Adipose tissue as regulator of vascular tone.

Adipokines secreted by visceral, subcutaneous, and perivascular adipocytes are involved in the regulation of vascular tone by acting as circulatory hormones (leptin, adiponectin, omentin, visfatin, angiotensin II, resistin, tumor necrosis factor-α, interleukin-6, apelin) and/or via local paracrine factors (perivascular adipocyte-derived relaxing and contractile factors). Vascular tone regulation by adipokines is compromised in obesitas and obesity-related disorders. Hypoxia created in growing adipose tissue dysregulates synthesis of vasoactive adipokines in favor of harmful proinflammatory adipokines, while the levels of the cardioprotective adipokines adiponectin and omentin decrease. Considering the potential of the role of adipokines in obesity-related vascular diseases, strategies to counter these diseases by targeting the adipokines are discussed.

Regulation of vascular tone by adipocytes.

Recent studies have shown that adipose tissue is an active endocrine and paracrine organ secreting several mediators called adipokines. Adipokines include hormones, inflammatory cytokines and other proteins. In obesity, adipose tissue becomes dysfunctional, resulting in an overproduction of proinflammatory adipokines and a lower production of anti-inflammatory adipokines. The pathological accumulation of dysfunctional adipose tissue that characterizes obesity is a major risk factor for many other diseases, including type 2 diabetes, cardiovascular disease and hypertension. Multiple physiological roles have been assigned to adipokines, including the regulation of vascular tone. For example, the unidentified adipocyte-derived relaxing factor (ADRF) released from adipose tissue has been shown to relax arteries. Besides ADRF, other adipokines such as adiponectin, omentin and visfatin are vasorelaxants. On the other hand, angiotensin II and resistin are vasoconstrictors released by adipocytes. Reactive oxygen species, leptin, tumour necrosis factor α, interleukin-6 and apelin share both vasorelaxing and constricting properties. Dysregulated synthesis of the vasoactive and proinflammatory adipokines may underlie the compromised vascular reactivity in obesity and obesity-related disorders.

Hypoxia enhances the relaxing influence of perivascular adipose tissue in isolated mice aorta.

Adipose tissue releases an "adipocyte-derived relaxing factor" (ADRF) lowering tone of isolated arteries. The potential influence of hypoxia on the vasorelaxing properties of adipose tissue was investigated. Aortas from male Swiss mice with or without adherent adipose tissue were mounted in a wire myograph for isometric tension recording. Hypoxia (bubbling with 95% N(2), 5% CO(2)) relaxed precontracted (norephinephrine, 5 microM) aorta with adipose tissue while only a minimal vasorelaxing effect was observed in arteries without adipose tissue. This effect was also seen after precontraction with prostaglandin F(2alpha) (30 microM) or U-46619 (10 nM). Precontraction with 60 or 120 mM K(+), incubation with tetraethylammoniumchloride (3 mM) or glibenclamide (30 microM) significantly impaired the hypoxic response. Glibenclamide (30 microM) enhanced the vasorelaxing effect of NaHS (except at high concentrations of NaHS). Lactate (10 nM to 1 mM) had no effect on preparations with or without adipose tissue. 8-(p-sulfophenyl)theophylline (0.1 mM), zinc protoporphyrin IX (10 microM), 1 H-[1, 2, 4]oxadiazolo[4,3-A]quinoxalin-1-one (10 microM) and removal of the endothelium did not influence the hypoxic relaxation. Our findings indicate that hypoxia has a relaxing influence on mice aorta that is dependent on the presence of adherent adipose tissue. This relaxation is partly mediated by opening K(ATP) channels and independent of the endothelium and soluble guanylyl cyclase. Neither lactate, adenosine, CO nor H(2)S seems to be involved in this hypoxic response. However, the involvement of the as yet unidentified "adipocyte-derived relaxing factor" (ADRF) cannot be excluded.

Adenosine enhances the relaxing influence of retinal tissue.

Retinal tissue from different species continuously releases an as yet unidentified retinal relaxing factor (RRF) lowering tone of isolated arteries. The potential influence of adenosine on this relaxing influence was investigated using isometric tension recording of different isolated arteries. The presence of bovine retinal tissue or rat retinal tissue enhanced the vasorelaxing effect of adenosine on isolated bovine retinal artery. In isolated rat carotid artery adenosine elicited no relaxation. However, a small relaxation is observed in the presence of rat retinal tissue, but not in the presence of porcine retina. The fact that adenosine potentiates the effect of rat retinal tissue but not that of a similar piece of porcine retinal tissue indicates species differences. Neither a NO-synthase inhibitor (nitro-L-arginine, 0.1mM), a cyclooxygenase inhibitor (indomethacin, 10 microM) or an epoxygenase inhibitor (miconazole, 10 microM) influenced the enhanced vasodilating effect of adenosine on bovine retinal arteries in the presence of bovine retinal tissue. On the other hand, when the retinal arteries were contracted with 120 mM K(+), adenosine no longer induced relaxation of the preparation with bovine retinal tissue. This is in line with the concept that adenosine enhances the influence of RRF. Also, the fact that rat carotid artery is less sensitive to RRF than bovine retinal artery - corresponding with a less enhanced adenosine response in rat carotid artery - is in line with the potential involvement of the RRF in the enhanced adenosine response. However, experiments using a bioassay setup for RRF gave no evidence for an increased RRF-release from the retina, nor for an increased RRF-sensitivity of the retinal artery in the presence of adenosine. In conclusion, our findings indicate that adenosine potentiates the relaxing influence of bovine and rat retinal tissue. This effect is species dependent as it is not seen with porcine retinal tissue. Neither NO, cyclooxygenase metabolites or epoxyeicosatrienoic acids seem to be involved in this enhanced vasorelaxing response. The involvement of the RRF cannot be excluded.

Control of retinal arterial tone by a paracrine retinal relaxing factor.

Retinal blood flow is regulated by local factors. In vitro bioassay experiments give evidence that retinal tissue from different species (dogs, pigs, sheep, cows, rats, and mice) continuously releases a factor lowering tone of isolated retinal arteries. This factor is a general relaxant as it was effective in relaxing different types of vascular as well as nonvascular smooth muscle preparations. This factor is called the retinal relaxing factor (RRF) and its characteristics do not correspond with those of the many well-known vasorelaxants found in retina (i.e., NO, prostanoids, adenosine, ADP, ATP, lactate, glutamate, GABA, taurine, adrenomedullin, CGRP, ANP, BNP, and CNP). This unknown RRF is transferable, hydrophilic, and heat-stable. Its relaxing effect is independent of the presence of the vascular endothelium and of NO-synthase, adenylyl cyclase, guanylyl cyclase, and cyclooxygenase activity. RRF might have a role in hypoxic vasodilation in retinal arteries since hypoxia induces relaxation only when retinal tissue is present. Thus, the RRF pathway is sensitive to changes in oxygen tension and might be a sensitive mechanism for adjusting vascular diameter to retinal oxygen levels. Diminished RRF release might explain the decreased retinal circulation observed in disease with atrophic retina.