoA Hydratase: Three Atoms From a Single Water are Added in Either an E1cb Stepwise or Concerted Fashion." Biochemistry 41 (2002): 2621-2629. SciFinder Scholar. 2 December 2007.

[2] TEngel, Christian K., Tiila R. Kiema, J. Kalervo Hiltunen, and Rik K. Wierenga. "The Crystal Structure of Enoyl-CoA Hydratase Complexed with Octanoyl-CoA Reveals the Structural Adaptations Required for Binding of a Long Chain Fatty Acid-CoA Molecule." Journal of Molecular Biology 275 (1998): 847-859. SciFinder Scholar. 2 December 2007.

[3] Nelson, David L., and Michael M. Cox. Lehninger Principles of Biochemistry. 4th ed. New York: W. H. Freeman and Company, 2005. 637-643.

[ISSN_position_stand_2013-4] 4.0 ^4.1 Wilson JM, Fitschen PJ, Campbell B, Wilson GJ, Zanchi N, Taylor L, Wilborn C, Kalman DS, Stout JR, Hoffman JR, Ziegenfuss TN, Lopez HL, Kreider RB, Smith-Ryan AE, Antonio J (February 2013). "International Society of Sports Nutrition Position Stand: beta-hydroxy-beta-methylbutyrate (HMB)". Journal of the International Society of Sports Nutrition. 10 (1): 6. doi:10.1186/1550-2783-10-6. PMC 3568064. PMID 23374455.

[HMB_athletic_performance-related_effects_2011_review-5] 5.0 ^5.1 Zanchi NE, Gerlinger-Romero F, Guimarães-Ferreira L, de Siqueira Filho MA, Felitti V, Lira FS, Seelaender M, Lancha AH (April 2011). "HMB supplementation: clinical and athletic performance-related effects and mechanisms of action". Amino Acids. 40 (4): 1015–1025. doi:10.1007/s00726-010-0678-0. PMID 20607321. HMB is a metabolite of the amino acid leucine (Van Koverin and Nissen 1992), an essential amino acid. The first step in HMB metabolism is the reversible transamination of leucine to [α-KIC] that occurs mainly extrahepatically (Block and Buse 1990). Following this enzymatic reaction, [α-KIC] may follow one of two pathways. In the first, HMB is produced from [α-KIC] by the cytosolic enzyme KIC dioxygenase (Sabourin and Bieber 1983). The cytosolic dioxygenase has been characterized extensively and differs from the mitochondrial form in that the dioxygenase enzyme is a cytosolic enzyme, whereas the dehydrogenase enzyme is found exclusively in the mitochondrion (Sabourin and Bieber 1981, 1983). Importantly, this route of HMB formation is direct and completely dependent of liver KIC dioxygenase. Following this pathway, HMB in the cytosol is first converted to cytosolic β-hydroxy-β-methylglutaryl-CoA (HMG-CoA), which can then be directed for cholesterol synthesis (Rudney 1957) (Fig. 1). In fact, numerous biochemical studies have shown that HMB is a precursor of cholesterol (Zabin and Bloch 1951; Nissen et al. 2000).

[Leucine_metabolism-6] 6.0 ^6.1 Kohlmeier M (May 2015). "Leucine". Nutrient Metabolism: Structures, Functions, and Genes (2nd ed.). Academic Press. pp. 385–388. ISBN 978-0-12-387784-0. Retrieved 6 June 2016. Energy fuel: Eventually, most Leu is broken down, providing about 6.0kcal/g. About 60% of ingested Leu is oxidized within a few hours ... Ketogenesis: A significant proportion (40% of an ingested dose) is converted into acetyl-CoA and thereby contributes to the synthesis of ketones, steroids, fatty acids, and other compounds
Figure 8.57: Metabolism of L-leucine

[7] Bahnson, Brian J., Vernon E. Anderson, and Gregory A. Petsko. "Structural Mechanism of Enoyl-CoA Hydratase: Three Atoms From a Single Water are Added in Either an E1cb Stepwise or Concerted Fashion." Biochemistry 41 (2002): 2621-2629. SciFinder Scholar. 2 December 2007.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

v t e Carbon-oxygen lyases (EC 4.2) (primarily dehydratases)
4.2.1: Hydro-Lyases	Carbonic anhydrase Fumarase Aconitase Enolase Alpha Enolase 2 Enoyl-CoA hydratase/3-Hydroxyacyl ACP dehydrase Methylglutaconyl-CoA hydratase Tryptophan synthase Cystathionine beta synthase Porphobilinogen synthase 3-Isopropylmalate dehydratase Urocanase Uroporphyrinogen III synthase Nitrile hydratase
4.2.2: Acting on polysaccharides	Hyaluronate lyase
4.2.3: Acting on phosphates	Threonine synthase
4.2.99: Other	Carboxymethyloxysuccinate lyase Hydroperoxide lyase

v t e Enzymes
Activity	Active site Binding site Catalytic triad Oxyanion hole Enzyme promiscuity Catalytically perfect enzyme Coenzyme Cofactor Enzyme catalysis
Regulation	Allosteric regulation Cooperativity Enzyme inhibitor Enzyme activator
Classification	EC number Enzyme superfamily Enzyme family List of enzymes
Kinetics	Enzyme kinetics Eadie–Hofstee diagram Hanes–Woolf plot Lineweaver–Burk plot Michaelis–Menten kinetics
Types	EC1 Oxidoreductases (list) EC2 Transferases (list) EC3 Hydrolases (list) EC4 Lyases (list) EC5 Isomerases (list) EC6 Ligases (list)