Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-22T16:32:14.311Z Has data issue: false hasContentIssue false
  • English
  • Français

Adiponectin, the controversial hormone

Published online by Cambridge University Press:  01 October 2007

Marta Garaulet ,
Juan J Hernández-Morante ,
Fátima Pérez de Heredia  and
Francisco J Tébar
Marta Garaulet*
Affiliation:
Department of Physiology, Faculty of Biology, University of Murcia, Campus de Espinardo, s/n. 30100, Murcia, Spain
Juan J Hernández-Morante
Affiliation:
Department of Physiology, Faculty of Biology, University of Murcia, Campus de Espinardo, s/n. 30100, Murcia, Spain
Fátima Pérez de Heredia
Affiliation:
Department of Physiology, Faculty of Biology, University of Murcia, Campus de Espinardo, s/n. 30100, Murcia, Spain
Francisco J Tébar
Affiliation:
Department of Endocrinology and Nutrition, University Hospital ‘Virgen de la Arrixaca’, Murcia, Spain
*
Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To discuss present knowledge about adiponectin hormone.

Design

Review of existing literature.

Setting and results

Adiponectin is one of the most interesting cytokines associated with obesity, although its physiological role remains to be fully clarified. Adiponectin is a 247-amino acid protein that contains four differentiable domains. Contrary to most adipose-related cytokines, adiponectin levels are surprisingly lower in obese than in lean humans. Women have been found to have significantly higher adiponectin plasma concentrations than men. Further research is needed in order to identify new polymorphisms which contribute to explain the potential role of adiponectin in obesity and related pathologies.

Considering the anti-inflammatory properties of adiponectin and the fact that it is negatively associated with adiposity, this cytokine could be one of the links between obesity and inflammation. The main mechanisms of action of adiponectin are directed to a protective role against atherogenic and insulin resistance processes. Research has revealed interesting new functions far beyond metabolism, such as immunity, cancer and bone formation.

Contrary to all adipose-related proteins, adiponectin decreases with obesity. Most of the contradictory data surrounding adiponectin are related to plasma values and their relationship with body fat, gender differences and insulin resistance. There are important confounding results regarding the mechanisms of action and functions of adiponectin, especially in relation to insulin resistance and inflammation.

Keywords

AdiponectinCytokinesObesityInflammationAdipose tissue
Type
Original Article
Information
Public Health Nutrition , Volume 10 , Issue 10A , October 2007 , pp. 1145 - 1150
Copyright
Copyright © The Authors 2007

Only in the last decade, more than 2000 scientific articles have been published about one of the most interesting cytokines associated with obesity: Adiponectin. Its interest is mainly based on the novelty of this hormone, on its high production in the adipose tissue (adiponectin is also called ApM1, i.e., adipose most abundant gene transcript 1) and on its protective role in the different alterations associated with obesity, such as insulin resistance and inflammationReference Gil-Campos, Canete and Gil1. This cytokine in a certain way can be considered as the ‘guardian angel’ against the pathophysiology of obesity.

However, the physiological role of adiponectin remains to be fully clarified, since many of the results obtained are contradictory. Furthermore, some crucial points must be considered when investigating this hormone. First of all, it is important to take into account the different configurations circulating in plasma, and the fact that depending on the analytic method used, we may be detecting one of these configurations, and not total adiponectin. On the other hand, there are still remaining questions about the nature, specificity and actions of the receptors for adiponectin.

In the present review, all these topics will be commented, beginning with the name and the structural and biochemical characteristics of adiponectin; later, we will describe its relationship with obesity, insulin resistance and other alterations such as inflammation and atherosclerosis; finally, we will introduce the recently discovered functions of adiponectin and focus on the controversial aspects of this surprising hormone.

The name

In the same way the name of a person can provide information about them, so also with hormones. Some of the most characteristic features of a protein lie behind its name. Who has selected it and for what reasons? What is implicit in the name?

In the case of adiponectin, the name has varied with time, among different research groups, or because of the species in which the protein was found. Adiponectin was discovered almost simultaneously by four different research groups. In 1995, Scherer et al.Reference Scherer, Williams, Fogliano, Baldini and Lodish2 identified the protein by cDNA cloning from the mouse adipocyte cell line 3T3-L1 and named it Acrp30, which means ‘adipose complement-related protein of 30 kDa’, because of its high similarity to the complement protein family. Practically, at the same time, Hu et al.Reference Chandran, Phillips, Ciaraldi and Henry3, using the 3T3-F442A adipocyte cell line, also isolated the protein, and called it AdipoQ. Both names are still used when referring to this protein in miceReference Chandran, Phillips, Ciaraldi and Henry4.

In humans, a group of Japanese researchers described an adipose-specific gene from a cDNA library, which was curiously the most abundant transcript found in human adipose tissue, so they named it ApM1 (‘adipose most abundant gene transcript 1’). Nakano et al.Reference Nakano, Tobe, Choi-Miura, Mazda and Tomita5 isolated the protein as well, by high-affinity chromatography, and named it GBP-28 (gelatin-binding protein of 28 kDa). The gene product was predicted to be a kind of matrix protein synthesised by adipose tissue, so in 1999 Arita et al.Reference Arita, Kihara, Ouchi, Takahashi, Maeda and Miyagawa6 decided to call it adiponectinReference Chandran, Phillips, Ciaraldi and Henry4. The use of these five different names (Acrp 30, adipoQ, ApM1, GBP28 and adiponectin) makes it highly confusing to obtain information about this protein. Nowadays, ‘adiponectin’ is the most commonly accepted name and therefore we will use it throughout this review.

The protein and its activity

Adiponectin is a 247-amino acid protein, which contains four differentiable domains: an amino-terminal signal sequence and a variable region, with no homology to any other known protein, a collagenous domain, and a carboxy-terminal globular domain. The monomeric (30 kDa) form of adiponectin is thought to appear only in the adipocyte, since it has not yet been detected in the circulation. The most abundant configuration of adiponectin is the trimer, formed by a strong association between three monomers at their globular domains (Fig. 1). Trimers themselves associate through their collagenous domains, in groups of four to six, resulting in higher molecular weight oligomersReference Chandran, Phillips, Ciaraldi and Henry4. There is still a fourth possible configuration for adiponectin, the globular one. It is the result of a cleavage of the adiponectin monomer, and maintains the ability of trimerising, although higher order structures cannot be formedReference Chandran, Phillips, Ciaraldi and Henry4. The globular portion of adiponectin appears to be as efficient as full-length adiponectin at lowering serum glucose and free fatty acid levels, at least in miceReference Berg, Combs, Du, Brownlee and Scherer7. Regarding oligomers, the interactions among globular and collagenous domains seem to confer stability and to determine their activity, even though the precise molecular mechanisms underlying these associations of adiponectin trimers are not known.

Fig. 1 Different configurations of adiponectin

In plasma, the protein circulates mainly in two forms: hexamers of relatively low molecular weight (LMW) and larger multimeric structures of high molecular weight (HMW). It is likely for them to have different properties and actions, but it has been suggested that it is the ratio between them (HMW/LMW), rather than their respective concentrations, which determines adiponectin physiological activityReference Pajvani, Hawkins, Combs, Rajala, Doebber and Berger8.

Plasma values

Adiponectin is really abundant in plasma, at concentrations ranging from 5 to 30 μg ml−1, thus accounting for 0.01% of total plasma proteinsReference Gil-Campos, Canete and Gil1. This concentration is higher than that of most hormones; indeed, leptin and cortisol values are a thousand times lower, in the order of ng ml−1, while tumour necrosis factor alpha (TNF-α) or interleukin (IL)-6 are measured in pg ml−1 (10−6 times lower than adiponectin).

Contrary to most adipose-related cytokines (leptin, adipsin, resistin, IL-6, etc.), adiponectin levels are surprisingly lower in obese than in lean humans. It has been generally accepted that adiponectin decreases with obesityReference Ryan, Berman, Nicklas, Sinha, Gingerich and Meneilly9, although there are still studies that find no significant associations between body mass index and adiponectin plasma valuesReference Skurk, van Harmelen, Lee, Wirth and Hauner10, Reference Hernandez-Morante, Milagro, Gabaldon, Martinez, Zamora and Garaulet11. In addition, it is interesting to highlight that women have been found to have significantly higher adiponectin plasma concentrations than menReference Chandran, Phillips, Ciaraldi and Henry4. These data are surprising considering that women have a higher body fat content than men and, as it has been already commented, adiponectin is negatively associated with body fat percentage. Adiponectin plasma levels appear to depend on body fat distributionReference Staiger, Tschritter, Machann, Thamer, Fritsche and Maerker12, which in turn is strongly affected by sex hormones; thus, the involvement of sex steroids could be a possible explanation of this paradoxical relationship between adiponectin plasma values and gender. In this way, some studies have shown an inverse relationship between androgens and adiponectin plasma values. Furthermore, our own research group has observed a dehydroepiandrosterone and its sulphate (DHEAS)-induced up-regulation of adiponectin gene expression in adipocytesReference Hernandez-Morante, Milagro, Gabaldon, Martinez, Zamora and Garaulet11.

The gene and its expression

To fully understand a protein, it is important to have a deep knowledge of its gene, the characteristics, the expression and the different polymorphisms that may affect the function of the protein.

One of the most significant characteristics of human adiponectin gene is its localisation: it spans 17 kb on chromosome 3, locus 3q27. This locus is of special interest, since it is associated with the susceptibility to type 2 diabetes and cardiovascular disease, two alterations highly interrelated with adiponectin protective roleReference Vionnet, Hani, Dupont, Gallina, Francke and Dotte13. Analysis of the gene structure has been extensively described by Takahashi et al.Reference Takahashi, Arita, Yamagata, Matsukawa, Okutomi and Horie14 in 2000. It consists of three exons and two introns, which coincides with the gene structure of the anti-obesity protein par excellence, leptin.

During the last years, it has been defended that the expression of adiponectin is confined to adipose tissue. Recently, some studies have demonstrated that other tissues such as bone, mammary glands, salivary glands, etc. are able to express adiponectin, although in a minimum quantityReference Berner, Lyngstadaas, Spahr, Monjo, Thommesen and Drevon15Reference Katsiougiannis, Kapsogeorgou, Manoussakis and Skopouli17.

Perhaps one of the most exciting subjects in protein research is the identification of different polymorphisms on its gene. Indeed, many studies support that polymorphisms are associated with alterations of the protein function or even with important related diseases. In the case of adiponectin, 16 polymorphisms have been described in its gene, although only a reduced part has clinical implications. In the study of Takahashi et al. Reference Takahashi, Arita, Yamagata, Matsukawa, Okutomi and Horie14, two polymorphisms, one occurring in exon 2 and the other being a missense mutation in exon 3, were associated to markedly low plasma adiponectin concentrations. Menzaghi et al.Reference Menzaghi, Ercolino, Di Paola, Berg, Warram and Scherer18 have also found two single-nucleotide polymorphisms (SNP) associated with high risk of type 2 diabetes. Another SNP, which cause no change in the protein, is associated with obesity, insulin resistance and dyslipidaemiaReference Kondo, Shimomura, Matsukawa, Kumada, Takahashi and Matsuda19. Further research is needed in order to identify new polymorphisms, which contribute to explain the potential role of adiponectin in obesity and related pathologies.

The adiponectin receptors

Since adiponectin was first described in 1995, a receptor-mediated activity was postulated. Paradoxically, the mechanism of action of the hormone was described previously to receptor identificationReference Yamauchi, Kamon, Minokoshi, Ito, Waki and Uchida20.

In 2003, Yamauchi et al.Reference Katsiougiannis, Kapsogeorgou, Manoussakis and Skopouli21 isolated and described for the first time human and mouse adiponectin receptors, transforming the understanding of several actions of this hormone. The two receptors, designated AdipoR1 and AdipoR2, are abundantly synthesised in skeletal muscle and liver, respectively, but they are ubiquitously expressed. In fact, adiponectin receptors have been detected in pancreatic β-cells, macrophages, osteoblast-like cells and othersReference Scherer, Williams, Fogliano, Baldini and Lodish22, Reference Chinetti, Zawadski, Fruchart and Staels23. Experiments of overexpression and/or suppression of receptor activity demonstrated that both AdipoR1 and AdipoR2 bind globular and full-length adiponectin, but with different affinities. Nowadays, we know that AdipoR1 is a high-affinity receptor for globular adiponectin and a low-affinity receptor for full-length adiponectin. In contrast, AdipoR2 is an intermediate-affinity receptor for both formsReference Yamauchi, Kamon, Ito, Tsuchida, Yokomizo and Kita21. In 2004, a third receptor for adiponectin was proposed: T-cadherin, a member of the cadherin superfamily, a group of proteins involved in cell adhesion and signalling. It is thought to bind hexamers and high-molecular-weight adiponectin oligomersReference Yamauchi, Kamon, Minokoshi, Ito, Waki and Uchida24.

The existence of these two distinct natures of adiponectin receptors can be explained by the variety of adiponectin structures – trimers, hexamers, HWM oligomers – which require different receptor conformations to ensure a high binding affinity, and by the wide tissue distribution of adiponectin actions.

The family and the functions

Knowing the characteristics of a family usually helps to understand the individual. Concerning adiponectin, its three-dimensional structure reminds of that from other proteins and cytokines, throwing a little light on the actions and characteristics of this hormone (Fig. 2).

Fig. 2 Adiponectin structure (by courtesy of 10-year-old Olga Albasini-Garaulet)

What is of interest in adiponectin structure is its collagen-like domain, responsible for oligomerisation, and the globular domain with high homology to some factors from the alternate pathway of the complement system. The complement system is a complex protein activation cascade that participates in immune defense, and the alternate pathway is related to natural immunity, which acts through direct interaction between macrophages and pathogens, without the involvement of antibodies. On the basis of both its primary amino acid sequence and its C-terminal domain structure, adiponectin is most similar to complement protein C1q. However, X-ray crystallography of the globular fragment of adiponectin also reveals a striking structural homology to TNF-αReference Chandran, Phillips, Ciaraldi and Henry4.

Taking into account this similarity between adiponectin and immune-related proteins, the question arose as to whether it would play a role in immunity. Further studies have shown that the globular domain confers interesting immune actions to this proteinReference Tilg and Moschen24.

The guardian angel

Adiponectin is capable, like the proteins of the complement system, of interacting with immune cells, such as macrophages and monocytes. In macrophages, it suppresses the production and secretion of TNF-α and IL-6, and the formation of foam cells; it also prevents monocytes precursors from differentiating, and monocytes themselves from adhering to vascular walls; and enhances the production of anti-inflammatory cytokines by monocytes, macrophages and dendritic cellsReference Tilg and Moschen24. There is a growing number of studies considering obesity as a state of low-grade but chronic inflammation. Considering the anti-inflammatory properties of adiponectin and the fact that it is negatively associated with adiposity, this cytokine could be one of the links between obesity and inflammation.

On the other hand, adiponectin has been called ‘fat-burning molecule’, because it is able to redirect fatty acids to the muscle for their oxidation. This special capability is of great interest, because the influx of fatty acids to the liver decreases, and so does total trilglyceride content, leading to a higher insulin-sensitivity state.

The main mechanisms of action of adiponectin are all directed to the same finality, a protective role against atherogenic and insulin resistance processes, one of the reasons why adiponectin is considered as a ‘guardian angel’ in the metabolic syndrome.

New discoveries in adiponectin

After the discovery of adiponectin in 1995, research has revealed interesting new functions far beyond metabolism, such as immunity, cancer and bone formation.

Adiponectin and bone formation

A link between adiponectin and bone homoeostasis was first described by Berner et al. Reference Berner, Lyngstadaas, Spahr, Monjo, Thommesen and Drevon15. These authors observed that both adiponectin and its receptors, AdipoR1 and AdipoR2, were expressed and secreted in bone-forming cells. They also demonstrated that adiponectin addition to osteoblast cultures stimulated cell proliferation. Conversely, a recent study of Shinoda et al. Reference Shinoda, Yamaguchi, Ogata, Akune, Kubota and Yamauchi25 has shown the opposite effect. In this work, the addition of adiponectin suppressed osteogenesis. In consequence, although adiponectin clearly acts on bone metabolism, the precise mechanism of action remains unclear.

Adiponectin and endometrium

Adiponectin receptors have been also detected in the endometriumReference Kharroubi, Rasschaert, Eizirik and Cnop26, where it decreases interleukin and chemoattractant production from endometrial stromal cells. Furthermore, patients with endometrial cancer show serum adiponectin levels significantly lower than controlsReference Soliman, Wu, Tortolero-Luna, Schmeler, Slomovitz and Bray27.

Adiponectin and cancer

The association between low levels of adiponectin and cancer has been once again observed in patients with breast and prostate cancerReference Kelesidis, Kelesidis and Mantzoros28. In vitro, adiponectin inhibits tumour growth in mice, probably through suppression of neo-vascularisation, a key process for tumourigenesisReference Brakenhielm, Veitonmaki, Cao, Kihara, Matsuzawa and Zhivotovsky29.

Adiponectin and adipose tissue

Adipose tissue itself is a target for adiponectin activity. Overexpression of adiponectin gene in 3T3-L1 cells has been shown to stimulate cell proliferation and differentiationReference Fu, Luo, Klein and Garvey30.

The actions of adiponectin span other tissues

Adiponectin has been associated with platelet activityReference Takahashi, Ushida, Komine, Shimizu, Uchida and Ishihara31, and it has been even proposed as a regulator of β-cell proliferation, in a cooperative mechanism associated with leptinReference Huypens32. There is no doubt that innovative research is necessary to provide and identify the different and tissue-specific actions of this pleiotropic hormone.

The controversial hormone

Throughout the present review we have highlighted several controversial aspects of adiponectin, which affect the protein structure, its receptors and plasma values, and in consequence, the main functions exerted by the hormone.

Perhaps the most striking paradox related to this protein is that, contrary to all adipose-related proteins, adiponectin decreases with obesity. This fact is even more surprising when considering the fact that adiponectin is the most secreted protein in adipose tissue, so it would be expected to increase proportionally to body fat. One possible explanation is that although adiponectin expression is activated during adipogenesis, a feedback inhibition on its production may occur during the development of obesity. For example, adiponectin expression and secretion in adipocytes has been shown to be reduced by TNF-αReference Tilg and Moschen24. Therefore, the adipocytokines that are increased in obesity could be contributing to the decreased adiponectin production.

Most of the contradictory data surrounding adiponectin are related to plasma values and their relationship with body fat, gender differences and insulin resistance. Additionally, there are important confounding results regarding the mechanisms of action and functions of adiponectin, especially in relation to insulin resistance and inflammation.

The lack of a direct relationship between adipose tissue adiponectin expression and plasma concentrations as observed by some authorsReference Hernandez-Morante, Milagro, Gabaldon, Martinez, Zamora and Garaulet11, Reference Garaulet, Viguerie, Porubsky, Klimcakova, Clement and Langin33 is controversial. Another paradox is that, in general, women show significantly higher adiponectin levels than men, despite having higher body fat content. In addition, results about the relationship between plasma adiponectin and insulin are contradictory; although adiponectin is supposed to lower hyperinsulinemiaReference Gil-Campos, Canete and Gil1, there are works in which no significant correlations have been found between both hormones. Indeed, in a work performed by our own group in obese women, we did not observe any relationship between both hormones in the total population. However, when we divided our subjects attending to body fat distribution, an inverse correlation was found between adiponectin and insulin only in women with a gluteo-femoral fat distributionReference Garaulet, Viguerie, Porubsky, Klimcakova, Clement and Langin33.

Regarding adiponectin actions, we have already mentioned in the present review that both globular and full-length adiponectin are efficient in ameliorating hyperinsulinemia and hyperglycaemiaReference Gil-Campos, Canete and Gil1. However, this affirmation is in disagreement with the observations of Berg et al.Reference Berg, Combs, Du, Brownlee and Scherer7, whereby injection of bacterially produced globular adiponectin into mouse models of diabetes did not induce a decrease in serum glucose, even though the full-length form did.

In addition, the physiological action of adiponectin in immunity and inflammation is not, to our surprise, as clear as it seems, since it can also exert proinflammatory actions. In some cases, adiponectin stimulates the secretion of chemotactic factors and, even more remarkable, it increases IL-6 production in human adipocytesReference Tilg and Moschen24.

Is there an explanation for these paradoxical results?

It has been postulated that the different adiponectin conformations exert diverse effects in various tissues. For instance, trimers seem to be responsible for the insulin-sensitising action of adiponectin in skeletal muscle, while hexamers would be acting in the liver. In addition, it has been suggested that the high-molecular-weight form of adiponectin is responsible for its proinflammatory actions, while the low-molecular-weight form would be the anti-inflammatory oneReference Tilg and Moschen24. These findings highlight the importance of considering adiponectin oligomerisation when studying its properties and functions.

On the other hand, not only the different adiponectin forms determine its action but also the participation of the different receptors is of high relevance. More information is needed regarding their types and structures, their tissue distribution and, above all, the particular affinities of these receptors for the various adiponectin configurations, i.e., trimers, hexamers and HMW oligomers.

Perhaps the main problem in the interpretation of data regarding the relationships between adiponectin concentrations, obesity, insulin resistance and inflammation, is the fact that we really do not know what we are actually measuring in plasma when using standardised analytic techniques such as enzyme-linked immunosorbent assay (ELISA) or radioimmunoassay (RIA). The key point is to know if we are detecting the trimer, the hexamer, larger multimeric structures or total adiponectin. But first of all, we must determine what we are really looking for. In the near future, we will be able to measure the distinct adiponectin structures in plasma depending on the function to be studied. In our opinion, these technical handicaps are obstructing the comprehension and interpretation of adiponectin functions and mechanisms of action. A most specific research on this hormone will allow us to avoid all these contradictory data surrounding adiponectin.

Acknowledgements

Sources of funding:This work was supported by the Seneca Foundation from the Government of Murcia (Project 02934/P1/05 to M.G.).

Conflict of interest declaration:The authors have nothing to disclose.

Authorship contributions:All the authors have contributed in the redaction of the present review.

References

1Gil-Campos, M, Canete, RR, Gil, A. Adiponectin, the missing link in insulin resistance and obesity. Clinical Nutrition 2004; 23: 963974.CrossRefGoogle ScholarPubMed
2Scherer, PE, Williams, S, Fogliano, M, Baldini, G, Lodish, HF. A novel serum protein similar to C1q produced exclusively in adipocytes. Journal of Biological Chemistry 1995; 270: 2674626749.CrossRefGoogle ScholarPubMed
3Hu, E, Liang, P, Spiegelman, BM. AdipoQ is a novel adipose-specific gene dysregulated in obesity. Journal of Biological Chemistry 1996; 271: 1069710703.CrossRefGoogle ScholarPubMed
4Chandran, M, Phillips, SA, Ciaraldi, T, Henry, RR. Adiponectin: more than just another fat cell hormone? Diabetes Care 2003; 26: 24422450.CrossRefGoogle ScholarPubMed
5Nakano, Y, Tobe, T, Choi-Miura, NH, Mazda, T, Tomita, M. Isolation and characterization of GBP28, a novel gelatin-binding protein purified from human plasma. Journal of Biochemistry 1996; 120: 803812.CrossRefGoogle ScholarPubMed
6Arita, Y, Kihara, S, Ouchi, N, Takahashi, M, Maeda, K, Miyagawa, J, et al. . Paradoxical decrease of an adipose-specific protein, adiponectin, in obesity. Biochemical and Biophysical Research Communications 1999; 257: 7983.CrossRefGoogle ScholarPubMed
7Berg, AH, Combs, TP, Du, X, Brownlee, M, Scherer, PE. The adipocyte-secreted protein Acrp30 enhances hepatic insulin action. Nature Medicine 2001; 7: 947953.CrossRefGoogle ScholarPubMed
8Pajvani, UB, Hawkins, M, Combs, TP, Rajala, MW, Doebber, T, Berger, JP, et al. . Complex distribution, not absolute amount of adiponectin, correlates with thiazolidinedione-mediated improvement in insulin sensitivity. Journal of Biological Chemistry 2004; 279: 1215212162.CrossRefGoogle Scholar
9Ryan, AS, Berman, DM, Nicklas, BJ, Sinha, M, Gingerich, RL, Meneilly, GS, et al. . Plasma adiponectin and leptin levels, body composition, and glucose utilization in adult women with wide ranges of age and obesity. Diabetes Care 2003; 26: 23832388.CrossRefGoogle ScholarPubMed
10Skurk, T, van Harmelen, V, Lee, YM, Wirth, A, Hauner, H. Relationship between IL-6, leptin and adiponectin and variables of fibrinolysis in overweight and obese hypertensive patients. Hormone and Metabolism Research 2002; 34: 659663.CrossRefGoogle ScholarPubMed
11Hernandez-Morante, JJ, Milagro, F, Gabaldon, JA, Martinez, JA, Zamora, S, Garaulet, M. Effect of DHEA-sulfate on adiponectin gene expression in adipose tissue from different fat depots in morbidly obese humans. European Journal of Endocrinology 2006; 155: 593600.CrossRefGoogle ScholarPubMed
12Staiger, H, Tschritter, O, Machann, J, Thamer, C, Fritsche, A, Maerker, E, et al. . Relationship of serum adiponectin and leptin concentrations with body fat distribution in humans. Obesity Research 2003; 11: 368372.CrossRefGoogle ScholarPubMed
13Vionnet, N, Hani, El-H, Dupont, S, Gallina, S, Francke, S, Dotte, S, et al. . Genome wide search for type 2 diabetes susceptibility genes in French whites: evidence for a novel susceptibility locus for early onset diabetes on chromosome 3q27-qter and independent replication of a type 2 diabetes locus on chromosome 1q21–q24. American Journal of Human Genetics 2000; 67: 14701480.CrossRefGoogle Scholar
14Takahashi, M, Arita, Y, Yamagata, K, Matsukawa, Y, Okutomi, K, Horie, M, et al. . Genomic structure and mutations in adipose-specific gene, adiponectin. International Journal of Obesity 2000; 24: 861868.CrossRefGoogle ScholarPubMed
15Berner, HS, Lyngstadaas, SP, Spahr, A, Monjo, M, Thommesen, L, Drevon, CA, et al. . Adiponectin and its receptors are expressed in bone-forming cells. Bone 2004; 35: 842849.CrossRefGoogle ScholarPubMed
16Martin, LJ, Woo, JG, Geraghty, SR, Altaye, M, Davidson, BS, Banach, W, et al. . Adiponectin is present in human milk and is associated with maternal factors. American Journal of Clinical Nutrition 2006; 83 (5): 11061111.CrossRefGoogle ScholarPubMed
17Katsiougiannis, S, Kapsogeorgou, EK, Manoussakis, MN, Skopouli, FN. Salivary gland epithelial cells: a new source of the immunoregulatory hormone adiponectin. Arthritis and Rheumatism 2006; 54 (7): 22952299.CrossRefGoogle ScholarPubMed
18Menzaghi, C, Ercolino, T, Di Paola, R, Berg, AH, Warram, JH, Scherer, PE, et al. . A haplotype at the adiponectin locus is associated with obesity and other features of the insulin resistance syndrome. Diabetes 2002; 51: 23062311.CrossRefGoogle ScholarPubMed
19Kondo, H, Shimomura, I, Matsukawa, Y, Kumada, M, Takahashi, M, Matsuda, M, et al. . Association of adiponectin mutation with type 2 diabetes. A candidate gene for the insulin resistance syndrome. Diabetes 2002; 51: 23252328.CrossRefGoogle ScholarPubMed
20Yamauchi, T, Kamon, J, Minokoshi, Y, Ito, Y, Waki, H, Uchida, S, et al. . Adiponectin stimulates glucose utilization and fatty-acid oxidation by activating AMP-activated protein kinase. Nature Medicine 2002; 8: 12881295.CrossRefGoogle ScholarPubMed
21Yamauchi, T, Kamon, J, Ito, Y, Tsuchida, A, Yokomizo, T, Kita, S , et al. . Cloning of adiponectin receptors that mediate antidiabetic metabolic effects. Nature 2003; 423: 762769.CrossRefGoogle ScholarPubMed
22Kharroubi, I, Rasschaert, J, Eizirik, DL, Cnop, M. Expression of adiponectin receptors in pancreatic beta cells. Biochemical and Biophysical Research Communications 2003; 312: 11181122.CrossRefGoogle ScholarPubMed
23Chinetti, G, Zawadski, C, Fruchart, JC, Staels, B. Expression of adiponectin receptors in human macrophages and regulation by agonists of the nuclear receptors PPARα, PPARγ, and LXR. Biochemical and Biophysical Research Communications 2004; 314: 151158.CrossRefGoogle ScholarPubMed
24Tilg, H, Moschen, AR. Adipocytokines: mediators linking adipose tissue, inflammation and immunity. Nature 2006; 6: 772783.Google ScholarPubMed
25Shinoda, Y, Yamaguchi, M, Ogata, N, Akune, T, Kubota, N, Yamauchi, T, et al. . Regulation of bone formation by adiponectin through autocrine/paracrine and endocrine pathways. Journal of Cell Biochemistry 2006; 99: 196208.CrossRefGoogle ScholarPubMed
26Takemura, Y, Osuga, Y, Yamauchi, T, Kobayashi, M, Harada, M, Hirata, T, et al. . Expression of adiponectin receptors and its possible implication in the human endometrium. Endocrinology 2006; 147 (7): 32033210.CrossRefGoogle ScholarPubMed
27Soliman, PT, Wu, D, Tortolero-Luna, G, Schmeler, KM, Slomovitz, BM, Bray, MS, et al. . Association between adiponectin, insulin resistance, and endometrial cancer. Cancer 2006; 106 (11): 23762381.CrossRefGoogle ScholarPubMed
28Kelesidis, I, Kelesidis, T, Mantzoros, CS. Adiponectin and cancer: a systematic review. British Journal of Cancer 2006; 94: 12211225.CrossRefGoogle ScholarPubMed
29Brakenhielm, E, Veitonmaki, N, Cao, R, Kihara, S, Matsuzawa, Y, Zhivotovsky, B, et al. . Adiponectin-induced antiangiogenesis and antitumor activity involve caspase-mediated endothelial cell apoptosis. Proceedings of the National Academy of Sciences of the United States of America 2004; 101: 24762481.CrossRefGoogle ScholarPubMed
30Fu, Y, Luo, N, Klein, RL, Garvey, WT. Adiponectin promotes adipocyte differentiation, insulin sensitivity, and lipid accumulation. Journal of Lipid Research 2005; 46: 13691379.CrossRefGoogle ScholarPubMed
31Takahashi, S, Ushida, M, Komine, R, Shimizu, A, Uchida, T, Ishihara, H, et al. . Increased basal platelet activity, plasma adiponectin levels, and diabetes mellitus are associated with poor platelet responsiveness to in vitro effect of aspirin. Thrombosis Research 2007; 119: 517524.CrossRefGoogle ScholarPubMed
32Huypens, PR. Leptin and adiponectin regulate compensatory beta cell growth in accordance to overweight. Medical Hypotheses 2007; 68: 11341137.CrossRefGoogle ScholarPubMed
33Garaulet, M, Viguerie, N, Porubsky, S, Klimcakova, E, Clement, K, Langin, D, et al. . Adiponectin gene expression and plasma values in obese women during very-low-calorie diet. Relationship with cardiovascular risk factors and insulin resistance. Journal of Clinical Endocrinology and Metabolism 2004; 89: 756760.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Different configurations of adiponectin

Figure 1

Fig. 2 Adiponectin structure (by courtesy of 10-year-old Olga Albasini-Garaulet)