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Previous Article | Next Article 
J Bacteriol, February 1998, p. 690-698, Vol. 180, No. 3
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Genetic Evaluation of Physiological Functions of Thiolase
Isozymes in the n-Alkane-Assimilating Yeast
Candida tropicalis
Naoki
Kanayama,
Mitsuyoshi
Ueda,
Haruyuki
Atomi, and
Atsuo
Tanaka*
Laboratory of Applied Biological Chemistry,
Department of Synthetic Chemistry and Biological Chemistry,
Graduate School of Engineering, Kyoto University, Yoshida,
Sakyo-ku, Kyoto 606-01, Japan
Received 2 September 1997/Accepted 5 December 1997
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ABSTRACT |
The n-alkane-assimilating diploid yeast Candida
tropicalis possesses three thiolase isozymes encoded by two pairs
of alleles: cytosolic and peroxisomal acetoacetyl-coenzyme A (CoA)
thiolases, encoded by CT-T1A and CT-T1B, and
peroxisomal 3-ketoacyl-CoA thiolase, encoded by CT-T3A and
CT-T3B. The physiological functions of these thiolases have
been examined by gene disruption. The homozygous ct-t1a
/t1b null mutation abolished the activity of
acetoacetyl-CoA thiolase and resulted in mevalonate auxotrophy. The
homozygous ct-t3a/t3b null mutation abolished the
activity of 3-ketoacyl-CoA thiolase and resulted in growth deficiency
on n-alkanes (C10 to C13). All
thiolase activities in this yeast disappeared with the ct-t1a/t1b and ct-t3a/t3b null
mutations. To further clarify the function of peroxisomal
acetoacetyl-CoA thiolases, the site-directed mutation leading
acetoacetyl-CoA thiolase without a putative C-terminal peroxisomal
targeting signal was introduced on the CT-T1A locus in the
ct-t1b null mutant. The truncated acetoacetyl-CoA
thiolase was solely present in cytoplasm, and the absence of
acetoacetyl-CoA thiolase in peroxisomes had no effect on growth on all
carbon sources employed. Growth on butyrate was not affected by a lack of peroxisomal acetoacetyl-CoA thiolase, while a retardation of growth
by a lack of peroxisomal 3-ketoacyl-CoA thiolase was observed. A defect
of both peroxisomal isozymes completely inhibited growth on butyrate.
These results demonstrated that cytosolic acetoacetyl-CoA thiolase
was indispensable for the mevalonate pathway and that both
peroxisomal acetoacetyl-CoA thiolase and 3-ketoacyl-CoA
thiolase could participate in peroxisomal 
-oxidation. In addition to
its essential contribution to the -oxidation of longer-chain fatty acids, 3-ketoacyl-CoA thiolase contributed greatly even to the -oxidation of a C4 substrate butyrate.
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INTRODUCTION |
Candida tropicalis is an
asporogenic diploid yeast which can utilize n-alkanes as a
carbon source. The most striking feature of this yeast is profound
proliferation of peroxisomes, ubiquitous organelles in eukaryotic
cells, in growth on specific carbon sources such as
n-alkanes and fatty acids (37). Peroxisomal
proteins, including fatty-acid -oxidation enzymes, are induced, as
well as proliferation of peroxisomes (19, 28).
Thiolase catalyzes the thiolytic cleavage of 3-ketoacyl-coenzyme A
(CoA) to acetyl-CoA and acyl-CoA, and this enzyme is classified into
two types by substrate specificity. One type is acetoacetyl-CoA thiolase (EC 2.3.1.9), which catalyzes the thiolytic cleavage of
acetoacetyl-CoA and the reverse condensation of acetyl-CoA. The other
is 3-ketoacyl-CoA thiolase (EC 2.3.1.16), which has broad substrate
specificity for 3-ketoacyl-CoAs in carbon length (
C4). In
bacterial cells, 3-ketoacyl-CoA thiolase takes part in fatty-acid
-oxidation (7) and acetoacetyl-CoA thiolase takes part in
poly--hydroxybutyrate metabolism (36, 42). In eukaryotic
cells, especially in mammalian cells, thiolases exhibit diversity in
intracellular localization related to their metabolic functions as well
as in substrate specificity. For example, they contribute to fatty-acid
-oxidation in peroxisomes and mitochondria (31, 34, 46,
49), ketone body metabolism in mitochondria (31), and
the early steps of mevalonate pathway in peroxisomes and cytoplasm
(11, 31, 48). In addition to biochemical investigations, analyses of genetic disorders have made clear the basis of their functions (33, 41). Genetic studies have also started to
disclose the physiological functions of thiolases in the yeast
Saccharomyces cerevisiae (10, 12).
In C. tropicalis pK233, there are at least three
thiolase isozymes, cytosolic acetoacetyl-CoA thiolase (Cs-Thiolase I),
peroxisomal acetoacetyl-CoA thiolase (Ps-Thiolase I), and peroxisomal
3-ketoacyl-CoA thiolase (Thiolase III) (23, 24, 26).
Ps-Thiolase I and Thiolase III are each encoded by two extremely
similar genes (CT-T1A and CT-T1B for Ps-Thiolase
I, and CT-T3A and CT-T3B for Thiolase III)
(17, 27). Recently, we have reported that Cs-Thiolase I and
Ps-Thiolase I are derived from the same genes (18). As for
individual roles of these isozymes in the metabolism of fatty acids,
the exclusive localization of -oxidation in peroxisomes and the
inductive expression of peroxisomal isozymes led us to presume that
Ps-Thiolase I and Thiolase III participate in peroxisomal -oxidation, whereas the constitutive localization of Cs-Thiolase I
in cytoplasm suggests that Cs-Thiolase I has a role in the mevalonate pathway (19, 25, 26, 51). Information about the
physiological roles of thiolase isozymes will be a clue to
understanding the evolution of the -oxidation system and the
regulation of peroxisomal -oxidation. The mechanism of sorting of
Thiolase I to two intracellular locations is also important with
respect to the metabolic functions of Thiolase I.
In the present study, in order to genetically evaluate the
physiological functions of these thiolase isozymes in C. tropicalis, we disrupted their genes and altered the localization
of Thiolase I by the deletion of its putative peroxisomal targeting
signal sequence. The growth phenotype of strains carrying various
combinations of mutations on thiolase genes enabled us to understand
the functions of thiolase isozymes.
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MATERIALS AND METHODS |
Strains and growth conditions.
C. tropicalis
strains used in this study are classified into representative and
intermediate strains and are listed in Table 1 (see also Fig.
1). C. tropicalis SU-2
(ATCC 20913) (ura3a/ura3b) (9), derived from
C. tropicalis pK233 (ATCC 20336), was used as a
wild-type strain and as a host strain for transformation. Escherichia coli DH5
(3) was used for gene
manipulation. S. cerevisiae MT8-1 (MATa
ade his3 leu2 trp1 ura3) (47) was used as a host
strain for the cloning of C. tropicalis URA3. Media for
genetic experiments with C. tropicalis were as follows: YPD (10 g of yeast extract [Difco]/liter, 20 g of peptone
[Difco]/liter, and 20 g of glucose/liter), SD (6.7 g of yeast
nitrogen base without amino acid [Difco]/liter and 20 g of
glucose/liter), SD+U (SD supplemented with 0.1 g of uracil/liter,
0.1 g of uridine/liter, and 0.1 g of UMP/liter), and SD+S (SD
containing 1 M sorbitol). L-Mevalonolactone
[(R)-(
)-3-hydroxy-3-methyl-5-pentanolide; Wako, Osaka,
Japan] (5 g/liter) was used to supplement YPD, SD+U, and SD+S, if
necessary.
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FIG. 1.
Illustration of subcellular distribution of thiolase
isozymes in wild-type and representative mutant strains prepared in
this study. The presence or absence of each of the four thiolase genes
(T1A/T1B T3A/T3B) in each strain is shown by plus or minus
signs in parentheses. Outer and inner circles represent the yeast cell
and peroxisome, respectively. Abbreviations: T1, Ps- or Cs-Thiolase I;
T3, Thiolase III; T1C, C-terminal-truncated Thiolase I.
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C. tropicalis was cultivated aerobically at 30°C in a
medium containing glucose (16.5 g/liter), glycerol (20 g/liter),
ethanol (20 ml/liter), sodium propionate (10 g/liter), sodium butyrate (11 g/liter), or n-alkane mixture (C10 to
C13) (10 ml/liter) as a sole carbon source (25,
50). The pH was adjusted to 5.2 for glucose-, glycerol-,
ethanol-, or n-alkane-containing medium and to 6.0 for
propionate- or butyrate-containing medium. Tween 80 (0.5 g/liter) was
added to n-alkane medium used for preparation of cell
extracts and for subcellular fractionation. Supplemental nutrients were
added as described above, if necessary. Cell growth was monitored by
measuring light scattering at 570 nm.
Cloning and sequencing of C. tropicalis URA3.
To
make a minimal genomic DNA library of C. tropicalis
(5, 35), genomic DNA of C. tropicalis was
digested with NcoI and fractionated in size by 0.5% agarose
gel electrophoresis. A fraction containing 6- to 9-kbp DNA fragments
was cloned into the NcoI site of the E. coli-S.
cerevisiae shuttle vector pMW1 containing the TRP1
selectable marker (16), which was modified to have an
NcoI site in multicloning sites. This genomic DNA library
was introduced into a uracil-auxotrophic (Ura
) strain,
S. cerevisiae MT8-1, by the electroporation method
(30). Six uracil prototrophs (Ura+) were
obtained from 4.5 × 104 tryptophan-prototrophic
(Trp+) transformants. Plasmids were recovered from
Ura+ Trp+ candidates. The plasmids contained a
7-kbp fragment, in which a 1.7-kbp BglII fragment was enough
to complement ura3 of S. cerevisiae MT8-1.
Sequence analysis of the BglII fragment indicated that this
fragment contained an 801-base open reading frame, and the deduced
amino acid sequence exhibited high similarity to Ura3p's from various
organisms (data not shown). Sequence analysis was carried out with a
PRISM DyeDeoxy Terminator Cycle Sequencing Kit and a DNA sequencer
(model 373A; Applied Biosystems). The 1.7-kb C. tropicalis
URA3 was subcloned into the BamHI site of pUC19 and
into the BglII site of the modified pUC19, where a
BglII linker was inserted in the SmaI site (the
subclones were named pUC-URA3 and pUC-URA3Bg, respectively), and was
used for the construction of disruption cassettes as described below.
Construction of disruption cassettes of thiolase isozyme
genes.
To disrupt multiple thiolase genes by using the
URA3 selectable marker in C. tropicalis SU-2
(uracil auxotrophy), the Ura-blasting procedure was applied
(2). In this procedure, URA3 was placed between
two directly repeated sequences in a disruption cassette (see Fig. 2).
The 1.9-kb part of lacZ (EcoRV-EcoRI
fragment) was used as a repeated sequence. Two lacZ
fragments were inserted stepwise into pUC-URA3, one in the
SmaI site and one in the XbaI site, and all the
ends of the fragments were filled with T4 DNA polymerase. Thus a
plasmid, pZUZ, containing the lacZ-URA3-lacZ module was
constructed.
pT16BE and pT16B contain the coding and flanking regions of
CT-T1A, and pT18B contains those of CT-T1B
(18, 27). pT37Bg, carrying the coding and flanking regions
of CT-T3A, and pT30Bg, carrying those of CT-T3B,
were constructed by insertion of the BglII fragments of
CT-KCT-A and CT-KCT-B (17) into the modified pUC19
where a BglII linker was inserted into the HincII
site and where the EcoRI site was deleted,
respectively. EcoRI-SalI fragments (1,400 bp) of
pT16B and pT18B were replaced with the lacZ-URA3-lacZ fragment (5,500 bp), which was excised from pZUZ by EcoRI
and SalI. The EcoRI-KpnI (600 bp)
fragments of pT37Bg and pT30Bg were replaced with the
lacZ-URA3-lacZ fragment after the KpnI
sites of pT37Bg and pT30Bg had been filled and ligated with a
SalI linker, respectively. After a BglII linker
was inserted into the EcoRV site of pT16BE, the
EcoRV-BglII fragment (500 bp) of pT16BE was replaced with the BglII fragment (1,700 bp) of
URA3 excised from pUC-URA3Bg. These constructs were named
pT16B::ZUZ, pT18B::ZUZ, pT37Bg::ZUZ,
pT30Bg::ZUZ, and pT16BE::U, respectively (see Fig. 2). Before these disruption cassettes were used for transformation, pT16BE::U was linearized with BamHI and
EcoRI, pT16B::ZUZ and pT18B::ZUZ were
linearized with BamHI, and pT37Bg::ZUZ and
pT30Bg::ZUZ were linearized with BglII.
Transformation of C. tropicalis by the
spheroplast method.
The spheroplast method developed for S. cerevisiae (4) was applied to the transformation of
C. tropicalis with a slight modification: cells were
lysed in 20 ml of KPE (1 M sorbitol, 10 mM potassium phosphate buffer
[pH 7.2], and 10 mM EDTA) containing 40 µl of mercaptoethanol and
150 µl of Zymolyase 20T solution (10 mg in 1 ml of KPE) at 30°C for
15 min. After 2 to 4 days of incubation of cells transformed by this
modified method at 30°C, Ura+ cells formed colonies on
selective media at a frequency of approximately 103
colonies/µg of DNA. In order to pop out URA3,
Ura+ cells in which the disruption cassette containing
lacZ-URA3-lacZ had been integrated were inoculated on a
minimal medium containing 5-fluoroorotic acid (5FOA) (SD+U containing
0.75 g of 5FOA/liter) at 30°C for 3 to 4 days. 5FOA-resistant
colonies were used as host cells for the next round of transformation.
These cells were subjected to Southern blot analysis and PCR at each
stage of the process.
Construction of a Thiolase IA mutant with the C terminus
deleted.
A site-directed mutation on CT-T1A was
generated by PCR (13). PCR conditions were as follows:
template, 50 pmol of primers, 0.2 mM deoxynucleoside triphosphates, 1×
reaction buffer (supplied by the vendor), and 5 U of Pfu DNA
polymerase (Stratagene, La Jolla, Calif.). Primers used were as
follows: PRT1AN1, 5'-AACCATGGACGACGTCGTTATCG-3'; PRT1AD1,
5'-CTTGGCGTCGGTTTAAATCTTTTCA-3'; PRT1Cl,
5'-GTGCCGAATCGATGTCTAACA-3'; and M13 reverse,
5'-CAGGAAACAGCTATGAC-3'.
First, two sets of PCR were carried out with two primers each, one set
with PRT1AN and PRT1AD1 and the other with PRT1Cl and M13 reverse.
pT16B (18) was used as a template. After the heteroduplex of
two PCR products was formed, the second round of PCR was carried out
with PRT1AN1 and M13 reverse. The amplified fragment was digested with
BglII and SacI and was cloned into the
BamHI and SacI sites of pUC-URA3, with a
BamHI linker inserted in the SmaI site. The plasmid was named pUT1A. The inserted fragment was sequenced to
check whether mutagenesis and PCR had been correctly performed.
The scheme for introducing the mutation on a chromosome by homologous
recombination (40) is shown below (see Fig. 6C). pUT1A was linearized with NcoI prior to its use in transformation.
After pUT1A was integrated into CT-T1A on the chromosome,
URA3 and vector parts were popped out by 5FOA selection as
described above. Subsequently, the desired strain carrying the mutation
on CT-T1A was selected from Ura candidates by
Southern blot analysis.
Preparation of cell extracts.
Yeast cells were cultivated in
10 ml of each medium and harvested at mid-logarithmic phase. Cells were
suspended in 500 µl of 50 mM potassium phosphate buffer (pH 7.2)
containing 10% (wt/vol) glycerol, 1 mM dithiothreitol, and protease
inhibitors (0.2 mM phenylmethylsulfonyl fluoride, 1 mM EDTA, 0.05 g of pepstatin A/liter, 0.05 g of leupeptin/liter, 0.05 g of
antipain/liter, and 0.05 g of chymostatin/liter) and were
disintegrated by vortexing with 0.3 g of glass beads (diameter,
0.4 to 0.45 mm) in a microtube. Cell extracts were obtained by
centrifugation at 14,000 × g for 20 min at 0°C.
Other methods.
Thiolase activity was assayed by monitoring
acetoacetyl-CoA or 3-ketooctanoyl-CoA degradation as reported by
Kurihara et al. (23). The protein concentration was
determined by the Lowry method (29). Subcellular
fractionation (51), Western blot analysis (52),
and Southern blot analysis (27) were carried out as
described previously. General methods for gene manipulation and yeast
genetics were used as described in general protocols (3,
14).
Nucleotide sequence accession number.
The nucleotide
sequence of C. tropicalis URA3 has been assigned
GenBank/EMBL/DDBJ accession no. AB006207.
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RESULTS |
Development of disruptants of thiolase isozymes.
In order
to genetically evaluate the physiological functions of thiolase
isozymes in C. tropicalis, two pairs of genes for thiolase isozymes were individually disrupted. C. tropicalis URA3 was cloned to construct disruption cassettes for
thiolase isozyme genes with the Ura-blasting procedure (Fig. 1)
(see also Materials and Methods) (2).
First, we disrupted a single gene among the four thiolase genes.
Strains K6ZUZ, K8ZUZ, K7ZUZ, and K0ZUZ were obtained as
Ura+ transformants from the wild-type strain C. tropicalis SU-2 (9, 38) by using disruption cassettes
pT16B::ZUZ, pT18::ZUZ, pT37Bg::ZUZ, and pT30Bg::ZUZ (Fig. 2),
respectively. Following selection of Ura segregants on
the basis of resistance to 5FOA, strains K6, K8, K7, and K0 were
obtained. Southern blot analysis indicated that the desired chromosomal
regions were correctly replaced with lacZ-URA3-lacZ in
K6ZUZ, K8ZUZ, K7ZUZ, and K0ZUZ and that URA3 was eliminated in K6, K8, K7, and K0 by the 5FOA treatment (data not shown). Compared
with thiolase genes in the wild-type strain, SU-2, the increased size
of each disrupted thiolase gene on a Southern blot also showed that the
first round of transformation was successful (Fig.
3). The shift of each band, or the
disappearance of a band at the position seen in the SU-2 lane, revealed
that each gene was present as a single copy, suggesting that the almost
identical A and B genes were allelic in the diploid yeast C. tropicalis. Therefore, we can regard K6 and K8 as the hemizygous
CT-T1A/T1B null mutants and K7 and K0 as the hemizygous
CT-T3A/T3B null mutants.
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FIG. 2.
Physical maps of thiolase isozyme genes and
disruption cassettes, and disruption strategies. Horizontal arrows
indicate the orientation of transcription. Vertical arrows indicate the
popping out of the lacZ-URA3-lacZ cassette. A boxed region
of each thiolase gene shows the open reading frame. Restriction sites:
Ba, BamHI; Bg, BglII; EI, EcoRI; EV,
EcoRV; H, HindIII; K, KpnI; S,
SalI.
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FIG. 3.
Southern blot analysis of mutant strains derived from
C. tropicalis SU-2. Genomic DNA was digested with
EcoRI and BamHI (A and B) and with
EcoRI, BamHI, and BanIII (C). The
blots were probed with biotin-labeled cDNA of Ps-Thiolase I
(28) (A and C) or Thiolase III (17) (B). Panels A
and B are the same blot in each lane. The presence or absence of each
thiolase gene is indicated as explained for Fig. 1. The genotype
corresponding to each band is given in the key. Asterisk, nonspecific
signal.
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Second, the homozygous ct-t1a/t1b null mutant and the
homozygous ct-t3a/t3b null mutant were developed from
K8 and K7, respectively. Cs-Thiolase I is expected to have a role in
the mevalonate pathway. The ct-t1a/t1b mutant,
therefore, was expected to show mevalonate auxotrophy. Thus, in the
selection of this mutant, L-mevalonolactone was included in
the selective medium. However, the disruption using pT16::ZUZ was
not successful despite the use of the medium containing
L-mevalonolactone. Consequently, an improved disruption
cassette for CT-T1A, pT16BE::U, was constructed (Fig.
2), in which one of two regions homologous to CT-T1A was exchanged with the region eliminated in the CT-T1B locus in
K8 after the first round of transformation. Using this vector, we successfully disrupted CT-T1A to obtain the
ct-t1a/t1b mutant K68U as shown on a Southern blot
(Fig. 3). The ct-t3a/t3b mutant K70 was developed from
K7 by using pT30::ZUZ, followed by the elimination of
URA3 (Fig. 3).
Third, to obtain the homozygous ct-t1a/t1b
ct-t3a/t3b null mutant K6870U, K70 was transformed by the
same method that was applied to develop K68U from SU-2.
K870ZUZ and K870 were obtained as intermediate strains. In K6870U, all
bands of the genes encoding thiolase isozymes shifted in size (Fig.
3), revealing the correct disruption of all four genes.
Expression of thiolase isozymes in mutant strains.
Development of a series of disruptants enabled us to examine the
expression level of each isozyme and its contribution to thiolase activity in the cells. The expression of Thiolase I's and
Thiolase III in disruptants was monitored by thiolase activity and
Western blot analysis (Fig. 4 and 5).
According to substrate specificity, the activity of Thiolase I's was
represented mainly by the degradation of acetoacetyl-CoA and the
activity of Thiolase III was represented exactly by the degradation of
3-ketooctanoyl-CoA (23, 24).
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FIG. 4.
Thiolase activities of mutants for acetoacetyl-CoA (A)
and 3-ketooctanoyl-CoA (B). The activities for acetoacetyl-CoA and
3-ketooctanoyl-CoA represent the activities of Thiolase I and Thiolase
III, respectively. The presence or absence of each thiolase gene is
indicated as explained for Fig. 1. Carbon sources for growth are
displayed.
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In the hemizygous CT-T1A/T1B null mutants, K6 and K8, the
thiolase activity for acetoacetyl-CoA was half that of the wild-type strain, SU-2, on all carbon sources tested (Fig. 4A). Also, in the
hemizygous CT-T3A/T3B null mutants, K7 and K0, the activity for 3-ketooctanoyl-CoA was half of that in SU-2 when these strains were
grown on n-alkanes and butyrate (Fig. 4B). The band
intensities of Thiolase I and Thiolase III in Western blot analysis
paralleled the levels of thiolase activity in the wild-type and
disruptant strains (Fig. 5). These
results indicated that the expression of the A and B genes of Thiolase
I and Thiolase III contributed equally to total intracellular thiolase
activity and that their regulation in response to the carbon source was
identical. These results confirmed that the A and B genes of both
Thiolase I and Thiolase III were allelic. As for the homozygous null
mutants, no thiolase activity for acetoacetyl-CoA was detected in the
ct-t1a/1b mutant K68U grown on glucose (Fig. 4A).
Residual activity for acetoacetyl-CoA was detected in K68U cells grown
on n-alkanes and butyrate, but it was supposed to be the
contribution of Thiolase III, which shows broad-chain-length
specificity. This is strongly supported by the fact that this residual
activity was abolished in the ct-t1a/t1b
ct-t3a/t3b mutant K6870U (Fig. 4A). There was no protein
detected by anti-Thiolase I antiserum in K68U grown on any of the
carbon sources tested (Fig. 5A). No thiolase activity for
3-ketooctanoyl-CoA was detected in the ct-t3a/t3b
mutant K70 grown on n-alkanes and butyrate (Fig. 4B), and no
band was detected by anti-Thiolase III antiserum in K70 (Fig. 5B).
Furthermore, in K6870U, no thiolase activity was found in the cells
(Fig. 4A) and no protein was recognized by either anti-Thiolase I or
anti-Thiolase III antiserum (data not shown) (see Fig. 5), indicating
that in C. tropicalis there are only three thiolase
isozymes encoded by the two pairs of alleles, as we have previously
suggested (17, 27).
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FIG. 5.
Western blot analysis of various Thiolase I (A) and
Thiolase III (B) mutant strains. Aliquots of 50 µg (glucose) and 25 µg (n-alkane and butyrate) (A) and 20 µg (B) of cell
extracts were run on gels. Thiolase I and Thiolase III were detected
with anti-Ps-Thiolase I and anti-Thiolase III antiserum, respectively.
The presence or absence of each thiolase gene is indicated as explained
for Fig. 1. Carbon sources for growth are displayed. Thiolase IC6,
C-terminus-truncated mutant of Thiolase I.
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Development of the strains expressing the C-terminus-truncated
protein of Thiolase I.
Compared with the amino acid sequences of
acetoacetyl-CoA thiolases of other organisms, only Thiolase I of
C. tropicalis has an additional 6 amino acid residues
at the C terminus: DADAKL for Thiolase IA encoded by CT-T1A and DSDAKL
for Thiolase IB encoded by CT-T1B, in which there is a putative motif
of peroxisomal targeting signal type I (PTS1) (8, 27)
(Fig. 6A). In order to investigate whether this sequence functions as a PTS1 and, furthermore, to distinguish the physiological roles of Cs- and Ps-Thiolase I's, we
developed two further strains, K8 (CT-T1AC6/ct-t1b
CT-T3A/CT-T3B) and K870 (CT-T1AC6/ct-t1b
ct-t3a/ct-t3b). These strains express only the
C-terminus-truncated Thiolase I with and without Thiolase III,
respectively. A nonsense codon was introduced into CT-T1A to
delete the C-terminal 6 amino acids of Thiolase I by site-directed mutagenesis (Fig. 6B). A DraI restriction site was also
introduced as a marker for this mutation, and then a mutation cassette,
pUT1A, was constructed. By using this cassette, these mutations were incorporated on the CT-T1A locus in K8 and K870 (Fig. 6C).
Southern blot analysis showed that the CT-T1A locus in both
K8 and K870 could be digested by DraI although
BamHI-EcoRI fragments were identical to that of
the wild type in size, indicating that the mutation was correctly
introduced onto the CT-T1A locus in these strains (Fig. 3).
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FIG. 6.
(A) Comparison of C-terminal domains of acetoacetyl-CoA
thiolases from various sources. The boxed residue is the catalytically
important Cys in this domain. Abbreviations: Thiolase IA, C. tropicalis acetoacetyl-CoA thiolase encoded by CT-T1A; SCCACT,
S. cerevisiae cytosolic acetoacetyl-CoA thiolase; HCACT,
human cytosolic acetoacetyl-CoA thiolase; RCACT, radish cytosolic
acetoacetyl-CoA thiolase; RMACT, rat mitochondrial acetoacetyl-CoA
thiolase; ZRACT, Zooglea ramigera acetoacetyl-CoA thiolase.
Amino acid sequences were retrieved from GenBank/EMBL/DDBJ as accession
no. D13470 for Thiolase IA, L20428 for SCCACT, S70154 for HCACT, X78116
for RCACT, D00511 for RMACT, and J02631 for ZRACT. (B) Strategy for
deletion of a putative peroxisomal targeting signal of Thiolase I by
site-directed mutagenesis. Open box, DraI site. (C) Strategy
for the introduction of the site-directed mutation on the
CT-T1A locus. Restriction sites: Ba,
BamHI; Bg, BglII; E,
EcoRI; N, NcoI; Sa,
SacI.
|
|
The expression and subcellular localization of the C-terminus-truncated
Thiolase I in K8 were examined. The truncated Thiolase I was
expressed as a slightly smaller protein than the wild-type Thiolase I
(Fig. 5A). The thiolase activity for acetoacetyl-CoA and the band
intensity of Thiolase I in K8 were essentially identical to those in
the parent strain, K8, on all carbon sources tested (Fig. 4A and 5A).
These results revealed that the C-terminal 6 amino acid residues of
Thiolase I did not have any function for the enzymatic activity of
Thiolase I and that this truncated protein was present in a completely
active form. The truncated protein was also expressed in K870 (data
not shown). The postnuclear supernatant fractions (S1) of
strains K8 and K8 grown on n-alkanes were separated to
cytoplasm/microsome fractions (S2) and organelle fractions
(P2) at 20,000 × g (Fig.
7). Thiolase I was present only in the
S2 fraction in K8, whereas it was present in both the
S2 and P2 fractions in K8. Proper subcellular
fractionation was confirmed by the presence of the majority of Thiolase
III in the P2 fraction. These results demonstrated that the
C-terminal residues of Thiolase I functioned as a PTS1 in C. tropicalis and that the localization of Thiolase I was
successfully restricted to the cytoplasm.
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|
FIG. 7.
Subcellular distribution of the wild-type Thiolase I
[K8 (+/ +/+)] and C-terminus-deleted Thiolase I [K8 (C/
+/+)]. Cells grown on n-alkanes were harvested at
mid-logarithmic phase, lysed to protoplast, homogenized, and separated
to nuclear and postnuclear fractions (51). S1,
S2, and P2 represent postnuclear supernatant,
cytoplasm/microsome, and organelle fractions, respectively. Protein (20 µg) from each fraction was run on gels. Thiolases were detected with
anti-Ps-Thiolase I (upper panel) and anti-Thiolase III (lower panel)
antisera. Thiolase IC6, C-terminus-truncated Thiolase I.
|
|
Mevalonate requirement of mutant strains.
The
ct-t1a/t1b mutants K68U and K6870U could be
obtained in an SD+S medium containing L-mevalonolactone. In
the yeast S. cerevisiae, cytosolic acetoacetyl-CoA thiolase
encoded by ERG10 has been genetically shown to be essential
for the mevalonate pathway (10). If a thiolase isozyme
in C. tropicalis catalyzes the initial step of this
pathway, its deficiency would result in mevalonate auxotrophy. K68U and
K6870U, both of which lacked Thiolase I, could grow on YPD medium only
when it was supplemented with L-mevalonolactone. K70, which
lacks Thiolase III, K8, which lacks Ps-Thiolase I, and
K870, which lacks Ps-Thiolase I and Thiolase III, did not require
mevalonate, as was the case with the wild-type strain, SU-2. These
results suggest that Cs-Thiolase I has an indispensable role in the
mevalonate pathway.
Cell growth of mutant strains on various carbon sources.
Previously, we reported that C. tropicalis could
utilize a short-chain fatty acid, butyrate, as well as
n-alkanes and longer-chain fatty acids (25). In
butyrate-grown cells, peroxisomes and the enzymes of the peroxisomal
-oxidation system were induced. Therefore, the contributions of
thiolase isozymes to fatty-acid -oxidation and/or to other
metabolic processes were examined by observation of the cell growth of
thiolase disruptants on various carbon sources (Fig.
8).
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|
FIG. 8.
Growth kinetics of wild-type and mutant strains on
various carbon sources. Open circle, solid circle, open triangle, and
solid triangle represent strains SU-2 (+/+ +/+), K70 (+/+ /), K8
(C/ +/+), and K870 (C/ /), respectively.
|
|
Significant differences in growth were not observed among the wild-type
strain, SU-2, and the hemizygous thiolase gene null mutants K6, K8, K7,
and K0 on glucose, n-alkane, and butyrate (data not shown),
indicating that neither the A nor the B gene has an independent
physiological role in cell growth. K70, which lacks Thiolase III, could
not grow on n-alkanes (C10 to C13), whereas K8, which lacks Ps-Thiolase I, exhibited growth on
n-alkanes. K70 could not grow on oleic acid either (data not
shown). These results demonstrated that Thiolase III was indispensable
for -oxidation of long-chain fatty acids. On butyrate, however,
K8 also showed good growth, while the growth of K70 was retarded,
but the growth of both strains reached almost the same level as that of
the wild-type strain, SU-2, in the stationary-growth phase. No growth
on butyrate was observed for K870, which lacks both Ps-Thiolase I
and Thiolase III, suggesting that butyrate was utilized solely through
peroxisomal -oxidation. This fact supports the induction of
-oxidation enzymes in butyrate-utilizing cells (25).
There was no significant difference among strains SU-2, K70, and K8
in cell growth on another short-chain fatty acid, propionate, on
glucose, or on the nonfermentable carbon sources, glycerol and ethanol
(Fig. 8); these results also indicate the indispensable participation
of peroxisomal thiolase isozymes in -oxidation.
| |
DISCUSSION |
In the diploid yeast C. tropicalis, we disrupted
the thiolase isozyme genes and altered the distribution of Thiolase
I in order to elucidate the physiological functions of the thiolase isozymes. Intracellular thiolase activity was completely abolished in the double homozygous mutant lacking the Thiolase I and Thiolase III
genes, indicating that there is no thiolase in C. tropicalis other than Cs-Thiolase I, Ps-Thiolase I, and
Thiolase III, which are encoded by two pairs of alleles. For
S. cerevisiae, it has been reported that there are
peroxisomal 3-ketoacyl-CoA thiolase (Pot1p/Fox3p), cytosolic
acetoacetyl-CoA thiolase (Erg10p), and mitochondrial
acetoacetyl-CoA thiolase (10, 12, 22), although the gene
encoding the mitochondrial enzyme has not been cloned yet. In mammalian
cells, there are at least five thiolase isozymes, and they are
encoded by distinct genes. Compared with these systems, C. tropicalis has a simple set of thiolase isozymes encoded by two pairs of allelic genes.
Experiments with deletions of the C-terminal 6 amino acid residues of
Thiolase I, DADAKL, revealed the necessity of the sequence for
targeting of the enzyme to peroxisomes in C. tropicalis. The last 3 residues, AKL, are in good agreement with
one motif of PTS1 (8). The transport of peroxisomal proteins
of C. tropicalis to peroxisomes has been examined for
acyl-CoA oxidase and the multifunctional protein, but these studies
were performed in in vitro systems or in heterologous in vivo systems
(1, 15, 43). Therefore, the present result marks the first
case for C. tropicalis in which a peroxisomal targeting
signal was identified in a homologous in vivo system.
The expression of Thiolase I (Ps-Thiolase I and Cs-Thiolase I) genes
was totally induced in response to n-alkane utilization (Fig. 5A) (17, 26), but Cs-Thiolase I is present
constitutively (26) and contributes indispensably to the
mevalonate pathway. Therefore, it is important that Thiolase I is
sorted into peroxisomes and cytoplasm in a regulated manner. Many
mechanisms for the sorting of a single protein to dual compartments
have been proposed (6). Recently, the 4th residue of
C-terminal PTS1 of human catalase has been shown to be important in
determining the efficiency of transportation of catalase to
peroxisomes, which was attributed to the binding affinity of PTS1 for
PTS1 receptor (39). Further detailed analysis of the
C-terminal 6 amino acids will be necessary to reveal their relation to
the dual sorting mechanism of Thiolase I.
The present results demonstrated that Cs-Thiolase I was essential for
the mevalonate pathway, the early steps of sterol synthesis, in
C. tropicalis. This physiological function is
consistent with the enzymatic properties of Thiolase I, i.e., the
activity for condensation reaction of acetyl-CoA units (18).
It has also been shown that Thiolase I which can catalyze the
condensation reaction was present both in cytoplasm and in peroxisomes
of C. tropicalis (18). In mammalian cells
also, the condensation reaction of thiolase is detected in these two
compartments (11, 32, 48), and additionally,
3-hydroxy-3-methylglutaryl-CoA reductase, which is the rate-limiting
enzyme in the mevalonate pathway, is colocalized with the condensation
reaction (20, 21), suggesting two pathways in the early
steps of sterol synthesis. However, this reductase has not been
detected in peroxisomes of C. tropicalis (26), and lack of Ps-Thiolase I had no significant effect on growth (Fig. 8). Therefore, it is suggested that the early steps of
sterol synthesis occur only in the cytoplasm of this yeast.
The fatty-acid -oxidation system is present only in peroxisomes in
C. tropicalis (19). The present results for
thiolase isozymes clarified this observation that peroxisomal
-oxidation exclusively contributes to fatty-acid degradation. On the
other hand, unlike lack of Ps-Thiolase I, lack of Thiolase III resulted in growth retardation on butyrate (Fig. 8), suggesting that Thiolase III degraded acetoacetyl-CoA more efficiently than Ps-Thiolase I did in
peroxisomal -oxidation. The results were not consistent with the
biochemical observations that Thiolase I has much higher specific
activity for a C4 substrate, acetoacetyl-CoA, than
Thiolase III (23, 24). Furthermore, most of the thiolase
activity for acetoacetyl-CoA was due to Thiolase I (Fig. 4A).
Therefore, we presume that the reasons for the growth retardation
brought about by lack of Thiolase III are as follows. First, the
contribution of each isozyme to -oxidation might be determined
by its quantity. In C. tropicalis peroxisomes, the
amount of Thiolase III is much higher than that of Ps-Thiolase I. The
molar ratio of the two isozymes (Thiolase III/Ps-Thiolase I) can be
estimated as approximately 16 for the native enzyme and 5.2 for the
subunit from specific activities of the peroxisomal fraction and the
purified proteins (23, 24). Second, Thiolase III might be
one component of a -oxidation multienzyme complex in C. tropicalis. There is a "metabolon" hypothesis which suggests
that enzymes included in a metabolic pathway form a multienzyme complex
to bring about an efficient metabolic flux (44, 45). If
Thiolase III belongs to a multienzyme complex, lack of Thiolase III
would result in the inhibition of -oxidation despite the presence of
Ps-Thiolase I.
In C. tropicalis peroxisomes, either Ps-Thiolase I or
Thiolase III allows this yeast to utilize butyrate through peroxisomal -oxidation. This is the first genetic demonstration that
acetoacetyl-CoA thiolase participates in peroxisomal -oxidation.
This system can be taken advantage of to alter the flux of peroxisomal
-oxidation in growing conditions and will give us insight into the
relation between the control of flux and the regulation of gene
expression in peroxisomal -oxidation.
| |
ACKNOWLEDGMENTS |
We thank Takahito Suzuki and Shin-ichi Iwaguchi, Nara Women's
University, for their technical advice and suggestions on the transformation of C. tropicalis. We thank Akihiro Hara,
Japan Energy Corp., for helpful discussions.
N.K. is a research fellow of the Japan Society for the Promotion of
Science (JSPS). This study was supported in part by a grant-in-aid for
JSPS fellows from the Ministry of Education, Science, Sports, and
Culture of Japan.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Applied Biological Chemistry, Department of Synthetic Chemistry and
Biological Chemistry, Graduate School of Engineering, Kyoto University,
Yoshida, Sakyo-ku, Kyoto 606-01, Japan. Phone: 81-75-753-5524. Fax:
81-75-753-5534. E-mail: atsuo{at}sbchem.kyoto-u.ac.jp.
| |
REFERENCES |
| 1.
|
Aitchison, J. D.,
W. W. Murray, and R. A. Rachubinski.
1991.
The carboxyl-terminal tripeptide Ala-Lys-Ile is essential for targeting Candida tropicalis trifunctional enzyme to yeast peroxisomes.
J. Biol. Chem.
266:23197-23203[Abstract/Free Full Text].
|
| 2.
|
Alani, E.,
L. Cao, and N. Kleckner.
1987.
A method for gene disruption that allows repeated use of URA3 selection in the construction of multiply disrupted yeast strains.
Genetics
116:541-545[Abstract/Free Full Text].
|
| 3.
|
Ausubel, F. M.,
R. Brent,
R. E. Kingston,
D. D. Moore,
J. G. Seidman,
J. A. Smith, and K. Struhl.
1994.
.
Current protocols in molecular biology.
John Wiley & Sons, Inc., New York, N.Y.
|
| 4.
|
Burgers, P. M. J., and K. J. Percival.
1987.
Transformation of yeast spheroplasts without cell fusion.
Anal. Biochem.
163:391-397[Medline].
|
| 5.
|
Cregg, J. M.,
K. J. Barringer,
A. Y. Hessler, and K. R. Madden.
1985.
Pichia pastoris as a host system for transformation.
Mol. Cell. Biol.
5:3376-3385[Abstract/Free Full Text].
|
| 6.
|
Danpure, C. J.
1995.
How can the products of a single gene be localized to more than one intracellular compartment?
Trends Cell Biol.
5:230-238.
[Medline] |
| 7.
|
Feigenbaum, J., and H. Schulz.
1975.
Thiolases of Escherichia coli: purification and chain length specificities.
J. Bacteriol.
122:407-411[Abstract/Free Full Text].
|
| 8.
|
Gould, S. J.,
G. A. Keller,
N. Hosken,
J. Wilkinson, and S. Subramani.
1989.
A conserved tripeptide sorts proteins to peroxisomes.
J. Cell Biol.
108:1657-1664[Abstract/Free Full Text].
|
| 9.
|
Haas, L. O. C.,
J. M. Cregg, and M. A. G. Gleeson.
1990.
Development of an integrative DNA transformation system for the yeast Candida tropicalis.
J. Bacteriol.
172:4571-4577[Abstract/Free Full Text].
|
| 10.
|
Hiser, L.,
M. E. Basson, and J. Rine.
1994.
ERG10 from Saccharomyces cerevisiae encodes acetoacetyl-CoA thiolase.
J. Biol. Chem.
269:31383-31389[Abstract/Free Full Text].
|
| 11.
|
Hovik, R.,
B. Brodal,
K. Bartlett, and H. Osmundsen.
1991.
Metabolism of acetyl-CoA by isolated peroxisomal fractions: formation of acetate and acetoacetyl-CoA.
J. Lipid Res.
32:993-999[Abstract].
|
| 12.
|
Igual, J. C.,
E. Matallana,
C. Gonzalez-Bosch,
L. Franco, and J. E. Pérez-Ortin.
1991.
A new glucose-repressible gene identified from the analysis of chromatin structure in deletion mutants of yeast SUC2 locus.
Yeast
7:379-389[Medline].
|
| 13.
|
Ito, W.,
H. Ishiguro, and Y. Kurosawa.
1991.
A general method for introducing a series of mutations into cloned DNA using the polymerase chain reaction.
Gene
102:67-70[Medline].
|
| 14.
|
Kaiser, C.,
S. Michaelis, and A. Mitchell.
1994.
.
Methods in yeast genetics. A Cold Spring Harbor Laboratory course manual.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 15.
|
Kamiryo, T.,
Y. Sakasegawa, and H. Tan.
1989.
Expression and transport of Candida tropicalis peroxisomal acyl-coenzyme A oxidase in the yeast Candida maltosa.
Agric. Biol. Chem.
53:179-186.
|
| 16.
|
Kanai, T.,
H. Atomi,
K. Umemura,
H. Ueno,
Y. Teranishi,
M. Ueda, and A. Tanaka.
1996.
A novel heterologous gene expression system in Saccharomyces cerevisiae using the isocitrate lyase gene promoter from Candida tropicalis.
Appl. Microbiol. Biotechnol.
44:759-765[Medline].
|
| 17.
|
Kanayama, N.,
M. Ueda,
H. Atomi,
T. Kurihara,
J. Kondo,
Y. Teranishi, and A. Tanaka.
1994.
Comparison of molecular structures and regulation of biosynthesis of unique thiolase isozymes localized only in peroxisomes of n-alkane-utilizing yeast, Candida tropicalis.
J. Ferment. Bioeng.
78:273-278.
|
| 18.
|
Kanayama, N.,
Y. Himeda,
H. Atomi,
M. Ueda, and A. Tanaka.
1997.
Expression of acetoacetyl-CoA thiolase isozyme genes of n-alkane-assimilating yeast, Candida tropicalis: isozymes in two intracellular compartments are derived from the same genes.
J. Biochem. (Tokyo)
122:616-621[Abstract/Free Full Text].
|
| 19.
|
Kawamoto, S.,
C. Nozaki,
A. Tanaka, and S. Fukui.
1978.
Fatty acid -oxidation system in microbodies of n-alkane-grown Candida tropicalis.
Eur. J. Biochem.
83:609-613[Medline].
|
| 20.
|
Keller, G. A.,
M. C. Barton,
D. J. Shapiro, and S. J. Singer.
1985.
3-Hydroxy-3-methylglutaryl-coenzyme A reductase is present in peroxisomes in normal rat liver cells.
Proc. Natl. Acad. Sci. USA
82:770-774[Abstract/Free Full Text].
|
| 21.
|
Keller, G. A.,
M. Pazirandeh, and S. Krisans.
1986.
3-Hydroxy-3-methylglutaryl coenzyme A reductase localization in rat liver peroxisomes and microsomes of control and cholestyramine-treated animals: quantitative biochemical and immunoelectron microscopical analyses.
J. Cell Biol.
103:875-886[Abstract/Free Full Text].
|
| 22.
|
Kornblatt, J. A., and H. Rudney.
1971.
Two forms of acetoacetyl coenzyme A thiolase in yeast. II. Intracellular location and relationship to growth.
J. Biol. Chem.
246:4424-4430[Abstract/Free Full Text].
|
| 23.
|
Kurihara, T.,
M. Ueda, and A. Tanaka.
1988.
Occurrence and possible roles of acetoacetyl-CoA thiolase and 3-ketoacyl-CoA thiolase in peroxisomes of an n-alkane-grown yeast, Candida tropicalis.
FEBS Lett.
229:215-218[Medline].
|
| 24.
|
Kurihara, T.,
M. Ueda, and A. Tanaka.
1989.
Peroxisomal acetoacetyl-CoA thiolase and 3-ketoacyl-CoA thiolase from an n-alkane-utilizing yeast, Candida tropicalis: purification and characterization.
J. Biochem. (Tokyo)
106:474-478[Abstract/Free Full Text].
|
| 25.
|
Kurihara, T.,
M. Ueda,
H. Okada,
N. Kamasawa,
N. Naito,
M. Osumi, and A. Tanaka.
1992.
-Oxidation of butyrate, the short-chain-length fatty acid, occurs in peroxisomes in the yeast Candida tropicalis.
J. Biochem. (Tokyo)
111:783-787[Abstract/Free Full Text].
|
| 26.
|
Kurihara, T.,
M. Ueda,
H. Okada,
N. Kamasawa,
M. Osumi, and A. Tanaka.
1992.
Physiological roles of acetoacetyl-CoA thiolase in n-alkane-utilizable yeast, Candida tropicalis: possible contribution to alkane degradation and sterol biosynthesis.
J. Biochem. (Tokyo)
112:845-848[Abstract/Free Full Text].
|
| 27.
|
Kurihara, T.,
M. Ueda,
N. Kanayama,
J. Kondo,
Y. Teranishi, and A. Tanaka.
1992.
Peroxisomal acetoacetyl-CoA thiolase of an n-alkane-utilizing yeast, Candida tropicalis.
Eur. J. Biochem.
210:999-1005[Medline].
|
| 28.
|
Lazarow, P. B., and Y. Fujiki.
1985.
Biogenesis of peroxisomes.
Annu. Rev. Cell Biol.
1:489-530.
|
| 29.
|
Lowry, O. H.,
N. J. Rosebrough,
A. L. Farr, and R. J. Randall.
1951.
Protein measurement with the Folin phenol reagent.
J. Biol. Chem.
193:265-275[Free Full Text].
|
| 30.
|
Meilhoc, E.,
J. M. Masson, and J. Teissié.
1990.
High efficiency transformation of intact yeast cells by electric field pulses.
Bio/Technology
8:223-227[Medline].
|
| 31.
|
Middleton, B.
1973.
The oxoacyl-coenzyme A thiolases of animal tissues.
Biochem. J.
132:717-730[Medline].
|
| 32.
|
Middleton, B.
1974.
The kinetic mechanism and properties of the cytoplasmic acetoacetyl-coenzyme A thiolase from rat liver.
Biochem. J.
139:109-121[Medline].
|
| 33.
|
Middleton, B., and K. Bartlett.
1983.
The synthesis and characterization of 2-methylacetoacetyl coenzyme A and its use in the identification of the site of the defect in 2-methylacetoacetic and 2-methyl-3-hydroxybutyric aciduria.
Clin. Chim. Acta
128:291-305[Medline].
|
| 34.
|
Miyazawa, S.,
T. Osumi, and T. Hashimoto.
1980.
The presence of a new 3-oxoacyl-CoA thiolase in rat liver peroxisomes.
Eur. J. Biochem.
103:589-596[Medline].
|
| 35.
|
Nicholls, R. D.,
A. V. S. Hill,
J. B. Clegg, and D. R. Higgs.
1985.
Direct cloning of specific genomic DNA sequences in plasmid libraries following fragment enrichment.
Nucleic Acids Res.
13:7569-7578[Abstract/Free Full Text].
|
| 36.
|
Oeding, V., and H. G. Schlegel.
1973.
-Ketothiolase from Hydrogenomonas eutropha H16 and its significance in the regulation of poly--hydroxybutyrate metabolism.
Biochem. J.
134:239-248[Medline].
|
| 37.
|
Osumi, M.,
N. Miwa,
Y. Teranishi,
A. Tanaka, and S. Fukui.
1974.
Ultrastructure of Candida yeasts grown on n-alkanes. Appearance of microbodies and its relationship to high catalase activity.
Arch. Microbiol.
99:181-201[Medline].
|
| 38.
|
Picataggio, S.,
K. Deanda, and J. Mielenz.
1991.
Determination of Candida tropicalis acyl coenzyme A oxidase isozyme function by sequential gene disruption.
Mol. Cell. Biol.
11:4333-4339[Abstract/Free Full Text].
|
| 39.
|
Purdue, P. E., and P. B. Lazarow.
1996.
Targeting of human catalase to peroxisomes is dependent upon a novel COOH-terminal peroxisomal targeting sequence.
J. Cell Biol.
134:849-862[Abstract/Free Full Text].
|
| 40.
|
Scherer, S., and R. W. Davis.
1979.
Replacement of chromosome segments with altered DNA sequences constructed in vitro.
Proc. Natl. Acad. Sci. USA
76:4951-4955[Abstract/Free Full Text].
|
| 41.
|
Schram, A. W.,
S. Goldfischer,
C. W. T. van Roermund,
E. M. Brouwer-Kelder,
J. Collins,
T. Hashimoto,
H. S. A. Heymans,
H. van den Bosch,
R. B. H. Schutgens,
J. M. Tager, and R. J. A. Wanders.
1987.
Human peroxisomal 3-oxoacyl-coenzyme A thiolase deficiency.
Proc. Natl. Acad. Sci. USA
84:2494-2496[Abstract/Free Full Text].
|
| 42.
|
Senior, P. J., and E. A. Dawes.
1973.
The regulation of poly--hydroxybutyrate metabolism in Azotobacter beijerinckii.
Biochem. J.
134:225-238[Medline].
|
| 43.
|
Small, G. M.,
L. J. Szabo, and P. B. Lazarow.
1988.
Acyl-CoA oxidase contains two targeting sequences each of which can mediate protein import into peroxisomes.
EMBO J.
7:1167-1173[Medline].
|
| 44.
|
Srere, P. A.
1987.
Complexes of sequential metabolic enzymes.
Annu. Rev. Biochem.
56:89-124[Medline].
|
| 45.
|
Srere, P. A., and B. Sumegi.
1994.
Processivity and fatty acid oxidation.
Biochem. Soc. Trans.
22:446-450[Medline].
|
| 46.
|
Staack, H.,
J. F. Binstock, and H. Schulz.
1978.
Purification and properties of a pig heart thiolase with broad chain length specificity and comparison of thiolases from pig heart and Escherichia coli.
J. Biol. Chem.
253:1827-1831[Abstract/Free Full Text].
|
| 47.
|
Tajima, M.,
Y. Nogi, and T. Fukasawa.
1985.
Primary structure of the Saccharomyces cerevisiae GAL7 gene.
Yeast
1:67-77[Medline].
|
| 48.
|
Thompson, S. L., and S. K. Krisans.
1990.
Rat liver peroxisomes catalyze the initial step in cholesterol synthesis. The condensation of acetyl-CoA units into acetoacetyl-CoA.
J. Biol. Chem.
265:5731-5735[Abstract/Free Full Text].
|
| 49.
|
Uchida, Y.,
K. Izai,
T. Orii, and T. Hashimoto.
1992.
Novel fatty acid beta-oxidation enzymes in rat liver mitochondria. II. Purification and properties of enoyl-coenzyme A (CoA) hydratase/3-hydroxyacyl-CoA dehydrogenase/3-ketoacyl-CoA thiolase trifunctional protein.
J. Biol. Chem.
267:1034-1041[Abstract/Free Full Text].
|
| 50.
|
Ueda, M.,
H. Okada,
A. Tanaka,
M. Osumi, and S. Fukui.
1983.
Induction and subcellular localization of enzymes participating in propionate metabolism in Candida tropicalis.
Arch. Microbiol.
136:169-176[Medline].
|
| 51.
|
Ueda, M.,
K. Yamanoi,
T. Morikawa,
H. Okada, and A. Tanaka.
1985.
Peroxisomal localization of enzymes related to fatty acid -oxidation in an n-alkane-grown yeast, Candida tropicalis.
Agric. Biol. Chem.
49:1821-1828.
|
| 52.
|
Ueda, M.,
S. Mozaffar,
H. Atomi,
M. Osumi, and A. Tanaka.
1989.
Characterization of peroxisomes in n-alkane-utilizable yeast, Candida tropicalis, grown on glucose and propionate.
J. Ferment. Bioeng.
68:411-416.
|
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Abstract
Introduction
