Altered expression of BK channel beta1 subunit in vascular tissues from spontaneously hypertensive rats.

Correlation of blood pressure (BP) with expression levels of large-conductance, voltage- and Ca2+-activated K+ (BK) channel beta1 subunit in vascular tissues from spontaneously hypertensive rats (SHR), Wistar-Kyoto rats (WKY), and Sprague-Dawley rats (SD) at different ages was investigated. Systolic BP and BK beta1 expression in mesenteric arteries at either mRNA or protein levels were not different among 4-week-old SHR, WKY, and SD. With hypertension developed at 7 weeks and reached plateau at 12 weeks, expression levels of BK beta1 mRNA in mesenteric arteries and aortae from SHR during this period of time were significantly higher than in age-matched normotensive WKY. The BK beta1 protein expression was significantly higher in mesenteric arteries from 12-week-old but not 7-week-old SHR when compared with age-matched WKY and SD. The BK beta1 protein levels in aortae were not different among 7-week-old SHR, WKY, and SD but were significantly lower in 12-week-old WKY than in age-matched SHR and SD. Captopril treatment normalized BP of 12-week-old SHR. This treatment downregulated BK beta1 protein in mesenteric arteries but upregulated it in aortae. No significant difference in BK alpha subunit expression was detected in mesenteric arteries from three strains of rats as well as the captopril-treated SHR. It appears that expression patterns of BK beta1 in vascular tissues vary depending on tissue types, animal age, and animal strains. Expression of BK beta1 in mesenteric arteries is closely correlated with BP in SHR. Increased BK beta1 expression in mesenteric arteries may represent a compensatory reaction to limit the development of hypertension.

Both transmembrane domains of BK ß1 subunits are essential to confer the normal phenotype of ß1-containing BK channels.

Voltage/Ca²âº(i)-gated, large conductance K+ (BK) channels result from tetrameric association of α (slo1) subunits. In most tissues, BK protein complexes include regulatory ß subunits that contain two transmembrane domains (TM1, TM2), an extracellular loop, and two short intracellular termini. Four BK ß types have been identified, each presenting a rather selective tissue-specific expression profile. Thus, BK ß modifies current phenotype to suit physiology in a tissue-specific manner. The smooth muscle-abundant BK ß1 drastically increases the channel's apparent Ca²âº(i) sensitivity. The resulting phenotype is critical for BK channel activity to increase in response to Ca2+ levels reached near the channel during depolarization-induced Ca2+ influx and myocyte contraction. The eventual BK channel activation generates outward K+ currents that drive the membrane potential in the negative direction and eventually counteract depolarization-induced Ca2+ influx. The BK ß1 regions responsible for the characteristic phenotype of ß1-containing BK channels remain to be identified. We used patch-clamp electrophysiology on channels resulting from the combination of smooth muscle slo1 (cbv1) subunits with smooth muscle-abundant ß1, neuron-abundant ß4, or chimeras constructed by swapping ß1 and ß4 regions, and determined the contribution of specific ß1 regions to the BK phenotype. At Ca2+ levels found near the channel during myocyte contraction (10 µM), channel complexes that included chimeras having both TMs from ß1 and the remaining regions ("background") from ß4 showed a phenotype (V(half), τ(act), τ(deact)) identical to that of complexes containing wt ß1. This phenotype could not be evoked by complexes that included chimeras combining either ß1 TM1 or ß1 TM2 with a ß4 background. Likewise, ß "halves" (each including ß1 TM1 or ß1 TM2) resulting from interrupting the continuity of the EC loop failed to render the normal phenotype, indicating that physical connection between ß1 TMs via the EC loop is also necessary for proper channel function.

Positions of ß2 and ß3 subunits in the large-conductance calcium- and voltage-activated BK potassium channel.

Large-conductance voltage- and Ca(2+)-gated K(+) channels are negative-feedback regulators of excitability in many cell types. They are complexes of α subunits and of one of four types of modulatory ß subunits. These have intracellular N- and C-terminal tails and two transmembrane (TM) helices, TM1 and TM2, connected by an ∼100-residue extracellular loop. Based on endogenous disulfide formation between engineered cysteines (Cys), we found that in ß2 and ß3, as in ß1 and ß4, TM1 is closest to αS1 and αS2 and TM2 is closest to αS0. Mouse ß3 (mß3) has seven Cys in its loop, one of which is free, and this Cys readily forms disulfides with Cys substituted in the extracellular flanks of each of αS0-αS6. We identified by elimination mß3-loop Cys152 as the only free Cys. We inferred the disulfide-bonding pattern of the other six Cys. Using directed proteolysis and fragment sizing, we determined this pattern first among the four loop Cys in ß1. These are conserved in ß2-ß4, which have four additional Cys (eight in total), except that mß3 has one fewer. In ß1, disulfides form between Cys at aligned positions 1 and 8 and between Cys at aligned positions 5 and 6. In mß3, the free Cys is at position 7; position 2 lacks a Cys present in all other ß2-ß4; and the disulfide pattern is 1-8, 3-4, and 5-6. Presumably, Cys 2 cross-links to Cys 7 in all other ß2-ß4. Cross-linking of mß3 Cys152 to Cys substituted in the flanks of αS0-S5 attenuated the protection against iberiotoxin (IbTX); cross-linking of Cys152 to K296C in the αS6 flank and close to the pore enhanced protection against IbTX. In no case was N-type inactivation by the N-terminal tail of mß3 perturbed. Although the mß3 loop can move, its position with Cys152 near αK296, in which it blocks IbTX binding, is likely favored.

Altered cryptal expression of luminal potassium (BK) channels in ulcerative colitis.

Decreased sodium (Na(+)), chloride (Cl(-)), and water absorption, and increased potassium (K(+)) secretion, contribute to the pathogenesis of diarrhoea in ulcerative colitis. The cellular abnormalities underlying decreased Na(+) and Cl(-) absorption are becoming clearer, but the mechanism of increased K(+) secretion is unknown. Human colon is normally a K(+) secretory epithelium, making it likely that K(+) channels are expressed in the luminal (apical) membrane. Based on the assumption that these K(+) channels resembled the high conductance luminal K(+) (BK) channels previously identified in rat colon, we used molecular and patch clamp recording techniques to evaluate BK channel expression in normal and inflamed human colon, and the distribution and characteristics of these channels in normal colon. In normal colon, BK channel alpha-subunit protein was immunolocalized to surface cells and upper crypt cells. By contrast, in ulcerative colitis, although BK channel alpha-subunit protein expression was unchanged in surface cells, it extended along the entire crypt irrespective of whether the disease was active or quiescent. BK channel alpha-subunit protein and mRNA expression (evaluated by western blotting and real-time PCR, respectively) were similar in the normal ascending and sigmoid colon. Of the four possible beta-subunits (beta(1-4)), the beta(1)- and beta(3)-subunits were dominant. Voltage-dependent, barium-inhibitable, luminal K(+) channels with a unitary conductance of 214 pS were identified at low abundance in the luminal membrane of surface cells around the openings of sigmoid colonic crypts. We conclude that increased faecal K(+) losses in ulcerative colitis, and possibly other diseases associated with altered colonic K(+) transport, may reflect wider expression of luminal BK channels along the crypt axis.