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Applied and Environmental Microbiology, November 2001, p. 5254-5260, Vol. 67, No. 11
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.11.5254-5260.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Synthesis of Polyhydroxyalkanoate in the Peroxisome
of Saccharomyces cerevisiae by Using Intermediates of
Fatty Acid 
-Oxidation
Yves
Poirier,*
Nadine
Erard, and
Jean
MacDonald-Comber
Petétot
Laboratoire de Biotechnologie
Végétale, Institut d'Écologie, Université de
Lausanne, CH-1015 Lausanne, Switzerland
Received 18 May 2001/Accepted 31 August 2001
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ABSTRACT |
Medium-chain-length polyhydroxyalkanoates (PHAs) are polyesters
having properties of biodegradable thermoplastics and elastomers that
are naturally produced by a variety of pseudomonads.
Saccharomyces cerevisiae was transformed with the
Pseudomonas aeruginosa PHAC1 synthase modified for
peroxisome targeting by the addition of the carboxyl 34 amino acids
from the Brassica napus isocitrate lyase. The PHAC1 gene
was put under the control of the promoter of the catalase A gene. PHA
synthase expression and PHA accumulation were found in recombinant
S. cerevisiae growing in media containing fatty acids. PHA containing even-chain monomers from 6 to 14 carbons was found in recombinant yeast grown on oleic acid, while odd-chain monomers from 5 to 15 carbons were found in PHA from yeast grown on
heptadecenoic acid. The maximum amount of PHA accumulated was 0.45% of the dry weight. Transmission electron microscopy of
recombinant yeast grown on oleic acid revealed the presence of numerous
PHA inclusions found within membrane-bound organelles. Together, these data show that S. cerevisiae expressing a
peroxisomal PHA synthase produces PHA in the peroxisome using the
3-hydroxyacyl coenzyme A intermediates of the 
-oxidation of fatty
acids present in the media. S. cerevisiae
can thus be used as a powerful model system to learn how fatty acid
metabolism can be modified in order to synthesize high amounts of PHA
in eukaryotes, including plants.
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INTRODUCTION |
Polyhydroxyalkanoate (PHA) is a
family of polyesters composed primarily of R-3-hydroxyalkanoic acids
(2, 30, 40, 41). PHA is synthesized as intracellular
inclusions by a wide variety of bacteria, including gram-positive and
gram-negative species as well as some phototrophic bacteria, and is
used as a carbon and electron sink. PHAs have been broadly defined in
two main classes, namely, short-chain-length PHA (SCL-PHA) and
medium-chain-length PHA (MCL-PHA). Whereas SCL-PHA typically harbors
monomers of 3-hydroxy acids from 3 to 5 carbons, MCL-PHA contains
3-hydroxy acids from 6 to 16 carbons in length (2, 40).
The best-characterized SCL-PHA is polyhydroxybutyrate (PHB), a
homopolymer of 3-hydroxybutyric acid. In Ralstonia eutropha,
PHB accumulates up to 80% of the dry weight (dwt), with inclusions
being typically 0.2 to 1 µm in diameter. MCL-PHAs are typically
synthesized by pseudomonads, such as Pseudomonas oleovorans
and Pseudomonas aeruginosa.
Industrial interest in PHAs arises largely from their properties as
thermoplastics and elastomers (2, 30, 40). Furthermore, numerous bacteria and fungi can hydrolyze PHAs to monomers and oligomers, which are further metabolized as a carbon source
(2). PHAs are thus attractive as a source of renewable and
biodegradable polyesters. PHB is a highly crystalline polymer with
rather poor physical properties, being relatively stiff and brittle and
degrading at temperatures slightly above its melting point
(5). Incorporation of longer-chain monomers into the
polymer, to form the copolymer poly(hydroxybutyrate-cohydroxyvalerate)
[P(HB-HV)], reduces the crystallinity and melting point of the
polymer, leading to improvement in the flexibility, strength, and
processing of the polymer (5).
In contrast to SCL-PHAs, which are regarded as thermoplastics, MCL-PHAs
have low crystallinity and melting points and are generally regarded as
elastomers (15). There exist two main pathways for the
synthesis of MCL-PHAs in bacteria. In bacteria such as P. oleovorans, MCL-PHA accumulates when cells are grown on
alkanoic acids as the carbon source (2, 40, 41). The nature of the PHA produced is related to the substrate used for growth
and is typically composed of monomers that are 2n
(n 
0) carbons shorter than the substrate. For
example, growth of P. oleovorans on octanoate
generates a PHA polymer containing 89 mol% 3-hydroxyoctanoic acid and
11 mol% 3-hydroxyhexanoic acid, whereas growth on dodecanoate
generates PHA containing 31 mol% 3-hydroxydodecanoic acid, 36 mol%
3-hydroxydecanoic acid, 31 mol% 3-hydroxyoctanoic acid, and 2 mol%
3-hydroxyhexanoic acid (22). These studies have indicated
that MCL-PHAs are synthesized by the PHA synthase from 3-hydroxyacyl
coenzyme A (CoA) intermediates generated by the -oxidation of
alkanoic acids. A second pathway exists in some bacteria, such as
Pseudomonas putida, that can synthesize MCL-PHA from glucose
using intermediates of fatty acid biosynthesis (16, 20, 35,
43). The phaG gene that encodes a 3-hydroxyacyl-acyl
carrier protein-CoA transferase provides the metabolic link between
fatty acid biosynthesis and MCL-PHA synthesis (9, 32).
The main limitation for the use of PHAs as a commodity polymer is the
high cost of producing PHA by bacterial fermentation relative to the
cost of petroleum-derived plastics (27, 30). In this
perspective, synthesis of PHAs in crop plants has been seen as an
attractive alternative for the commercial production of large amounts
of PHA at low cost (27, 28). Synthesis of SCL-PHAs has
been demonstrated in a number of plants (28). Synthesis of
PHB from acetyl-CoA was first shown in the cytoplasm and plastids of
Arabidopsis thaliana cells (26, 29) and later
in the peroxisomes of maize culture cells (14).
Accumulation of PHB up to 40% dwt has recently been demonstrated in
A. thaliana (4) as well as the
synthesis of the copolymer P(HB-HV) in the seed leukoplasts of
A. thaliana and Brassica napus
(39). Furthermore, synthesis of PHB has also been
demonstrated in the cytoplasm of S. cerevisiae (23) and in transgenic insect cells (45)
expressing the PHB synthase from R. eutropha.
Synthesis of MCL-PHA in plants has been demonstrated in transgenic
A. thaliana expressing the PHA synthase from
P. aeruginosa in the peroxisome (24,
25). In these plants, MCL-PHAs containing saturated and
unsaturated 3-hydroxyalkanoic acids ranging from 6 to 16 carbons were
synthesized using intermediates of the -oxidation of fatty acid
(24, 25). The maximal amount of PHA synthesized in this
system is low, at approximately 0.4 to 0.6% dwt, indicating the need
for further modifications of fatty acid metabolic pathways before
plants can be used for commercial production of MCL-PHAs.
We have sought to develop a more amenable eukaryotic system to
understand how to manipulate the pathways involved in the degradation of fatty acids to increase the amount of MCL-PHA synthesized in peroxisomes. We now report the development of Saccharomyces
cerevisiae for the synthesis of MCL-PHA in peroxisomes using
intermediates of the -oxidation of fatty acids.
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MATERIALS AND METHODS |
Strains and culture conditions.
Plasmids were maintained and
propagated in Escherichia coli DH5
according to Sambrook
et al. (36). S. cerevisiae diploid strain INVSc1 (his3D1 leu2 trp1-289
ura3-52) was obtained from Invitrogen (Groningen, The
Netherlands). S. cerevisiae harboring the PHA
synthase gene was maintained in leucine-deficient media (0.67% yeast
nitrogen base without amino acids [Difco, Detroit, Mich.], 0.5%
ammonium sulfate, 2% glucose, and 0.4 g of leucine dropout
supplement [Clontech, Palo Alto, Calif.]/liter). For PHA production,
a stationary-phase culture was harvested by centrifugation and cells
were washed once in water and resuspended at a 1:10 dilution in fresh
leucine-deficient media containing 0.1% or no glucose as well as
detergent (either Tween 80 or Pluronic-127 [Sigma, St. Louis, Mo.])
and fatty acid (oleic acid or heptadecenoic acid). Cells were grown for
an additional 1 to 6 days before harvest of the cells for PHA analysis.
The pH of the growth media with or without fatty acids was 6.0.
DNA constructs.
The plasmid pYE352-PHA was constructed from
the plasmid pYE352-CTA1 containing the S. cerevisiae catalase gene with its promoter and terminator
sequences (10). The catalase-coding region of pYE352-CTA1
was removed by a SacI-XhoI digestion, and the
vector was made blunt ended by using T4 DNA polymerase. The PHA
synthase from P. aeruginosa modified for
peroxisomal targeting by the addition, at the carboxy end, of the last
34 amino acids of the B. napus isocitrate lyase,
was obtained from the plasmid pART7-PhaC1-ICL (25). The
plasmid pART7-PhaC1-ICL was digested by
EcoRI-XbaI, and the fragment harboring the
modified PHA synthase was made blunt ended by T4 DNA polymerase and was
ligated to the blunt-ended pYE352-CTA1 vector to create pYE352-PHA. The
gene expression cassette containing the CTA1 promoter-PHA synthase-CTA1
terminator was excised from pYE352-PHA by a partial EcoRI
digestion and was cloned into the EcoRI site of the
integrative shuttle vector Yiplac128 (12), giving the
plasmid Yiplac128-PHA. This plasmid was linearized by digestion with
ClaI and transferred into the S. cerevisiae strain INVSc1 by the lithium acetate procedure.
Transformants were recovered on media without leucine.
Western blot analysis.
The equivalent of an optical density
at 600 nm of 0.2 of S. cerevisiae cells was
harvested by centrifugation in a 1.5-ml tube and was suspended in 6 µl of 2 N NaOH-5% (vol/vol) -mercaptoethanol. The suspension was
put on ice for 10 min before adding 7.8 µl of 10% (wt/vol) sodium
dodecyl sulfate. The mixture was briefly vortexed and was left at room
temperature for 20 min with occasional mixing. The resulting crude
protein extract was separated by sodium dodecyl sulfate-polyacrylamide
gel electrophoresis and was blotted onto nitrocellulose
membranes using a Trans-Blot electrophoretic cell (Bio-Rad, Richmond,
Calif.). Free binding sites were saturated by incubation in blocking
buffer (0.4 M NaCl, 2 mM KCl, 20 mM Tris-HCl, pH 7.4, 1% [vol/vol]
Tween 40, and 5% [wt/vol] milk powder) for 1 h. The membranes
were incubated for 2 h at room temperature in blocking buffer with
anti-PHA synthase antibody. The antigen-antibody complexes were
visualized with horseradish peroxidase-coupled goat anti-rabbit
antibodies using the enhanced-chemiluminescence method (Amersham,
Little Chalfont, United Kingdom).
Analysis of fatty acids and PHA.
Fatty acids present in the
growth media were determined by analysis of fatty acid methyl-esters by
gas chromatography (GC). Briefly, media were harvested and cleared of
cells by centrifugation at 5,000 × g for 10 min. The
cleared solution was transferred to a fresh tube and lyophilized. The
dried residues were suspended in a methanol solution containing 1 N HCl
and were heated at 80°C for 2 h. The fatty acid methyl-esters
were extracted with 0.5 to 1 ml of hexane and 1 ml of 0.9% (wt/vol)
NaCl, and the organic phase was transferred to autoinjector vials. GC
analysis was performed using a Hewlett Packard 5890 gas chromatograph
that was equipped with a Supelco SP2330 glass capillary column and
coupled to a flame ionization detector.
For PHA analysis, cells were harvested by centrifugation, washed twice
in water, and lyophilized. The dried material was then weighed
(approximately 15 to 30 mg) and transferred to a glass tube. The
material was extracted four or five times with warm (65°C) methanol
to remove lipids, free fatty acids, and acyl-CoA, including
3-hydroxyacyl-CoA, while PHA, which is insoluble in methanol, remains
associated with the cells. After centrifugation and removal of the
residual methanol, the material was suspended in 0.5 ml of chloroform
to which 0.5 ml of methanol containing 3% sulfuric acid was added. The
mixture was heated at 95°C for 4 h and cooled down on ice. One
milliliter of 0.1% NaCl was added to each tube, and the mixture was
vortexed vigorously and centrifuged at 5,000 × g for 5 min. The chloroform phase was harvested and dried over anhydrous
MgCl2. The methyl-esters of 3-hydroxy acids were
identified and quantified by GC-mass spectrometry (GC-MS) using a
Hewlett-Packard 5890 gas chromatograph (HP-5MS column) coupled to a
Hewlett-Packard 5972 mass spectrometer. Analysis by GC-MS was made
utilizing the ion-selective mode (mass-to-charge ratio of 103).
Identification of monomers present in plant PHA was facilitated by the
use of commercial 3-hydroxy acid standards and purified bacterial PHAs.
In one experiment, lyophilized cells were extracted with methanol in a
Soxhlet apparatus for 24 h followed by PHA extraction with
chloroform for 24 h. The PHA-containing chloroform was
concentrated using a Rotovapor and extracted once with water to remove
residual solid particles. PHA was precipitated by the addition of 10 volumes of cold methanol and was subsequently washed by two cycles of
chloroform solubilization and methanol precipitation. PHA dissolved in
chloroform was analyzed by GC-MS as described above. The composition of
the PHA isolated after Soxhlet extraction was similar to the PHA
analyzed following esterification of the methanol-washed cells in chloroform.
Electron microscopy.
Cells were fixed for 4 h at room
temperature in 4% (vol/vol) glutaraldehyde in 0.1 M sodium cacodylate,
pH 7.2, and 0.1% (wt/vol) Brij 35, followed by an overnight treatment
in the same solution without Brij 35. The cells were then rinsed
several times with 0.1 M sodium cacodylate, pH 7.2, transferred to 2%
osmium tetroxide for either 8 h at room temperature or 16 h
at 4°C, and were then transferred to 2% uranyl acetate in 10%
ethanol for 40 min. Cells were dehydrated through a graded series of
ethanol with a final treatment in propylene oxide. Cells were embedded
in Epon/Araldite resin and were polymerized for 3 days at 70°C. The
blocks were cut with a Diatome diamond knife on a Reichret ultracut S
microtome. Fine sections of 50 nm were placed on Formvar-coated copper
grids, contrasted with a 2% aqueous solution of uranyl acetate for 6 min followed by lead citrate for 6 min. The grids were examined with a
Philips Biotwin CM100 (Lab6 filament) transmission electron microscope.
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RESULTS |
Expression of the P. aeruginosa PHA
synthase in recombinant yeast.
Previous studies had shown that the
PHA synthase from P. aeruginosa could be targeted
to plant peroxisomes by modifying the carboxy end of the bacterial
protein by the addition of the last 34 amino acids of the peroxisomal
protein isocitrate lyase from B. napus
(25). This protein harbors the carboxy-terminal tripeptide ARM, a peroxisomal signal that was shown to be effective in targeting foreign proteins to peroxisomes in both plants and yeast (1, 44). The same modified PHA synthase was thus expressed in
S. cerevisiae. The structure of the gene
expression cassette is shown in Fig. 1.
The modified PHA synthase was put under the control of the promoter and
transcription terminator of the yeast catalase gene CTA1
(10). This promoter allows strong expression of genes in
yeast grown in media containing fatty acids as the carbon source (19, 38). The expression cassette was cloned into the
integrative yeast shuttle vector Yiplac128 for transformation into
S. cerevisiae.
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FIG. 1.
DNA construct used to express the PHAC1 synthase of
P. aeruginosa in S.
cerevisiae. Only the portion of the construct containing
the gene (open box) and regulatory elements (shaded box) is shown. The
partial amino acid sequence of the C terminus of the PHA
synthase-isocitrate lyase (ICL) fusion is indicated using the
one-letter symbols, with the amino acids derived from the PHAC1 protein
given in plain letters, novel amino acids created at the fusion
junction italicized, and the last 34 amino acids derived from the
B. napus isocitrate lyase underlined.
CTA-Pr, CTA1 promoter; CTA-Tr, CTA1 terminator; E,
EcoRI; H, HindIII.
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Western blot analysis of recombinant PHA synthase.
Recombinant
yeast transformed with Yiplac128-PHA was tested for expression of the
PHA synthase by Western blot analysis using an anti-PHA synthase serum
(Fig. 2). In these experiments, yeast grown to stationary phase in media containing 2% glucose was washed in
water and resuspended at a 1:10 dilution in leucine-deficient media
supplemented with glucose, oleic acid, and/or the detergent Pluronic-127 or Tween 80. While Pluronic-127 is a polyoxyethylene polymer containing no fatty acids, Tween 80 is a detergent containing approximately 20% oleic acid by weight that is esterified to the polyoxyethylenesorbitan backbone. These detergents were used to insure
solubilization of the free oleic acid added to the media. While no
expression of the PHA synthase was detected in transformed cells grown
for 24 h in media supplemented with 1% glucose, expression of the
65-kDa PHA synthase was readily detected in cells grown for 72 h
in media supplemented with only 0.1% glucose or in media containing
0.1% glucose and either 0.5% Tween 80, 2% Pluronic-127, 0.5% Tween
80 with 0.1% oleic acid, or 2% Pluronic-127 with 0.1% oleic acid
(Fig. 2).
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FIG. 2.
Western blot analysis of PHA synthase expression in
S. cerevisiae. Wild-type (A) or
recombinant yeast transformed with the PHA synthase (B to H) was grown
for 24 h in media containing 1% glucose (B) or 0.1% glucose, 2%
Pluronic-127, and 0.1% oleic acid (A and C) or for 72 h in media
containing 0.1% glucose (D); 0.1% glucose and 0.5% Tween 80 (E);
0.1% glucose and 2% Pluronic-127 (F); 0.1% glucose, 0.5% Tween 80, and 0.1% oleic acid (G); or 0.1% glucose, 2% Pluronic-127, and 0.1%
oleic acid (H). Molecular mass marker (in kilodaltons) is indicated on
the left.
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Production of MCL-PHA.
Cells grown to stationary phase in
media containing 2% glucose were shifted to media containing various
fatty acids and detergents with or without 0.1% glucose and were grown
for an additional 4 days before being harvested for PHA analysis (Table
1). Yeast grown on 0.5% Tween 80 produced only 0.02% (dwt) PHA, while addition of 0.1% oleic acid to
media containing 0.5% Tween 80 led to a 10-fold increase of PHA to
0.2% (dwt). Since the PHA synthase is well expressed in yeast grown in
media containing either Tween 80 alone or Tween 80 supplemented with
free oleic acid (Fig. 2), these data indicate that free oleic acid is a
better substrate for PHA synthesis in yeast than is the esterified
oleic acid found in Tween 80. Addition of 0.1% glucose to media
containing 0.5% Tween 80 and 0.1% oleic acid led to an increase of
PHA to 0.35% (dwt). Recombinant yeast grown in media containing 0.1%
glucose and 2% Pluronic-127 shows less than 0.01% PHA (Table 1),
similar to cells grown in media containing only 0.1% or 2% glucose
(data not shown). In contrast, cells grown in media supplemented with 0.1% glucose, 2% Pluronic-127, and 0.1% oleic acid produced 0.31% (dwt) PHA. No PHA could be detected in cells that were transformed with
the control vector pYE352-CTA1 (which harbors the peroxisomal catalase
gene) and were grown in media containing oleic acid (Fig. 3). Together, these data show that PHA
synthesis in recombinant yeast is dependent on the presence of both a
PHA synthase and an external source of fatty acids.
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FIG. 3.
GC-MS analysis of PHA produced in transgenic yeast
expressing the PHA synthase. Yeast cells transformed with the control
vector pYE352-CTA1 (A) or the plasmid pYE352-PHA harboring the PHA
synthase gene (B) were grown for 3 days in media containing 2%
Pluronic-127, 0.1% glucose, and 0.1% oleic acid, and the PHA was
analyzed as described in Materials and Methods. Only ions with a
mass-to-charge ratio of 103 are shown. The various 3-hydroxy acids are
identified with the prefix H. The y axes in panels A and
B are on the same scale.
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The amount of PHA in cells, as well as concentrations of oleic acid and
glucose in the media, were monitored over 6 days after
the shift of
cells to media containing 0.1% glucose, 2% Pluronic-127,
and 0.1%
oleic acid (Fig.
4). The amount of
glucose in the media
was below detection (<0.002%) after 24 h,
while oleic acid decreased
only slightly to 0.09%. PHA accumulated in
cells until day 5,
in parallel with the decrease in the amount of free
oleic acid
in the media. At days 5 and 6, PHA was found in
S. cerevisiae at 0.43 to 0.45% (dwt).
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FIG. 4.
Time course of the accumulation of PHA in
S. cerevisiae. Recombinant yeast was used
to inoculate media containing 0.1% glucose, 2% Pluronic-127, and
0.1% oleic acid. PHA content ( ) in cells and the concentration of
oleic acid ( ) present in the media were monitored over 6 days.
Values represent the mean and standard deviation of four measurements.
w/dwt, weight/dwt; v/v, vol/vol.
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PHA inclusions detected by electron microscopy.
Wild-type and
recombinant cells grown for 3 days in media containing oleic acid were
analyzed by transmission electron microscopy (TEM). While both types of
cells showed the presence of numerous oil bodies (Fig.
5A and B), only recombinant cells
producing PHA showed the presence of small electron-lucent inclusions
within membrane-bound organelles (Fig. 5B to D). The apparent size of these inclusions is in the range of 0.1 to 0.2 µm in diameter. Both
the size and general appearance of these inclusions, as seen by TEM,
are very similar to PHA granules found in bacteria (2, 30)
as well as in transgenic plants (25, 29), indicating that,
similar to PHA synthesized in these other hosts, PHA produced in yeast
accumulates in the form of inclusions.
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FIG. 5.
Analysis of PHA inclusions in S.
cerevisiae. The wild-type (A) or recombinant yeast
expressing the PHA synthase gene (B to D) was used to inoculate media
containing 0.1% glucose, 2% Pluronic-127, and 0.1% oleic acid and
was grown for 4 days before being processed for TEM. Panels C and D are
close-up views of panel B. Arrows indicate the presence of PHA
inclusions within membrane-bound organelles. ob, oil body. Bars
indicate 1 µm (A and B) and 0.5 µm (C and D).
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Composition of MCL-PHA produced in yeast.
In order to
determine the influence of the carbon source on PHA monomer
composition, recombinant yeast was grown for 4 days in media containing
0.1% glucose, 2% Pluronic-127, and 0.1% oleic acid or 0.1%
heptadecenoic acid (17:1 
10cis). Table
2 shows that the PHA monomer composition
is dependent on the nature of the external fatty acids and on the range
of 3-hydroxyacyl-CoA intermediates generated by the degradation of the
external fatty acid by the peroxisomal -oxidation pathway. PHA
synthesized in yeast growing on oleic acid (18:1 9cis)
contains even-chain 3-hydroxy acid monomers from 6 to 14 carbons in
length. The presence of both 3-hydroxytetradecanoic acid and
3-hydroxytetradecenoic acid agrees with the generation of the
corresponding acyl-CoA by the -oxidation of fatty acids having a
cis-unsaturated bond at an odd-numbered carbon (13,
17). Similarly, growth of recombinant yeast in media containing
17:1 10cis gave a PHA containing odd-chain monomers
ranging from 5 to 15 carbons, with two monomers being unsaturated
(Table 2). Together, these data show that external fatty acids are
imported into cells and degraded via the peroxisomal -oxidation
cycle and that 3-hydroxyacyl-CoAs generated by the -oxidation cycle
are used for the synthesis of MCL-PHA.
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DISCUSSION |
Expression in S. cerevisiae of a PHA
synthase from P. aeruginosa, modified at the
carboxy end by the addition of a peroxisome targeting signal, was shown
to lead to MCL-PHA synthesis in yeast growing in media containing fatty
acid. Expression of MCL-PHA was dependent on the promoter of the CTA1
gene encoding the peroxisomal catalase A. This gene was shown
previously to be repressed by glucose and activated by fatty acids
(19, 38). In consequence, the PHA synthase was found to be
expressed in cell cultures that had depleted the glucose initially
present in the media, as well as in cells growing in media containing
fatty acids.
Feeding experiments with oleic acid or heptadecenoic acid added to the
growth media clearly indicate that the monomers used in the synthesis
of MCL-PHA in yeast are derived from the -oxidation of the external
fatty acids. Thus, addition of heptadecenoic acid leads to the
synthesis of MCL-PHA containing odd-chain monomers, while addition of
oleic acid leads to the synthesis of a PHA containing even-chain
monomers. Furthermore, for each of these fatty acids, the monomers
found in PHA correspond to the 3-hydroxyacyl-CoAs generated by the
degradation of the external fatty acid through peroxisomal
-oxidation. Thus, degradation of the fatty acid 17:1 10cis, according to the pathway for the degradation of
fatty acids having a cis double bond at an even-numbered
carbon (13), is expected to lead to the production of the
three unsaturated 3-hydroxyacyl-CoAs, namely, H17:1 (the prefix H
refers to the 3-hydroxy moiety), H15:1, and H13:1, and of five
saturated 3-hydroxyacyl-CoAs, namely, H11, H9, H7, H5, and H3. All
these 3-hydroxy acids are found in the PHA synthesized in S. cerevisiae grown in 17:1 10cis, except for
H17:1 and H3, which fall outside the range of monomers generally
accepted by the P. aeruginosa PHA synthase.
Incorporation of 3-hydroxypentanoic acid in the yeast PHA is
interesting, since PHA synthesized by P. aeruginosa, as well as other by pseudomonads producing
MCL-PHAs, typically includes only monomers between 6 and 16 carbons
(40). It has been previously reported that expression of a
PHA synthase in a heterologous host may lead to the incorporation into
PHA of a range of monomers broader than that normally found in the
polymer of the native host (3, 6, 21). For example, while
Chromobacterium violaceum growing on fatty acids produces a
PHA containing only 3- or 4-carbon monomers, expression of the C. violaceum PHA synthase in R. eutropha leads to the synthesis of PHA containing in
addition a 6-carbon monomer (21). These studies
demonstrate that the PHA monomer composition is not only dependent on
the substrate specificity of the PHA synthase but also on the metabolic
environment of the host organism. Thus, in contrast to P. aeruginosa, the -oxidation cycle of yeast allows the
inclusion of 3-hydroxypentanoic acid into PHA.
Growth of recombinant yeast on oleic acid leads to the synthesis of PHA
containing even-chain monomers from 6 to 14 carbons that are generated
by the degradation of this fatty acid via the peroxisomal -oxidation
cycle, namely, H14:1, H14, H12, H10, H8, and H6. No 16-carbon 3-hydroxy
acids were detectable in the yeast PHA, even though expression of the
same PHA synthase in the peroxisome of the plant A. thaliana led to the incorporation of saturated and
unsaturated 16-carbon monomers in the PHA (25). It is
again likely that differences in the in vivo concentration or
availability of the 3-hydroxyhexadecanoyl-CoA intermediates between
S. cerevisiae and A. thaliana may influence the incorporation of 16-carbon
monomers into PHA.
PHA production in yeast is accompanied by the appearance of
electron-lucent inclusions within membrane-bound organelles. The size
and general appearance of these inclusions are very similar to PHA
granules found in bacteria or plants accumulating PHA. TEM, by itself,
cannot unambiguously identify the organelle containing the PHA
inclusions as being peroxisomes. However, all results obtained strongly
support the notion that PHA granules are found within the peroxisomes.
First, PHA synthesized in yeast is clearly derived from intermediates
of -oxidation of the fatty acids added to the media. Furthermore, we
have recently found that expression of the modified PHA synthase in the
fox1 mutant, deficient in the peroxisomal -oxidation
enzyme acyl-CoA oxidase, does not produce MCL-PHA (data not shown).
These data show that MCL-PHA synthesis depends directly on substrates
generated by the peroxisomal -oxidation cycle. Second, the PHA
synthase contains a peroxisomal targeting sequence that has been
clearly shown to direct foreign proteins to the peroxisome (1,
44). Finally, -oxidation is found to occur only in the
peroxisome in S. cerevisiae.
In bacteria and plants, PHAs are composed of the R isomer of
3-hydroxyalkanoic acids due to the stereospecificity of the PHA synthase, which accepts only R-3-hydroxyacyl-CoAs (15).
Since the core -oxidation cycle of bacteria, mammals, and plants
generates mainly the S isomer of 3-hydroxyacyl-CoAs from the hydration
of enoyl-CoAs by the enoyl-CoA hydratase I (17, 37),
synthesis of MCL-PHAs in these organisms implicates the presence of
enzymes which can convert intermediates of -oxidation to
R-3-hydroxyacyl-CoAs. In several bacteria synthesizing MCL-PHAs from
alkanoic acids, an R-specific enoyl-CoA hydratase II has been
identified which converts the -oxidation intermediate
trans-2-enoyl-CoAs to R-3-hydroxyacyl-CoAs (11,
33). Furthermore, a 3-ketoacyl-ACP reductase has also been
identified in E. coli and P. aeruginosa which can contribute to the synthesis of
R-3-hydroxyacyl-CoAs from 3-ketoacyl-CoA (34, 42). In
plants, a range of R-3-hydroxyacyl-CoAs is thought to be generated by
either a monofunctional enoyl-CoA hydratase II or the
3-hydroxyacyl-CoA epimerase activity found within the -oxidation multifunctional protein, which also harbors an enoyl-CoA hydratase I
and a 3-hydroxyacyl-CoA dehydrogenase (8, 31).
In contrast to bacteria, plants, and animals, many fungi, including
S. cerevisiae and Candida tropicalis,
have a -oxidation cycle that normally occurs through
R-3-hydroxyacyl-CoA intermediates. This is because these organisms
have only an R-specific enoyl-CoA hydratase II instead of an S-specific
enoyl-CoA hydratase I (18). It was thus expected that
S. cerevisiae would be a good host for the
synthesis of MCL-PHAs from the intermediates of fatty acid -oxidation. However, PHA synthesis in yeast is 1 or 2 orders of
magnitude lower then MCL-PHA production in several pseudomonads. For
example, growth of P. putida in media containing
oleic acid gives an accumulation of 37% MCL-PHA (7),
while in this study recombinant S. cerevisiae
accumulates a maximum of 0.45% PHA. Although one should be cautious
about comparing PHA synthesis in bacteria grown in fermentors and yeast
cultures grown in shake flasks, these studies nevertheless indicate
that PHA synthesis in yeast is suboptimal compared to bacterial
production. This raises the interesting question of the biochemical
basis of this difference.
Interestingly, although the isomers of 3-hydroxyacyl-CoA generated by
the -oxidation cycle in yeast and plants are different, the levels
of PHA synthesized in the peroxisome of these two organisms are similar
at 0.4% (dwt) (24, 25). These results indicate that the
stereospecificity of the substrate generated by the core -oxidation
cycle may not be the only factor influencing PHA synthesis from
-oxidation intermediates. Although it is possible that some of the
factors limiting MCL-PHA synthesis in yeast and plants may be
different, the pathways of degradation of fatty acids is sufficiently
similar between these organisms to consider using the power of yeast
genetics as a tool to understand how more intermediates from the
peroxisomal -oxidation cycle can be channeled towards PHA and to
apply this knowledge to the production of MCL-PHA in plants.
| |
ACKNOWLEDGMENTS |
This research was funded by the Etat de Vaud.
We thank Silvia Marchesini for help with the figures and Kalervo
Hiltunen for providing the plasmid pYE352-CTA1.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratoire de
Biotechnologie Végétale, Institut d'Écologie,
Université de Lausanne, CH-1015 Lausanne, Switzerland. Phone: 41 21 692 4222. Fax: 41 21 692 4195. E-mail:
yves.poirier{at}ie-bpv.unil.ch.
| |
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Applied and Environmental Microbiology, November 2001, p. 5254-5260, Vol. 67, No. 11
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.11.5254-5260.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
