Drosophila neuropeptide F mediates integration of chemosensory stimulation and conditioning of the nervous system by food

The conserved neuropeptide Y (NPY) signaling pathway has been strongly implicated in the stimulation of food uptake in vertebrates as well as in the regulation of food conditioned foraging behaviors of Caenorhabditis elegans. Using in situ RNA hybridization and immunocytochemistry, we report the neuronal network of Drosophila neuropeptide F (dNPF), a human NPY homologue, in the larval central nervous system and its food-dependent modifications. We provide indications that gustatory stimulation by sugar, but not its ingestion or metabolism, is sufficient to trigger long-term, dose-dependent alterations of the dNPF neuronal circuit through both dnpf activation and increased synaptic transmission. Our results strongly suggest that the dNPF neuronal circuit is an integral part of the sensory system that mediates food signaling, providing the neural basis for understanding how invertebrate NPY regulates food response.     

Cardiac effects produced by long-term stimulation of thoracic autonomic ganglia or nerves: implications for interneuronal interactions within the thoracic autonomic nervous system

Electrical stimulation of an acutely decentralized stellate or middle cervical ganglion or cardiopulmonary nerve augments cardiac chronotropism or inotropism; as the stimulation continues there is a gradual reduction of this augmentation following the peak response, i.e., an inhibition of augmentation. The amount of this inhibition was found to be dependent upon the region of the heart investigated and the neural structure stimulated. The cardiac parameters which were augmented the most displayed the greatest inhibition. Maximum augmentation or inhibition occurred, in most instances, when 5-20 Hz stimuli were used. Inhibition of augmentation was overcome when the stimulation frequency was subsequently increased or following the administration of nicotine or tyramine, indicating that the inhibition was not primarily due to the lack of availability of noradrenaline in the nerve terminals of the efferent postganglionic sympathetic neurons. Furthermore, as infusions of isoproterenol or noradrenaline during the period of inhibition could still augment cardiac responses, whereas during the early peak responses they did not, the inhibition of augmentation does not appear to be due primarily to down regulation of cardiac myocyte beta-adrenergic receptors. The inhibition was modified by hexamethonium but not by phentolamine or atropine. Inhibition occurred when all ipsilateral cardiopulmonary nerves connected with acutely decentralized middle cervical and stellate ganglia were stimulated, whereas significant inhibition did not occur when these nerves were stimulated after they had been disconnected from the ipsilateral decentralized ganglia. Taken together these data indicate that the inhibition of cardiac augmentation which occurs during relatively long-term stimulation of intrathoracic sympathetic neural elements is due in large part to nicotinic cholinergic synaptic mechanisms that lie primarily in the major thoracic autonomic ganglia. They also indicate that long-term stimulation in intrathoracic sympathetic neural elements with frequencies as low as 2 Hz may augment the heart as much as higher stimulation frequencies, depending upon the structure stimulated and the cardiovascular parameter monitored.     

Neuropeptide Y and autonomic nervous system

Neuropeptide Y (NPY) containing 6 amino acid residues belongs to peptides widely spread in the central and peripheral nervous system. NPY and its receptors play an extremely diverse role in the nervous system, including regulation of satiety, of emotional state, of vascular tone, and of gastrointestinal secretion. In mammals, NPY has been revealed in the majority of sympathetic ganglion neurons, in a high number of neurons of parasympathetic cranial ganglia as well as of intramural ganglia of the metasympathetic nervous system. At present, six types of receptors to NPY (Y₁–Y₆) have been identified. All receptors to NPY belong to the family of G-bound proteins. Actions of NPY on peripheral organs-targets are predominantly realized through postsynaptic receptors Y₁, Y₃–Y₅, and presynaptic receptors of the Y₂ type. NPY is present in large electrondense vesicles and is released at high-frequency stimulation. NPY affects not only vascular tone, frequency and strength of heart contractions, motorics and secretion of the gastrointestinal tract, but also has trophic effect and produces proliferation of cells of organs-targets, specifically of vessels, myocardium, and adipose tissue. In early postnatal ontogenesis the percent of the NPY-containing neurons in ganglia of the autonomic nervous system increases. In senescent organisms, this parameter decreases. This seems to be connected with the trophic NPY effect on cell-targets as well as with regulation of their functional state.     

自主神经对心肌膜离子通道的调节

自主神经通过多种机制对心肌膜Na^ ,K^ ,Ca^2 ,Cl^-等多种离子通道进行调节,从而实现其对心脏的变动,变力,变传导等多种作用。研究自主神经对心脏离子通道的调节,对于人们认识心脏电生理,病理生理及多种心血管疾病的发病和治疗具有重要意义。本文对自主神经对心肌膜离子通道的调节及其信号转导进行论述。     

Mechanisms of synergism of the autonomic nervous system compartments

The realization mechanisms of phenomena of sympathetic nerve potentiation of vagal stimulation of motor activity of duodenal and jejunal intestine, urinary bladder and ureters, uterus and tubes, vas deference and mechanism of sympathetic nerve potentiation of vagal cardioinhibitory action were studied. There were demonstrated that these phenomena were realized with participation of preganglionic serotoninergic nerve fibers transmitting an excitation on ganglionary serotoninergic neurons. It was found an existence of increasing cranio-caudal and decreasing ventro-dorsal gradients of serotoninergic innervation of visceral organs.     

Effect of juvenile hormone on the autonomic nervous system

The effects of juvenoids on the autonomic nervous system, which controls certain physiological functions by means of special extracardiac pulsations in hemolymph pressure, have been studied in pupae of the mealworm, Tenebrio molitor. Prolonged tensiometric monitoring of the hemolymph pressure changes revealed that the extra-pupal development that had been caused by juvenoids evoked unusual reappearance of prepupal pattern of extracardiac pulsations. By contrast, the specific pharate adult types of the pulsations completely disappeared. The functioning of the autonomic nervous system was aberrant or incomplete during an unsuccessful extra-pupal ecdysis. It is suggested that malfunction of the autonomic nervous system in the extra-pupal instars may be the reason for the ecdysial failures associated with the use of juvenoids.