Purine Nucleotides in the Regulation of Brown Adipose Tissue Activity.

Non-shivering thermogenesis in mammalian brown adipose tissue is a powerful mechanism to defend normothermia in cold climates. To minimize the loss of chemical energy, the central functional component, mitochondrial uncoupling protein 1, UCP1, must be tightly regulated. The canonical pathway of UCP1 activation includes lipolytic release of free fatty acids in response to an adrenergic signal. Activating fatty acids overcome constitutive inhibition of UCP1 by the di- and triphosphate forms of purine nucleotides, i.e., ATP, ADP, GTP, and GDP. Cellular concentrations of inhibitory, free nucleotides are subject to significant, adrenergically induced alterations. The regulatory components involved may constitute novel drug targets to manipulate brown fat thermogenesis and thereby organismic energy balance. We here review evidence for and against a dominant role of nucleotides in thermogenic control, describe conceptual routes to endogenously and pharmacologically alter free nucleotide pool size, speculate on a signaling role of degradation products released from active brown fat, and highlight gaps in our understanding of signaling and metabolic pathways involved.

Purines in the eye: recent evidence for the physiological and pathological role of purines in the RPE, retinal neurons, astrocytes, Müller cells, lens, trabecular meshwork, cornea and lacrimal gland.

This review highlights recent findings that describ how purines modulate the physiological and pathophysiological responses of ocular tissues. For example, in lacrimal glands the cross-talk between P2X7 receptors and both M3 muscarinic receptors and α1D-adrenergic receptors can influence tear secretion. In the cornea, purines lead to post-translational modification of EGFR and structural proteins that participate in wound repair in the epithelium and influence the expression of matrix proteins in the stroma. Purines act at receptors on both the trabecular meshwork and ciliary epithelium to modulate intraocular pressure (IOP); ATP-release pathways of inflow and outflow cells differ, possibly permitting differential modulation of adenosine delivery. Modulators of trabecular meshwork cell ATP release include cell volume, stretch, extracellular Ca(2+) concentration, oxidation state, actin remodeling and possibly endogenous cardiotonic steroids. In the lens, osmotic stress leads to ATP release following TRPV4 activation upstream of hemichannel opening. In the anterior eye, diadenosine polyphosphates such as Ap4A act at P2 receptors to modulate the rate and composition of tear secretion, impact corneal wound healing and lower IOP. The Gq11-coupled P2Y1-receptor contributes to volume control in Müller cells and thus the retina. P2X receptors are expressed in neurons in the inner and outer retina and contribute to visual processing as well as the demise of retinal ganglion cells. In RPE cells, the balance between extracellular ATP and adenosine may modulate lysosomal pH and the rate of lipofuscin formation. In optic nerve head astrocytes, mechanosensitive ATP release via pannexin hemichannels, coupled with stretch-dependent upregulation of pannexins, provides a mechanism for ATP signaling in chronic glaucoma. With so many receptors linked to divergent functions throughout the eye, ensuring the transmitters remain local and stimulation is restricted to the intended target may be a key issue in understanding how physiological signaling becomes pathological in ocular disease.

Involvement of purinergic system in inflammation and toxicity induced by copper in zebrafish larvae.

The use of zebrafish (Danio rerio) is increasing as an intermediate preclinical model, to prioritize drug candidates for mammalian testing. As the immune system of the zebrafish is quite similar to that of mammals, models of inflammation are being developed for the screening of new drugs. The characterization of these models is crucial for studies that seek for mechanisms of action and specific pharmacological targets. It is well known that copper is a metal that induces damage and cell migration to hair cells of lateral line of zebrafish. Extracellular nucleotides/nucleosides, as ATP and adenosine (ADO), act as endogenous signaling molecules during tissue damage by exerting effects on inflammatory and immune responses. The present study aimed to characterize the inflammatory status, and to investigate the involvement of the purinergic system in copper-induced inflammation in zebrafish larvae. Fishes of 7 days post-fertilization were exposed to 10 µM of copper for a period of 24 h. The grade of oxidative stress, inflammatory status, copper uptake, the activity and the gene expression of the enzymes responsible for controlling the levels of nucleotides and adenosine were evaluated. Due to the copper accumulation in zebrafish larvae tissues, the damage and oxidative stress were exacerbated over time, resulting in an inflammatory process involving IL-1ß, TNF-α, COX-2 and PGE2. Within the purinergic system, the mechanisms that control the ADO levels were the most involved, mainly the reactions performed by the isoenzyme ADA 2. In conclusion, our data shed new lights on the mechanisms related to copper-induced inflammation in zebrafish larvae.

Nucleotides in the eye: focus on functional aspects and therapeutic perspectives.

The presence and activity of nucleotides and dinucleotides in the physiology of most, if not all, organisms, from bacteria to humans, have been recognized by the scientific community, and the eye is no exception. Nucleotides in the dynamic fluids interact with many ocular structures, such as the tears and aqueous humor. Moreover, high concentrations of nucleotides in these secretions may reflect disease states such as dry eye and glaucoma. Apart from the nucleotide concentration in these fluids, P2 purinergic receptors have been described on the ocular surface (cornea and conjunctiva), anterior pole (ciliary body, trabecular meshwork), and posterior pole (retina). P2X and P2Y purinergic receptors are essential in maintaining the homeostasis of ocular processes, such as tear secretion, aqueous humor production, or retinal modulation. When they are functioning properly, they allow the eye to do its job (to see), but in some cases, a lack or an excess of nucleotides or a malfunction in the corresponding purinergic receptors leads to disease. This Perspective is focused on the nucleotides and dinucleotides and the P2 purinergic receptors in the eye and how they contribute to normal and disease states. We also emphasize the action of nucleotides and their receptors and antagonists as potential therapeutic agents.

Purine nucleotides reduce superoxide production by nitric oxide synthase in a murine sepsis model

Sepsis involves a systemic inflammatory response of multiple endogenous mediators, resulting in many of the injurious and sometimes fatal physiological symptoms of the disease. This systemic activation leads to a compromised vascular response and endothelial dysfunction. Purine nucleotides interact with purinoceptors and initiate a variety of physiological processes that play an important role in maintaining cardiovascular function. The purpose of the present study was to investigate the effects of ATP on vascular function in a lipopolysaccharide (LPS) model of sepsis. LPS induced a significant increase in aortic superoxide production 16 h after injection. Addition of ATP to the organ bath incubation solution reduced superoxide production by the aortas of endotoxemic animals. Reactive Blue, an antagonist of the P2Y receptor, blocked the effect of ATP on superoxide production, and the nonselective P2Y agonist MeSATP inhibited superoxide production. Nitric oxide synthase (NOS) inhibition by L-NAME blocked vascular relaxation and reduced superoxide production in LPS-treated animals. In the presence of L-NAME there was no ATP effect on superoxide production. A vascular reactivity study showed that ATP increased maximal relaxation in LPS-treated animals compared to controls. The presence of ATP induced increases in Akt and endothelial NOS phosphorylated proteins in the aorta of septic animals. ATP reduces superoxide release resulting in an improved vasorelaxant response. Sepsis may uncouple NOS to produce superoxide. We showed that ATP through Akt pathway phosphorylated endothelial NOS and “re-couples” NOS function.

Purine nucleotides reduce superoxide production by nitric oxide synthase in a murine sepsis model.

Sepsis involves a systemic inflammatory response of multiple endogenous mediators, resulting in many of the injurious and sometimes fatal physiological symptoms of the disease. This systemic activation leads to a compromised vascular response and endothelial dysfunction. Purine nucleotides interact with purinoceptors and initiate a variety of physiological processes that play an important role in maintaining cardiovascular function. The purpose of the present study was to investigate the effects of ATP on vascular function in a lipopolysaccharide (LPS) model of sepsis. LPS induced a significant increase in aortic superoxide production 16 h after injection. Addition of ATP to the organ bath incubation solution reduced superoxide production by the aortas of endotoxemic animals. Reactive Blue, an antagonist of the P2Y receptor, blocked the effect of ATP on superoxide production, and the nonselective P2Y agonist MeSATP inhibited superoxide production. Nitric oxide synthase (NOS) inhibition by L-NAME blocked vascular relaxation and reduced superoxide production in LPS-treated animals. In the presence of L-NAME there was no ATP effect on superoxide production. A vascular reactivity study showed that ATP increased maximal relaxation in LPS-treated animals compared to controls. The presence of ATP induced increases in Akt and endothelial NOS phosphorylated proteins in the aorta of septic animals. ATP reduces superoxide release resulting in an improved vasorelaxant response. Sepsis may uncouple NOS to produce superoxide. We showed that ATP through Akt pathway phosphorylated endothelial NOS and "re-couples" NOS function.

Role of ATP and related purines in inhibitory neurotransmission to the pig urinary bladder neck.

BACKGROUND AND PURPOSE: As adenosine 5'-triphosphate (ATP) is one of the inhibitory mediators of the bladder outflow region, this study investigates the possible release of ATP or related purines in response to electrical field stimulation (EFS) and the purinoceptor(s) involved in nerve-mediated relaxations of the pig urinary bladder neck. EXPERIMENTAL APPROACH: Urothelium-denuded and intact phenylephrine-precontracted strips were mounted in organ baths containing physiological saline solution at 37 degrees C and gassed with 95% O(2) and 5% CO2 for isometric force recordings. KEY RESULTS: EFS, in the presence of atropine, guanethidine and N(G)-nitro-L-arginine, and exogenous purines, produced frequency- and concentration-dependent relaxations respectively. Adenosine 5'-diphosphate (ADP) and adenosine were more potent than ATP in producing relaxation, while uridine 5'-triphosphate, uridine 5'-diphosphate and alpha,beta-methylene ATP were less effective. The non-selective P2 antagonist suramin, and the P2Y(1) and P1 receptor blockers 2'-deoxy-N6-methyladenosine 3',5'-bisphosphate tetrasodium and 8-(p-sulphophenyl)theophylline, respectively, inhibited the responses to EFS and ATP. The P1 agonist's potency was: 5'-N-ethylcarboxamidoadenosine (NECA)>4-2[[6-amino-9-(N-ethyl-b-D-ribofuranuronamidosyl)-9H-purin-2-yl]amino]ethyl]benzene propanoic acid hydrochloride>2-chloro-N(6)-cyclopentyladenosine>-2-chloro-6-[[(3-iodophenyl)methyl]amino]-9H-purin-9-yl]-1-deoxy-N-methyl-b-D-ribofuranuronamide = adenosine. 4-(-[7-amino-2-(2-furyl)[1,2,4]triazolo[2,3-a][1,3,5]triazin-5-ylamino]ethyl) phenol, an A(2A) antagonist, reduced the relaxations to EFS, adenosine and NECA. In urothelium-intact samples, relaxations to EFS and purines were smaller than in urothelium-denuded preparations. Neuronal voltage-gated Na(+) channels blockade failed to modify ATP relaxations. At basal tension, EFS- and ATP-induced contractions were resistant to desensitization or blockade of P2X(1) and P2X(3) receptors. CONCLUSIONS AND IMPLICATIONS: ATP is involved in the non-adrenergic, non-cholinergic, non-nitrergic inhibitory neurotransmission in the pig bladder neck, producing relaxation largely through muscle A(2A) receptors after breakdown to adenosine, and P2Y(1) receptors after breakdown to ADP. Antagonists of these receptors may be useful for urinary incontinence treatment produced by intrinsic sphincteric deficiency.

Vasoactive intestinal peptide. Relaxant neurotransmitter in tenia coli of the guinea pig.

Two main candidates have been proposed for the role of relaxant neurotransmitter in the intestine: (a) the purine nucleotide, 5'-adenosine triphosphate (ATP) and (b) the neuropeptide, vasoactive intestinal peptide (VIP). The candidacy of VIP is favored by its precise location in nerve fibers that innervate circular smooth muscle and tenia coli. We have used a photoaffinity analog of ATP, 3'-O-(4-Benzoyl)benzoyl ATP, that binds irreversibly to ATP receptors and inactivates them in the presence of light, and a specific VIP antiserum to examine the claims of VIP and ATP as relaxant neurotransmitters in tenia coli of the guinea pig. Both VIP and ATP caused dose-dependent, tetrodotoxin-insensitive relaxation of tenia coli. The effect of ATP was equipotent to that of its stable isostere alpha, beta-methylene ATP and resistant to degradation by adenosine deaminase, indicating interaction of ATP with purinergic-P2 receptors. Photoactivated 3'-O-(4-Benzoyl) benzoyl adenosine triphosphate selectively inhibited relaxation induced by ATP but had no effect on relaxation induced by VIP or by field (i.e., neural) stimulation. Vasoactive intestinal peptide antiserum (final dilution 1:60), on the other hand, inhibited relaxation caused by VIP and by field stimulation but had no effect on relaxation caused by ATP. Neither normal rabbit serum nor preneutralized VIP antiserum had any effect on relaxation induced by ATP, VIP, or field stimulation. Inhibition of neurally induced relaxation by VIP antiserum ranged from 52% +/- 7% (p less than 0.01) at the lowest frequency of stimulation to 15% +/- 4% (p less than 0.01) at the highest frequency, consistent with competitive interaction between antiserum and neurally released VIP. Near-maximal field stimulation at 1 Hz caused an eightfold (800% +/- 49%, p less than 0.01) increase in VIP release into the bathing medium. The results favor VIP (and probably peptide histidine isoleucine, a relaxant homologue known to be cosynthesized with VIP) as the main neural mediator of relaxation in tenia coli.

Purinergic neurotransmission and neuromodulation.

Conflicting views abound on the peripheral neurotransmitter and neuromodulator roles of purine compounds. Substantial organ- and species-related variations have become apparent. There is, however, a body of compelling evidence for such roles, if not so broad and ubiquitous as those envisioned (7) for the central nervous system. The variations may in part be attributable to the neuroeffector synaptic geometry. The transmitter concentration found at the postsynaptic membrane drops precipitously with increase in the synaptic cleft (85). Where the cleft is narrow, a purine may serve as the primary or sole transmitter (purinergic nerve) and presynaptic modulator. Alternatively, from nonpurinergic (e.g. adrenergic) nerves a purine may be released, possibly ATP by exocytosis, to act as a cotransmitter. It may also serve as pre- and post-synaptic modulator, potentially with a contribution from postsynaptic release (Figure 1). The purine could conceivably diffuse and affect other varicosities. Where the cleft is wide, the postsynaptic concentration of the neurogenic purine may be too low to permit a transmitter or postsynaptic modulator function. The concentration of the nonpurine transmitter may also be insufficient to elicit a significant postsynaptic purine release. The neuronally released purine may, however, presynaptically exert inhibition of transmitter release much as in a narrow cleft. It seems, therefore, that the origin of synaptic purines and their function, be it transmitter, cotransmitter, or modulator, are dictated at least in part by the characteristics of the purine pools, purinergic receptors, and synaptic configuration, which await further assessment.

Evidence for purinergic innervation of the anococcygeus muscle.

1 Fluorescence histochemical localization of quinacrine (which binds to adenosine 5'-triphosphate (ATP)) revealed nerve fibres running singly and in bundles in both rat and rabbit anococcygeus muscle. Single neurone cell bodies and ganglia containing between 2 and 50 cells were also observed.2 Catecholamine fluorescence studies revealed a dense adrenergic ground plexus, but no adrenergic ganglion cells were detected. No acetylcholinesterase-positive nerve fibres or ganglion cells were seen in the rat.3 When the tone was raised with guanethidine, a relaxation in response to field stimulation was revealed, which was unaffected by atropine but blocked by tetrodotoxin.4 Release of ATP increased 3 to 6 times above background during stimulation of these non-adrenergic, non-cholinergic, inhibitory nerves.5 Neither quinacrine staining nor the release of ATP during inhibitory nerve stimulation was affected by 6-hydroxydopamine treatment, which abolished catecholamine fluorescence.6 Exogenous ATP produced relaxation in high tone preparations of the rabbit anococcygeus muscle. ATP produced either contraction or a small relaxation followed by a contraction of the rat anococcygeus muscle, but treatment with low concentrations of the prostaglandin synthesis inhibitor indomethacin, converted the contraction to a relaxation.7 These data are consistent with the view that the anococcygeus muscle is innervated by purinergic inhibitory nerves.