A modular switch for spatial Ca2+ selectivity in the calmodulin regulation of CaV channels.

Ca2+/calmodulin-dependent regulation of voltage-gated CaV1-2 Ca2+ channels shows extraordinary modes of spatial Ca2+ decoding and channel modulation, vital for many biological functions. A single calmodulin (CaM) molecule associates constitutively with the channel's carboxy-terminal tail, and Ca2+ binding to the C-terminal and N-terminal lobes of CaM can each induce distinct channel regulations. As expected from close channel proximity, the C-lobe responds to the roughly 100-microM Ca2+ pulses driven by the associated channel, a behaviour defined as 'local Ca2+ selectivity'. Conversely, all previous observations have indicated that the N-lobe somehow senses the far weaker signals from distant Ca2+ sources. This 'global Ca2+ selectivity' satisfies a general signalling requirement, enabling a resident molecule to remotely sense cellular Ca2+ activity, which would otherwise be overshadowed by Ca2+ entry through the host channel. Here we show that the spatial Ca2+ selectivity of N-lobe CaM regulation is not invariably global but can be switched by a novel Ca2+/CaM-binding site within the amino terminus of channels (NSCaTE, for N-terminal spatial Ca2+ transforming element). Native CaV2.2 channels lack this element and show N-lobe regulation with a global selectivity. On the introduction of NSCaTE into these channels, spatial Ca2+ selectivity transforms from a global to local profile. Given this effect, we examined CaV1.2/CaV1.3 channels, which naturally contain NSCaTE, and found that their N-lobe selectivity is indeed local. Disruption of this element produces a global selectivity, confirming the native function of NSCaTE. Thus, differences in spatial selectivity between advanced CaV1 and CaV2 channel isoforms are explained by the presence or absence of NSCaTE. Beyond functional effects, the position of NSCaTE on the channel's amino terminus indicates that CaM can bridge the amino terminus and carboxy terminus of channels. Finally, the modularity of NSCaTE offers practical means for understanding the basis of global Ca2+ selectivity.

G protein-gated inhibitory module of N-type (ca(v)2.2) ca2+ channels.

Voltage-dependent G protein (Gbetagamma) inhibition of N-type (CaV2.2) channels supports presynaptic inhibition and represents a central paradigm of channel modulation. Still controversial are the proposed determinants for such modulation, which reside on the principal alpha1B channel subunit. These include the interdomain I-II loop (I-II), the carboxy tail (CT), and the amino terminus (NT). Here, we probed these determinants and related mechanisms, utilizing compound-state analysis with yeast two-hybrid and mammalian cell FRET assays of binding among channel segments and G proteins. Chimeric channels confirmed the unique importance of NT. Binding assays revealed selective interaction between NT and I-II elements. Coexpressing NT peptide with Gbetagamma induced constitutive channel inhibition, suggesting that the NT domain constitutes a G protein-gated inhibitory module. Such inhibition was limited to NT regions interacting with I-II, and G-protein inhibition was abolished within alpha1B channels lacking these NT regions. Thus, an NT module, acting via interactions with the I-II loop, appears fundamental to such modulation.

Live-cell transforms between Ca2+ transients and FRET responses for a troponin-C-based Ca2+ sensor.

Genetically encoded Ca(2+) sensors promise sustained in vivo detection of Ca(2+) signals. However, these sensors are sometimes challenged by inconsistent performance and slow/uncertain kinetic responsiveness. The former challenge may arise because most sensors employ calmodulin (CaM) as the Ca(2+)-sensing module, such that interference via endogenous CaM may result. One class of sensors that could minimize this concern utilizes troponin C as the Ca(2+) sensor. Here, we therefore probed the reliability and kinetics of one representative of this class (cyan fluorescence protein/yellow fluorescent protein-fluorescence resonance energy transfer (FRET) sensor TN-L15) within cardiac ventricular myocytes. These cells furnished a pertinent live-cell test environment, given substantial endogenous CaM levels and fast reproducible Ca(2+) transients for testing sensor kinetics. TN-L15 was virally expressed within myocytes, and Indo-1 acutely loaded to monitor "true" Ca(2+) transients. This configuration permitted independent and simultaneous detection of TN-L15 and Indo-1 signals within individual cells. The relation between TN-L15 FRET responses and Indo-1 Ca(2+) transients appeared reproducible, though FRET signals were delayed compared to Ca(2+) transients. Nonetheless, a three-state mechanism sufficed to map between measured Ca(2+) transients and actual TN-L15 outputs. Overall, reproducibility of TN-L15 dynamics, coupled with algorithmic transforms between FRET and Ca(2+) signals, renders these sensors promising for quantitative estimation of Ca(2+) dynamics in vivo.

A CaVbeta SH3/guanylate kinase domain interaction regulates multiple properties of voltage-gated Ca2+ channels.

Auxiliary Ca(2+) channel beta subunits (Ca(V)beta) regulate cellular Ca(2+) signaling by trafficking pore-forming alpha(1) subunits to the membrane and normalizing channel gating. These effects are mediated through a characteristic src homology 3/guanylate kinase (SH3-GK) structural module, a design feature shared in common with the membrane-associated guanylate kinase (MAGUK) family of scaffold proteins. However, the mechanisms by which the Ca(V)beta SH3-GK module regulates multiple Ca(2+) channel functions are not well understood. Here, using a split-domain approach, we investigated the role of the interrelationship between Ca(V)beta SH3 and GK domains in defining channel properties. The studies build upon a previously identified split-domain pair that displays a trans SH3-GK interaction, and fully reconstitutes Ca(V)beta effects on channel trafficking, activation gating, and increased open probability (P(o)). Here, by varying the precise locations used to separate SH3 and GK domains and monitoring subsequent SH3-GK interactions by fluorescence resonance energy transfer (FRET), we identified a particular split-domain pair that displayed a subtly altered configuration of the trans SH3-GK interaction. Remarkably, this pair discriminated between Ca(V)beta trafficking and gating properties: alpha(1C) targeting to the membrane was fully reconstituted, whereas shifts in activation gating and increased P(o) functions were selectively lost. A more extreme case, in which the trans SH3-GK interaction was selectively ablated, yielded a split-domain pair that could reconstitute neither the trafficking nor gating-modulation functions, even though both moieties could independently engage their respective binding sites on the alpha(1C) (Ca(V)1.2) subunit. The results reveal that Ca(V)beta SH3 and GK domains function codependently to tune Ca(2+) channel trafficking and gating properties, and suggest new paradigms for physiological and therapeutic regulation of Ca(2+) channel activity.

Nanodomain Ca²âº of Ca²âº channels detected by a tethered genetically encoded Ca²âº sensor.

Coupling of excitation to secretion, contraction and transcription often relies on Ca(2+) computations within the nanodomain-a conceptual region extending tens of nanometers from the cytoplasmic mouth of Ca(2+) channels. Theory predicts that nanodomain Ca(2+) signals differ vastly from the slow submicromolar signals routinely observed in bulk cytoplasm. However, direct visualization of nanodomain Ca(2+) far exceeds optical resolution of spatially distributed Ca(2+) indicators. Here we couple an optical, genetically encoded Ca(2+) indicator (TN-XL) to the carboxy tail of Ca(V)2.2 Ca(2+) channels, enabling near-field imaging of the nanodomain. Under total internal reflection fluorescence microscopy, we detect Ca(2+) responses indicative of large-amplitude pulses. Single-channel electrophysiology reveals a corresponding Ca(2+) influx of only 0.085 pA, and fluorescence resonance energy transfer measurements estimate TN-XL distance to the cytoplasmic mouth at ~55 Å. Altogether, these findings raise the possibility that Ca(2+) exits the channel through the analogue of molecular portals, mirroring the crystallographic images of side windows in voltage-gated K channels.