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J. Biol. Chem., Vol. 277, Issue 48, 45874-45879, November 29, 2002
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From the Mike Rosenbloom Laboratory for Cardiovascular Research,
McGill University Health Center, Montreal, Quebec H3A 1A1,
Canada
Received for publication, July 19, 2002, and in revised form, September 18, 2002
Acylation-stimulating protein (ASP) acts as a
paracrine signal to increase triglyceride synthesis in adipocytes. ASP
administration results in more rapid postprandial lipid clearance. In
mice, C3 (the precursor to ASP) knockout results in ASP deficiency and leads to reduced body fat and leptin levels. The protective potential of ASP deficiency against obesity and involvement of the leptin pathway
were examined in ob/ob C3( Acylation-stimulating protein
(ASP)1 is an
adipocyte-derived protein that has potent anabolic effects on human
adipose tissue for both glucose uptake and non-esterified fatty acid
(NEFA) storage (1, 2). This occurs via translocation of glucose
transporters (GLUT1, GLUT3, and GLUT4) from intracellular sites to the
cell surface (3, 4) and an increase in diacylglycerol acyltransferase (DGAT) activity (2). These effects appear to be mediated through specific cell surface binding (6, 7), resulting in activation of a
signaling pathway that includes protein kinase C (8). In addition, ASP
has been shown to inhibit hormone-sensitive lipase in adipocytes,
independently and additively to insulin (9). There is a
differentiation-dependent increase in ASP binding and ASP
response in adipocytes (1). The major site of action of ASP is
adipocytes, as determined by competitive binding, stimulation of
triglyceride synthesis, enhanced glucose transport, and transporter translocation (6).
ASP is identical to C3adesArg, a cleavage product of complement C3.
Cleavage of complement C3 is mediated through the alternate complement
pathway via the interaction of C3, factor B, and adipsin that generates
C3a. Rapid cleavage of the C-terminal arginine of C3a by
carboxypeptidase N generates ASP (10). Adipocytes are one of
the few cells capable of producing all three factors (factor B,
adipsin, and C3) that are required for the production of ASP (11). ASP
production increases consequent to adipocyte differentiation (13), and
plasma ASP levels are elevated in obesity (14, 15). Chylomicrons
in vitro stimulate ASP production by adipocytes (16, 17).
In vivo arterial-venous gradients across a subcutaneous
adipose tissue bed in humans demonstrate direct postprandial production
of ASP (18). The postprandial increase in ASP is adipose tissue
specific and is not observed in the general circulation (19).
Altogether, these data suggest that ASP and lipid storage are
metabolically intertwined.
ASP acts as an adipocyte autocrine factor and we propose that it plays
a central role in the metabolism of adipose tissue by increasing the
efficiency of triglyceride synthesis in adipocytes, an action that
results in more rapid postprandial lipid clearance (20). As ASP is
derived through cleavage of complement C3, C3 knockout mice are
necessarily deficient in ASP. We have previously demonstrated that
genetic deficiency of ASP leads to reduced body fat and decreased
leptin levels (21, 22). In addition, male mice have delayed
triglyceride clearance (22, 18) although this has not been demonstrated
in all studies (23).
To determine the influence of the leptin pathway on ASP action and
obesity resistance, we examined the effect of ASP deficiency in
ob/ob mice, which are leptin-deficient. The ob/ob
mice have been used to test for protection from obesity in a number of
double knockout models, such as the ob/ob VLDL
receptor( Leptin is produced by adipocytes (26) and is involved in the regulation
of body fat stores. Leptin is critically involved in the regulation of
body energy balance via its central actions on food intake and energy
expenditure (27). Ob/ob mice lose an important negative
feedback on food intake caused by a leptin gene mutation. It is well
known that leptin acts via a receptor in the hypothalamus, while there
is little evidence that ASP acts via this route. However, leptin also
appears to have peripheral actions on substrate fluxes in the adipose
tissue (28) and may act directly on adipocytes, where it has been
reported to increase lipolysis and impair insulin-mediated lipogenesis
(29, 30). Finally, leptin production is regulated by insulin responses
to meals (31), an effect that appears to involve increased adipocyte glucose metabolism (32). Leptin and ASP contrast both in their function
and major site of action; however both alter energy disposition through
altering either storage or oxidation and the aim of this paper was to
determine how the absence of leptin coupled to ASP deficiency alters
fat metabolism.
Generation and Genotyping of Mice--
The leptin and complement
C3 double knockout (2KO) mouse strain was generated by crossing the
Leptin (+/ Genotyping--
The mice were selected by genotyping with PCR as
described previously for C3 (21, 22) and for the leptin gene (33). Mice
tail tips were collected when the mice were weaned at 3 weeks of age.
Tails were digested with 750 ul of digestion buffer (500 µM Tris, 50 µM EDTA, 0.004% SDS, 40 mM NaCl, 0.028% proteinase K, pH 8.5) at 56 °C
overnight with mild rotation. Samples were centrifuged (14,000 × g, 5 min). To the supernatant was added 600 ul of isopropyl
alcohol followed by centrifugation for 1 min at 14,000 × g to isolate the DNA pellet. The DNA was washed with 70%
ethanol and then re-dissolved in 50 ul of Tris/EDTA buffer. For PCR, 1 ul of DNA was used.
The primers used for ob/ob mice genotyping were: Sn,
5'-TGACCTGGAGAATCTCC-3' and Asn, 5'-CATCCAGGCTCTCTGGC-3' for the wild type leptin gene and Sn, 5'-TGACCTGGAGAATCTCC-3' and Asn,
5'-TGACCTGGAGAATCTCT-3' for the mutated leptin gene. PCR conditions
were: 10 µM each leptin primer, 200 µM
dNTP, 2 mM MgCl2, 10 µM TMAC
amplified for 35 cycles of 94 °C, 1 min; 55 °C, 1 min; and
72 °C, 1 min.
For detection of the C3 gene: Sn,
5'-CTTAACTGTCCCACTGCCAAGAAACCGTCCCAGATC-3' and Asn,
5'-CTCTGGTCCCTCCCTGTTCCTGCACCAGGGACTGCCCAAAATTTCGCAAC-3' were used for
the wild type complement C3 gene, and Sn,
5'-ATCGCATCGAGCGAGCACGTACTCGGA-3' and Asn,
5'-AGCTCTTCAGCAATATCACGGGTATCC-3' were used for neomycin detection in
the complement C3 knockout mice. The PCR condition for genotyping were:
32 µM each primer, 200 µM dNTP, 1.5 mM MgCl2 for 35 cycles of 94 °C, 1 min;
67 °C, 1 min; and 72 °C, 1 min.
All of the recruited mice had body weight determined every week and
food intake was measured every 2 days from the 4th week to the 17th
week of age.
Fat Load--
Fat loads were done as a crossover design
experiment. 2KO mice were divided into 2 groups. When the mice were 14 weeks old, a fat load was given to 2KO mice (half with ASP injection
and half without ASP injection), as well as wild type mice (male and female) and ob/ob mice (male and female). After an overnight
fast (16 h), 400 ul of olive oil (followed by 100 ul of air above the oil) was administrated by gastric gavage using a feeding tube (12-cm
curved ball tipped feeding needle (34)) according to standard
procedures as previously published (21, 22, 35-38). There was at least
a 2-week interval between the fasting blood sample and the fat load.
Blood (40 ul) was collected at 0, 2, 4, and 6 h by tail bleeding.
Where indicated, ASP was injected intraperitoneally at the time of the
fat load. ASP was purified and injected as described previously. Each
mouse received intraperitoneally either sterile ASP (500 µg)
dissolved in 300 µl of phosphate-buffered saline, pH 7.4, containing
1 mg/ml fatty acid free bovine serum albumin (Sigma) or sterile vehicle
(same solution without ASP). Previous experiments have demonstrated
that injection of the vehicle solution (1 mg/ml bovine serum albumin in
phosphate-buffered saline, 300 µl) had no effect of postprandial TG
clearance in the mice compared with the same mice without vehicle as
shown previously (21, 22). When the mice were 16 weeks old, a fat load
was given to the 2KO mice again, but the groups were switched. The remaining wild type mice and ob/ob mice were given fat loads
at the same time. Blood was collected as before.
Plasma Assays--
Blood was collected at 14 weeks (for fasting
lipids and glucose), 16 weeks (for fat load test), and 22 weeks (to
measure insulin) into EDTA-containing tubes by tail bleeding from mice
fasted overnight (16 h) with water ad libitum. Blood was
separated by centrifugation and stored at Oxygen Consumption Measurement--
Oxygen consumption and
CO2 production were measured using the Columbus Instrument
Oxymax System (Columbus Instruments, Columbus, OH). Each mouse was
measured individually over 4 h in a resting state at 21 °C in
the absence of food and water. Five time points were sampled, and the
experiment was repeated the following day. The average value was used
in the analysis.
Statistical Analysis--
All results are presented as
average ± S.E. Statistical comparisons were by Student's
t test, ANOVA, 2-way ANOVA, or Pearson Correlation as
indicated in the text and figure legends. Statistical significance was
set at p < 0.05, where p ns indicates not significant.
We first examined body weight in these double knockout
ob/ob C3( In ASP-deficient mice, we have previously demonstrated a delayed
postprandial triglyceride and non-esterified fatty acids (NEFA)
clearance following a fat load in the male mice (21, 22), and we also
examined these parameters in the mice. Despite their pronounced
obesity, the ob/ob mice have a similar NEFA profile to the
wild type mice (Fig. 2). However, while
the fasting NEFA levels were no different in 2KO mice, they demonstrate
clearly a delayed postprandial NEFA clearance compared with both the
ob/ob group and the wild type group (Fig. 2,
p < 0.01 by 2-way ANOVA for 2KO versus wild
type). Intraperitoneal administration of ASP restored a normal NEFA
clearance pattern. Similar changes were demonstrated in the
triglyceride profiles (as shown in Fig.
3) where again the ob/ob mice
had a relatively normal postprandial triglyceride clearance, which is
markedly delayed in the 2KO mice (p < 0.01).
Interestingly, the delayed NEFA and triglyceride clearance in the 2KO
mice were present in both male and female mice, a difference from
previous studies in ASP-deficient mice, where only the male mice
demonstrated delayed triglyceride clearance (21, 22).
Acylation-stimulating Protein (ASP) Deficiency Induces Obesity
Resistance and Increased Energy Expenditure in ob/ob
Mice*
ABSTRACT
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/) double knockout mice
(2KO). Compared with age-matched ob/ob mice, 2KO mice had
delayed postprandial triglyceride and fatty acid clearance; associated
with decreased body weight (4-17 weeks age: male: 13.7%, female:
20.6%, p < 0.0001) and HOMA (homeostasis model
assessment) index (37.7%), suggesting increased insulin sensitivity.
By contrast, food intake in 2KO mice was +9.1% higher over
ob/ob mice (p < 0.001, 2KO 5.1 ± 0.2 g/day, ob/ob 4.5 ± 0.2 g/day, wild type 2.6 ± 0.1 g/day). The hyperphagia/leanness was balanced by a 28.5%
increase in energy expenditure (oxygen consumption: 2KO, 131 ± 8.9 ml/h; ob/ob, 102 ± 4.5 ml/h; p < 0.01; wild type, 144 ± 8.9 ml/h). These results suggest
that the ASP regulation of energy storage may influence energy
expenditure and dynamic metabolic balance.
INTRODUCTION
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/) or the ob/ob PAI-1(/). In most cases,
the decrease in weight, which was evident in the single knockout, was
enhanced when examined on the background of the ob/ob obese
mouse model (24, 25).
MATERIALS AND METHODS
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) mice (C57Bl/6, Jackson Laboratories, Bar Harbor, ME) with
complement C3 knockout (C3/) (129/Sv genetic background)
(previously obtained from Dr. Harvey Coulton) to generate (Leptin+/,
C3+/) mice. The mixed genetic background mice were bred to generate
Leptin(+/) C3(/), Leptin(+/) C3(+/+). These leptin(+/)
heterozygous mice were used to generate ob/ob C3(/) 2KO
mice as well as ob/ob C3 (+/+) and wild type mice. All the
mice studied were of a mixed genetic background but littermates were
used. Mice were housed in a pathogen-free barrier facility, 21 °C,
12/12 h light cycle, and fed regular rodent chow food. All procedures
on mice followed the guidelines established by the CACC and were
approved by the Royal Victoria Hospital Animal Care Committee.
80 °C until analysis.
Fasting insulin was measured using a rat insulin RIA kit (Linco Inc.,
St. Charles, MO, cat. RI-13K), which has 100% cross-reactivity to
mouse insulin (as described by the manufacturer, Linco Research, Inc.).
Glucose was measured using a Trinder glucose kit (Sigma). Plasma
non-esterified fatty acids (NEFA) and triglyceride were measured using
colorimetric enzymatic kits (Roche Molecular Biochemicals, Laval, Canada).
RESULTS
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/) (2KO) mice. Compared with the
ob/ob mice of the same age, 2KO have lower body weight. As
shown in Fig. 1, this is especially pronounced during the 4-12 week age group. Over the total time (4-17
weeks) there was a 13.7% reduction of body weight in the males, and a
20.6% reduction in the females (both p < 0.0001) (Fig. 1). The effect was the same in male and female mice.
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Fig. 1.
In both male and female 2KO mice had
significantly lower body weight than the ob/ob group
but higher than the wild type group. Male, 13.7%; female,
20.6% versus ob/ob over 4-17 weeks,
p < 0.0001. The number of subjects (n) is
6. Values are shown as mean ± S.E. for n = 6 per
group. The data were analyzed using ANOVA.
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Fig. 2.
NEFA clearance after a fat load. Wild
type, ob/ob and 2KO were given an oral fat load, serial
blood samples were obtained, and serum NEFA measured. 2KO were
significantly different from wild type (p < 0.01). ASP
administration (intraperitoneal ASP) restored the NEFA profile to
normal. (as versus wild type or ob/ob mice).
Values are shown as mean ± S.E. for n = 12. The
data were analyzed using 2-way ANOVA.
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Fig. 3.
Both male and female 2KO mice had delayed
postprandial triglyceride clearance compared with ob/ob
mice or wild type mice. The ob/ob mice had a
profile similar to the wild type mice (p value NS) while the
2KO were significantly different (p < 0.01). Values
are shown as mean ± S.E. for n = 6 per group. The
data were analyzed using 2-way ANOVA.
In addition to lipids, we also measured fasting insulin and glucose
in the three groups of mice. The obesity in ob/ob mice is
usually associated with increased plasma insulin and glucose, as
quantitated by the HOMA index (the homeostasis model assessment for
insulin resistance, Ref. 12) and this is also shown here. There was no
difference in fasting or postprandial glucose between 2KO and
ob/ob. The fasting glucose was: 2KO 4.1 ± 0.7 mM; ob/ob 4.0 ± 0.5 mM; wild
type 4.0 ± 0.4 mM. However the 2KO mice had lower
insulin levels and a significantly lower HOMA index (37.7%) as
compared with ob/ob mice (Fig.
4, inset, wild type: 2.7 ± 0.5 mM·milliunits/liter, ob/ob 15.8 ± 2.4 mM·milliunits/liter, and 2KO: 9.8 ± 1.5 mM·milliunits/liter, p < 0.05),
suggesting greater insulin sensitivity in the 2KO mice compared with
the ob/ob. These changes in HOMA and in insulin are very
closely related to the decrease in body weight in the 2KO as shown in
Fig. 4A. Again, both male and female 2KO mice were equally
improved in this respect.
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The analysis of food intake is shown in Fig.
5A (inset).
Strikingly, although body weight is decreased in the 2KO compared with
the ob/ob mice, the 2KO mice actually ingest a greater
caloric amount. In the 2KO group, food intake was 5.3 ± 0.2 g/day, whereas it was 4.7 ± 0.2 g/day in the ob/ob and
only 2.6 ± 0.1 g/day in the wild type mice (2KO +9.1% increase
versus ob/ob, p < 0.001; +95%
increase versus wild type, p < 0.001). This
increase in food intake was seen in both males and females. Thus the
decreased body weight is not a result of decreased daily food intake.
Consequently, 2KO mice have a significantly reduced food efficiency
index: for a 1-g increase in body weight 2KO consume 17.5 ± 1.3 g of food, while the ob/ob consume 13.0 ± 0.8 g of food, p < 0.01. This parameter (food
efficiency) is significantly correlated with HOMA (Fig. 4B).
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The interesting phenomenon that the 2KO mice ate more food than
ob/ob mice daily, but gain less weight suggests that there are important alterations in energy expenditure and disposition. This
was examined by measuring oxygen consumption (VO2) and CO2 production in the 3 groups of mice (2KO, ob/ob, and wild
type). The results demonstrate that the ob/ob mice have
lower oxygen consumption than wild type mice, while oxygen consumption
in 2KO mice is almost restored to the same level as the wild type group (wild type, 144.3 ± 9.1 ml/h; ob/ob, 102.1 ± 7.6 ml/h; 2KO, 131.2 ± 7.7 ml/h; +28.5% versus
ob/ob, p < 0.01; Fig. 5B inset).
A similar result was obtained for heat production (wild type, 0.64 ± 0.04 Kcal/h; ob/ob, 0.48 ± 0.03 Kcal/h; 2KO,
0.62 ± 0.03 Kcal/h; +28.8% versus ob/ob,
p < 0.01;). These parameters both correlated
negatively with body weight (as shown for oxygen consumption, Fig.
5B). Oxygen consumption was also significantly correlated
with food efficiency (Fig. 5A) and HOMA index (not shown).
On the other hand, while the RQ (respiratory quotient) was
significantly increased in the ob/ob mice compared with the
wild type mice indicating an increase in the proportion of carbohydrate
versus fat oxidized, it was not further changed in the 2KO mice.
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DISCUSSION |
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These results extend our knowledge of the role of ASP in energy storage and energy expenditure. Firstly, ASP-deficient ob/ob mice demonstrate delayed postprandial triglyceride and NEFA clearance, as demonstrated previously in ASP deficient male mice (21, 22). Note that this is not only seen in the males (as described before), but in the 2KO mice this is also evident in females. In both cases, for ASP-deficient or 2KO mice, administration of ASP normalizes the postprandial profile.
In addition, HOMA was significantly reduced suggesting that the metabolic changes induced by ASP deficiency lead to increased insulin sensitivity. The very close association between the body weight and HOMA index suggests that it is the decreased weight that results in increased insulin sensitivity.
In the present study we demonstrate increases in food intake and basal metabolic rate in double knockout mice, without any changes in RQ (respiratory quotient). The 9% increase in food intake is more than offset by a 28% increase in energy consumption (oxygen consumption) resulting in an overall decrease in body weight of 17% as compared with the ob/ob mice.
The first result of interest to address is the increase in food intake.
Previously we demonstrated that in C3(/) mice, food intake
increased but the mice were leaner. This was coupled to a decrease in
adipose tissue mass and decreased circulating leptin levels. This led
us to speculate that the increased food intake was a consequence of
decreased levels of the satiety factor leptin. However, in the present
2KO mice, the 2KO have a greater food intake than the ob/ob
mice, a finding that cannot be explained by a decreased leptin, since
leptin is absent in both mice. This suggests that the increase in food
intake caused by ASP deficiency is not mediated through the leptin
pathway. Could ASP or C3a have a satiety effect that is lost in the
ASP-deficient and 2KO mice strains? The effects of both ASP (C3adesArg)
and C3a have been tested both centrally and peripherally. While there
were acute effects on food intake, two studies demonstrated an increase
(39, 40) and the other a decrease (41). Neither effect was pronounced and disappeared quite rapidly. Likely the effect of ASP deficiency on
food intake is not a direct one.
The second intriguing finding was the increase in basal metabolic rate (BMR) that was quite pronounced in the 2KO mice. The increase in BMR cannot simply be a consequence of hyperphagia, since the ob/ob also overeat, but their BMR is substantially lower than normal. Similarly, the change in BMR cannot simply be due to a lack of leptin, since both mutant mice are lacking leptin. Thus the change in BMR must relate (directly or indirectly) to a lack of ASP (as discussed below).
ob/ob have an increased RQ relative to wild type, with an increased shift toward carbohydrate oxidation, probably derived from the high carbohydrate content in the chow diet (46). It is known that leptin acts not only as a satiety factor but also up-regulates energy utilization (42-46), and preferentially increases oxidation of fat in a dose dependent manner (47). In the absence of leptin, energy metabolism shifts toward carbohydrate oxidation. On the other hand, while ASP deficiency induced increases in food intake and BMR, there was no change in RQ compared with ob/ob. Thus the increased oxidation in 2KO mice is an increase in both carbohydrate and fat oxidation. This increase in carbohydrate oxidation and glycolysis may help to explain the increase in insulin sensitivity.
What is the mechanism for the increased BMR without a change in RQ in the 2KO? Contributions to BMR can be quantified in terms of oxygen consumption, ATP turnover or uncoupling. About 90% of mammalian oxygen consumption is used by the mitochondria; of this about 20% is uncoupled by the mitochondrial proton leak (through UCP), whereas the other 80% is coupled to ATP synthesis (48). Through proton leaks in the mitochondria, energy is expended without the generation of ATP resulting in heat production. Over the last decade, there has been considerable interest in the role of UCP1, UCP2, and UCP3 in mediating this thermogenesis (49). Increased expression of UCP is associated with increased energy expenditure. Certainly one mechanism by which leptin increases energy expenditure is through stimulation of UCP1 in brown adipose tissue (50).
However an equally important mechanism of energy expenditure which generates heat through the utilization of ATP is termed substrate cycling. A substrate cycle exists when opposing, non-equilibrium reactions catalyzed by different enzymes are operating simultaneously (for review see (51, 52)). At least one of the reactions must involve the hydrolysis of ATP. Thus, a substrate cycle both liberates heat and increases energy expenditure; yet there is no net conversion of substrate to product. One example of a substrate cycle is the simultaneous breakdown (lipolysis) and re-synthesis (re-esterification) of triglyceride (triglyceride-fatty acid cycling). Other substrate cycles in the pathways of glycolysis and gluconeogenesis also exist (such as the glucose/glucose-6-phosphate cycle, the fructose-1-phosphate/fructose-1,6-diphosphate cycle, and the phosphoenolpyruvate/pyruvate/oxaloacetate). Substrate cycles have been proposed to be important not only in thermogenesis but also in maintaining the sensitivity and flexibility of metabolic regulation (48). Substrate cycling occurs primarily in the liver, muscle and adipose tissue (48). While 20% of total mitochondrial energy is expended via proton leaks (as mentioned above), it has been estimated that a further 20% is expended in substrate cycling (48). Newsholme (53) estimated that if the fructose-1-phosphate/fructose-1,6-diphosphate cycle was fully active, it could account for ~50% of an adult human's daily energy expenditure.
Of particular interest to the present discussion is the triglyceride-fatty acid cycle, which is highly active in adipose tissue. In humans the activity of this cycle ranges enormously from 0 to 100% re-esterification of released fatty acids (54) and is regulated through environmental (diet, exercise) (55), anatomic (gender and adipose tissue site) (56), and hormonal influences (57). A number of hormones, such as norepinephrine and insulin have been shown to modulate the triglyceride/fatty acid cycle in adipose tissue, as well as other substrate cycles in additional tissues (56, 57).
In a recent paper, Reidy and Weber (5) proposed that accelerated triglyceride/fatty acid substrate cycling in adipose tissue provides a new mechanism by which leptin triggers increased metabolic rate. Leptin is thought to increase energy expenditure primarily by driving the hypothalamic-pituitary-thyroid axis to produce more triiodothyronine (T3), a key regulator of standard metabolic rate. T3 in turn increases the expression of uncoupling proteins to reduce the efficiency of ATP production and increase heat. However leptin was also shown to directly activate the triglyceride/fatty acid cycle, lipolysis and fatty acid oxidation, shifting fuel preference from carbohydrate to fat oxidation. Thus, in ob/ob mice, the loss of leptin stimulation of UCP1 and triglyceride/fatty acid cycling will simultaneously contribute to the decrease in energy expenditure and the increase in fat storage.
Does ASP influence uncoupling proteins and substrate cycling? Since ASP
is known to increase triglyceride synthesis and re-esterification (9,
11) and decrease intracellular triglyceride lipolysis (9), then the
effect of ASP, at least in adipose tissue, is to effectively decrease
substrate cycling and increase triglyceride trapping. It is possible
that ASP deficiency could release the brake on this cycling process,
allowing for increased substrate cycling and augmenting energy
expenditure. These hypotheses remain to be addressed experimentally.
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FOOTNOTES |
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* This work was supported by a grant from Natural Sciences and Engineering Research Council of Canada (NSERC) (to K. C.) and by ServierPharmaceuticals (to A. D. S.).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.
Supported by a scholarship from the Fonds de la Recherche en
Santé du Québec (FRSQ). To whom correspondence
should be addressed: Cardiology, H7.30, Royal Victoria Hospital, 687 Pine Ave. W., Montreal, Quebec H3A 1A1, Canada. Tel.: 514-842-1231 (ext. 35426); Fax: 514-843-2843; E-mail:
katherine.cianflone@mcgill.ca.
Published, JBC Papers in Press, September 19, 2002, DOI 10.1074/jbc.M207281200
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ABBREVIATIONS |
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The abbreviations used are: ASP, acylation-stimulating protein; HOMA, homeostasis model assessment; BMR, basal metabolic rate; RQ, respiratory quotient; NEFA, postprandial non-esterified fatty acid; 2KO, double knockout mice; ANOVA, analysis of variance.
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REFERENCES |
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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