Min Song

Molecular constituents of maxi KCa channels in human coronary smooth muscle: predominant α+β subunit complexes

1 Human large‐conductance voltage‐ and calcium‐sensitive K+ (maxi KCa) channels are composed of at least two subunits: the pore‐forming subunit, α, and a modulatory subunit, β. Expression of the β subunit induces dramatic changes in α subunit function. It increases the apparent Ca2+ sensitivity and it allows dehydrosoyasaponin I (DHS‐I) to upregulate the channel. 2 The functional coupling of maxi KCa channel α and β subunits in freshly dissociated human coronary smooth muscle cells was assessed. To distinguish maxi KCa currents modulated by the β subunit, we examined (a) their apparent Ca2+ sensitivity, as judged from the voltage necessary to half‐activate the channel (V1/2), and (b) their activation by DHS‐I. 3 In patches with unitary currents, the majority of channels were half‐activated near –85 mV at 18 μm Ca2+, a value similar to that obtained when the human KCa channel α (HSLO) and β (HKVCaβ) subunits are co‐expressed. A small number of channels half‐activated around 0 mV, suggesting the activity of the α subunit alone. 4 The properties of macroscopic currents were consistent with the view that most pore‐forming α subunits were coupled to β subunits, since the majority of currents had values for V1/2 near to –90 mV, and currents were potentiated by DHS‐I. 5 We conclude that in human coronary artery smooth muscle cells, most maxi KCa channels are composed of α and β subunits. The higher Ca2+ sensitivity of maxi KCa channels, resulting from their coupling to β subunits, suggests an important role of this channel in regulating coronary tone. Their massive activation by micromolar Ca2+ concentrations may lead to a large hyperpolarization causing profound changes in coronary blood flow and cardiac function.

Decreased Expression of Voltage- and Ca2+-Activated K+ Channels in Coronary Smooth Muscle During Aging

Abstract— Aging is the main risk factor for coronary artery disease. One characteristic of aging coronary arteries is their enhanced contractile responses to endothelial vasoconstricting factors, which increase the risk of coronary vasospasm in older people. Because large-conductance voltage- and Ca2+-activated K+ channels (MaxiK) are key regulators of vascular tone, we explored the possibility that this class of channels is diminished with increasing age. Using site-directed antibodies recognizing the pore-forming &agr; subunit and electrophysiological methods, we demonstrate that the number of MaxiK channels is dramatically diminished in aged coronary arteries from old F344 rats. Channel density was reduced from 52±9 channels/pF (3 months old) to 18±5 channels/pF (25 to 30 months old), which represents a 65% reduction in the older population. Pixel intensity of Western blots was also diminished by ≈50%. Moreover, the age-related decrease in the channel protein expression was also evident in humans, which showed ≈80% reduction in 61- to 70-year-old subjects compared with 3- to 18-year-old youngsters and ≈45% reduction compared with 19- to 56-year-old adults. In agreement with a reduction of MaxiK channel numbers in aging coronary arteries, old coronary arteries from F344 rats contract less effectively (≈70% reduction) than young coronary arteries when exposed to the MaxiK channel blocker iberiotoxin. The contraction studies indicate that under physiological conditions, MaxiK channels are tonically active, serving as a hyperpolarizing force that opposes contraction. Thus, reduced expression of MaxiK channels in aged coronary arteries would lead to a decreased vasodilating capacity and increased risk of coronary spasm and myocardial ischemia in older people.

Aging, ion channel expression, and vascular function

Cardiovascular disease remains the leading cause of death in the United States, and aging is one of the main risk factors for its development. Coronary arteries nurture the heart, but as age progresses, they suffer changes that make them stiffer, thicker, and with higher spontaneous contractile activity. Even in the absence of pathological atherosclerotic lesions, these changes make the coronary arteries at risk for vasospasm and the individual at risk for myocardial ischemia and heart failure. Thus, knowledge of the molecular mechanisms involved in the vascular physiology, disease, and aging of the coronary circulation is required to develop strategies to preserve the quality of life of an increasingly aging population. One of the key factors that regulate coronary arterial tone is the activity of K+ channels in the vascular smooth muscle cells (SMCs). In particular, voltage-dependent and Ca(2+)-activated K+ (BKCa) channels, which are abundant in the coronary SMCs, are targets of vasoconstrictors and vasorelaxants, and play a key role in determining arterial tone and diameter. Aging induces a reduction in the density of the alpha-subunit of BKCa channels in coronary smooth muscle, lowers baseline endothelial release of the relaxant nitric oxide (NO), and increases the response to endothelial constrictor factors and K+. Thus, aging induces the remodeling of important proteins involved in the excitability and contractility of the coronary circulation. Altogether, these changes increase the risk of coronary artery vasospasm, myocardial ischemia, and infarct in the elderly.

Hormonal control of protein expression and mRNA levels of the MaxiK channel α subunit in myometrium

Large conductance voltage‐dependent and Ca2+‐modulated K+ channels play a crucial role in myometrium contractility. Western blots and immunocytochemistry of rat uterine sections or isolated cells show that MaxiK channel protein signals drastically decrease towards the end of pregnancy. Consistent with a transcriptional regulation of channel expression, mRNA levels quantified with the ribonuclease protection assay correlated well with MaxiK protein levels. As a control, Na+/K+‐ATPase protein and RNA levels do not significantly change at different stages of pregnancy. The low numbers of MaxiK channels at the end of pregnancy may facilitate uterine contraction needed for parturition.

Alternative splicing of Slo channel gene programmed by estrogen, progesterone and pregnancy.

STREX alternative‐exon adds to Slo channel a phosphorylation sequence that can invert protein kinase A (PKA) regulation from excitatory to inhibitory. Because pregnancy switches Slo responsiveness to PKA from inhibitory to excitatory, we hypothesized that STREX expression diminishes with pregnancy and is regulated by sex hormones. Different from total‐rSlo, which is elevated around mid‐pregnancy and decreases at term, STREX transcripts progressively decreased with pregnancy near 80% at term. STREX downregulation was mimicked by estrogen, and opposed by estrogen‐receptor antagonist ICI 182,780 or progesterone (Pg). The regulation of STREX splicing directed by estrogen and Pg provides a mechanism for Slos PKA‐related phenotypic alteration with pregnancy.

Endocytic trafficking signals in kcnmb2 regulate surface expression of a large conductance voltage and Ca2+-activated K+ channel

Large conductance voltage and calcium-activated K(+) channels play critical roles in neuronal excitability and vascular tone. Previously, we showed that coexpression of the transmembrane beta2 subunit, KCNMB2, with the human pore-forming alpha subunit of the large conductance voltage and Ca(2+)-activated K(+) channel (hSlo) yields inactivating currents similar to those observed in hippocampal neurons [Hicks GA, Marrion NV (1998) Ca(2+)-dependent inactivation of large conductance Ca(2+)-activated K(+) (BK) channels in rat hippocampal neurones produced by pore block from an associated particle. J Physiol (Lond) 508 (Pt 3):721-734; Wallner M, Meera P, Toro L (1999b) Molecular basis of fast inactivation in voltage and Ca(2+)-activated K(+) channels: A transmembrane beta-subunit homolog. Proc Natl Acad Sci U S A 96:4137-4142]. Herein, we report that coexpression of beta2 subunit with hSlo can also modulate hSlo surface expression levels in HEK293T cells. We found that, when expressed alone, beta2 subunit appears to reach the plasma membrane but also displays a distinct intracellular punctuated pattern that resembles endosomal compartments. beta2 Subunit coexpression with hSlo causes two biological effects: i) a shift of hSlos intracellular expression pattern from a relatively diffuse to a distinct punctated cytoplasmic distribution overlapping beta2 expression; and ii) a decrease of hSlo surface expression that surpassed an observed small decrease in total hSlo expression levels. beta2 Site-directed mutagenesis studies revealed two putative endocytic signals at the C-terminus of beta2 that can control expression levels of hSlo. In contrast, a beta2 N-terminal consensus endocytic signal had no effect on hSlo expression levels. Thus, beta2 subunit not only can influence hSlo currents but also has the ability to limit hSlo surface expression levels via an endocytic mechanism. This new mode of beta2 modulation of hSlo may depend on particular coregulatory mechanisms in different cell types.

Tissue-specific regulation of Ca2+ channel protein expression by sex hormones

The L-type Ca(2+) channel pore-forming alpha subunit, alpha(1C) can be detected in brain and heart as two proteins with molecular masses of approximately 240 kDa and approximately 190 kDa known as alpha(1C-long) and alpha(1C-short), respectively. In brain, the alpha(1C-short) is thought to be the product of a approximately 50 kDa C-terminus calpain-mediated proteolytic deletion. We now show that uterine smooth muscle also possesses alpha(1C-long) and alpha(1C-short) isoforms, and that the relative expression of these two forms is regulated by sex hormones in a tissue-specific manner. Protein expression of alpha(1C) L-type Ca(2+) channels was examined in uterine smooth muscle, brain and heart, comparing non-pregnant (NP) estrus vs. late-pregnant (21 days) rats. The two forms of alpha(1C) were detected in all studied tissues. In late-pregnant uterus, alpha(1C-long) doubled the expression of alpha(1C-short); in NP uterus the opposite occurred. However, these changes were restricted to the uterine muscle, with no changes in brain and heart. To investigate the mechanism of such regulation, ovariectomized rats were treated with sex hormones, progesterone (P4) and/or 17beta-estradiol (estrogen, E2). P4 treatment, which yielded P4 plasma levels of 5 +/- 1 ng/ml and a high P4/E2 ratio (3 +/- 1.5 x 10(3)) similar to the ratio in late-pregnant uterus (1.5 +/- 0.3 x10(3)), facilitated alpha(1C-long) expression. In contrast, E2 or E2+P4 treatment that increased E2 plasma levels to 60 +/- 8 pg/ml and 75 +/- 24 pg/ml, produced low P4/E2 ratios of 0.03 +/- 0.006 and 0.2 +/- 0.1, respectively. These low P4/E2 ratios also found in NP rats at estrus (0.3 +/- 0.1) favored the expression of alpha(1C-short) form in myometrium. Neither hormone treatment altered alpha(1C) expression in brain or heart. Our results indicate that expression of alpha(1C) isoforms depends on P4/E2 ratios. Plasma P4/E2 ratios <1 x 10(3) favor the expression of the alpha(1C-short); whereas ratios >1 x 10(3) facilitate the expression of the alpha(1C-long) form. This regulation is tissue-specific for myometrium since it did not occur in heart and brain tissues.