The Ca2+ channel β2 subunit is selectively targeted to the axon terminals of supraoptic neurons

The assembly of high voltage-activated Ca²⁺ channels with different β subunits influences channel properties and possibly subcellular targeting. We studied β subunit expression in the somata and axon terminals of the magnocellular neurosecretory cells, which are located in the supraoptic nucleus (SON) and neurohypophysis, respectively. Antibodies directed against the 4 Ca_Vβ subunits (Ca_Vβ₁-Ca_Vβ₄) were used for immunoblots and for immunostaining of slices of these two tissues. We found that all 4 β subunits are expressed in both locations, but that Ca_Vβ₂ had the highest relative expression in the neurohypophysis. These data suggest that the Ca_Vβ₂ subunit is selectively targeted to axon terminals and may play a role in targeting and/or regulating the properties of Ca²⁺ channels.     

Ca2+/Calmodulin-Dependent Protein Kinase Kinases (CaMKKs) Effects on AMP-Activated Protein Kinase (AMPK) Regulation of Chicken Sperm Functions

Sperm require high levels of energy to ensure motility and acrosome reaction (AR) accomplishment. The AMP-activated protein kinase (AMPK) has been demonstrated to be strongly involved in the control of these properties. We address here the question of the potential role of calcium mobilization on AMPK activation and function in chicken sperm through the Ca²⁺/calmodulin-dependent protein kinase kinases (CaMKKs) mediated pathway. The presence of CaMKKs and their substrates CaMKI and CaMKIV was evaluated by western-blotting and indirect immunofluorescence. Sperm were incubated in presence or absence of extracellular Ca²⁺, or of CaMKKs inhibitor (STO-609). Phosphorylations of AMPK, CaMKI, and CaMKIV, as well as sperm functions were evaluated. We demonstrate the presence of both CaMKKs (α and β), CaMKI and CaMKIV in chicken sperm. CaMKKα and CaMKI were localized in the acrosome, the midpiece, and at much lower fluorescence in the flagellum, whereas CaMKKβ was mostly localized in the flagellum and much less in the midpiece and the acrosome. CaMKIV was only present in the flagellum. The presence of extracellular calcium induced an increase in kinases phosphorylation and sperm activity. STO-609 reduced AMPK phosphorylation in the presence of extracellular Ca²⁺ but not in its absence. STO-609 did not affect CaMKIV phosphorylation but decreased CaMKI phosphorylation and this inhibition was quicker in the presence of extracellular Ca²⁺ than in its absence. STO-609 efficiently inhibited sperm motility and AR, both in the presence and absence of extracellular Ca²⁺. Our results show for the first time the presence of CaMKKs (α and β) and one of its substrate, CaMKI in different subcellular compartments in germ cells, as well as the changes in the AMPK regulation pathway, sperm motility and AR related to Ca²⁺ entry in sperm through the Ca²⁺/CaM/CaMKKs/CaMKI pathway. The Ca²⁺/CaMKKs/AMPK pathway is activated only under conditions of extracellular Ca²⁺ entry in the cells.     

Role of the beta1 subunit in large-conductance Ca(2+)-activated K(+) channel gating energetics. Mechanisms of enhanced Ca(2+) sensitivity

Over the past few years, it has become clear that an important mechanism by which large-conductance Ca²⁺-activated K⁺ channel (BK_Ca) activity is regulated is the tissue-specific expression of auxiliary β subunits. The first of these to be identified, β1, is expressed predominately in smooth muscle and causes dramatic effects, increasing the apparent affinity of the channel for Ca²⁺ 10-fold at 0 mV, and shifting the range of voltages over which the channel activates −80 mV at 9.1 μM Ca²⁺. With this study, we address the question: which aspects of BK_Ca gating are altered by β1 to bring about these effects: Ca²⁺ binding, voltage sensing, or the intrinsic energetics of channel opening? The approach we have taken is to express the β1 subunit together with the BK_Ca α subunit in Xenopus oocytes, and then to compare β1''s steady state effects over a wide range of Ca²⁺ concentrations and membrane voltages to those predicted by allosteric models whose parameters have been altered to mimic changes in the aspects of gating listed above. The results of our analysis suggest that much of β1''s steady state effects can be accounted for by a reduction in the intrinsic energy the channel must overcome to open and a decrease in its voltage sensitivity, with little change in the affinity of the channel for Ca²⁺ when it is either open or closed. Interestingly, however, the small changes in Ca²⁺ binding affinity suggested by our analysis (K_c 7.4 μM → 9.6 μM; K_o = 0.80 μM → 0.65 μM) do appear to be functionally important. We also show that β1 affects the mSlo conductance–voltage relation in the essential absence of Ca²⁺, shifting it +20 mV and reducing its apparent gating charge 38%, and we develop methods for distinguishing between alterations in Ca²⁺ binding and other aspects of BK_Ca channel gating that may be of general use.     

Arachidonic acid inhibition of L-type calcium (CaV1.3b) channels varies with accessory CaVβ subunits

Arachidonic acid (AA) inhibits the activity of several different voltage-gated Ca²⁺ channels by an unknown mechanism at an unknown site. The Ca²⁺ channel pore-forming subunit (Ca_Vα₁) is a candidate for the site of AA inhibition because T-type Ca²⁺ channels, which do not require accessory subunits for expression, are inhibited by AA. Here, we report the unanticipated role of accessory Ca_Vβ subunits on the inhibition of Ca_V1.3b L-type (L-) current by AA. Whole cell Ba²⁺ currents were measured from recombinant channels expressed in human embryonic kidney 293 cells at a test potential of −10 mV from a holding potential of −90 mV. A one-minute exposure to 10 µM AA inhibited currents with β_1b, β₃, or β₄ 58, 51, or 44%, respectively, but with β_2a only 31%. At a more depolarized holding potential of −60 mV, currents were inhibited to a lesser degree. These data are best explained by a simple model where AA stabilizes Ca_V1.3b in a deep closed-channel conformation, resulting in current inhibition. Consistent with this hypothesis, inhibition by AA occurred in the absence of test pulses, indicating that channels do not need to open to become inhibited. AA had no effect on the voltage dependence of holding potential–dependent inactivation or on recovery from inactivation regardless of Ca_Vβ subunit. Unexpectedly, kinetic analysis revealed evidence for two populations of L-channels that exhibit willing and reluctant gating previously described for Ca_V2 channels. AA preferentially inhibited reluctant gating channels, revealing the accelerated kinetics of willing channels. Additionally, we discovered that the palmitoyl groups of β_2a interfere with inhibition by AA. Our novel findings that the Ca_Vβ subunit alters kinetic changes and magnitude of inhibition by AA suggest that Ca_Vβ expression may regulate how AA modulates Ca²⁺-dependent processes that rely on L-channels, such as gene expression, enzyme activation, secretion, and membrane excitability.     

TRPC5 Is a Ca2+-activated Channel Functionally Coupled to Ca2+-selective Ion Channels

TRPC5 forms non-selective cation channels. Here we studied the role of internal Ca²⁺ in the activation of murine TRPC5 heterologously expressed in human embryonic kidney cells. Cell dialysis with various Ca²⁺ concentrations (Ca²⁺_i) revealed a dose-dependent activation of TRPC5 channels by internal Ca²⁺ with EC₅₀ of 635.1 and 358.2 nm at negative and positive membrane potentials, respectively. Stepwise increases of Ca²⁺_i induced by photolysis of caged Ca²⁺ showed that the Ca²⁺ activation of TRPC5 channels follows a rapid exponential time course with a time constant of 8.6 ± 0.2 ms at Ca²⁺_i below 10 μm, suggesting that the action of internal Ca²⁺ is a primary mechanism in the activation of TRPC5 channels. A second slow activation phase with a time to peak of 1.4 ± 0.1 s was also observed at Ca²⁺_i above 10 μm. In support of a Ca²⁺-activation mechanism, the thapsigargin-induced release of Ca²⁺ from internal stores activated TRPC5 channels transiently, and the subsequent Ca²⁺ entry produced a sustained TRPC5 activation, which in turn supported a long-lasting membrane depolarization. By co-expressing STIM1 plus ORAI1 or the α₁C and β₂ subunits of L-type Ca²⁺ channels, we found that Ca²⁺ entry through either calcium-release-activated-calcium or voltage-dependent Ca²⁺ channels is sufficient for TRPC5 channel activation. The Ca²⁺ entry activated TRPC5 channels under buffering of internal Ca²⁺ with EGTA but not with BAPTA. Our data support the hypothesis that TRPC5 forms Ca²⁺-activated cation channels that are functionally coupled to Ca²⁺-selective ion channels through local Ca²⁺ increases beneath the plasma membrane.     

Phosphorylation of the Consensus Sites of Protein Kinase A on ��1D L-type Calcium Channel

The novel α_1D L-type Ca²⁺ channel is expressed in supraventricular tissue and has been implicated in the pacemaker activity of the heart and in atrial fibrillation. We recently demonstrated that PKA activation led to increased α_1D Ca²⁺ channel activity in tsA201 cells by phosphorylation of the channel protein. Here we sought to identify the phosphorylated PKA consensus sites on the α₁ subunit of the α_1D Ca²⁺ channel by generating GST fusion proteins of the intracellular loops, N terminus, proximal and distal C termini of the α₁ subunit of α_1D Ca²⁺ channel. An in vitro PKA kinase assay was performed for the GST fusion proteins, and their phosphorylation was assessed by Western blotting using either anti-PKA substrate or anti-phosphoserine antibodies. Western blotting showed that the N terminus and C terminus were phosphorylated. Serines 1743 and 1816, two PKA consensus sites, were phosphorylated by PKA and identified by mass spectrometry. Site directed mutagenesis and patch clamp studies revealed that serines 1743 and 1816 were major functional PKA consensus sites. Altogether, biochemical and functional data revealed that serines 1743 and 1816 are major functional PKA consensus sites on the α₁ subunit of α_1D Ca²⁺ channel. These novel findings provide new insights into the autonomic regulation of the α_1D Ca²⁺ channel in the heart.L-type Ca²⁺ channels are essential for the generation of normal cardiac rhythm, for induction of rhythm propagation through the atrioventricular node and for the contraction of the atrial and ventricular muscles (1–5). L-type Ca²⁺ channel is a multisubunit complex including α₁, β and α₂/δ subunits (5–7). The α₁ subunit contains the voltage sensor, the selectivity filter, the ion conduction pore, and the binding sites for all known Ca²⁺ channel blockers (6–9). While α_1C Ca²⁺ channel is expressed in the atria and ventricles of the heart (10–13), expression of α_1D Ca²⁺ channel is restricted to the sinoatrial (SA)² and atrioventricular (AV) nodes, as well as in the atria, but not in the adult ventricles (2, 3, 10).Only recently it has been realized that α_1D along with α_1C Ca²⁺ channels contribute to L-type Ca²⁺ current (I_Ca-L) and they both play important but unique roles in the physiology/pathophysiology of the heart (6–9). Compared with α_1C, α_1D L-type Ca²⁺ channel activates at a more negative voltage range and shows slower current inactivation during depolarization (14, 15). These properties may allow α_1D Ca²⁺ channel to play critical roles in SA and AV nodes function. Indeed, α_1D Ca²⁺ channel knock-out mice exhibit significant SA dysfunction and various degrees of AV block (12, 16–19).The modulation of α_1C Ca²⁺ channel by cAMP-dependent PKA phosphorylation has been extensively studied, and the C terminus of α₁ was identified as the site of the modulation (20–22). Our group was the first to report that 8-bromo-cAMP (8-Br-cAMP), a membrane-permeable cAMP analog, increased α_1D Ca²⁺ channel activity using patch clamp studies (2). However, very little is known about potential PKA phosphorylation consensus motifs on the α_1D Ca²⁺ channel. We therefore hypothesized that the C terminus of the α₁ subunit of the α_1D Ca²⁺ channel mediates its modulation by cAMP-dependent PKA pathway.     

Abnormal Ca2+ Spark/STOC Coupling in Cerebral Artery Smooth Muscle Cells of Obese Type 2 Diabetic Mice

Diabetes is a major risk factor for stroke. However, the molecular mechanisms involved in cerebral artery dysfunction found in the diabetic patients are not completely elucidated. In cerebral artery smooth muscle cells (CASMCs), spontaneous and local increases of intracellular Ca2+ due to the opening of ryanodine receptors (Ca2+ sparks) activate large conductance Ca2+-activated K+ (BK) channels that generate spontaneous transient outward currents (STOCs). STOCs have a key participation in the control of vascular myogenic tone and blood pressure. Our goal was to investigate whether alterations in Ca²⁺ spark and STOC activities, measured by confocal microscopy and patch-clamp technique, respectively, occur in isolated CASMCs of an experimental model of type-2 diabetes (db/db mouse). We found that mean Ca²⁺ spark amplitude, duration, size and rate-of-rise were significantly smaller in Fluo-3 loaded db/db compared to control CASMCs, with a subsequent decrease in the total amount of Ca²⁺ released through Ca²⁺ sparks in db/db CASMCs, though Ca²⁺ spark frequency remained. Interestingly, the frequency of large-amplitude Ca²⁺ sparks was also significantly reduced in db/db cells. In addition, the frequency and amplitude of STOCs were markedly reduced at all voltages tested (from −50 to 0 mV) in db/db CASMCs. The latter correlates with decreased BK channel β1/α subunit ratio found in db/db vascular tissues. Taken together, Ca²⁺ spark alterations lead to inappropriate BK channels activation in CASMCs of db/db mice and this condition is aggravated by the decrease in the BK β1 subunit/α subunit ratio which underlies the significant reduction of Ca²⁺ spark/STOC coupling in CASMCs of diabetic animals.     

Enhancement effects of martentoxin on glioma BK channel and BK channel (α+β1) subtypes

Background

BK channels are usually activated by membrane depolarization and cytoplasmic Ca²⁺. Especially,the activity of BK channel (α+β4) can be modulated by martentoxin, a 37 residues peptide, with Ca²⁺-dependent manner. gBK channel (glioma BK channel) and BK channel (α+β1) possessed higher Ca²⁺ sensitivity than other known BK channel subtypes.

Methodology and Principal Findings

The present study investigated the modulatory characteristics of martentoxin on these two BK channel subtypes by electrophysiological recordings, cell proliferation and Ca²⁺ imaging. In the presence of cytoplasmic Ca²⁺, martentoxin could enhance the activities of both gBK and BK channel (α+β1) subtypes in dose-dependent manner with EC₅₀ of 46.7 nM and 495 nM respectively, while not shift the steady-state activation of these channels. The enhancement ratio of martentoxin on gBK and BK channel (α+β1) was unrelated to the quantitive change of cytoplasmic Ca²⁺ concentrations though the interaction between martentoxin and BK channel (α+β1) was accelerated under higher cytoplasmic Ca²⁺. The selective BK pore blocker iberiotoxin could fully abolish the enhancement of these two BK subtypes induced by martentoxin, suggesting that the auxiliary β subunit might contribute to the docking for martentoxin. However, in the absence of cytoplasmic Ca²⁺, the activity of gBK channel would be surprisingly inhibited by martentoxin while BK channel (α+β1) couldn''t be affected by the toxin.

Conclusions and Significance

Thus, the results shown here provide the novel evidence that martentoxin could increase the two Ca²⁺-hypersensitive BK channel subtypes activities in a new manner and indicate that β subunit of these BK channels plays a vital role in this enhancement by martentoxin.     

Splice Variants of Na(V)1.7 Sodium Channels Have Distinct β Subunit-Dependent Biophysical Properties

Genes encoding the α subunits of neuronal sodium channels have evolutionarily conserved sites of alternative splicing but no functional differences have been attributed to the splice variants. Here, using Na_V1.7 as an exemplar, we show that the sodium channel isoforms are functionally distinct when co-expressed with β subunits. The gene, SCN9A, encodes the α subunit of the Na_V1.7 channel, and contains both sites of alternative splicing that are highly conserved. In conditions where the intrinsic properties of the Na_V1.7 splice variants were similar when expressed alone, co-expression of β1 subunits had different effects on channel availability that were determined by splicing at either site in the α subunit. While the identity of exon 5 determined the degree to which β1 subunits altered voltage-dependence of activation (P = 0.027), the length of exon 11 regulated how far β1 subunits depolarised voltage-dependence of inactivation (P = 0.00012). The results could have a significant impact on channel availability, for example with the long version of exon 11, the co-expression of β1 subunits could lead to nearly twice as large an increase in channel availability compared to channels containing the short version. Our data suggest that splicing can change the way that Na_V channels interact with β subunits. Because splicing is conserved, its unexpected role in regulating the functional impact of β subunits may apply to multiple voltage-gated sodium channels, and the full repertoire of β subunit function may depend on splicing in α subunits.     

Interactions between β Subunits of the KCNMB Family and Slo3: β4 Selectively Modulates Slo3 Expression and Function

Background

The pH and voltage-regulated Slo3 K⁺ channel, a homologue of the Ca²⁺- and voltage-regulated Slo1 K⁺ channel, is thought to be primarily expressed in sperm, but the properties of Slo3 studied in heterologous systems differ somewhat from the native sperm KSper pH-regulated current. There is the possibility that critical partners that regulate Slo3 function remain unidentified. The extensive amino acid identity between Slo3 and Slo1 suggests that auxiliary β subunits regulating Slo1 channels might coassemble with and modulate Slo3 channels. Four distinct β subunits composing the KCNMB family are known to regulate the function and expression of Slo1 Channels.

Methodology/Principal Findings

To examine the ability of the KCNMB family of auxiliary β subunits to regulate Slo3 function, we co-expressed Slo3 and each β subunit in heterologous expression systems and investigated the functional consequences by electrophysiological and biochemical analyses. The β4 subunit produced an 8–10 fold enhancement of Slo3 current expression in Xenopus oocytes and a similar enhancement of Slo3 surface expression as monitored by YFP-tagged Slo3 or biotin labeled Slo3. Neither β1, β2, nor β3 mimicked the ability of β4 to increase surface expression, although biochemical tests suggested that all four β subunits are competent to coassemble with Slo3. Fluorescence microscopy from β4 KO mice, in which an eGFP tag replaced the deleted exon, revealed that β4 gene promoter is active in spermatocytes. Furthermore, quantitative RT-PCR demonstrated that β4 and Slo3 exhibit comparable mRNA abundance in both testes and sperm.

Conclusions/Significance

These results argue that, for native mouse Slo3 channels, the β4 subunit must be considered as a potential interaction partner and, furthermore, that KCNMB subunits may have functions unrelated to regulation of the Slo1 α subunit.     

Two distinct effects of PIP2 underlie auxiliary subunit-dependent modulation of Slo1 BK channels

Phosphatidylinositol 4,5-bisphosphate (PIP₂) plays a critical role in modulating the function of numerous ion channels, including large-conductance Ca²⁺- and voltage-dependent K⁺ (BK, Slo1) channels. Slo1 BK channel complexes include four pore-forming Slo1 (α) subunits as well as various regulatory auxiliary subunits (β and γ) that are expressed in different tissues. We examined the molecular and biophysical mechanisms underlying the effects of brain-derived PIP₂ on human Slo1 BK channel complexes with different subunit compositions that were heterologously expressed in human embryonic kidney cells. PIP₂ inhibited macroscopic currents through Slo1 channels without auxiliary subunits and through Slo1 + γ1 complexes. In contrast, PIP₂ markedly increased macroscopic currents through Slo1 + β1 and Slo1 + β4 channel complexes and failed to alter macroscopic currents through Slo1 + β2 and Slo1 + β2 Δ2–19 channel complexes. Results obtained at various membrane potentials and divalent cation concentrations suggest that PIP₂ promotes opening of the ion conduction gate in all channel types, regardless of the specific subunit composition. However, in the absence of β subunits positioned near the voltage-sensor domains (VSDs), as in Slo1 and probably Slo1 + γ1, PIP₂ augments the negative surface charge on the cytoplasmic side of the membrane, thereby shifting the voltage dependence of VSD-mediated activation in the positive direction. When β1 or β4 subunits occupy the space surrounding the VSDs, only the stimulatory effect of PIP₂ is evident. The subunit compositions of native Slo1 BK channels differ in various cell types; thus, PIP₂ may exert distinct tissue- and divalent cation–dependent modulatory influences.     

The smooth muscle-type β1 subunit potentiates activation by DiBAC4(3) in recombinant BK channels

Large-conductance Ca²⁺-activated (BK) channels, expressed in a variety of tissues, play a fundamental role in regulating and maintaining arterial tone. We recently demonstrated that the slow voltage indicator DiBAC₄(3) does not depend, as initially proposed, on the β₁ or β₄ subunits to activate native arterial smooth muscle BK channels. Using recombinant mslo BK channels, we now show that the β₁ subunit is not essential to this activation but exerts a large potentiating effect. DiBAC₄(3) promotes concentration-dependent activation of BK channels and slows deactivation kinetics, changes that are independent of Ca²⁺. K_d values for BK channel activation by DiBAC₄(3) in 0 mM Ca²⁺ are approximately 20 μM (α) and 5 μM (α+β₁), and G-V curves shift up to −40mV and −110 mV, respectively. β₁ to β₂ mutations R11A and C18E do not interfere with the potentiating effect of the subunit. Our findings should help refine the role of the β₁ subunit in cardiovascular pharmacology.     

Akt regulates L-type Ca2+ channel activity by modulating Cavα1 protein stability

The insulin IGF-1–PI3K–Akt signaling pathway has been suggested to improve cardiac inotropism and increase Ca²⁺ handling through the effects of the protein kinase Akt. However, the underlying molecular mechanisms remain largely unknown. In this study, we provide evidence for an unanticipated regulatory function of Akt controlling L-type Ca²⁺ channel (LTCC) protein density. The pore-forming channel subunit Ca_vα1 contains highly conserved PEST sequences (signals for rapid protein degradation), and in-frame deletion of these PEST sequences results in increased Ca_vα1 protein levels. Our findings show that Akt-dependent phosphorylation of Ca_vβ2, the LTCC chaperone for Ca_vα1, antagonizes Ca_vα1 protein degradation by preventing Ca_vα1 PEST sequence recognition, leading to increased LTCC density and the consequent modulation of Ca²⁺ channel function. This novel mechanism by which Akt modulates LTCC stability could profoundly influence cardiac myocyte Ca²⁺ entry, Ca²⁺ handling, and contractility.     

Characterization of Cav1.4 Complexes (α11.4, β2, and α2δ4) in HEK293T Cells and in the Retina

In photoreceptor synaptic terminals, voltage-gated Ca_v1.4 channels mediate Ca²⁺ signals required for transmission of visual stimuli. Like other high voltage-activated Ca_v channels, Ca_v1.4 channels are composed of a main pore-forming Ca_v1.4 α₁ subunit and auxiliary β and α₂δ subunits. Of the four distinct classes of β and α₂δ, β₂ and α₂δ₄ are thought to co-assemble with Ca_v1.4 α₁ subunits in photoreceptors. However, an understanding of the functional properties of this combination of Ca_v subunits is lacking. Here, we provide evidence that Ca_v1.4 α₁, β₂, and α₂δ₄ contribute to Ca_v1.4 channel complexes in the retina and describe their properties in electrophysiological recordings. In addition, we identified a variant of β₂, named here β_2X13, which, along with β_2a, is present in photoreceptor terminals. Ca_v1.4 α_1, β₂, and α₂δ₄ were coimmunoprecipitated from lysates of transfected HEK293 cells and mouse retina and were found to interact in the outer plexiform layer of the retina containing the photoreceptor synaptic terminals, by proximity ligation assays. In whole-cell patch clamp recordings of transfected HEK293T cells, channels (Ca_v1.4 α₁ + β_2X13) containing α₂δ₄ exhibited weaker voltage-dependent activation than those with α₂δ₁. Moreover, compared with channels (Ca_v1.4 α₁ + α₂δ₄) with β_2a, β_2X13-containing channels exhibited greater voltage-dependent inactivation. The latter effect was specific to Ca_v1.4 because it was not seen for Ca_v1.2 channels. Our results provide the first detailed functional analysis of the Ca_v1.4 subunits that form native photoreceptor Ca_v1.4 channels and indicate potential heterogeneity in these channels conferred by β_2a and β_2X13 variants.     

Gene Splicing of an Invertebrate Beta Subunit (LCavβ) in the N-Terminal and HOOK Domains and Its Regulation of LCav1 and LCav2 Calcium Channels

The accessory beta subunit (Ca_vβ) of calcium channels first appear in the same genome as Ca_v1 L-type calcium channels in single-celled coanoflagellates. The complexity of this relationship expanded in vertebrates to include four different possible Ca_vβ subunits (β₁, β₂, β₃, β₄) which associate with four Ca_v1 channel isoforms (Ca_v1.1 to Ca_v1.4) and three Ca_v2 channel isoforms (Ca_v2.1 to Ca_v2.3). Here we assess the fundamentally-shared features of the Ca_vβ subunit in an invertebrate model (pond snail Lymnaea stagnalis) that bears only three homologous genes: (LCa_v1, LCa_v2, and LCa_vβ). Invertebrate Ca_vβ subunits (in flatworms, snails, squid and honeybees) slow the inactivation kinetics of Ca_v2 channels, and they do so with variable N-termini and lacking the canonical palmitoylation residues of the vertebrate β2a subunit. Alternative splicing of exon 7 of the HOOK domain is a primary determinant of a slow inactivation kinetics imparted by the invertebrate LCa_vβ subunit. LCa_vβ will also slow the inactivation kinetics of LCa_v3 T-type channels, but this is likely not physiologically relevant in vivo. Variable N-termini have little influence on the voltage-dependent inactivation kinetics of differing invertebrate Ca_vβ subunits, but the expression pattern of N-terminal splice isoforms appears to be highly tissue specific. Molluscan LCa_vβ subunits have an N-terminal “A” isoform (coded by exons: 1a and 1b) that structurally resembles the muscle specific variant of vertebrate β1a subunit, and has a broad mRNA expression profile in brain, heart, muscle and glands. A more variable “B” N-terminus (exon 2) in the exon position of mammalian β3 and has a more brain-centric mRNA expression pattern. Lastly, we suggest that the facilitation of closed-state inactivation (e.g. observed in Ca_v2.2 and Ca_vβ₃ subunit combinations) is a specialization in vertebrates, because neither snail subunit (LCa_v2 nor LCa_vβ) appears to be compatible with this observed property.     

The Cellular and Molecular Basis of Bitter Tastant-Induced Bronchodilation

Bronchodilators are a standard medicine for treating airway obstructive diseases, and β2 adrenergic receptor agonists have been the most commonly used bronchodilators since their discovery. Strikingly, activation of G-protein-coupled bitter taste receptors (TAS2Rs) in airway smooth muscle (ASM) causes a stronger bronchodilation in vitro and in vivo than β2 agonists, implying that new and better bronchodilators could be developed. A critical step towards realizing this potential is to understand the mechanisms underlying this bronchodilation, which remain ill-defined. An influential hypothesis argues that bitter tastants generate localized Ca²⁺ signals, as revealed in cultured ASM cells, to activate large-conductance Ca²⁺-activated K⁺ channels, which in turn hyperpolarize the membrane, leading to relaxation. Here we report that in mouse primary ASM cells bitter tastants neither evoke localized Ca²⁺ events nor alter spontaneous local Ca²⁺ transients. Interestingly, they increase global intracellular [Ca²⁺]_i, although to a much lower level than bronchoconstrictors. We show that these Ca²⁺ changes in cells at rest are mediated via activation of the canonical bitter taste signaling cascade (i.e., TAS2R-gustducin-phospholipase Cβ [PLCβ]- inositol 1,4,5-triphosphate receptor [IP3R]), and are not sufficient to impact airway contractility. But activation of TAS2Rs fully reverses the increase in [Ca²⁺]_i induced by bronchoconstrictors, and this lowering of the [Ca²⁺]_i is necessary for bitter tastant-induced ASM cell relaxation. We further show that bitter tastants inhibit L-type voltage-dependent Ca²⁺ channels (VDCCs), resulting in reversal in [Ca²⁺]_i, and this inhibition can be prevented by pertussis toxin and G-protein βγ subunit inhibitors, but not by the blockers of PLCβ and IP3R. Together, we suggest that TAS2R stimulation activates two opposing Ca²⁺ signaling pathways via Gβγ to increase [Ca²⁺]_i at rest while blocking activated L-type VDCCs to induce bronchodilation of contracted ASM. We propose that the large decrease in [Ca²⁺]_i caused by effective tastant bronchodilators provides an efficient cell-based screening method for identifying potent dilators from among the many thousands of available bitter tastants.     

Evolutionary Genomics Reveals Lineage-Specific Gene Loss and Rapid Evolution of a Sperm-Specific Ion Channel Complex: CatSpers and CatSperβ

The mammalian CatSper ion channel family consists of four sperm-specific voltage-gated Ca²⁺ channels that are crucial for sperm hyperactivation and male fertility. All four CatSper subunits are believed to assemble into a heteromultimeric channel complex, together with an auxiliary subunit, CatSperβ. Here, we report a comprehensive comparative genomics study and evolutionary analysis of CatSpers and CatSperβ, with important correlation to physiological significance of molecular evolution of the CatSper channel complex. The development of the CatSper channel complex with four CatSpers and CatSperβ originated as early as primitive metazoans such as the Cnidarian Nematostella vectensis. Comparative genomics revealed extensive lineage-specific gene loss of all four CatSpers and CatSperβ through metazoan evolution, especially in vertebrates. The CatSper channel complex underwent rapid evolution and functional divergence, while distinct evolutionary constraints appear to have acted on different domains and specific sites of the four CatSper genes. These results reveal unique evolutionary characteristics of sperm-specific Ca²⁺ channels and their adaptation to sperm biology through metazoan evolution.