Mechanisms of the action of endogenous electrotonic influences and exogenous factors on biological rhythms of neurons

Mechanisms of the action of endogenous electrotonic influences and exogenous factors on biological rhythms of neurons

Автор: Orlov Valery I., Sukhov Aleksandr G., Kit Oleg I., Shikhlyarova Alla I., Rudenko Mikhail Y., Kirichenko Evgeniya Y., Fillipova Svetlana Y., Pashintsev Germany Gieen Ludwigstrae, Protasova Tatiana

Журнал: Cardiometry @cardiometry

Рубрика: Original research

Статья в выпуске: 12, 2018 года.

Бесплатный доступ

Subjects of our experimental studies were neurons in the snail Helix Pomatia, from which continuous intracellular recordings according to our specific microelectrode recording technique were produced. We have carried out original investigations of the processes of control and regulation of endogenous biological rhythms of neurons, observing them both under their background activity (free of stimulation) and under the action of the exogenous factors within a chronic experiment, which involved continuous recordings of activity from the neurons that covered periods from 50 to 60 hours, with an incubated ganglion cell life span up to four 24-hour days. In the neurophysiological experimental studies with recordings of intracellular activity of the identified CNS neurons in the Roman snail Helix Pomatia, we conducted a research into identification of a contribution of potential-dependent ion (K+, Ca2+, Na+) channels to formation of pacemaking oscillatory activity of the neurons and an interplay of the AP generation loci unequally or irregularly spaced. It has been shown that it is possible to activate at the same time 2-3 individual loci of generation of the Na+ spikes, differing in their amplitudes, which appear at different segments of the axo-dendritic axis of the neurons in the snail Helix Pomatia.

Еще

Neuron, rhythm genesis, biological intracellular rhythm, synapse, potential-dependent ion channels, functional state, electromagnetic radiation

Короткий адрес: https://sciup.org/148308841

IDR: 148308841   |   DOI: 10.12710/cardiometry.2018.12.3953

Список литературы Mechanisms of the action of endogenous electrotonic influences and exogenous factors on biological rhythms of neurons

  • Sukhov AG, Serdyuk TS, Lysenko LV, et al. Cholinergic and potential-dependent mechanisms of local rhythmogenesis in neuronal columns of the somatic crust of the rat. Rostov-on-Don: Southern Federal University Publishing, 2011. 346 p.
  • Adams DS, Levin M. Endogenous voltage gradients as mediators of cell-cell communication: strategies for investigating bioelectrical signals during pattern formation. Cell Tissue Res. 2013;352:95-122.
  • Liebau S, Propper C, Bockers T, et al. Selective blockage of Kv1.3 and Kv3.1 channels increases neural progenitor cell proliferation. J Neurochem. 2006;99:426-37.
  • MacFarlane SN, Sontheimer H. Changes in ion channel expression accompany cell cycle progression of spinal cord astrocytes. J. Glia. 2000;30:39-48.
  • Morokuma J, Blackiston D, Levin M. KCNQ1 and KCNE1 K+ channel components are involved in early left-right patterning in Xenopus laevis embryos. Cell Physiol Biochem. 2008;21:357-72.
  • Rouzaire-Dubois B, Gerard V, Dubois JM. Involvement of K+ channels in the quercetin-induced inhibition of neuroblastoma cell growth. Pflugers. Arch. 1993;423:202-5
  • Stillwell EF, Cone CM, Cone CD. Stimulation of DNA synthesis in CNS neurones by sustained depolarization. Nat. New Biol. 1973;246:110-1.
  • Wonderlin WF, Strobl JS. Potassium channels, proliferation and G1 progression. J. Membr. Biol. 1996;154:91-107.
  • Gong B, et al. Membrane Potential Dependent Duration of Action Potentials in Cultured Rat Hippocampal Neurons. Cell. Mol. Neurobiol. 2008;28:49-56.
  • Orlov VI, Laskov VN, Karpenko LD. Method for dissecting the central nervous system of a grape snail. Patent No. 1561962, 1990.
  • Orlov VI, Marutkina EA, Sukhov AG. Intracellular research of interaction of different loci of pacemaker activity in helix's neurons. Proceedings of the 4th International Scientific Conference "Fundamental and Applied Science today". October, 20-21, 2014. North Charleston, USA. Volume 3. p. 18-23.
  • Orlov VI, Vislobokov AI, Shabanov PD, Marutkina EA. Anesthetic effective on the external side of neurons' plasmatic membrane. Proceedings of the 7th International Scientific Conference "Science in modern information society". November 9-10, 2015. North Charleston, USA. V. 3, p. 113-122.
  • Vislobokov AI, Malov AM, Orlov VI. Changes in intracellular potentials and ion currents of neurons with extra-and intracellular effects of mercuric acetate. www.medline.ru. V. 16, Article No. 64. Toxicology. 2015. p. 700-716
  • Orlov VI, Vislobokov AI, Marutkina EA, Sukhov AG. Membranotropic effects of ethanol: changes in the potentials and ion currents of mollusks' neurons. Neurocomputers: development, application. 2014;8:29-37.
  • Jiang Yu-Q, Sun Q, Tu HY, Wan Y. Characteristics of HCN Channels and Their Participation in Neuropathic Pain. Neurochem Res. 2008;33(10):1979-89.
  • Dere Ekram. Editor: Gap Junction in the Brain, Physiological and Pathological Roles. 2013. Academic Res, Paris. 2012. 290 pages
  • Sokolov EN, Arakelov GG, Litvinov EG, et al. The pacemaker potential of a neuron. Tbilisi. 1975. p. 214.
  • Carr DB, Cooper DC, Ulrich SL, Spruston N, Surmeier DJ. Serotonin receptor activation inhibits sodium current and dendritic excitability in prefrontal cortex via a protein kinase C-dependent mechanism. J Neurosci. 2002 Aug 15;22(16):6846-55.
  • Korkushko AO. Physical basis of interaction of laser radiation with biological objects. Likar'ska sprava. 2001;4:134-7.
  • Nikitin AV, Yesaulenko IE, Vasilieva LV. Low-intensity laser radiation in practical medicine. VGU, 2000. 190 p.
  • Xiao Y, Tian W, López-Schier H. Optogenetic stimulation of neuronal repair. Curr. Biol. 2015; 25(22):R1068-9.
  • Presman AS. Electromagnetic fields and wildlife. М., 1968. 193p.
  • Kholodov YA. The brain in electromagnetic fields. М., 1982. 120p.
  • Putilov AA. System-forming function of synchronization in living nature. Novosibirsk.
  • Orlov VI, Rudenko MY, Shikhlyarova AI, et al. Mechanisms of electromagnetic influences and effects on membrane systems in neurons and cardiomyocytes. Cardiometry. November 2017;11:17-27; ; DOI: 10.12710/cardiometry.2017.11.1727
  • Shikhlyarova AI. The role of biotropic parameters of electromagnetic fields in the increase of nonspecific antitumor resistance. Dissertation. Rostov-on-Don, 2001. 50p.
  • Kit OI, Shikhlyarova AI, Maryanovskaya GY, et al. Theory of health: successful translation into the real life. Cardiometry. 2015;7:11-7.
  • Kit OI, Komarova EF, Shikhlyarova AI, et al. Pathogenetic substantiation for anti-tumor effectiveness of experimental electromagnetic therapy. November 2017; Cardiometry. 11:54-63; ; DOI: 10.12710/cardiometry.2017.11.5463
  • Garkavi LK, Kvakina EB, Kuzmenko TS, Shikhlyarova AI. Anti-stress reactions and activation therapy. Ekaterinburg. RIA Philanthrop. 2002.
  • Grechenko TN. Neuron, signal processing, plasticity, modeling. Chapter 13. Book: collective monograph.
  • Shnol' SE. Physicochemical factors of biological evolution. 1979. Mscow: Nauka.
Еще
Статья научная
SciUp 2024 © 2024 ©