Characterization of adenosine-induced respiratory depression in the preterm rabbit

Possible Beneficial Actions of Caffeine in SARS-CoV-2

The COVID-19 pandemic has established an unparalleled necessity to rapidly find effective treatments for the illness; unfortunately, no specific treatment has been found yet. As this is a new emerging chaotic situation, already existing drugs have been suggested to ameliorate the infection of SARS-CoV-2. The consumption of caffeine has been suggested primarily because it improves exercise performance, reduces fatigue, and increases wakefulness and awareness. Caffeine has been proven to be an effective anti-inflammatory and immunomodulator. In airway smooth muscle, it has bronchodilator effects mainly due to its activity as a phosphodiesterase inhibitor and adenosine receptor antagonist. In addition, a recent published document has suggested the potential antiviral activity of this drug using in silico molecular dynamics and molecular docking; in this regard, caffeine might block the viral entrance into host cells by inhibiting the formation of a receptor-binding domain and the angiotensin-converting enzyme complex and, additionally, might reduce viral replication by the inhibition of the activity of 3-chymotrypsin-like proteases. Here, we discuss how caffeine through certain mechanisms of action could be beneficial in SARS-CoV-2. Nevertheless, further studies are required for validation through in vitro and in vivo models.

The Purinome and the preBötzinger Complex - A Ménage of Unexplored Mechanisms That May Modulate/Shape the Hypoxic Ventilatory Response

Exploration of purinergic signaling in brainstem homeostatic control processes is challenging the traditional view that the biphasic hypoxic ventilatory response, which comprises a rapid initial increase in breathing followed by a slower secondary depression, reflects the interaction between peripheral chemoreceptor-mediated excitation and central inhibition. While controversial, accumulating evidence supports that in addition to peripheral excitation, interactions between central excitatory and inhibitory purinergic mechanisms shape this key homeostatic reflex. The objective of this review is to present our working model of how purinergic signaling modulates the glutamatergic inspiratory synapse in the preBötzinger Complex (key site of inspiratory rhythm generation) to shape the hypoxic ventilatory response. It is based on the perspective that has emerged from decades of analysis of glutamatergic synapses in the hippocampus, where the actions of extracellular ATP are determined by a complex signaling system, the purinome. The purinome involves not only the actions of ATP and adenosine at P2 and P1 receptors, respectively, but diverse families of enzymes and transporters that collectively determine the rate of ATP degradation, adenosine accumulation and adenosine clearance. We summarize current knowledge of the roles played by these different purinergic elements in the hypoxic ventilatory response, often drawing on examples from other brain regions, and look ahead to many unanswered questions and remaining challenges.

Pharmacological potential of methylxanthines: Retrospective analysis and future expectations

Methylated xanthines (methylxanthines) are available from a significant number of different botanical species. They are ordinarily included in daily diet, in many extremely common beverages and foods. Caffeine, theophylline and theobromine are the main methylxanthines available from natural sources. The supposedly relatively low toxicity of methylxanthines, combined with the many beneficial effects that have been attributed to these compounds through time, generated a justified attention and a very prolific ground for dedicated scientific reports. Methylxanthines have been widely used as therapeutical tools, in an intriguing range of medicinal scopes. In fact, methylxanthines have been/were medically used as Central Nervous System stimulants, bronchodilators, coronary dilators, diuretics and anti-cancer adjuvant treatments. Other than these applications, methylxanthines have also been hinted to hold other beneficial health effects, namely regarding neurodegenerative diseases, cardioprotection, diabetes and fertility. However, it seems now consensual that toxicity concerns related to methylxanthine consumption and/or therapeutic use should not be dismissed. Taking all the knowledge and expectations on the potential of methylxanthines into account, we propose a systematic look at the past and future of methylxanthine pharmacologic applications, discussing all the promise and anticipating possible constraints. Anyways, methylxanthines will still substantiate considerable meaningful research and discussion for years to come.

Structure-Bioactivity Relationships of Methylxanthines: Trying to Make Sense of All the Promises and the Drawbacks

Methylxanthines are a group of phytochemicals derived from the purine base xanthine and obtained from plant secondary metabolism. They are unobtrusively included in daily diet in common products as coffee, tea, energetic drinks, or chocolate. Caffeine is by far the most studied methylxanthine either in animal or epidemiologic studies. Theophylline and theobromine are other relevant methylxanthines also commonly available in the aforementioned sources. There are many disseminated myths about methylxanthines but there is increased scientific knowledge to discuss all the controversy and promise shown by these intriguing phytochemicals. In fact, many beneficial physiologic outcomes have been suggested for methylxanthines in areas as important and diverse as neurodegenerative and respiratory diseases, diabetes or cancer. However, there have always been toxicity concerns with methylxanthine (over)consumption and pharmacologic applications. Herein, we explore the structure-bioactivity relationships to bring light those enumerated effects. The potential shown by methylxanthines in such a wide range of conditions should substantiate many other scientific endeavors that may highlight their adequacy as adjuvant therapy agents and may contribute to the advent of functional foods. Newly designed targeted molecules based on methylxanthine structure may originate more specific and effective outcomes.

Neuromodulation: purinergic signaling in respiratory control

The main functions of the respiratory neural network are to produce a coordinated, efficient, rhythmic motor behavior and maintain homeostatic control over blood oxygen and CO2/pH levels. Purinergic (ATP) signaling features prominently in these homeostatic reflexes. The signaling actions of ATP are produced through its binding to a diversity of ionotropic P2X and metabotropic P2Y receptors. However, its net effect on neuronal and network excitability is determined by the interaction between the three limbs of a complex system comprising the signaling actions of ATP at P2Rs, the distribution of multiple ectonucleotidases that differentially metabolize ATP into ADP, AMP, and adenosine (ADO), and the signaling actions of ATP metabolites, especially ADP at P2YRs and ADO at P1Rs. Understanding the significance of purinergic signaling is further complicated by the fact that neurons, glia, and the vasculature differentially express P2 and P1Rs, and that both neurons and glia release ATP. This article reviews at cellular, synaptic, and network levels, current understanding and emerging concepts about the diverse roles played by this three-part signaling system in: mediating the chemosensitivity of respiratory networks to hypoxia and CO2/pH; modulating the activity of rhythm generating networks and inspiratory motoneurons, and; controlling blood flow through the cerebral vasculature.

Adenosinergic Modulation of Ventilation in Obese Zucker Rats

OBJECTIVES

The goal of our study was to determine whether altered adenosinergic mechanisms contribute to the depressed ventilatory response observed in obese Zucker rats.

RESEARCH METHODS AND PROCEDURES

Eight lean and eight obese Zucker rats were studied at 7 to 8 weeks of age. Ventilation (V(E)) during room air, during 5-minute hypercapnic (7% CO(2), balance O(2)), and during 30-minute sustained hypoxic (10% O(2)) exposures were sequentially measured by the barometric method on three separate occasions after the randomized blinded administration of equal volumes of either saline (control), 8-(p-sulfophenyl)-theophylline (8-PST, 7 mg/kg, peripheral adenosine antagonist), or aminophylline (AMPH, 15 mg/kg, peripheral and central adenosine antagonist).

RESULTS

During room air and hypercapnic exposures, AMPH (but not 8-PST) significantly (p < 0.05) increased V(E) in both lean and obese rats. During acute (2 minute) hypoxic exposure, 8-PST (but not AMPH) significantly depressed V(E) in lean rats. In contrast, AMPH (but not 8-PST) selectively increased V(E) in obese rats. During sustained (10 to 30 minutes) hypoxic exposure, neither AMPH nor 8-PST administration altered V(E) in lean rats. In contrast, AMPH (but not 8-PST) selectively increased V(E) during the late response in obese rats.

DISCUSSION

Our findings indicate that obese rats possess altered adenosinergic modulation of ventilatory responses to acute and sustained hypoxia in two opposite ways. We conclude that the reduced hypoxic ventilatory response observed in obese Zucker rats is attributed to depressed adenosinergic peripheral excitatory mechanisms and to enhanced adenosinergic central depression mechanisms, both of which contribute to the blunted ventilatory response in obesity.

Role of ATP and adenosine on carotid body function during development

The carotid body is the main peripheral oxygen sensor involved in cardio-respiratory control under both normoxic and hypoxic conditions. This review focuses on data from newborn animals related to the involvement of the purinergic system in carotid body function during development. We describe the potential effects mediated by ATP and adenosine receptors on ventilation, chemoreceptor activity and their influence on respiratory instability, such as apnea. The conclusions that appear from this review is that in newborn rats, activation of ATP receptors increases the carotid body function although with no age dependent manner, regulates breathing under normoxia, and enhances the initial increase in ventilation in response to hypoxia (likely reflecting carotid body responses). However, activation of adenosine receptors may play a role on carotid body function under chronic conditions, such as intermittent hypoxia or exposure to the adenosine receptor antagonist caffeine. Under the later conditions, an indirect effects involving the carotid body dopaminergic system are observed.

Activation of central adenosine A2A receptors enhances superior laryngeal nerve stimulation-induced apnea in piglets via a GABAergic pathway

Activation of the laryngeal mucosa results in apnea that is mediated through, and can be elicited via electrical stimulation of, the superior laryngeal nerve (SLN). This potent inhibitory reflex has been suggested to play a role in the pathogenesis of apnea of prematurity and sudden infant death syndrome, and it is attenuated by theophylline and blockade of GABAA receptors. However, the interaction between GABA and adenosine in the production of SLN stimulation-induced apnea has not been previously examined. We hypothesized that activation of adenosine A2A receptors will enhance apnea induced by SLN stimulation while subsequent blockade of GABAA receptors will reverse the effect of A2A receptor activation. The phrenic nerve responses to increasing levels of SLN stimulation were measured before and after sequential intracisternal administration of the adenosine A2A receptor agonist CGS ( n = 10) and GABAA receptor blocker bicuculline ( n = 7) in ventilated, vagotomized, decerebrate, and paralyzed newborn piglets. Increasing levels of SLN stimulation caused progressive inhibition of phrenic activity and lead to apnea during higher levels of stimulation. CGS caused inhibition of baseline phrenic activity, hypotension, and enhancement of apnea induced by SLN stimulation. Subsequent bicuculline administration reversed the effects of CGS and prevented the production of apnea compared with control at higher SLN stimulation levels. We conclude that activation of adenosine A2A receptors enhances SLN stimulation-induced apnea probably via a GABAergic pathway. We speculate that SLN stimulation causes endogenous release of adenosine that activates A2A receptors on GABAergic neurons, resulting in the release of GABA at inspiratory neurons and subsequent respiratory inhibition.

Maturation of respiratory reflex responses in the fetus and neonate

Respiratory control in the fetus and neonate is quite immature when compared to that of adults. This immaturity involves all facets of respiration including respiratory responses to hypoxia, hypercapnia, an exaggerated apnoeic response to laryngeal stimulation and immature responses to activation of pulmonary afferents. The net result of this immaturity of breathing responses is the vulnerability of neonates and especially preterm infants to apnoea and respiratory pauses. The mechanisms behind immature control of breathing are not fully understood, but seem to originate from a predominance of inhibitory input early in life on respiratory centres. The relative contribution of up-regulation of inhibitory pathways versus down-regulation of excitatory ones is not clear. Multiple neurotransmitters have been implicated in the regulation of breathing in mammals and some of them are discussed in this chapter.

Combined use of adenosine and amrinone inhibits reperfusion injury of rat liver

Although intraportal infusion of adenosine suppressed the oxidative stress caused by activated neutrophils and attenuated ischemia-reperfusion injury of canine liver, high doses of adenosine elicit systemic hypotension. The present work demonstrates that combined use of low doses of adenosine and amrinone, a phosphodiesterase inhibitor, strongly inhibited reperfusion injury of the liver without eliciting hypotension. After 45 min ischemia followed by 60 min reperfusion of rat liver, low doses of adenosine and amrinone were administrated intraportally, resulting in significantly increased hepatic levels of cGMP, cAMP, nitrite plus nitrate in plasma, and decreased alanine aminotransferase in plasma without changing hemodynamics. Thus, intraportal administration of low doses of adenosine and amrinone increased the cyclic nucleotides, thereby improved microcirculation and attenuated reperfusion injury of the liver.

Anticonvulsant A(1) receptor-mediated adenosine action on neuronal networks in the brainstem-spinal cord of newborn rats

Membrane potential of ventral respiratory group neurons as well as inspiratory-related cranial (hypoglossal) and spinal (C(1)-Th(4)) nerve activities were analysed in brainstem-spinal cord preparations from neonatal rats. Block of Cl(-)-mediated inhibition with bicuculline (plus strychnine) affected neither rhythmic depolarizations nor spike discharge in 23 of 30 ventral respiratory group cells. In the other seven neurons, block of inhibitory postsynaptic potentials evoked pronounced depolarizations and spike discharge that was synchronous with seizure-like spinal nerve activity. Respiratory hypoglossal nerve activity persisted after transection at the spinomedullary junction, whereas spinal rhythm was blocked. After transection, the moderate bicuculline-evoked seizure-like perturbation of hypoglossal nerve activity was abolished and rhythmic ventral respiratory group neuron activity was not disturbed, whereas epileptiform discharge persisted in spinal nerves. The seizure-like nerve activity and depolarization of the minor subpopulation of perturbed ventral respiratory group neurons were reversed by either adenosine or the A(1) adenosine receptor agonist 2-chloro-N(6)-cyclopentyladenosine. The A(2) receptor agonist CGS 21860 had no effect. In control preparations, inspiratory nerve activity and membrane potential fluctuations (29 of 35 cells) were not changed by adenosine, 2-chloro-N(6)-cyclopentyladenosine or CGS 21860. In the other six cells, adenosine evoked a hyperpolarization (<10 mV) with no major change in input resistance. The anticonvulsant effects of adenosine and 2-chloro-N(6)-cyclopentyladenosine were antagonized by the A(1) adenosine receptor blocker 8-cyclopentyl-1,3-dipropylxanthine. After pre-incubation with 8-cyclopentyl-1,3-dipropylxanthine, bicuculline also evoked seizure-like discharge in the hypoglossal nerve. The results indicate that seizure-like spinal motor output of the respiratory network upon block of Cl(-)-mediated inhibition is caused by disinhibition of spinal neuronal networks with afferent connections to the ventral respiratory group. Presynaptic A(1) adenosine receptors exert an anticonvulsant action on the disinhibited spinal motor network, but have no depressing effect per se on the isolated medullary respiratory network.

Adenosine modulates inspiratory neurons and the respiratory pattern in the brainstem of neonatal rats

The role of adenosine in the modulation of respiration-related neurons was examined using an in vitro brainstem-spinal cord preparation from neonatal rats (0-4 d old). Respiratory activity was recorded from the C4 or C5 ventral roots by suction electrodes and from inspiratory related neurons (I neurons) in the rostral ventrolateral medulla by microelectrodes. The following substances were added to the preparation superfusate, and their effect was evaluated: the adenosine A1 receptor agonist N6-(2-phenylisopropyl)adenosine, R(-)isomer (R-PIA), the adenosine uptake blocker dipyridamole, the adenosine receptor antagonist theophylline, and the specific A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX). R-PIA and dipyridamole decreased the activity of I neurons and the C4 respiratory burst rate. Furthermore, these compounds induced a significantly more irregular respiratory rate in three-quarters of preparations from the youngest animals (<48 h old) compared with that of controls. Theophylline or DPCPX reversed the effects of both R-PIA and dipyridamole on respiratory rate, regularity of respiratory rate, inspiratory time, amplitude, and intra-burst frequency of I neurons. Thus, adenosine depresses both the I neurons in the rostral ventrolateral medulla and the respiratory motor output. This depression of I neurons and respiratory rate can be abolished by theophylline primarily through a blockade of medullary adenosine A1 receptors. An age-dependent correlation of the effects of R-PIA and dipyridamole, with a more pronounced decrease in respiratory activity in preparations from younger animals, indicates that adenosinergic modulation of medullary respiration-related neurons changes during the first days of postnatal life.