Renal function and Ca2+ currents after dye-labeling identification of renal sympathetic neurons
1 Department of Physiology, University of North Dakota School of Medicine, Grand Forks, North Dakota 58202; and 2 Department of Physiology, Tulane University School of Medicine, New Orleans, Louisiana 70112 The present study was performed to determine whether renal efferent sympathetic neurons cou...
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| Veröffentlicht in: | American journal of physiology. Regulatory, integrative and comparative physiology integrative and comparative physiology, 1999-11, Vol.277 (5), p.1513 |
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| container_title | American journal of physiology. Regulatory, integrative and comparative physiology |
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| creator | Vari, Richard C Emaduddin, Muhammad Schofield, Geoffrey G |
| description | 1 Department of Physiology,
University of North Dakota School of Medicine, Grand Forks, North
Dakota 58202; and 2 Department of
Physiology, Tulane University School of Medicine, New Orleans,
Louisiana 70112
The
present study was performed to determine whether renal efferent
sympathetic neurons could be identified using a retrograde neuronal
tracer without compromising renal function and whether the labeling and
identification procedure alters
Ca 2+ currents and neuromodulation
of those neurons. Renal sympathetic and superior cervical ganglion
(SCG) neurons were labeled with the fluorescent retrograde tracer fast
blue. Renal function studies made 1 wk after labeling revealed that
renal hemodynamics and fluid and electrolyte excretion were similar
between the dye-injected (left) kidney and the control (right) kidney
under control conditions and after hemorrhage. After volume expansion,
urine flow in the dye-injected kidney was slightly, but significantly,
less than that of the control kidney, whereas urinary sodium excretion
increased by approximately ninefold in both kidneys. Patch-clamp
studies of SCG neurons in 10 mM external
Ca 2+ revealed that peak currents
were not affected by the presence of the dye or a 1-min exposure to
ultraviolet (UV) light. Neither maximal norepinephrine-induced
Ca 2+ current inhibition nor the
sensitivity to norepinephrine was affected by the dye or 1-min UV
exposure. Facilitation protocols revealed that G protein modulation of
Ca 2+ currents remained intact in
dye-labeled UV-exposed neurons. This study demonstrates that a
retrograde fluorescent dye technique to identify renal sympathetic
neurons does not compromise renal function and the presence of the dye
label or UV exposure has no effect on
Ca 2+ currents and neuromodulation
in these neurons. Isolation of single identified renal sympathetic
neurons coupled with patch-clamp techniques represents a tool to
investigate the role of individual current systems in the modulation of
excitability in these neurons, which play an important role in the
control of renal hemodynamics and excretory function and in the
pathogenesis of hypertension.
retrograde labeling technique; fast blue microinjections; renal
projection neurons; calcium current; patch clamp |
| format | Article |
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University of North Dakota School of Medicine, Grand Forks, North
Dakota 58202; and 2 Department of
Physiology, Tulane University School of Medicine, New Orleans,
Louisiana 70112
The
present study was performed to determine whether renal efferent
sympathetic neurons could be identified using a retrograde neuronal
tracer without compromising renal function and whether the labeling and
identification procedure alters
Ca 2+ currents and neuromodulation
of those neurons. Renal sympathetic and superior cervical ganglion
(SCG) neurons were labeled with the fluorescent retrograde tracer fast
blue. Renal function studies made 1 wk after labeling revealed that
renal hemodynamics and fluid and electrolyte excretion were similar
between the dye-injected (left) kidney and the control (right) kidney
under control conditions and after hemorrhage. After volume expansion,
urine flow in the dye-injected kidney was slightly, but significantly,
less than that of the control kidney, whereas urinary sodium excretion
increased by approximately ninefold in both kidneys. Patch-clamp
studies of SCG neurons in 10 mM external
Ca 2+ revealed that peak currents
were not affected by the presence of the dye or a 1-min exposure to
ultraviolet (UV) light. Neither maximal norepinephrine-induced
Ca 2+ current inhibition nor the
sensitivity to norepinephrine was affected by the dye or 1-min UV
exposure. Facilitation protocols revealed that G protein modulation of
Ca 2+ currents remained intact in
dye-labeled UV-exposed neurons. This study demonstrates that a
retrograde fluorescent dye technique to identify renal sympathetic
neurons does not compromise renal function and the presence of the dye
label or UV exposure has no effect on
Ca 2+ currents and neuromodulation
in these neurons. Isolation of single identified renal sympathetic
neurons coupled with patch-clamp techniques represents a tool to
investigate the role of individual current systems in the modulation of
excitability in these neurons, which play an important role in the
control of renal hemodynamics and excretory function and in the
pathogenesis of hypertension.
retrograde labeling technique; fast blue microinjections; renal
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University of North Dakota School of Medicine, Grand Forks, North
Dakota 58202; and 2 Department of
Physiology, Tulane University School of Medicine, New Orleans,
Louisiana 70112
The
present study was performed to determine whether renal efferent
sympathetic neurons could be identified using a retrograde neuronal
tracer without compromising renal function and whether the labeling and
identification procedure alters
Ca 2+ currents and neuromodulation
of those neurons. Renal sympathetic and superior cervical ganglion
(SCG) neurons were labeled with the fluorescent retrograde tracer fast
blue. Renal function studies made 1 wk after labeling revealed that
renal hemodynamics and fluid and electrolyte excretion were similar
between the dye-injected (left) kidney and the control (right) kidney
under control conditions and after hemorrhage. After volume expansion,
urine flow in the dye-injected kidney was slightly, but significantly,
less than that of the control kidney, whereas urinary sodium excretion
increased by approximately ninefold in both kidneys. Patch-clamp
studies of SCG neurons in 10 mM external
Ca 2+ revealed that peak currents
were not affected by the presence of the dye or a 1-min exposure to
ultraviolet (UV) light. Neither maximal norepinephrine-induced
Ca 2+ current inhibition nor the
sensitivity to norepinephrine was affected by the dye or 1-min UV
exposure. Facilitation protocols revealed that G protein modulation of
Ca 2+ currents remained intact in
dye-labeled UV-exposed neurons. This study demonstrates that a
retrograde fluorescent dye technique to identify renal sympathetic
neurons does not compromise renal function and the presence of the dye
label or UV exposure has no effect on
Ca 2+ currents and neuromodulation
in these neurons. Isolation of single identified renal sympathetic
neurons coupled with patch-clamp techniques represents a tool to
investigate the role of individual current systems in the modulation of
excitability in these neurons, which play an important role in the
control of renal hemodynamics and excretory function and in the
pathogenesis of hypertension.
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University of North Dakota School of Medicine, Grand Forks, North
Dakota 58202; and 2 Department of
Physiology, Tulane University School of Medicine, New Orleans,
Louisiana 70112
The
present study was performed to determine whether renal efferent
sympathetic neurons could be identified using a retrograde neuronal
tracer without compromising renal function and whether the labeling and
identification procedure alters
Ca 2+ currents and neuromodulation
of those neurons. Renal sympathetic and superior cervical ganglion
(SCG) neurons were labeled with the fluorescent retrograde tracer fast
blue. Renal function studies made 1 wk after labeling revealed that
renal hemodynamics and fluid and electrolyte excretion were similar
between the dye-injected (left) kidney and the control (right) kidney
under control conditions and after hemorrhage. After volume expansion,
urine flow in the dye-injected kidney was slightly, but significantly,
less than that of the control kidney, whereas urinary sodium excretion
increased by approximately ninefold in both kidneys. Patch-clamp
studies of SCG neurons in 10 mM external
Ca 2+ revealed that peak currents
were not affected by the presence of the dye or a 1-min exposure to
ultraviolet (UV) light. Neither maximal norepinephrine-induced
Ca 2+ current inhibition nor the
sensitivity to norepinephrine was affected by the dye or 1-min UV
exposure. Facilitation protocols revealed that G protein modulation of
Ca 2+ currents remained intact in
dye-labeled UV-exposed neurons. This study demonstrates that a
retrograde fluorescent dye technique to identify renal sympathetic
neurons does not compromise renal function and the presence of the dye
label or UV exposure has no effect on
Ca 2+ currents and neuromodulation
in these neurons. Isolation of single identified renal sympathetic
neurons coupled with patch-clamp techniques represents a tool to
investigate the role of individual current systems in the modulation of
excitability in these neurons, which play an important role in the
control of renal hemodynamics and excretory function and in the
pathogenesis of hypertension.
retrograde labeling technique; fast blue microinjections; renal
projection neurons; calcium current; patch clamp</abstract><pmid>10564226</pmid></addata></record> |
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| ispartof | American journal of physiology. Regulatory, integrative and comparative physiology, 1999-11, Vol.277 (5), p.1513 |
| issn | 0363-6119 1522-1490 |
| language | eng |
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| source | American Physiological Society; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals |
| title | Renal function and Ca2+ currents after dye-labeling identification of renal sympathetic neurons |
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