Expression of leptin receptor mRNA and the long form splice variant in human anterior pituitary and pituitary adenoma

Evaluation of the leptin receptor in human spermatozoa

BACKGROUND

Leptin, a 167 amino acid peptide hormone, profoundly effects reproduction exerting its biological effects via interaction with the leptin receptor (ObR) which is widely expressed on peripheral tissues. In this study, we have attempted to assess leptin receptor expression in the spermatozoa of fertile males and those diagnosed with male factor infertility; both at the mRNA or protein levels.

METHODS

Semen samples were collected from fertile males and individuals with male factor infertility. In order to evaluate leptin receptor expression several techniques were utilized, including: reverse transcriptase-polymerase chain reaction (RT-PCR), immunostaining, flow cytometry, and western blotting. Mononuclear cells isolated from volunteers' peripheral blood were used as positive controls for leptin receptor expression.

RESULTS

leptin receptor was noted on mononuclear cells but we were unable to detect this receptor on spermatozoa at the protein level. Leptin receptor expression was detected on peripheral blood mononuclear cells (PBMCs) as positive controls; however it was not detectable on the spermatozoa of both groups by immunofluorescence microscopy or flow cytometry. Furthermore, positive expression of the ObR long isoform as assessed by RT-PCR was observed in the sperm of only four cases, whereas expression of beta-Actin, a house keeping gene, and HspA2, a testis specific gene, was present in all cases.

CONCLUSION

The long isoform of leptin receptor may not be present on human sperm. Species difference may be accounted for diverse reproductive physiology which depends on metabolic requirement. Leptin receptor expression at the mRNA level in some individuals may be related to contamination by other cells in semen.

Leptin and leptin receptor in pig spermatozoa: evidence of their involvement in sperm capacitation and survival

Several studies have recently investigated the role of leptin, the adipocyte-secreted hormone, in the growth and reproduction of rodents, humans, and domestic animals. The present study was designed to explore the expression of leptin and its receptor in pig spermatozoa. Successful Western blot evidenced a 16 kDa band for leptin and six isoforms, ranging from 120 to 40 kDa, for the leptin receptor. Both leptin and leptin receptor were interestingly located at sperm acrosomal level, suggesting their involvement in the oocyte fertilization events. In fact, both capacitation indexes and acrosin activity were enhanced by leptin, and these effects were reduced by the anti-leptin receptor antibody. Afterwards, we investigated the main transduction pathways regulated by the hormone. Our results showed that, in pig sperm, leptin can trigger the signal transducer and activator of transcription 3, a classical component of cytokine signal transduction pathways, whose expression has not been previously reported in male gamete; in addition it was found constitutively activated. Besides, leptin was able to induce the activation of phosphatidylinositol phosphate kinase 3 and MAP kinase pathways as well as of BCL2, a known antiapoptotic protein. These data address to a role of leptin and its receptor on pig sperm survival. The presence of leptin and its receptor in pig sperm suggests that they, through an autocrine short loop, may induce signal transduction and molecular changes associated with sperm capacitation and survival.

Leptin and the regulation of the hypothalamic-pituitary-adrenal axis

Leptin, the product of the obesity gene (ob) predominantly secreted from adipocytes, plays a major role in the negative control of feeding and acts via a specific receptor (Ob-R), six isoforms of which are known at present. Evidence has been accumulated that leptin, like other peptides involved in the central regulation of food intake, controls the function of the hypothalamic-pituitary-adrenal (HPA) axis, acting on both its central and peripheral branches. Leptin, along with Ob-R, is expressed in the hypothalamus and pituitary gland, where it modulates corticotropin-releasing hormone and ACTH secretion, probably acting in an autocrine-paracrine manner. Only Ob-R is expressed in the adrenal gland, thereby making it likely that leptin affects it by acting as a circulating hormone. Although in vitro and in vivo findings could suggest a glucocorticoid secretagogue action in the rat, the bulk of evidence indicates that leptin inhibits steroid-hormone secretion from the adrenal cortex. In keeping with this, leptin was found to dampen the HPA axis response to many kinds of stress. In contrast, leptin enhances catecolamine release from the adrenal medulla. This observation suggests that leptin activates the sympathoadrenal axis and does not appear to agree with its above-mentioned antistress action. Leptin and/or Ob-R are also expressed in pituitary and adrenal tumors, but little is known about the role of this cytokine in the pathophysiology.

Role of leptin in regulating appetite, neuroendocrine function, and bone remodeling

Leptin, a hormone secreted by adipocytes, acts on the hypothalamus to regulate appetite and neuroendocrine function. In the hypothalamus, both the arcuate nucleus and the ventromedial nucleus express leptin receptors. Specific neurons in the arcuate nucleus regulate appetite and reproduction. In contrast, neurons in the ventromedial nucleus regulate bone mass. The melanocortin system is the downstream pathway for regulating appetite and neuroendocrine function. In contrast, the sympathetic nervous system is the downstream pathway for regulating bone mass. Leptin, in regulating food intake and body weight, acts, in part, by inhibiting the synthesis of neuropeptide Y and its release from the hypothalamus. The leptin and insulin pathways may interact and may be important in the pathogenesis of the metabolic syndrome.

Leptin system in embryo development and implantation: a protein in search of a function

Implantation is a crucial moment in the reproduction process that requires perfect synchronization between the embryo and the maternal endometrium. The embryo must reach the blastocyst stage and the endometrium must be prepared to receive it. An appropriate and specific molecular dialogue must also take place between them. There is ample evidence to show that the leptin system is implicated in this cross-talk. Examples are described. Although there is some controversy surrounding the data, they are supported by the presence of leptin receptor mRNA in mouse and human oocytes and embryos throughout preimplantation development. Otherwise, the leptin mRNA is only detected at the blastocyst stage in both human and mouse. Furthermore, leptin is found at higher concentrations in the conditioned media from competent human blastocysts than in those from arrested embryos, suggesting that this molecule is a marker for blastocyst viability. Given that expression of the leptin receptor increases in the human endometrium during the luteal phase, the secreted leptin could trigger its activation. Finally, leptin and the leptin receptor have been detected in implantation sites. All these findings point to the involvement of the leptin system in the molecular mechanism of the implantation process and embryo development.

Leptin receptors are developmentally regulated in rat pituitary and hypothalamus

We have previously reported that leptin is expressed in adult rat brain and pituitary gland, though the role of leptin in these sites has not been determined. Leptin mRNA is developmentally regulated in the brain and pituitary of male and female rats during early postnatal development, suggesting a role in the maturation of the brain-pituitary system. Here, we sought to extend our previous studies by evaluating (1) the ontogeny of leptin receptor mRNA levels in rat brain and pituitary and (2) pituitary leptin protein levels in neonatal and pre-pubertal rats. Pituitary leptin concentration was highest shortly after birth (postnatal day (PD) 4, 25 ng/mg protein) and fell significantly throughout postnatal development and into adulthood (PD 60, 3.5 ng/mg protein; P<0.005) coincident with a decline in pituitary leptin mRNA levels. Significant age-related effects on leptin receptor mRNA levels were also observed in the pituitary and the hypothalamus of male and female rats using semi-quantitative RT-PCR analysis. In the pituitary, the short form (OBRa) mRNA levels were highest in neonatal rats (PD 4) but declined throughout postnatal development (PD 4-22) paralleling the fall in pituitary leptin mRNA and protein levels. The long form (OBRb) mRNA levels were unaffected by age between PD 4 and 22. In contrast, hypothalamic, levels of OBRb mRNA were very low to undetectable shortly after birth (PD 4) and rose significantly between PD 4 and 14/22 while levels of OBRa mRNA were not significantly different between PD 4 and 22. Immunohistochemical detection of leptin receptor immunoreactivity (all forms) revealed the presence of OBR-like protein in pituitary and hypothalamus as early as PD 4. Cortical leptin receptor mRNA levels were similar throughout early postnatal development. No gender-related differences in leptin receptor mRNA levels were noted in brain or pituitary. In conclusion, these data, together with our previous work, indicate that the neonatal pituitary gland expresses leptin and leptin receptors at levels far in excess of those observed in mature rats. The pituitary is thus quite different from adipose tissue, hypothalamus and cerebral cortex, in which neonatal leptin expression is lowest at birth. Since neonatal pituitary leptin receptor expression is also elevated, it is possible that pituitary-derived leptin plays some role in the development of the hypothalamic-pituitary system.

Significance of leptin expression in invasive potential of pituitary adenomas

We immunohistochemically examined the expression of leptin in pituitary adenomas to investigate the correlation between the invasiveness of tumours and leptin expression. The subjects consisted of 79 patients with pituitary adenoma and were classified into the following groups: (1) non-functioning adenomas; (2) GH-secreting adenomas; (3) prolactinomas; (4) ACTH-secreting adenomas; (5) others (LH, FSH or TSH-secreting adenomas). Thereafter all cases were subdivided according to the size of tumour and the presence of invasion to the surrounding tissue. Among non-functioning adenomas, there was no significant difference between invasive and non-invasive non-functioning adenoma. In functioning adenomas, a significant difference in leptin expression was noted in intrasellar non-invasive adenomas compared to other adenomas. There was also a significant difference in leptin expression between non-invasive and invasive adenomas regardless of size. These results suggest that leptin has a role in the invasive potential of functioning adenomas.

The release of leptin and its effect on hormone release from human pituitary adenomas

BACKGROUND

Leptin is the protein product of the obese gene, known to play an important role in body energy balance. The leptin receptor exists in numerous isoforms, the long isoform being the major form involved in signal transduction. Leptin expression has recently been demonstrated in the human pituitary, both in normal tissue and in pituitary adenomas. The long isoform of the leptin receptor has also been shown to be present in pituitary adenomas; however, contrasting results have been obtained regarding its expression in the normal human pituitary.

AIM

The aim of this study was (i) to investigate the presence and pattern of distribution of leptin mRNA and the long isoform of its receptor mRNA in the normal pituitary and in different types of pituitary adenomas with RT-PCR; (ii) to study leptin secretion from human pituitary tumours in culture and (iii) to assess in vitro pituitary hormone release following stimulation with human leptin.

RESULTS

Leptin receptor long isoform expression was detected in 2/4 GH-secreting adenomas, 12/17 non-functioning adenomas, 5/9 ACTH-secreting adenomas, 1/2 prolactinomas, 2/2 FSH-secreting adenomas and 5/5 normal pituitaries. The receptor long isoform did not segregate with any particular tumour type, and varying levels of expression were detected between the tissues studied. Leptin mRNA was detected at a low level of expression in 2/7 GH-secreting adenomas, 9/14 non-functioning adenomas, 2/3 ACTH-secreting adenomas, 1/3 prolactinomas and 1/3 FSH-secreting adenomas. We were unable to detect leptin mRNA in any of the five normal pituitaries removed at autopsy; however, immunostaining of a non-tumorous pituitary adjacent to an adenoma removed at transsphenoidal surgery showed scattered leptin positive cells. Culture of pituitary adenomas showed that 16/47 released leptin into the incubation media. Leptin release did not correlate with tumour type or with any of the other pituitary hormones released. In vitro leptin stimulation of pituitary tumours caused stimulation of FSH and alpha-subunit secretion from a non-functioning adenoma and TSH secretion from a somatotroph adenoma.

CONCLUSION

We conclude that not only is leptin stored within the pituitary, but it may also be released from pituitary cells and modulate other pituitary hormone secretion. Pituitary leptin may therefore be a novel paracrine regulator of pituitary function.

Regulation of metabolism and body fat mass by leptin

The relative stability of body weight over the long term and under a variety of environmental conditions that alter short-term energy intake and expenditure provides strong evidence for the regulation of body energy content. The lipostatic theory of energy balance regulation proposed 40 years ago that circulating factors, generated in proportion to body fat stores, acted as signals to the brain, eliciting changes in energy intake and expenditure. The discovery of leptin and its receptors has now provided a molecular basis for this theory. Leptin functions as much more than an adipocyte-derived signal of lipid stores, however. Although suppression of food intake is an important centrally mediated effect of leptin, considerable evidence indicates that leptin also functions both directly and indirectly, via the brain, to orchestrate complex metabolic changes in a number of organs and tissues, altering nutrient flux to favor energy expenditure over energy storage.

Leptin and the hypothalamic-pituitary regulation of the gonadotropin-gonadal axis

Leptin is an adipocyte-derived protein hormone which not only conveys a signal of the amount of energy stores to the central nervous system but also plays an important role in regulating neuroendocrine function. The importance of leptin in the reproductive system has been suggested by the reproductive dysfunction associated with leptin deficiency and resistance in both animal models and humans as well as the ability of leptin to accelerate the onset of reproductive function in normal mice. Transgenic mice overexpressing leptin also have accelerated puberty, and leptin administration reverses the fasting-induced suppression of sexual maturation in rodents, indicating that leptin may serve as the critical link between sufficient energy stores and proper functioning of the reproductive system. Normal women have a pulsatile release pattern of leptin that is significantly associated with the variations in luteinizing hormone (LH) and estradiol levels. In various animal models, leptin administration restores the LH pulsatility pattern which is suppressed during fasting, indicating a hypothalamic site of action since LH pulsatility is under the control of gonadotropin-releasing hormone (GnRH). In humans, leptin has been administered to a 9-year-old leptin-deficient girl, resulting in a gonadotropin secretory pattern consistent with early puberty. While in vitro experiments with hypothalamic explants and a GnRH-secreting neuronal cell line have shown that leptin can directly stimulate GnRH secretion, the lack of leptin receptors on GnRH neurons suggests that leptin may act through other hypothalamic neuropeptides. Several neuropeptides which act as downstream effectors of leptin have been investigated, and recent studies indicate that cocaine and amphetamine-regulated transcript may be such a mediator of leptin's effect on GnRH. Leptin receptors have also been identified in human pituitaries, and leptin may influence LH release from the pituitary. However, the current evidence is conflicting, and further studies are needed in order to clarify leptin's role at the level of the pituitary. Thus, accumulating evidence suggests that leptin can regulate gonadotropin levels, and its secretion may, in turn, be influenced by GnRH or gonadal steroids but appears to be independent of LH control.

Neuroendocrine effects of leptin

Leptin, the product of the obesity gene, is a cytokine-like circulating protein acting as a peripheral satiety signal to the hypothalamus. It was initially described as a secreted product of white adipose cells, but more recent data have demonstrated its expression by endocrine and neuroendocrine tissues like the ovary and the hypothalamus, as well as several anterior pituitary cell types. The effects of leptin on body weight homeostasis are mediated via different hypothalamic neurotransmitters regulating appetite and energy expenditure. In addition, leptin participates to the modulation of the activity of the neuroendocrine thyrotrope, somatotrope, corticotrope and gonadotrope axes. These endocrine effects of leptin have progressively emerged as important physiological functions of this molecule. Its role as a permissive factor for puberty and normal reproductive function in adulthood is becoming widely recognized. In addition, leptin participates in the fine tuning of the corticotrope axis. Thus, by signalling body fat stores to the hypothalamus and other endocrine organs, leptin serves as a metabolic integrator of several neuroendocrine functions. The precise site of action and mode of regulation of the gonadotrope and somatotrope axes by leptin are reviewed.

Pituitary leptin gene expression is reduced by neonatal androgenization of female rats

We have previously reported evidence of leptin gene expression (ob mRNA) in adult rat brain and pituitary gland. We have also shown that ob mRNA levels in female rat brain and pituitary are regulated in an age- and tissue-dependent fashion. In view of the known sexual dimorphism in adipose tissue leptin expression, we have extended our original work to include an assessment of ob mRNA levels in brain, pituitary and fat of developing male and female rats. In addition we determined the effects of neonatal androgenization of female rat pups with testosterone propionate. Leptin (ob) mRNA expression was evaluated using semi-quantitative RT-PCR analysis. Leptin mRNA levels were developmentally regulated in the pituitary and cortex of male rats, paralleling the changes previously observed in female rats. In the pituitary, leptin expression was significantly higher during the early postnatal period and dropped abruptly by postnatal day (PD) 22. In the cortex, leptin expression was lowest at PD 4 and rose significantly by PD 14. In addition gender differences, most notably in the pituitary, were also observed. In pituitary gland, ob mRNA was significantly higher in female rats than in males at PD 14 (+60%; p < 0.05) but there were no sex differences at PD 4 and PD 22. Testosterone treatment of neonatal female rats profoundly reduced ob mRNA at PD 14 (3.5-fold; p < 0.01) and PD 22 (3-fold; p = 0.05). In subcutaneous adipose tissue and hypothalamus we observed no sex difference in ob mRNA levels nor an effect of testosterone. We conclude that leptin gene expression in rat pituitary gland is sexually dimorphic and sensitive to neonatal manipulation of sex steroid levels.

Leptin and leptin receptor in anterior pituitary function

Leptin is a 16 kDa protein that exerts important effects on the regulation of food intake and energy expenditure by interacting with the leptin receptor in the brain and in many other tissues. Although leptin is produced mainly by white adipose tissue, several laboratories have shown low levels of leptin production by a growing number of tissues including the anterior pituitary gland. Many studies have implicated leptin in anterior pituitary function including the observation that homozygous mutations of the leptin receptor gene led to morbid obesity, lack of pubertal development and decreased GH and TSH secretion. In addition, leptin functions as a neuroendocrine hormone and regulates many metabolic activities. Leptin also interacts with and regulates the hypothalamic-pituitary-adrenal, the hypothalamic-pituitary-thyroid and the hypothalamic-pituitary-gonadal axes. All of the anterior pituitary cell types express the leptin receptor. However, leptin has been localized in specific subtypes of anterior pituitary cells indicating cell type-specific production of leptin in the anterior pituitary. Subcellular localization of leptin indicates co-storage with secretory granules and implicates hypothalamic releasing hormones in leptin secretion from anterior pituitary hormone cells. Leptin signal transduction in the anterior pituitary has been shown to involve the janus protein-tyrosine kinase (JAK)/signal transducer and activation of transcription (STAT) as well as suppressor of cytokine signalling (SOCS). These proteins are activated by tyrosine-phosphorylation in anterior pituitary cells. The various steps in pituitary leptin signal transduction remain to be elucidated.

Leptin signal transduction in the HP75 human pituitary cell line

Leptin is an adipocyte-derived cytokine with many functions including signaling the status of body energy stores through activation of the leptin receptor (OBR). Activation of the long form of OB-R (OB-Rb) results in JAK2 phosphorylation, activation of STATs, and subsequent gene expression. Activated STAT3 induces SOCS-3 expression in some cell types, which in turn down-regulates the JAK/STAT pathway. Although both leptin and OB-R are expressed in pituitary cells, the mechanism of signal transduction and its regulation in this organ has not been studied extensively. In these experiments we show that leptin reduces proliferation in a human pituitary cell line (HP75) and also increased apoptosis in these cells. Leptin also increased SOCS-3 mRNA and protein expression and tyrosine-phosphorylation in the HP75 human pituitary cell line. These findings suggest that SOCS-3 plays an important role in the inhibition of proximal leptin signal transduction in the anterior pituitary.

Long form leptin receptor mRNA expression in the brain, pituitary, and other tissues in the pig

Much effort has focused recently on understanding the role of leptin, the obese gene product secreted by adipocytes, in regulating growth and reproduction in rodents, humans and domestic animals. We previously demonstrated that leptin inhibited feed intake and stimulated growth hormone (GH) and luteinizing hormone (LH) secretion in the pig. This study was conducted to determine the location of long form leptin receptor (Ob-Rl) mRNA in various tissues of the pig. The leptin receptor has several splice variants in the human and mouse, but Ob-Rl is the major form capable of signal transduction. The Ob-Rl is expressed primarily in the hypothalamus of the human and rodents, but has been located in other tissues as well. In the present study, a partial porcine Ob-Rl cDNA, cloned in our laboratory and specific to the intracellular domain, was used to evaluate the Ob-Rl mRNA expression by RT-PCR in the brain and other tissues in three 105 d-old prepuberal gilts and in a 50 d-old fetus. In 105 d-old gilts, Ob-Rl mRNA was expressed in the hypothalamus, cerebral cortex, amygdala, thalamus, cerebellum, area postrema and anterior pituitary. In addition, Ob-Rl mRNA was expressed in ovary, uterine body, liver, kidney, pancreas, adrenal gland, heart, spleen, lung, intestine, bone marrow, muscle and adipose tissue. However, expression was absent in the thyroid, thymus, superior vena cava, aorta, spinal cord, uterine horn and oviduct. In the 50 d-old fetus, Ob-Rl mRNA was expressed in brain, intestine, muscle, fat, heart, liver and umbilical cord. These results support the idea that leptin might play a role in regulating numerous physiological functions.

Expression of the leptin receptor during germ cell development in the mouse testis

Leptin, a recently identified hormonal product of the ob gene, is known to regulate appetite, body metabolism, and reproductive functions. We investigated the expression of the leptin receptor (Ob-R) in testes from different age groups. The messenger RNA for Ob-R was found in testes from all age groups using RT-PCR. Using immunohistochemistry, we observed age- and stage-dependent distribution of the Ob-R in mouse testis. In testis of 5-day-old mice, its expression was mainly in type A spermatogonia. In the 20- and 30-day-old testis, Ob-R expression was in the spermatocytes; in the adult testis, it was specific to spermatocytes in stages IX and X of the cycle of the seminiferous epithelium. Five main immunoreactive proteins were detected using Western blot (220, 120, 90, 66, and 46 kDa). The 120-kDa protein was evident only in 20-day-old and older testes, whereas the 90-kDa band was present only in the 5- and 10-day-old testis. Leptin treatment induced phosphorylation of signal transducer and activator of transcription-3 in cultured seminiferous tubules from adult and 5-day-old testes. Our results show for the first time age- and stage-specific localization of a functional Ob-R in testicular germ cells. We hypothesize a direct role for leptin, through phosphorylation of signal transducer and activator of transcription-3, in proliferation and differentiation of germ cells, which may partially explain the infertility observed in leptin-deficient mice.

Effects of leptin on the response of rat pituitary-adrenocortical axis to ether and cold stresses

Leptin is a hormone mainly secreted by the adipose tissue, which acts through specific receptors widely distributed in the body tissues, including hypothalamopituitary-adrenal axis. We have investigated the effects of a subcutaneous bolus injection of 5 nmol/kg leptin on the pituitary-adrenocortical function in both normal and ether- or cold-stressed rats. Blood concentrations of ACTH, aldosterone and corticosterone were measured by specific RIA 2 or 4 h after the leptin injection. Leptin administration to normal rats resulted in significant rises in the blood levels of ACTH, aldosterone and corticosterone at 2 h, but not at 4 h. Ether and cold stresses markedly increased hormonal blood concentrations at both 2 and 4 h. Leptin magnified ACTH response to ether stress at 2 h, but depressed it at 4 h, and enhanced aldosterone response at 2 h, without affecting corticosterone response. Leptin increased ACTH response to cold stress at both 2 and 4 h, without altering aldosterone and corticosterone responses. In light of these findings, we conclude that: (i) leptin evokes a middle transient activation of the pituitary-adrenocortical axis of rats under basal conditions; (ii) leptin inhibits the ACTH response to ether stress, but magnifies that to cold stress; and (iii) the leptin-evoked changes in the blood level of ACTH are not paralleled by significant modifications in the secretory activity of the adrenal cortex, which probably undergoes a maximal stimulation under stressful conditions.

Leptin prolonged administration inhibits the growth and glucocorticoid secretion of rat adrenal cortex

Leptin is an adipose-tissue secreted hormone, that acts to decrease caloric intake and to increase energy expenditure. Some of the leptin effects on the energy balance are known to be mediated by the hypothalamo-pituitary-adrenal (HPA) axis, but the role of this cytokine in the regulation of the growth and steroidogenic capacity of adrenal cortex is still controversial. Therefore, the present study was designed to explore the long-term effects of native leptin[1-147] and its biologically active fragment leptin[116-130] (6 daily subcutaneous injection of 20 nmol/kg) on the rat HPA axis. Leptin[1-147] and leptin[116-130] caused a significant adrenal atrophy, which was mainly due to the decrease in the volume of zona fasciculata (ZF) and in the number of its parenchymal cells. Both leptins provoked a marked drop in the plasma concentrations of ACTH and corticosterone, the main hormone produced by ZF cells. The effects of leptin[116-130] were more intense than those of leptin[1-147]. Leptin[1-147], but not its fragment, evoked a clear-cut rise in the plasma concentration of aldosterone. Collectively, these findings indicate that prolonged leptin administration, by inhibiting pituitary ACTH release, exerts a potent suppressive action on the growth and glucocorticoid secretory capacity of the adrenal cortex in the rat. The mechanism(s) underlying the aldosterone secretagogue action of native leptin remain(s) to be investigated.

Effects of recombinant murine leptin[1-147] and leptin fragment 116-130 on steroid secretion and proliferative activity of the regenerating rat adrenal cortex

Leptin, the product of the ob gene, is a hormone mainly secreted by the adipose tissue, which acts through specific receptors (Ob-R) widely distributed in the body tissues. Ob-Rs are present in the mammalian hypothalamo-pituitary-adrenal axis, and evidence indicates that leptin regulates adrenocortical secretion. Moreover, leptin is known to act as a growth promoting factor in some tissues, including the endocrine ovary. We have investigated the effects of three subcutaneous injections of 2 nmol/100 g of native murine leptin[1-147] and of its biologically active fragment 116-130 on the secretory and proliferative activity of the regenerating rat adrenal cortex. Leptin[1-147] increased plasma aldosterone concentration at day 8 and plasma corticosterone concentration (PBC) at day 5 of regeneration, without affecting mitotic index. In contrast, leptin[116-130] lowered PBC and mitotic index at both times of adrenal regeneration. In light of the fact that adrenal regeneration is at least in part dependent on the pituitary ACTH, we conclude that: (i) native leptin moderately stimulates steroid secretion, acting directly on the adrenal cortex, through signaling mechanisms other than those involved in the ACTH action; (ii) native leptin is unable to enhance the proliferative activity of regenerating adrenals, which conceivably is maximally stimulated by ACTH; (iii)leptin[1-147] and leptin[116-130] differently interact with Ob-Rs or interact with different receptors; and (iv) leptin[116-130] inhibits the signaling pathways mediating both the secretagogue effect of native leptin and the proliferogenic effect of ACTH.

Leptin and leptin receptor expression in normal and neoplastic human pituitary: evidence of a regulatory role for leptin on pituitary cell proliferation

Leptin is a circulating hormone secreted by adipose and a few other tissues. The leptin receptor consists of a single transmembrane-spanning polypeptide that is present as a long physiologically important form as well as in several short isoforms. Recent studies have suggested that the anterior pituitary may have a role in the regulatory effects of leptin in animal models. To test this possibility in human pituitaries, we examined the expression of leptin and OB-R in normal and neoplastic pituitaries, and the possible functions of leptin in the pituitary were also analyzed. Leptin was present in 20-25% of anterior pituitary cells and was expressed in most normal anterior pituitary cells, including ACTH (70% of ACTH cells), GH (21%), FSH (33%), LH (29%), TSH (32%), and folliculo-stellate cells (64%), but was colocalized with very few PRL cells (3%), as detected by double labeling immunohistochemistry with two different antileptin antibodies. In addition, leptin expression was detected by RT-PCR in some pituitary tumors, including ACTH (three of four), GH (one of four), null cells (two of four), and gonadotroph (one of four) tumors as well as in normal pituitary. Immunohistochemical staining showed greater immunoreactivity for leptin in normal pituitaries compared to adenomas. Treatment of an immortalized cultured anterior pituitary cell line, HP75, with leptin stimulated pancreastatin secretion in vitro. Leptin also inhibited cell growth in the human HP75 and in the rat pituitary GH3 cell lines. Both long (OB-Rb) and common (OB-Ra) forms of the leptin receptor messenger ribonucleic acid and leptin receptor protein were expressed in normal and neoplastic anterior pituitary cells. These findings show for the first time that leptin is expressed by most human anterior pituitary cell types and that there is decreased leptin protein immunoreactivity in pituitary adenomas compared to that in normal pituitary tissues. We also show that OB-Rb is widely expressed by normal and neoplastic anterior pituitary cells, implicating an autocrine/paracrine loop in the production and regulation of leptin in the pituitary.