Isolation and purification of high molecular weight adiponectin from human plasma fraction.

Adiponectin, a crucial protein hormone originating from adipose tissue, regulates key metabolic processes, including lipid metabolism, mitochondrial activity, and insulin sensitivity. These pleiotropic roles of adiponectin, along with its inverse correlation with metabolic disorders such as obesity, type II diabetes, and atherosclerosis, establish this protein as a potential therapeutic target. However, due to this complexity, challenges have arisen in its production with a natural conformation in bacterial or mammalian expression systems, hindering clinical translation. Furthermore, while inducers for adiponectin secretion or chemical agonists targeting adiponectin receptors have shown promise in laboratory settings, clinical studies with these agents have not yet been conducted. This study proposes a method for isolating and purifying natural high molecular weight (HMW) adiponectin from discarded plasma fractions during the conventional pharmaceutical protein manufacturing process. The process involved Cohn-Oncley fractionation, initial chromatography using reduced cellufine formyl, and subsequent purification via DEAE Sepharose chromatography. Characterization involved gel electrophoresis and biological assays on a hepatocyte cell-line. The purification process effectively captured adiponectin from the I + III paste, demonstrating that this fraction contained a significant portion of total plasma adiponectin. The two-step chromatography led to highly purified HMW adiponectin, confirmed by native-PAGE showing a 780 kDa multimeric complex. Biological assessments demonstrated normal downstream signaling, with HMW adiponectin inducing AMPK phosphorylation. This study demonstrates the feasibility of obtaining purified HMW adiponectin by repurposing plasma fractionation processes. It offers a promising avenue for the HMW adiponectin production, tapping into HMW adiponectin's therapeutic potential against metabolic disorders while optimizing plasma resource utilization in healthcare.

A microfluidic interface for the culture and sampling of adiponectin from primary adipocytes.

Secreted from adipose tissue, adiponectin is a vital endocrine hormone that acts in glucose metabolism, thereby establishing its crucial role in diabetes, obesity, and other metabolic disease states. Insulin exposure to primary adipocytes cultured in static conditions has been shown to stimulate adiponectin secretion. However, conventional, static methodology for culturing and stimulating adipocytes falls short of truly mimicking physiological environments. Along with decreases in experimental costs and sample volume, and increased temporal resolution, microfluidic platforms permit small-volume flowing cell culture systems, which more accurately represent the constant flow conditions through vasculature in vivo. Here, we have integrated a customized primary tissue culture reservoir into a passively operated microfluidic device made of polydimethylsiloxane (PDMS). Fabrication of the reservoir was accomplished through unique PDMS "landscaping" above sampling channels, with a design strategy targeted to primary adipocytes to overcome issues of positive cell buoyancy. This reservoir allowed three-dimensional culture of primary murine adipocytes, accurate control over stimulants via constant perfusion, and sampling of adipokine secretion during various treatments. As the first report of primary adipocyte culture and sampling within microfluidic systems, this work sets the stage for future studies in adipokine secretion dynamics.

Isolation and quantitation of adiponectin higher order complexes.

Adiponectin is a circulating bioactive hormone secreted by adipocytes as oligomers ranging in size from 90 kDa trimers and 180 kDa hexamers to larger high molecular weight oligomers that may reach 18- or 36-mers in size. While total circulating adiponectin levels correlate well with metabolic health, it is the relative distribution of adiponectin complexes that is most clinically relevant to glucose sensitivity and inflammation. High molecular weight adiponectin best mirrors insulin sensitivity, while trimeric adiponectin dominates with insulin resistance and adipose tissue inflammation. Experimental animal and in vitro models have also linked the relative fraction of high molecular weight adiponectin to its positive effects. Quantitating adiponectin size distribution thus provides a window into metabolic health and can serve as a surrogate marker for adipose tissue fitness. Here, we present a detailed protocol for isolating and quantitating adiponectin complexes in serum or plasma that has been extensively utilized for both human clinical samples and numerous animal models under various experimental conditions. Examples are presented of different adiponectin distributions and tips are provided for optimization using available equipment. Comparison of this rigorous approach to other available methods is also discussed. In total, this summary is a blueprint for the expanded quantitation and study of adiponectin complexes.

An effective technique for the processing of saliva for the analysis of leptin and adiponectin.

The recovery of protein from saliva has been extensively investigated as a method to monitor health. The aim of this study was to compare filtration and centrifugation as two methods of saliva processing necessary for determining the levels of salivary leptin and adiponectin. Thirty-seven healthy patients (median age of 45 years; range 35-73) participated in the study. Unstimulated whole saliva was collected by a drooling technique. An aliquot was filtered using a Millex-Millipore(®) (0.45µm PVDF Dura Pore membrane) syringe and a second aliquot was centrifuged at 15000×g for 15min at 4°C. Leptin and adiponectin levels were analyzed using an ELISA kit for serum (RayBio(®), GA, USA) with minor modifications. Leptin and adiponectin levels following the filtration technique yielded comparable results with those after centrifugation. Correlation was observed between filtered and centrifuged salivary leptin levels ((r=0.9155; 95% CI 0.8362-0.9573; p<0.0001) with concordance correlation coefficient k 0.9114 (95% CI 0.8332-0.9539)). Less correlation was observed for adiponectin ((r=0.5718; 95% CI 0.3041-0.7558; p=0.0002) with concordance correlation coefficient k 0.5586 (95% CI 0.2977-0.7419)). Using a Bland-Altman plot, similar measurements for both adipocytokines were observed with mean difference within a 95% CI, and interpreted as no systematic differences between the two processing techniques. This study showed that filtration is an alternative saliva processing technique to retrieve supernatant for protein analysis. Filtered saliva yielded leptin and adiponectin concentrations comparable with those obtained from centrifuged saliva.

A monoclonal antibody against bovine adiponectin.

Adiponectin (AdipoQ) is an adipokine mainly secreted by white fatty tissue, playing a major role in energy homeostasis and insulin sensitivity. For cattle, AdipoQ data are largely limited to mRNA expression; to our knowledge, valid information about the AdipoQ protein in bovine tissues and body fluids is not available. Therefore, we have developed a monoclonal antibody against bovine AdipoQ. This study describes the preparation, application, and characterization of a monoclonal antibody for use in ELISA, Western blot, and histology. The antibody was developed by PEG fusion of the SP2/0 cell line with splenic B cells from AdipoQ immunized C57Bl/6 mice. Antibody-producing cells were identified by ELISA and specified by immunoblotting and immunostaining of bovine retroperitoneal adipose tissue. The novel antibody detects AdipoQ in histological samples, ELISA, and Western blots.

Adiponectin stimulates glucose uptake in rabbit blastocysts.

Since the discovery of adipokines, the adipose tissue is no longer considered to be an inactive fat storage. It secretes a variety of bioactive molecules, which regulate body metabolism and energy homeostasis. One of these molecules is the adipokine adiponectin. In different tissues, adiponectin triggers metabolic effects through the adenosine monophosphate-activated protein kinase (PRKA), which is a master regulator in glucose and lipid metabolism. Recent studies point to a role for adiponectin in reproduction. Adiponectin and its receptors are present in female reproductive tract during pregnancy, and the preimplantation embryo is fully equipped with adiponectin. Here, we show that both receptor isoforms, ADIPOR1 and ADIPOR2, are expressed in 6-day-old rabbit blastocysts. To investigate the signaling pathway of adiponectin in preimplantation embryos, rabbit blastocysts were cultured in vitro and stimulated with adiponectin. Supplementation of adiponectin (1 µg/ml) enhanced PRKA alpha 1/2 (PRKAA1/2) phosphorylation and decreased expression of phosphoenolpyruvate carboxykinase 2 (PCK2), a key regulator of gluconeogenesis. Inhibition of PRKAA1/2 by Compound C (10 µM) restored PCK2 transcription. Adiponectin enhanced embryonic glucose uptake and led to a translocation of solute carrier family 2 (facilitated glucose transporter), member 4 (SLC2A4), previously known as GLUT4. We conclude that adiponectin influences the glucose metabolism of rabbit blastocysts via the phosphorylation of PRKAA1/2, which in turn results in a decrease of gluconeogenesis and an increase in glycolysis. The regulatory influence of adiponectin on glucose metabolism of blastocysts may be of specific interest in pathophysiological situations, such as obesity during pregnancy.

Access to gram scale amounts of functional globular adiponectin from E. coli inclusion bodies by alkaline-shock solubilization.

The adipose tissue derived protein adiponectin exerts anti-diabetic, anti-inflammatory and anti-atherosclerotic effects. Adiponectin serum concentrations are in the microgram per milliliter range in healthy humans and inversely correlate with obesity and metabolic disorders. Accordingly, raising circulating adiponectin levels by direct administration may be an intriguing strategy in the treatment of obesity-related metabolic disorders. However production of large amounts of recombinant adiponectin protein is a primary obstacle so far. Here, we report a novel method for large amount production of globular adiponectin from E. coli inclusion bodies utilizing an alkaline-shock solubilization method without chaotropic agents followed by precipitation of the readily renaturing protein. Precipitation of the mildly solubilized protein capitalizes on advantages of inclusion body formation. This approach of inclusion body protein recovery provides access to gram scale amounts of globular adiponectin with standard laboratory equipment avoiding vast dilution or dialysis steps to neutralize the pH and renature the protein, thus saving chemicals and time. The precipitated protein is readily renaturing in buffer, is of adequate purity without a chromatography step and shows biological activity in cultured MCF7 cells and significantly lowered blood glucose levels in mice with streptozotocin induced type 1 diabetes.

Adiponectin does not bind to gelatin: a new and easy way to purify high-molecular-weight adiponectin from human plasma.

Human plasma contains three forms of adiponectin, a trimer, a hexamer, and a high-molecular-weight (HMW) multimer. We previously reported HMW adiponectin was a gelatin-binding protein of 28 kDa (GBP28), it having been purified due to its affinity to gelatin-Cellulofine (Nakano, Y., et al. Isolation and characterization of GBP28, a novel gelatin-binding protein purified from human plasma. J. Biochem. 1996. 120: 803-12). Although HMW adiponectin binds to gelatin-Cellulofine, it cannot bind to gelatin-Sepharose. Gelatin-Cellulofine was made of formyl-Cellulofine and gelatin, and we found that HMW adiponectin binds to reduced formyl-Cellulofine with similar affinity as to gelatin-Cellulofine. Through only two steps using reduced formyl-Cellulofine and DEAE-Sepharose, HMW adiponectin can be effectively purified from human plasma.

An adiponectin-like molecule with antidiabetic properties.

Adiponectin increases glucose transport, reduces inflammation, and controls vascular functions. Hence, we propose that treatment with a recombinant globular domain of adiponectin (rgAd110-244) has significant therapeutic potential to treat insulin resistance. Mice were fed for 3 months on a high-fat diet (HFD) to induce insulin resistance, diabetes, and moderate weight gain. The mice were first infused iv with different doses of rgAd110-244 (0.12, 0.4, and 1.2 microg/kg x min) for 5 h. Basal and insulin-sensitive glucose use rates were assessed by the use of a submaximal rate of insulin in the awake free-moving mouse. rgAd110-244 reduced, with dose dependence, epinephrine-induced hyperglycemia and HFD-induced insulin resistance by increasing whole-body glucose use (35% at the highest dose) and glycolysis rates. Similarly, the reduction of plasma free fatty acid concentrations by insulin was dramatically improved. Basal hepatic glucose production was unchanged by rgAd110-244 infusion. This acute rgAd110-244 treatment improved glucose homeostasis and was associated with an increased content of muscle phospho-Akt, glycogen synthase kinase-3beta, and AMP-activated kinase. Second, HFD mice were chronically treated with sc rgAd110-244 injections (10, 30, and 100 microg/kg). Fasting glycemia and insulin-sensitive glucose use were improved by rgAd110-244 at the highest dose at completion of the treatment, with concomitant reduction in body weight gain. We here show for the first time that a recombinant adiponectin fragment (110-244 amino acids called rgAd110-244) is able to treat insulin-resistant diabetes. Our results strongly suggest further pharmacological investigation of rgAd110-244 with the objective of developing a new treatment of insulin-resistant diabetes.

Regulation of expression of the mouse adiponectin gene by the C/EBP family via a novel enhancer region.

Adiponectin plays protective roles against the development of insulin resistance and atherosclerosis. To clarify the regulation of adiponectin gene expression, reporter gene assay by using the several truncated mouse adiponectin 5'-flanking regions was performed after the differentiation of 3T3-L1 preadipocytes. The results indicated that a novel mouse adiponectin enhancer exists in the-2228 to -2066 region. Nuclear proteins from the differentiated adipocytes bound to two DNA fragments, namely, -2153 to -2114 and -2093 to -2054. Both fragments had a common motif, CACAATGC, which was similar to the CCAAT/enhancer binding protein (C/EBP) binding motif. A gel mobility shift assay with anti-C/EBPs antibodies showed that C/EBP alpha, beta, and delta bound to this motif. These data provide the first evidence that the transcriptional activity of the mouse adiponectin gene during adipocyte differentiation is enhanced by the motif in a novel adiponectin enhancer region, via the recruitment of the C/EBPs.

Plasma adiponectin complexes have distinct biochemical characteristics.

Adipocytes release the secretory protein adiponectin in a number of different higher-order complexes. Once synthesized and assembled in the secretory pathway of the adipocyte, these complexes circulate as biochemically distinct and stable entities with little evidence of interchange between the different forms that include a high-molecular-weight (HMW) species, a hexamer (low-molecular-weight form), and a trimeric form of the complexes. Here, we validate a high-resolution gel filtration method that reproducibly separates the three complexes in recombinant adiponectin and adiponectin from human and murine samples. We demonstrate that the HMW form is prominently reduced in male vs. female subjects and in obese, insulin-resistant vs. lean, insulin-sensitive individuals. A direct comparison of human and mouse adiponectin demonstrates that the trimer is generally more abundant in human serum. Furthermore, when the production of adiponectin is reduced, either by obesity or in mice carrying only a single functional allele of the adiponectin locus, then the amount of the HMW form is selectively reduced in circulation. The complex distribution of adiponectin can be regulated in several ways. Both mouse and human HMW adiponectin are very stable under basic conditions but are exquisitely labile under acidic conditions below pH 7. Murine and human adiponectin HMW forms also display differential susceptibility to the presence of calcium in the buffer. A mutant form of adiponectin unable to bind calcium is less susceptible to changes in calcium concentrations. However, the lack of calcium binding results in a destabilization of the structure. Disulfide bond formation (at position C39) is also important for complex formation. A mutant form of adiponectin lacking C39 prominently forms HMW and trimer but not the low-molecular-weight form. Injection of adiponectin with a fluorescent label reveals that over time, the various complexes do not interconvert in vivo. The stability of adiponectin complexes highlights that the production and secretion of these forms from fat cells has a major influence on the circulating levels of each complex.

Adiponectin binds C1q and activates the classical pathway of complement.

The adipose-specific protein adiponectin binds to a number of target molecules, including damaged endothelium and the surface of apoptotic cells. However, the significance of this binding remains unclear. This study demonstrates the binding of purified C1q to recombinant adiponectin under physiological conditions, and the dependence of this upon Ca(++) and Mg(++). Binding was enhanced by metaperiodate-mediated destruction of glucosylgalactosyl sugars on adiponectin. Adiponectin was bound by the globular domain of the A chain of collagenase-digested C1q, and C1q binding induced deposition of C4 and C3 through activation of the classical complement pathway. After Western blotting, affinity-purified adiponectin from human serum bound C1q, whereas adiponectin in whole serum did not, unless pre-treated with metaperiodate. These results suggest adiponectin is member of the pattern-recognition family of defence collagens, able to bind target molecules and activate complement. It may therefore play an important role in innate immunity and autoimmune phenomena.

Recent advances in the measurement of adiponectin isoform distribution.

PURPOSE OF REVIEW: Adiponectin has potent antidiabetic and antiatherosclerotic actions. Recent studies in animals and humans suggest that the high-molecular weight adiponectin complex, consisting of many adiponectin monomers, is the biologically active form of the peptide. This article will present recent methodological approaches for analyzing adiponectin isoform distribution. RECENT FINDINGS: A handful of methods have been used for the isolation and measurement of high-molecular weight adiponectin, based on velocity gradient centrifugation, gel filtration chromatography and polyacrylamide gel electrophoresis. Recently, two novel sandwich enzyme-linked immuno-sorbent assays have been developed. The first makes use of antibodies raised against human high-molecular weight adiponectin and thus allows for the specific determination of high-molecular weight adiponectin in plasma. The second and more versatile enzyme-linked immuno-sorbent assay system enables the measurement of all adiponectin isoforms (i.e. low, middle and high-molecular weight) by means of selective digestion by proteases. SUMMARY: The development and commercial availability of novel enzyme-linked immuno-sorbent assay kits enables the easy and rapid measurement of high-molecular weight adiponectin in both research and clinical practice and will undoubtedly advance further our understanding of the role of adiponectin in health and disease.

Glycosylation of human adiponectin affects its conformation and stability.

The collagenous region of adiponectin is glycosylated in vitro with glucosylgalactosyl moieties on four conserved lysines. We investigated the glycosylation of human adiponectin in vivo. Sugar vicinyl hydroxides on adiponectin were oxidized with 10 or 1 mM metaperiodate, and the result analyzed by two-dimensional electrophoresis and immunoblotting. Only 10 mM metaperiodate caused significant changes in electrophoretic mobility and an altered susceptibility to proteinase K digestion. Such treatment also increased the susceptibility of hexamers and high molecular weight (HMW) isoforms to dissociation by SDS. By contrast, untreated low molecular weight (LMW) isoforms were readily dissociated by low concentrations of SDS. Reduced HMW isoforms were able to partially reassemble following the removal of dithiothreitol, and this process was unaffected by metaperiodate. The presence of sialic acid was detected by Maackia amurensis Lectin II blotting, and by oxidation with 1 mM metaperiodate, followed by detection with Emerald Green 300 fluorescent dye. Quantitation of sugars on affinity-purified adiponectin from nine human plasmas showed that dimers of HMW isoforms contained a 1.3-fold greater amount of total sugar than LMW isoforms. However, both contained similar amounts of sialic acid. We conclude that glucosylgalactosyl residues contribute to the conformation of HMW human plasma adiponectin. In addition, the HMW isoform contains greater amounts of glucosylgalactosyl residues than the LMW isoform, and these sugars are important in determining its stability in vivo.

Local adiponectin treatment reduces atherosclerotic plaque size in rabbits.

In this study, we investigated the in vivo role of adiponectin, an adipocytokine, on the development of atherosclerosis in rabbits mainly using adenovirus expressing adiponectin gene (Ad-APN) and intravascular ultrasonography. Serum adiponectin concentrations in rabbits after Ad-APN local transfer to abdominal aortas increased about nine times as much as those before transfer (P < 0.01), about ten times as much as the levels of endogenous adiponectin in adenovirus expressing beta-galactosidase gene (Ad-beta gal) treated rabbits (P < 0.01), and about four times as much as those in the aorta of non-injured rabbits on a normal cholesterol diet (P < 0.01). Ultrasonography revealed a significantly reduced atherosclerotic plaque area in abdominal aortas of rabbits infected through intima with Ad-APN, by 35.2% compared with the area before treatment (P < 0.01), and by 35.8% compared with that in Ad-beta gal-treated rabbits (P < 0.01). In rabbits infected through adventitia, Ad-APN treatment reduced plaque area by 28.9% as compared with the area before treatment (P < 0.01) and 25.6% compared with that in Ad-beta gal-treated rabbits (P < 0.01). Adiponectin significantly suppressed the mRNA expression of vascular cell adhesion molecule-1 (VCAM-1) by 18.5% through intima transfer (P < 0.05) and 26.9% through adventitia transfer (P < 0.01), and intercellular adhesion molecule-1 (ICAM-1) by 40.7% through intima transfer (P < 0.01), and 30.7% through adventitia transfer (P < 0.01). However, adiponectin had no effect on the expression of types I and III collagen. These results suggest that local adiponectin treatment suppresses the development of atherosclerosis in vivo in part by attenuating the expression of VCAM-1 and ICAM-1 in vascular walls.

Selective purification and characterization of adiponectin multimer species from human plasma.

Adiponectin is an adipocyte-derived hormone and known to form several species of multimer, however, the precise components of each multimer have not been fully determined. We purified each multimer adiponectin selectively from human plasma and characterized them by affinity columns using anti-adiponectin, gelatin, or anti-albumin antibody and gel filtration. We found that adiponectin exists as four species of multimers in human plasma. According to their migrating mobility and N-terminal amino acid analysis, we defined them as a trimer, albumin-binding trimer, hexamer, and HMW. Low pH shifted HMW to hexamer, raising the possibility that HMW is a 12 mer or larger multimer. We also showed that HMW had the highest binding activity to the membrane fractions of C2C12 myocytes and activated AMPK most potently. Our results indicate that adiponectin forms diverse multimer species and at least some of the functional properties are dependent on a multimer status.

The oligomeric structure of high molecular weight adiponectin.

There is great interest in the structure of adiponectin as its oligomeric state may specify its biological activities. It occurs as a trimer, a hexamer and a high molecular weight complex. Epidemiological data indicate that the high molecular weight form is significant with low serum levels in type 2 diabetics but to date, has not been well-defined. To resolve this issue, characterization of this oligomer from bovine serum and 3T3-L1 adipocytes by sedimentation equilibrium centrifugation and gel electrophoresis respectively, was carried out, revealing that it is octadecameric. Further studies by dynamic light scattering and electron microscopy established that bovine and possibly mouse high molecular weight adiponectin is C1q-like in structure.

Adiponectin-induced secretion of interleukin-6 (IL-6), monocyte chemotactic protein-1 (MCP-1, CCL2) and interleukin-8 (IL-8, CXCL8) is impaired in monocytes from patients with type I diabetes.

BACKGROUND: Systemic adiponectin is reduced in patients with cardiovascular disease (CVD) and low adiponectin may contribute to the pathogenesis of atherosclerosis. However, circulating adiponectin is elevated in type 1 diabetes (T1D) patients, who have also a higher incidence to develop CVD. Because monocytes play an important role in atherosclerosis, we analysed the influence of adiponectin on cytokine and chemokine release in monocytes from T1D patients and controls. METHODS: Systemic adiponectin was determined in the plasma and the high-molecular weight (HMW) form of adiponectin was analysed by immunoblot. Monocytes were isolated from T1D patients and controls and the adiponectin-stimulated release of interleukin-6 (IL-6), monocyte chemotactic protein-1 (MCP-1, CCL2) and interleukin-8 (IL-8, CXCL8) was analysed. RESULTS: Systemic adiponectin was higher in T1D patients. Immunoblot analysis of the plasma indicate abundance of HMW adiponectin in T1D patients and controls. IL-6, CCL2 and CXCL8 secretion in response to adiponectin were found induced in monocytes from controls whereas only IL-6 was upregulated in T1D cells. The induction of IL-6 by adiponectin was abrogated by an inhibitor of the NFkappaB pathway. CONCLUSION: These data indicate that adiponectin-mediated induction of IL-6, CCL2 and CXCL8 is disturbed in monocytes from T1D patients and therefore elevated systemic adiponectin in T1D patients may be less protective when compared to controls.

Adiponectin: Identification, physiology and clinical relevance in metabolic and vascular disease.

Adiponectin is the most abundant adipose-specific protein. Its expression is reduced in obesity, insulin resistance and type 2 diabetes, and plasma concentrations are inversely related to body weight, especially visceral adiposity. Adiponectin is also inversely associated with other traditional cardiovascular risk factors, such as blood pressure, low-density lipoprotein cholesterol and triglyceride levels, and is positively related to high-density lipoprotein cholesterol (HDL-C) levels. Recent research has indicated that adiponectin has anti-inflammatory, anti-atherogenic and antidiabetic properties. The ability of adiponectin to reduce insulin resistance in conjunction with its anti-inflammatory and anti-atherogenic properties makes this novel adipocytokine a promising therapeutic target, and agents that enhance adiponectin secretion or action have potential for treatment of metabolic and vascular disease. Current management strategies that may increase endogenous adiponectin production in humans include weight loss, soy protein and therapy with peroxisome proliferator-activating receptor gamma (PPARgamma) agonists.