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Journal of Bacteriology, January 2000, p. 365-370, Vol. 182, No. 2
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
-Ketoacyl-Acyl Carrier Protein Synthase III (FabH) Is a
Determining Factor in Branched-Chain Fatty Acid Biosynthesis
Keum-Hwa
Choi,1
Richard J.
Heath,1 and
Charles O.
Rock1,2,*
Department of Biochemistry, St. Jude
Children's Research Hospital, Memphis, Tennessee
38105,1 and Department of
Biochemistry, University of Tennessee, Memphis, Tennessee
381632
Received 11 August 1999/Accepted 27 October 1999
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ABSTRACT |
A universal set of genes encodes the components of the dissociated,
type II, fatty acid synthase system that is responsible for producing
the multitude of fatty acid structures found in bacterial membranes. We
examined the biochemical basis for the production of branched-chain
fatty acids by gram-positive bacteria. Two genes that were predicted to
encode homologs of the 
-ketoacyl-acyl carrier protein synthase III
of Escherichia coli (eFabH) were identified in the
Bacillus subtilis genome. Their protein products were
expressed, purified, and biochemically characterized. Both B. subtilis FabH homologs, bFabH1 and bFabH2, carried out the initial condensation reaction of fatty acid biosynthesis with acetyl-coenzyme A (acetyl-CoA) as a primer, although they possessed lower specific activities than eFabH. bFabH1 and bFabH2 also utilized iso- and anteiso-branched-chain acyl-CoA primers as substrates. eFabH
was not able to accept these CoA thioesters. Reconstitution of a
complete round of fatty acid synthesis in vitro with purified E. coli proteins showed that eFabH was the only E. coli
enzyme incapable of using branched-chain substrates. Expression of
either bFabH1 or bFabH2 in E. coli resulted in the
appearance of a branched-chain 17-carbon fatty acid. Thus, the
substrate specificity of FabH is an important determinant of
branched-chain fatty acid production.
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INTRODUCTION |
Bacteria synthesize fatty acids by
using the type II, or dissociated, fatty acid synthase system. This
biosynthetic pathway has been studied primarily in Escherichia
coli, providing a fairly complete picture of the mechanisms that
govern the synthesis of straight-chain saturated and unsaturated fatty
acids (for reviews, see references 7, 24, and
25). The pathway consists of a collection of
individual proteins encoded by unique genes that function in concert to
produce the variety of fatty acid products found in bacteria. The
genomes of a number of bacteria are now known, and all these organisms
possess a highly related, and clearly identified, set of genes that
carry out the reactions in the pathway. E. coli and many
other gram-negative bacteria synthesize even-chain saturated and
unsaturated fatty acids. Fatty acid synthesis is initiated by the
condensation of acetyl-coenzyme A (acetyl-CoA) with malonyl-acyl
carrier protein (malonyl-ACP) by -ketoacyl-ACP synthase III, the
product of the fabH gene (14, 15, 31). However,
other bacteria produce such a great variety of fatty acid structures
that E. coli cannot be considered typical (25).
Many gram-positive organisms, such as the bacilli, staphylococci,
and streptomycetes, produce odd- and even-carbon-number branched-chain
fatty acids (20). These branched-chain fatty acid structures
have either iso- or anteiso-methyl branches, and it is tenable to
hypothesize that the FabH component in organisms like B. subtilis would be able to accept isovaleryl-CoA, isobutyryl-CoA, and 2-methylbutyryl-CoA as primers to produce these fatty acids. Thus, earlier work by Butterwork and Bloch
(5), showing that acyl-CoA:ACP transacylase
activity, one of the reactions catalyzed by FabH (31), in
Bacillus cell extracts was selective for branched-chain acyl-CoAs is consistent with the idea that bFabH prefers these primers.
Genetic experiments with B. subtilis demonstrate that these
CoA thioesters are essential intermediates in fatty acid synthesis and
arise from iso- and anteiso-branched 
-keto acids derived from
the biosynthetic pathways for the amino acids valine, leucine, and
isoleucine (33, 34). The enzyme responsible for the
formation of these acyl-CoAs is a specialized branched-chain -keto
acid dehydrogenase complex, and mutations in the activity of this
enzyme system result in strains that are auxotrophic for branched-chain
acids (34). The Streptomyces glaucescens FabH enzyme efficiently utilizes both butyryl-CoA and isobutyryl-CoA and is
thought to be responsible for initiating branched-chain fatty acid
synthesis in this organism (10). eFabH is selective for
acetyl-CoA (12, 14, 15, 31), and its low activity with
butyryl-CoA (12) suggests that bulkier branched-chain CoA thioesters may not be substrates, although this idea has not been experimentally tested. In addition to the FabH component, it is also
possible that all of the enzymes of the elongation cycle in
gram-negative organisms (FabF, FabG, FabZ, and FabI) cannot utilize
branched-chain intermediates. The goal of this study was to
biochemically characterize the FabH enzymes of B. subtilis and determine if the FabH component is unique among the enzymes of type
II fatty acid synthases in its selectivity toward branched-chain intermediates.
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MATERIALS AND METHODS |
Materials.
Sources of supplies were as follows:
Amersham-Pharmacia Biotechnology ([2-14C]malonyl-CoA;
specific activity, 56.0 Ci/mol); DuPont-New England Nuclear
([1-14C]acetyl-CoA; specific activity, 45.8 Ci/mol);
Sigma (fatty acids, ACP, and acyl-CoAs); and Matreya, Inc. (fatty acid
methyl esters). Proteins were quantitated by the Bradford method by
using gamma globulin as a standard (4). The E. coli FabH, FabG, FabA, FabZ, FabI, and FabD proteins were purified
as described previously (11-13). All other chemicals were
of reagent grade or better.
Construction of expression vectors and purification of the
His-tag proteins.
The fabH1 and fabH2 genes
were amplified from genomic DNA isolated from B. subtilis. Primers created novel restriction sites for
XhoI or NdeI at the amino terminus of the
predicted coding sequence and BamHI immediately downstream
of the stop codon. The fabH1 PCR primer pair consisted of
5'-CTCGAGAAAGCTGGAATACTTGGTGTTG-3' and
5'-GGATCCTCTTGTGTGCACCTCACCT-3', and the fabH2
primer pair consisted of 5'-GTGAGGTGCACACCATATGACTAAA-3' and
5'-GGATCCGGAAGAAACATCAGAAGAACAG-3'. The PCR products were
ligated into plasmid pCR2.1 (Invitrogen) and transformed into E. coli INVF'. Plasmids were isolated and digested with either
XhoI and BamHI for fabH1 or
NdeI and BamHI for fabH2. The
fragments were isolated and ligated into plasmid pET-15b digested with
XhoI and BamHI or with NdeI and
BamHI. These ligation mixtures were used to transform strain
BL21(DE3). One clone was chosen for each gene, and the insert DNA was
sequenced to verify the absence of any PCR artifacts. The proteins were purified as described previously (12).
Enzyme assays.
A filter disc assay was used to assay the
activity of the FabH proteins with acetyl-CoA as the substrate
essentially as described by Tsay et al. (31). The assays
contained 25 µM ACP, 1 mM -mercaptoethanol, 65 µM malonyl-CoA,
45 µM [1-14C]acetyl-CoA (specific activity, 45.8 Ci/mol), E. coli FabD (0.2 µg), and 0.1 M sodium phosphate
buffer (pH 7.0) in a final volume of 40 µl. The reaction was
initiated by the addition of FabH, and the mixture was incubated at
37°C for 12 min. A 35-µl aliquot was then removed and deposited on
a Whatman 3MM filter disc. The discs were washed with three changes (20 ml/disc for 20 min each) of ice-cold trichloroacetic acid. The
concentration of the trichloroacetic acid was reduced from 10 to 5 to
1% in each successive wash. The filters were dried and counted in 3 ml
of scintillation cocktail.
The second FabH assay used gel electrophoresis to separate and
quantitate the products (12). This assay mixture contained 25 µM ACP, 1 mM -mercaptoethanol, 70 µM
[2-14C]malonyl-CoA (specific activity, 9.4 Ci/mol), 45 µM substrate (acetyl-CoA, propionyl-CoA, butyryl-CoA, isobutyryl-CoA,
valeryl-CoA, isovaleryl-CoA, hexanoyl-CoA, heptanoyl-CoA, octanoyl-CoA,
or 2-methylbutyryl-CoA), FabD (0.2 µg), 100 µM NADPH, FabG (0.2 µg), and 0.1 M sodium phosphate buffer (pH 7.0) in a final volume of 40 µl. The reaction was initiated by the addition of FabH, the mixture was incubated at 37°C for 12 min and then placed in an ice
slurry, gel loading buffer was added, and the mixture was loaded onto a
conformationally sensitive 13% polyacrylamide gel containing 0.5 to
2.0 M urea depending on the chain length of the acyl-ACP product
(10-12). Electrophoresis was performed at 25°C and 32 mA/gel. The gels were dried, and the bands were quantitated by exposure
of the gel to a PhosphoImager screen. Specific activities were
calculated from the slopes of the plot of product formation versus FabH
protein concentration in the assay.
Synthesis of 2-methylbutyryl-CoA.
2-Methylbutyryl-CoA was
synthesized from the mixed acid anhydride of 2-methylbutyric acid by a
modified method of the thiol ester synthesis described by Stadtman
(27). To prepare the mixed acid anhydride, 10 mmol of
2-methylbutyric acid and 10 mmol of pyridine were dissolved in
anhydrous ethyl ether (at 0°C), and 10 mmol of ethylchloroformate was
added dropwise with stirring. The mixture was left at 0°C for 1 h, and the insoluble pyridine hydrochloride was then removed by
centrifugation. The yield of mixed acid anhydride was determined by
using the hydroxylamine-ferric chloride method (26). To form
acyl-CoA derivatives, 75 µmol of the mixed acid anhydride was added
dropwise with shaking to a cold aqueous solution containing 18.7 µmol
of CoA-SH in 0.2 M KHCO3 (adjusted to pH 7.5). The pH was
then adjusted to 6.0 with 1 M HCl, and then the aqueous layer was
extracted three times with an equal volume of ethyl ether. The last
traces of ether were removed from the aqueous solution by bubbling with
nitrogen, and the final product, 2-methylbutyryl-CoA, was quantitated
with the hydroxylamine-ferric chloride method (26).
Reconstitution of fatty acid synthesis in vitro.
A single
cycle of fatty acid elongation was reconstituted in vitro by
sequentially adding the individual enzymes that catalyzed each reaction
in the cycle as described by Heath and Rock (11). The
reaction mixtures included, in a volume of 40 µl, 50 µM ACP, 1 mM
-mercaptoethanol, 0.1 M Na2PO4 (pH 7.4), 100 µM NADPH, 100 µM NADH, 65 µM acetyl-CoA or isovaleryl-CoA, and 30 µM [2-14C]malonyl-CoA (specific activity, 56.0 Ci/mol),
and the individual proteins were added at concentrations of 0.2 µg/reaction mixture. The assay mixtures were incubated for 20 min at
37°C and analyzed by conformationally sensitive gel electrophoresis
in 13% polyacrylamide gels containing 0.5 M urea for acetyl-CoA and
1.0 M urea for isovaleryl-CoA. Product formation was quantitated with a PhosphoImager.
Fatty acid analysis.
Plasmids were constructed to express
bFabH1 and bFabH2 in E. coli by digesting the expression
vectors with XbaI and BamHI and placing the
inserts into pBluescript. Colonies of E. coli SJ53 harboring
either the pKHC1 (bFabH1), pKHC2 (bFabH2), or pBluescript (control)
plasmid were grown on M9 minimal agar medium (22) supplemented with 0.1% Casamino Acids, 0.4% glycerol, 0.01%
methionine, 0.0005% thiamine, 100 µM -alanine, and 50 µg of
ampicillin per ml, harvested from the plates, and collected by
centrifugation. The cell pellets were extracted as described by Bligh
and Dyer (3), and fatty acid methyl esters were
prepared by using HCl-methanol. The fatty acid methyl esters were
fractionated with a Hewlett-Packard model 5890 gas chromatograph
equipped with a flame ionization detector. Separations were performed
with a glass column (2 m by 4 mm, internal diameter) containing
Supelcoport (100/120 mesh) coated with 3% SP2100 at 190°C. The
injector temperature was 270°C, the detector temperature was 190°C,
and the flow rate of the carrier gas (nitrogen) was 40 ml/min. Fatty
acid methyl esters were identified by comparing their retention times
with branched-chain and straight-chain fatty acid methyl ester
standards (Matreya). The fatty acid compositions were expressed as
weight percent.
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RESULTS |
Identification of putative FabH homologs in B. subtilis.
The E. coli FabH sequence (31) was used to search
the B. subtilis genome (21) for related
sequences. This analysis identified two open reading frames that
encoded putative FabH sequences that we named bFabH1 and bFabH2 (Fig.
1). bFabH1 corresponded to open reading
frame yjaX. This open reading frame consisted of 971 bp predicted to encode a protein that was 45% identical and 56% similar to E. coli FabH. The second FabH homolog, bFabH2,
corresponded to the 973-bp open reading frame yhfB. bFabH2
was 38% identical and 48% similar to the E. coli FabH
enzyme. bFabH1 was 46% identical and 54% similar to bFabH2. These
data showed that there were two putative FabH condensing enzymes in
Bacillus.
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FIG. 1.
Comparison of the amino acid sequences of E. coli FabH with B. subtilis FabH1 and FabH2. Identical
amino acids shared by any two of the FabH proteins are shaded in black.
The active site Cys is denoted by an asterisk, and the putative
acetyl-CoA binding site between residues 156 and 167 is denoted by gray
shading (31).
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The two open reading frames for the predicted bFabH proteins were
amplified by PCR and cloned into the pET15-b vector, and
the His-tagged
versions of the proteins were expressed and purified
(Fig.
2). The tagged bFabH1 protein exhibited a
molecular size
of 42.7 kDa, and the bFabH2 protein had an apparent size
of 39.8
kDa, as compared to the 37.6-kDa eFabH.
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FIG. 2.
Expression and purification of FabH proteins. The FabH
proteins were expressed as His-tag fusion proteins and purified by
Ni2+-chelate affinity chromatography as described in
Materials and Methods. Samples were analyzed by using sodium dodecyl
sulfate gel electrophoresis through a 12% polyacrylamide gel, and the
proteins were visualized by staining with Coomassie blue.
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Substrate specificity of B. subtilis FabHs.
Two
assays were used to determine the specific activity of B. subtilis and E. coli FabH enzymes with
acetyl-CoA. The filter disc assay, using
[14C]acetyl-CoA, relied on trapping the
-[14C]ketobutyryl-ACP product (14).
eFabH was the most active enzyme in this assay, with bFabH2 having
about 20% of the activity of eFabH and bFabH1 having 2.5% of the
activity of eFabH (Table 1). The
filter disc assay is a reliable, sensitive, and rapid method to
determine FabH activity (12, 31) but can only be used when a 14C-labeled primer is available. Therefore, we
employed a second assay to determine the activity of the enzymes for
branched-chain primers based on the incorporation of
[2-14C]malonyl-CoA and the separation of products by
conformationally sensitive gel electrophoresis and quantitation of
product formation by PhosphoImager analysis (12). The
conversion of the product to the stable -hydroxyacyl-ACP was
necessary because the -ketoacyl-ACPs were unstable and were degraded
during the electrophoretic separation (12). Thus, saturating
concentrations of FabG plus NADPH were included to ensure reduction of
all of the -ketoacyl-ACPs formed to the corresponding stable
-hydroxyacyl-ACPs. When acetyl-CoA was the substrate in this assay,
the specific activity measurements were essentially the same as in the
filter disc assay (Table 1), indicating that both assays accurately
reflect the catalytic properties of the condensing enzymes. An example
of the electrophoretic assay system in the analysis of the utilization
of isovaleryl-CoA as a primer for the three FabH enzymes is shown in
Fig. 3. In this experiment, eFabH was
inactive with the isovaleryl-CoA, whereas bFabH2 was more active than
bFabH1 (see also Table 1). The band migrating faster than malonyl-ACP
in the eFabH experiment was acetyl-ACP, reflecting the malonyl-ACP
decarboxylase activity of the condensing enzyme.
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FIG. 3.
Utilization of an isovaleryl-CoA by FabH isoforms.
Assays contained E. coli FabH or B. subtilis
FabH1 or FabH2, E. coli FabD, FabG, ACP, NADPH,
isovaleryl-CoA (iso-C5:0), and [14C]malonyl-CoA as
described in Materials and Methods. The resulting
-OH-iso-C7:0-ACP was detected with a PhosphoImager
following conformationally sensitive gel electrophoresis in 13%
polyacrylamide containing 1.0 M urea. The amount of label
incorporated into -OH-iso-C7:0-ACP was determined by using
a PhosphoImager system that was calibrated with a standard curve of
[14C]malonyl-CoA that was exposed at the same time as the
gel. (A) E. coli FabH; (B) B. subtilis FabH1; (C)
B. subtilis FabH2; (D) the specific activities of E. coli FabH, B. subtilis FabH1, and FabH2 calculated from
the slopes of the lines obtained from plotting the nanomoles of
-OH-iso-C7:0-ACP per minute versus the protein concentration in the
assay. Symbols:  , E. coli FabH;  , B. subtilis FabH1;  , B. subtilis FabH2.
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The specific activities for a range of acyl-CoA primers were determined
for all three enzymes (Table
1). As reported previously
(
12), eFabH was most active with acetyl-CoA, had
considerably
reduced activity (0.2%) with butyryl-CoA, and was
inactive with
longer chain lengths. Most importantly, we did not detect
any
activity of eFabH when branched-chain acyl-CoA primers were used.
The bFabH1 protein exhibited a low activity with acetyl-CoA but
was
active with 4- to 8-carbon straight-chain acyl-CoA and all
branched-chain acyl-CoAs. The bFabH2 protein was more active than
the
bFabH1 enzyme with acetyl-CoA, but like bFabH1 it readily
utilized 4- and 5-carbon straight-chain acyl-CoAs and the three
branched-chain
acyl-CoAs tested. Whereas bFabH1 and bFabH2 did
not have markedly
dissimilar specific activities, bFabH1 did have
a slight preference for
the anteiso precursor, 2-methylbutyryl-CoA,
while bFabH2 was more
active with the iso precursors, isobutyryl-CoA
and isovaleryl-CoA.
These data illustrate that the ability to
use branched-chain acyl-CoA
primers distinguishes the
B. subtilis FabH enzymes from
E. coli FabH.
Specificity of other Fab enzymes for branched-chain
substrates.
The finding that eFabH does not accept branched-chain
primers suggested that the other enzymes in the E. coli
fatty acid synthase might also be selective against branched-chain
intermediates. This idea was tested by reconstituting one complete
round of fatty acid synthesis by using either eFabH or bFabH2 to form
the initial intermediates and the other Fab enzymes to complete the
cycle (Fig. 4). The control experiment
with all E. coli enzymes and acetyl-CoA (Fig. 4A) gave the
expected distribution of products at each step and efficient formation
of butyryl-ACP (11). As expected, there was no formation of
products when eFabH was used as the initiator enzyme and isovaleryl-CoA
was used as the primer (Fig. 4B). The bFabH2 enzyme was less active
with acetyl-CoA, but nonetheless butyryl-ACP was formed as anticipated
(Fig. 4C). Importantly, the E. coli enzymes in conjunction
with bFabH2 were able to generate isoheptanoyl-ACP from isovaleryl-CoA
(Fig. 4D). These data demonstrated that eFabH selected
against branched-chain primers but that the other enzymes in the
pathway were able to use either straight-chain or branched-chain
intermediates.
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FIG. 4.
FabH substrate specificity governs the synthesis of
branched-chain fatty acids. A complete cycle of fatty acid synthesis
was reconstituted from purified components by using combinations of
FabD, FabG, FabI, FabA, or FabZ enzymes (0.2 µg/assay) purified from
E. coli and either E. coli FabH (0.2 µg/assay)
or B. subtilis FabH2 (0.2 µg/assay), ACP, NADH, NADPH,
acetyl-CoA, or isovaleryl-CoA with [14C]malonyl-CoA as
the label as described in Materials and Methods. Acetyl-CoA was used as
the primer in panels A and C, whereas isovaleryl-CoA was used as a
primer in panels B and D. The products were analyzed by
conformationally sensitive gel electrophoresis through 13%
polyacrylamide gels containing either 0.5 M urea (A and C) or 1.0 M
urea (B and D). Products were visualized and quantitated with a
PhosphoImager.
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One interesting point from these experiments was that the ratios of
products from the FabA and FabZ dehydratases were different
depending
on the nature of the substrate. With the straight-chain
4-carbon
intermediates, crotonyl-ACP was a minor component and
the
-hydroxyacyl-ACP was predominant as described previously
by our
laboratory (
11,
13). In contrast, when the
long-straight-chain
(
11,
13) or branched-chain (Fig.
4)
substrates were used,
the enoyl-ACP intermediate was present in
greater abundance. Figure
4 is an example of this different product
distribution (compare
panels C and D), but it was the same regardless
of the structure
of the branched-chain substrate (data not shown). It
will be interesting
to determine whether the FabZ component of
B. subtilis fatty acid
synthase gives rise to a product distribution
skewed toward the
-hydroxyacyl-ACP or enoyl-ACP side of the
reaction. The answer
to this question would have important implications
with regard
to whether FabI plays the same role in controlling fatty
acid
biosynthesis in gram-positive bacteria as it does in
E. coli (
11).
Formation of branched-chain fatty acids in E. coli.
The in vitro enzymology suggested that a
branched-chain-specific FabH was necessary and sufficient for the
formation of branched-chain fatty acids by type II fatty acid
synthase systems. This idea was tested in vivo by the transformation of
E. coli SJ53 (panD fadE metB) with
constructs that expressed the various FabH proteins followed by the
chromatographic analysis of the cellular fatty acid composition (Table
2). The control experiments with the empty vector showed that the cells had the normal composition of
straight-chain saturated and unsaturated fatty acids typical of
E. coli. In contrast, transformation of strain SJ53 with
plasmids expressing either bFabH1 or bFabH2 resulted in the appearance of branched-chain 17-carbon fatty acids in the cellular lipids. These
data illustrate that the substrate specificity of FabH is a key
determinant of branched-chain fatty acid synthesis by type II fatty
acid synthases.
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DISCUSSION |
Our results lead to the conclusion that the substrate specificity
of the FabH condensing enzyme is the determining factor in the
biosynthesis of branched-chain fatty acids by type II fatty acid
synthases. The high degree of specificity of E. coli FabH for acetyl-CoA noted in this work and in previous studies
(12, 14, 15, 31) provides a solid rationale for the
exclusion of branched-chain acyl-CoA primers and the absence of
iso- and anteiso-branched fatty acids in this organism. In contrast,
the FabH enzymes from the gram-positive B. subtilis are less
active with acetyl-CoA and readily utilize branched-chain acyl-CoA
primers. The ability of bFabH1 and bFabH2 to use branched-chain primers correlates with higher activities with straight-chain 4-, 5-, and
6-carbon primers. The substrate specificities of the B. subtilis FabH1 and FabH2 enzymes are consistent with previous data
on the incorporation of exogenous branched-chain precursors into
cellular fatty acids (16, 18, 19) and the proposed origin of
the primers for branched-chain amino acids by a specialized -keto acid dehydrogenase complex (20, 23). A single FabH protein from Streptomyces glaucescens which also uses both
isobutyryl-CoA and butyryl-CoA as primers has been characterized
(10). Thus, the FabH proteins from organisms that produce
branched-chain fatty acids exhibit a broader substrate specificity than
the FabH enzymes from an organism which produces straight-chain fatty
acids and is highly selective for acetyl-CoA. The FabH components of
the type II polyketide synthases are also the determining
factor in primer selectivity in antibiotic synthesis (1).
The other enzymes in the type II fatty acid biosynthetic pathway do not
have a significant degree of selectivity for either branched-chain or
straight-chain fatty acids. Reconstitution of an elongation cycle in
vitro showed that FabG, FabZ, and FabI of E. coli all were
capable of utilizing the branched-chain acyl-ACP substrates. This
finding was corroborated by the fact that expression of either the
B. subtilis FabH1 or FabH2 proteins in E. coli
resulted in the production of 17-carbon branched-chain fatty
acids. The converse is also true. The expression of B. subtilis
fabI complements the phenotype of an E. coli fabI(Ts)
mutant and restores normal fatty acid composition, illustrating that
the gram-positive FabI is capable of using unsaturated straight-chain
enoyl-ACP as well as saturated branched- and straight-chain enoyl-ACP
(R. J. Heath and C. O. Rock, unpublished observations).
The broad substrate specificity of the bFabH proteins suggests that the
supply of precursors is a significant factor in determining the
composition of fatty acids produced by B. subtilis fatty acid synthase. Feeding B. subtilis
branched-chain acids increases the levels of the corresponding
long-chain branched fatty acids, whereas the addition of butyrate
to the medium increased the formation of straight-chain fatty acids
(16). The addition of exogenous leucine or valine to
cultures of S. glaucescens resulted in a concomitant
increase in the relevant branched-chain fatty acid derived from these
precursors (29). It was noted previously that the largest
component of the branched-chain fatty acid profile was related to the
relative size of metabolic pools of -ketoisocaproate, -keto--methylvalerate, and -ketoisovalerate (17,
20). These -keto acids are present at much lower intracellular
concentrations than the corresponding amino acids in E. coli, due to the high affinities of the transaminases for the
-keto acids compared to the corresponding amino acids
(32). Although pyruvate dehydrogenase will also accept
branched-chain -keto acids as substrates at a low rate, a
specialized -keto acid dehydrogenase is critical for generating the
branched-chain acyl-CoA primers for FabH in Bacillus
(23).
The physiological significance of two FabH enzymes in
B. subtilis is not clear. Other organisms with
type II fatty acid synthase systems contain only a single
fabH homolog in their genomes. These include E. coli (2), Rickettsia prowazekii
(6), Clamydia trachomatis (28),
Aquifex aeolicus (8), Helicobacter
pylori (30), and Haemophilus influenzae
(9). There are no major differences in substrate
specificity (straight-chain versus branched, or iso- versus
anteiso-branched primers) that clearly distinguish the two
Bacillus enzymes, as might have been expected. The bFabH1 protein appears certain to participate in the type II fatty acid synthase system based on its genetic association with a
fabF homolog. FabF and FabB are condensing enzymes that
carry out the subsequent elongation reactions in fatty acid synthesis,
and there is only a single FabF/B homolog in B. subtilis.
Analysis of the Bacillus FabF (yjaY) sequence predicted a
protein that was 22% identical and 30% similar to E. coli
fabF and 21% identical and 30% similar to E. coli
fabB. The yjaY open reading frame was located
immediately downstream of yjaX, and the two genes appear to
form an operon. The organization of the fabH1
(yjaX) and fabF (yajY) genes in a
single transcriptional unit argues that these two proteins act in
concert in the B. subtilis type II fatty acid synthase. The differential inhibition of branched-chain fatty acid synthesis in
relation to straight-chain fatty acid production by thiolactomycin in
S. glaucescens may be interpreted as evidence for two FabH enzymes in this organism; however, the similar experiment with B. subtilis did not provide evidence for two mechanisms for
initiation (10). It seems likely that fabH1 is a
constitutively expressed initiator of fatty acid synthesis and that
fabH2 expression may be regulated by environmental or
developmental signals to modify membrane fatty acid composition.
Alternatively, it is possible that bFabH2 participates in a
biosynthetic pathway that is distinct from fatty acid synthesis, for
example, the production of a secondary metabolite.
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ACKNOWLEDGMENTS |
We thank Magdalena Kaminska for excellent technical assistance.
This work was supported by National Institutes of Health Grant GM
34496, Cancer Center (CORE) Support Grant CA 21765, and the American
Lebanese Syrian Associated Charities.
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FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry, St. Jude Children's Research Hospital, 332 N. Lauderdale, Memphis, TN 38105-2794. Phone: (901) 495-3491. Fax: (901)
525-8025. E-mail: charles.rock{at}stjude.org.
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Abstract
Introduction
