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J Biol Chem, Vol. 274, Issue 50, 35455-35460, December 10, 1999
From the Institut für Arterioskleroseforschung and the Institut für Klinische Chemie und Laboratoriumsmedizin (Zentrallaboratorium) der Westfälischen Wilhelms-Universität Münster, D-48129 Münster, Germany
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Peroxisomal Peroxisomes catalyze essential reactions in a number of different
pathways and thus play an indispensable role in intermediary metabolism. Their importance is emphasized by the existence of a group
of disorders called peroxisomal diseases, caused by an impairment of
one or more peroxisomal functions. The cerebro-hepato-renal (Zellweger)
syndrome is generally considered to be the prototype of this group of
diseases. Zellweger patients show a large range of severe clinical
anomalies, often leading to early death (1). The catabolic pathways in
which peroxisomes are involved include the Sterol carrier protein-2
(SCP2)1 contains
a PTS1 peroxisomal targeting signal at its C terminus and the protein
is one of the most abundant proteins that is present in peroxisomes
(4). Despite this fact, no human inherited disease is known at present that is caused by SCP2 mutations. The SCP2 gene (Scp2) codes
not only for SCP2, but also for a fused protein of 60 kDa called sterol carrier protein-x (SCPx) (5, 6). The C-terminal domain of SCPx is
identical with SCP2 whereas its N-terminal part consists of an active
In contrast, relatively little is known about the precise roles of
SCP2. It has been shown that the protein binds acyl-CoAs (12, 13) and
forms specific complexes in peroxisomes with acyl-CoA oxidase and other
It has once been proposed that SCP2 functions in cytosolic cholesterol
transport in liver and adrenals by virtue of its ability to act as a
cholesterol carrier (16-18). Bile acid synthesis starts from
cholesterol and proceeds via a complex sequence of enzymatic steps that
are compartmentalized in cytoplasm, endoplasmic reticulum, mitochondria, and peroxisomes (19). Therefore, this pathway represents
the prototype that would depend on target-specific cholesterol
trafficking and thus on SCP2. In the present work, we therefore
investigated whether the Scp2 gene disruption affects bile
acid synthesis in vivo in order to elaborate more precise information about the roles of SCP2 and SCPx in metabolism.
Materials--
Most bile acid standards were obtained from Sigma
(Deisenhofen, Germany) except for the muricholic acids and oxo-bile
acids, which were purchased from Steraloids (Newport, RI). All nor-bile acids that were used in this study were synthesized by side chain degradation of the corresponding bile acids (20).
3 Serum Analysis of Bile Acids--
Internal standard
(nordeoxycholic acid, 250 ng) was added to 100 µl of serum followed
by simultaneous enzymatic hydrolysis and solvolysis at 45 °C for
3 h as described previously (24). Bile compounds were extracted
from the suspension using a Baker-bond RP-18 cartridge, which was
washed with 5 ml of water (pH = 3, equilibrated with hydrochloric
acid), cholesteryl esters were removed with 10 ml of petroleum ether
(b.p. 40-60 °C), and free cholesterol was removed with 8 ml of
petroleum ether/ethyl acetate 9:1 (v/v). The bound fraction was eluted
with 5 ml of methanol and 5 ml of diethyl ether. The solvents were
evaporated, and the residue containing the bile acids was derivatized
into the methyl esters with 1 M trimethylchlorosilane in
methanol (400 µl) at 60 °C for 30 min. After removal of excess
reagents, derivatization of the bile compounds into the trimethylsilyl
ethers was carried out using a solution of
pyridine/hexamethyldisilazane/trimethylchlorosilane (3:2:1, v/v/v; 200 µl) at 60 °C for 30 min. Excess reagents were evaporated and the
derivatives of the bile compounds were dissolved in 100 µl
n-hexane/pyridine (99:1, v/v). The mixture was sonicated and
centrifuged at 2000 × g for 3 min. 20 µl of the
supernatant were subjected to further analyses by GC-MS.
Gas Chromatography-Mass Spectrometry Analyses--
GC-MS was
performed on a Finnigan GCQ (Thermoquest, Egelsbach, Germany) equipped
with an ion trap mass analyzer and a HT-5 fused silica capillary column
(25 m, inner diameter 0.22 mm, film thickness 0.1 µm; SGE,
Weiterstadt, Germany). The sample was injected by the large volume
injection technique: after removal of the solvent at 50 °C followed
by ballistic temperature increase of the injection port to 280 °C.
The temperature of the column oven was maintained at 55 °C for 1 min
and increased with 30 °C/min to 280 °C. The parameters for the
ion trap mass analyzer were as follows: transfer line at 280 °C,
positive EI mode (70 eV), ion source at 200 °C, full scan on masses
100-700 Da; AGC target value 75. Helium was used as carrier gas with
30 cm/s. Bile compounds concentrations were quantified by comparing the
ion current response of the sum of characteristic quantitation masses
with the peak area response obtained for the known amount of the added
internal standard (nordeoxycholic acid) (25). Calculations were
performed with the GCQ data processing software 2.2.
Analyses of Bile Samples--
Murine bile was collected by
puncture of the gall bladder and analyzed according to a modification
of the method of Chijiiwa and Nakayama (26). Briefly, 10 µg of
epicoprostanol was added as internal standard per 5 µl of bile,
followed by protein precipitation with ethanol and enzymatic hydrolysis
with choloylglycine hydrolase. Bile acids were extracted with ethyl
acetate and derivatized into ethyl esters dimethylethylsilyl ethers.
Alternatively, derivatization into methyl esters trimethylsilyl ethers
was carried out as described above. 1 µl of the final sample was
analyzed by gas chromatography, performed on a SP-7100 (Spectra
Physics, Darmstadt, Germany) equipped with an flame ionization detector
and a SE54-CB fused silica capillary column (30 m, inner diameter 0.32 mm, film thickness 0.25 µm) (Chromatographic Service GmbH,
Langerwehe, Germany). The temperature of the column oven was maintained
at 100 °C for 1 min, then increased with 20 °C/min to 200 °C,
maintained for 5 min and finally increased with 5 °C/min to
280 °C. The temperature of the injection port and the detection unit
was at 300 °C. Helium at a flow rate of 1 ml/min was used as the
carrier gas. The split ratio was 1:10. Peak areas were calculated with
the MT2-Software (Kontron, Neufahrn, Germany) and compared with the
peak areas of the added internal epicoprostanol standard.
Murine Strains, Northern Blotting, and Statistical
Analyses--
Unless stated otherwise, 6-24-week-old male SCP2/SCPx
knockout mice (genetic background: C57Bl/6) were used (10). Age- and sex-matched C57Bl/6 mice served as controls. The mice were fed a
standard chow diet (Altrumin, Hanover, Germany) and water of pH 3.4 to
3.6 ad libitum. The cholestyramine diet consisted of standard chow supplemented with 2% (w/w) of cholestyramine (Sigma, Deisenhofen, Germany). Animals were kept individually, food intake and
body weights were monitored daily. Tissues were dissected routinely
between 9 and 10 a.m. (to exclude variations that may be due to
circadian regulation). Total RNA was isolated from mouse tissues with
the guandinium-thiocyanate-phenol-chloroform extraction procedure (27)
followed by selection of poly(A) RNA on oligi(dT)-cellulose. Northern
blots were hybridized with digoxigenin-labeled probes prepared by
random priming using a commercially available kit (Roche Molecular
Biochemicals, Mannheim, Germany). All probes were obtained from a mouse
liver cDNA library by polymerase chain reaction amplification with
appropriate primers. Quantification was carried out relative to
expression of gapdh, detected with a probe derived from a 1.3-kilobase
PstI fragment from pGAPDH (28) containing rat
glyceraldehyde-3-phosphate dehydrogenase cDNA. The membranes were
rinsed twice in 0.1% SDS, 2 × SSC at room temperature and then
twice in 1% SDS, 0.5 × SSC at 68 °C for 15 min. Bands were
visualized using the chemiluminescence substrate CDP-Star
(Tropix-Serva, Heidelberg, Germany). DNA sequencing was performed on an
automated laser fluorescence DNA sequencer (Amersham Pharmacia Biotech,
Upsala, Sweden) according to the instruction manual of the supplier.
Statistical analyses were performed with the paired t test.
Values of p Any abnormality leading to decreased production of bile acids is
likely to result in an up-regulation of the cholesterol
7
-oxidation plays an important role
in the metabolism of a wide range of substrates, including various
fatty acids and the steroid side chain in bile acid synthesis. Two
distinct thiolases have been implicated to function in peroxisomal
-oxidation: the long known 41-kDa -ketothiolase identified by
Hashimoto and co-workers (Hijikata, M., Ishii, N., Kagamiyama, H.,
Osumi, T., and Hashimoto, T. (1987) J. Biol. Chem.
262, 8151-8158) and the recently discovered 60-kDa SCPx thiolase, that
consists of an N-terminal domain with -ketothiolase activity and a
C-terminal moiety of sterol carrier protein-2 (SCP2, a lipid carrier or
transfer protein). Recently, gene targeting of the SCP2/SCPx gene has
shown in mice that the SCPx -ketothiolase is involved in peroxisomal -oxidation of 2-methyl-branched chain fatty acids like pristanic acid. In our present work we have investigated bile acid synthesis in
the SCP2/SCPx knockout mice. Specific inhibition of -oxidation at
the thiolytic cleavage step in bile acid synthesis is supported by our
finding of pronounced accumulation in bile and serum from the knockout
mice of 3
,7,12-trihydroxy-27-nor-5-cholestane-24-one (which
is a known bile alcohol derivative of the cholic acid synthetic intermediate 3,7,12-trihydroxy-24-keto-cholestanoyl-coenzyme A). Moreover, these mice have elevated concentrations of bile acids
with shortened side chains (i.e. 23-norcholic acid and
23-norchenodeoxycholic acid), which may be produced via - rather
than -oxidation. Our results demonstrate that the SCPx thiolase is
critical for -oxidation of the steroid side chain in conversion of
cholesterol into bile acids.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-oxidation of fatty
acids, the -oxidation of phytanic acid, the degradation of
glyoxylate and various xenobiotics. In addition, anabolic functions
contribute to the synthesis of ether phospholipids, docosahexaenoic
acid, bile acids, cholesterol, and other isoprenoids (2, 3).
-ketothiolase (7, 8). The two proteins are expressed from a common
gene via alternative transcription initiation at two separated
promoters (9). It was shown previously that SCPx is localized in
peroxisomes and that its -ketothiolase functions in a newly
identified peroxisomal -oxidation pathway that is involved in the
oxidation of 2-methyl-branched chain fatty acids like pristanic acid
(10). Conversely, the long known 41-kDa peroxisomal -ketothiolase
identified by Hashimoto and co-workers (11) acts preferentially on
straight very long chain substrates.
-oxidation enzymes (14). In addition, our previous data indicated
that peroxisomal -oxidation of phytanoyl-CoA is diminished in the
SCP2/SCPx knockout mice (10). These results imply that the protein may
play a role as substrate carrier or regulatory factor in peroxisomal
acyl-CoA metabolism. It was recently shown that the SCP2/SCPx gene
disruption is associated with activation of the peroxisome proliferator
activated receptor, PPAR (15), which suggests that SCP2 represents a
potentially important peroxisomal regulator of PPAR signal transduction.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
,7,12-Trihydroxy-27-nor-5-cholestane-24-one was
synthesized essentially as described in references (21, 22). All
solvents and high performance liquid chromatography-grade water were
obtained from Baker (Griesheim, Germany). Organic solvents were dried
over molecular sieves (Merck, Darmstadt, Germany, 0.4 nm).
Choloylglycine hydrolase (EC 3.5.1.24) from Clostridium perfringens, -glucoronidase (EC 3.2.1.31), and sulfatase (EC 3.1.6.1) from Helix pomatia and all other chemicals were of analytical grade and supplied by Sigma (Deisenhofen, Germany). Reverse-phase octadecylsilane bonded silica cartridges were purchased from Baker (Baker-bond RP-18, 3 ml, 500-mg beds). The cartridges were
washed with 5 ml of methanol and primed with 5 ml of water (pH = 3, equilibrated with hydrochloric acid) before use. Glassware was
silanized with 1% (v/v) dimethyldichlorosilane in toluene to prevent
adsorption of the bile acids (23).
0.05 were considered statistically significant.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-hydroxylase as a result of reduced negative feedback suppression
of this enzyme (29). To clarify whether this mechanism operates in
SCP2/SCPx knockout mice, we compared the expression of cholesterol
7-hydroxylase and mitochondrial cholesterol 27-hydroxylase in liver
from SCP2/SCPx knockout mice with C57Bl/6 controls. As is shown in Fig.
1, cholesterol 7-hydroxylase was
expressed ~4-fold higher in homozygous knockout mice than in C57Bl/6
controls. In contrast, no difference between the two strains could be
observed concerning the mitochondrial sterol 27-hydroxylase.
View larger version (14K):
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Fig. 1.
Expression of
cholesterol-7 -hydroxylase
(CYP7a) and sterol-27-hydroxylase
(CYP27) mRNA in liver from SCP2/SCPx
knockout mice and C57Bl/6 controls. Northern blot analyses with
poly(A)+ RNA from liver of SCP2/SCPx knockout
(KO) and C57Bl/6 control mice fed a standard chow diet were
performed as described under "Experimental Procedures." Northern
blots were probed with a labeled cholesterol-7-hydroxylase
(CYP7a) cDNA (top) or a sterol-27-hydroxylase
(CYP27) cDNA (bottom). Subsequently, the
blots were reprobed with a rat GAPDH cDNA to exclude lane loading
differences. The shown data are representative for eight mice of each
genotype (six males and two females). Signal intensities were evaluated
with a model BAS-KR 1500 bioimager (Raytest, Düsseldorf,
Germany). No difference was obtained for CYP27, whereas CYP7a
expression was 4-fold higher in the knockout mice compared with
controls.
Methyl ester-trimethylsilylether derivatives of bile acids and other
relevant compounds were analyzed by GC-MS in bile collected from
SCP2/SCPx knockout mice and age- and sex-matched C57Bl/6 controls. As
is shown in Fig. 2, all major bile acids,
including cholic acid and the three muricholic acids (, , and
), were present in bile from homozygous knockout mice. In addition,
the primary bile acid CDCA, which represents only a minor component of
murine bile, could be detected as ethyl ester-dimethylethylsilylether derivative in the samples from the knockout mice (data not shown). Based on an analysis including six mice in each experimental group, we
found that the mean biliary levels of bile acids were ~20% lower in
homozygotes compared with C57Bl/6 controls, although the differences
were not significant statistically. Moreover, the relative fractions of
the common bile acids did not differ significantly between both strains
(data not shown). We noted, however, two additional peaks in the
chromatograms from knockout bile (marked X1 and
X2 in Fig. 2). Both were detected in every sample from
homozygous transgenes but were nondetectable in heterozygotes or
C57Bl/6 controls. When homozygotes were treated with the bile acid
sequestrating drug cholestyramine, known to stimulate bile acid
synthesis, both peaks increased pronouncedly, whereas cholic acid
remained at a lower level in homozygotes compared with controls (Fig.
3). After 14 days of treatment with
cholestyramine, the two extra peaks did not appear in analyses with the
samples from C57Bl/6 controls (Fig. 3).
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The mass spectra that were obtained for both compounds are shown in
Fig. 4. They point to normal
3,7,12-hydroxylated ring structures that are combined with
abnormal side chains. Whereas the side chain of X1 appeared 14 mass
units smaller than the carboxymethylated side chain of cholic acid, it
was 2 mass units smaller in X2. Comparative analyses performed on
methyl ester-trimethylsilylether and ethyl
ester-dimethylethylsilylether modified biliary samples showed that X1
was an unusual bile acid whereas X2 lacked the carboxylic function and
thus represented an unusual bile alcohol (data not shown). Comparison
with a number of chemically synthesized standards led to the
identification of X1 as 23-NCA and X2 as 27-NC-24-one. Whereas 23-NCA
differs from cholic acid by lack of one methylene group in the side
chain, 27-NC-24-one represents an unusual bile alcohol carrying a
keto-function at C-atom 24, shortened by one methylene group compared
with trihydroxycholestane (Fig. 4).
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Due to small sample sizes and variable secretion rates of different
biliary constituents, analytical measurements of murine bile have
limitations. Therefore, we next performed analyses of bile acids and
the related alcohols in serum. On the basis of their mass spectra, we
identified 23-NCDCA and 23-NUDCA as additional nor-bile acids which
were present besides 23-NCA in sera but were absent from bile of
SCP2/SCPx knockout mice (Fig. 5). As
demonstrated in Fig. 6, the sera from
SCP2/SCPx knockout mice also contained high concentrations of
27-NC-24-one, which was not detected in C57Bl/6 controls. Conversely,
significantly lower concentrations of all common bile acids were found
in the knockout mice compared with C57Bl/6 controls. The decrease found
for cholic acid, CDCA, the muricholic acids (, , ), DCA, and
UDCA consisted of 40-60% (p < 0.001). In contrast,
extremely high concentrations of 23-NCA, 23-NCDCA, 23-NUDCA, and
27-NC-24-one could be demonstrated in SCP2/SCPx knockout mice treated
with cholestyramine (Fig. 6). Conversely, these compounds were
essentially absent from serum of identically treated C57Bl/6
controls.
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We did neither detect varanic acid, known to accumulate in patients
with D-peroxisomal bifunctional enzyme deficiency (30), nor
THCA, present in Zellweger disease (1), or complex bile alcohols
consisting of 27 C-atoms and cholestanol (known to accumulate in the
human disease cerebrotendinous xanthomatosis) (19) in bile or serum of
the knockout mice (data not shown).
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Our results show for the first time that the SCP2/SCPx gene is
critical for the synthesis of normal bile acids in vivo.
Although the sequence of enzymatic steps in bile acid synthesis are
diverse from different species, almost all mammals produce
7--hydroxylated bile acids that consist of 24 C-atoms (19). These
compounds play important roles in cholesterol and lipid metabolism,
intestinal lipid and vitamin absorption, and in diseases like
atherosclerosis, cholestatic liver disease, or gall stone formation.
Unlike in normal mice, a large fraction of bile acids consist of only
23 C-atoms (i.e. 23-NCA and 23-NCDCA) in SCP2/SCPx knockout
mice. These bile acids, which lack one methylene group from their side chains, accumulate preferentially in serum of chow- or
cholestyramine-fed knockout mice, whereas their concentrations in bile
are relatively low. Thus, it may be assumed that the 23-nor-bile acids
are less efficiently secreted in bile than their normal counterparts.
In particular, 23-NCDCA showed extremely high concentrations in serum, whereas it appeared much less prominent in bile. This is in line with
previous data showing that 23-NCA and 23-NCDCA are conjugated ineffectively in rats (31, 32). Moreover, hepatic uptake and secretion
into bile of 23-NCA was shown to be much lower compared with cholic
acid in the perfused rat liver (33).
23-Nor-bile acids are most likely produced via -oxidation from their
normal counterparts. It has been shown that 23-hydroxylated cholic acid
and CDCA are converted rapidly to the respective 23-nor-bile acids in
several rodents (34). Increased 23-hydroxylation has also been shown in
human patients with cerebrotendinous xanthomatosis who have elevated
concentrations of 23-nor-bile acids (35). Cerebrotendinous
xanthomatosis is caused by defective sterol-27-hydroxylation, catalyzed
by a mitochondrial enzyme that belongs to the cytochrome P-450 family.
Because the defect leads to a block in normal -oxidation of the side
chain located prior to the peroxisomal import of THCA-CoA, it differs
clearly from the situation in the SCP2/SCPx knockout mice.
Nevertheless, induction of -oxidation, leading to synthesis of
23-nor-derivatives, may represent a more general mechanism of
compensation that could be associated with inefficient -oxidation of
the steroid side chain. It appears, however, interesting to us that
23-nor-bile acids were apparently absent from sterol-27-hydroxylase knockout mice (29), which suggests that their production is regulated
differently in human and mice.
Besides the 23-nor-bile acids, we detected accumulation of high amounts
of 27-NC-24-one in SCP2/SCPx knockout mice. For a number of reasons, we
think that this unusual bile alcohol originates from peroxisomal
metabolism of THCA-CoA. During normal bile acid synthesis, the
reduction from 27 to 24 C-atoms takes place in peroxisomes via removal
of one unit of propionic acid from the side chain of THCA-CoA in one
cycle of -oxidation (compare Fig. 7
for a schematic illustration of peroxisomal bile acid metabolism). Model analyses have shown that 27-NC-24-one is formed readily via
spontaneous decarboxylation from
3,7,12-trihydroxy-24-keto-cholestanoic acid (22), which comes
from the expected biosynthetic cholic acid intermediate
3,7,12-trihydroxy-24-keto-cholestanoyl-CoA. 27-NC-24-one has
been found in an earlier study besides varanic acid and
3,7,12-trihydroxy-
24-cholestenoic acid in a human patient
who may have had thiolase deficiency (36). Thus, we think that our
results show convincingly that side chain oxidation is inhibited
in vivo in SCP2/SCPx knockout mice at the thiolytic step
that takes place in peroxisomal -oxidation of THCA-CoA. This leads
us to conclude that the thiolase that is associated with SCPx is
essential for the thiolytic step involved in bile acid synthesis.
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In a previous study, we showed that the SCP2/SCPx knockout mice have a
defect in peroxisomal - and -methyl-branched fatty acid
metabolism (10). The metabolic block occurred at two levels of
peroxisomal metabolism: first, inefficient -oxidation, presumably via inhibition of import of 3-methyl-branched fatty acids into peroxisomes, and second, inhibition of the thiolytic cleavage of the
2-methylated 3-ketoacyl-CoA derivatives. The structures of these 3-keto
substrates are in fact very similar as the 24-keto substituted steroid
side chain that is present in
3,7,12-trihydroxy-24-keto-cholestanoic acid. Thus, it appears
plausible to us that both substrates use the same thiolase for their
-oxidation. This conclusion is furthermore in accordance with the
substrate specificity that has been studied in vitro for the
recombinant rat SCPx protein (37-39). In contrast, the substrate for
peroxisomal -oxidation, which is THCA, did not accumulate in
SCP2/SCPx knockout mice. This negative finding shows that import of
THCA-CoA into peroxisomes may not depend on the presence of SCP2 or
SCPx. Alternatively, accumulation of THCA may be prevented by induction
of efficient alternative side chain oxidation pathways. Such
extraperoxisomal pathways could also explain why SCP2/SCPx knockout
mice are still capable of synthesizing normal bile acids. One known
alternative side chain oxidation pathway that is active in mice is the
microsomal 25-hydroxylase pathway (19). This or a 24-hydroxylase
pathway was made previously responsible for residual bile acid
synthesis in sterol 27-hydroxylase knockout mice (29). Alternatively,
the long known 41-kDa peroxisomal -ketothiolase identified by
Hashimoto and co-workers (11) could be responsible for the residual
synthesis of normal bile acids in the SCP2/SCPx knockout mice. Although
this enzyme is known to act preferentially on straight very long chain
fatty acid substrates (37), it cannot be excluded that overlap of
substrate specificity exists between the two peroxisomal thiolases.
The hydroxylation steps which occur at the -cholestane nucleus are
apparently not affected in our model. We think that this is an
interesting finding, because SCP2, which is missing in the model, has
once been proposed to act as cytoplasmic cholesterol carrier (16-18).
Considering the physicochemical properties and asymmetric intracellular
distribution of cholesterol one would expect that target-specific
intracellular cholesterol transport would be required for bile acid
synthesis. According to current concepts, the initial steps that use
cholesterol as the substrate proceed via two alternative pathways. The
first and presumably major pathway consists of 7-hydroxylation of
cholesterol catalyzed by cholesterol-7-hydroxylase (called CYP7a) at
the endoplasmic reticulum (19). The second, which is called the acidic
pathway, is initiated by 27-hydroxylation of cholesterol in
mitochondria and the 7-hydroxylation step proceeds later via a newly
identified oxysterol 7-hydroxylase called CYP7b1 (40-42). Thus, the
recent studies showed that there are two enzymes that are capable of 7-hydroxylation, the classical cholesterol 7-hydroxylase, and the
newly identified oxysterol 7-hydroxylase. The precise metabolic consequences in mice of inhibition of either pathway became evident from the recent characterization of CYP7a and sterol 27-hydroxylase knockout mice (29, 40, 43). In our study, we show that the abnormalities in bile acid synthesis of the SCP2/SCPx knockout mice are
clearly distinct from those that have been described for the two other
models. Therefore, we presume that the hypothetical function of SCP2
and SCPx as cytosolic cholesterol carrier may either be masked by
efficient compensatory mechanisms in our model or that this function is
not essential for murine bile acid synthesis in vivo.
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ACKNOWLEDGEMENTS |
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We thank Renate Kokott and Barbara Glass for expert technical assistance.
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FOOTNOTES |
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* This work was supported by Deutsche Forschungsgemeinschaft Grant Se 459/2-3 (to U. S.) and by the Interdisziplinäres Klinisches Forschungszentrum of the Medical Faculty, University of Münster (Project A4).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.
To whom correspondence should be addressed: Institut für
Arterioskleroseforschung, Domagkstr. 3, 48149 Münster, Germany. Tel.: 49-251-8356197; Fax:
49-251-8355187; E-mail: seedorfu@uni-muenster.de.
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ABBREVIATIONS |
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The abbreviations used are:
SCP, sterol carrier
protein;
CA, cholic acid;
23-NCA, 23-norcholic acid;
CDCA, chenodeoxycholic acid;
UDCA, ursodeoxycholic acid;
23-NCDCA, 23-norchenodeoxycholic acid;
23-NUDCA, 23-norursodeoxycholic acid;
27-NC-24-one, 3,7,12-trihydroxy-27-nor-5-cholestane-24-one;
CoA, coenzyme A;
DCA, deoxycholic acid;
GC-MS, gas chromatography-mass
spectrometry;
THCA, 3,7,12-trihydroxycholestanoic acid.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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