J Biol Chem, Vol. 275, Issue 10, 7390-7394, March 10, 2000
Molecular and Biochemical Characterization of Rat
-Trimethylaminobutyraldehyde Dehydrogenase and Evidence for the
Involvement of Human Aldehyde Dehydrogenase 9 in Carnitine
Biosynthesis*
Frédéric M.
Vaz,
Sigrid W.
Fouchier,
Rob
Ofman,
Monica
Sommer, and
Ronald J. A.
Wanders
From the Laboratory for Genetic Metabolic Diseases, Departments of
Clinical Chemistry and Pediatrics, Emma Children's Hospital, Academic
Medical Center, University of Amsterdam, P. O. Box 22700, 1100 DE Amsterdam, The Netherlands
 |
ABSTRACT |
The penultimate step in carnitine biosynthesis is
mediated by 
-trimethylaminobutyraldehyde dehydrogenase (EC
1.2.1.47), a cytosolic NAD+-dependent
aldehyde dehydrogenase that converts -trimethylaminobutyraldehyde into -butyrobetaine. This enzyme was purified from rat liver, and
two internal peptide fragments were sequenced by Edman degradation. The
peptide sequences were used to search the Expressed Sequence Tag data
base, which led to the identification of a rat cDNA containing an
open reading frame of 1485 base pairs encoding a polypeptide of 494 amino acids with a calculated molecular mass of 55 kDa. Expression of
the coding sequence in Escherichia coli confirmed that the
cDNA encodes -trimethylaminobutyraldehyde dehydrogenase. The
previously identified human aldehyde dehydrogenase 9 (EC 1.2.1.19) has
92% identity with rat trimethylaminobutyraldehyde dehydrogenase and
has been reported to convert substrates that resemble
-trimethylaminobutyraldehyde. When aldehyde dehydrogenase 9 was
expressed in E. coli, it exhibited high
trimethylaminobutyraldehyde dehydrogenase activity. Furthermore, comparison of the enzymatic characteristics of the heterologously expressed human and rat dehydrogenases with those of purified rat liver
trimethylaminobutyraldehyde dehydrogenase revealed that the three
enzymes have highly similar substrate specificities. In addition, the
highest Vmax/Km values were
obtained with -trimethylaminobutyraldehyde as substrate.
This indicates that human aldehyde dehydrogenase 9 is the
-trimethylaminobutyraldehyde dehydrogenase, which functions in
carnitine biosynthesis.
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INTRODUCTION |
Carnitine (3-hydroxy-4-N-trimethylaminobutyrate) is a
vital compound that plays an indispensable role in the transport of activated fatty acids across the inner mitochondrial membrane into the
matrix, where 
-oxidation takes place (1, 2). Furthermore, carnitine
is involved in the transfer of the products of peroxisomal -oxidation, including acetyl-CoA, to the mitochondria for oxidation to CO2 and H2O in the Krebs cycle (3, 4). Apart
from the dietary intake of carnitine, most eukaryotes are able to
synthesize this compound from trimethyllysine (5-7). This
trimethyllysine is generated by the hydrolysis of proteins containing
lysines that are trimethylated at their 
-amino group by a
protein-dependent methyltransferase using
S-adenosylmethionine as a methyl donor. In the carnitine
biosynthetic pathway, trimethyllysine is first hydroxylated at the
-position by -trimethyllysine hydroxylase, after which the
resulting -hydroxytrimethyllysine is cleaved by a specific aldolase
into -trimethylaminobutyraldehyde and glycine.
-Trimethylaminobutyraldehyde is subsequently oxidized by
-trimethylaminobutyraldehyde dehydrogenase
(TMABA-DH)1 to form
-butyrobetaine (8). In the last step, -butyrobetaine is
hydroxylated at the -position by a second hydroxylase,
-butyrobetaine hydroxylase, yielding L-carnitine (5, 9,
10). In rat and mouse, -butyrobetaine hydroxylase is exclusively
localized in the liver, whereas in man, the enzyme is present in
kidney, liver, and brain. Although most tissues are capable of
converting trimethyllysine into -butyrobetaine, liver and kidney are
the main sites of carnitine biosynthesis in all animals (9-13).
Kaufman and Broquist (6) were the first to demonstrate that
-trimethylaminobutyraldehyde is an intermediate in the carnitine biosynthesis of Neurospora crassa using isotope labeling
experiments, and they suggested that an aldehyde dehydrogenase mediates
its conversion to -butyrobetaine. Perfusion experiments showed that -trimethylaminobutyraldehyde is readily absorbed by rat liver and
converted to carnitine via -butyrobetaine, demonstrating the
conservation of the dehydrogenation step in higher eukaryotes (14). Subsequently, Rebouche and Engel (10) showed that TMABA-DH activity was present in the cytosolic fraction of human liver, kidney,
brain, heart, and muscle homogenates. In the same year, Hulse and
Henderson (8) purified a cytosolic
NAD+-dependent aldehyde dehydrogenase
from bovine liver showing maximum activity with
-trimethylaminobutyraldehyde, converting it into -butyrobetaine.
Except for the human -butyrobetaine hydroxylase, which has recently
been identified in our laboratory (15), none of the enzymes of the
carnitine biosynthetic route have been characterized at the molecular
level. We therefore purified the aldehyde dehydrogenase responsible for
the conversion of -trimethylaminobutyraldehyde to
-butyrobetaine from rat liver and determined part of its amino acid
sequence. Using this sequence information we identified the cDNAs
encoding TMABA-DH from rat, human, and mouse. Finally, we expressed the cDNAs in Escherichia coli and
compared the substrate specificities of the recombinant enzymes with
those of the purified rat liver trimethylaminobutyraldehyde dehydrogenase.
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EXPERIMENTAL PROCEDURES |
Materials--
4-Aminobutyraldehydediethylacetal,
1,8-bis(dimethylamino)naphtalene, methyliodide,
2,4-dinitrophenylhydrazine, methanal, ethanal, propanal, butanal,
pentanal, hexanal, heptanal, octanal, and betaine aldehyde chloride
were from Sigma. NAD+ and NADH were from Roche Molecular
Biochemicals. Hexadecanal and octadecanal were synthesized as described
earlier (16). SP-Sepharose fast flow and red-Sepharose CL-6B were
obtained from Amersham Pharmacia Biotech, and CHT-II hydroxylapatite
was from Bio-Rad. All other reagents were of analytical grade. The
pMAL-C2X vector was purchased from New England Biolabs (Herts, UK).
Synthesis of
-Trimethylaminobutyraldehyde--
4-Aminobutyraldehyde
diethylacetal was trimethylated in ethyl acetate using methyliodide in
the presence of 1,8-bis(dimethylamino)naphatalene (proton sponge). The
iodide salt of 4-N-trimethylaminobutyraldehyde diethylacetal
precipitated together with the protonated proton sponge. This
precipitate was subsequently dissolved in distilled water by heating
the mixture in a boiling water bath. After slow cooling to room
temperature, only the protonated proton sponge crystallized, whereas
4-N-trimethylaminobutyraldehyde diethylacetal remained in
solution. After removal of the proton sponge by filtration, the process
was repeated five times in smaller volumes of distilled water to
completely remove the remainder of the proton sponge. Hydrolysis of the
resulting acetal in 0.1 M HCl for 30 min at room
temperature gave -trimethylaminobutyraldehyde. Water and HCl were
evaporated in a rotavapor, and the -trimethylaminobutyraldehyde was
taken up in distilled water. In solution,
-trimethylaminobutyraldehyde was stable for at least three months at
20 °C.
TMABA-DH Assay--
TMABA-DH activity was determined either
spectrophotometrically or fluorometrically at 37 °C by monitoring
the formation of NADH using a centrifugal analyzer (COBAS FARA; Roche
Molecular Biochemicals). The assay mixture used in both methods
contained 0.1 M sodium pyrophosphate buffer at pH 9.0, 0.5 mM NAD+, and the enzyme sample in a final
volume of 250 µl. The reaction was started by adding
-trimethylaminobutyraldehyde to a final concentration of 100 µM, unless otherwise indicated. In the spectrophotometric assay, the increase in absorbance at 340 nm was measured, and the
activity was calculated using 6220 M
1
cm1 as the molar extinction coefficient of NADH. In the
fluorometric method, NADH formation was detected by measuring the
fluorescence at 450 nm after excitation at 340 nm. Standard solutions
of NADH were used for calibration.
Purification of TMABA-DH--
Livers were taken from Wistar rats
and homogenized by five strokes of a Teflon pestle in a Potter-Elvehjem
glass homogenizer at 500 rpm in a 5 mM MOPS buffer, pH 6.0, containing 0.25 M sucrose and 2 mM EDTA. The
crude homogenate was centrifuged for 10 min at 800 × g
at 4 °C to remove nuclei and whole cells. The resulting post-nuclear
supernatant was centrifuged for 3 h at 20.000 × g at 4 °C to obtain the cytosolic fraction. The cytosolic fraction was
applied to an SP-Sepharose fast flow column (inner diameter =2.8 cm,
length = 10 cm), which was pre-equilibrated with a 10 mM
MES buffer, pH 6.0, containing 200 g/liter glycerol and 1 mM dithiothreitol (DTT). Bound proteins were eluted with a
linear gradient from 0 to 100 mM NaCl in the same buffer.
Fractions containing high TMABA-DH activity were pooled and loaded onto
a red Sepharose CL-6B column (inner diameter = 0.8 cm, length = 7.5 cm), that was pre-equilibrated with a 10 mM MES buffer, pH
6.0, containing 200 g/liter glycerol, 1 mM DTT, and 25 mM NaCl. Bound proteins were eluted with a linear gradient
from 25 to 500 mM NaCl in the same buffer. Fractions
containing TMABA-DH activity were pooled and dialyzed against a 10 mM MES buffer, pH 6.0, containing 200 g/liter glycerol, 1 mM DTT, and 20 mM potassium phosphate. This dialysate was loaded onto an Econo-Pac CHT-II hydroxylapatite column
(inner diameter =1 cm, length = 5 cm) equilibrated with the same
buffer. Bound proteins were eluted with a linear gradient from 25 to
250 mM potassium phosphate. Fractions were tested for TMABA-DH activity and analyzed by sodium dodecyl sulfate-acrylamide gel
electrophoresis (PAGE) followed by silver staining. SDS-PAGE and silver
staining were performed as described by Laemmli (17) and Rabilloud
et al. (18), respectively. Protein concentrations were
determined by the method of Bradford (19), using bovine serum albumin
as standard.
Protein Digestion, Western Blotting, and Automated Edman
Degradation--
10 µg of the purified TMABA-DH was digested for
1 h at 37 °C with 0.05 µg of endoprotease Glu-C (Roche
Molecular Biochemicals) in a 50 mM Tris-HCl buffer, pH 8.0, containing 0.01% SDS. Protein fragments were resolved on a 15%
SDS-PAGE gel, and a Multiphor II Nova Blot electrophoretic transfer
unit (Amersham Pharmacia Biotech) was used to transfer proteins onto a
polyvinylidene difluoride-sequencing membrane (Millipore, Bedford, MA)
as described by the manufacturer of the transfer unit. Proteins were
visualized with Coomassie Brilliant Blue. N-terminal amino acid
sequencing was performed using a Procise 494 protein sequencer.
Cloning, Expression, and Purification of the Rat TMABA-DH and
Aldehyde Dehydrogenase 9 (ALDH9) in E. coli--
The complete open
reading frame (ORF) of TMABA-DH was amplified by the polymerase chain
reaction from rat liver cDNA using Advantage cDNA polymerase
(CLONTECH, Palo Alto, CA) and the following primers: an EcoRI-tagged forward primer
5'-tatagaattcATGAGCACTGGCACCTTCG-3' and a
SalI-tagged reverse primer
5'-tatagtcgacTTTTCAAAARGCWGAYTCCAC-3'. The
degenerate nature of the second primer also allowed the amplification of the ALDH9 ORF from human liver cDNA using the same primer set. The polymerase chain reaction products were cloned downstream of the
isopropyl-1-thio--D-galactopyranoside-inducible
PTAC promoter into the EcoRI and SalI
sites of the bacterial expression vector pMAL-C2X, to express the
TMABA-DH and ALDH9 as a fusion protein with maltose-binding protein
(MBP). The ORFs were sequenced to exclude sequence errors introduced by
the polymerase chain reaction, after which the constructs were
transformed to the E. coli strain BL21. Transformed cells
were grown on LB medium to an A600 of 0.7, and
isopropyl-1-thio--D-galactopyranoside was added to a final concentration of 1 mM to induce expression of the
fusion protein. After 2 h, cells were pelleted and lysed in
one-tenth of the culture volume in a 10 mM sodium phosphate
buffer, pH 7.4, containing 140 mM NaCl, 200 g/liter
glycerol, and 1 mM DTT by sonicating 2 times for 15 s
at 8 W. The bacterial lysate was centrifuged for 10 min at 14,000 × g, and the pellet was discarded. Fusion proteins were
purified from the supernatant following the specifications of the
manufacturer of the expression system (New England Biolabs) and stored
at 80 °C in a 10 mM sodium phosphate buffer, pH 7.4, containing 140 mM NaCl, 200 g/liter glycerol, 1 mM DTT, and 3 mg/ml bovine serum albumin.
Characterization of TMABA-DH--
The Michaelis-Menten constant
(Km) and maximal velocity
(Vmax) for -trimethylaminobutyraldehyde and
several other aldehydes were determined for the purified rat liver
enzyme and the purified recombinant fusion proteins using the assay
described above. The concentration of -trimethylaminobutyraldehyde
was determined with 2,4-dinitrophenylhydrazine as described by Ariga (20). -Aminobutyraldehyde was freshly prepared from
4-aminobutyraldehyde diethylacetal as described by Kurys et
al. (21). Its concentration was determined with
o-aminobenzaldehyde as reported by Jakoby and Fredericks
(22). Because of the instability of -aminobutyraldehyde at alkaline
pH, activity measurements with this compound as substrate were
performed at pH 7.4 using a 0.1 M sodium phosphate buffer. For the determination of the Km of NAD+
and NADP+, -trimethylaminobutyraldehyde was used at a
fixed concentration of 100 µM.
| |
RESULTS |
Purification of TMABA-DH from Rat Liver--
In initial
experiments, high TMABA-DH activity (~3 nmol/min·mg) could be
measured in crude rat liver homogenates. Subsequent measurement of
TMABA-DH activity in subcellular fractions of rat liver showed that the
activity was only present in the cytosolic fraction (results not
shown). Therefore, rat liver cytosol was used as source of enzyme for
the purification of TMABA-DH using liquid chromatography. An overview
of the purification scheme is given in Table
I. TMABA-DH activity was completely
retained by all columns used and eluted as a single peak during all
purification steps. Samples obtained after each purification step were
analyzed by SDS-PAGE followed by silver-staining (Fig.
1). A single protein band with an
apparent molecular mass of 55 kDa was observed after the last
purification step. The purified enzyme was highly unstable, except when
stored at 80 °C in the presence of 1 mM DTT and 200 g/liter glycerol. Even after several months of storage, no loss of
activity could be measured.
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Fig. 1.
Overview of TMABA-DH purification.
Protein samples of the various purification steps were analyzed by 12%
SDS-PAGE followed by silver staining. Lane 1, molecular
weight marker; lane 2, 20,000 × g rat liver
supernatant and pooled fractions of SP-Sepharose (lane 3),
red Sepharose (lane 4), hydroxylapatite CHT-II (lane
5).
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Identification of the cDNA Encoding TMABA-DH--
Attempts to
directly sequence the protein by Edman degradation failed, suggesting
that the N terminus of TMABA-DH is blocked. Therefore, the purified
enzyme was subjected to digestion with the endoprotease Glu-C to
generate peptides with a free N terminus. Peptide fragments were
separated on SDS-PAGE, blotted onto a polyvinylidene difluoride-sequencing membrane, and visualized by Coomassie Brilliant Blue staining. Two peptide fragments were N-terminally sequenced, which
resulted in the following sequences: EXINNGKSIFEA and
EARLDVDTS (where X denotes an amino acid that could not be
identified unambiguously). When the Swiss-Prot data base was screened
with these sequences, the only homology found was with the human ALDH9
(EC 1.2.1.19, Swiss-Prot P49189). Subsequent searches in the Expressed Sequence Tag (EST) data base identified several rat, mouse, and human
EST clones with high homology to the peptide sequences. The homologous
human ESTs all corresponded to the ALDH9 cDNA (GenBankTM accession
number U34252) (23, 24). Based on the EST data, primers were selected
to amplify the ORFs from rat and mouse liver cDNA. The rat and
mouse amplicons both contained an ORF of 1485 base pairs, coding for a
polypeptide of 494 amino acids with a predicted molecular mass of 55 kDa (GenBankTM accession numbers AF170918 and AF170919, respectively).
The translated rat and mouse ORFs both have 92% positional identity
with the human ALDH9 protein. The rat and mouse proteins are also
highly homologous and share 96% positional identity. The two peptides
obtained by Edman degradation were found to overlap, resulting in the
following sequence: EXINNGKSIFEARLDVDTS. This sequence is
identical to a 19-amino acid stretch in the N-terminal region of the
rat sequence (95-114), demonstrating that the rat cDNA encodes
TMABA-DH.
Expression of the Rat ORF as MBP Fusion Protein in E. coli--
The entire coding sequence of the rat cDNA was cloned
into the pMAL-C2X expression vector and expressed in E. coli
as a fusion protein with MBP. The fusion protein was purified from the
E. coli lysate by affinity chromatography, and TMABA-DH
activity was measured. The purified fusion protein exhibited high
TMABA-DH activity, which confirmed that the cDNA encodes
TMABA-DH.
Expression of the ALDH9-MBP Fusion Protein in E. coli--
Human
ALDH9 has high homology with the identified rat TMABA-DH and has been
reported to dehydrogenate -aminobutyraldehyde and betaine aldehyde
(21, 25), which are compounds with considerable structural resemblance
to -trimethylaminobutyraldehyde (Fig. 2). Therefore, the ALDH9 ORF was cloned
in the pMAL-C2X vector to express ALDH9 as an MBP fusion protein.
Sequencing of the ALDH9 ORF revealed three additional nucleotides in a
GC-rich stretch of the previously reported ALDH9 cDNA, altering the
predicted amino acid sequence. This information can be accessed through the GenBankTM data base, accession number AF172093. The MBP-ALDH9 fusion protein was affinity-purified from E. coli lysate to
determine whether ALDH9 was also active toward
-trimethylaminobutyraldehyde. The fusion protein exhibited high
TMABA-DH activity, which indicates that ALDH9 is the human orthologue
of rat TMABA-DH.
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Fig. 2.
Structure of
-aminobutyraldehyde (A),
-trimethylaminobutyraldehyde (B),
and betaine aldehyde (C).
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Characterization of the Purified Rat Liver TMABA-DH and Comparison
with MBP Fusion Proteins--
To investigate if the purified rat liver
TMABA-DH and the rat MBP-TMABA-DH could also handle the substrates
reported for ALDH9 and to further characterize the substrate
specificity of the three enzymes, their kinetic properties were
determined. Table II shows the kinetic
parameters of the purified rat liver TMABA-DH, rat MBP-TMABA-DH, and
MBP-ALDH9 with NAD+, NADP+,
-trimethylaminobutyraldehyde, -aminobutyraldehyde, betaine aldehyde, and a range of aliphatic aldehydes as substrates. The Km and relative Vmax values
of the purified MBP fusion proteins for the different substrates show a
similar profile as the purified rat liver TMABA-DH. NAD+
was by far the preferred oxidant for all substrates, although NADP+ could also be used. The three enzymes have the lowest
Km for -trimethylaminobutyraldehyde in
combination with a high Vmax value. As a
consequence, the Vmax/Km
ratio is highest for -trimethylaminobutyraldehyde when compared with
the other substrates. The presence of a free amino group in
-aminobutyraldehyde instead of the trimethylated amino group in
-trimethylaminobutyraldehyde results in considerably lower
efficiency. Betaine aldehyde, the carbon backbone of which is two atoms
shorter than -trimethylaminobutyraldehyde but that contains the
trimethylated amino group, is readily oxidized to betaine as reflected
in the high Vmax values. The three enzymes have
a high Km for betaine aldehyde, however, which
results in a substantially lower efficiency when compared with
-trimethylaminobutyraldehyde. For the aliphatic aldehydes in
the C2-C8 range, the decrease in the
Km values is accompanied by a steady increase of Vmax, showing that the efficiency of the enzymes
is higher when the chain length of the aliphatic aldehyde increases.
The efficiency of the enzymes with the longer aldehydes, hexadecanal
and octadecanal, is very low if not undetectable.
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Table II
Substrate specificity of purified TMABA-DH and heterologously expressed
enzymes
Enzyme assays were performed as described in "Experimental
Procedures," and the results are the means of three independent
measurements. Vmax is expressed as the percentage of
the maximal velocity measured with -trimethylaminobutyraldehyde. In
the measurements with NAD(P)+, 100 µM
-trimethylaminobutyraldehyde was used as the substrate. Measurements
with -aminobutyraldehyde were performed in a 0.1 M
sodium phosphate buffer, pH 7.4. The Vmax values for
this substrate are based on measurements with 100 µM
-trimethylaminobutyraldehyde as the substrate at the same pH.
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| |
DISCUSSION |
To identify the enzymes of the carnitine biosynthetic pathway at
the molecular level, we previously purified rat liver -butyrobetaine hydroxylase, the last enzyme in carnitine biosynthesis and used protein
sequence data in combination with the EST data base to identify the
corresponding human cDNA (15). In this study the same approach was
used to identify TMABA-DH, which mediates the penultimate step in
carnitine biosynthesis. The enzyme was purified from rat liver to
apparent homogeneity and used for peptide sequencing. The resulting
peptide sequences were subsequently used to search the EST data base,
and two ORFs were identified from rat and mouse encoding proteins with
high homology to the previously reported human ALDH9. The following
observations demonstrated that the identified rat cDNA truly
encodes TMABA-DH. First, the peptide sequence obtained by sequencing of
the purified rat TMABA-DH exactly matched a 19-amino acid stretch in
the translated coding region of the rat cDNA. Second, the cDNA
encodes a protein with a calculated molecular mass of 55 kDa, which is
in accordance with the apparent molecular mass of the purified rat
liver TMABA-DH. Third, heterologously expressed rat cDNA exhibited
high TMABA-DH activity. Finally, the kinetic properties of the
recombinant rat MBP fusion protein are highly similar to those of
TMABA-DH purified from rat liver. Although we did not express the mouse
ORF in E. coli, it has 96% positional identity with
the rat TMABA-DH and, therefore, most likely represents the
mouse orthologue of rat TMABA-DH.
The rat TMABA-DH has high positional identity (92%) with human ALDH9.
ALDH9 is a cytosolic NAD+-dependent
dehydrogenase belonging to the human aldehyde dehydrogenase gene family
(26). It has been extensively investigated because of its proposed
function in the alternative synthesis of the inhibitory neurotransmitter -aminobutyric acid (GABA) (23, 27-29). In this pathway, diamine oxidase oxidatively deaminates putrescine
(1,4-diaminobutane) to -aminobutyraldehyde, which is subsequently
oxidized to GABA by ALDH9. The majority of the GABA in rat adrenal
gland is produced via this alternative pathway, whereas the GABA in
brain is predominantly synthesized from glutamate by glutamate
decarboxylase (30). Both the physiological importance of the conversion
of putrescine to -aminobutyric acid and the function of GABA outside
the central nervous system is not well understood and remains to be established.
More recently, ALDH9 has also been implicated in the synthesis of
betaine. Betaine can serve as a methyl donor in the biosynthesis of
methionine and has also been proposed to be involved in the regulation
of the osmolarity in the kidney during antidiuresis (31-33). For the
synthesis of betaine, choline is oxidized by choline dehydrogenase to
betaine aldehyde, which is subsequently converted to betaine by ALDH9
(25, 34). In human tissues, betaine aldehyde dehydrogenase activity is
predominantly found in liver, adrenal gland, and kidney. Northern blot
analysis has shown the presence of the ALDH9 mRNA in liver, kidney,
skeletal muscle, heart, brain, pancreas, lung, and placenta (23, 27,
34).
The high homology with rat TMABA-DH and the structural resemblance of
the substrates of ALDH9 with -trimethylaminobutyraldehyde prompted
us to study whether human ALDH9 is in fact the human TMABA-DH. The
finding that the recombinant human MBP-ALDH9 fusion protein exhibits
high TMABA-DH activity suggests that human ALDH9 is, indeed, the human
TMABA-DH.
Since ALDH9 has been reported to oxidize betaine aldehyde and
-aminobutyraldehyde, the kinetic properties of the two recombinant MBP fusion proteins and the purified rat liver TMABA-DH were also determined for these and other substrates. Like the ALDH9 MBP fusion
protein, both rat liver TMABA-DH and the rat TMABA-DH MBP fusion
protein oxidized -aminobutyraldehyde and betaine aldehyde. However,
when considering both affinity and maximal velocity, -trimethylaminobutyraldehyde is clearly the best substrate for all three enzymes.
Recently, the three-dimensional structure of cod liver ALDH9 has been
determined at a 2.1-Å resolution by x-ray crystallography (35). This
protein has 70% positional identity with the human ALDH9 and is
considered to be the cod orthologue of human ALDH9. The structural
information revealed that the active site of cod ALDH9 is capable of
handling larger aldehydes than betaine aldehyde, which is in accordance
with our results, which reveal that the three forms of ALDH9 studied in
this paper show the highest
Vmax/Km ratio for
straight-chain aldehydes with a length of 7/8 carbon atoms. The
preference for longer aldehydes also explains the relatively low
Km values for -trimethylaminobutyraldehyde and
-aminobutyraldehyde opposed to the high Km value
for betaine aldehyde. The high Vmax value of the
enzymes for betaine aldehyde is difficult to explain on the basis of
the data presented here. Additional research is needed to understand
this phenomenon.
Further investigation of the active site of cod ALDH9 showed that there
is no negatively charged residue in the substrate pocket that interacts
with the trimethylated amino group of betaine aldehyde. Instead, a
hydrophobic interaction has been proposed between a tryptophan residue
and the trimethylamino group of betaine aldehyde (35). If the nature of
the interaction with the amino group of the substrate is hydrophobic
instead of electrostatic, the reason for a higher Km
value for -aminobutyraldehyde than for
-trimethylaminobutyraldehyde could be that the positively charged
amino group in -aminobutyraldehyde is shielded by three methyl
groups in -trimethylaminobutyraldehyde.
The high activity of the heterologously expressed human ALDH9 with
-trimethylaminobutyraldehyde and the highly similar substrate specificity of ALDH9 and rat TMABA-DH strongly suggest that the human
ALDH9 is the human TMABA-DH. This is supported by the presence of high
betaine aldehyde dehydrogenase activity in human kidney and liver and
the ALDH9 mRNA in tissues that contain high TMABA-DH activity (10,
23, 34). Although our data do not exclude an additional function of
ALDH9 in GABA and/or betaine synthesis, the results presented in this
paper indicate that ALDH9 is the predominant, if not exclusive aldehyde
dehydrogenase that functions in carnitine biosynthesis.
| |
ACKNOWLEDGEMENTS |
We thank M. Q. Slagt and J. Ruiter for
technical assistance, A. O. Muijsers for peptide sequencing,
and Dr. H. R. Waterham for critical comments on the manuscript.
| |
FOOTNOTES |
*
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF170918, AF170919, and AF172093.
To whom correspondence should be addressed: University of
Amsterdam, Academic Medical Center, Depts. of Clinical Chemistry and
Pediatrics, Laboratory for Genetic Metabolic Diseases (F0-224), P. O.
Box 22700, 1100 DE Amsterdam, The Netherlands. Tel.: 31 20 5665958;
Fax: 31 20 6962596; E-mail: wanders@amc.uva.nl.
| |
ABBREVIATIONS |
The abbreviations used are:
TMABA-DH, -trimethylaminobutyraldehyde dehydrogenase;
ALDH9, aldehyde
dehydrogenase 9, MBP, maltose-binding protein, GABA, -aminobutyric
acid;
MOPS, 4-morpholinopropanesulfonic acid;
MES, 4-morpholinoethanesulfonic acid;
DTT, dithiothreitol;
PAGE, polyacrylamide gel electrophoresis: ORF, open reading frame;
EST, Expressed Sequence Tag.
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