TY  - CONF
AU  - Nikolić, Ljiljana
AU  - Bataveljić, Danijela
AU  - Moldovan, Ivana
AU  - Balind, Snežana
AU  - Todorović, Dajana
AU  - Nedeljković, Miodrag
AU  - Petković, Branka
PY  - 2014
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4028
AB  - Hibernation is a physiological state that enables certain animal species to survive severe
environmental conditions during the cold periods. In hibernation state the brain activity
is maintained at a very low, but functionally responsive level, indicating that neurons
and glial cells undergo certain physiological modifications. These modifications should
be characterized as a neuroprotective, since the brain of hibernated animals endures extreme
physiological conditions without any damage. In the present study we examined
the electrophysiological responses of neurons and glial cells all acutely isolated from
active and hibernating land snail Helix pomatia by the patch-clamp technique. Hibernating
state lasted six months. Data obtained revealed that the steady-state outward neuronal
current density was significantly lower in hibernation. In addition, the fast Na+
inward current density was significantly reduced in the population of isolated hibernated
neurons, indicating that neuronal activity is suppressed in hibernation. The lower neuronal
activity was supported by the suppressed electrophysiological response of glial
cells. Thus, hibernated glia had significantly lower specific membrane conductance and
reduced inward current density compared to active glia. Particularly important was the
modification of the glial inwardly rectifuing potassium (Kir) channel activity, essential
for the coupling of the function of glial cells with neuronal activity. Thus, in the presence
of BaCl2, Ba2+-sensitive current density mediated by the glial Kir channels was significantly
lower in hibernation. Altogether, our data indicate that overall suppression of
neuronal and glial activity is important natural neuroprotective strategy necessary.
PB  - Belgrade: Serbian Physiological Society
C3  - 3rd Congress of Physiological Sciences of Serbia With International Participation
T1  - Modified Electrophysiological Responses of Neurons and Glial Cells Acutely Isolated From The Hibernating Land Snail
SP  - 149
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4028
ER  - 

@conference{
author = "Nikolić, Ljiljana and Bataveljić, Danijela and Moldovan, Ivana and Balind, Snežana and Todorović, Dajana and Nedeljković, Miodrag and Petković, Branka",
year = "2014",
abstract = "Hibernation is a physiological state that enables certain animal species to survive severe
environmental conditions during the cold periods. In hibernation state the brain activity
is maintained at a very low, but functionally responsive level, indicating that neurons
and glial cells undergo certain physiological modifications. These modifications should
be characterized as a neuroprotective, since the brain of hibernated animals endures extreme
physiological conditions without any damage. In the present study we examined
the electrophysiological responses of neurons and glial cells all acutely isolated from
active and hibernating land snail Helix pomatia by the patch-clamp technique. Hibernating
state lasted six months. Data obtained revealed that the steady-state outward neuronal
current density was significantly lower in hibernation. In addition, the fast Na+
inward current density was significantly reduced in the population of isolated hibernated
neurons, indicating that neuronal activity is suppressed in hibernation. The lower neuronal
activity was supported by the suppressed electrophysiological response of glial
cells. Thus, hibernated glia had significantly lower specific membrane conductance and
reduced inward current density compared to active glia. Particularly important was the
modification of the glial inwardly rectifuing potassium (Kir) channel activity, essential
for the coupling of the function of glial cells with neuronal activity. Thus, in the presence
of BaCl2, Ba2+-sensitive current density mediated by the glial Kir channels was significantly
lower in hibernation. Altogether, our data indicate that overall suppression of
neuronal and glial activity is important natural neuroprotective strategy necessary.",
publisher = "Belgrade: Serbian Physiological Society",
journal = "3rd Congress of Physiological Sciences of Serbia With International Participation",
title = "Modified Electrophysiological Responses of Neurons and Glial Cells Acutely Isolated From The Hibernating Land Snail",
pages = "149",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4028"
}

Nikolić, L., Bataveljić, D., Moldovan, I., Balind, S., Todorović, D., Nedeljković, M.,& Petković, B.. (2014). Modified Electrophysiological Responses of Neurons and Glial Cells Acutely Isolated From The Hibernating Land Snail. in 3rd Congress of Physiological Sciences of Serbia With International Participation
Belgrade: Serbian Physiological Society., 149.
https://hdl.handle.net/21.15107/rcub_ibiss_4028

Nikolić L, Bataveljić D, Moldovan I, Balind S, Todorović D, Nedeljković M, Petković B. Modified Electrophysiological Responses of Neurons and Glial Cells Acutely Isolated From The Hibernating Land Snail. in 3rd Congress of Physiological Sciences of Serbia With International Participation. 2014;:149.
https://hdl.handle.net/21.15107/rcub_ibiss_4028 .

Nikolić, Ljiljana, Bataveljić, Danijela, Moldovan, Ivana, Balind, Snežana, Todorović, Dajana, Nedeljković, Miodrag, Petković, Branka, "Modified Electrophysiological Responses of Neurons and Glial Cells Acutely Isolated From The Hibernating Land Snail" in 3rd Congress of Physiological Sciences of Serbia With International Participation (2014):149,
https://hdl.handle.net/21.15107/rcub_ibiss_4028 .

TY  - JOUR
AU  - Nikolić, Ljiljana
AU  - Bataveljić, Danijela B.
AU  - Anđus, Pavle R.
AU  - Moldovan, Ivana
AU  - Nedeljković, Miodrag
AU  - Petković, Branka
PY  - 2014
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/2112
UR  - https://journals.sagepub.com/doi/full/10.1177/0748730414559126
AB  - Hibernation is a dormant state of some animal species that enables them
   to survive harsh environmental conditions during the winter seasons. In
   the hibernating state, preservation of neuronal rhythmic activity at a
   low level is necessary for maintenance of suspended forms of behavior.
   As glial cells support rhythmic activity of neurons, preservation of
   brain function in the hibernating state implies accompanying
   modification of glial activity. A supportive role of glia in regulating
   neuronal activity is reflected through the activity of inwardly
   rectifying K+ channels (Kir). Therefore, we examined
   electrophysiological response, particularly Kir current response, of
   glial cells in mixture with neurons acutely isolated from active and
   hibernating land snail Helix pomatia. Our data show that hibernated glia
   have significantly lower inward current density, specific membrane
   conductance, and conductance density compared with active glia. The
   observed reduction could be attributed to the Kir currents, since the
   Ba2+-sensitive Kir current density was significantly lower in hibernated
   glia. Accordingly, a significant positive shift of the current reversal
   potential indicated a more depolarized state of hibernated glia. Data
   obtained show that modification of glial current response could be
   regulated by serotonin (5-HT) through an increase of cGMP as a secondary
   messenger, since extracellular addition of 5-HT or intracellular
   administration of cGMP to active glia induced a significant reduction of
   inward current density and thus mimicked the reduced response of
   hibernated glia. Lower Kir current density of hibernated glia
   accompanied the lower electrical activity of hibernated neurons, as
   revealed by a decrease in neuronal fast inward Na+ current density. Our
   findings reveal that glial response is reduced in the hibernating state
   and suggest seasonal modulation of glial activity. Maintenance of low
   glial activity in hibernation could be important for preservation of
   brain rhythmic activity and survival of the animal.
PB  - Sage Publications Inc.
T2  - Journal of Biological Rhythms
T1  - Modification of Glial Response in Hibernation: A Patch-Clamp Study on
 Glial Cells Acutely Isolated from Hibernating Land Snail
IS  - 6
VL  - 29
DO  - 10.1177/0748730414559126
SP  - 442
EP  - 455
ER  - 

@article{
author = "Nikolić, Ljiljana and Bataveljić, Danijela B. and Anđus, Pavle R. and Moldovan, Ivana and Nedeljković, Miodrag and Petković, Branka",
year = "2014",
abstract = "Hibernation is a dormant state of some animal species that enables them
   to survive harsh environmental conditions during the winter seasons. In
   the hibernating state, preservation of neuronal rhythmic activity at a
   low level is necessary for maintenance of suspended forms of behavior.
   As glial cells support rhythmic activity of neurons, preservation of
   brain function in the hibernating state implies accompanying
   modification of glial activity. A supportive role of glia in regulating
   neuronal activity is reflected through the activity of inwardly
   rectifying K+ channels (Kir). Therefore, we examined
   electrophysiological response, particularly Kir current response, of
   glial cells in mixture with neurons acutely isolated from active and
   hibernating land snail Helix pomatia. Our data show that hibernated glia
   have significantly lower inward current density, specific membrane
   conductance, and conductance density compared with active glia. The
   observed reduction could be attributed to the Kir currents, since the
   Ba2+-sensitive Kir current density was significantly lower in hibernated
   glia. Accordingly, a significant positive shift of the current reversal
   potential indicated a more depolarized state of hibernated glia. Data
   obtained show that modification of glial current response could be
   regulated by serotonin (5-HT) through an increase of cGMP as a secondary
   messenger, since extracellular addition of 5-HT or intracellular
   administration of cGMP to active glia induced a significant reduction of
   inward current density and thus mimicked the reduced response of
   hibernated glia. Lower Kir current density of hibernated glia
   accompanied the lower electrical activity of hibernated neurons, as
   revealed by a decrease in neuronal fast inward Na+ current density. Our
   findings reveal that glial response is reduced in the hibernating state
   and suggest seasonal modulation of glial activity. Maintenance of low
   glial activity in hibernation could be important for preservation of
   brain rhythmic activity and survival of the animal.",
publisher = "Sage Publications Inc.",
journal = "Journal of Biological Rhythms",
title = "Modification of Glial Response in Hibernation: A Patch-Clamp Study on
 Glial Cells Acutely Isolated from Hibernating Land Snail",
number = "6",
volume = "29",
doi = "10.1177/0748730414559126",
pages = "442-455"
}

Nikolić, L., Bataveljić, D. B., Anđus, P. R., Moldovan, I., Nedeljković, M.,& Petković, B.. (2014). Modification of Glial Response in Hibernation: A Patch-Clamp Study on
 Glial Cells Acutely Isolated from Hibernating Land Snail. in Journal of Biological Rhythms
Sage Publications Inc.., 29(6), 442-455.
https://doi.org/10.1177/0748730414559126

Nikolić L, Bataveljić DB, Anđus PR, Moldovan I, Nedeljković M, Petković B. Modification of Glial Response in Hibernation: A Patch-Clamp Study on
 Glial Cells Acutely Isolated from Hibernating Land Snail. in Journal of Biological Rhythms. 2014;29(6):442-455.
doi:10.1177/0748730414559126 .

Nikolić, Ljiljana, Bataveljić, Danijela B., Anđus, Pavle R., Moldovan, Ivana, Nedeljković, Miodrag, Petković, Branka, "Modification of Glial Response in Hibernation: A Patch-Clamp Study on
 Glial Cells Acutely Isolated from Hibernating Land Snail" in Journal of Biological Rhythms, 29, no. 6 (2014):442-455,
https://doi.org/10.1177/0748730414559126 . .