We present the cloning and characterization of two novel calcium-activated potassium channel  subunits, hKCNMB3 and hKCNMB4, that are enriched in the testis and brain, respectively. We compare and contrast the steady state and kinetic properties of these  subunits with the previously cloned mouse 1 (mKCNMB1) and the human 2 subunit (hKCNMB2). Once inactivation is removed, we find that hKCNMB2 has properties similar to mKCNMB1. hKCNMB2 slows Hslo1 channel gating and shifts the current-voltage relationship to more negative potentials. hKCNMB3 and hKCNMB4 have distinct effects on slo currents not observed with mKCNMB1 and hKCNMB2. Although we found that hKCNMB3 does interact with Hslo channels, its effects on Hslo1 channel properties were slight, increasing Hslo1 activation rates. In contrast, hKCNMB4 slows Hslo1 gating kinetics, and modulates the apparent calcium sensitivity of Hslo1. We found that the different effects of the  subunits on some Hslo1 channel properties are calcium-dependent. mKCNMB1 and hKCNMB2 slow activation at 1 M but not at 10 M free calcium concentrations. hKC-NMB4 decreases Hslo1 channel openings at low calcium concentrations but increases channel openings at high calcium concentrations. These results suggest that  subunits in diverse tissue types fine-tune slo channel properties to the needs of a particular cell.The large conductance calcium-activated potassium channel (BK) 1 is a unique member of the six transmembrane domain potassium channel family that is activated by voltage and calcium. BK channels are composed of a pore-forming ␣ subunit (1, 2) and, in some tissues, are tightly associated with an accessory  subunit (3, 4). BK channels have diverse physiological properties with tissue-specific distribution. In neurons, BK channels are functionally colocalized with calcium channels (5, 6), shape action potential wave forms (7,8), and modulate neurotransmitter release (9, 10). In smooth muscle, BK channels regulate constriction in arteries (11), uterine contraction (12), and filtration rate in the kidney (13). Unlike other potassium channel families, BK channels can as yet only be attributed to a single gene, slowpoke (slo), that encodes the poreforming ␣ subunit of the channel. In light of the broad tissue localization and diverse functional properties, it is not surprising that a number of mechanisms have been identified that alter slo channel properties. These include alternative splicing of the slo RNA (14 -18), heteromeric assembly with other subunits (slak) (19), and modification by phosphorylation/dephosphorylation (20 -22) and oxidation/reduction (23).In addition, accessory  subunits are a means of generating BK channel diversity. Coexpression of the 1 subunit in Xenopus oocytes increases the apparent calcium sensitivity, slows activation kinetics, and increases charybdotoxin binding affinity (24 -27). 1 subunit mRNA is enriched in smooth muscle (28) and can account for the apparent increased calcium sensitivity of BK channels in that tissue relative to skeletal muscl...
