Vol. 284, Issue 3, R639-R651, March 2003
INVITED REVIEW
Cardiovascular effects of leptin and orexins
Tetsuro
Shirasaka1,
Mayumi
Takasaki1, and
Hiroshi
Kannan2
Departments of 1 Anesthesiology and
2 Physiology, Miyazaki Medical College, 5200 Kihara,
Kiyotake, Miyazaki 889-1692, Japan
 |
ABSTRACT |
Leptin, the product of the ob
gene, is a satiety factor secreted mainly in adipose tissue and is part
of a signaling mechanism regulating the content of body fat. It acts on
leptin receptors, most of which are located in the hypothalamus, a
region of the brain known to control body homeostasis. The fastest and
strongest hypothalamic response to leptin in ob/ob mice
occurs in the paraventricular nucleus, which is involved in
neuroendocrine and autonomic functions. On the other hand, orexins
(orexin-A and -B) or hypocretins (hypocretin-1 and -2) were recently
discovered in the hypothalamus, in which a number of neuropeptides are
known to stimulate or suppress food intake. These substances are
considered important for the regulation of appetite and energy
homeostasis. Orexins were initially thought to function in the
hypothalamic regulation of feeding behavior, but orexin-containing
fibers and their receptors are also distributed in parts of the brain
closely associated with the regulation of cardiovascular and autonomic
functions. Functional studies have shown that these peptides are
involved in cardiovascular and sympathetic regulation. The objective of
this article is to summarize evidence on the effects of leptin and
orexins on cardiovascular function in vivo and in vitro and to discuss
the pathophysiological relevance of these peptides and possible interactions.
mean arterial pressure; heart rate; sympathetic nerve activity; catecholamine; hypothalamic paraventricular nucleus; depolarization; sympathoexcitation
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INTRODUCTION |
HYPERPHAGIA (OVEREATING) is often
associated with energy overstorage and obesity, which may lead to a
myriad of serious health problems, including heart disease,
hypertension, and type 2 diabetes. Thus understanding the complex
pathological mechanisms underling hyperphagia and obesity has important
clinical significance. The concept of the hypothalamus playing a role
in the regulation of feeding behavior and energy homeostasis was
originally based on observations of brain lesions (69).
Lesions of the ventromedial hypothalamus (VMH) produce
hyperphagic obesity, whereas lesions of the lateral hypothalamus (LH)
induce hypophagia and weight loss, suggesting that satiety and
feeding centers existed in the VMH and LH, respectively
(7). Recent advances have led to a greater understanding
of the signaling pathways that regulate these centers, particularly
those involving the satiety center in the VMH (7), which
is dominated by the hormone leptin (11, 103). Leptin, the
protein product of the ob/ob gene, is a 167-amino acid
protein produced and secreted by adipocytes in direct proportion to
adiposity in rats and humans (11, 32, 103). Leptin
suppresses food intake by inhibiting neuropeptide Y (NPY) secretion
from the arcuate nucleus (18, 67, 70, 88), by acting on
the VMH through increasing the production of the melanocyte-stimulating hormone (MSH), or by decreasing the agouti-related peptide (AGRP), an
antagonist of MSH at the MC4 receptor (25, 26). In
addition, leptin receptor mutations and modifications in the
ob/ob gene, which result in a lack of leptin production,
also result in obesity, hyperinsulinemia, and hypercorticosteronemia
(72). In contrast, two novel hypothalamic peptides that
stimulate food consumption when administered centrally were discovered
in an intracellular calcium influx assay on multiple cells expressing
individual orphan G protein-coupled receptors (76). Two
research groups reported this finding almost simultaneously (21,
76). These peptides are known as orexins (orexin-A and -B)
(76) or hypocretins (hypocretin-1 and -2)
(21). Orexin-A (hypocretin-1) consists of 33 amino acids and has an NH2 terminal pyroglutamyl residue and COOH
terminal amide group (76). Orexin-B (hypocretin-2)
consists of 28 amino acids and is 46% identical to orexin-A
(76). Intracerebroventricular administration of orexin-A
and -B stimulates food intake in a dose-dependent manner
(76). In addition to the appetite-promoting activity of
orexins, their mRNA levels were upregulated more than twofold after a
48-h fasting period (76). The mRNA is expressed abundantly
and specifically in the lateral hypothalamus (LHA) and adjacent areas
(76), a region implicated in the central regulation of
feeding behavior and energy homeostasis (7). Orexin-A and
-B neurons are restricted to the lateral and posterior hypothalamus,
whereas both orexin-A and -B nerve fibers projected widely into the
olfactory bulb, cerebral cortex, thalamus, hypothalamus, and brain stem
(20, 71). In contrast, expression of orexin receptor mRNA
(OX1R and OX2R) is widely distributed in the
rat brain (96). The expression patterns for
OX1R and OX2R are distinct. Within the
hypothalamus, OX1R mRNA is most abundant in the
ventromedial hypothalamic nucleus (VMH) (76, 96) and
moderate levels are detected in the medial preoptic area,
lateroanterior and dorsomedial hypothalamic nuclei (DMH), lateral
mamillary nucleus, and posterior hypothalamic area. In contrast,
OX2R mRNA is expressed predominantly in the hypothalamic
paraventricular nucleus (PVN) and moderate levels are detected in the
VMH and DMH and the posterior and lateral hypothalamic areas
(96). The difference in expression patterns for
OX1R and OX2R mRNA in the VMH and PVN is
significant. Although it appears that both nuclei play key roles in the
neuronal circuitry of feeding regulation, the hypothalamus is the main
integrative center for a number of other neuroendocrine and autonomic
nervous functions in addition to feeding behavior (7, 91).
For example, the PVN of the hypothalamus, which is enriched with a vast
number of neuroendocrine modulators (19, 36), has been
implicated in the stress response, control of pituitary function, body
fluid homeostasis, analgesia, and cardiovascular and gastrointestinal functions (4, 90, 91). Hypothalamic PVN is a heterogeneous structure comprised of neuronal populations that are grouped generally into magnocellular (type 1) and parvocellular (type 2) neurons (91, 94). Both magnocellular and parvocellular neurons can be further subdivided on the basis of peptide expression, projection targets, and/or location in the nucleus (91).
Magnocellular neurons can be oxytocinergic neurons or vasopressinergic
neurons, whereas parvocellular neurons can be either neuroendocrine or preautonomic neurons (89, 91). The preautonomic
parvocellular neurons project to rostral ventrolateral medulla (RVLM)
and to the intermediolateral cell column (IML) of the spinal cord,
which are involved in the regulation of heart rate (HR) and arterial pressure (AP) (4, 80, 91). Electrical and chemical
stimulation of the PVN increases AP and renal sympathetic nerve
activity (RSNA) in conscious rats (47). Conversely, VMH is
involved in the homeostatic regulation of body metabolism mediated via
sympathetic nerves (84). Several peptides, which affect
food intake, have an effect on cardiovascular response and sympathetic
nerve activity (9, 22, 83). This review describes results
that provide anatomical and physiological evidence for the
cardiovascular and sympathetic effects of leptin and orexins and
discusses the significance of each peptide and their possible interaction.
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LEPTIN AND CARDIOVASCULAR FUNCTION |
Leptin binding sites have been found in brain regions that are
important in cardiovascular control (93). Leptin receptor mRNA is also found extensively in the central nervous system (CNS) (40, 79, 93), and leptin has been shown to activate
neurons in many nuclei of the hypothalamus, including the PVN and VMH (23, 24, 102). The intracerebroventricular or intravenous administration of leptin produces marked changes in AP (17, 81), HR, sympathetic nerve activity (SNA) (34, 35,
60), and renal excretory function (45, 75) in rats
and rabbits.
Integrative Action of Leptin
Effects induced by intracerebroventricular administration.
The effects of leptin on cardiovascular function have been studied in
animals by determining changes in HR and AP induced by
intracerebroventricular and intravenous administration of leptin. The
administration of leptin intracerebroventricularly activates specific
nuclear groups in the hypothalamus and brain stem known to regulate
cardiovascular responses (24, 99). On the basis of this
knowledge, it was hypothesized that leptin may affect cardiovascular
function via a CNS site of action. To explore this possibility,
cardiovascular responses induced by intracerebroventricular administration of leptin were investigated (17, 22, 60). Intracerebroventricular administration of leptin (5-50 µg) was found to elicit a dose-related increase in MAP and RSNA in conscious rabbits, with peak values obtained after 10 and 20 min, respectively, while producing no consistent, significant increases in HR
(60). Correia et al. (17) reported that a
chronic (2-4 wk) high dose (1,000 ng/h) of leptin increased AP and
HR in conscious Sprague-Dawley (SD) rats. Acutely injected leptin did
not induce tachycardia, possibly due to the prevention of a direct
cardiac sympathoexcitatory effect as a result of baroreceptor reflex
activation by elevated AP levels. Intracerebroventricular
administration of leptin in a chloralose-urethane-anesthetized Wistar
rat increased MAP, lumbar, and renal SNA with a reduction in blood flow
in the iliac and superior mesenteric arteries, but not in the renal
artery (22). Sympathoactivation induced by
intracerebroventricular leptin administration was observed in the
kidneys, adrenal glands, hindlimbs, and brown adipose tissue (BAT)
(34, 35). Haynes et al. (33) demonstrated that an increase in RSNA induced by intracerebroventricular application of leptin was due to activation of hypothalamic melanocortin receptors; in contrast, sympathoactivation of thermogenic BAT by leptin was found
to be independent of the melanocortin system. These data suggest that
sympathoactivation caused by leptin is controlled by heterogeneous
neural mechanisms, which only partly involve the melanocortin system.
Leptin-induced sympathoactivation was apparent after transection of
sympathetic nerves distal to the recording site (35),
implying the involvement of efferent, rather than afferent, nerves.
This was confirmed by the prevention of sympathoexcitatory and pressor
effects of central leptin after the intravenous administration of a
ganglion-blocking agent (27, 60). In contrast to
administration of leptin intracerebroventricularly, intravenous
administration at the same dose did not increase AP or RSNA in
conscious rats (17) and rabbits (60). The
pressor effect of leptin was proportional to the level of leptin in the cerebrospinal fluid (CSF) (17). These results suggest that
the pressor and sympathoexcitatory effects of leptin are due to a central neural action. Leptin did not cause sympathoactivation in obese
Zucker rats (35), which are known to possess a mutation in
the gene for the leptin receptor (72). This implies that the sympathoexcitatory action of leptin requires the presence of an
intact leptin receptor. Taken together these results suggest that
intracerebroventricularly administered leptin produces pressor and
sympathoexcitatory effects mediated via a central leptin receptor.
Effects induced by intravenous administration.
Intravenous infusion of leptin increases Fos production in spinally
projecting neurons in the hypothalamic PVN, and this directly influences sympathetic nerve activity (5). Chronic
intravenous infusion of leptin in conscious SD rats at 1 µg · kg
1 · min1
(1,152-3,456 µg) significantly increases MAP and HR after 3 and 4 days, respectively (81). This dose of leptin also
increases plasma levels of leptin, explaining the slow onset of
increase in AP and HR levels induced by increasing levels of
circulating leptin. All variables returned to control levels when
leptin infusion is stopped. A low dose of leptin (0.1 µg · kg1 · min1;
345.6 µg) did not affect these variables (81). Some
studies reported that AP and HR levels were unaffected by acute leptin infusion (33, 34, 35). One possible explanation is that AP
and HR levels were measured while the animal was under anesthesia (33-35). Another explanation is that the acute
administration of leptin, either by a single bolus injection or by
short-term infusion, induced plasma leptin levels that were too low to
influence the level of AP or HR. Leptin increases the norepinephrine
turnover in interscapular BAT (15) and acute intravenous
infusion of leptin in anesthetized SD rats increases SNA in the
adrenals, BAT, and the kidneys (34, 35). Since the
leptin-induced elevation of AP and HR is abolished by 
1-
and 
-adrenergic receptor blockage, the mechanism controlling these
events may be mediated by activation of the sympathetic nervous system
(12). How the large (Mr 16,000) leptin protein
crosses the blood-brain barrier to activate the OB-RB receptor in the
CNS is not known. It is possible that the hypothalamic leptin receptor
is in a region where there is a weak or non-existent blood-brain
barrier. The functional leptin receptor OB-RB is expressed in
endothelial cells (87). This is significant because the
vascular endothelium is known to play a critical role in AP
homeostasis, in part by its ability to produce potent vasoactive factors, principal among these being the vasodilator nitric oxide (NO)
(66). Intravenous infusion of leptin (10-1,000
µg/kg) increases serum NO concentrations in a dose-dependent manner
in anesthetized Wistar rats (27) and enhances the increase
in AP and HR levels under NO synthesis inhibition (53).
This suggests that leptin originating from the peripheral tissue
increases the sympathetic outflow through the CNS and may tonically
modulate the cardiovascular function mediated via local NO. However,
Mitchell et al. (63) demonstrated that acute intravenous
infusion of leptin had no significant effect on hemodynamics in the
presence of an NO synthase inhibitor, despite a significant increase in
lumbar SNA in conscious rats. Chronic intravenous infusion of leptin,
under impaired NO synthesis, moderately enhances the hypertensive
effects of leptin and severely amplifies the tachycardia caused by
hyperleptinemia in conscious rats (53). Acute injection of
leptin does not induce hypertension and may reflect the brief duration
of leptin administration. It is also possible that the depressor action
of NO may prevent the pressor responses induced by sympathetic
activation. A further possibility is that changes in baroreceptor
reflex activity induced by leptin may modulate the direct
cardiovascular response, as well as NPY, which attenuates baroreflex
sensitivities by intracerebroventricular injection (61).
These findings suggest that stimulation of endothelium-derived NO has a
depressor effect and opposes the pressor effect mediated by the direct
sympathoexcitatory effects of leptin. It is likely that intravenously
administered leptin modulates cardiovascular function mediated by the
central sympathetic nervous system and/or the peripheral NO system.
Cellular Action of Leptin
The leptin receptor (Ob-Rb) gene has at least six splice variants
(103). The observations that the Ob-Rb variant is highly expressed in the hypothalamus and that the obese diabetic
db/db mouse mutation is found in the Ob-Rb variant strongly
suggest that leptin normally exerts its effects on this hypothalamic
receptor. Systemic administration of leptin (1 mg/kg) in the
ob/ob mouse activates Fos protein expression in the PVN
(102), and intracerebroventricular administration of
leptin (3.5 µg) induces c-Fos-like expression, in addition to
enhancing levels of CRH mRNA in the PVN in Long-Evans rats
(99). Furthermore, intracerebroventricular and
intraperitoneal administration of leptin (1 mg/kg) induces Fos
expression in the dorsal, ventral, and lateral parvocellular
subdivisions of the PVN (24). These subnuclei are a major
source of descending axons to autonomic preganglionic neurons within
the medulla and spinal cord. These results suggest that circulating
leptin activates PVN neurons and regulates physiological functions. To
examine this possibility, Powis et al. (73) examined the
direct membrane effects of leptin on the PVN neuron of rat brain slices
using whole cell patch-clamp recording techniques. Bath applications of
leptin (1-100 nM) produced dose-related depolarizations in 82% of
the type 1 (magnocellular) neurons tested and 67% of the type 2 (parvocellular) neurons tested. Similar depolarizations were observed
in response to bath application of leptin during synaptic transmission
blockage using the sodium channel blocker TTX, indicating that leptin
has a postsynaptic site of action in PVN neurons. A voltage-clamp study
revealed that leptin-induced currents have a reversal potential between
25 and 30 mV, indicating that a nonspecific mix of cations carries
this current. These results suggest that leptin has an
excitatory effect on CNS neurons, in particular PVN neurons.
| |
OREXINS AND CARDIOVASCULAR FUNCTION |
The orexins were initially characterized as potent stimulants of
food intake (76); however, mRNA mapping of the orexin
receptors (OX1R and OX2R) (76, 96)
and orexin nerve fibers (20, 97, 98) suggests that they
have a role in other physiological functions, such as the regulation of
blood pressure, the neuroendocrine system (98), and the
sleep-waking cycle (13, 50, 56). For example, the
administration of orexin-A or -B induces marked changes in AP, HR,
RSNA, and plasma catecholamine (CA) in anesthetized (3, 14) and conscious (62, 77, 78, 86) animals.
Integrative Action of Orexins
Effects induced by intracerebroventricular administration.
Intracerebroventricular injection of orexins induces c-Fos expression
in the locus ceruleus, arcuate nucleus, central gray, raphe nuclei,
NTS, supraortic nucleus (SON), and PVN in Wistar rats (20,
54), indicating that central administration of orexin activates
specific nuclear groups in the hypothalamus and brain stem known to
regulate autonomic and neuroendocrine functions (91). We
hypothesized that orexin might affect cardiovascular function mediated
via a CNS site of action. To examine this possibility, the
cardiovascular and sympathetic responses produced by the central administration of orexin-A and -B were studied in conscious,
unrestrained Wistar rats (86), because anesthesia is well
known to have a profound effect on the cardiovascular and autonomic
nervous systems (101). Intracerebroventricular
administration of orexin-A provoked a dose-related increase in MAP, HR,
and RSNA in conscious rats (Fig. 1). The
MAP and HR increased rapidly and reached peak values 10-15 min
after orexin-A administration. Pressor effects induced by
intracerebroventricularly administered orexin-A and -B were also
observed in conscious SD rats (77) and rabbits
(62). In urethane-anesthetized rats, intracisternal
(14) or intrathecal (3) injections of
orexin-A or -B increased MAP and HR in a dose-dependent manner.
Intravenous injection of the same dose of orexin-A or -B used in the
intracerebroventricular injection experiment failed to cause any
cardiovascular and SNA change (62, 86). These results
suggest that the pressor effects induced by orexin-A and -B were
mediated via a CNS site of action. A high dose of orexin-A produced a
significant increase in RSNA 10 min after injection, which persisted
for ~15 min (Fig. 1). RSNA also increased transiently at a low dose
(0.3 nmol) of orexin-A. There was a statistically significant
correlation coefficient (r) between RSNA and MAP
(r = 0.69 and r = 0.83, respectively;
both P values < 0.001) or HR (r = 0.76 and r = 0.89, respectively; both P
values < 0.001) at 0.3- and 3.0-nmol doses in the orexin-A
injected group (Fig. 2).
Intracerebroventricularly administered orexin-B (3.0 nmol) also
produced a significant increase in MAP, this response pattern being
similar to that observed for orexin-A administration (Fig.
3). HR also rapidly increased and
returned to control levels within 30 min of orexin-B (3.0 nmol)
administration. In contrast to the results with orexin-A, RSNA did not
increase significantly at a dose of 0.3 or 3.0 nmol. However, a 30-nmol
dose of orexin-B resulted in an ~40% (P < 0.001)
increase in RSNA 20 min after injection (unpublished data). For each
dose, the maximum changes from control values for orexin-A and -B
during the recording time (60 min) were compared (Fig.
4A). Central orexin-A induced
an increase in MAP ~1.5-fold greater than orexin-B for both doses, but no significant differences were observed in HR. These results are
consistent with findings by Chen et al. (14). The increase in RSNA produced by intracerebroventricular administration of orexin-A
was greater than that produced by orexin-B at 3.0 nmol. To provide a
description of the duration and magnitude of cardiovascular and
sympathetic responses, the area under the curve (AUC) (2) was calculated for the 60-min period immediately after peptide injection for each animal within a group (Fig. 4B). The AUC
in MAP and HR was significantly larger for orexin-A than for orexin-B at only 3.0 nmol. The AUC in RSNA was larger for orexin-A than for
orexin-B at each dose. In almost all rats subjected to
intracerebroventricular administration of orexin, increases in
locomotor activities known to be related to a stress response
(29), such as chewing and grooming, were observed
(42). Stress causes an increase in sympathetic nerve
activity (52, 95). Muscle exercise and postural change are
well known to induce the activation of sympathetic outflow (59). To exclude the effects of stress and/or locomotion
on these parameters, we also injected orexin-A and -B (3.0 nmol) centrally in rats anesthetized with pentobarbital (50 mg/kg ip) (86). Intracerebroventricularly administered orexin-A
induced a significant increase in MAP, HR, and RSNA, whereas orexin-B induced a significant increase in MAP and HR in anesthetized rats, indicating that the observed increases in these parameters were not due
to activated locomotion and/or stress. Intravenous injection of
pentolinium, a ganglion-blocking agent, abolished the AP response (62). This suggests that the pressor and tachycardic
effects of orexins may have been due to activation of sympathetic
outflow. Regional differences in sympathetic outflow are known to exist (100). To examine systemic sympathetic outflow induced by
central orexins, plasma CA was measured under similar conditions to
record nerve activity (Fig. 5). High
doses of orexin-A and -B increase plasma norepinephrine (NE), the
effect being larger and longer lasting with orexin-A. Therefore, it is
likely that the orexin-induced increase in sympathetic nerve outflow
leads to the increase in plasma NE, which in turn induces
cardiovascular responses. Intracerebroventricularly administered
orexin-A also significantly increases plasma epinephrine (Epi) levels
10 min after injection. Al-Barazanji et al. (1) demonstrated that intracerebroventricular injection of orexin-A results
in a rapid and significant increase in plasma levels of ACTH and
corticosterone and mRNA levels of CRF and AVP in the parvocellular
neurons of the PVN. These results suggest that orexin-A acts centrally
to activate the hypothalamic-pituitary-adrenal (HPA) axis and involves
the stimulation of both CRF and AVP expression. Central orexin-A also
increases plasma Epi, glucose, and AVP levels in conscious rabbits
(62). The elevated circulating level of Epi in addition to
NE, after injections of a high dose of orexin-A, suggests that the
sympathoadrenomedullary system (SA system) is activated. In contrast to
orexin-A, central orexin-B did not produce an increase in plasma Epi.
The large pressor response induced by central orexin-A, compared with
that induced by orexin-B, may be due to activation of the SA system in
addition to sympathetic outflow. This suggests that
intracerebroventricular administration of orexin-A and -B induces
cardiovascular responses via different central mechanisms.
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Fig. 1.
Time course of changes in mean arterial pressure (MAP),
heart rate (HR), and renal sympathetic nerve activity (RSNA) during the
60 min after intracerebroventricular administration of orexin-A (0.3 and 3.0 nmol) or vehicle (saline) in conscious rats. Vertical dotted
line indicates the time, 0 min; bpm, beats/min. All data are means ± SE; n is the number of animals. * P < 0.05 vs. vehicle.  P < 0.05 vs. orexin-A (0.3 nmol). [Borrowed with permission from Shirasaka et al.
(86).]
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Fig. 2.
Relationship between RSNA and MAP (A) or HR
(B). There was a statistically significant correlation
between RSNA and MAP or HR (r = 0.83 and
r = 0.89, respectively; both P values < 0.001) in the orexin-A (3.0 nmol)-injected group. [Reprinted with
permission from Elsevier Science (86a).]
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Fig. 3.
Time course of change in MAP (A), HR
(B), and RSNA (C) during the 60 min after
intracerebroventricular administration of orexin-B (0.3 and 3.0 nmol)
or vehicle (saline) in conscious rats. Vertical dotted line indicates
the time, 0 min. All data are means ± SE; n is the
number of animals. * P < 0.05 vs. vehicle.
P < 0.05 vs. orexin-B (0.3 nmol). [Borrowed
with permission from Shirasaka et al. (86).]
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Fig. 4.
Bar graph showing maximal changes from control values
(A) and the area under the curve (AUC; B) for
MAP, HR, and RSNA during the 60 min after intracerebroventricular
administration of orexin-A and -B (0.3 and 3.0 nmol, respectively) in
conscious rats. All data are means ± SE; n is the
number of animals. * P < 0.05 vs. orexin-B for each
dose. [Borrowed with permission from Shirasaka et al.
(86).]
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Fig. 5.
Effect of intracerebroventricular administration of vehicle
(saline) or orexin-A (0.3 and 3.0 nmol) (A) and orexin-B
(0.3 and 3.0 nmol) (B) on the plasma concentration of
epinephrine (Epi) and norepinephrine (NE) in conscious rats. 0 min,
time of administration. All data are means ± SE; n is
the number of animals. * P < 0.05 vs.
pre-administration values. P < 0.05 vs. orexin-A
(0.3 nmol). [Borrowed with permission from Shirasaka et al.
(86).]
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Effects induced by intravenous administration.
Orexins were initially thought to be synthesized exclusively in the
brain in cell bodies in the lateral hypothalamic/perifornical area
(76). It is known that prepro-orexin and orexin receptor mRNAs are also expressed in peripheral tissues such as kidney, adrenal,
thyroid, testis, ovaries, and jejunum (46, 51). Although peripherally administered orexin-A enters the brain (49),
reports of positive effects of intravenously administered orexin-A or -B are not as common. Thyrotropin-releasing hormone (TRH) release from
the rat hypothalamus in vitro was inhibited significantly in a
dose-related manner with the intravenous injection of orexin-A (64). A high dose of intravenously administered orexin-A
(3 mg/kg) induces analgesia in Wistar rats in the hotplate test; in
addition, thermal hyperalgesia is induced by carrageenan
(8). The level of intravenously administered orexins may
have been too low to evoke other physiological responses.
Alternatively, the action of leptin in peripheral tissue may be via an
autocrine/paracrine mechanism.
Cellular Action of Orexins
The two known orexin receptors (OX1R and
OX2R) belong to the G protein-coupled receptor superfamily
with a proposed seven-transmembrane topology (76).
OX1R and OX2R mRNAs are located exclusively in the rat brain. Orexin-A or -B evokes NE release from rat
cerebrocortical slices (37). These findings are consistent
with the idea that orexins are regulatory peptides that function within
the CNS. The mRNA of OX1R and OX2R is
differentially distributed, with OX1R mRNA most abundant in
the VMH and OX2R mRNA predominantly expressed in the PVN.
The preautonomic parvocellular neurons of the PVN send long descending
projections to several areas within the CNS that are known to be
important in cardiovascular function (4, 89, 91). These
regions include the NTS, where baroreceptor and chemoreceptor afferents
terminate, the dorsal vagal complex, which is present in the
dorsomedial medulla and contains vagal preganglionic neurons, the RVLM,
which is probably a major site for the generation of sympathetic tone
for the vasculature, and the IML cell column of the thoracolumbar
spinal cord, which is the site of sympathetic preganglioic motor
neurons involved in the regulation of HR and BP (4, 90).
Taken together, these data suggest that orexins are likely to affect
PVN neurons and play a broad regulatory role in the CNS. To examine
whether orexins affect PVN neurons, we measured the changes in membrane
potential induced by an application of orexins on the PVN neurons of a
rat hypothalamic slice using the whole cell patch-clamp recording technique (85), according to cell classification
(94). Bath applications of orexin-B (0.01-1.0 µM)
depolarized 80.8% of type 1 and 79.2% of type 2 neurons in a
dose-dependent manner in normal artificial CSF (aCSF) (Figs. 6 and
7).
Orexin-A (1.0 µM) also induced depolarization in type 1 (magnocellular) and type 2 (parvocellular) neurons. These responses
were accompanied by an increase in action potential firing (Fig.
6A). A similar reversible depolarization was observed in the
presence of TTX (Fig. 6B), indicating that the depolarizing
action is mediated by a postsynaptic orexin receptor. The direct
postsynaptic excitatory action of orexins (hypocretins) was
demonstrated in the locus ceruleus (30, 39, 44), arcuate nucleus (74), dorsal motor nucleus of the vagus (DMNV)
(41), IML (3), and laterodorsal tegmental
nucleus (LDT) (10). In further experiments involving the
addition of Cd2+ in the aCSF-containing TTX (Fig.
6C), the increases in membrane potential induced by orexin-B
significantly decreased in type 2 neurons (10.1 ± 0.64 to
7.84 ± 0.51 mV; n = 7, P < 0.05). This suggests that the orexin-evoked depolarization was produced
in part by Cd2+-sensitive Ca2+ channels, which
contribute to the release of glutamate from presynaptic nerve
terminals, and that orexin-B also excites type 2 neurons, at least in
part, by glutamatergic transmission. Therefore, it may be possible that
orexin-B depolarizes type 2 neurons via both postsynaptic and
presynaptic action. Monitoring membrane resistance during the response
does not reveal a clear conductance change. Orexin-B has been reported
to decrease or affect potassium conductance (44) or reduce
afterhyperpolarization (39). Hwang et al.
(41) demonstrated that orexins affect more than one
conductance, which may include a nonselective cation conductance and a
potassium conductance in DMNV neurons. It is possible that orexins
excite type 1 and type 2 neurons of the PVN by increasing depolarizing conductance and decreasing hyperpolarizing conductance, leading to no
change in conductance. Intracerebroventricularly administered orexins
induce c-Fos expression in the PVN (20, 54). These studies
suggest that endogenous orexin-A and -B depolarize PVN neurons and
increase the firing rate via postsynaptic receptors, leading to
modulation of various physiological functions, including cardiovascular
responses.
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Fig. 6.
Effects of orexin-B on membrane potential in hypothalamic
paraventricular nucleus (PVN) neurons. Horizontal bars indicate the
peptide application time (1 min). Arrows indicate the resting membrane
potential (RMP). A, top: administration of
orexin-B (1 µM) induced a transient depolarization in type 1 PVN
neurons in normal artificial cerebrospinal fluid (aCSF). Bottom
left: baseline firing at the RMP. Bottom right:
increased action potential frequency at the peak of the response to 1 µM orexin-B. B: in the presence of TTX (1 µM), orexin-B
(1 µM) depolarized a type 2 PVN neuron. C: addition of
Cd2+ (1 mM) in aCSF-containing TTX (1 µM) significantly
reduced the depolarization induced by orexin-B (1 µM) in the same
type 2 neurons. [Borrowed with permission from Shirasaka et al.
(85).]
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Fig. 7.
Concentration-response curves for depolarization induced
by orexin-B in type 1 and type 2 neurons of the PVN. Depolarization
induced by orexin-B was plotted vs. peptide concentration. Number of
neurons tested for each concentration is indicated near the error bars.
[Borrowed with permission from Shirasaka et al. (85).]
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THE POSSIBLE CENTRAL INTERACTION BETWEEN OREXINS AND LEPTIN |
Orexins were first characterized as stimulators of appetite and
food consumption (76, 84); on the other hand, leptin was suspected to reduce food intake, mainly acting on neurons in the arcuate nucleus of the hypothalamus (103), and increase
energy expenditure (18, 35). Intracerebroventricular or
intraperitoneal administration of leptin inhibits a fasting-induced
increase in prepro-orexin mRNA and orexin receptor (OX1R)
mRNA levels (57) or reduces the orexin-A concentration in
the rat hypothalamus (7). Horvath et al. (38)
observed orexin fibers making direct contact with NPY cells and leptin
receptors coexpressing in neurons in the arcuate nucleus. This suggests
that orexins may act as a relay for leptin-induced actions in the CNS.
Administration of leptin inhibits the electrical activity of
orexin-sensitive neurons in the arcuate nucleus of the hypothalamus
(74). The opposing actions of orexin and leptin on
neuronal excitability are consistent with their opposing effects on
food intake. These data support the hypothesis that the arcuate nucleus
is a site of integration for stimulatory and inhibitory drives on food
intake, the former being mediated by the neuropeptide orexin from the LHA and the latter by leptin circulating in the blood. The hypothesis that control of feeding and energy metabolism involves leptin and
orexins is supported by observations of morphological (28, 31,
68) and functional (6, 67, 84, 92) interactions between these peptides. With respect to cardiovascular function, the
pressor, tachycardic, and sympathoexcitatory effects of orexins (14, 62, 77, 86) are similar to the effects of leptin (12, 17, 22, 34, 60). Neurons in the arcuate nucleus of
the hypothalamus are known to establish functional synaptic contacts
with the PVN neurons (55). Stressful stimuli significantly increase Fos protein levels in orexin neurons (104), and
the orexin system is involved in the stress reaction mediated via a CRF
(43). Leptin is an acute phase reactant with
hematopoietic, immunomodulatory, and hepatocyte stimulating activity
during the infectious and noninfectious stress responses
(58). In critically ill patients, leptin levels increase
significantly in response to stress-related cytokines (tumor necrosis
factor, interleukin-1) (65) and may contribute to the
anorexia and cachexia of infection. Considering the similarity in
cardiovascular and sympathetic action of these peptides, it is possible
that the orexins and leptin interact in the hypothalamus, most likely
in the arcuate nucleus-PVN areas. Both peptides may be activated under
stress conditions and cause an increase in AP, HR, and SNA as an
adaptive response. The orexins and leptin have a direct excitatory
postsynaptic effect on PVN neurons (73, 78, 85), leading
to diverse pathophysiological consequences, including autonomic and
cardiovascular functions associated with the stress reaction (Fig.
8). The majority of obese human subjects
have high circulating concentrations of leptin (16).
Leptin-induced sympathoexcitation may increase thermogenesis but may
also contribute to the sympathetically mediated renal sodium
reabsorption and hypertension of obesity. Although the pathophysiological role of the sympathoexcitatory effects of leptin and
orexins is not clear, the close relationship between obesity, hypertension, and altered cardiovascular responses has been documented in a number of studies (48). Therefore, leptin and orexins
may be the chemical mediators in the brain responsible for the
generation and maintenance of hypertension that is associated with
conditions of energy imbalance, such as obesity.
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Fig. 8.
Schematic diagram of possible mechanisms for the action
of central leptin and orexins in cardiovascular, neuroendocrine, and
sympathetic outflows. Leptin and orexins bind to their receptors of the
magnocellular or parvocellular neurons of the hypothalamic
paraventricular nucleus or arcuate nucleus neurons, causing their
depolarization. Excitation of magnocellular neurons induces secretion
of arginine vasopressin (AVP) from the posterior pituitary,
antidiuresis, and vasoconstriction. Conversely, parvocellular neurons
activate autonomic centers in the brain stem and spinal cord,
increasing the HR and blood pressure or causing the release of CRF.
Secretion of ACTH from the anterior pituitary is controlled by CRF and
AVP, synthesized by the parvocellular neuron. Right lower
vessel, norepinephrine released from the sympathetic nerve ending
induces vasoconstriction. Activation of the renal sympathetic nerve
induces antidiuresis and secretion of renin. Solid lines, a neural or
humoral pathway. Dotted lines, functional influence. ARC, arcuate
nucleus; CVOs, cerebroventricular organs; DVC, dorsal vagal complex;
IML, intermediolateral cell column; LHA, lateral hypothalamus; PVN,
paraventricular nucleus; Ma, magnocellular neuron; Pa, parvocellular
neuron; RVLM, rostral ventrolateral medulla.
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ACKNOWLEDGEMENTS |
This work was supported in part by a grant-in-aid for Scientific
Research (14370024, 14770780) from the Ministry of Education, Science,
Sports, and Culture, Japan and by Japanese COE Program (Section of Life
Science). This study was also carried out as part of "Ground Research
Announcement for Space Utilization" promoted by the Japan Space Forum.
| |
FOOTNOTES |
Address for reprint requests and other correspondence:
H. Kannan, First Dept. of Physiology Miyazaki Medical College,
5200 Kihara, Kiyotake, Miyazaki 889-1692, Japan (E-mail:
kannanh{at}post.miyazaki-med.ac.jp).
10.1152/ajpregu.00359.2002
| |
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ABSTRACT
INTRODUCTION
