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Identifiers | ||||||
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Aliases | LEP, LEPD, OB, OBS, leptin | |||||
External IDs | OMIM: 164160 MGI: 104663 HomoloGene: 193 GeneCards: LEP | |||||
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Species | Human | Mouse | |||||
Entrez | |||||||
Ensembl | |||||||
UniProt | |||||||
RefSeq (mRNA) |
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RefSeq (protein) |
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Location (UCSC) | Chr 7: 128.24 – 128.26 Mb | Chr 6: 29.06 – 29.07 Mb |
Identifiers | |
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Symbol | Leptin |
Pfam | PF02024 |
Pfam clan | CL0053 |
InterPro | IPR000065 |
SCOPe | 1ax8 / SUPFAM |
Leptin (from Greek λεπτός leptos, "thin") is a hormone predominantly made by adipose cells and enterocytes in the small intestine that helps to regulate energy balance by inhibiting hunger, which in turn diminishes fat storage in adipocytes. Leptin acts on cell receptors in the arcuate nucleus of the hypothalamus.
Although regulation of fat stores is deemed to be the primary
function of leptin, it also plays a role in other physiological
processes, as evidenced by its many sites of synthesis other than fat
cells, and the many cell types beyond hypothalamic cells that have
leptin receptors. Many of these additional functions are yet to be
defined.
In obesity, a decreased sensitivity to leptin occurs (similar to insulin resistance in type 2 diabetes), resulting in an inability to detect satiety despite high energy stores and high levels of leptin.
Effects
Predominantly, the "energy expenditure hormone" leptin is made by adipose cells, thus it is labeled fat cell-specific. In the context of its effects, it is important to recognize that the short describing words direct, central, and primary are not used interchangeably. In regard to the hormone leptin, central vs peripheral refers to the hypothalamic portion of the brain vs non-hypothalamic location of action of leptin; direct vs indirect refers to whether there is no intermediary, or there is an intermediary in the mode of action of leptin; and primary vs secondary is an arbitrary description of a particular function of leptin.
- Location of action
- Leptin acts directly on leptin receptors in the cell membrane of different types of cells in the human body in particular, and in vertebrates in general. The leptin receptor is found on a wide range of cell types. It is a single-transmembrane-domain type I cytokine receptor, a special class of cytokine receptors. Further, leptin interacts with other hormones and energy regulators, indirectly mediating the effects of: insulin, glucagon, insulin-like growth factor, growth hormone, glucocorticoids, cytokines, and metabolites.
- Mode of action
- The central location of action (effect) of the fat cell-specific hormone leptin is the hypothalamus, a part of the brain, which is a part of the central nervous system. Non-hypothalamic targets of leptin are referred to as peripheral targets. There is a different relative importance of central and peripheral leptin interactions under different physiologic states, and variations between species.
- Function
- The primary function of the hormone leptin is the regulation of adipose tissue mass through central hypothalamus mediated effects on hunger, food energy use, physical exercise and energy balance. Outside the brain, in the periphery of the body, leptin's secondary functions are: modulation of energy expenditure, modulation between fetal and maternal metabolism, and that of a permissive factor in puberty, activator of immune cells, activator of beta islet cells, and growth factor.
Central nervous system
In vertebrates, the nervous system consists of two main parts, the central nervous system (CNS) and the peripheral nervous system (PNS). The primary effect of leptins is in the hypothalamus, a part of the central nervous system. Leptin receptors are expressed not only in the hypothalamus but also in other brain regions, particularly in the hippocampus. Thus some leptin receptors in the brain are classified as central (hypothalamic) and some as peripheral (non-hypothalamic).
As scientifically known so far, the general effects of leptin in the central nervous system are:
- Deficiency of leptin has been shown to alter brain proteins and neuronal functions of obese mice which can be restored by leptin injection.
- In humans, low circulating plasma leptin has been associated with cognitive changes associated with anorexia, depression, and Alzheimer's Disease .
- Studies in transgenic mouse models of Alzheimer's disease have shown that chronic administration of leptin can ameliorate brain pathology and improve cognitive performance, by reducing b-amyloid and hyperphosphorylated Tau, two hallmarks of Alzheimer's pathology.
Generally, leptin is thought to enter the brain at the choroid plexus, where the intense expression of a form of leptin receptor molecule could act as a transport mechanism.
Increased levels of melatonin causes a downregulation of leptin, however, melatonin also appears to increase leptin levels in the presence of insulin, therefore causing a decrease in appetite during sleeping. Partial sleep deprivation has also been associated with decreased leptin levels.
Mice with type 1 diabetes treated with leptin or leptin plus
insulin, compared to insulin alone had better metabolic profiles: blood
sugar did not fluctuate so much; cholesterol levels decreased; less body
fat formed.
Hypothalamus
Leptin acts on receptors in the lateral hypothalamus to inhibit hunger and the medial hypothalamus to stimulate satiety.
- In the lateral hypothalamus, leptin inhibits hunger by
- counteracting the effects of neuropeptide Y, a potent hunger promoter secreted by cells in the gut and in the hypothalamus
- counteracting the effects of anandamide, another potent hunger promoter that binds to the same receptors as THC
- In the medial hypothalamus, leptin stimulates satiety by
- promoting the synthesis of α-MSH, a hunger suppressant
Thus, a lesion in the lateral hypothalamus causes anorexia (due to a
lack of hunger signals) and a lesion in the medial hypothalamus causes
excessive hunger (due to a lack of satiety signals).
This appetite inhibition is long-term, in contrast to the rapid inhibition of hunger by cholecystokinin (CCK) and the slower suppression of hunger between meals mediated by PYY3-36.
The absence of leptin (or its receptor) leads to uncontrolled hunger
and resulting obesity. Fasting or following a very-low-calorie diet
lowers leptin levels.
Leptin levels change more when food intake decreases than when it increases.
The dynamics of leptin due to an acute change in energy balance may be
related to appetite and eventually, to food intake rather than fat
stores.
- It controls food intake and energy expenditure by acting on receptors in the mediobasal hypothalamus.
Leptin binds to neuropeptide Y (NPY) neurons in the arcuate nucleus
in such a way as to decrease the activity of these neurons. Leptin
signals to the hypothalamus which produces a feeling of satiety.
Moreover, leptin signals may make it easier for people to resist the
temptation of foods high in calories.
Leptin receptor activation inhibits neuropeptide Y and agouti-related peptide (AgRP), and activates α-melanocyte-stimulating hormone
(α-MSH). The NPY neurons are a key element in the regulation of hunger;
small doses of NPY injected into the brains of experimental animals
stimulates feeding, while selective destruction of the NPY neurons in
mice causes them to become anorexic. Conversely, α-MSH is an important
mediator of satiety, and differences in the gene for the α-MSH receptor
are linked to obesity in humans.
Leptin interacts with six types of receptors (Ob-Ra–Ob-Rf, or LepRa-LepRf), which in turn are encoded by a single gene, LEPR.[40] Ob-Rb is the only receptor isoform that can signal intracellularly via the Jak-Stat and MAPK signal transduction pathways, and is present in hypothalamic nuclei.
Once leptin has bound to the Ob-Rb receptor, it activates the
stat3, which is phosphorylated and travels to the nucleus to effect
changes in gene expression, one of the main effects being the
down-regulation of the expression of endocannabinoids, responsible for increasing hunger.
In response to leptin, receptor neurons have been shown to remodel
themselves, changing the number and types of synapses that fire onto
them.
Circulatory system
The role of leptin/leptin receptors in modulation of T cell
activity and the innate immune system was shown in experimentation with
mice. It modulates the immune response to atherosclerosis, of which
obesity is a predisposing and exercise a mitigating factor.
Exogenous leptin can promote angiogenesis by increasing vascular endothelial growth factor levels.
Hyperleptinemia produced by infusion or adenoviral gene transfer decreases blood pressure in rats.
Leptin microinjections into the nucleus of the solitary tract
(NTS) have been shown to elicit sympathoexcitatory responses, and
potentiate the cardiovascular responses to activation of the
chemoreflex.
Fetal lung
In fetal lung, leptin is induced in the alveolar interstitial fibroblasts ("lipofibroblasts") by the action of PTHrP
secreted by formative alveolar epithelium (endoderm) under moderate
stretch. The leptin from the mesenchyme, in turn, acts back on the
epithelium at the leptin receptor carried in the alveolar type II
pneumocytes and induces surfactant expression, which is one of the main
functions of these type II pneumocytes.
Reproductive system
Ovulatory cycle
In mice, and to a lesser extent in humans, leptin is required for male and female fertility.
Ovulatory cycles in females are linked to energy balance (positive or
negative depending on whether a female is losing or gaining weight) and
energy flux (how much energy is consumed and expended) much more than
energy status (fat levels). When energy balance is highly negative
(meaning the woman is starving) or energy flux is very high (meaning the
woman is exercising at extreme levels, but still consuming enough
calories), the ovarian cycle stops and females stop menstruating. Only
if a female has an extremely low body fat percentage does energy status
affect menstruation. Leptin levels outside an ideal range may have a
negative effect on egg quality and outcome during in vitro fertilization. Leptin is involved in reproduction by stimulating gonadotropin-releasing hormone from the hypothalamus.
Pregnancy
The placenta produces leptin.
Leptin levels rise during pregnancy and fall after childbirth. Leptin
is also expressed in fetal membranes and the uterine tissue. Uterine
contractions are inhibited by leptin. Leptin plays a role in hyperemesis gravidarum (severe morning sickness of pregnancy), in polycystic ovary syndrome and hypothalamic leptin is implicated in bone growth in mice.
Lactation
Immunoreactive
leptin has been found in human breast milk; and leptin from mother's
milk has been found in the blood of suckling infant animals.
Puberty
Leptin along with kisspeptin controls the onset of puberty. High levels of leptin, as usually observed in obese females, can trigger neuroendocrine cascade resulting in early menarche. This may eventually lead to shorter stature as oestrogen secretion starts during menarche and causes early closure of epiphyses.
Bone
Leptin's role in regulating bone mass was identified in 2000. Leptin can affect bone metabolism via direct signalling from the brain. Leptin decreases cancellous bone, but increases cortical bone.
This "cortical-cancellous dichotomy" may represent a mechanism for
enlarging bone size, and thus bone resistance, to cope with increased
body weight.
Bone metabolism can be regulated by central sympathetic outflow, since sympathetic pathways innervate bone tissue. A number of brain-signalling molecules (neuropeptides and neurotransmitters) have been found in bone, including adrenaline, noradrenaline, serotonin, calcitonin gene-related peptide, vasoactive intestinal peptide and neuropeptide Y. Leptin binds to its receptors in the hypothalamus, where it acts through the sympathetic nervous system to regulate bone metabolism. Leptin may also act directly on bone metabolism via a balance between energy intake and the IGF-I pathway. There is a potential for treatment of diseases of bone formation - such as impaired fracture healing - with leptin.
Immune system
Factors
that acutely affect leptin levels are also factors that influence other
markers of inflammation, e.g., testosterone, sleep, emotional stress,
caloric restriction, and body fat levels. While it is well-established
that leptin is involved in the regulation of the inflammatory response,
it has been further theorized that leptin's role as an inflammatory
marker is to respond specifically to adipose-derived inflammatory cytokines.
In terms of both structure and function, leptin resembles IL-6 and is a member of the cytokine superfamily. Circulating leptin seems to affect the HPA axis, suggesting a role for leptin in stress response. Elevated leptin concentrations are associated with elevated white blood cell counts in both men and women.
Similar to what is observed in chronic inflammation, chronically
elevated leptin levels are associated with obesity, overeating, and
inflammation-related diseases, including hypertension, metabolic syndrome, and cardiovascular disease.
While leptin is associated with body fat mass, however, the size of
individual fat cells, and the act of overeating, it is interesting that
it is not affected by exercise (for comparison, IL-6 is released in response to muscular contractions). Thus, it is speculated that leptin responds specifically to adipose-derived inflammation.
Leptin is a pro-angiogenic, pro-inflammatory and mitogenic factor, the
actions of which are reinforced through crosstalk with IL-1 family
cytokines in cancer.
Taken as such, increases in leptin levels (in response to caloric
intake) function as an acute pro-inflammatory response mechanism to
prevent excessive cellular stress induced by overeating. When high
caloric intake overtaxes the ability of fat cells to grow larger or increase in number
in step with caloric intake, the ensuing stress response leads to
inflammation at the cellular level and ectopic fat storage, i.e., the
unhealthy storage of body fat within internal organs, arteries, and/or
muscle. The insulin increase in response to the caloric load provokes a
dose-dependent rise in leptin, an effect potentiated by high cortisol
levels.
(This insulin-leptin relationship is notably similar to insulin's
effect on the increase of IL-6 gene expression and secretion from preadipocytes in a time- and dose-dependent manner.) Furthermore, plasma leptin concentrations have been observed to gradually increase when acipimox is administered to prevent lipolysis, concurrent hypocaloric dieting and weight loss notwithstanding.
Such findings appear to demonstrate high caloric loads in excess of
storage rate capacities of fat cells lead to stress responses that
induce an increase in leptin, which then operates as an adipose-derived
inflammation stopgap signaling for the cessation of food intake so as to
prevent adipose-derived inflammation from reaching elevated levels.
This response may then protect against the harmful process of ectopic
fat storage, which perhaps explains the connection between chronically
elevated leptin levels and ectopic fat storage in obese individuals.
Leptin increases the production of leukocytes via actions on the
hematopoietic niche, a pathway that is more active in sedentary mice and
humans when compared to individuals which are physically active.
Location of gene and structure of hormone
The Ob(Lep) gene (Ob for obese, Lep for leptin) is located on chromosome 7 in humans. Human leptin is a 16-kDa protein of 167 amino acids.
Mutations
A human mutant leptin was first described in 1997,
and subsequently six additional mutations were described. All of those
affected were from Eastern countries; and all had variants of leptin not
detected by the standard immunoreactive technique, so leptin levels
were low or undetectable. The most recently described eighth mutation
reported in January 2015, in a child with Turkish parents, is unique in
that it is detected by the standard immunoreactive technique,
where leptin levels are elevated; but the leptin does not turn on the
leptin receptor, hence the patient has functional leptin deficiency. These eight mutations all cause extreme obesity in infancy, with hyperphagia.
Nonsense
A nonsense mutation in the leptin gene that results in a stop codon
and lack of leptin production was first observed in mice. In the mouse
gene, arginine-105 is encoded by CGA and only requires one nucleotide
change to create the stop codon TGA. The corresponding amino acid in
humans is encoded by the sequence CGG and would require two nucleotides
to be changed to produce a stop codon, which is much less likely to
happen.
Frameshift
A recessive frameshift mutation resulting in a reduction of leptin has been observed in two consanguineous
children with juvenile obesity. A 2001 study of 13 people with a
heterozygous frameshift mutation known as delta-G133 found that they had
lower blood leptin levels than controls. There was an increased rate of
obesity in these individuals, with 76% having a BMI of over 30 compared
to 26% in the control group.
Polymorphisms
A
Human Genome Equivalent (HuGE) review in 2004 looked at studies of the
connection between genetic mutations affecting leptin regulation and
obesity. They reviewed a common polymorphism in the leptin gene (A19G;
frequency 0.46), three mutations in the leptin receptor gene (Q223R, K109R and K656N) and two mutations in the PPARG gene (P12A and C161T). They found no association between any of the polymorphisms and obesity.
A 2006 study found a link between the common LEP-2548 G/A genotype and morbid obesity in Taiwanese aborigines, but a 2014 meta-analysis did not, however, this polymorphism has been associated with weight gain in patients taking antipsychotics.
The LEP-2548 G/A polymorphism has been linked with an increased risk of prostate cancer, gestational diabetes, and osteoporosis.
Other rare polymorphisms have been found but their association with obesity are not consistent.
Transversion
A single case of a homozygous transversion mutation of the gene encoding for leptin was reported in January 2015. It leads to functional leptin deficiency with high leptin levels in circulation. The transversion of (c.298G → T) changed aspartic acid to tyrosine at position 100 (p.D100Y). The mutant leptin could neither bind to nor activate the leptin receptor in vitro, nor in leptin-deficient mice in vivo.
It was found in a two-year-old boy with extreme obesity with recurrent
ear and pulmonary infections. Treatment with metreleptin led to "rapid
change in eating behavior, a reduction in daily energy intake, and
substantial weight loss."
Sites of synthesis
Leptin is produced primarily in the adipocytes of white adipose tissue. It also is produced by brown adipose tissue, placenta (syncytiotrophoblasts), ovaries, skeletal muscle, stomach (the lower part of the fundic glands), mammary epithelial cells, bone marrow, gastric chief cells and P/D1 cells.
Blood levels
Leptin circulates in blood in free form and bound to proteins.
Physiologic variation
Leptin levels vary exponentially, not linearly, with fat mass. Leptin levels in blood are higher between midnight and early morning, perhaps suppressing appetite during the night. The diurnal rhythm of blood leptin levels may be modified by meal-timing.
In specific conditions
In
humans, many instances are seen where leptin dissociates from the
strict role of communicating nutritional status between body and brain
and no longer correlates with body fat levels:
- Leptin plays a critical role in the adaptive response to starvation.
- Leptin level is decreased after short-term fasting (24–72 hours), even when changes in fat mass are not observed.
- Serum level of leptin is reduced by sleep deprivation.
- Leptin levels are paradoxically increased in obesity.
- Leptin level is increased by emotional stress.
- Leptin level is chronically reduced by physical exercise training.
- Leptin level is decreased by increases in testosterone levels and increased by increases in estrogen levels.
- Leptin level is increased by insulin.
- Leptin release is increased by dexamethasone.
- In obese patients with obstructive sleep apnea, leptin level is increased, but decreased after the administration of continuous positive airway pressure. In non-obese individuals, however, restful sleep (i.e., 8–12 hours of unbroken sleep) can increase leptin to normal levels.
In mutations
All
known leptin mutations except one are associated with low to
undetectable immunoreactive leptin blood levels. The exception is a
mutant leptin reported in January 2015 which is not functional, but is
detected with standard immunoreactive methods. It was found in a
massively obese 2-1/2-year-old boy who had high levels of circulating
leptin which had no effect on leptin receptors, so he was functionally
leptin-deficient.
Role in disease
Obesity
Although leptin reduces appetite as a circulating signal, obese
individuals generally exhibit a higher circulating concentration of
leptin than normal weight individuals due to their higher percentage body fat. These people show resistance to leptin, similar to resistance of insulin in type 2 diabetes,
with the elevated levels failing to control hunger and modulate their
weight. A number of explanations have been proposed to explain this. An
important contributor to leptin resistance is changes to leptin receptor
signalling, particularly in the arcuate nucleus,
however, deficiency of, or major changes to, the leptin receptor itself
are not thought to be a major cause. Other explanations suggested
include changes to the way leptin crosses the blood brain barrier (BBB) or alterations occurring during development.
Studies on leptin cerebrospinal fluid
(CSF) levels provide evidence for the reduction in leptin crossing the
BBB and reaching obesity-relevant targets, such as the hypothalamus, in
obese people.
In humans it has been observed that the ratio of leptin in the CSF
compared to the blood is lower in obese people than in people of a
normal weight. The reason for this may be high levels of triglycerides affecting the transport of leptin across the BBB or due to the leptin transporter becoming saturated.
Although deficits in the transfer of leptin from the plasma to the CSF
is seen in obese people, they are still found to have 30% more leptin in
their CSF than lean individuals.
These higher CSF levels fail to prevent their obesity. Since the amount
and quality of leptin receptors in the hypothalamus appears to be
normal in the majority of obese humans (as judged from leptin-mRNA
studies),
it is likely that the leptin resistance in these individuals is due to a
post leptin-receptor deficit, similar to the post-insulin receptor
defect seen in type 2 diabetes.
When leptin binds with the leptin receptor, it activates a number
of pathways. Leptin resistance may be caused by defects in one or more
part of this process, particularly the JAK/STAT pathway. Mice with a mutation in the leptin receptor gene that prevents the activation of STAT3 are obese and exhibit hyperphagia. The PI3K
pathway may also be involved in leptin resistance, as has been
demonstrated in mice by artificial blocking of PI3K signalling. The PI3K
pathway also is activated by the insulin receptor and is therefore an
important area where leptin and insulin act together as part of energy
homeostasis. The insulin-pI3K pathway can cause POMC neurons to become insensitive to leptin through hyperpolarization.
The consumption of a high fructose
diet from birth has been associated with a reduction in leptin levels
and reduced expression of leptin receptor mRNA in rats. Long-term
consumption of fructose in rats has been shown to increase levels of
triglycerides and trigger leptin and insulin resistance,
however, another study found that leptin resistance only developed in
the presence of both high fructose and high fat levels in the diet. A
third study found that high fructose levels reversed leptin resistance
in rats given a high fat diet. The contradictory results mean that it is
uncertain whether leptin resistance is caused by high levels of
carbohydrates or fats, or if an increase of both, is needed.
Leptin is known to interact with amylin,
a hormone involved in gastric emptying and creating a feeling of
fullness. When both leptin and amylin were given to obese,
leptin-resistant rats, sustained weight loss was seen. Due to its
apparent ability to reverse leptin resistance, amylin has been suggested
as possible therapy for obesity.
It has been suggested that the main role of leptin is to act as a
starvation signal when levels are low, to help maintain fat stores for
survival during times of starvation, rather than a satiety signal to
prevent overeating. Leptin levels signal when an animal has enough
stored energy to spend it in pursuits besides acquiring food.
This would mean that leptin resistance in obese people is a normal part
of mammalian physiology and possibly, could confer a survival
advantage.
Leptin resistance (in combination with insulin resistance and weight
gain) is seen in rats after they are given unlimited access to
palatable, energy-dense foods. This effect is reversed when the animals are put back on a low-energy diet.
This also may have an evolutionary advantage: allowing energy to be
stored efficiently when food is plentiful would be advantageous in
populations where food frequently may be scarce.
Response to weight loss
Dieters
who lose weight, particularly those with an overabundance of fat cells,
experience a drop in levels of circulating leptin. This drop causes
reversible decreases in thyroid activity, sympathetic tone, and energy
expenditure in skeletal muscle, and increases in muscle efficiency and
parasympathetic tone. Many of these changes are reversed by peripheral
administration ( intravenously into the veins of the arms, hands,
legs, or feet ) of recombinant leptin to restore pre-diet levels.
A decline in levels of circulating leptin also changes brain
activity in areas involved in the regulatory, emotional, and cognitive
control of appetite that are reversed by administration of leptin.
Role in osteoarthritis with obesity
Obesity and osteoarthritis
Osteoarthritis
and obesity are closely linked. Obesity is one of the most important
preventable factors for the development of osteoarthritis.
Originally, the relationship between osteoarthritis and obesity
was considered to be exclusively biomechanically based, according to
which the excess weight caused the joint to become worn down more
quickly. However, today we recognise that there is also a metabolic
component which explains why obesity is a risk factor for
osteoarthritis, not only for weight-bearing joints (for example, the
knees), but also for joints that do not bear weight (for example, the
hands). Consequently, it has been shown that decreasing body fat lessens osteoarthritis to a greater extent than weight loss per se.
This metabolic component related with the release of systemic factors,
of a pro-inflammatory nature, by the adipose tissues, which frequently
are critically associated with the development of osteoarthritis.
Thus, the deregulated production of adipokines and inflammatory
mediators, hyperlipidaemia, and the increase of systemic oxidative
stress are conditions frequently associated with obesity which can
favour joint degeneration. Furthermore, many regulation factors have
been implicated in the development, maintenance and function, both of
adipose tissues, as well as of the cartilage and other joint tissues.
Alterations in these factors can be the additional link between obesity
and osteoarthritis.
Leptin and osteoarthritis
Adipocytes
interact with other cells through producing and secreting a variety of
signalling molecules, including the cell signalling proteins known as
adipokines. Certain adipokines can be considered as hormones, as they
regulate the functions of organs at a distance, and several of them have
been specifically involved in the physiopathology of joint diseases. In
particular, there is one, leptin, which has been the focus of attention
for research in recent years.
The circulating leptin levels are positively correlated with the
Body Mass Index (BMI), more specifically with fatty mass, and obese
individuals have higher leptin levels in their blood circulation,
compared with non-obese individuals.
In obese individuals, the increased circulating leptin levels induce
unwanted responses, that is, reduced food intake or losing body weight
does not occur as there is a resistance to leptin (ref 9). In addition
to the function of regulating energy homeostasis, leptin carries out a
role in other physiological functions such as neuroendocrine
communication, reproduction, angiogenesis and bone formation. More
recently, leptin has been recognised as a cytokine factor as well as
with pleiotropic actions also in the immune response and inflammation.
For example, leptin can be found in the synovial fluid in correlation
with the body mass index, and the leptin receptors are expressed in the
cartilage, where leptin mediates and modulates many inflammatory
responses that can damage cartilage and other joint tissues. Leptin has
thus emerged as a candidate to link obesity and osteoarthritis and
serves as an apparent objective as a nutritional treatment for
osteoarthritis.
As in the plasma, the leptin levels in the synovial fluid are positively correlated with BMI.
The leptin of the synovial fluid is synthesised at least partially in
the joint and may originate in part in the circulation. Leptin has been
shown to be produced by chondrocytes, as well as by other tissues in the
joints, including the synovial tissue, osteophytes, the meniscus and
bone.
An infrapatellar fat pad located extrasynovially within the knee joint
is also adjacent to the synovial membrane and cartilage, and has
recently been highly appreciated as an important source of leptin, as
well as other adipokines and mediators which contribute to the
pathogenesis of osteoarthritis
The risk of suffering osteoarthritis can be decreased with weight
loss. This reduction of risk is related in part with the decrease of
the load on the joint, but also in the decrease of fatty mass, the
central adipose tissue and the low-level inflammation associated with
obesity and systemic factors.
This growing evidence points to leptin as a cartilage degradation
factor in the pathogenesis of osteoarthritis, and as a potential
biomarker in the progression of the disease, which suggests that leptin,
as well as regulation and signalling mechanisms, can be a new and
promising target in the treatment of osteoarthritis, especially in obese
patients.
Obese individuals are predisposed to developing osteoarthritis,
not only due to the excess mechanical load, but also due to the excess
expression of soluble factors, that is, leptin and pro-inflammatory
cytokines, which contribute to joint inflammation and cartilage
destruction. As such, obese individuals are in an altered state, due to a
metabolic insufficiency, which requires specific nutritional treatment
capable of normalising the leptin production and reducing the systematic
low-level inflammation, in order to reduce the harmful impact of these
systematic mediators on the joint health.
There are nutritional supplements and pharmacological agents capable of directing these factors and improving both conditions.
Therapeutic use
Leptin
Leptin was approved in the United States in 2014 for use in congenital leptin deficiency and generalized lipodystrophy.
Analog metreleptin
An analog of human leptin metreleptin
(trade names Myalept, Myalepta) was first approved in Japan in 2013,
and in the United States in February 2014 and in Europe in 2018. In the
US it is indicated as a treatment for complications of leptin
deficiency, and for the diabetes and hypertriglyceridemia associated with congenital or acquired generalized lipodystrophy. In Europe based on EMA,
metreleptin should be used in addition to diet to treat lipodystrophy,
where patients have loss of fatty tissue under the skin and build-up of
fat elsewhere in the body such as in the liver and muscles. The medicine
is used in adults and children above the age of 2 years with generalised lipodystrophy (Berardinelli-Seip syndrome and Lawrence syndrome); and in adults and children above the age of 12 years with partial lipodystrophy (including Barraquer-Simons syndrome), when standard treatments have failed.
The National Health Service in England will commission
metreleptin treatment for all with congenital leptin deficiency
regardless of age beginning on April 1, 2019.
History
The
leptine was discovered by Jeffrey Friedman in 1994 after several decades
of research conducted by others institutions since 1950 on obese mouse
models
Identification of the encoding gene
In 1949, a non-obese mouse colony being studied at the Jackson Laboratory
produced a strain of obese offspring, suggesting that a mutation had
occurred in a hormone regulating hunger and energy expenditure. Mice
homozygous for the so-called ob mutation (ob/ob) ate voraciously and
were massively obese. In the 1960s, a second mutation causing obesity and a similar phenotype was identified by Douglas Coleman, also at the Jackson Laboratory, and was named diabetes (db), as both ob/ob and db/db were obese. In 1990 Rudolph Leibel and Jeffrey M. Friedman reported mapping of the db gene.
Consistent with Coleman's and Leibel's hypothesis, several
subsequent studies from Leibel's and Friedman's labs and other groups
confirmed that the ob gene encoded a novel hormone that circulated in
blood and that could suppress food intake and body weight in ob and wild
type mice, but not in db mice.
In 1994, Friedman's laboratory reported the identification of the gene. In 1995, Jose F. Caro's
laboratory provided evidence that the mutations in the mouse ob gene
did not occur in humans. Furthermore, since ob gene expression was
increased, not decreased, in human obesity, it suggested resistance to
leptin to be a possibility. At the suggestion of Roger Guillemin, Friedman named this new hormone "leptin" from the Greek lepto meaning thin. Leptin was the first fat cell-derived hormone (adipokine) to be discovered.
Subsequent studies in 1995 confirmed that the db gene encodes the leptin receptor, and that it is expressed in the hypothalamus, a region of the brain known to regulate the sensation of hunger and body weight.
Recognition of scientific advances
Coleman and Friedman have been awarded numerous prizes acknowledging their roles in discovery of leptin, including the Gairdner Foundation International Award (2005), the Shaw Prize (2009), the Lasker Award, the BBVA Foundation Frontiers of Knowledge Award and the King Faisal International Prize,
Leibel has not received the same level of recognition from the
discovery because he was omitted as a co-author of a scientific paper
published by Friedman that reported the discovery of the gene. The
various theories surrounding Friedman's omission of Leibel and others as
co-authors of this paper have been presented in a number of
publications, including Ellen Ruppel Shell’s 2002 book The Hungry Gene.
The discovery of leptin also is documented in a series of books including Fat: Fighting the Obesity Epidemic by Robert Pool, The Hungry Gene by Ellen Ruppel Shell, and Rethinking Thin: The New Science of Weight Loss and the Myths and Realities of Dieting by Gina Kolata. Fat: Fighting the Obesity Epidemic and Rethinking Thin: The New Science of Weight Loss and the Myths and Realities of Dieting review the work in the Friedman laboratory that led to the cloning of the ob gene, while The Hungry Gene draws attention to the contributions of Leibel.