Tài liệu Báo cáo khoa học: Biochemical characterization of human 3-methylglutaconyl-CoA hydratase and its role in leucine metabolism docx

3-methylglutaconyl-coenzyme A 3-MG-CoA hydratase EC 4.2.1.18 catalyses the fifth step in the leucine degradation pathway, the reversible hydration of 3-MG-CoA to 3-hydroxy-3-methyl-glutar

3-methylglutaconyl-CoA hydratase and its role in leucine metabolism

Matthias Mack1, Ute Schniegler-Mattox2, Verena Peters3, Georg F Hoffmann3, Michael Liesert4, Wolfgang Buckel4and Johannes Zschocke2

1 Institut fu¨r Technische Mikrobiologie der Hochschule Mannheim, Germany

2 Institut fu¨r Humangenetik, Ruprecht-Karls-Universita¨t Heidelberg, Germany

3 Abteilung fu¨r Allgemeine Pa¨diatrie, Ruprecht-Karls-Universita¨t Heidelberg, Germany

4 Labor fu¨r Mikrobiologie der Philipps-Universita¨t-Marburg, Germany

In humans, isolated deficiencies of each of the six

dif-ferent steps within the leucine degradation pathway

(Fig 1) cause their own characteristic disease [1] The

enzymes of this pathway are primarily located in the

mitochondria Together with the corresponding genes

and their associated metabolic disorders they are

sum-marized in Table 1 3-methylglutaconyl-coenzyme A

(3-MG-CoA) hydratase (EC 4.2.1.18) catalyses the fifth

step in the leucine degradation pathway, the reversible

hydration of 3-MG-CoA to

3-hydroxy-3-methyl-glutaryl-CoA (HMG-CoA) Reduced or absent 3-MG-CoA hydratase activity causes a metabolic block (Fig 1) and as a result, 3-MG-CoA accumulates within the mitochondrial matrix [2,3] 3-MG-CoA is hydrolyzed in the mitochondrion by a yet unknown acyl-CoA hydrolase to form 3-methylglutaconic acid and free CoA, followed by export of

3-methylglutacon-ic acid from the mitochondrion Reduced 3-MG-CoA hydratase activity also produces increased levels of 3-methylglutaric acid and 3-hydroxyisovaleric acid

Keywords

leucine metabolism; 3-methylglutaconic

aciduria type I;

3-methylglutaconyl-coenzyme A hydratase; AUH

Correspondence

M Mack, Institut fu¨r Technische

Mikrobiologie der Hochschule Mannheim,

Windeckstr 110, 68163 Mannheim,

Germany

Fax: +49 6212926420

Tel: +49 6212926496

E-mail: m.mack@hs-mannheim.de

(Received 14 September 2005, revised

3 March 2006, accepted 7 March 2006)

doi:10.1111/j.1742-4658.2006.05218.x

The metabolic disease 3-methylglutaconic aciduria type I (MGA1) is char-acterized by an abnormal organic acid profile in which there is excessive urinary excretion of 3-methylglutaconic acid, 3-methylglutaric acid and 3-hydroxyisovaleric acid Affected individuals display variable clinical manifestations ranging from mildly delayed speech development to severe psychomotor retardation with neurological handicap MGA1 is caused by reduced or absent 3-methylglutaconyl-coenzyme A (3-MG-CoA) hydratase activity within the leucine degradation pathway The human AUH gene has been reported to encode for a bifunctional enzyme with both RNA-binding and enoyl-CoA-hydratase activity In addition, it was shown that muta-tions in the AUH gene are linked to MGA1 Here we present kinetic data

of the purified gene product of AUH using different CoA-substrates The best substrates were (E)-3-MG-CoA (Vmax¼ 3.9 UÆmg)1, Km¼ 8.3 lm,

kcat¼ 5.1 s)1) and (E)-glutaconyl-CoA (Vmax¼ 1.1 UÆmg)1, Km¼ 2.4 lm,

kcat¼ 1.4 s)1) giving strong evidence that the AUH gene encodes for the major human 3-MG-CoA hydratase in leucine degradation Based on these results, a new assay for AUH activity in fibroblast homogenates was developed The only missense mutation found in MGA1 phenotypes, c.719C>T, leading to the amino acid exchange A240V, produces an enzyme with only 9% of the wild-type 3-MG-CoA hydratase activity

Abbreviations

ARE, A + U-rich elements; Gct, glutaconate CoA-transferase; HMG-CoA, 3-hydroxy-3-methylglutaryl-CoA; MBP, maltose binding protein; MGA (MGA1), 3-methylglutaconic aciduria (type I); 3-MG-CoA, 3-methylglutaconyl-CoA; MTP, mitochondrial trifunctional protein.

3-Methylglutaric acid is synthesized by the action of

an as yet unspecified dehydrogenase on accumulating

3-MG-CoA (Fig 1) whilst 3-hydroxyisovaleric acid is

produced via the enzymatic hydration of

3-methylcro-tonyl-CoA (crotonase, EC 4.2.1.17) (Fig 1) [2] Conse-quently, humans with reduced or absent 3-MG-CoA hydratase activity show excessive urinary excretion of 3-methylglutaconic acid, 3-hydroxyisovaleric acid and

Fig 1 The metabolic pathway of (S)-leucine

( L -leucine) and isovalerate Enzymes

involved are as follows: 1, EC 2.6.1.42,

branched chain amino transferase 1; 2, EC

1.2.4.4 ⁄ 2.3.1.168 ⁄ 1.8.1.4, branched chain

2-keto acid dehydrogenase complex; 3, EC

1.3.99.10, isovaleryl-CoA dehydrogenase;

4, EC 6.4.1.4, 3-methylcrotonyl-CoA

carboxylase 1; 5, EC 4.2.1.18,

3-methylgluta-conyl-CoA hydratase; 6, EC 4.1.3.4,

3-hydroxy-3-methylglutaryl-CoA lyase; 7, EC

2.8.3.–, isovalerate-CoA-transferase; 8,

crot-onase, EC 4.2.1.17 9, unknown.

Table 1 Enzymes, genes, and associated diseases of the human leucine degradation pathway.

Branched chain keto acid dehydrogenase E1,

alpha ⁄ beta subunits

3-methylglutaric acid [2] Human 3-MG-CoA

hydra-tase deficiency is known as type I 3-methylglutaconic

aciduria (MGA1, MIM 250 950) It has been found

in association with variable phenotypes ranging from

apparently normal development to severe psychomotor

retardation with progressive neurological symptoms

[4] At present, three additional forms of MGA in

humans have been recognized [5] These diseases are

not associated with reduced 3-methylglutaconyl-CoA

hydratase levels and the excretion of 3-MG and

3-methylglutaric acid is secondary Type II MGA

(MIM 302060), also referred to as Barth syndrome, is

a cardiomyopathy associated with neutropenia and

growth retardation and caused by mutations in the

gene encoding tafazzin (TAZ, previously denoted

G4.5) [6] Type III (MIM 258501) or Costeff

syndrome, is a disorder caused by mutations in the

OPA3 gene [7], leading to bilateral optic atrophy

Finally, type IV (MIM 250951) comprises a

heteroge-neous group of patients with progressive neurological

symptoms [5] The molecular basis for type IV MGA

is unknown, however, experiments with the fungus

Aspergillus nidulans carrying null alleles in the known

genes for 3-methylglutaconyl-CoA hydratase and

3-methylcrotonyl-CoA carboxylase strongly suggest

that a second route for 3-MG biosynthesis exists [8]

Interestingly, certain patients with Smith–Lemli–Opitz

syndrome also show abnormally increased plasma

levels of this compound, further challenging our

under-standing of 3-methylglutaconic acid metabolism [9]

Lastly, pregnancy was reported as a possible cause of

MGA [10] For a long time it had been unclear which

enzyme was responsible for the hydratase step within

leucine degradation A 3-MG-CoA hydratase was

partially purified from bovine⁄ ovine liver [11] It was

established that this enzyme catalyses the syn-addition

of water to (E)-3-MG-CoA leading to (S)-HMG-CoA

[12] Another enoyl-CoA hydratase, mitochondrial

crotonase, is not active using HMG-CoA and

measur-ing the reverse (dehydration) reaction [13]

Mitochond-rial trifunctional protein (MTP) is the main enoyl-CoA

hydratase in long chain fatty acid b-oxidation [14]

This enzyme, however, is unlikely to be involved in

leucine degradation since MTP deficiency (MIM

143450, MIM 600890) is not associated with increased

urinary excretion of 3-methylglutaconic acid A protein

was purified from human brain cells by affinity

chro-matography using the immobilized

RNA-oligonucleo-tide (AUUUA)5 or ‘AU’ followed by cloning of the

corresponding gene [15] Interestingly, the gene showed

sequence similarity to enoyl-CoA-hydratases-1

(2-trans-enoyl-CoA-hydratases; EC 4.2.1.17) and its gene

product had weak enoyl-CoA-hydratase activity using

crotonyl-CoA as a substrate [15] The gene encoding this bifunctional protein was named AUH (‘AU bind-ing homolog of enoyl-CoA hydratase’) The RNA-binding activity of the human protein and also of the murine homologue was investigated further, its biologi-cal function, however, remained unclear [16,17] The three-dimensional structure of AUH was determined at 2.2 A˚ resolution and regarding its hydratase activity a high affinity for short-chain substrates was predicted [18]

The first pure preparation of a 3-MG-CoA hydra-tase was obtained from the bacterium Acinetobacter

sp which aerobically grows on isovalerate as sole car-bon and energy source Isovalerate is activated by

a CoA-transferase (2.8.3.–) to give isovaleryl-CoA (Fig 1) Isovalerate is metabolized via isovaleryl-CoA,

an intermediate of the oxidative (S)-leucine degrada-tion pathway [19] The gene for 3-MG-CoA hydratase

in Acinetobacter sp was partially cloned The transla-ted nucleotide sequence had weak similarities to enoyl-CoA-hydratases (30% identity) and also human AUH

It was shown by two independent groups, that MGA1 patients with reduced or absent hydratase activity have mutations within the AUH gene [13,20]

In addition it was shown that AUH has 3-MG-CoA hydratase activity using HMG-CoA as a substrate and measuring the dehydration reaction AUH locates on chromosome 9q22.31

The present work was initiated to kinetically charac-terize AUH on its presumed natural substrate 3-MG-CoA using a new strategy for its synthesis and developing a new assay In addition, a mutant form of AUH (A240V) derived from an MGA1 patient was tested using 3-MG-CoA

Results

Overexpression of AUH in Escherichia coli and purification of the corresponding gene product The gene for AUH which was cloned from a cDNA library by Nakagawa et al [15] encodes 339 amino acids specifying a 40-kDa protein (AUHp40) Western blot analysis of brain extracts consistently revealed a

32 kDa AUH protein and it was thus assumed that the mature form of human AUH in brain has a molecular weight of 32 kDa (AUHp32) [15] For the kinetic characterization of AUH described in the work

at hand, AUH was overproduced in Escherichia coli as

a maltose binding protein fusion (MBP-AUH) The complete AUH gene (producing MBP-AUHp40 in

E coli) but also a truncated form of AUH (producing MBP-AUHp32 in E coli) were ligated into the

bacterial expression vector pMAL-c2 Consequently,

two different forms of AUH, namely MBP-AUHp40

and MBP-AUHp32 could be isolated from the

corres-ponding E coli strains AUHp40 and

MBP-AUHp32 were purified to apparent homogeneity In a

subsequent step, the MBP portion of both fusion

teins was removed by proteolysis and the resulting

pro-teins AUHp40 and AUHp30 were again purified by

chromatography Thus, four different pure fractions of

AUH could be generated: MBP-AUHp40, AUHp40,

MBP-AUHp32 and AUHp32 Using the substrate

3-MG-CoA no difference in enzymatic activity was

detected between the four AUH forms MBP-AUHp40,

AUHp40, MBP-AUHp32 and AUHp32 Since the

purification procedure for MBP-AUHp40 was highly

reproducible, the kinetic data were collected using

purified MBP-AUHp40

Enzymatic synthesis of 3-MG-CoA and

glutaconyl-CoA

The substrates 3-MG-CoA and glutaconyl-CoA were

synthesized using recombinant glutaconate

CoA-trans-ferase from the glutamate fermenting bacterium

Acid-aminococcus fermentans [21,22] This enzyme catalyses

the transfer of coenzyme A from a CoA-donor to a

CoA-acceptor (Fig 2) In addition to its natural

sub-strate (R)-2-hydroxyglutarate, glutaconate

CoA-trans-ferase uses glutaconate, 3-methylglutaconate and other

short chain carboxylic acids as CoA-acceptors Because

the CoA-acceptor 3-methylglutaconate was not

com-mercially available, it was produced by alkaline

hydroly-sis of the corresponding dimethylester HPLC analyhydroly-sis

of the enzymatically produced 3-MG-CoA revealed five

signals (Fig 3) The compounds producing the signals

were analyzed by mass spectrometry The compounds

producing the first two signals (peak 1 and peak 2) had

molecular masses corresponding to unreacted

acetyl-CoA and free coenzyme A The compounds producing

the following signals (peak 3, peak 4 and peak 5) were

found to all have the same relative molecular mass of

893 matching the calculated molecular mass of 3-MG-CoA (893.647) Thus, three 3-MG-3-MG-CoA isomers were produced using the enzyme glutaconate CoA-transferase (Fig 4) The three different forms of 3-MG-CoA were separated by HPLC, collected and their concentration was determined using an enzymatic 5,5¢-dithiobis-2-ni-trobenzoate-based assay Subsequently, the 3-MG-CoA isomers were tested using AUH (Fig 3) It was found, that peak 5 (2 mm) was readily converted to (S)-HMG-CoA In addition, free CoA was detected Peak 4 (2 mm) produced significantly less HMG-CoA and also, in this reaction, a substantial amount of free CoA was found Peak 3 (0.5 mm) gave mainly free CoA and only small amounts of HMG-CoA Peak 5, being the best sub-strate, should correspond to (E)-3-MG-1-CoA, the inter-mediate of the leucine degradation pathway (Fig 4) Peak 4 is most likely to correspond to (E)-3-MG-5-CoA Peak 3 is probably (Z)-3-MG-5-CoA

Glutaconyl-CoA was prepared accordingly Also in this reaction two compounds were produced by glut-aconate CoA-transferase The molecules were separ-ated by HPLC, analyzed by mass spectrometry and were found to both have the same relative molecular mass of 881 corresponding to glutaconyl-CoA (881.247) Peak 1 was dominant and most likely was glutaconyl-1-CoA Peak 2 probably was glutaconyl-5-CoA The two isomers were separated from each other However, upon repeated analysis of the isolated compounds, the same two signals appeared The two isomers seem to interconvert into each other making a separation impossible Therefore, a mixture of the two isomers had to be used in the following studies

Kinetic constants for AUH on different CoA-substrates

Besides (E)-3-MG-1-CoA, the potential substrates glu-taconyl-CoA and HMG-CoA as well as crotonyl-CoA, 3-hydroxybutyryl-CoA and 3-methylcrotonyl-CoA were used for the kinetic characterization of AUH The data are summarized in Table 2

Overexpression of a mutant form of AUH and its activity on (E)-3-MG-1-CoA

Mutations in AUH are linked to the metabolic disease MGA1 Most published patients have been homozy-gous or compound heterozyhomozy-gous for null mutations expected to completely remove protein function [13,20] One patient was compound heterozygous for a null mutation and a missense mutation A240V (c.719C>T) This mutant form of AUH was overproduced as an

Fig 2 General mechanism for coenzyme A-transferases The CoAS–

moiety is transferred from the carboxyl group of the CoA-donor

(R1-COO – ) to the carboxyl group of the CoA-acceptor (R2-COO – ).

In the case of glutaconate CoA-transferase from A fermentans,

CoAS – transiently is bound to the c-carboxyl group of bE54 [24].

MBP fusion (MBP-AUHp40mut) in E coli according

to the wild-type enzyme and tested using the substrate

(E)-3-MG-1-CoA In these experiments, the specific

activity of MBP-AUHp40mut was 9% (0.068 UÆmg)1

protein) in comparison to the wild-type enzyme

(0.76 UÆmg)1protein) Hence, the mutation A240V

cau-ses a significant loss of enzyme activity

Direct nonisotopic assay of 3-MG-CoA hydratase

in cultured human skin fibroblasts

The nonisotopic 3-MG-CoA hydratase assay that was

developed during this work was evaluated for its use

in testing homogenates derived from human skin fibro-blast cultures Different cell cultures derived from type

I MGA patients and from wild-type controls were grown, fibroblast homogenates were prepared and tes-ted using 3-MG-CoA (10 lm) It was not possible to detect HMG-CoA in this assay probably due to rapid further processing of this common intermediate by enzymes present in the fibroblast homogenate (e.g by 3-hydroxy-3-methylglutaryl-CoA lyase; EC 4.1.3.4) Therefore, 3-MG-CoA (10 lm) was replaced by gluta-conyl-CoA (10 lm), which had been shown in our work to be an excellent substrate for AUH The product of this reaction, 3-hydroxyglutaryl-CoA, was

mAU

0 200 400 600

Acetyl CoA

CoA

(Z)-3-methylglutaconyl-5-CoA

MW 893,36

(E)-3-methylglutaconyl-5-CoA

MW 893,36

(E)-3-methylglutaconyl-1-CoA

MW 893,59

0 200 400 600

1000 mAU

HMG-CoA 800

CoA

(E)-3-methyl-glutaconyl-1-CoA

AUH AUH AUH

0 20 40 60 80 100 120 mAU

CoA

(Z)-3-methyl- glutaconyl-5-CoA

200 400 600 800 1000 mAU

0

CoA HMG-CoA

(E)-3- methyl- glutaconyl-5-CoA

1

2

3

4 5

HMG-CoA

B A

Fig 3 Isomers of 3-MG-CoA as substrates for human 3-MG-CoA hydratase (AUH) (A) 3-MG-CoA was enzymatically synthesized by incuba-ting 100 m M 3-methylglutaconate in 100 m M potassium phosphate pH 7.0 with 1 m M acetyl-CoA (reaction volume 1 mL) Synthesis was started by addition of 0.25 mg glutaconate-CoA-transferase from A fermentans The reaction was analyzed by HPLC and the CoA deriva-tives were detected by their absorbance at 260 nm Five signals were found, analyzed by mass spectrometry and assigned to be free CoA (peak 1), acetyl-CoA (peak 2) (Z)-3-MG-5-CoA (peak 3) (E)-3-MG-5-CoA (peak 4) and (E)-3-MG-1-CoA (peak 5) The determined relative molec-ular masses (MW) of the 3-MG-CoA compounds producing the signals are shown Acetyl-CoA was purchased from Sigma Aldrich (A 2056) and does contain traces of free CoA (peak 1) Nothing is known about the fronting and the peak shoulder of peak 1, however, the compound

is described by the supplier as only approximately 95% pure The tailing of acetyl-CoA (peak 2) most likely also is due to impurities of the commercially available compound If acetyl-CoA (Sigma Aldrich A 2056) only (without the addition of fibroblast homogenate) is applied to the HPLC-system the same picture appears Thus, it seems, that the fronting, the shoulder and the tailing is due to acetyl-CoA and not due to any other compound (B) The peaks 3, 4, and 5 were isolated by HPLC and used as substrates for AUH The AUH assay contained 2 m M of the respective isomers of 3-MG-CoA in a total volume of 25 lL The reaction was started by addition of AUH (1 lg), incubated for 1 h and the CoA products were HPLC-detected by their absorbance at 260 nm Peak 3 produced small amounts of HMG-CoA and large amounts of free CoA Peak 4 produced HMG-CoA and also large amounts of free CoA Peak 5 produced large amounts of HMG-CoA, but also free CoA.

readily detectable (Fig 5) We investigated fibroblast

homogenates from two controls and fibroblast

homo-genates from three patients with established MGA

type 1 Patient 1 [20] was homozygous for a mutation

leading to a stop codon at residue 197 (R197X) and

patient 2 [20] was homozygous for a mutation at the

splice acceptor site of intron 8 (IVS8–1G>A) Patient

3 [20] was compound heterozygous for a missense mutation A240V (c.719C>T) in exon 7 and an inser-tion mutainser-tion c.613–614insA This inserinser-tion causes a frameshift that starts at Met205 and leads to the intro-duction of a stop codon after four amino acids The intra-assay variation, estimated by measuring four fibroblast homogenates in a single experiment, was 3.9%, the interassay variation was 5.4% (n¼ 3 days) The fibroblast material from all MGA1 patients pro-duced significantly less (4–16 mUÆmg)1 protein, mean¼ 8 mUÆmg)1protein) of 3-hydroxyglutaryl-CoA

as compared to the two controls (72 mUÆmg)1protein and 80 mUÆmg)1protein) These results show, that the test measuring the hydratase reaction of AUH indeed

is useful for the direct analysis of fibroblast cultures derived from patients The residual activity within the patient material may be due to other enzymes in the fibroblast protein mixture No other specific soluble human enzyme, however, is known to accept glutaco-nyl-CoA as a substrate and to produce 3-hydroxyglut-aryl-CoA

Fig 4 Possible isomeric products of

3-MG-CoA produced by recombinant

glutaconate CoA-transferase (Gct) from

A fermentans Gct was used to produce

3-MG-CoA from (E,Z)-3-methylglutaconate

and acetyl-CoA (A) Gct transfers CoAS – to

either the 1-carboxyl- (left) or the 5-carboxyl

group (right) of (E)-3-methylglutaconate.

(E)-3-MG-1-CoA (left) was the best substrate

for human 3-MG-CoA hydratase (AUH).

According to this scheme (E)-3-MG-5-CoA

(right) bound to Gct isomerizes to give

(E)-3-MG-1-CoA (B) The production of

(Z)-3-MG-5-CoA by Gct is probably due to

the possible trans-conformation of the

5-carboxyl group of (Z)-3-methylglutaconate.

Table 2 Kinetic constants of AUH (human 3-methylglutaconyl-CoA

hydratase).

Substrate

K m

(l M )

V maxa

(UÆmg)1)

k cat

(s)1)

k cat ⁄ K m

(l M )1Æs)1)

(E)-3-Methylglutaconyl-1-CoA 8.3 3.9 5.1 0.6

(R,S)-3-Hydroxy-3-methylglutaryl-CoA

a Specific activities (UÆmg)1) are in lmolÆmin)1x mg protein.

In the present study, we characterized the 3-MG-CoA

hydratase reaction of leucine catabolism at the protein

and DNA levels and developed a novel assay for

enzyme analysis in a diagnostic setting The human

AUH protein was first recognized by its ability to bind

A + U-rich elements (ARE) of mRNA Surprisingly,

AUH showed sequence similarity to enoyl-CoA

hydra-tases, suggesting that this enzyme had another function

in cellular metabolism Indeed, AUH had enoyl-CoA

hydratase activity, which was described as an additional

intrinsic function of the protein Its role in intermediary

metabolism, however, was not clear [15] It was

subse-quently shown, that the metabolic disorder MGA1

caused by reduced 3-MG-CoA hydratase activity is

associated with mutations in the AUH gene This

indi-cated that AUH, in addition to its RNA binding

func-tion, must play an important role in leucine catabolism

AUH was overproduced in E coli and characterized

by measuring the reverse reaction, the dehydration of

HMG-CoA to 3-MG-CoA The reaction was followed

photometrically [4]

In order to measure AUH in the forward reaction

(hydratase activity), it was necessary to synthesize

3-MG-CoA, which is not commercially available

Glut-aconate CoA-transferase (Gct) from A fermentans

proved to be useful for the enzymatic production of this compound Earlier, Gct was reported to be specific for (E)-glutaconate and to be completely inactive with (Z)-glutaconate [21] The activity of Gct using the CoA-donor acetyl-CoA and the CoA-acceptor 3-meth-ylglutaconate was relatively low Our data suggest that Gct produces three isomers The production of (Z)-3-MG-5-CoA is probably due to the possible trans-conformation of the C5-carboxyl group of (Z)-3-methylglutaconate (Fig 4) Most of (Z)-3-MG-5-CoA was hydrolyzed by AUH to give free CoA and (Z)-3-methylglutaconate, trace amounts of HMG-CoA, however, were detected (E)-3-MG-5-CoA was a better substrate for hydration with AUH An explanation for this may be, that upon binding to AUH, (E)-3-MG-5-CoA is isomerized to give (E)-3-MG-1-(E)-3-MG-5-CoA (Fig 4A)

An intrinsic isomerase activity has also been reported for 4-hydroxybutyryl-CoA-dehydratase of Clostridium aminobutyricum [23] The isomerization reaction, how-ever, obviously takes time and the acyl-CoA-hydrolase reaction is favored over the hydratase reaction produ-cing free CoA and (E)-3-methylglutaconate The best substrate for AUH was (E)-3-MG-1-CoA (Km¼ 8.3 lm, Vmax¼ 3.9 UÆmg)1, kcat¼ 5.1), which is the intermediate of the leucine degradation pathway Surprisingly, also with this substrate, large amounts

of free CoA were produced Enzyme assays for the

mAU

0

20

40

60

80

100

120

140

1 4

mAU

0 20 40 60 80 100 120 140 mAU

0 20 40 60 80 100 120 140

1

1 2 3 4

glutaconyl-CoA

glutaconyl-CoA

3-hydroxy-glutaryl-CoA

3-hydroxy- glutaryl-CoA

glutaconyl-CoA

Fig 5 Direct nonisotopic assay of 3-MG-CoA hydratase (AUH) in cultured human skin fibroblasts 3-MG-CoA hydratase was tested in fibro-blast homogenates using glutaconyl-CoA (10 l M ) as a substrate The reaction was started by the addition of fibroblast homogenate (55 mg fibroblast proteinÆL)1), incubated for 1 h and the products of the reaction were HPLC-detected by their absorbance at 260 nm (A) As a con-trol, the assay mixture was incubated without the addition of fibroblast homogenates Two different cell cultures derived from a wild-type control (B) and an MGA1 patient (C, homozygous for mutation IVS8-1G>A in the AUH gene) were grown and fibroblast homogenates were prepared in phosphate-buffered saline (55 mg proteinÆmL)1) The compounds producing the signals (peak 1, peak 2, peak 3 and peak 4) were analyzed by mass spectrometry Peak 1 is free CoA, peak 2 probably is glutaryl-CoA, peak 3 is 3-hydroxyglutaryl-CoA and peak 4 is the sub-strate glutaconyl-CoA The fibroblast homogenate derived from the MGA1 patient produces significantly less (9%) of 3-hydroxyglutaryl-CoA confirming AUH deficiency.

characterization of AUH have been carried out with

crotonyl-CoA as a substrate or by measuring the

dehy-dratase reaction using HMG-CoA In these

experi-ments, an acyl-CoA-hydrolase activity of AUH was

not detected This is the first report showing kinetic

data for purified AUH, although a 3-MG-CoA

hydra-tase activity was found earlier in fibroblast and

lym-phocyte lysates measuring the hydration reaction [3]

At that time, the substrate [5-14C]3-MG-CoA was

pre-pared by incubation of 3-methylcrotonyl-CoA with

3-methylcrotonyl-CoA-carboxylase in the presence of

NaH14CO3 In this work, Kmvalues for the hydration

of [5-14C]3-MG-CoA of 6.9 lm (fibroblast) and 9.4 lm

(lymphocyte), respectively, were reported [3] The

formation of [5-14C]3-methylglutaconate from [5-14

C]3-methylglutaconyl-CoA was interpreted as nonspecific

hydrolysis Our results suggest that CoA-hydrolysis is

an intrinsic function of AUH

Experiments with the substrate HMG-CoA and

AUH showed that the hydration reaction (kcat¼ 5.1)

is favored by a factor of 20 over the dehydration

reac-tion (kcat¼ 0.26) which is consistent with the main

role of AUH in leucine catabolism, the hydration of

3-MG-CoA Comparing the turnover numbers of

glu-taconyl-CoA (kcat¼ 1.4) and 3-MG-CoA (kcat¼ 5.1)

it is obvious, that 3-MG-CoA is a better substrate

Crotonyl-CoA (kcat¼ 6.8) and 3-hydroxybutyryl-CoA

(kcat¼ 1.7) have higher Km values (12 and 55 mm),

indicating that the missing carboxylate reduces affinity

to the active site Also in this case, the hydration

reac-tion was favored over the dehydrareac-tion reacreac-tion (factor

of 4)

The mutant enzyme MBP-AUHp40mut (A240V),

identified in one MGA1 patient, had a clearly reduced

3-MG-CoA hydratase activity (9% of the wild-type

enzyme) This finding provides further evidence

con-firming that AUH is indeed the main hydratase in the

human leucine degradation pathway and that

muta-tions leading to reduced hydratase activity are

respon-sible for the MGA1 phenotype

The need to differentiate patients with AUH

defi-ciency from patients with other forms of MGA

requires the availability of a sensitive and specific

enzyme assay Our data show that the hydratase

reaction of AUH is favored over the dehydratase

reaction (factor of 20) Hence, measuring the

for-ward reaction in fibroblast homogenates of

patient-derived cells should increase the sensitivity of an

AUH test The product of this reaction, however, is

the common intermediate HMG-CoA, which is

quickly degraded by, e.g

3-hydroxy-3-methylglutaryl-CoA lyase (EC 4.1.3.4), to give acetyl-3-hydroxy-3-methylglutaryl-CoA and

acetoacetate As glutaconyl-CoA is a very good

substrate for AUH and since the product of the hy-dratase reaction, 3-hydroxyglutaryl-CoA, is not an intermediate within human metabolism, we hypothes-ized that glutaconyl-CoA may be used as a substrate for testing AUH activity in a routine setting Indeed,

we were able to show that AUH activity in fibro-blasts can be determined by monitoring the forma-tion of 3-hydroxyglutaryl-CoA The producforma-tion of a small amount of 3-hydroxyglutaryl-CoA in a patient homozygous for a null mutation in the AUH gene may be due to the action of another mitochondrial hydratase, e.g crotonase This will need to be taken into consideration when the assay is used in a diag-nostic setting Nevertheless, we believe that the novel assay may be a superior method for confirmation of AUH deficiency in fibroblast homogenates

In summary, our data show that the main biological function of AUH in human metabolism is the hydra-tion of (E)-3-MG-CoA to (S)-HMG-CoA in the leu-cine degradation pathway

Experimental procedures

Production and purification of human AUH

in E coli The production of AUHp40 (precursor form), AUHp32 (mature form), AUHp40A240 V and AUHp32A240 V in

E coliwas performed using the pMAL-c2 bacterial expres-sion vector [17] The different forms of AUH were pro-duced as fusions to the MBP of E coli The purification of the gene products was carried out as previously described [17] Protein was estimated using the method of Bradford [24]

Production and purification of glutaconate CoA-transferase from A fermentans in E coli

The production of glutaconate CoA-transferase from

A fermentansin E coli and its subsequent purification was carried out as described earlier [22]

Site-directed mutagenesis Plasmids corresponding to constructs a and b [17] were modified using the Stratagene QuikChange Site-Directed Mutagenesis Kit and the mismatch oligonucleotides AUH

GC-3¢ and AUH RP 5¢-GCCATCGAGGACTCGCACA GAGAATATGAGCT-3¢ (the c.719C>T mutation leading

to the amino acid exchange A240V is underlined) The AUH genes were proof-sequenced and no secondary muta-tions were detected

Mass spectrometry

The CoA-esters were separated by HPLC, ionized by ESI

and detected by TOF The HPLC system consisted of a

HP1100 series binary-gradient pump, a vacuum degasser (all

from Hewlett-Packard), and a CTC HTS PAL autosampler

(CTC) The dry sample was dissolved in water and 20 lL

injected onto a 4· 40-mm Grom-Sil120 ODS-4 HE column

(3-lm particle diameter; Grom) The samples were separated

from interfering compounds by a gradient between solution

B (acetonitrile +1 vol% formic acid) and solution A (water

+ 1 volume % formic acid) The gradient (1 mLÆmin)1) was

as follows: 0–5 min, 0% B to 83% B; 6–8 min, 100% B All

gradient steps were linear, and the total analysis time,

inclu-ding equilibration, was 10 min A splitter between the

HPLC column and the mass spectrometer was used, and

100 lLÆmin)1 of eluent was introduced into the mass

spec-trometer A LCT TOF (time-of-flight) mass spectrometer

(Micromass) was used in the negative and positive

electro-spray ionization (ESI) mode Nitrogen was used as the

neb-ulizing gas The capillary voltage was 3 kV, the source

temperature was set at 120
C, and the optimal cone-voltage

energy was 45 V

Enzymatic synthesis of 3-MG-CoA and

glutaconyl-CoA

Alkaline hydrolysis of dimethyl (E,Z)-3-methylglutaconate

(Sigma-Aldrich, Deisenhofen, Germany) in 1 m NaOH for

30 min under reflux followed by exchange of Na+ against

H+ with the ion exchanger Dowex 50 W· 8 (H+

-form, Serva, Heidelberg, Germany) yielded

(E,Z)-3-methylgluta-conic acid Its CoA-derivative 3-MG-CoA was enzymatically

synthesized by incubating 100 mm 3-methylglutaconate in

100 mm potassium phosphate pH 7.0 with 1 mm

acetyl-CoA The reaction (1 mL) was started by addition of

0.25 mg recombinant glutaconate CoA-transferase (EC

2.8.3.12) from A fermentans which was purified from an

overproducing E coli strain [22] After 1 h at room

tempera-ture the reaction was stopped by addition of an equal

vol-ume of 8 m guanidinium chloride (1 mL) and the pH was

adjusted to 3–4 using 1 m HCl The desired product

3-MG-CoA was separated from unreacted compounds using a

Waters Sep – Pak tC18 column (1 mL cartridge, 100 mg

sorbent) (Waters, Eschborn, Germany) The column was

first treated with 10 volumes 0.1% (v⁄ v) trifluoroacetic acid

in H2O, 50% acetonitrile (v⁄ v) The acetonitrile component

also contained 0.1% trifluoroacetic acid Subsequently, the

column was washed with 10 volumes 0.1% (v⁄ v)

trifluoro-acetic acid in H2O The samples were loaded and the column

was washed with 10 volumes 0.1% (v⁄ v) trifluoroacetic acid

in H2O The CoA-ester was eluted with 10 volumes 0.1%

(v⁄ v) trifluoroacetic acid in H2O, 50% acetonitrile (v⁄ v)

con-taining 0.1% trifluoroacetic acid After evaporation in vacuo,

the CoA-ester was dissolved in water and stored at)20
C

For analytic and preparative purposes a Phenomenex Syn-ergi 4 l Polar-RP 80 A column (5 lm) was used at a flow rate of 1 mLÆmin)1 (Phenomenex, Aschaffenburg, Ger-many) The eluents were 0.1% trifluoroacetic acid (v⁄ v) in

H2O (solution A) and 0.085% trifluoroacetic acid (v⁄ v) in acetonitrile (solution B) The columns were equilibrated for

5 min with solution A After injection of the CoA derivative

a linear gradient was applied from 0 to 8% solution B within

3 min in order to remove impurities The separation was achieved with a gradient from 8 to 13% solution B within

20 min Afterwards the column was regenerated with 100% solution B for 15 min followed by 100% sol A for 10 min The CoA esters were detected by their absorbance at

260 nm, evaporated in vacuo and dissolved in H2O The CoA esters were identified by their masses using mass spectro-metry The concentration of 3-MG-CoA and glutaconyl-CoA was determined enzymatically in a cuvette (1 mL) containing 100 mm potassium phosphate pH 7.0, 200 mm sodium acetate, 1 mm 5,5¢-dithiobis-2-nitrobenzoate and

1 mm oxaloacetate, k¼ 412 nm, e ¼ 14.2 mm)1Æcm)1[22,25]

An increase in absorbance after addition of 3-MG-CoA was due to free CoASH If acetyl-CoA was present, a further increase followed the addition of 10 lg citrate synthase (Roche, Mannheim, Germany) The final increase after addi-tion of 10 lg glutaconate CoA-transferase was proporaddi-tional

to the concentration of 3-MG-CoA The CoA-substrate glutaconyl-CoA was prepared accordingly from glutaconic acid (Fluka 49360) and acetyl-CoA

Other CoA-substrates (R,S)-HMG-CoA, crotonyl-CoA, 3-methylcrotonyl-CoA and 3-hydroxybutyryl-CoA were obtained from Sigma-Aldrich

Assay of 3-MG-CoA hydratase The assay contained in a total volume of 25 lL 50 mm Tris HCl pH 7.4, 10 mm EDTA, 1 mgÆmL)1bovine serum albu-min and 0.05–0.2 mm 3-MG-CoA The reaction was started

by addition of the enzyme (1 lg) The products of the reac-tion were analyzed by HPLC as described above and mass spectrometry The kinetic constants Km (lM) and Vmax

(UÆmg protein)1) were evaluated with the Michaelis-Menten equation and Lineweaver-Burk plots using the Microsoft Excel program The turnover numbers, kcat (s)1), were calculated with the subunit molecular mass (78.4 Da) of MBP-AUHp40

Direct nonisotopic assay of 3-MG-CoA hydratase

in cultured human skin fibroblasts Fibroblasts were grown and harvested as described elsewhere [26] Cells were suspended in 200 lL phosphate-buffered

saline by repeated pipetting and sonicated three times on ice

for 15 s at 8 W at 45-s intervals An aliquot of the fibroblast

homogenate (55 mgÆL)1fibroblast protein) was added to the

3-MG-CoA hydratase assay Protein was estimated using the

method of Bradford [24] The 3-MG-CoA hydratase assay

mixture contained, in a final volume of 25 lL, 100 mm

Tris-HCl (pH 8.0), 10 mm EDTA, 1 gÆL)1bovine serum albumin

and 10 lm 3-MG-CoA or glutaconyl-CoA After incubation

at 37
C for 60 min, the reaction was terminated by the

addi-tion of 2.5 lL of 2 m HCl The samples were homogenized,

and the assay tubes were placed on ice After 5 min, the

homogenates were brought to pH 6 with 2 mm KOH, 1 mm

Mes (pH 6) and centrifuged at 21 000 g for 10 min at 4
C

The supernatant was transferred to an HPLC vial The

products of the reaction were detected at 260 nm using the

HPLC system described above for the synthesis of the

CoA-esters The assay was linear with an incubation time up to at

least 60 min with up to 70 mgÆL)1total protein

Acknowledgements

We are grateful to C Moroni and J Nakagawa for

sharing the cDNA encoding human AUH This work

received financial support from the Deutsche

Fors-chungsgemeinschaft, Grant number Zs 17⁄ 4–2

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