| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
3-adrenergic agonist CL-316243
in obese Zucker-ZDF rats
Department of Physiology, Faculty of Medicine, Laval University, Québec City, Canada G1K 7P4
 |
ABSTRACT |
|---|
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
|---|
Previous
studies have demonstrated that chronic cold exposure activates the
sympathetic nervous system, increases energy expenditure, improves
glucose tolerance, enhances insulin sensitivity, and stimulates glucose
uptake in peripheral tissues [brown and white adipose tissues
(BAT and WAT) and muscles] of normal rats. The goal of the
present studies was to test whether the selective 
3-adrenergic agonist CL-316243
(CL) would mimic the beneficial effects of cold exposure
in lean and obese ZDF/Gmi-fa male
(ZDF) rats, a new model of type II diabetes. In obese ZDF rats, chronic infusion of CL (1 mg · kg
1 · day1
for 14 days) significantly decreased body weight gain, food intake, and
WAT weight. It also increased total tissue cytochrome oxidase activity,
not only in BAT (15 times), but also in WAT (2-4 times), suggesting that it progressively enhanced mitochondriogenesis in
adipose tissues. CL treatment normalized hyperglycemia and reduced
hyperinsulinemia and circulating free fatty acid (FFA) levels. It also
improved glucose tolerance and reduced insulin response during an
intravenous glucose tolerance test. In general, the beneficial effects
of CL were more pronounced in obese than in lean rats.
Hyperinsulinemic-euglycemic glucose clamps combined with the
[2-3H]deoxyglucose
method revealed that CL markedly improved insulin responsiveness in
obese rats (3-4 times) and increased glucose uptake in BAT (21 times), WAT (3 times), skeletal muscles (2-3 times), and in the
diaphragm (2.8 times), but not in the heart. It is concluded that
chronic CL treatment improves glucose tolerance and insulin
responsiveness in obese ZDF rats by a mechanism similar to that induced
by chronic cold exposure, i.e., by stimulating facultative
thermogenesis, mitochondriogenesis, and glucose utilization in BAT and
WAT. In addition to this mechanism, the reduction in plasma FFA levels
induced by chronic CL treatment may further contribute to enhance
glucose uptake in skeletal muscles (a tissue that does not express
typical 3-adrenoceptors) via
the "glucose-fatty acid" cycle. The antiobesity and antidiabetic
properties of CL suggest that selective
3-adrenergic agonists may
represent useful agents for the treatment of type II diabetes.
obesity; diabetes; brown adipose tissue; skeletal muscles; insulin
| |
INTRODUCTION |
|---|
|
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
|---|
CHRONIC COLD EXPOSURE activates the sympathetic nervous
system, increases energy expenditure, improves glucose tolerance, enhances insulin sensitivity, and stimulates glucose uptake in rat
peripheral tissues [brown adipose tissue (BAT), white adipose tissue (WAT), the heart, diaphragm, and skeletal muscles] (44, 52, 54, 55). Cold exposure exerts these antidiabetic effects despite
the fact that it decreases plasma insulin levels and increases plasma
norepinephrine concentration. The beneficial effects of cold exposure
may be partly mimicked by chronic norepinephrine treatment in vivo (33)
or by electrical stimulation of the ventromedial hypothalamus (51). In
vitro studies have revealed that norepinephrine stimulates glucose
uptake in isolated brown adipocytes (even in the absence of
extracellular insulin) and potentiates the glucose-stimulatory effects
of insulin (35). The stimulatory effects of norepinephrine can be
blocked by the nonspecific -agonist propranolol or by inhibiting
mitochondrial fatty acid oxidation with methylpalmixorate, a specific
inhibitor of mitochondrial carnitine acyltransferase (35). This
suggests that norepinephrine stimulates glucose uptake in BAT because
it stimulates mitochondrial fatty acid oxidation and the glycolytic
flux. Glycolysis presumably provides the necessary ATP for activating
fatty acids when oxidative phosphorylation is uncoupled by fatty acids
bound to the mitochondrial uncoupling protein (for reviews, see Refs.
24, 25).
On the other hand, pharmacological studies revealed that BAT and WAT
contain at least three types of -adrenoceptors (ARs) (for a review,
see Ref. 30). Binding studies using hydrophilic radioligands performed
on intact brown adipocytes showed that the low-affinity
3-ARs are 10 times more
abundant than the high-affinity 1-ARs, whereas
2-ARs appear to be mainly
localized in cells other than typical brown adipocytes, possibly in
endothelial cells forming the numerous capillaries irrigating BAT (10).
Other metabolic studies indicated that norepinephrine, at
concentrations usually found in the circulation (1-25 nM),
controls both lipolysis and respiration mainly via
1-ARs, whereas at much higher
levels, presumably occurring in the synaptic cleft after sympathetic
stimulation (by cold exposure, diet, stress, etc.), norepinephrine
regulates these metabolic processes via both
1- and
3-adrenergic pathways (3).
Until recently, it was generally considered that
3-ARs were absent in the heart
(containing mainly 1-ARs) and
in skeletal muscles (containing mainly
2-ARs), but it appears that the
heart may contain functional
3-ARs (15) and/or
"atypical" (4)-ARs (27). Although the role of these receptors still remains to be defined
in different species, the presence of a variety of -ARs in different
tissues opens up the possibility of developing new drugs that
specifically activate thermogenesis in adipose tissues and consequently
increase glucose utilization, without stimulating the heart or muscles
(2, 7).
On this basis, we tested whether the selective
3-agonist CL-316243
[disodium(R,R)-5-[2[[2-(3-chlorophenyl)-2-hydroxyethyl]-amino]propyl]-1,3-benzodioxole-2,2-dicarboxylate] (CL) would mimic the beneficial effects of cold exposure (that were
mainly studied in normal rats) in lean and obese
ZDF/Gmi-fa male (ZDF) rats. The obese
ZDF rat is a recently developed model of obesity and type II diabetes
that is characterized by elevated plasma levels of insulin, glucose,
triglyceride, and cholesterol (41). In this new model, hyperglycemia
can be detected at ~7 wk of age, and obese animals are clearly
diabetic (blood glucose of ~25 mM) by 10 wk of age. Initially, the
diabetic animals are markedly hyperinsulinemic, but hyperinsulinemia
progressively decreases with age. Downregulation of glucose
transporters in the pancreas (GLUT-2) and in muscles (GLUT-4) may
contribute to the development of diabetic hyperglycemia (14, 47).
Because of these characteristics and the consistency in the development of diabetes, the obese ZDF represents an ideal model for investigating the effects of antidiabetic drugs on type II diabetes (49).
In preliminary experiments, we observed that CL did not reduce hyperglycemia in diabetic ZDF rats when given under acute conditions (single intravenous injections or subcutaneous infusions for a few days). Therefore, we tested the long-term effects of CL that was chronically infused via an osmotic minipump during 2 wk. It was found that chronic CL treatment progressively normalizes glycemia, reduces insulinemia, and decreases the levels of circulating free fatty acids (FFA) in obese diabetic ZDF rats. This treatment also markedly improved their glucose and insulin responses during an intravenous glucose tolerance test (IVGTT). Hyperinsulinemic-euglycemic clamps combined with the [2-3H]deoxyglucose ([2-3H]DG) method revealed that chronic CL treatment markedly increases insulin responsiveness in obese rats and that it increases glucose uptake in BAT, WAT, the diaphragm, and skeletal muscles, but not in the heart.
| |
MATERIALS AND METHODS |
|---|
|
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
|---|
Animals and treatments. ZDF and their lean littermates were obtained from Genetic Models at the age of 7 wk and were housed in individual cages at 23°C with a 12:12-h light-dark cycle. The rats received Purina chow and water ad libitum and were used 3-5 wk after their arrival.
CL
administration. CL was obtained from
Lederle Laboratories, American Cyanamid, Pearl River, NY (7). The drug
was dissolved under sterile conditions in distilled water containing
sodium metabisulfite (0.2 mM) and was administered for 14 days at a
dose of 1 mg · kg1 · day1
via osmotic minipumps (Alza, Palo Alto, CA; model 2002) that were
implanted in the back of the animals under isoflurane (Anaquest, Mississauga, ON, Canada) anesthesia. Control animals received the
carrier solution (33).
IVGTTs. One week before the IVGTTs and
the hyperinsulinemic-euglycemic clamps (see below), two polyethylene
cannulas filled with sterile heparinized saline (30 U/ml) were inserted
under anesthesia with a mixture of ketamine and xylazine (60 mg and 7.5 mg/kg) into the right external jugular vein and the common carotid
artery (PE-50 and PE-10, respectively; Becton Dickinson, Parsippany,
NJ), as previously described (33). Both tubes were exteriorized through
a neck incision, checked for patency, and sealed. Glucose tolerance
tests were performed 13 days after the beginning of the treatment with
CL in conscious and semifasted rats (3-4 h). Glucose (0.5 g/kg)
was injected into the jugular vein, arterial blood was sampled (0.18 ml) at various time points, and the samples were immediately replaced
with an equivalent volume of heparinized saline. Blood samples were
transferred into chilled heparinized tubes, centrifuged at 4°C, and
the plasma was kept frozen (
80°C) for later insulin and
glucose determinations. Total and incremental glucose and insulin areas
were calculated as previously described (53).
Glucose uptake in peripheral tissues. Glucose uptake was estimated by determining the glucose metabolic index (R'g) of individual tissues using the [2-3H]DG method (28, 29), as previously described (33).
Determination of plasma levels of glucose, FFA, and insulin. Plasma glucose levels were measured with a glucose analyzer (Beckman, Brea, CA). Insulin levels were determined by RIA (Incstar, Stillwater, MN). FFA levels were determined using a nonesterified fatty acid kit (Wako Chemicals, Dallas, TX).
Hyperinsulinemic-euglycemic clamps.
The clamps were performed in unanesthetized, undisturbed, unrestrained
rats. About 0.5 h before the experiment, polyethylene extension tubes
were connected to the indwelling catheters of the jugular vein (PE-50)
and carotid artery (PE-10). A four-way stopcock was used to infuse
glucose, insulin, and radiolabeled tracers into the jugular vein,
whereas the carotid artery was used for blood withdrawal. A first blood sample was taken and analyzed on the glucose analyzer. Then, insulin (100 mU · kg1 · min1)
and glucose (2.78 M) were infused in parallel. The rate of glucose infusion was adjusted to maintain euglycemia (5.3-6.6 mM), and blood glucose concentration was tested at 5-min intervals. Sixty minutes after the initiation of the hyperinsulinemic-euglycemic clamp,
[2-3H]DG and
[14C]sucrose were
intravenously injected for measurements of the rates of glucose uptake
in peripheral tissues, as described above.
Statistics. The data were statistically analyzed using either the unpaired t-test or one-way ANOVA followed by the Fisher's protected least-significant difference post hoc test. Results are expressed as means ± SE.
| |
RESULTS |
|---|
|
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
|---|
Effects of CL on body weights, food
intake, and tissue
weights. Total body weights, daily food intake values,
and the weights of several adipose depots were markedly increased in
the obese rats (Table 1). However, the
individual weights of all six skeletal muscles studied were decreased,
whereas the weights of the diaphragm, the heart, and the liver were not
significantly different. CL treatment (1 mg · kg1 · day1
for 14 days) significantly decreased body weight gain much more in
obese than in lean rats. It also decreased the mean value of daily food
intake in the obese, but not in the lean rats. However, this decrease
mainly occurred during the first 2-3 days of the 2-wk treatment
period (daily food intake values were not statistically significant
between treated and untreated obese rats from
day 3 to day
14, not shown). In obese rats, CL
increased interscapular BAT weight, but decreased the weights of
epididymal and retroperitoneal WAT depots as well as that of the liver.
It also slightly increased the mass of several muscles and that of the
heart. In lean rats, CL did not significantly affect food intake and
body weight gain, but it decreased epididymal and retroperitoneal WAT
weight, slightly decreased the weight of the gastrocnemius muscle, and
did not affect the weights of other organs.
|
Effects of CL on the total protein content and cytochrome oxidase activity in BAT and WAT. In previous studies, we found that total cytochrome oxidase activity (an index of total tissue mitochondrial content) was markedly decreased in interscapular BAT of obese SHR/N-cp rats, another model of type II diabetes that results from the cp mutation (4, 37). Morphometric-stereologic analysis of brown adipocytes in lean and obese SHR/N-cp rats revealed that the total number of mitochondria per brown adipocyte decreased from >4,000 mitochondria per adipocyte in lean rats to ~250 in obese animals (21), resulting in a marked decrease of norepinephrine-stimulated respiration (4, 37). To assess whether BAT oxidative capacity was also reduced in obese ZDF rats, total protein content and cytochrome oxidase activity were measured in several adipose depots. In agreement with our previous observations, it was found that cytochrome oxidase activity was markedly reduced in interscapular BAT of obese ZDF rats (Table 2). Significantly, CL treatment increased cytochrome oxidase activity 5.4 times in interscapular BAT of obese rats, whereas it increased the same parameter by only 2.1 times in lean animals. It also increased total tissue protein content in obese rats. Furthermore, this treatment increased total protein content and cytochrome oxidase activity in the epididymal (2.0 and 4.5 times) and retroperitoneal (2.4 and 2.4 times) WAT depots of obese rats, whereas in lean animals, it only increased cytochrome oxidase activity in retroperitoneal WAT (1.8 times). Thus the defective BAT mitochondrial oxidative capacity in obese diabetic rats is normalized after CL treatment, whereas WAT oxidative capacity appears to be even enhanced compared with controls (Table 2). Recent observations revealed that CL treatment also increases uncoupling protein content or its expression in BAT and WAT of obese ZDF rats (F. D'Allaire and L. J. Bukowiecki, unpublished observations), obese Zucker rats (19), yellow KK obese mice (38), ob/ob mice (1), and diet-induced obese rats (18).
|
Effect of CL on plasma glucose, insulin, and FFA levels. Untreated obese ZDF rats were markedly diabetic (their plasma glucose levels were nearly 5 times more than those of lean controls). They were also significantly hyperinsulinemic, and their plasma FFA levels were approximately six times greater than those of lean rats (Fig. 1). Two weeks of treatment with CL normalized plasma glucose levels of obese animals to essentially normoglycemic concentrations (6.4 mM). CL also significantly decreased plasma insulin and FFA levels, although not entirely to control values. In contrast, CL treatment slightly decreased the levels of glucose and FFA in lean rats, without significantly affecting plasma insulin levels.
|
Effects of CL on the glucose and insulin responses to
an IVGTT in lean and obese ZDF rats. CL treatment
markedly decreased the glucose response in obese ZDF rats during an
IVGTT (Fig. 2). This effect was evident at
all time points after the intravenous injection of glucose, as well as
when the data were expressed as total surfaces under the glucose curve
(Fig. 2, inset). In lean rats, the
3-agonist slightly decreased
plasma glucose levels at several, but not all, time points after
glucose administration, resulting in a small, statistically
nonsignificant, decrease in the total glucose area. Similarly, CL
decreased the insulin response, mainly in obese animals (Fig.
3). Thus both the glucose and insulin responses were significantly decreased in treated obese ZDF rats, providing a first indication that CL increases insulin responsiveness in these animals.
|
|
Effects of CL on the
R'g of obese ZDF rats under
hyperinsulinemic-euglycemic clamp conditions. To
further assess whether CL increases insulin responsiveness
(Vmax)
in peripheral tissues of obese rats, hyperinsulinemic-euglycemic clamps
were performed and the R'g was
measured using the
[2-3H]DG method (28,
29). A new set of obese rats was infused either with the
3-agonist or with vehicle for a
slightly shorter period of time (12 days), but using the same dose and
infusion rate as in the preceding experiment (1 mg · kg1 · day1).
The untreated obese rats were so resistant to insulin that they had to
be infused with relatively high insulin doses to decrease their plasma
glucose concentrations to normoglycemic levels (5.5-6 nM),
resulting in plasma insulin levels close to the insulin
Vmax for net
glucose utilization (28) (Fig. 4). Thus,
when steady-state conditions were reached, the glucose and insulin
concentrations were similar in both groups. However, the amount of
glucose that had to be infused to maintain euglycemia was nearly four
times higher in CL-treated rats than in untreated animals, indicating that CL-treatment significantly enhanced insulin responsiveness. Under
these conditions, the
[2-3H]DG tests
revealed that CL markedly increased the
R'g in interscapular BAT
(~20-fold), various adipose depots (1- to 3-fold), several muscles
(1- to 2-fold), but not in the heart (Figs.
5 and 6).
|
|
|
| |
DISCUSSION |
|---|
|
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
|---|
The main goal of the present studies was to determine whether treatment
of diabetic rats with CL exerts a beneficial effect in a new rat model
of type II diabetes to investigate, in a second step, the mechanisms of
action of this selective
3-agonist. In the first series
of experiments, we found that CL, when given for 2 wk to ZDF diabetic
rats, normalizes their plasma glucose levels and significantly
decreases their plasma insulin and FFA concentrations (Fig. 1). These
observations agree with previous findings, showing that
3-agonists display antidiabetic
effects in various animal models of type II diabetes (1, 48). In the
present experiments, CL treatment improved not only basal glycemia, but
also glucose tolerance (Fig. 2). During the entire IVGTT, both plasma
glucose and insulin concentrations of treated rats remained decreased
in comparison with untreated animals, providing a first indication that
CL improves insulin responsiveness in peripheral tissues.
This conclusion was supported by the hyperinsulinemic-euglycemic clamp experiments (Figs. 4-6). They revealed that CL markedly increased insulin responsiveness: nearly four times more glucose had to be infused in CL-treated than in untreated obese animals to achieve euglycemia. It was very difficult in the clamp experiments to significantly reduce the elevated glycemia of untreated obese rats without increasing plasma insulin concentrations to levels close to the insulin Vmax for net glucose utilization (28). This situation is rather different from what happens with other rat models of obesity that generally develop milder forms of insulin resistance not associated with frank diabetes. Nevertheless, the fact that chronic CL treatment normalized plasma glucose levels in ~2 wk (Figs. 1-3) is remarkable in view of the marked insulin resistance of obese ZDF rats.
The maximal capacity of various tissues for glucose uptake in
CL-treated animals varied with the following order: BAT > heart > diaphragm > skeletal muscles > WAT. This sequence of potencies agrees with previous observations made with normal rats treated with
insulin (54) or norepinephrine (33) as well as with cold-exposed animals (55). It shows that BAT possesses a remarkable capacity for
glucose utilization, either for storing it in the form of triglycerides
or for oxidizing it for thermogenesis (in cold-exposed animals or in
warm-exposed animals treated with norepinephrine or -agonists) (5,
24, 33, 55). In vitro studies confirmed that both insulin and
norepinephrine stimulate glucose uptake and revealed that a very low
(nanomolar) norepinephrine concentration potentiates the glucose
stimulatory effects of insulin (35). This suggests that norepinephrine
facilitates glucose entry into brown adipocytes by stimulating
thermogenesis, fatty acid oxidation, and glycolysis. It is likely that
CL acts in a fashion similar to that of norepinephrine, with the
exception that this selective 3-agonist is not expected to
activate 1-adrenergic pathways. However, maximal thermogenesis can be achieved in isolated brown adipocytes by stimulating them either with
1- or
3agonists (3).
The mechanism by which CL improves insulin responsiveness and glucose
uptake by peripheral tissues appears to be similar to that occurring
during cold acclimation of warm-acclimated rats. Similar to long-term
CL treatment, chronic cold exposure (4-5°C) improves glucose
tolerance, increases insulin sensitivity, stimulates glucose uptake in
peripheral tissues (BAT, WAT, skeletal muscles, and heart), and
reverses the diabetogenic effects of high-fat feeding (44, 52-55).
It exerts these beneficial effects despite the fact that it decreases
plasma insulin concentration and increases norepinephrine levels.
Chronic cold exposure also stimulates mitochondrial proliferation and
mitochondrial uncoupling protein content (4-5°C) (16, 17, 22,
25). Furthermore, in CL-treated animals (Figs. 5 and 6), as in
cold-exposed rats (54, 55), glucose uptake is increased much more in
BAT (by 1-2 orders of magnitude) than in WAT or muscles. This
order of potency agrees with the fact that BAT capacity for
nonshivering thermogenesis is much higher than that of WAT or muscles.
Cold exposure stimulates the release of norepinephrine from sympathetic
nerves and consequently increases nonshivering thermogenesis in BAT and
WAT, not only via 3-, but also
via 1-adrenergic pathways
(2-ARs are undetectable in
brown adipocytes) (10, 24, 30, 31). Although the affinity of 1-ARs for norepinephrine is
much higher than that of 3-ARs, the latter are ~10 times more numerous and appear to be resistant to
catecholamine-induced desensitization or downregulation (9, 10, 23, 30,
39, 40). In muscles, norepinephrine may stimulate nonshivering
thermogenesis and glucose uptake via
2-ARs and/or atypical
(4)-ARs (12, 27, 34, 45, 54).
Thus it is likely that CL mimics the
3-effects of norepinephrine in BAT and WAT, but its stimulatory effects in muscles are probably indirect because this tissue lacks typical
3-ARs. Most probably, the
decrease in FFA levels induced by CL treatment (Fig. 1) enhances glucose uptake in muscles via the so-called Randle's effect or glucose-fatty acid cycle (42). However, this remains to be directly demonstrated.
A question that is often raised is how a potent lipolytic agent, such
as CL, decreases the levels of circulating fatty acids instead of
increasing them. We believe that this paradox is merely apparent
because, in addition to stimulating lipolysis,
3-agonists markedly stimulate
thermogenesis, particularly in BAT (3, 18, 19, 26, 46).
Fatty acids represent the principal substrates used for thermogenesis
by BAT (50), and activation of nonshivering thermogenesis by
norepinephrine or 3-agonists
stimulates fatty acid oxidation, decreases the circulating levels of
fatty acids, and diminishes triglyceride stores in adipose tissues.
Using an oxygen consumption system for continuously monitoring daily
oxygen consumption in rats (43), we recently found that CL does in fact
stimulate 24-h oxygen consumption in obese ZDF rats when infused during
14 days under the same experimental conditions as in the present
experiments (11). Remarkably, the enhancement of oxygen consumption
progressively increased from ~10% above basal values during the
first 4 days of the infusion to 35% during the last 4 days
(days
10-14).
This progressive increase was accompanied by a parallel increase in
total tissue cytochrome oxidase activity and uncoupling protein
content, not only in BAT, but also in several WAT depots, confirming
previous observations (26). We therefore hypothesize that CL exerts its
beneficial action by 1) acutely enhancing thermogenesis in BAT, WAT, and possibly also other tissues and 2) by restoring to normal the
defective BAT thermogenic capacity, as evidenced by its remarkable
effect on total tissue cytochrome oxidase activity (Table 2). The fact
that CL did not reduce hyperglycemia in diabetic ZDF rats at short term
(single injection or infusion for <1 wk) strongly suggests that the
3-agonist acts by progressively stimulating mitochondriogenesis in BAT and restoring to normal the
defective thermogenic capacity of obese rats (4, 36, 37). Another
explanation for the decreased FFA levels in obese rats chronically
treated with CL could be based on the increased insulin responsiveness
of adipose tissues. Insulin is a potent antilipolytic hormone, and the
increased insulin responsiveness induced by CL treatment may contribute
to decrease lipolysis and plasma FFA levels.
The observation that CL augmented glucose uptake ~10 times more in BAT than in WAT (per gram of tissue) (Fig. 5) agrees with the observations that BAT possesses a much higher capacity for heat production than WAT (Table 2, cytochrome oxidase data). Quantitatively, WAT may still represent a significant site of glucose and fat oxidation, because it is much more abundant than BAT, although it is difficult to precisely estimate the relative proportion of WAT versus BAT, particularly in obese rats. Nevertheless, the muscles remain the main anatomic site of glucose uptake in CL-treated rats under the clamp conditions described in Figs. 3-5. On the assumption that the muscles, WAT, and BAT, respectively, represent 30, 40, and 1% of the body weight of obese rats and by averaging the individual glucose uptake values for the different types of muscles and fat depots investigated, it can roughly be estimated that total BAT and WAT combined represent ~20% of glucose uptake in muscles (BAT 10% and WAT 10%).
In summary, it is concluded that chronic, but not short-term, CL
treatment normalizes glycemia and increases insulin responsiveness and
glucose uptake in adipose tissues and muscles, but not in the heart, of
obese ZDF rats. It is suggested that the
3-agonist progressively
increases the defective mitochondrial oxidative capacity in BAT and WAT
of diabetic animals, thereby increasing energy expenditure and fat
oxidation, and, consequently, reducing plasma FFA levels. This may lead
to an enhancement of glucose utilization by skeletal muscles via the
glucose fatty acid cycle. Although human
3-ARs appear to be different
from rat 3-ARs, selective
3-agonists such as CL-316243
may represent useful agents for the treatment of obesity and type II
diabetes (6, 32).
Perspectives
When we started to investigate the effects of cold exposure on glucose metabolism a few years ago, we had no idea that one day catecholamines or-adrenergic agonists would represent potential agents for normalizing plasma glucose levels in type II diabetes. At
that time, catecholamines, glucagon, and other lipolytic hormones were
considered counterregulatory hormones, because they inhibited, generally at high pharmacological doses, the beneficial effects of
insulin. It took several years to demonstrate that the main effector of
the stimulation of glucose uptake by peripheral tissues in cold-exposed
animals was norepinephrine secreted from sympathetic nerves. The idea
that physiological conditions (cold exposure, exercise) or drugs
(adrenergic agonists) activating mitochondrial ATP synthesis or heat
production also stimulate glucose utilization in muscles and adipose
tissues has opened and still opens new avenues for developing more
efficient and more selective antidiabetic drugs. In recent years,
adipose tissues (brown or white) have been the focus of much attention,
probably because they are unique in possessing both
3-ARs and the uncoupling
protein 1 (UCP 1). This particular combination allowed the development
of drugs that selectively stimulate thermogenesis and glucose uptake in
adipose tissues. However, the recent finding that the skeletal muscles express two new uncoupling proteins (UCP 2 and 3) (8, 13, 20, 56),
which are possibly linked to atypical
(4)-ARs (different from
1-,
2-, or
3-ARs), will provide additional
research opportunities for developing new drugs facilitating glucose
uptake directly in the skeletal muscles that represent the main
anatomic sites of glucose utilization in humans as well in laboratory
animals.
| |
ACKNOWLEDGEMENTS |
|---|
The authors thank Drs. A. Marette and C. Atgié for assistance in part of these studies.
| |
FOOTNOTES |
|---|
This study was supported by grants from the Canadian Diabetes Association and the Medical Research Council of Canada.
Address for reprint requests: L. J. Bukowiecki, Dept. of Physiology, Faculty of Medicine, Laval Univ., Québec City, Canada G1K 7P4.
Received 2 June 1997; accepted in final form 26 January 1998.
| |
REFERENCES |
|---|
|
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
|---|
1.
Arbeeny, C. M.,
D. S. Meyers,
D. E. Hillyer,
and
K. E. Bergquist.
Metabolic alterations associated with the antidiabetic effect of 3-adrenergic receptor agonists in obese mice.
Am. J. Physiol.
268 (Endocrinol. Metab. 31):
E678-E684,
1995
2.
Arch, J. R. S.,
A. T. Ainsworth,
M. A. Cawthorne,
V. Piercy,
M. V. Sennitt,
V. E. Thody,
C. Wilson,
and
S. Wilson.
Atypical -adrenoceptor on brown adipocytes as target for anti-obesity drugs.
Nature
309:
163-165,
1984[Medline].
3.
Atgié, C.,
F. D'Allaire,
and
L. J. Bukowiecki.
Role of 1- and 3-adrenoceptors in the regulation of lipolysis and thermogenesis in rat brown adipocytes.
Am. J. Physiol.
273 (Cell Physiol. 42):
C1136-C1142,
1997.
4.
Atgié, C.,
A. Marette,
M. Desautels,
O. Tulp,
and
L. J. Bukowiecki.
Specific decrease of mitochondrial thermogenic capacity in brown adipose tissue of obese SHR/N-cp rats.
Am. J. Physiol.
265 (Cell Physiol. 34):
C1674-C1680,
1993
5.
Atgié, C.,
G. Tavernier,
F. D'Allaire,
T. Bengtsson,
L. Marti,
C. Carpéné,
M. Lafontan,
L. J. Bukowiecki,
and
D. Langin.
3-Adrenoceptor in guinea pig brown and white adipocytes: low expression and lack of function.
Am. J. Physiol.
271 (Regulatory Integrative Comp. Physiol. 40):
R1729-R1738,
1996
6.
Atkinson, R. L., R. C. Blank, J. F. Loper, D. Schumacher, and R. A. Lutes. Combined drug
treatment of obesity. Obesity Res.
3, Suppl. 4:
497S-500S, 1995.
7.
Bloom, J. D.,
M. D. Dutia,
B. D. Johnson,
A. Wissner,
M. G. Burns,
E. E. Largis,
J. A. Dolan,
and
T. H. Claus.
Disodium (R,R)-5-[2-[[2-(3-chlorophenyl)-2-hydroxyethyl]-amino] propyl]-1,3-benzodioxole-2,2-dicarboxylate (CL 316,243). A potent beta-adrenergic agonist virtually specific for beta 3 receptors. A promising antidiabetic and antiobesity agent.
J. Med. Chem.
35:
3081-3084,
1992[Medline].
8.
Boss, O.,
S. Samec,
A. PaoloniGiacobino,
C. Rossier,
A. Dulloo,
J. Seydoux,
P. Muzzin,
and
J. Giacobino.
Uncoupling protein-3: a new member of the mitochondrial carrier family with tissue-specific expression.
FEBS Lett.
408:
39-42,
1997[Medline].
9.
Carpéné, C.,
J. Galitzky,
P. Collon,
F. Esclapez,
M. Dauzats,
and
M. Lafontan.
Desensitization of beta-1 and beta-2, but not beta-3, adrenoceptor-mediated lipolytic responses of adipocytes after long-term norepinephrine infusion.
J. Pharmacol. Exp. Ther.
265:
237-247,
1993
10.
D'Allaire, F.,
C. Atgié,
P. Mauriège,
P.-M. Simard,
and
L. J. Bukowiecki.
Characterization of 1- and 3-adrenoceptors in intact brown adipocytes of the rat.
Br. J. Pharmacol.
114:
275-282,
1995[Medline].
11.
D'Allaire, F., X. Liu, F. Pérusse, and L. J. Bukowiecki. Mechanisms of the beneficial effects of the
selective 3-agonist CL 316 243 on obesity, diabetes and energy
expenditure (Abstract). Obesity Res.
4, Suppl. 1: 16S, 1996.
12.
Dulloo, A. G.,
J. B. Young,
and
L. Landsberg.
Sympathetic nervous system responses to cold exposure and diet in rat skeletal muscle.
Am. J. Physiol.
255 (Endocrinol. Metab. 18):
E180-E188,
1988
13.
Fleury, C.,
M. Neverova,
S. Collins,
S. Raimbault,
O. Champigny,
C. Levi-Meyrueis,
F. Bouillaud,
M. Seldin,
R. Surwit,
D. Ricquier,
and
C. Warden.
Uncoupling protein-2: a novel gene linked to obesity and hyperinsulinemia.
Nat. Genet.
15:
269-272,
1997[Medline].
14.
Friedman, J. E.,
J. E. De Vente,
R. G. Peterson,
and
G. L. Dohm.
Altered expression of muscle glucose transporter GLUT-4 in diabetic fatty Zucker rats (ZDF/Drt-fa).
Am. J. Physiol.
261 (Endocrinol. Metab. 24):
E782-E788,
1991
15.
Gauthier, C.,
G. Tavernier,
F. Charpentier,
D. Langin,
and
H. Le Marec.
Functional beta3-adrenoceptor in the human heart.
J. Clin. Invest.
98:
556-562,
1996[Medline].
16.
Géloën, A.,
A. J. Collet,
G. Guay,
and
L. J. Bukowiecki.
In vivo differentiation of brown adipocytes in adult mice: an electron microscopic study.
Am. J. Anat.
188:
366-372,
1990[Medline].
17.
Géloën, A.,
A. J. Collet,
G. Guay,
and
L. J. Bukowiecki.
-Adrenergic stimulation of brown adipocyte proliferation.
Am. J. Physiol.
254 (Cell Physiol. 23):
C175-C182,
1988
18.
Ghorbani, M.,
T. Claus,
and
J. Himms-Hagen.
Hypertrophy of brown adipocytes in brown and white adipose tissues and reversal of diet-induced obesity in rats treated with a beta(3)-adrenoceptor agonist.
Biochem. Pharmacol.
54:
121-131,
1997[Medline].
19.
Ghorbani, M.,
and
J. Himms-Hagen.
Appearance of brown adipocytes in white adipose tissue during CL 316,243-induced reversal of obesity and diabetes in Zucker fa/fa rats.
Int. J. Obes.
21:
465-475,
1997[Medline].
20.
Gimeno, R.,
M. Dembski,
X. Weng,
N. Deng,
A. Shyjan,
C. Gimeno,
F. Iris,
S. Ellis,
E. Woolf,
and
L. Tartaglia.
Cloning and characterization of an uncoupling protein homolog: a potential molecular mediator of human thermogenesis.
Diabetes
46:
900-906,
1997[Abstract].
21.
Goglia, F., A. Géloën, C. Atgié, A. Marette,
and L. J. Bukowiecki. Morphometric-stereologic analysis
of brown adipocytes in lean and obese SHR/N-cp rats (Abstract).
Int. J. Obes. 7, Suppl. 2: 10, 1993.
22.
Goglia, F.,
A. Géloën,
A. Lanni,
Y. Minaire,
and
L. J. Bukowiecki.
Morphometric-stereologic analysis of brown adipocyte differentiation in adult mice.
Am. J. Physiol.
262 (Cell Physiol. 31):
C1018-C1023,
1992
23.
Granneman, J. G.
Effects of agonist exposure on the coupling of beta1 and beta3-adrenergic receptors to adenylyl cyclase in isolated adipocytes.
J. Pharmacol. Exp. Ther.
261:
638-642,
1992
24.
Himms-Hagen, J.
Brown adipose tissue thermogenesis: role in thermoregulation, energy regulation and obesity.
In: Thermoregulation: Physiology and Biochemistry, edited by E. Schönbaum,
and P. Lomax. New York: Pergamon, 1990, p. 327-341.
25.
Himms-Hagen, J.
Neural control of brown adipose tissue thermogenesis, hypertrophy, and atrophy.
In: Frontiers in Neuroendocrinology, edited by W. F. Ganong,
and L. Martini. New York: Raven, 1991, p. 38-91.
26.
Himms-Hagen, J.,
J. Cui,
E. Danforth, Jr.,
D. J. Taatjes,
S. S. Lang,
B. L. Waters,
and
T. H. Claus.
Effect of CL-316,243, a thermogenic 3 agonist, on energy balance and brown and white adipose tissues in rats.
Am. J. Physiol.
266 (Regulatory Integrative Comp. Physiol. 35):
R1371-R1382,
1994
27.
Kaumann, A. J.
Four -adrenoceptor subtypes in the mammalian heart.
Trends Pharmacol. Sci.
18:
70-76,
1997[Medline].
28.
Kraegen, E. W.,
D. E. James,
A. B. Jenkins,
and
D. J. Chisholm.
Dose-response curves for in vivo insulin sensitivity in individual tissues in rats.
Am. J. Physiol.
248 (Endocrinol. Metab. 11):
E353-E362,
1985
29.
Kraegen, E. W.,
D. E. James,
L. H. Storlien,
K. M. Burleigh,
and
D. J. Chisholm.
In vivo insulin resistance in individual peripheral tissues of the high fat fed rat: assessment by euglycaemic clamp plus deoxyglucose administration.
Diabetologia
29:
192-198,
1986[Medline].
30.
Lafontan, M.,
and
M. Berlan.
Fat cell adrenergic receptors and the control of white and brown fat cell function.
Rev. J. Lipid. Res.
34:
1057-1091,
1993.
31.
Landsberg, L.,
M. E. Saville,
and
J. B. Young.
Sympathoadrenal system and regulation of thermogenesis.
Am. J. Physiol.
247 (Endocrinol. Metab. 10):
E181-E189,
1984
32.
Lipworth, B. J.
Clinical pharmacology of 3-adrenoceptors.
Br. J. Clin. Pharmacol.
42:
291-300,
1996[Medline].
33.
Liu, X.,
F. Pérusse,
and
L. J. Bukowiecki.
Chronic norepinephrine infusion stimulates glucose uptake in white and brown adipose tissues.
Am. J. Physiol.
266 (Regulatory Integrative Comp. Physiol. 35):
R914-R920,
1994
34.
Liu, Y.-L.,
M. A. Cawthorne,
and
M. J. Stock.
Biphasic effects of the -adrenoceptor agonist, BRL 37344, on glucose utilization in rat isolated skeletal muscle.
Br. J. Pharmacol.
117:
1355-1361,
1996[Medline].
35.
Marette, A.,
and
L. J. Bukowiecki.
Noradrenaline stimulates glucose transport in rat brown adipocytes by activating thermogenesis.
Biochem. J.
277:
119-124,
1991.
36.
Marette, A.,
Y. Deshaies,
A. J. Collet,
O. Tulp,
and
L. J. Bukowiecki.
Major thermogenic defect associated with insulin resistance in brown adipose tissue of obese diabetic SHR/N-cp rats.
Am. J. Physiol.
261 (Endocrinol. Metab. 24):
E204-E213,
1991
37.
Marette, A.,
P. Mauriège,
J.-P. Després,
O. L. Tulp,
and
L. J. Bukowiecki.
Norepinephrine- and insulin-resistant glucose transport in brown adipocytes from diabetic SHR/N-cp rats.
Am. J. Physiol.
265 (Regulatory Integrative Comp. Physiol. 34):
R577-R583,
1993
38.
Nagase, I.,
T. Yoshida,
K. Kumamoto,
T. Umekawa,
N. Sakane,
H. Nikami,
T. Kawada,
and
M. Saito.
Expression of uncoupling protein in skeletal muscle and white fat of obese mice treated with thermogenic 3-adrenergic agonist.
J. Clin. Invest.
97:
2898-2904,
1996[Medline].
39.
Nantel, F.,
H. Bonin,
L. J. Emorine,
V. Zilberfarb,
A. D. Strosberg,
M. Bouvier,
and
S. Marullo.
The human beta3-adrenergic receptor is resistant to short term agonist-promoted desensitization.
Mol. Pharmacol.
43:
548-555,
1993[Abstract].
40.
Nantel, F.,
S. Marullo,
S. Krief,
A. D. Strosberg,
and
M. Bouvier.
Cell-specific down-regulation of the 3-adrenergic receptor.
J. Biol. Chem.
269:
13148-13155,
1994
41.
Peterson, R. G.,
W. N. Shaw,
M.-A. Neel,
L. A. Little,
and
J. Eichberg.
Zucker diabetic fatty rat as a model for non-insulin-dependent diabetes mellitus. (Abstract).
Institute of Laboratory Animal Resources News
32:
16-19,
1990.
42.
Randle, P. J.,
P. Garland,
C. N. Hales,
and
E. A. Newsholme.
The glucose fatty-acid cycle: its role in insulin sensitivity and the metabolic disturbances of diabetes mellitus.
Lancet
1:
785-789,
1963[Medline].
43.
Shibata, H.,
and
L. J. Bukowiecki.
Regulatory alterations of daily energy expenditure induced by fasting and overfeeding in unrestrained rats.
J. Appl. Physiol.
63:
465-470,
1987
44.
Shibata, H.,
F. Pérusse,
A. Vallerand,
and
L. J. Bukowiecki.
Cold exposure reverses inhibitory effects of fasting on peripheral glucose uptake in rats.
Am. J. Physiol.
257 (Regulatory Integrative Comp. Physiol. 26):
R96-R101,
1989
45.
Shiota, M.,
and
S. Masumi.
Effect of norepinephrine on consumption of oxygen in perfused skeletal muscle from cold-exposed rats.
Am. J. Physiol.
254 (Endocrinol. Metab. 17):
E482-E489,
1988
46.
Simard, P.-M.,
C. Atgié,
P. Mauriège,
F. D'Allaire,
and
L. J. Bukowiecki.
Comparison of the lipolytic effects of norepinephrine and BRL 37344 in rat brown and white adipocytes.
Obesity Res.
2:
424-431,
1994[Medline].
47.
Slieker, L. J.,
K. L. Sundell,
W. F. Heath,
H. E. Osborne,
J. Bue,
J. Manetta,
and
J. R. Sportsman.
Glucose transporter levels in tissues of spontaneously diabetic Zucker fa/fa rat (ZDF/drt) and viable yellow mouse (Avy/a).
Diabetes
41:
187-193,
1992[Abstract].
48.
Smith, S. A.,
M. V. Sennitt,
and
M. A. Cawthorne.
BRL 35135: an orally active anti-hyperglycemic agent with weight reducing effects.
In: New Anti-Diabetic Drugs, edited by C. J. Bailey,
and P. R. Flatt. London: Smith-Gordon, 1990, p. 177-189.
49.
Sreenan, S.,
J. Sturis,
W. Pugh,
C. F. Burant,
and
K. S. Polonsky.
Prevention of hyperglycemia in the Zucker diabetic fatty rat by treatment with metformin or troglitazone.
Am. J. Physiol.
271 (Endocrinol. Metab. 34):
E742-E747,
1996
50.
Susulic, V. S.,
R. C. Frederich,
J. Lawitts,
E. Tozzo,
B. B. Kahn,
M.-E. Harper,
J. Himms-Hagen,
J. S. Flier,
and
B. B. Lowell.
Targeted disruption of the 3-adrenergic receptor gene.
J. Biol. Chem.
270:
29483-29492,
1995
51.
Takahashi, A.,
M. Sudo,
Y. Minokoshi,
and
T. Shimazu.
Effects of ventromedial hypothalamic stimulation on glucose transport system in rat tissues.
Am. J. Physiol.
263 (Regulatory Integrative Comp. Physiol. 32):
R1228-R1234,
1992
52.
Vallerand, A. L.,
J. Lupien,
and
L. J. Bukowiecki.
Cold exposure reverses the diabetogenic effect of high-fat feeding.
Diabetes
35:
329-334,
1986[Abstract].
53.
Vallerand, A. L.,
J. Lupien,
and
L. J. Bukowiecki.
Interactions of cold exposure and starvation on glucose tolerance and insulin response.
Am. J. Physiol.
245 (Endocrinol. Metab. 8):
E575-E581,
1983
54.
Vallerand, A. L.,
F. Pérusse,
and
L. J. Bukowiecki.
Cold exposure potentiates the effect of insulin on in vivo glucose uptake.
Am. J. Physiol.
253 (Endocrinol. Metab. 16):
E179-E186,
1987
55.
Vallerand, A. L.,
F. Pérusse,
and
L. J. Bukowiecki.
Stimulatory effects of cold exposure and cold acclimation on glucose uptake in rat peripheral tissues.
Am. J. Physiol.
259 (Regulatory Integrative Comp. Physiol. 28):
R1043-R1049,
1990
56.
VidalPuig, A.,
G. Solanes,
D. Grujic,
J. Flier,
and
B. Lowell.
UCP3: an uncoupling protein homologue expressed preferentially and abundantly in skeletal muscle and brown adipose tissue.
Biochem. Biophys. Res. Commun.
235:
79-82,
1997[Medline].
This article has been cited by other articles:
|
|
 |
|
  A. A. da Silva, L. S. Tallam, J. Liu, and J. E. Hall Chronic antidiabetic and cardiovascular actions of leptin: role of CNS and increased adrenergic activity Am J Physiol Regulatory Integrative Comp Physiol, November 1, 2006; 291(5): R1275 - R1282. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 R. L. G. S. Oliveira, M. Ueno, C. T. de Souza, M. Pereira-da-Silva, A. L. Gasparetti, R. M. N. Bezzera, L. C. Alberici, A. E. Vercesi, M. J. A. Saad, and L. A. Velloso Cold-induced PGC-1{alpha} expression modulates muscle glucose uptake through an insulin receptor/Akt-independent, AMPK-dependent pathway Am J Physiol Endocrinol Metab, October 1, 2004; 287(4): E686 - E695. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
M. C. Moore, S. Cardin, D. S. Edgerton, B. Farmer, D. W. Neal, M. Lautz, and A. D. Cherrington Unlike mice, dogs exhibit effective glucoregulation during low-dose portal and peripheral glucose infusion Am J Physiol Endocrinol Metab, February 1, 2004; 286(2): E226 - E233. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 B. CANNON and J. NEDERGAARD Brown Adipose Tissue: Function and Physiological Significance Physiol Rev, January 1, 2004; 84(1): 277 - 359. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
| Visit Other APS Journals Online |
