G. Trevor Cottrell

Sensory circumventricular organs: central roles in integrated autonomic regulation

Circumventricular organs (CVO) play a critical role as transducers of information between the blood, neurons and the cerebral spinal fluid (CSF). They permit both the release and sensing of hormones without disrupting the blood-brain barrier (BBB) and as a consequence of such abilities the CVOs are now well established to have essential regulatory actions in diverse physiological functions. The sensory CVOs are essential signal transducers located at the blood-brain interface regulating autonomic function. They have a proven role in the control of cardiovascular function and body fluid regulation, and have significant involvement in central immune response, feeding behavior and reproduction, the extent of which is still to be determined. This review will attempt to summarize the research on these topics to date. The complexities associated with sensory CVO exploration are intense, but should continue to result in valuable contributions to our understanding of brain function.

The Subfornical Organ: A Central Target for Circulating Feeding Signals

The mechanisms through which circulating ghrelin relays hunger signals to the CNS are not yet fully understood. In this study, we have examined the potential role of the subfornical organ (SFO), a circumventricular structure that lacks the normal blood–brain barrier, as a CNS site in which ghrelin acts to influence the hypothalamic centers controlling food intake. We report that ghrelin increased intracellular calcium concentrations in 28% (12 of 43) of dissociated SFO neurons and that the SFO expresses mRNA for the growth hormone secretagogue receptor. Whole-cell patch recordings from SFO neurons demonstrated that in 29% (9 of 31) of neurons tested ghrelin induced a mean depolarization of 7.4 ± 0.69 mV, accompanied by an increase in action potential frequency. Voltage-clamp recordings revealed that ghrelin activates a putative nonselective cationic conductance. Previous reports that the satiety signal amylin exerts similar excitatory effects on SFO neurons led us to examine whether these two peptides influence different subpopulations of SFO neurons. Concentration-dependent depolarizing effects of amylin were observed in 59% (28 of 47) of SFO neurons (mean depolarization, 8.32 ± 0.60 mV). In contrast to ghrelin, voltage-clamp recordings suggest that amylin influences a voltage-dependent current activated at depolarized potentials. We tested single SFO neurons with both peptides and identified cells responsive only to ghrelin (n = 9) and only to amylin (n = 7) but no cells that responded to both peptides. These data support a role for the SFO as a center at which ghrelin and amylin may influence separate subpopulations of neurons to influence the hypothalamic regulation of feeding.

Prokineticin 2 modulates the excitability of subfornical organ neurons.

The recent discovery of prokineticin 2 (PK2) expression in the suprachiasmatic nucleus and its receptors in critical autonomic control centers of the brain, including the subfornical organ (SFO), suggests the intriguing possibility that PK2 regulates the excitability of SFO neurons and thus influences autonomic function. Using current-clamp techniques to record from dissociated SFO neurons, we examined the effects of PK2 on the excitability of these cells. PK2 (20 nm) induced depolarizations in 40% of SFO neurons (n = 45; mean, 7.5 ± 1.7 mV), an effect that was reversible, PK2-specific, and concentration dependent. The depolarization was accompanied by an increase in action potential frequency from 0.4 ± 0.1 to 1.4 ± 0.5 Hz in responding cells (n = 10). This excitatory effect appears to be, in part, attributable to a PK2-induced decrease in the delayed rectifier potassium current (IK). In 10 SFO neurons recorded using perforated patch voltage-clamp techniques, six demonstrated a reversible decrease in IK (mean decrease, 26.7 ± 6.4%) in response to 20 nm PK2, whereas artificial CSF alone was without an effect on these currents. These data are the first to show excitatory effects of PK2 on neurons and, in addition, demonstrate that this peptide modulates voltage-activated K+ channels. The activation of SFO neurons by PK2 illustrates a mechanism through which this peptide may exert circadian control of autonomic functions.

Functional Characteristics of Heteromeric Cx40-Cx43 Gap Junction Channel Formation

Cx40:Cx43 expression ratio in A7r5 cells is augmented in growth stimulated vs. growth arrested conditions. To determine the impact of changing Cx40:Cx43 expression ratio on gap junction function, we have developed A7r5 cell lines that display Cx40:Cx43 ratios of 1:1 (6B5n) and 10:1 (A7r540C3). When Rin43 cells were paired with these coexpressing cells, there was an increasing asymmetry of voltage dependent gating as the Cx40:Cx43 ratio increased in the coexpressing cell. This asymmetry was opposite to that which is predicted by Cx40/Cx43 heterotypic channels. In addition, when Rin43 cells were paired with coexpressing cells there was a shift toward smaller single channel event amplitudes with increasing Cx40:Cx43 ratio in the coexpressing cell. Again, this is opposite to that which is predicted by Cx40/Cx43 heterotypic channels. In dye coupling experiments, 6B5N, A7r5, and A7r540C3 cells displayed charge and size selectivity that increased with increasing Cx40:Cx43 expression ratio. These data indicate that although the electrophysiological properties of heteromeric/heterotypic channels are not directly related to the proportions of Cx constituents that comprise the channel, the dye permeability data fit what would be predicted by an increase in Cx40:Cx43 ratio.

Prokineticin 2 influences subfornical organ neurons through regulation of MAP kinase and the modulation of sodium channels

Prokineticin 2 (PK2) is a neuropeptide that acts as a signaling molecule regulating circadian rhythms in mammals. We have previously reported PK2 actions on subfornical organ (SFO) neurons, identifying this circumventricular organ as a target at which PK2 acts to influence autonomic control (Cottrell GT, and Ferguson AV. J. Neurosci. 24: 2375-2379, 2004). In this study, we have examined the cellular mechanisms by which PK2 increases the excitability of SFO neurons. Whole cell patch recordings from dissociated rat SFO neurons demonstrated that the mitogen-activated protein (MAP) kinase inhibitor PD-98059 prevented PK2-induced depolarization and decreases in delayed rectifier K(+) current. PK2 also increased intracellular Ca(2+) concentration ([Ca(2+)](i)) in 39% of dissociated SFO neurons (mean increase = 20.8 +/- 5.5%), effects that were maintained in the presence of thapsigargin but abolished by both nifedipine, or the absence of extracellular Ca(2+), suggesting that PK2-induced [Ca(2+)](i) transients resulted from Ca(2+) entry through voltage-gated Ca(2+) channels. Voltage-clamp recordings showed that PK2 was without effects on Ca(2+) currents evoked by voltage ramps, suggesting that PK2-induced Ca(2+) influx was secondary to PK2-induced increases in action potential frequency, an hypothesis supported by data showing that tetrodotoxin abolished effects of PK2 on [Ca(2+)](i). These observations suggested PK2 modulation of voltage-gated Na(+) currents, a possibility confirmed by voltage-clamp experiments showing that PK2 increased the amplitude of both transient and persistent Na(+) currents in 29% of SFO neurons (by 34 and 38%, respectively). These data indicate that PK2 influences SFO neurons through the activation of a MAP kinase cascade, which, in turn, modulates Na(+) and K(+) conductances.

Time to consider new brain clock signals.

Circadian change in the expression of L-type Ca2+ channels, and a novel protein prokineticin, might play essential roles in molding the crucial circadian output from the superchiasmatic nucleus.