Activation of neurons in the anterolateral cell group of the bed nucleus of the stria terminalis (BNSTALG) is thought to play a pivotal role in the anxiogenic response to psychological and physical stressors (for review, see Hammack et al., 2009; Walker et al., 2009b). Recently, we have shown that the firing properties and subthreshold intrinsic membrane excitability of the majority of BNSTALG neurons are critically dependent on an interplay between the voltage-dependent transient inward calcium current, IT, and the voltage-dependent transient outward potassium current, IA (Hammack et al., 2007). While IT is depolarizing and promotes action potential generation, IA acts in opposition to IT and can delay the onset to action potential firing and limit the number of spikes elicited in response to excitatory input. The family of voltage-gated potassium channels, referred to as Kv, is a heterogeneous group (Song, 2002), with each channel consisting of four pore-forming α subunits, and multiple accessory subunits. To date, four subfamilies of genes encoding Kv α subunits have been identified: Kv1, Kv2, Kv3, and Kv4, and each subfamily contains multiple members (Yu et al., 2005). In heterologous expression systems, specific Kv α subunits have been shown to form functional channels that have properties similar to physiologically defined A-type potassium channels, namely, the Kv1.4, Kv3.4, and Kv4.1–4.3 subunits (Serodio et al., 1996; Coetzee et al., 1999). Moreover, recent immunohistochemical and biophysical evidence suggests that most of the somatodendritic IA in central neurons is carried by the Kv4 subfamily of α subunits (for review, see Sheng et al., 1992; Birnbaum et al., 2004; Jerng et al., 2004). Significantly, the biophysical properties of A-type potassium channels composed of only the pore-forming α subunits when expressed in heterologous systems do not match the properties of the IA observed in native neuronal systems (Serodio and Rudy, 1998; Holmqvist et al., 2001; Decher et al., 2001; Malin and Nerbonne, 2001). This discrepancy is due to the requirement for auxiliary β subunits not present in these experiments. It is now known that several auxiliary subunits associate with the α subunits to form a macromolecular complex (see Shibata et al., 2003; Birnbaum et al., 2004; Zagha et al., 2005; Jerng et al., 2005), and that association with these auxiliary subunits regulates not only the biophysical properties of the IA channels, but also their cellular distribution and density within the plasma membrane. Included among the auxiliary subunits are the Kvβ subunits (Kvβ1–Kvβ3), a family of membrane bound dipetidyl peptidase proteins (DPPX and DPP10), as well as a family of potassium channel interacting proteins (KChIPs). Importantly, the KChIPs contain an ef-hand domain and act as calcium binding proteins (Burgoyne and Weiss, 2001). Binding of calcium to KChIPs is reported to facilitate the transport of Kv4 α subunits from the endoplasmic reticulum to the plasma membrane (Shibata et al., 2003; Chen et al., 2006a). Given the key role played by opposing IA and IT channels in regulating firing activity of BNSTALG neurons (Hammack et al., 2007), it is possible that the KChIPs may help to regulate the firing pattern of these neurons by determining the level of somatodendritic IA channel expression. To date, four KChIPs have been identified (KChIP1–KChIP4), each of which shows differential distribution within the central nervous system (CNS (Xiong et al., 2004; Rhodes et al., 2004; Dabrowska and Rainnie, 2010). Coexpression of the KChIPs with members of the Kv4 family has been shown to promote cell surface expression and increase peak current density, as well as increase the rate of recovery from inactivation (An et al., 2000; Birnbaum et al., 2004). Recently, we reported that three electrophysiologically distinct cell types (Type I–III) exist in the dorsal portion of the BNSTALG including the oval, juxtacapsular, and rhomboid nuclei and anterolateral area (Hammack et al., 2007). It should be noted, however, that most recording were centered on the oval nucleus. Type I neurons are characterized by a regular firing pattern in response to membrane depolarization, and a depolarizing sag in the voltage response to hyperpolarizing current injection that is mediated by the hyperpolarization-activated cation current, Ih. Type II neurons are characterized by a burst-firing pattern that is mediated by activation of the low-threshold calcium current, IT, and also express a prominent Ih. Type III neurons are characterized by a regular firing pattern, have no prominent Ih, and a pronounced fast hyperpolarization-activated voltage rectification indicative of the inwardly rectifying potassium current, IK(IR). Because the firing activity of BNSTALG neurons is critically dependent on the interplay between IA and IT, we hypothesized that Type I–III neurons may differentially express at least one member of the Kv4 subfamily of α subunits, which could in turn form a macromolecular complex with one or more of the KChIPs. In this way the KChIP auxiliary protein could act as a feedback regulator of IA expression by sensing enhanced calcium influx through IT during periods of heightened excitability. More recently, we have shown that mRNA transcripts for the different Kv4 α subunits are differentially expressed by neurons in the BNSTALG (Hazra et al., 2011b). Here, we extend this observation and using molecular biological, immunofluorescence, electron microscopic, and electrophysiological techniques demonstrate that Type I–III BNSTALG neurons differentially coexpress distinct Kv4 and KChIP subunits and that the Kv4 subunits are located in the somatodendritic compartment of these neurons. Furthermore, we show that expression of IA in BNSTALG neurons regulates action potential threshold and half-width, and that attenuating Kv4 channel function lowered the threshold for induction of synaptic plasticity in these neurons.