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Originally published In Press as doi:10.1074/jbc.M202839200 on April 8, 2002
J. Biol. Chem., Vol. 277, Issue 31, 28070-28079, August 2, 2002
Mechanisms of Inhibition of Triacylglycerol Hydrolysis by
Human Gastric Lipase*
Yan
Pafumi,
Denis
Lairon,
Paulette Lechene
de la Porte,
Christine
Juhel,
Judith
Storch ,
Margit
Hamosh§, and
Martine
Armand¶
From Unité 476-INSERM (National Institute of Health and
Medical Research)/Université de la Méditerranée, 18 avenue Mozart, 13009 Marseille, France, the Department of
Nutritional Sciences, Rutgers University, New Brunswick, New Jersey
08901, and the § Department of Pediatrics, Division of
Developmental Biology and Nutrition, Georgetown University Medical
Center, Washington, D. C. 20007
Received for publication, March 25, 2002
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ABSTRACT |
In the human stomach, gastric lipase hydrolyzes
only 10 to 30% of ingested triacylglycerols because of an inhibition
process induced by the long chain free fatty acids generated, which are mostly protonated at gastric pH. The aim of this work was to elucidate the mechanisms by which free fatty acids inhibit further hydrolysis. In vitro experiments examined gastric lipolysis of
differently sized phospholipid-triolein emulsions by human gastric
juice or purified human gastric lipase, under close to physiological
conditions. The lipolysis process was further investigated by scanning
electron microscopy, and gastric lipase and free fatty acid movement
during lipolysis were followed by fluorescence microscopy. The results demonstrate that: 1) free fatty acids generated during lipolysis partition between the surface and core of lipid droplets with a molar
phase distribution coefficient of 7.4 at pH 5.40; 2) the long chain
free fatty acids have an inhibitory effect only when generated during
lipolysis; 3) inhibition of gastric lipolysis can be delayed by the use
of lipid emulsions composed of small-size lipid droplets; 4) the
release of free fatty acids during lipolysis induces a marked increase
in droplet surface area, leading to the formation of novel particles at
the lipid droplet surface; and 5) the gastric lipase is trapped in
these free fatty acid-rich particles during their formation. In
conclusion, we propose a model in which the sequential physicochemical
events occurring during gastric lipolysis lead to the inhibition of
further triacylglycerol lipolysis.
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INTRODUCTION |
Dietary fat digestion and absorption is a complex process
involving enzyme activities and physicochemical changes (1-5). In
humans, hydrolysis of dietary triacylglycerols starts in the stomach
where it is catalyzed by an acid-stable gastric lipase, a globular
protein of about 50 kDa with a broad pH range (6, 7). Triacylglycerol
hydrolysis continues in the duodenum, by the synergetic actions of
gastric and colipase-dependent pancreatic lipases and bile
secretion (1). A characteristic feature of these lipases is their
specificity to act on insoluble emulsified substrates (1, 2). A few
in vitro and in vivo experiments have
shown that the extent of lipid emulsification, which directly affects
the lipid/water interface area, modulates the activity of digestive
lipases (8-10). Dietary lipids are organized mainly in the form of
droplets in the aqueous digestive system (1, 3, 4). The lipid droplets
consist of a hydrophobic core containing the majority of the
triacylglycerol molecules, esterified cholesterol, and fat-soluble
vitamins, surrounded by an amphipatic surface monolayer of
phospholipids, free cholesterol, and a few triacylglycerol molecules
(11, 12). Earlier studies on lipoprotein models (11, 13, 14) and a
recent investigation using dietary emulsions (12) have shown that 2-5
mol % of the droplet surface lipid is triacylglycerol, thereby
enabling lipase action at the surface of the lipid droplet.
In healthy humans, gastric lipolysis leads to the hydrolysis of
10-30% (3, 4, 10, 15) of ingested triacylglycerols, generating mainly
free fatty acids and diacylglycerols (1, 16, 17). This facilitates
subsequent triacylglycerol hydrolysis by pancreatic lipase by allowing
fat emulsification (3, 4) and promoting enzyme activity (8, 17).
Furthermore, in physiological (preterm or full-term infants) (18) and
pathological (cystic fibrosis, pancreatitis) (19-21) pancreatic
insufficiencies, gastric lipolysis plays a key role in the digestion of
dietary fat by hydrolyzing 10-40% of fat in the stomach (18-21), as
well as acting more effectively in the duodenum because of acid pH
conditions (19). The relatively limited extent of lipolysis by the
gastric lipase under physiological or pathological conditions suggested that a feedback inhibition by the products of lipolysis probably occurs (1, 22).
It has been hypothesized that the inhibition of gastric lipase activity
may be due to the progressive release of protonated free fatty acids
(8, 23) that might accumulate at the lipid droplet surface (1, 16, 22).
At present, however, the mechanism by which free fatty acids inhibit
gastric lipase action in the stomach is unknown. It can be
suggested from the literature that long chain free fatty acids prevent
further gastric lipase lipolysis by modifying the physicochemical
properties of the lipid/water interface, especially the interfacial
tension or the surface pressure (2, 13, 16, 24, 25); they could prevent
the interfacial binding of gastric lipase or promote its release from
the droplet surface (2), or they could limit the number of
triacylglycerol molecules located at the droplet surface by steric
hindrance (13). However, thus far no study has provided direct evidence
for the mechanisms involved. A few previous studies have examined the effect of free fatty acid on gastric lipase activity (8, 23) or the
distribution of fatty acids in model systems (26-28), however, they
were not performed under physiological conditions. In the present work
we have performed several in vitro experiments using conditions close to those occurring physiologically, to understand the
mechanism of inhibition of gastric lipolysis in vivo, and to
begin to elucidate conditions that will enable modulation of the extent
of gastric lipolysis.
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EXPERIMENTAL PROCEDURES |
Purification of Human Gastric Lipase and Lipase Activity
Measurements
Human gastric juice was collected from healthy adult patients
for diagnostic purposes after pentagastric stimulation (6 µg/kg) (a
generous gift from Dr. J. Peyrot and Pr. J. Salducci, Gastroenterology Department, Nord Hospital, Marseille, France). Pure human gastric lipase (HGL)1 with a specific
activity of 910 units/mg on tributyrin was obtained according to
Thiruppathi and Balasubramanian (29). Gastric lipase activity of
gastric juice (100-200 µl) or purified lipase was determined using a
pH-stat titrator (Metrohm, Herisau, Switzerland) at pH 5.40 and
37 °C with tributyrin as substrate (ICN Biomedicals Inc., OH) as
previously described (3, 23). One lipase unit corresponds to the
release of 1 µmol of fatty acid per min.
Lipid Mixtures
The relative proportion of lipids used was chosen in accordance
with human daily dietary intake (1). The lipid mixture contained 93.5%
triolein (w/w) (ICN), 6% phospholipids (PL) (w/w) (L- -phosphatidylcholine, XVI-E from egg yolk), and 0.5%
free cholesterol (w/w) (both from Sigma, La Verpillière,
France). Lipids were solubilized in chloroform/methanol (2:1, v/v),
mixed, dried under nitrogen, and dessicated using a rotavapor under
vacuum at 30 °C. The lipid mixture was stored at  20 °C. For
lipolysis experiments, the mixture contained [3H]- or
[14C]triolein (3 × 104 dpm/µmol
of triolein or 1.5 × 106 dpm/µmol of triolein
when a low HGL/TO ratio was used) and
[14C]L-1-palmitoyl-2-oleoyl
phosphatidylcholine (3.5 × 104 dpm/µmol PL)
(PerkinElmer Life Science, Dreiech, Belgium). Lipid mixtures
enriched with different concentrations of oleic acid (OA) (2 and 6.9%
oleic acid (w/w), i.e. 0.063 and 0.216 µmol of OA/µmol
of TO) contained [14C]triolein (PerkinElmer Life
Sciences, 3 × 104 dpm/µmol of triolein) and
[3H]oleic acid (1.2 × 104 dpm/µmol of
OA) (Amersham International plc, UK). These OA/TO ratios were selected
to mimic the amount of free fatty acids released after 2 or 25 min of
gastric lipolysis under present physiological conditions, respectively.
To study the distribution of lipolysis-generated free fatty acids
between the core and surface of the lipid droplet, the lipid mixture
was radiolabeled with [14C]triolein (106
dpm/µmol of triolein),
[3H]L--dipalmitoyl phosphatidylcholine
(106 dpm/µmol PL), and [3H]cholesterol
(107 dpm/µmol of free cholesterol) (PerkinElmer Life
Sciences). The lipid mixture for fluorescence studies was labeled with
dansyl cholesterol (gift from Drs. A. Misharin and C. Alquier).
Emulsification Procedures and Determination of Emulsion Droplet
Size
A fine emulsion (about 0.7 µm in median diameter) was prepared
by sonication of 100 mg of lipid mixture in 6 ml of distilled water for
10 min at 95% power level and a frequency of 20,178 Hz (Sonoreactor,
Undatim, Japan), in ice/ethanol. A medium-size emulsion (about 2 µm)
was obtained by sonicating 100 mg of lipid mixture in 3 ml of distilled
water for 5 min at 25 watts power in an ice/ethanol cooling bath using
a microtip probe (Brandson 250 W sonifier, Osi, France). A coarse
emulsion (about 15 µm) was prepared by mechanical stirring of 100 mg
of lipid mixture in 1 ml of distilled water for 1.5 min at room
temperature. The emulsions obtained were collected after concentration
and removal of excess phospholipids as follow: the coarse emulsion was
allowed to stand for 10 min in ice, and the medium-size and fine ones were centrifuged 10 min or 1 h at 4,000 rpm and 10 °C,
respectively. The resultant triacylglycerol/phospholipid ratios (w/w)
were found to be 50/1, 40/1, and 14/1 for the coarse, medium, and fine
emulsions, respectively. The emulsion droplet sizes were determined as
previously reported (3) using a particle-size analyzer (Capa-700,
Horiba, Kyoto, Japan). The results are given in the form of a frequency distribution graph (Fig. 1). Emulsion
median diameter (µm) and emulsion surface area (Sw, m2/g
emulsified fat) were calculated by the particle-sizer software from the
droplet size distribution. The coarse emulsion (Fig. 1A) was
composed of lipid droplets sizing from 1 to 40 µm with a majority of
particles between 8 and 30 µm (about 70% total particles by volume).
For the medium-size emulsion (Fig. 1B), lipid droplets sized
from 0.1 to 40 µm and about 80% of total particles ranged from 1 to
4 µm. The fine emulsion (Fig. 1C) was mainly composed of
small size droplets from 0.1 to 2 µm, with 75% of total particles sizing between 0.1 and 1 µm. Emulsion surface area varied inversely with the emulsion median diameter. Both parameters were significantly different for the three emulsions (ANOVA, p < 0.05).
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Fig. 1.
Droplet size distribution of emulsions.
Frequency distribution graphs were obtained using a particle-size
analyzer (capa 700, Horiba) and are expressed as percentage of total
volume occupied by lipid droplets in the coarse (A), medium
(B), and fine (C) emulsions. Values are mean ± S.E. of 7, 8, and 11 measurements, respectively. Median diameters
(MD) and emulsion surface areas (SW) were
determined using the particle-sizer software. Different superscript
letters for a given parameter (a, b, and
c) indicate significant differences (ANOVA,
p < 0.05).
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Lipolysis Experiments
Lipolysis of Differently Sized Emulsions by Pure
HGL--
Experiments were carried out at 37 °C and pH 5.40, using
polycarbonate test tubes (13 × 51 mm, Beckman Instruments, Palo
Alto, CA) to limit the loss of lipid molecules on the inner surface of
the test tube during lipolysis. The reaction medium was a 2.5-ml mixture containing 100 mM sodium acetate, 150 mM NaCl, 6 mM CaCl2 (buffer L), 1.5 µM bovine serum albumin, and 25 µmol of triolein emulsified as described above. The HGL/TO ratio was selected to mimic
physiological conditions (3, 10, 15), i.e. excess enzyme,
and was 2.5 units (53.2 pmol)/µmol of triolein. Samples (200 µl)
were collected at intervals from 0 to 100 min, and lipids were
extracted immediately by the Folch method (30). Lipids were separated
by thin-layer chromatography (TLC) on silica gel (Ready plastic sheet
F1500, Schleider and Schuell, Germany) according to Bitman and Wood
(31). After exposure to iodine vapors, individual lipid spots were
scraped and the radioactivity was measured by scintillation counting
(1600TR, Packard, Meriden, CT).
Lipolysis in the Presence of Exogenous OA--
The reaction
medium was a 0.8 ml of mixture of buffer L with medium-size
[3H]triolein emulsion, at pH 5.4 and 37 °C. Three
HGL/TO ratios were used corresponding to high (53.2 pmol/µmol) and
moderate (10.6 pmol/µmol) physiological ratios, and to a large excess
substrate (0.21 pmol/µmol). In the first experiment, a large amount
of exogenous OA (1.4 µmol of OA/µmol of triolein) (final ethanol
concentration: 1.2-2.5%, v/v) was added prior to the initiation of
lipolysis or 5 min after. In addition, a physiological amount of OA,
corresponding to the amount of free fatty acid generated during a
60-min lipolysis of the emulsion (0.3 µmol of OA/µmol of triolein),
was added 5 min after lipolysis started. For the second and third
experiments, 0.3 µmol of OA/µmol of triolein was added before or 5 min after the beginning of lipolysis. Samples (100 µl) were collected
at intervals from 0 to 60 min. [3H]OA produced were
separated by liquid-liquid partition (32) and radioactivity was
measured as described above.
Lipolysis of OA-enriched Emulsions--
The reaction medium was
a 0.8-ml mixture of buffer L with [3H]OA (2 or 6.9%) and
[14C]TO-PL emulsions of 2.5 or 1.3 µm,
respectively, at pH 5.4 and 37 °C. The HGL/TO ratio was 53.2 pmol/µmol. Samples (100 µl) were collected at intervals from 0 to
60 min and the amount of [14C]OA released was determined
as described above.
Lipolysis of a Pre-lipolysed Emulsion by Additional HGL--
The
reaction medium was a 1.1-ml mixture of buffer L and
[3H]triolein medium-size emulsion at pH 5.4 and 37 °C,
with a HGL/TO ratio of 53.2 pmol/µmol. Samples (100 µl) were
collected from 0 to 60 min. After 60 min lipolysis, a new dose of HGL
was added, thus doubling the initial concentration of enzyme, and
lipolysis was carried out for an additional 60 min. Samples (100 µl)
were collected then from 65 to 120 min after lipolysis.
Lipolysis of a New Emulsion Added to a Pre-lipolysed
Emulsion--
The reaction medium was a 1.5-ml mixture of buffer L and
[3H]triolein medium-size emulsion, at pH 5.4 and
37 °C. Pure HGL or gastric juice, with a gastric lipase
equivalent/triolein ratio of 53.2 pmol/µmol were used. Samples (100 µl) were collected from 0 to 90 min. At 90 min, a
[14C]triolein medium-size emulsion was added, thus
doubling the initial concentration of triolein. Samples (100 µl) were
then collected at 95 to 180 min lipolysis. The amounts of
[3H]- and [14C]OA released were determined
as described above.
Rates of lipolysis were calculated as the percent of triacylglycerols
hydrolyzed, from micromoles of released OA at a given time
(OAt) relative to the total micromoles of physiologically releasable OA (Sn-1 and
Sn-3 positions), based on the initial amount of
triolein, using the following equation: [OAt/(TO × 2)] × 100.
Surface-to-core Distribution of Free Fatty Acids in Emulsion
Lipid Droplets
Samples of a radiolabeled medium-size emulsion collected before
or after 10, 25, and 60 min lipolysis by pure HGL were transferred to
sealed glass disposable micro-sampling pipettes (inner diameter (1.1-1.2 mm) × L (75 mm)) (Corning, New York) and the surface and core phases of the lipid droplets were separated by centrifugating at 20,000 rpm for 18 h in a Beckman SW 40 Ti swinging bucket rotor (Beckman Instruments, Inc.) using a Beckman Ultracentrifuge (model number L7) according to Miller and Small (11). Lipid classes of the two
phases were analyzed as described above.
Scanning Electron Microscopy
Samples of a lipolysed medium-size emulsion collected at
intervals from 0 to 80 min were mixed volume/volume with 1%
OsO4 in distilled water at pH 5.4 and room temperature. The
mixture was gently shaken, put on a microscope cover glass, and fixed overnight in a moist chamber at room temperature. The emulsion deposit
was then gently washed with distilled water, first dried with filter
paper followed by drying 1 day in a silica gel dessicator. Preparations
were gold-palladium coated then examined at magnification ×4,800 to
6,600 with a JSM-35CF scanning electron microscope (JEOLS, Paris,
France) operated at 35 kV accelerating potential.
Fluorescence Microscopy
Immunolocalization of HGL during Lipolysis of Lipid
Droplets--
An aliquot (50 µl) of a medium-size emulsion
previously incubated with HGL for 60 min was mixed in a shaking bath at
37 °C with a medium-size emulsion labeled with dansyl cholesterol to distinguish from the first emulsion, at pH 5.40 for 15 min. Then the
mixture was incubated for 30 min on ice with 10 µl of purified specific polyclonal anti-HGL antibodies (6.2 mg/ml) from rabbit (diluted 10 times in buffer L) followed by incubation for 30 min on ice
with 10 µl of fluorescein isothiocyanate (FITC)-conjugated goat
anti-rabbit IgG (Zymed Laboratories Inc., South San
Francisco, CA) (diluted 10 times in buffer L). High levels of
antibodies were used to obtain sufficient labeling at acid pH and cold
temperature. A negative control was performed without the enzyme.
HGL Rhodamine Labeling--
HGL was mixed with TRITC (Molecular
Probe, Inc.) (25 µg/mg of protein) in 25 mM sodium
carbonate buffer, pH 9.0, at room temperature for 1 h, then
quickly neutralized to pH 6.0, dialyzed against sodium acetate 50 mM, 150 mM NaCl, pH 6.0, at
cold temperature overnight and concentrated on PEG-6000 at 4 °C.
Under these conditions HGL retained about 60% of its initial activity.
Visualization of Lipolysis-generated Free Fatty Acids--
Based
on the method of Holczinger (33), a copper acetate solution (Sigma)
(0.15% final concentration) was mixed carefully into the reaction
medium after 90 min lipolysis of a medium-size emulsion. The
copper-free fatty acid soaps formed were then visualized with
FITC-Gly-Gly-His (Molecular probe) (38 µg/ml final concentration), a
marker with high selectivity and sensitivity for Cu2+ due
to the presence of the tripeptide commonly called copper-binding peptide (34).
Microscopy--
All specimens were examined under a Leitz Dialux
20 microscope (Jena, Germany) equipped with a Ploemopak 3.1 epifluorescence system using filters specific for FITC (filter bloc
Leitz model L3), dansyl cholesterol (filter block Leitz model A2), or
TRITC (filter block Leitz model N2), at a final magnification of
×1,250. Photomicrographs were taken using a CCD color Camera (DC 100, Leica, Switzerland).
Isolation and Analysis of the Gastric Lipid Particles
A [14C]triolein, [3H]PL, free
[3H]cholesterol medium-size emulsion was incubated with
HGL for 90 min. The lipid particles generated during lipolysis were
isolated by FPLC using a Superose 6 column (6 × 57 cm) at room
temperature with a flow rate of 0.3 ml/min with buffer L as eluent. The
lipid droplets are retained on the column. The fractions obtained were
analyzed for lipid composition by TLC and radioisotope counting as
described above. The size of the lipid particles was determined with a
quasielastic light-scattering detector (SEMAtech, Nice, France). The
presence of HGL was ascertained by immunoblotting (35) by depositing 20 µl of the various fractions on a polyvinylidene difluoride membrane;
the membrane was soaked for 30 min at room temperature in 5% skim milk
in a TBS Tween buffer, washed, and incubated with HGL-polyclonal rabbit
antiserum (final dilution 1:5000); immunodetection was carried out with alkaline phosphatase-labeled goat anti-rabbit IgG (final dilution 1:5000) (Sigma).
Statistical Analysis
Statistical significances were analyzed by one-way analysis of
variance (ANOVA) and the differences were determined by the Fisher's
test at a probability of 95%. Correlation coefficient was obtained
from linear regression (StatView II; Abacus, Berkeley, CA) (36).
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RESULTS |
Kinetics of Hydrolysis of Differently Sized Emulsions by Gastric
Lipase--
The amounts of free fatty acid released by pure HGL at pH
5.4 on three differently sized emulsions are shown in Fig.
2. The rate of lipolysis was inversely
related to the emulsion size and decreased with time with all the
emulsions used. The amounts of OA released after 5 min lipolysis were
3.0 × 10 2, 2.0 × 102, and
0.78 × 102 µmol of OA/min for the fine, medium,
and coarse emulsions, respectively. Thus, a 50% loss of lipase
activity was reached after about 10 min incubation at 37 °C. The
rate of lipolysis reached a plateau after 40 to 60 min and at this time
the amounts of OA released were 0.444 (fine emulsion), 0.325 (medium
size emulsion), and 0.124 µmol (coarse emulsion) per µmol of
initial triolein. Maximum rates of triacylglycerol lipolysis obtained
over time were, expressed as mean ± S.E., 22.6 ± 0.7, 16.3 ± 2.8, and 7.1 ± 0.4% for the fine, medium, and
coarse emulsions, respectively. Thus, the extent of lipolysis was 1.4 to 3.2 times higher (p < 0.05) with the fine emulsion
as compared with the medium and coarse emulsions, respectively, showing
that HGL activity is directly related to the available interface area
(r2 = 0.73, p < 0.05).
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Fig. 2.
Kinetics of hydrolysis of differently sized
emulsions by HGL. Oleic acid released as a function of incubation
time with purified enzyme (53.2 pmol of pure HGL/µmol of triolein,
0.53 µM) from the fine, medium, and coarse emulsions. The
reactions were carried out at 37 °C, pH 5.40, using 10 mM [3H]triolein emulsions, 100 mM
sodium acetate, 150 mM NaCl, 6 mM
CaCl2, 1.5 µM bovine serum albumin. Results
are mean ± S.D. of three experiments.
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Kinetics of Hydrolysis of Emulsions in the Presence of Exogenous
OA--
To investigate whether the presence of protonated free fatty
acids is specifically responsible for the inhibition of gastric lipolysis, we studied the kinetics of hydrolysis of a medium-size emulsion after adding OA exogenously to reach or exceed the free fatty
acid concentrations found during lipolysis, or of preformed OA-enriched
emulsions (Fig. 3).
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Fig. 3.
Kinetics of hydrolysis of emulsions by pure
HGL in the presence of exogenous OA. The effect of adding
exogenous free oleic acid on the release of oleic acid from
triolein-phospholipid emulsions (medium-size emulsion) by pure HGL was
examined by adding 0.3 or 1.4 µmol of OA/µmol of triolein either
before or 5 min after lipolysis began with: A, a high
physiological amount of HGL (53.2 pmol of HGL/µmol of triolein);
B, a moderate physiological amount of HGL (10.6 pmol of
HGL/µmol of triolein); C, a large excess of substrate
(0.21 pmol of HGL/µmol of triolein); or D, comparing the
hydrolysis of a medium-size emulsion without exogenous OA to a 2.0%
OA-enriched emulsion and a 6.9% OA-enriched emulsion, using a high
physiological amount of HGL (53.2 pmol of pure HGL/µmol of triolein).
Values are mean ± S.D. of three experiments. The incubations were
done at 37 °C, pH 5.40, using 10 mM
[3H]triolein emulsions, 100 mM sodium
acetate, 150 mM NaCl, 6 mM
CaCl2.
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The addition of 0.3 µmol of OA/µmol of triolein to the reaction
medium 5 min after lipolysis started, as well as the addition of a very
high amount of OA (1.4 µmol of OA/µmol of triolein) before and 5 min after the beginning of lipolysis, did not modify significantly the
kinetics of hydrolysis (Fig. 3A). The rates of hydrolysis
reached a plateau after 60 min and the amounts of OA released were
similar to those shown in Fig. 2. We had expected to observe an
inhibitory effect of the added free fatty acid on triacylglycerol
hydrolysis (8, 23). However, previous in vitro experiments
showing such an inhibitory effect were done in excess of substrate (8,
23). Therefore, we have performed two other experiments changing the
HGL/TO ratio, one with a moderate physiological ratio (10.6 pmol of
HGL/µmol of triolein) (Fig. 3B) and the other with a large
excess of substrate (0.21 pmol of HGL/µmol of triolein) (Fig.
3C). In both cases, the kinetics of hydrolysis of a
medium-size emulsion were studied without or with the addition of 0.3 µmol of OA/µmol of triolein before or 5 min after lipolysis
started. As shown in Fig. 3B, at a moderate physiological
HGL/TO ratio, the addition of OA did not modify noticeably the kinetics
of hydrolysis and the rates of the lipolytic reaction (after 60 min
lipolysis: 9.9 × 102, 9.6 × 102, and 8.9 × 102 µmol of
OA/µmol of triolein, respectively). Conversely, when the triolein
emulsion was in large excess, the HGL activity was strongly inhibited
by exogenous OA (Fig. 3C). In this case, the amounts of
endogenous OA generated at the plateau were 2.2 × 102, 0.6 × 102, and 1.1 × 102 µmol of OA/µmol of triolein, for the control,
after the addition of OA before or 5 min after lipolysis started,
respectively. Thus, at a physiologic ratio of HGL to substrate,
inhibition by exogenous free fatty acids was not observed. Inhibition
was only seen when a large unphysiologic excess of substrate was used.
To determine whether OA present in the substrate emulsion, rather than
externally added OA, would be inhibitory, phospholipid-triolein emulsions were prepared to include 2 or 6.9% OA, as described under
"Experimental Procedures." The results show that when OA was added
during the emulsification step, i.e. when the free fatty acids were part of the emulsion, significant modulation of the kinetics
of triacylglycerol hydrolysis was observed (Fig. 3D). Indeed, the amounts of OA generated after the first 5 min of lipolysis of 2.0 and 6.9% OA-enriched emulsions were 1.98 × 102 and 2.66 × 102 µmol of OA/min,
compared with 1.82 × 102 µmol of OA/min for the
control. After 60 min lipolysis 0.521 and 0.534 µmol of OA/µmol of
triolein were released, respectively, compared with 0.306 µmol for
the control, and higher rates of lipolysis were reached (about 26% for
OA-enriched emulsions versus 15% for the control emulsion).
Thus, when OA was present in emulsions at 2.0 and 6.9% concentration,
the hydrolysis of the emulsion was enhanced (about 1.7 times). This
cannot be attributed to differences in emulsion size, as the
OA-enriched emulsions exhibited similar size to the control emulsion,
i.e. 2.5 and 1.3 µm for the 2 or 6.9% OA-enriched
emulsions, respectively (data not shown), versus 2 µm for the 0% OA control emulsion. These results indicate
that the reported inhibitory effect of protonated free fatty acids on
gastric lipolysis is more complex than previously envisioned, and that
physicochemical events occurring within or at the lipid droplet surface
during lipolysis under physiological conditions warrant further consider.
Lipolysis of a Pre-lipolysed Emulsion--
Because changes in the
lipid/water interfacial tension or in the surface pressure of the
emulsion droplet could be involved in the inhibition of lipolysis
catalyzed by the gastric lipase (13, 24, 25), we tested the hydrolysis
of an already maximally lipolysed [3H]emulsion,
i.e. once the rate of lipolysis had plateaued, by a second
addition of gastric lipase (Fig.
4A). In the first step, the
lipolysis rate of the emulsion during the first 5 min was 1.06 × 102 OA µmol/min and the amount of OA generated reached
0.275 µmol of OA/µmol of triolein after 60 min of lipolysis. After
the second addition of HGL, lipolysis started again, releasing 0.7 × 102 µmol of OA/min during the first 5 min, and the
total amount of free fatty acids generated over the second 60-min
lipolysis period reached 0.149 µmol of OA/µmol of triolein,
representing 54% of OA released during the first lipolysis period.
These results show that even if the emulsion interface undergoes
modification due to lipolysis, the emulsion is still a suitable
substrate for newly added lipase. Thus, the enzyme can still bind to
and hydrolyze triolein emulsion, even when that substrate has been
previously lipolysed for 60 min, implying that changes in the interface
alone cannot be solely responsible for HGL inactivation.
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Fig. 4.
Sequential kinetics of hydrolysis of
emulsions by HGL following addition of new enzyme or new emulsion.
A, a medium-size emulsion was hydrolyzed by pure HGL for 60 min and then a new amount of pure HGL was added. Incubation was at
37 °C and pH 5.40, using 5 mM [3H]triolein
emulsions, 100 mM sodium acetate, 150 mM NaCl,
6 mM Cacl2, with 53.2 pmol of pure HGL/µmol
of triolein. Values are mean ± S.D. of three experiments.
B, ability of HGL to hydrolyze a new
[14C]emulsion after having hydrolyzed a
[3H]emulsion for 90 min. Incubation was at 37 °C and
pH 5.40, using 6.25 mM [3H]- and
[14C]triolein emulsions, 100 mM sodium
acetate, 150 mM NaCl, 6 mM CaCl2,
with 53.2 pmol of pure HGL/µmol of triolein or with gastric juice
having lipase activity equivalent to 53.2 pmol of pure HGL/µmol of
triolein. The amounts of [3H]OA released from the first
[3H]emulsion and the amounts of [14C]OA
released from the second [14C]emulsion were
measured.
|
|
Behavior of HGL during Lipolysis of Sequentially Added
Emulsions--
To examine HGL during lipolysis, a medium-size
[3H]emulsion was incubated with pure HGL (53.2 pmol/µmol of triolein) for 90 min, the time necessary to reach a
plateau for lipolysis. Subsequently, another medium-size
[14C]emulsion was added and the lipolysis was followed
for another 90-min period (Fig. 4B). Under these
experimental conditions, the HGL/TO ratio was still in the
physiological range (3, 10, 15). During the first and the second
lipolysis, respectively, 1.72 × 102 µmol of
[3H]OA/min and 0.38 × 102 µmol of
[14C]OA/min were released for the first 5 min, and the
amounts of free fatty acids generated reached 0.360 µmol of
[3H]OA/µmol of triolein and of 0.115 µmol of
[14C]OA/µmol of triolein after 90 min. Interestingly,
during the second incubation, no further [3H]OA was
produced. Thus, the first lipolysis released 6.77 µmol of
[3H]OA/nmol of HGL and the second one produced no more
[3H]OA and 2.16 µmol of [14C]OA/nmol of
HGL. The total amount of OA released during the second lipolysis
represented 31.9% of the amount generated during the first lipolysis.
To better mimic physiological conditions we performed the same
experiment using human gastric juice (Fig. 4B). The amount of free fatty acid released for the first 5 min of incubation was
1.42 × 102 µmol of [3H]OA/min,
versus 0.16 × 102 µmol of
[14C]OA/min during the second lipolysis; at 90 min of
lipolysis, 0.346 µmol of [3H]OA/µmol of triolein and
0.173 µmol of [14C]OA/µmol of triolein were produced.
In parallel, we observed that after addition of the
[14C]emulsion, the lipolysis started again, to a small
extent, on the [3H]emulsion, leading to the release of
27.7% of free fatty acids generated during the first lipolysis. On
average, the first lipolysis generated 6.50 µmol of
[3H]OA/nmol of HGL and the second one, 1.80 µmol of
[3H]OA/nmol of HGL and 3.25 µmol of
[14C]OA/nmol, i.e. 77.7% of the amount of OA
released during the first lipolysis. We noted that HGL in intact juice
gave qualitatively similar results than pure HGL but the absolute rate
of lipolysis was different. This could mean that additional
nonidentified compounds in gastric juice might modify lipolysis. These
results show that HGL was not dramatically denaturated by exposure to
triolein-PL-emulsion substrate and was still able to hydrolyze a new
substrate triolein-PL-emulsion, albeit to a somewhat lesser extent.
Surface-to-core Distribution of Lipolysis-generated Free Fatty
Acids--
The lipid composition of the surface and the core of the
lipid droplets of a medium-size emulsion, before and after lipolysis, was determined using the physicochemical method developed by Miller and
Small (11) for artificial lipoproteins. This method is based on
separation of the core and the surface of the lipid droplet by
ultraspeed centrifugation in a thin space (glass capillary tubes),
using the fact that the density of the core and the surface phases are
markedly different because of their lipid compositions (11, 14, 37).
Data obtained after 10 min lipolysis by HGL at pH 5.4 are given in
Table I. The data obtained after 25 and 60 min lipolysis were deemed not as reliable because the density of the
surface became lower as the surface became highly enriched in lipolytic
products, making it impossible to effectively separate the surface from
the core. Surface-to-core distribution of triolein underwent
modification early during lipolysis. The phase distribution coefficient
(the weight fraction in the surface phase to the weight fraction in the
core phase, Ref. 11) varied greatly for triolein, decreasing from 0.051 to 0.0016, but remained relatively constant for cholesterol (7.77 to
7.53). After 10 min lipolysis, the phase distribution coefficients were
0.89 for diolein, 15.50 for monoolein, and 7.40 for oleic acid.
Thus, diolein partitioned almost equally between surface and core,
whereas monoolein and oleic acid had a higher affinity for the surface.
When the actual weight partition for each lipid was calculated
according to Miller and Small (13) taking into account the proportional
mass of core and surface, it was found that 8.99, 17.30, and 2.23% of
total free oleic acid, monoolein, and diolein generated during 10 min
lipolysis, respectively, were located within the surface. In addition,
0.01 and 11.15% of the total triolein and free cholesterol present in
the emulsion, respectively, were present in the surface.
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Table I
Lipid composition of the surface and core of a medium-size emulsion
lipid droplet before and after 10 min lipolysis by HGL
Values are given as wt % and represent the mean ± S.D. of three
determinations.
|
|
Scanning Electron Microscopy of Lipid Droplets during Lipolysis by
HGL--
Before lipolysis, the lipid droplets of a medium-size
emulsion appeared as spheres of about 0.5 to 2 µm diameter with
smooth surfaces (Fig. 5A).
During lipolysis the size of lipid droplets increased from a range of
2.6 to 6.4 at 5 min to 5.6-10 µm at 80 min. Notably the appearance
of the droplets changed (Fig. 5, B and C). The
surface of the lipid droplets became irregularly covered with
small-sized spherical protrusions (<1 µm) after 5 min (Fig.
5B, arrow 1, enlargement in E) and 25 min (data not shown) of HGL lipolysis. As lipolysis continued,
i.e. at 50 (data not shown) to 80 min (Fig. 5C,
arrow 2, enlargement in D), the enlarged lipid
droplets still appeared irregular, with a surface containing less
spherical protrusions and also showing the appearance of amorphous
lipid clusters.
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Fig. 5.
Scanning electron micrographs of lipid
droplets during hydrolysis by HGL. A, before lipolysis, the
medium-size emulsion contains lipid droplets that appear as spheres
from about 0.5 to 2 µm diameter with smooth surfaces. B,
after 5 min incubation with HGL the lipid droplet size increased (range
2.6 to 6.4 µm), and their surface became irregularly covered by small
size spherical protrusions (<1 µm, arrow 1, enlargement
in E). After 50 (data not shown) and 80 min (C)
lipolysis, the droplet size was still greater (range 5.6 to 10 µm),
and the droplet surface still appeared irregular containing fewer
spherical protrusions with also the appearance of amorphous lipid
clusters (C, arrow 2, enlargement in
D). Specimens were fixed with OsO4 at pH 5.40, put on a microscope cover glass, and coated with gold-palladium before
viewing. The bar represents 2 µm in all figures.
Magnification: ×6,000 for A; ×5,400 for B;
×4,800 for C.
|
|
Immunolocalization of HGL during Lipolysis of Lipid
Droplets--
To further examine HGL during lipolysis, a FITC-labeled
HGL was incubated for 60 min with a medium-size triolein-PL emulsion and then a medium-size dansyl-labeled triolein-PL emulsion was added
(Fig. 6, A and B).
FITC-HGL (Fig. 6B) was found associated either with highly
fluorescent lipid droplets (Fig. 6A) of the dansyl-labeled
emulsion (arrow 1) or with slightly fluorescent lipid
droplets (arrow 2). In both cases, the FITC-HGL fluorescence was quite inhomogeneous. The slightly fluorescent droplets probably arise from the fusion of a non-labeled droplet with a labeled droplet,
since dansyl-labeled lipid droplets in the absence of nonlabeled lipid
droplets show a homogeneous bright fluorescence (data not shown). Thus
based on the non-uniform distribution of the FITC-HGL, we suggest that
HGL may be associated with lipid clusters formed at the lipid droplet
surface during lipolysis. Those clusters trapping HGL might transfer
from a droplet to a new one directly (arrow 1) or indirectly
by fusion of the two droplets (arrow 2).
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Fig. 6.
Evolvement of HGL during lipolysis of lipid
droplets. An aliquot of a medium-size emulsion incubated
with HGL for 60 min was mixed in a shaking bath at 37 °C, pH 5.40, for 15 min with a medium-size emulsion labeled with dansyl cholesterol.
The mixture was then incubated with polyclonal anti-HGL for 30 min on
ice, and then with FITC-conjugated goat anti-rabbit IgG for 30 min on
ice. Samples were examined either using filters specific for dansyl
(A) (blue, lipid droplets) and for FITC
(B) (green, HGL). FITC-labeled HGL was clearly
found associated with highly fluorescent lipid droplets from the
dansyl-labeled emulsion (arrow 1) and with slightly
fluorescent lipid droplets (arrow 2) probably issued from
the fusion of a non-labeled droplet with a labeled droplet.
Magnification: ×1,200.
|
|
Co-localization of HGL and Free Fatty Acids Generated during
Lipolysis--
To further explore the hypothesis that HGL is
associated with free fatty acid clusters formed at the lipid droplet
surface during lipolysis, the co-localization of both was investigated by adding copper, that binds specifically to free fatty acids, in a
medium-size emulsion hydrolyzed by an active rhodamine-HGL. Visualization of both types of fluorescence showed that the green fluorescence, corresponding to the free fatty acids generated (Fig.
7A), and the red fluorescence,
corresponding to HGL (Fig. 7B), were perfectly co-localized.
Controls without copper were performed (Fig. 7, C and
D), demonstrating that HGL localization was not altered by
copper addition per se.
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Fig. 7.
Co-localization of HGL and free fatty acids
generated during lipolysis of a medium-sized emulsion. A
medium-sized emulsion was incubated for 60 min in a shaking bath at
37 °C, pH 5.4, with an active TRITC-labeled HGL. In parallel, the
localization of the free fatty acids generated during lipolysis was
ascertained using a labeling method specific to fatty acids,
i.e. copper acetate was added to an aliquot of the reaction
medium to bind free fatty acids and copper-fatty acids were visualized
after labeling with FITC-Gly-Gly-His. A and B or
C and D represent the same sample examined at two
different wavelengths either using specific filters for fluorescein
(green fluorescence, copper-fatty acids) (A and
C) or rhodamine (red fluorescence, HGL) (B and
D). C and D represent samples treated
without copper but with FITC-Gly-Gly-His. Green fluorescent-free fatty
acids (A) and red fluorescent HGL (B) were
clearly co-localized. Magnification: ×1,200.
|
|
Isolation and Composition of the Lipid Particles Generated during
Lipolysis--
If the hypothesis that lipid particles form at the
interface from lipid clusters during gastric lipolysis were true, it
should be possible to isolate these particles. As described under
"Experimental Procedures" we have isolated the lipid particles from
a medium-size emulsion lipolysed by HGL for 90 min using gel
filtration, and analyzed them. These particles were composed of 73.7%
free fatty acid, 15.6% phospholipid, 5.0% monoacylglycerol, 3.5%
diacylglycerol, 1.2% free cholesterol, and 0.9% triacylglycerol. The
composition of these particles was different from the surface
composition of the droplets, particularly in that they were highly
enriched in free fatty acids. Their apparent size (median diameter)
determined after isolation using a quasielastic light-scattering
detector was 196 ± 16 nm. Moreover, the isolated particles were
found to contain HGL as assessed by immunodetection.
| |
DISCUSSION |
In humans, gastric lipase is the key enzyme achieving the first
step of dietary lipid digestion (1, 3, 6). This enzyme has been shown
to be markedly inhibited by protonated free fatty acids (8, 23),
thereby explaining the limited lipolysis of triacylglycerols under
gastric conditions, compared with the complete triacylglycerol
hydrolysis by pancreatic lipase in the duodenum (4, 10). Nevertheless,
the mechanisms of the inhibition process have not yet been elucidated.
To better understand the mechanism of action of gastric lipase,
in vitro lipolysis experiments were conducted under
conditions close to those occurring in the human stomach using three
differently sized emulsions, a coarse (about 15 µm), a medium (about
2 µm), and a fine one (about 0.7 µm). These emulsions cover the
large range of sizes of dietary emulsions found in human stomach
contents (3, 10, 18, 38). As anticipated from prior studies (8, 10),
the inhibition of gastric lipolysis is highly dependent on the
water/lipid interface area, directly related to the lipid droplet size.
In addition, the concentration of free fatty acids generated expressed
as micromoles/m2 surface area (8, 10), rather than total
fatty acid concentration (23), is a key regulatory factor. The
lipolysis catalyzed by gastric lipase varied inversely with the droplet
size of the emulsion and the maximum extent of lipolysis in our
in vitro model reached ~7 to 23%, close to values found
in vivo (10, 18, 20). Lipolysis reached a plateau when the
generated free fatty acid concentrations were 122, 107, and 114 µmol/m2 lipid surface area, for the fine, medium, and
coarse emulsions, respectively. Again, these values are close to those
previously found in healthy humans (121-128 µmol/m2)
(10) or in children with cystic fibrosis (164-172
µmol/m2).2
Taken together, these data indicate that our in vitro model
is relevant to human gastric lipolysis, and, hence, suitable for the
study of the mechanisms involved in the physiological inhibition by
free fatty acids.
We found that the presence of long chain free fatty acids per
se was not inhibitory of lipolysis, since externally added oleic acid in amounts close to, or even higher than those generated during
physiological gastric lipolysis, did not alter the kinetics of triolein
hydrolysis by gastric lipase (Fig. 3, A and B).
Indeed, free fatty acids somewhat stimulated lipolysis (× 1.7) when
added as preformed triolein-PL-OA emulsions (Fig. 3D). An
inhibitory effect of the externally added OA was only obtained in the
presence of a large excess of substrate (Fig. 3C),
i.e. under unphysiological conditions (8, 23). These results
indicate that it is the long chain free fatty acids endogenously
generated that are potent inhibitors of gastric lipolysis under
physiological conditions. This suggests, in turn, an important role of
specific lipid-lipid or lipid-protein interactions.
To understand how free fatty acids play a role in the inhibition
process, we studied the localization of the generated free fatty acids
within the emulsion. The present results show for the first time that
at pH 5.40 oleic acids generated during lipolysis accumulate in part in
the surface monolayer of the lipid droplet, with a surface-to-core
molar phase distribution coefficient of 7.4 after 10 min lipolysis.
Thus, during gastric lipolysis free fatty acids have higher affinity
for the surface than the core of the droplets. This value is close to
the surface-to-core distribution coefficients reported for
triolein-PL-OA artificial emulsions at neutral pH, i.e.
around 7 to 10 (26-28). Taking into account the relative masses of the
surface monolayer and the core in these lipid droplets, the surface
being far smaller than the core, we have calculated (13) that about 9%
of the total free fatty acids generated are present in the surface of
the droplet, while about 91% are within the core. Thus free fatty
acids partly accumulate at the droplet surface.
Our results showed that other lipolytic products, such as diolein and
monoolein, are also present in the droplet surface monolayer, representing 2.2 and 17.3%, respectively, of the total amount of each
lipid species generated during lipolysis. It is therefore possible that
the presence of diacylglycerols and/or monoacylglycerols (39) at the
lipid droplet surface might also be involved in the inhibition of the
lipolysis by gastric lipase. We also found that the surface monolayer
content of triacylglycerol decreased 33-fold following 10 min
lipolysis. This indicates quantitatively that the interfacial
availability of triacylglycerols for hydrolysis is a function of the
surface composition of the droplet which evolves as lipolysis proceeds,
as previously reported for chylomicrons (40). It is noteworthy that the
great change in the number of triacylglycerol molecules exposed at the
droplet surface occurs very rapidly, within 10 min after lipolysis
started, whereas the full inhibition of triacylglycerol hydrolysis by
gastric lipase occurs after a longer period of time, ~60 min. This
suggests that, at least for gastric lipase, a marked decrease in the
number of triacylglycerol molecules present at the surface of the
droplet is not a key mechanism involved in the inhibition process. It is possible that a small quantity of triacylglycerol exposed at the surface is enough to permit lipolysis, and that this level is kept
more or less constant by a core-to-surface transfer of triacylglycerol
molecules (13).
The generation of surface active products can considerably modify the
physicochemical properties of the remaining substrate in such a system
(2). Indeed, a considerable fusion of the lipid droplets occurs during
gastric lipolysis, as previously observed (16), probably due to the
presence of free fatty acids, monoacylglycerols, and diacylglycerols
that are known to be fusiogenic (16). This change in the lipid
composition of the droplet surface during lipolysis could modify the
interfacial tension or the surface pressure and consequently interfere
with gastric lipase binding and activity (2, 24, 25). Alternatively, at
a high interfacial energy of the lipid/water interface or at a certain
droplet surface pressure, gastric lipase could undergo an irreversible
denaturation involving a change from a globular to an unfolded
conformation at the interface (2, 25). As HGL contains only one
disulfide bridge, it has been postulated that it can be denaturated
more readily than pancreatic lipase with six disulfide bridges (25). In
fact, our data do not support these hypotheses since (i) newly added
lipase can further hydrolyze a previously lipolysed emulsion showing
that the substrate is still available and (ii) a new emulsion added to
a previously lipolysed one can be hydrolyzed by the present gastric
lipase, indicating that interfacial denaturation is not a likely
mechanism for the inhibition of lipolysis.
It seems likely, therefore, that the accumulation of oleic acid at the
droplet surface leads to an inhibition of lipolysis by gastric lipase.
The mechanism by which this happens was further investigated using
microscopy and the results support this hypothesis. Scanning electron
microscopy of hydrolyzed emulsions at pH 5.40 allowed us to observe the
formation of clusters at the surface of the lipid droplets. The
hypothesis that free fatty acids were present in these clusters was
supported by immunofluorescence experiments using copper to localize
free fatty acids. The fact that copper readily bind to fatty acids
(Fig. 7) suggests that free fatty acids present at the surface of the
lipid droplet are not fully organized within the surface monolayer but
rather may be exposed in an ionized state, in part, at the surface.
Co-localization experiments showed that HGL labeled with rhodamine was
present in an identical distribution with the free fatty acids in the clusters formed at the surface of the lipid droplets during lipolysis. Moreover, isolation of these clusters showed that they are particles of
about 200 nm mainly composed primarily of free fatty acids (approximately 74%), as well as phospholipids (16%),
monoacylglycerols (5%), diacylglycerols (4%), free cholesterol
(1%), triacylglycerols (<1%), and HGL. Interestingly, the lipid
composition of these particles is close to that of the pelleted
material found in the human stomach content during fat digestion (3),
suggesting that they could have the same origin. Thus, it is likely
that gastric lipase becomes bound to and perhaps trapped in these fatty acid-rich particles that are generated during lipolysis at the droplet
interface, thereby preventing further hydrolysis of the substrate.
Nevertheless, a fluorescence study using an emulsion labeled with
dansyl cholesterol and FITC-labeled HGL clearly demonstrated that HGL
can move from a previously hydrolyzed droplet to a new one. Thus, it is
possible that the partial lipolysis that was observed after addition of
a new substrate is due to a limiting rate of the transfer of HGL,
secondary to its being trapped within the fatty acid-rich particles at
the droplet surface.
Based on the present findings and previous work of ours and others, we
propose the following working model for the mechanism of inhibition of
gastric lipolysis (Fig. 8). Step 1, HGL
binds at the surface of the lipid droplet. At t = 0, the droplet surface is composed of phospholipids, free cholesterol, and
some triacylglycerol molecules. Step 2, lipolysis begins, generating
mainly free fatty acids and diacylglycerols, with a small amount of
monoacylglycerols. These lipolytic products partition to the surface
and core of the lipid droplet according to their physicochemical
properties, i.e. a higher proportion of free fatty acids and
monoacylglycerols than diacylglycerols partition at the surface. The
surface area begins to expand as lipolysis continues. Step 3, at a
certain time point, the surface pressure increases such that excess
free fatty acid-enriched surface begins to reorganize into peripheral clusters that trap HGL during their formation, leading to the formation
of particles budding at the droplet surface as lipolysis proceeds. Step
4, the trapped HGL, although still present at the surface of the lipid
droplet, has diminished access to the triacylglycerol that is present
in the areas of the droplet surface free of fatty acid-rich particles.
The lipolysis inhibition process is completed over 60 min because HGL,
even in a trapped form, appears to be able to still bind and act on
particle-free lipid droplet surface, by transferring from one droplet
to another one.
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Fig. 8.
Schematic representation of the
physicochemical process involved in the inhibition of gastric
lipolysis. Step 1, HGL binds at the surface of the lipid droplet.
At t = 0, the droplet surface is composed of
phospholipids, free cholesterol and some molecules of triacylglycerol.
Step 2, lipolysis begins generating mainly free fatty acids and
diacylglycerols, with a small amount of monoacylglycerol. These
lipolytic products partition to the surface and core of the lipid
droplet according to their physicochemical properties, i.e.
a higher proportion of free fatty acids and monoacylglycerols than
diacylglycerols partition at the surface. The surface area begins to
expand as lipolysis continues. Step 3, with time, the surface pressure
increases such that excess free fatty acid-enriched surface reorganizes
into peripheral particles that trap HGL during their formation. Step 4, the trapped HGL, although still present at the surface of the lipid
droplet, has diminished access to the triacylglycerol that is present
in the areas of the droplet surface free of fatty acid-rich particles.
The lipolysis inhibition process is completed over 60 min because HGL,
even in a trapped form, appears able to transfer to a particle-free
surface on a new droplet.
|
|
The role of these newly observed gastric fatty acid-rich
particles in lipid digestion needs to be further explored; in
particular, it will be important to determine whether the prevention of
surface particle formation, through manipulation of emulsion
properties, can extend the effectiveness of HGL activity for the
benefit of patients suffering from lipid maldigestion and
malabsorption due to pancreatic insufficiencies.
| |
ACKNOWLEDGEMENTS |
We thank Drs. D. M. Small and A. Derksen
for the core-to-surface partition technique, Dr. Jacques Peyrot and
Professor J. Salducci for the generous gift of gastric juice, Drs.
Alexandre Misharin and Christian Alquier for the generous gift of
dansyl cholesterol, Claude Alasia and Jean Luc Ansaldi for technical help with scanning electron microscopy, and Dr. Gérard
Piéroni for scientific discussions.
| |
FOOTNOTES |
*
This work was supported in part by the Laphal Laboratory.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
To whom correspondence should be addressed: INSERM Unité
476, 18 Avenue Mozart, 13009 Marseille, France. Tel.: 33-4-91-75-86-00; Fax: 33-4-91-75-15-62; E-mail: armand@marseille.inserm.fr.
Published, JBC Papers in Press, April 8, 2002, DOI 10.1074/jbc.M202839200
2
M. Armand and M. Hamosh, unpublished observations.
| |
ABBREVIATIONS |
The abbreviations used are:
HGL, human
gastric lipase;
PL, phospholipid;
OA, oleic acid;
FITC, fluorescein
isothiocyanate;
dansyl, 5-dimethylaminonaphthalene-1-sulfonyl;
TRITC, tetramethyl rhodamine isothiocyanate;
TO, triolein.
| |
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