Calcium dependence of both lobes of calmodulin is involved in binding to a cytoplasmic domain of SK channels

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    This manuscript provides compelling evidence that in response to calcium, the C-lobe of calmodulin changes its interaction with the C-terminal domain of an SK2 small-conductance calcium-activated potassium channel. These findings will be of interest to those in the field of ion channels and calcium signaling as they are valuable to understanding the molecular mechanics by which calcium activates SK2 channels, which are important for a wide variety of physiological signaling processes.

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Abstract

KCa2.1–3 Ca 2+ -activated K + -channels (SK) require calmodulin to gate in response to cellular Ca 2+ . A model for SK gating proposes that the N-terminal domain (N-lobe) of calmodulin is required for activation, but an immobile C-terminal domain (C-lobe) has constitutive, Ca 2+ -independent binding. Although structures support a domain-driven hypothesis of SK gate activation by calmodulin, only a partial understanding is possible without measuring both channel activity and protein binding. We measured SK2 (KCa2.2) activity using inside-out patch recordings. Currents from calmodulin-disrupted SK2 channels can be restored with exogenously applied calmodulin. We find that SK2 activity only approaches full activation with full-length calmodulin with both an N- and a C-lobe. We measured calmodulin binding to a C-terminal SK peptide (SKp) using both composition-gradient multi-angle light-scattering and tryptophan emission spectra. Isolated lobes bind to SKp with high affinity, but isolated lobes do not rescue SK2 activity. Consistent with earlier models, N-lobe binding to SKp is stronger in Ca 2+ , and C-lobe-binding affinity is strong independent of Ca 2+ . However, a native tryptophan in SKp is sensitive to Ca 2+ binding to both the N- and C-lobes of calmodulin at Ca 2+ concentrations that activate SK2, demonstrating that the C-lobe interaction with SKp changes with Ca 2+ . Our peptide-binding data and electrophysiology show that SK gating models need deeper scrutiny. We suggest that the Ca 2+ -dependent associations of both lobes of calmodulin to SKp are crucial events during gating. Additional investigations are necessary to complete a mechanistic gating model consistent with binding, physiology, and structure.

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  1. Author Response

    Reviewer #1 (Public Review):

    This study analyzes the detailed chemical mechanics of the formation of a physiologically important protein multimer. The primary strengths of the study are careful analyses of two distinct methods, CG-MALS a direct measure of multimerization, and environment-sensitive tryptophan fluorescence, that each indicates that Ca2+ activation of the C-lobe alone can change the physical interaction with an SK2 C-terminal peptide. An intriguing finding is that while either the N- or C-lobes alone can interact with the C-terminal peptide, only with full-length CaM can the SK C-terminal peptide be bound by two CaM molecules simultaneously. This study also clearly demonstrates that Ca2+ activation of the N-lobe triggers binding to the SK2 Cterminal peptide. Methods descriptions are thorough and excellent. Discussion of relevance to structures and function are nuanced and free of presumptions. The weaknesses of this manuscript are that the physiological implications of these findings are not clear: CaM interacts with regions of SK channels besides the C-terminal peptide studied here, and no evidence is provided here that C-lobe calcium binding alters channel opening. Overall, the evidence for conformational changes of the complex due to Ca2+ binding to the C-lobe alone is very strong, and physiological importance seems likely. The interpretation of data in this manuscript is mostly cautious and logically crystalline, with alternative interpretations discussed at many junctures.

    We thank Reviewer #1 for very helpful and thoughtful considerations and catching some oversights in our work. Our work was improved by addressing their comments.

    Reviewer #2 (Public Review):

    Activation of SK channels by calcium through calmodulin (CaM) is physiologically important in tuning membrane excitability. Understanding the molecular mechanism of SK activation has therefore been a high priority in ion channel biophysics and calcium signaling. The prevailing view is that the C-terminal lobe of CaM serves as an immobile Ca2+-independent tether while the N-lobe acts as a sensor whose binding activates the channel. In the present study, the authors undertake extensive biophysical/biochemical analysis of CaM interaction with SK channel peptide and rigorous electrophysiological experiments to show that Ca2+ does bind to the C-lobe of CaM and this potentially evokes conformational changes that may be relevant for channel gating. Beyond SK channels, the approach and findings here may bear important implications for an expanding number of ion channels and membrane proteins that are regulated by CaM.

    A strength of the study is that the electrophysiological recordings are innovative and of high quality. Given that CaM is ubiquitous in nearly all eukaryotes, dissecting the effects of mutants particularly on individual lobes is technically challenging, as endogenous CaM can overwhelm low-affinity mutants. The excised patch approach developed here provides a powerful methodology to dissect fundamental mechanisms underlying CaM action. I imagine this could be adaptable for studying other ion channels. Armed with this strategy authors show that both N- and C-lobe of CaM are essential for maximal activation of SK channels. This revises the current model and may have physiological importance.

    The major weakness is that nearly all biochemical inferences are made from analysis of isolated peptides that do not necessarily recapitulate their arrangement in an intact channel. While the use of MALS provides new evidence of the potentially complex conformational arrangement of CaM on the C-terminal SK peptide (SKp), it is not fully clear that these complexes correspond to functionally relevant states. Lastly, perhaps as a consequence of these ambiguities, the overarching model or mechanism is not fully clear.

    We thank Reviewer #2 for their helpful review and requesting context to alleviate some the ambiguities in channel mechanism arising from our data. Although the ultimate goal of our field is to understand gating mechanism, there are too many parameters to solve with a single study. First off, we agree that there is not a clear model out there and we have only continued to assemble building blocks to make one.

    Our report is centered on calmodulin more than it is SK, which is why we studied more CaM mutants and no channel mutants. There are simply too many unanswered questions regarding stoichiometry and state dependencies to make even a basic working model. We invite the greater ion channel field to scrutinize these questions and delve deeper into approaches across disciplines.

    We strived to put our work in context with the decades of research on CaM and SK. Our work focuses on the C-terminus of SK and whether the C-lobe of CaM anchored independent of Ca2+. An anchored C-lobe would be fundamental to building any gating model with the proper energetics. Although we used only a piece of the full-length channel, a peptide that we call SKp has Ca2+-dependent associations with a full-length protein, WT-CaM. We do not have nearly enough data to solve the gating mechanism, nor do we make a claim to have solved the mechanism for SK gating, but if a piece of the channel has Ca2+-dependent interactions with another full-length protein, calmodulin, it is highly unlikely that the full-length SK channel is going to inhibit that interaction in all its closed and open states. Structures do not show inhibitory actions related to conformational Ca2+-sensitivity. The C-lobe is simply captured in most populated binding state, not necessarily its functional state. Indeed, we need a lot more data to get a clearer understanding. It was helpful to discuss this and we added more context to our work.

    Reviewer #3 (Public Review):

    Halling et. al. probe the mechanism whereby calmodulin (CaM) mediates SK channel activity in response to calcium. CaM regulation of SK channels is a critical modulator of membrane excitability yet despite numerous structural and functional studies significant gaps in our understanding of how each lobe participates in this regulation remain. In particular, while Ca2+ binding to the N-lobe of CaM has a clear functional effect on the channel, the C-lobe of CaM does not appear to participate beyond a tethering role, and structural studies have indicated that the C-lobe of CaM may not bind Ca2+ in the context of the SK channel. This study pairs functional and protein binding data to bridge this gap in mechanistic understanding, demonstrating that both lobes of CaM are likely Ca2+ sensitive in the context of SK channels and that both lobes of CaM are required for channel activation by Ca2+.

    Strengths:

    The molecular underpinnings of CaM-SK regulation are of significant interest and the paper addresses a major gap in knowledge. The pairing of functional data with protein binding provides a platform to bridge the static structural results with channel function. The data is robust, and the experiments are carefully done and appear to be of high quality. The use of multiple mutant CaMs and electrophysiological studies using a rescue effect in pulled patches to enable a more quantified evaluation of the functional impact of each lobe of CaM provides a compelling assessment of the contribution of each lobe of CaM to channel activation. The calibration of the patch data by application of WT CaM is innovative and provides precise internal control, making the conclusions drawn from these experiments clear. This data fully supports the conclusion that both lobes of CaM are required for channel activation.

    Weaknesses:

    The paper focuses heavily on the results of multi-angle light scattering experiments, which demonstrate that a peptide derived from the C-terminus of the SK channel can bind to CaM in multiple stochiometric configurations. However, it is not clear if these complexes are functionally relevant in the full channel, making interpretation challenging.

    We thank Reviewer #3 for their helpful review and for providing their concerns with our interpretation of the MALS experiments. From our previous work (Li et al. 2009 and Halling et al. 2014), we have had suggestions that stoichiometry at different functional states is complicated. Our new data presented here adds to the complexity. We do not claim to have solved whether Ca2+-dependent stoichiometry is important for channel function. That requires further research.

    As we stated with reviewer #2, we emphasize our findings convey how CaM interacts with one site on SK. CaM is the Ca2+ sensor, and Ca2+ alters how CaM binds. The channel will have more determinants for interacting with CaM, but just by studying one domain we see extraordinary complexity. We have firm results from our MALS and fluorescent binding assays that challenge the models on the full-channel even with the simplest interpretations, i.e., CaM is not a simple switch. We have shown fundamentally that CaM binding is Ca2+-dependent with a single SK binding site.

    There are several major studies that still need to be done to relate binding data to channel function: 1) Calmodulin binding studies to other calmodulin domains need to be completed 2) The dependence of Ca2+ concentration on calmodulin binding need to be determined and 3) Ca2+-dependent Calmodulin binding studies on full-length SK channels need to be completed. We invite more discussion from the ion channel field on developing models that are consistent with all data.

  2. eLife assessment

    This manuscript provides compelling evidence that in response to calcium, the C-lobe of calmodulin changes its interaction with the C-terminal domain of an SK2 small-conductance calcium-activated potassium channel. These findings will be of interest to those in the field of ion channels and calcium signaling as they are valuable to understanding the molecular mechanics by which calcium activates SK2 channels, which are important for a wide variety of physiological signaling processes.

  3. Reviewer #1 (Public Review):

    This study analyzes the detailed chemical mechanics of the formation of a physiologically important protein multimer. The primary strengths of the study are careful analyses of two distinct methods, CG-MALS a direct measure of multimerization, and environment-sensitive tryptophan fluorescence, that each indicates that Ca2+ activation of the C-lobe alone can change the physical interaction with an SK2 C-terminal peptide. An intriguing finding is that while either the N- or C-lobes alone can interact with the C-terminal peptide, only with full-length CaM can the SK C-terminal peptide be bound by two CaM molecules simultaneously. This study also clearly demonstrates that Ca2+ activation of the N-lobe triggers binding to the SK2 C-terminal peptide. Methods descriptions are thorough and excellent. Discussion of relevance to structures and function are nuanced and free of presumptions. The weaknesses of this manuscript are that the physiological implications of these findings are not clear: CaM interacts with regions of SK channels besides the C-terminal peptide studied here, and no evidence is provided here that C-lobe calcium binding alters channel opening. Overall, the evidence for conformational changes of the complex due to Ca2+ binding to the C-lobe alone is very strong, and physiological importance seems likely. The interpretation of data in this manuscript is mostly cautious and logically crystalline, with alternative interpretations discussed at many junctures.

  4. Reviewer #2 (Public Review):

    Activation of SK channels by calcium through calmodulin (CaM) is physiologically important in tuning membrane excitability. Understanding the molecular mechanism of SK activation has therefore been a high priority in ion channel biophysics and calcium signaling. The prevailing view is that the C-terminal lobe of CaM serves as an immobile Ca2+-independent tether while the N-lobe acts as a sensor whose binding activates the channel. In the present study, the authors undertake extensive biophysical/biochemical analysis of CaM interaction with SK channel peptide and rigorous electrophysiological experiments to show that Ca2+ does bind to the C-lobe of CaM and this potentially evokes conformational changes that may be relevant for channel gating. Beyond SK channels, the approach and findings here may bear important implications for an expanding number of ion channels and membrane proteins that are regulated by CaM.

    A strength of the study is that the electrophysiological recordings are innovative and of high quality. Given that CaM is ubiquitous in nearly all eukaryotes, dissecting the effects of mutants particularly on individual lobes is technically challenging, as endogenous CaM can overwhelm low-affinity mutants. The excised patch approach developed here provides a powerful methodology to dissect fundamental mechanisms underlying CaM action. I imagine this could be adaptable for studying other ion channels. Armed with this strategy authors show that both N- and C-lobe of CaM are essential for maximal activation of SK channels. This revises the current model and may have physiological importance.

    The major weakness is that nearly all biochemical inferences are made from analysis of isolated peptides that do not necessarily recapitulate their arrangement in an intact channel. While the use of MALS provides new evidence of the potentially complex conformational arrangement of CaM on the C-terminal SK peptide (SKp), it is not fully clear that these complexes correspond to functionally relevant states. Lastly, perhaps as a consequence of these ambiguities, the overarching model or mechanism is not fully clear.

  5. Reviewer #3 (Public Review):

    Halling et. al. probe the mechanism whereby calmodulin (CaM) mediates SK channel activity in response to calcium. CaM regulation of SK channels is a critical modulator of membrane excitability yet despite numerous structural and functional studies significant gaps in our understanding of how each lobe participates in this regulation remain. In particular, while Ca2+ binding to the N-lobe of CaM has a clear functional effect on the channel, the C-lobe of CaM does not appear to participate beyond a tethering role, and structural studies have indicated that the C-lobe of CaM may not bind Ca2+ in the context of the SK channel. This study pairs functional and protein binding data to bridge this gap in mechanistic understanding, demonstrating that both lobes of CaM are likely Ca2+ sensitive in the context of SK channels and that both lobes of CaM are required for channel activation by Ca2+.

    Strengths:
    The molecular underpinnings of CaM-SK regulation are of significant interest and the paper addresses a major gap in knowledge. The pairing of functional data with protein binding provides a platform to bridge the static structural results with channel function. The data is robust, and the experiments are carefully done and appear to be of high quality.
    The use of multiple mutant CaMs and electrophysiological studies using a rescue effect in pulled patches to enable a more quantified evaluation of the functional impact of each lobe of CaM provides a compelling assessment of the contribution of each lobe of CaM to channel activation. The calibration of the patch data by application of WT CaM is innovative and provides precise internal control, making the conclusions drawn from these experiments clear. This data fully supports the conclusion that both lobes of CaM are required for channel activation.

    Weaknesses:
    The paper focuses heavily on the results of multi-angle light scattering experiments, which demonstrate that a peptide derived from the C-terminus of the SK channel can bind to CaM in multiple stochiometric configurations. However, it is not clear if these complexes are functionally relevant in the full channel, making interpretation challenging.