Characterization of a novel long-chain acyl-CoA
thioesterase from Alcaligenes faecalis
Puja Shahi*
†
, Ish Kumar*
‡
, Ritu Sharma, Shefali Sanger and Ravinder S. Jolly
Institute of Microbial Technology, Chandigarh, India
Long-chain acyl-CoA thioesterases (EC 3.1.2.2) hydro-
lyze acyl-CoA esters to nonesterified fatty acids and
coenzyme A (CoASH) [1]. These are ubiquitously
expressed in bacteria, yeast, plants and mammals, and
in most cell compartments, such as endoplasmic reticu-
lum, cytosol, mitochondria and peroxisomes. Several
unrelated thioesterases have been purified to homogen-
eity from plants, animals, and bacteria, and the
cDNAs encoding several of them have been cloned
and sequenced [2–7]. Although the physiological func-
tions of these enzymes remain largely unknown, it is
speculated that they regulate lipid metabolism by
maintaining appropriate concentrations of acyl-CoA,
CoASH, and nonesterified fatty acids. The only estab-
lished function for acyl-CoA thioesterases is in the
termination of fatty acid synthesis in eukaryotes [8].
Two thioesterases, I and II, that cleave acyl-CoA
molecules in vitro have been characterized from
Keywords
Alcaligenes faecalis; immunogold electron
microscopy; long-chain acyl-CoA;
p-nitrophenyl esters; thioesterase
Correspondence

to C
18
chain length with V
max
and K
m
of 3.58–9.73 lmolÆmin
)1
Æ(mg protein)
)1
and 2.66–4.11 lm, respect-
ively. A catalytically important histidine residue is implicated in the active
site of the enzyme. The thioesterase was active and stable over a wide
range of temperature and pH. Maximum activity was observed at 65 °C
and pH 10.5, and varied between 60% and 80% at temperatures of
25–70 °C and pH 6.5–10. The thioesterase also hydrolyzed p-nitrophenyl
esters of C
2
to C
12
chain length, but substrate competition experiments
demonstrated that the long-chain acyl-CoAs are better substrates for thio-
esterase than p-nitrophenyl esters. When assayed at 37 and 20 °C, the affin-
ity and catalytic efficiency of the thioesterase for palmitoleoyl-CoA and
cis-vaccenoyl-CoA were reduced approximately twofold at the lower tem-
perature, but remained largely unaltered for palmitoyl-CoA.
Abbreviations
DTNB, 5,5¢-dithiobis(2-nitrobenzoic acid); TEM, transmission electron microscopy.
2374 FEBS Journal 273 (2006) 2374–2387 ª 2006 IMTECH
Escherichia coli. Thioesterase I, encoded by the tesA

5-cis-tetradecadienoyl-CoA is diverted from the path-
way by conversion into 3,5-cis-tetradecadienoyl-CoA
by D
3
,D
2
-enoyl-CoA isomerase. The 3,5- intermediate,
which would strongly inhibit b-oxidation if allowed to
accumulate, is hydrolyzed and the resultant 3,5-tetra-
decadienoate is excreted into the growth medium. In
another study, Zheng et al. [16] coexpressed thioest-
erase II with (R)-3-hydroxydecanoyl–acyl carrier pro-
tein-CoA transacylase (PhaG, encoded by the phaG
gene) to clarify the physiological role of thioesterase II.
3-Hydroxydecanoic acid was produced in E. coli by
mobilizing PhaG. By using an isogenic tesB (encoding
thioesterase II)-negative knockout E. coli strain, CH01,
it was found that the expression of tesB and phaG can
up-regulate each other. In addition, 3-hydroxydecanoic
acid was synthesized from glucose or fructose by
recombinant E. coli harboring phaG and tesB. This
study supports the hypothesis that the physiological
role of thioesterase II in E. coli is to prevent the
abnormal accumulation of intracellular acyl-CoA.
We have isolated a thioesterase from Alcaligenes
faecalis ISH108 and demonstrated its application in
chemoselective and racemization free deacylation of
thiol esters [17]. A. faecalis was isolated from soil sam-
ples during routine screening of micro-organisms for
various biotransformation applications. In this paper,

1-ol-saturated Tris ⁄ HCl buffer containing 0.1% Triton
X-100 [specific activity 2.43 lmolÆmin
)1
Æ(mg pro-
tein)
)1
].
As the specific activity in 1 m NaCl extract was the
highest, it was selected as the method of choice for the
isolation of the enzyme. SDS ⁄ PAGE of the NaCl
extract, run under reducing conditions, showed a prom-
inent band (> 90%) at 22 kDa, which suggested that
further purification of the protein could be achieved by
size exclusion chromatography. Preliminary investiga-
tion using Sephadex G-75 (fractionation range
3–80 kDa) revealed that the native size of the protein
was much larger as it moved into the void volume of
the column. This allowed ultrafiltration with a 50-kDa
Centricon membrane (Amicon, Bedford, MA, USA)
for concentration of the samples or buffer change. In
the first attempt, Sephacryl S-300 (fractionation range
10–1500 kDa) was selected for the purification of
protein. The NaCl extract obtained was desalted and
concentrated using 50-kDa Centricon membranes. The
concentrated sample was loaded on the column pre-
equilibrated with 50 mm Tris ⁄ HCl buffer (pH 7.6)
containing 150 mm NaCl. The column was eluted with
the same buffer at a flow rate of 24 mLÆh
)1
. Thioest-

stic acid at pH 8.0. An electron micrograph showed
granular structures with a mean diameter of 21.6 nm
(Fig. 3A). The size distribution is shown in Fig. 3B.
Intracellular localization of thioesterase
We carried out electron microscopic immunogold labe-
ling studies with ultrathin sections of Alcaligenes cells
to localize thioesterase at the ultrastructural level.
Polyclonal antibodies, AbTE-N and AbTE-D, raised
against purified native enzyme and the piece of gel cor-
responding to the 22-kDa monomeric protein on
SDS ⁄ PAGE, respectively, were assayed for their specif-
icity by western blotting. AbTE-D antibodies were
used to rule out any nonspecific binding that might
have occurred with AbTE-N because of the aggregated
nature of the native protein. The purified enzyme was
run on SDS ⁄ PAGE, and, after electroblotting on to
nitrocellulose membrane, it was probed with AbTE-N
and AbTE-D (Fig. 2C). Both antibodies identified the
22-kDa band corresponding to the monomer of thio-
esterase enzyme on denaturing gel.
Alcaligenes was grown to mid-exponential phase,
and, after several dehydration steps, embedded in LR
White resin, which was then dehydrated in several
steps. Optimal ultrastructural preservation required
inclusion of 0.2% glutaraldehyde in the fixative; the
reactivity of the antibody was not affected by glutaral-
dehyde fixation. Thin sections cut using an ultramicro-
tome were incubated with primary antibodies followed
by nanogold labeled secondary antibody as described
in Experimental procedures and visualized under the

Fraction No
51015202530
0.0
0.1
0.2
0.3
0.4
Lm/nim/lo
m
n
0
100
200
300
400
500
600
Fraction No
20 30 40 50 60 70
0.0
0.1
0.2
0.3
0.4
0.5
0.6
a
b
c
Fig. 1. Elution profile of thioesterase on gel filtration chromatogra-

by ultracentrifugation (100 000 g for 4 h). Most of the
thioesterase activity (> 80%) was present in the soluble
fraction, but the particulate fraction was also found to
be active. SDS ⁄ PAGE of both these fractions,
run under reducing conditions showed the presence of a
22-kDa protein (Fig. 2B). The particulate fraction on
incubation with 1 mL phosphate buffer, pH 7.0, con-
taining 1 m NaCl, released most of the activity. Total
proteins were combined and, after removal of particu-
lates, were concentrated to 2.5 mL by ultrafiltration
(3-kDa membrane; filtrate was devoid of thioesterase
activity). Then 1 mL of the concentrated protein was
applied to a Sephacryl S-300 gel-filtration column
(13 · 530 mm), pre-equilibrated with Tris ⁄ HCl buffer,
pH 7.5, containing 150 mm NaCl at a flow rate of
24 mLÆh
)1
and eluted in the same buffer. Fractions of
1.0 mL volume were collected and assayed, but thioest-
erase activity was detected only in the void volume.
SDS ⁄ PAGE of the void volume under reducing condi-
tions showed the presence of only 22-kDa protein.
Thus, we could identify only one thioesterase activity in
A. faecalis, in contrast with E. coli and Rhodopseudo-
monas sphaeroides, each of which contained two thio-
esterases; in addition, a third one has been implicated
in E. coli [2].
Mass spectrometry
Tandem MS was performed by Midwest Bio Services
(Overland Park, KS, USA) on an LCQ Deca XP Plus

14.2
kDa
kDa
2 1
1
3
2
1
2
3
A
B
C
Fig. 2. Purification of thioesterase, fraction-
ation of thioesterase activity and western
blot with antibodies to thioesterase. (A) Pro-
tein samples run on 12.5% SDS ⁄ PAGE after
purification. Lane 1, molecular mass marker;
lane 2, purified enzyme. (B) Fractionation of
thioesterase. The particulate and soluble
fractions, obtained by ultracentrifugation of
sonicated cells, were run on gel. Lane 1,
purified thioesterase; lane 2, membrane
fraction; lane 3, soluble fraction. (C) West-
ern blotting. Lane 1, marker; lane 2, antibod-
ies raised against purified protein (AbTE-N);
lane 3, antibodies raised against gel purified
and denatured protein (AbTE-D) were used
as primary antibody followed by horseradish
peroxidase-conjugated anti-rabbit IgG.

stearoyl-CoA (C
18:0
) was the most active substrate,
with the rate of hydrolysis decreasing with decreasing
chain length. The acyl-CoAs of chain length longer
than C
18
, were not studied. The rates of hydrolysis of
palmitoyl-CoA (C
16:0
) and myristoyl-CoA (C
14:0
)at
saturating concentrations were similar.
The enzyme showed very little activity towards octa-
noyl-CoA, which required a higher concentration of
enzyme for detectable activity. No activity was
observed with acyl-CoAs having chain length smaller
than C
8
. The thioesterase also possessed activity
towards unsaturated long-chain acyl-CoA derivatives.
V
max
and K
m
values were determined by least-squares
analysis of double-reciprocal plots of the data obtained
from the corresponding Michaelis–Menten plots.
V

most active substrate, with the activity decreasing
sharply with increasing or decreasing chain length.
Diameter
(
nm
)
10 15 20 25 30 35 40
selcitraP fo rebmuN
0
10
20
30
40
50
A
B
Fig. 3. TEM. The purified thioesterase was desalted and concentra-
ted by repeated ultrafiltration using a Centricon 50-kDa membrane
and suspended in water at a concentration of 600 lgÆmL
)1
.TEM
was performed on the carbon grid using 2% aqueous uranyl acet-
ate and 2% phosphotungstic acid at pH 8.0. (A) Electron micro-
graph showing granular particles with mean diameter 21.6 nm. (B)
Size distribution of the thioesterase particles in TEM. Particle size
distribution was evaluated by measuring the diameter of 100 parti-
cles. The diameter was the mean of two right angled axes.
Thioesterase of Alcaligenes faecalis P. Shahi et al.
2378 FEBS Journal 273 (2006) 2374–2387 ª 2006 IMTECH
p-Nitrophenyl acetate (C

bonate (from 1 m ethanol stock solution). A parallel
experiment was run as a control in which the addition
of substrate was omitted. The sample was incubated
for 5 min, and a 5-lL aliquot of each sample was
withdrawn and assayed for activity by the DTNB
method using stearoyl-CoA as substrate. (c) In an
analogous manner, when stearoyl-CoA was used as
AB
CD
Fig. 4. Transmission electron micrographs
of immunogold-labeled Alcaligenes treated
with various primary antibodies. Alcaligenes
cells were embedded in LR white resin as
described in Experimental procedures. Thin
sections were incubated with primary anti-
body raised against thioesterase, followed
by anti-rabbit IgG with conjugated nanogold
particles, and samples were analyzed under
the electron microscope. Different fields
were viewed. Arrowheads denote gold parti-
cles. (A) Primary antibody AbTE-N raised
against purified native thioesterase. (B)
Enlarged view of a single cell (bar, 200 nm).
(C) Primary antibody AbTE-D, raised against
a gel piece corresponding to the thioest-
erase band in SDS ⁄ PAGE. (D) Control in
which preimmune serum was used as pri-
mary antibody.
P. Shahi et al. Thioesterase of Alcaligenes faecalis
FEBS Journal 273 (2006) 2374–2387 ª 2006 IMTECH 2379

not have any significant effect on the thioesterase activ-
ity. Diethyl pyrocarbonate, a histidine-modifying agent,
caused total loss of activity at 1 mm concentration. The
thiol-reactive agent DTNB did not have a significant
effect on the thioesterase activity, allowing the use of
DTNB in the thioesterase assay. Picrylsulfonic acid, a
lysine-modifying agent, also had no effect on the activ-
ity of the enzyme. These results indicate the presence of
a catalytically important histidine residue in the
enzyme. The presence of a histidine residue was further
supported by the following experiments.
(a) Reversal of inhibition by hydroxylamine. The
activity of the enzyme could be partially recovered by
the treatment of diethyl pyrocarbonate-inhibited
enzyme with hydroxylamine. An aliquot of enzyme,
inactivated with 1 mm diethyl pyrocarbonate at 4 °C,
was incubated at 25 °C, for 8 h with 250 mm hydrox-
ylamine and assayed for thioesterase activity by the
DTNB method after extensive dialysis, as described in
Experimental procedures. Its activity was expressed as
a percentage of that obtained from an experiment,
run in parallel, in which same amount of active
enzyme (no inhibitor added) was incubated with
250 mm hydroxylamine for 8 h at 25 °C and assayed
for activity in the same manner. The treatment of
the diethyl pyrocarbonate-inhibited enzyme with
Table 1. Thioesterase catalyzed hydrolysis of acyl-CoA derivatives.
A solution of acyl-CoA derivative was prepared in 100 m
M Tris ⁄ HCl
buffer, pH 7.6, at various concentrations in the range 1.5–60 l

0.1
M phosphate buffer, pH 7.2, containing 0.1 M NaCl. The reaction was started by the addition of 0.2 lg thioesterase. Initial rates were
determined by measuring the increase in A
346
(e ¼ 4800 M
)1
Æcm
)1
), the isobestic point of the p-nitrophenol ⁄ p-nitrophenoxide couple.
Sr. No. p-Nitrophenyl ester
Specific activity
[lmolÆmin
)1
Æ(mg protein)
)1
]
Relative
activity (%)
1 p-Nitrophenyl acetate 9.16 30.14
2 p-Nitrophenyl propanoate 30.52 100
3 p-Nitrophenyl butanoate 15.87 51.02
4 p-Nitrophenyl hexanoate 9.77 33.16
5 p-Nitrophenyl dodecanoate 2.44 8.67
6 p-Nitrophenyl palmitate Not detected –
7 p-Nitrophenyl stearate Not detected –
Thioesterase of Alcaligenes faecalis P. Shahi et al.
2380 FEBS Journal 273 (2006) 2374–2387 ª 2006 IMTECH
hydroxylamine in this way resulted in 58.7% recovery
of activity.
(b) A 35.7% increase in absorption at k

ences in the interaction of the buffer ions with the
binding site [24]. Activity at pH 10.5 was maximum
and set as 100%. Activity above pH 10.5 was not stud-
ied. Controls were used in each case to compensate for
chemical hydrolysis, which was substantial at higher
pH. Although maximum activity was obtained at
pH 10.5, all studies were carried out at pH 7.0–7.5 as
the substrates are prone to degradation under basic
conditions.
To evaluate pH stability, the enzyme was incubated
in different buffers, pH 5.5–10.5, at 30 °C for 20 h.
The remaining activity is expressed as a percentage of
the activity relative to the activity in the corresponding
buffer at time zero. Thioesterase retained almost
Table 3. Effect of protein-modifying reagents on thioesterase activ-
ity. Purified and dialyzed thioesterase at a concentration of
20 lgÆmL
)1
was incubated with each reagent at 25 °C for 15 min
and dialyzed against 50 m
M Tris ⁄ HCl buffer, pH 7.5, at 4 °C with
four buffer changes for 12 h. Residual activity, percentage of the
original activity, was calculated by the DTNB method as described
in Experimental procedures.
Sr. No. Reagent (1 m
M) Residual activity (%)
1 N-Bromosuccinimide 0.0
2 Phenylmethanesulfonyl fluoride 90.7
3 N-Acetylimidazole 90.7
4 Iodoacetamide 98.9

Fig. 5. (A) Effect of pH on the activity of thioesterase. Assays were
performed at 30 °C in various buffers at different pH. The activity
in carbonate buffer at pH 10.5 was set as 100%, all other values
are relative to it. (B) pH stability of thioesterase. A predetermined
amount of thioesterase was incubated in different buffers for 20 h
at 30 °C and assayed for thioesterase activity. The remaining activ-
ity is expressed as percentage of activity relative to the activity in
the corresponding buffer at time zero. (d) phosphate buffer; (.)
Tris ⁄ HCl buffer; (n) carbonate buffer.
P. Shahi et al. Thioesterase of Alcaligenes faecalis
FEBS Journal 273 (2006) 2374–2387 ª 2006 IMTECH 2381
complete activity at pH 5.5–6.0 (Fig. 5B). It retained
 80% activity at pH 7.0–7.5 and was relatively unsta-
ble under alkaline conditions. After 20 h incubation at
pH 10.5 in carbonate buffer, only 20% activity was
retained.
Thermal properties of the thioesterase
Thioesterase activity was determined at different tem-
peratures in phosphate buffer at pH 7.0. Maximum
thioesterase activity occurred at 65 °C (Fig. 6A).
About 60–80% of maximum activity was retained at
temperatures of 25–70 °C. There was sharp decline in
activity at 75–80 °C; the enzyme retained  20% of
maximum activity at 80 °C.
To evaluate temperature stability, enzyme in phos-
phate buffer, pH 7.0 was incubated for 3 h at different
temperatures. Thioesterase activity was assayed at
30 °C by the DTNB method as described in Experi-
mental procedures. The activity at zero time at 30 °C
is assumed to be 100%, and all other values are

The cells were grown at 25, 30 and 37 °C and assayed
for thioesterase activity by the DTNB method. No
difference in activity was observed, ruling out a tem-
perature-dependent change in expression levels of thio-
esterase. The kinetics of thioesterase activity was
determined at 20 and 37 °C with palmitoyl-CoA,
palmitoleoyl-CoA or cis-vaccenoyl-CoA as substrate
(Table 4). With palmitoyl-CoA as substrate, thioest-
erase showed only marginal changes in V
max
and K
m
values at both the temperatures. However, approxi-
mately twofold reduced affinity and catalytic efficiency
was observed when palmitoleoyl-CoA or cis-vaccenoyl-
CoA was the substrate at the lower temperature.
Discussion
Two thioesterases, I and II, that cleave acyl-CoA mol-
ecules in vitro have been characterized from E. coli.
Thioesterase I is a periplasmic protein of 20.5 kDa and
has an active site similar to serine proteases [2,9]. Thio-
esterase II is a tetrameric protein with identical
subunits of 32 kDa and is insensitive to inhibition with
di-isopropyl fluorophosphate. A histidine residue in
thioesterase II has been implicated in the cleavage of
the thioester bond [10,11]. In comparison, thioesterase
from A. faecalis exists as large homomeric granular
aggregates (21.6 nm average diameter) of 22-kDa sub-
units (Figs 2A and 3). Phenylmethanesulfonyl fluoride,
a serine-active reagent, failed to inhibit the catalytic

to be 100%; all other values are expressed relative to it.
Thioesterase of Alcaligenes faecalis P. Shahi et al.
2382 FEBS Journal 273 (2006) 2374–2387 ª 2006 IMTECH
MS ⁄ MS spectra did not match any peptide from
E. coli thioesterases or any other thioesterase in the
database. Thioesterase was found to be associated
exclusively with the surface of cells as revealed by
ultrastructural studies using electron microscopic im-
munogold labeling studies (Fig. 4).
A histidine residue has been implicated in the
active site of the enzyme based on the following
observations. (a) Incubation of thioesterase with
1mm diethyl pyrocarbonate resulted in complete loss
of enzyme activity. (b) An increase in absorption at
k
245
corresponding to N-ethoxycarbonylation of histi-
dine on inactivation with diethyl pyrocarbonate was
observed when differential spectra were recorded.
(c) Approximately 60% of the enzyme activity could
be recovered by the treatment of diethyl pyrocarbo-
nate-inhibited enzyme with hydroxylamine. (d) Stea-
royl-CoA, a substrate of the thioesterase, provided
 93% protection against inactivation by diethyl
pyrocarbonate.
Alcaligenes thioesterase was active in and stable to a
wide range of temperatures and pH values. Maximum
activity was observed at 65 °C and pH 10.5 and varied
between 60% and 80% at 25–70 °C and pH 6.5–10
(Figs 5 and 6). Enzyme activity remained unaltered

, with the
activity falling sharply with increase or decrease in
chain length. Long-chain p-nitrophenyl esters were not
hydrolyzed by the enzyme. The odd-chain C
3
esters are
unlikely to be natural substrates of the enzyme. In any
case, the substrate competition experiments clearly
demonstrated that the long-chain acyl-CoAs are better
substrates than p-nitrophenyl esters.
The ratio of saturated ⁄ unsaturated fatty acid in mem-
brane phospholipids is tightly controlled in a tempera-
ture-dependent manner in micro-organisms, which
allows proper thermal regulation of membrane fluidity
[25–27]. Thermal regulation of membrane fluidity is
common to all organisms. Lower growth temperatures
result in an increase in the number of unsaturated
phospholipids in the membrane. E. coli can synthesize
phospholipids almost entirely from exogenous fatty
acids supplied by the growth medium. The satur-
ated ⁄ unsaturated fatty acids in membrane phospho-
lipids, synthesized from exogenous fatty acids is similar
to de novo ratio in a temperature-controlled fashion
[28]. A site for thermal regulation must therefore exist at
the level of utilization of exogenous fatty acids, in addi-
tion to a well-defined site for thermal regulation in
de novo fatty acid synthesis [26]. Previous literature sug-
gests that such a regulation is likely to be at the enzyme
and not gene level [29]. Starting from exogenous fatty
acids, the incorporation is known to involve first the

max
and K
m
values were determined by least-squares analysis of double-reciprocal plots of the
data obtained from the corresponding Michaelis–Menten plots.
Temp (°C)
Palmitoyl-CoA Palmitoleoyl-CoA cis-Vaccenoyl-CoA
K
m
V
max
V
max
⁄ K
m
K
m
V
max
V
max
⁄ K
m
K
m
V
max
V
max
⁄ K

The strain isolated from soil samples was identified as a
bacterium, A. faecalis according to Bergey’s Manual [31],
and was designated A. faecalis ISH108. The strain has been
deposited with Microbial Type Culture Collection, MTCC
(Institute of Microbial Technology, Chandigarh, India)
( accession num-
ber MTCC7733).
Cell growth and protein extraction from
A. faecalis
Cells were routinely grown for 18 h (A
600
¼ 4.00) at 30 °C
at 200 r.p.m. in shaking flasks in medium containing 1%
peptone and 0.5% beef extract at pH 7.0. The wet cells
were suspended in 50 mm phosphate buffer containing 1 m
NaCl at pH 7.0 at a concentration of 2 gÆmL
)1
and incuba-
ted at 30 °C at 200 r.p.m. for 2 h. The debris was removed
by centrifugation, and the supernatant, enriched in thioest-
erase activity, was used in these studies.
Assay of thioesterase activity
Thioesterase activity was measured by following the
increase in A
412
(e ¼ 7684 m
)1
Æcm
)1
), when free CoASH

antibody titer after every booster dose. The titer of anti-
bodies was determined after each booster dose. 98-well
ELISA plates were incubated overnight with 1 lg purified
protein. Primary antibody followed by horseradish peroxi-
dase-conjugated goat anti-rabbit IgG was used for the
colorimetric assay. After the addition of substrate (tetra-
methylbenzidine ⁄ H
2
O
2
), the absorbance was recorded at
450 nm (1 ⁄ X dilution ¼ X titer of antibody). The titer of
AbTE-N and AbTE-D was found to be 2 000 000 and
180 000, respectively, after the third booster dose.
Cells were grown in rich medium containing 1% peptone
and 0.5% beef extract in a 100-mL flask for 6 h. The culture
was re-inoculated in a 1-L flask with 2–3% preinoculum
and grown until the late exponential phase for better expres-
sion of the enzyme. These were harvested by centrifugation
at 5000 g at 4 °C and washed 4 times with Dulbecco’s phos-
phate-buffered saline (NaCl ⁄ P
i
), resuspended and kept at
4 °C in 0.5% paraformaldehyde and 0.5% glutaraldehyde
for 30 min. These were washed with NaCl ⁄ P
i
and a suspen-
sion was made in 2% agarose solution. The agarose blocks
were cut into small pieces and dehydrated with a graded ser-
ies of ethanol and embedded in LR White resin (polymeriza-

labeling of each set of samples with preimmune serum (i.e.
normal rabbit serum) instead of anti-thioesterase serum.
Enzyme-catalyzed hydrolysis of acyl-CoA
derivatives
Thioesterase-catalyzed hydrolysis of various long-chain
acyl-CoAs was studied as previously described [32]. A stock
solution of each acyl-CoA derivative was prepared in
100 mm Tris ⁄ HCl buffer, pH 7.6, at a concentration of
 1mm. The calculated amount of this solution was added
to 0.5 mL Tris ⁄ HCl buffer (100 mm), pH 7.6, to give a con-
centration in the range 1.5–60 lm. The exact concentration
of substrate was determined spectrophotometically from
A
232
using a molar absorption coefficient (e)as
9400 m
)1
Æcm
)1
. The reaction was started by the addition of
an aliquot of enzyme (0.2 lg). The initial rate of hydrolysis
was measured by the DTNB method as described above.
Enzyme-catalyzed hydrolysis of p-nitrophenyl
esters
Thioesterase-catalyzed hydrolysis of various p-nitrophenyl
esters was studied as previously described [21]. The assay
mixture (1 mL) consisted of 400 lm p-nitrophenyl ester in
100 mm phosphate buffer, pH 7.2, containing 0.1 m NaCl.
The reaction was started by the addition of 0.2 lg enzyme.
The initial rate was determined by measuring the increase

2
NbSBr
and diethyl pyrocarbonate which were performed in 50 mm
phosphate buffer, pH 6.0). After 15 min, the samples were
extensively dialyzed (four buffer changes) against 100 mm
Tris ⁄ HCl buffer, pH 7.6, for 12 h at 4 °C and assayed for
activity by the DTNB method, as described above.
Recovery of activity with hydroxylamine
An aliquot of enzyme (5 lg) was inactivated with 1 mm
diethyl pyrocarbonate at 4 °C as described above. It was
incubated at 25 °C, for 8 h with 250 mm hydroxylamine. A
parallel experiment was run as a control in which the same
amount of active enzyme (no inhibitor added) was incuba-
ted with 250 mm hydroxylamine for 8 h at 25 ° C. The sam-
ples were dialyzed at 4 °C for 15 h against Tris ⁄ HCl buffer,
pH 7.6 (four buffer changes) and assayed for activity by
the DTNB method, as described above.
Differential spectra of enzyme inhibition with
diethyl pyrocarbonate
Enzyme (1.5 mg) was added to 2.2 mL 50 mm phosphate
buffer, pH 6.0, and the contents cooled to 4 °C. Then 1 mL
of the solution was transferred to both reference and sample
cuvette. A stock solution of diethyl pyrocarbonate prepared
as above in alcohol was added to the sample cuvette at a
final concentration of 0.3 mm. An equal amount of alcohol
was added to the reference cuvette. The UV spectra (200–
400 nm) were recorded at 15 min intervals for 1 h. The
increase in A
245
was recorded, and the activity of both sam-

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