[K+]o and [Ca2+]o reached a steady-state level during a stable locomotor episode. Screening Library chemical structure The steady state of [K+]o reflects an equilibrium between the neuronal K+ efflux and its clearance from the extracellular space with neuronal Na+/K+ pump (Syková, 1987) and glial cells (Jendelová and Syková, 1991). The decrease in [Ca2+]o mainly involves an uptake into postsynaptic somata and/or dendrites (Heinemann and Pumain, 1981). Lowering [Ca2+]o has been reported to switch the firing mode of various CNS neurons from spiking to bursting (Brocard et al., 2006; Heinemann et al., 1977; Johnson et al., 1994; Su et al., 2001; Tazerart et al.,

2008). In our experiments, the reduction PF-01367338 clinical trial of [Ca2+]o requires a concomitant raise in [K+]o to trigger bursts. This synergistic effect probably results from a joint regulation of INaP and IK, respectively. An increase in INaP appears to be the major link between the reduction in [Ca2+]o and the bursting ability because a decrease of [Ca2+]o shifts the threshold of INaP activation toward more negative values and enhances its amplitude. In agreement with this, our simulation showed that the shift of the threshold of INaP activation toward more negative values plays a major role in the emergence of bursts, and even a subtle shift of activation by −3 mV produces the same effect as increasing INaP conductance by 50%. This is supported by the

sensitivity of pacemaker activity to riluzole and TTX. Changes in pore occupancy of sodium channels by calcium may be responsible for these modifications of INaP ( Armstrong, 1999). Although [K+]o increase does not upregulate INaP, as shown experimentally, our model demonstrates that it facilitates the emergence of INaP-dependent bursts by reducing IK as a result of reduction of EK (see also Rybak et al., 2003). The increased [K+]o also provides an additional depolarization of pacemaker cells via the reduction of the voltage-gated potassium and leak

currents, which also increases the frequency of oscillations. In summary, the regulation of INaP and IK by [Ca2+]o and [K+]o, respectively, may represent a fundamental Mephenoxalone mechanism in generating and regulating the pacemaker activities in other brain areas. Taking into account that changes in [K+]o and [Ca2+]o (1) precede the onset of locomotion, (2) promote INaP-dependent pacemaker properties in putative locomotor CPG cells, and (3) trigger a locomotor episode, a conceptual scheme can be proposed for rhythmogenesis in the mammalian spinal cord. A moderate spiking activity of CPG components causes a reduction in [Ca2+]o and increase in [K+]o. Changes in these concentrations cause the simultaneous regulation of INaP and IK, which together produce at a threshold level a switch from spiking to bursting representing the locomotor oscillations.