Presynaptic serotonin 2A receptors modulate thalamocortical plasticity and associative learning

Higher-level cognitive processes strongly depend on a complex interplay between mediodorsal thalamus nuclei and the prefrontal cortex (PFC). Alteration of thalamofrontal connectivity has been involved in cognitive deficits of schizophrenia. Prefrontal serotonin (5-HT)_2A receptors play an essential role in cortical network activity, but the mechanism underlying their modulation of glutamatergic transmission and plasticity at thalamocortical synapses remains largely unexplored. Here, we show that 5-HT_2A receptor activation enhances NMDA transmission and gates the induction of temporal-dependent plasticity mediated by NMDA receptors at thalamocortical synapses in acute PFC slices. Expressing 5-HT_2A receptors in the mediodorsal thalamus (presynaptic site) of 5-HT_2A receptor-deficient mice, but not in the PFC (postsynaptic site), using a viral gene-delivery approach, rescued the otherwise absent potentiation of NMDA transmission, induction of temporal plasticity, and deficit in associative memory. These results provide, to our knowledge, the first physiological evidence of a role of presynaptic 5-HT_2A receptors located at thalamocortical synapses in the control of thalamofrontal connectivity and the associated cognitive functions.The prefrontal cortex (PFC) is a brain region critical for many high-level cognitive processes, such as executive functions, attention, and working and contextual memories (1). Pyramidal neurons located in layer V of the PFC integrate excitatory glutamatergic inputs originating from both cortical and subcortical areas. The latter include the mediodorsal thalamus (MD) nuclei, which project densely to the medial PFC (mPFC) and are part of the neuronal network underlying executive control and working memory (2–4). Disruption of this network has been involved in cognitive symptoms of psychiatric disorders, such as schizophrenia (3, 5). These symptoms severely compromise the quality of life of patients and remain poorly controlled by currently available antipsychotics (3, 6).The PFC is densely innervated by serotonin (5-hydroxytryptamine, 5-HT) neurons originating from the dorsal and median raphe nuclei and numerous lines of evidence indicate a critical role of 5-HT in the control of emotional and cognitive functions depending on PFC activity (7, 8). The modulatory action of 5-HT reflects its complex pattern of effects on cortical network activity, depending on the 5-HT receptor subtypes involved, and on receptor localization in pyramidal neurons, GABAergic interneurons or nerve terminals of afferent neurons.Among the 14 5-HT receptor subtypes, the 5-HT_2A receptor is a Gq protein-coupled receptor (9, 10) particularly enriched in the mPFC, with a predominant expression in apical dendrites of layer V pyramidal neurons (11–14). Moreover, a low proportion of 5-HT_2A receptors was detected presynaptically on thalamocortical fibers (12, 15–17).Activation of 5-HT_2A receptors exerts complex effects upon the activity of the PFC network (18). The most prominent one is an increase in pyramidal neuron excitability, which likely results from the inhibition of slow calcium-activated after hyperpolarization current (19). 5-HT_2A receptor stimulation also increases the frequency and amplitude of spontaneous excitatory postsynaptic currents (sEPSCs) in pyramidal neurons (19–22). The prevailing view is that postsynaptic 5-HT_2A receptors expressed on pyramidal neurons located in layer V are key modulators of glutamatergic PFC network activity (14, 21–24). However, the role of presynaptic 5-HT_2A receptors located on thalamic afferents in the modulation of glutamatergic transmission at thalamocortical synapses remains unexplored.Here, we addressed this issue by combining electrophysiological recordings in acute PFC slices with viral infections to specifically rescue the expression of 5-HT_2A receptors at the presynaptic site (MD) or postsynaptic site (PFC) in 5-HT_2A receptor-deficient (5-HT_2A^−/−) mice (25). We focused our study on NMDA transmission in line with previous findings indicating that many symptoms of schizophrenia might arise from modifications in PFC connectivity involving glutamatergic transmission at NMDA receptors (26, 27). To our knowledge, we provide the first direct evidence that stimulation of presynaptic 5-HT_2A receptors at thalamocortical synapses gates the induction of spike timing-dependent long-term depression (t-LTD) by facilitating the activation of presynaptic NMDA receptors at these synapses. In line with the role of t-LTD in associative learning (28), these studies were extended by behavioral experiments to explore the role of presynaptic 5-HT_2A receptors at thalamocortical synapses in several paradigms of episodic-like memory.     

Inherent variations in CO-H2S-mediated carotid body O2 sensing mediate hypertension and pulmonary edema

Oxygen (O₂) sensing by the carotid body and its chemosensory reflex is critical for homeostatic regulation of breathing and blood pressure. Humans and animals exhibit substantial interindividual variation in this chemosensory reflex response, with profound effects on cardiorespiratory functions. However, the underlying mechanisms are not known. Here, we report that inherent variations in carotid body O₂ sensing by carbon monoxide (CO)-sensitive hydrogen sulfide (H₂S) signaling contribute to reflex variation in three genetically distinct rat strains. Compared with Sprague-Dawley (SD) rats, Brown-Norway (BN) rats exhibit impaired carotid body O₂ sensing and develop pulmonary edema as a consequence of poor ventilatory adaptation to hypobaric hypoxia. Spontaneous Hypertensive (SH) rat carotid bodies display inherent hypersensitivity to hypoxia and develop hypertension. BN rat carotid bodies have naturally higher CO and lower H₂S levels than SD rat, whereas SH carotid bodies have reduced CO and greater H₂S generation. Higher CO levels in BN rats were associated with higher substrate affinity of the enzyme heme oxygenase 2, whereas SH rats present lower substrate affinity and, thus, reduced CO generation. Reducing CO levels in BN rat carotid bodies increased H₂S generation, restoring O₂ sensing and preventing hypoxia-induced pulmonary edema. Increasing CO levels in SH carotid bodies reduced H₂S generation, preventing hypersensitivity to hypoxia and controlling hypertension in SH rats.Oxygen, an essential substrate for generating ATP, is vital for sustaining much of life on earth. A low availability of oxygen directs vertebrates’ complex respiratory and cardiovascular systems to maintain optimal oxygenation of tissues by increasing ventilation and blood pressure. Interestingly, ventilatory responses to hypoxia are not uniform but, instead, exhibit substantial variation among humans (1). These varied ventilatory responses to hypoxia result in dire physiological consequences: a diminished hypoxic ventilatory response can result in poor adaptation to low O₂ environments (2) and high-altitude pulmonary edema (3–5), whereas a heightened response is associated with essential hypertension (6). Similar variations in hypoxic response have also been documented in different strains of rodents (7–10). In comparison with Sprague-Dawley (SD) rats, Brown-Norway (BN) rats display a markedly reduced ventilatory response to hypoxia (8, 9), whereas Spontaneous Hypertensive (SH) rats exhibit an augmented response (11). SH rats also present enhanced sympathetic nerve activity and hypertension (7). Despite the physiological significance, the mechanisms underlying interindividual variation in systemic responses to hypoxia are not known.The carotid body is the key sensor of arterial blood oxygen, and its chemosensory reflex is a critical regulator of breathing, sympathetic tone, and blood pressure (12, 13). Differing responses in ventilation and sympathetic nerve activity to ambient oxygen levels may reflect inherent variations in the O₂ sensing ability of the carotid body. Although a number of hypotheses have been proposed to explain carotid body-mediated O₂ sensing (12, 13), emerging evidence suggests that the gasotransmitter hydrogen sulfide (H₂S) is required for O₂ sensing by the carotid body (14–17). Hypoxia results in increased H₂S generation in the carotid body. Glomus cells, the primary O₂ sensing cells in the carotid body, express cystathionine-γ-lyase (CSE), an H₂S catalyzing enzyme (15, 16). Homozygous CSE-null mice display diminished H₂S generation and a severely impaired response to hypoxia (15, 16). We hypothesized that variations in the chemosensory reflex are a result of differences in H₂S signaling in the carotid body. We tested this possibility by examining the carotid body response to hypoxia in SD, BN, and SH rats and further assessed the physiological consequences of variations in carotid body O₂ sensing on ventilatory adaptations to hypoxia and blood pressure.     

Cannabinoid CB2 receptors modulate midbrain dopamine neuronal activity and dopamine-related behavior in mice

Cannabinoid CB₂ receptors (CB₂Rs) have been recently reported to modulate brain dopamine (DA)-related behaviors; however, the cellular mechanisms underlying these actions are unclear. Here we report that CB₂Rs are expressed in ventral tegmental area (VTA) DA neurons and functionally modulate DA neuronal excitability and DA-related behavior. In situ hybridization and immunohistochemical assays detected CB₂ mRNA and CB₂R immunostaining in VTA DA neurons. Electrophysiological studies demonstrated that activation of CB₂Rs by JWH133 or other CB₂R agonists inhibited VTA DA neuronal firing in vivo and ex vivo, whereas microinjections of JWH133 into the VTA inhibited cocaine self-administration. Importantly, all of the above findings observed in WT or CB₁^−/− mice are blocked by CB₂R antagonist and absent in CB₂^−/− mice. These data suggest that CB₂R-mediated reduction of VTA DA neuronal activity may underlie JWH133''s modulation of DA-regulated behaviors.The presence of functional cannabinoid CB₂ receptors (CB₂Rs) in the brain has been controversial. When CB₂Rs were first cloned, in situ hybridization (ISH) failed to detect CB₂ mRNA in brain (1). Similarly, Northern blot and polymerase chain reaction (PCR) assays failed to detect CB₂ mRNA in brain (2–5). Therefore, CB₂Rs were considered “peripheral cannabinoid receptors” (1, 6).In contrast, other studies using ISH and radioligand binding assays detected CB₂ mRNA and receptor binding in rat retina (7), mouse cerebral cortex (8), and hippocampus and striatum of nonhuman primates (9). More recent studies using RT-PCR also detected CB₂ mRNA in the cortex, striatum, hippocampus, amygdala, and brainstem (9–14). Immunoblot and immunohistochemistry (IHC) assays detected CB₂R immunoreactivity or immunostaining in various brain regions (13, 15–20). The specificities of the detected CB₂R protein and CB₂-mRNA remain questionable, however, owing to a lack of controls using CB₁^−/− and CB₂^−/− mice in most previous studies (21). A currently accepted view is that brain CB₂Rs are expressed predominantly in activated microglia during neuroinflammation, whereas brain neurons, except for a very small number in the brainstem, lack CB₂R expression (21).On the other hand, we recently reported that brain CB₂Rs modulate cocaine self-administration and cocaine-induced increases in locomotion and extracellular dopamine (DA) in the nucleus accumbens in mice (22). This finding is supported by recent studies demonstrating that systemic administration of the CB₂R agonist O-1966 inhibited cocaine-induced conditioned place preference in WT mice, but not in CB₂^−/− mice (23), and that increased CB₂R expression in mouse brain attenuates cocaine self-administration and cocaine-enhanced locomotion (19). In addition, brain CB₂Rs may be involved in several DA-related CNS disorders, such as Parkinson’s disease (24), schizophrenia (25), anxiety (26), and depression (27). The cellular mechanisms underlying CB₂R modulation of DA-related behaviors and diseases are unclear, however. Given that midbrain DA neurons of the ventral tegmental area (VTA) play an important role in mediating the reinforcing and addictive effects of drugs of abuse (28, 29), we hypothesized that brain CB₂Rs, similar to other G protein-coupled receptors, are expressed in VTA DA neurons, where they modulate DA neuronal function and DA-related behaviors.In the present study, we tested this hypothesis using multiple approaches. We first assayed for CB₂ mRNA and protein expression in brain and in VTA DA neurons using quantitative RT-PCR (qRT-PCR), ISH, and double-label IHC techniques. We then examined the effects of the selective CB₂R agonist JWH133 and several other CB₂R agonists on VTA DA neuronal firing in both ex vivo and in vivo preparations using electrophysiological methods. Finally, we observed the effects of microinjections of JWH133 into the VTA on intravenous cocaine self-administration to study whether activation of VTA CB₂Rs modulates DA-dependent behavior. This multidisciplinary approach has provided evidence of functional CB₂Rs in VTA DA neurons. Importantly, all findings observed in WT or CB₁^−/− mice were blocked by a CB₂R antagonist and/or absent in CB₂^−/− mice, suggesting that CB₂Rs expressed in VTA DA neurons play an important role in modulating DA neuronal activity and DA-related functions.     

Allosteric interactions between agonists and antagonists within the adenosine A2A receptor-dopamine D2 receptor heterotetramer

Adenosine A_2A receptor (A_2AR)-dopamine D₂ receptor (D₂R) heteromers are key modulators of striatal neuronal function. It has been suggested that the psychostimulant effects of caffeine depend on its ability to block an allosteric modulation within the A_2AR-D₂R heteromer, by which adenosine decreases the affinity and intrinsic efficacy of dopamine at the D₂R. We describe novel unsuspected allosteric mechanisms within the heteromer by which not only A_2AR agonists, but also A_2AR antagonists, decrease the affinity and intrinsic efficacy of D₂R agonists and the affinity of D₂R antagonists. Strikingly, these allosteric modulations disappear on agonist and antagonist coadministration. This can be explained by a model that considers A_2AR-D₂R heteromers as heterotetramers, constituted by A_2AR and D₂R homodimers, as demonstrated by experiments with bioluminescence resonance energy transfer and bimolecular fluorescence and bioluminescence complementation. As predicted by the model, high concentrations of A_2AR antagonists behaved as A_2AR agonists and decreased D₂R function in the brain.Most evidence indicates that G protein-coupled receptors (GPCRs) form homodimers and heteromers. Homodimers seem to be a predominant species, and oligomeric entities can be viewed as multiples of dimers (1). It has been proposed that GPCR heteromers are constituted mainly by heteromers of homodimers (1, 2). Allosteric mechanisms determine a multiplicity of unique pharmacologic properties of GPCR homodimers and heteromers (1, 3). First, binding of a ligand to one of the receptors in the heteromer can modify the affinity of ligands for the other receptor (1, 3, 4). The most widely reproduced allosteric modulation of ligand-binding properties in a GPCR heteromer is the ability of adenosine A_2A receptor (A_2AR) agonists to decrease the affinity of dopamine D₂ receptor (D₂R) agonists in the A_2AR-D₂R heteromer (5). A_2AR-D₂R heteromers have been revealed both in transfected cells (6, 7), striatal neurons in culture (6, 8) and in situ, in mammalian striatum (9, 10), where they play an important role in the modulation of GABAergic striatopallidal neuronal function (9, 11).In addition to ligand-binding properties, unique properties for each GPCR oligomer emerge in relation to the varying intrinsic efficacy of ligands for different signaling pathways (1–3). Intrinsic efficacy refers to the power of the agonist to induce a functional response, independent of its affinity for the receptor. Thus, allosteric modulation of an agonist can potentially involve changes in affinity and/or intrinsic efficacy (1, 3). This principle can be observed in the A_2AR-D₂R heteromer, where a decrease in D₂R agonist affinity cannot alone explain the ability of an A_2AR agonist to abolish the decreased excitability of GABAergic striatopallidal neurons induced by high concentration of a D₂R agonist (9), which should overcome the decrease in affinity. Furthermore, a differential effect of allosteric modulations of different agonist-mediated signaling responses (i.e., functional selectivity) can occur within GPCR heteromers (1, 2, 8). Again, the A_2AR-D₂R heteromer provides a valuable example. A recent study has shown that different levels of intracellular Ca²⁺ exert different modulations of A_2AR-D₂R heteromer signaling (8). This depends on the ability of low and high Ca²⁺ to promote a selective interaction of the heteromer with different Ca²⁺-binding proteins, which differentially modulate allosteric interactions in the heteromer (8).It has been hypothesized that the allosteric interactions between A_2AR and D₂R agonists within the A_2AR-D₂R heteromer provide a mechanism responsible not only for the depressant effects of A_2AR agonists, but also for the psychostimulant effects of adenosine A_2AR antagonists and the nonselective adenosine receptor antagonist caffeine (9, 11, 12), with implications for several neuropsychiatric disorders (13). In fact, the same mechanism has provided the rationale for the use of A_2AR antagonists in patients with Parkinson’s disease (13, 14). The initial aim of the present study was to study in detail the ability of caffeine to counteract allosteric modulations between A_2AR and D₂R agonists (affinity and intrinsic efficacy) within the A_2AR-D₂R heteromer. Unexpectedly, when performing control radioligand-binding experiments, not only an A_2AR agonist, but also caffeine, significantly decreased D₂R agonist binding. However, when coadministered, the A_2AR agonist and caffeine co-counteracted their ability to modulate D₂R agonist binding. By exploring the molecular mechanisms behind these apparent inconsistencies, the present study provides new insight into the quaternary structure and function of A_2AR-D₂R heteromers.     

Aberrant calcium signaling by transglutaminase-mediated posttranslational modification of inositol 1,4,5-trisphosphate receptors

The inositol 1,4,5-trisphosphate receptor (IP₃R) in the endoplasmic reticulum mediates calcium signaling that impinges on intracellular processes. IP₃Rs are allosteric proteins comprising four subunits that form an ion channel activated by binding of IP₃ at a distance. Defective allostery in IP₃R is considered crucial to cellular dysfunction, but the specific mechanism remains unknown. Here we demonstrate that a pleiotropic enzyme transglutaminase type 2 targets the allosteric coupling domain of IP₃R type 1 (IP₃R1) and negatively regulates IP₃R1-mediated calcium signaling and autophagy by locking the subunit configurations. The control point of this regulation is the covalent posttranslational modification of the Gln2746 residue that transglutaminase type 2 tethers to the adjacent subunit. Modification of Gln2746 and IP₃R1 function was observed in Huntington disease models, suggesting a pathological role of this modification in the neurodegenerative disease. Our study reveals that cellular signaling is regulated by a new mode of posttranslational modification that chronically and enzymatically blocks allosteric changes in the ligand-gated channels that relate to disease states.Ligand-gated ion channels function by allostery that is the regulation at a distance; the allosteric coupling of ligand binding with channel gating requires reversible changes in subunit configurations and conformations (1). Inositol 1,4,5-trisphosphate receptors (IP₃Rs) are ligand-gated ion channels that release calcium ions (Ca²⁺) from the endoplasmic reticulum (ER) (2, 3). IP₃Rs are allosteric proteins comprising four subunits that assemble a calcium channel with fourfold symmetry about an axis perpendicular to the ER membrane. The subunits of three IP₃R isoforms (IP₃R1, IP₃R2, and IP₃R3) are structurally divided into three domains: the IP₃-binding domain (IBD), the regulatory domain, and the channel domain (3–6). Fitting of the IBD X-ray structures (7, 8) to a cryo-EM map (9) indicates that the IBD activates a remote Ca²⁺ channel by allostery (8); however, the current X-ray structure only spans 5% of each tetramer, such that the mechanism underlying allosteric coupling of the IBD to channel gating remains unknown.The IP₃R in the ER mediates intracellular calcium signaling that impinges on homeostatic control in various subsequent intracellular processes. Deletion of the genes encoding the type 1 IP₃R (IP₃R1) leads to perturbations in long-term potentiation/depression (3, 10, 11) and spinogenesis (12), and the human genetic disease spinocerebellar ataxia 15 is caused by haploinsufficiency of the IP₃R1 gene (13–15). Dysregulation of IP₃R1 is also implicated in neurodegenerative diseases including Huntington disease (HD) (16–18) and Alzheimer’s disease (AD) (19–22). IP₃Rs also control fundamental cellular processes—for example, mitochondrial energy production (23, 24), autophagy regulation (24–27), ER stress (28), hepatic gluconeogenesis (29), pancreatic exocytosis (30), and macrophage inflammasomes (31). On the other hand, excessive IP₃R function promotes cell death processes including apoptosis by activating mitochondrial or calpain pathways (2, 17). Considering these versatile roles of IP₃Rs, appropriate IP₃R structure and function are essential for living systems, and aberrant regulation of IP₃R closely relates to various diseases.Several factors such as cytosolic molecules, interacting proteins, and posttranslational modifications control the IP₃-induced Ca²⁺ release (IICR) through allosteric sites in IP₃Rs. Cytosolic Ca²⁺ concentrations strictly control IICR in a biphasic manner with activation at low concentrations and inhibition at higher concentrations. The critical Ca²⁺ sensor for activation is conserved among the three isoforms of IP₃ and ryanodine receptors, and this sensor is located in the regulatory domain outside the IBD and the channel domain (32). A putative ATP regulatory region is deleted in opisthotonos mice, and IICR is also regulated by this mutation in the regulatory domain (33). Various interacting proteins, such as cytochrome c, Bcl-2-family proteins, ataxin-3, huntingtin (Htt) protein, Htt-associated protein 1A (HAP1A), and G-protein–coupled receptor kinase-interacting protein 1 (GIT1), target allosteric sites in the carboxyl-terminal tail (3–5). The regulatory domain and the carboxyl-terminal tail also undergo phosphorylation by the protein kinases A/G and B/Akt and contain the apoptotic cleavage sites for the protease caspase-3 (4, 5). These factors allosterically regulate IP₃R structure and function to control cellular fates; therefore, understanding the allosteric coupling of the IBD to channel gating will elucidate the regulatory mechanism of these factors.Transglutaminase (TG) catalyses protein cross-linking between a glutamine (Gln) residue and a lysine (Lys) residue via an N^ε-(γ-glutamyl)lysine isopeptide bond (34, 35). TG type 2 (TG2) is a Ca²⁺-dependent enzyme with widespread distribution and is highly inducible by various stimulations such as oxidative stress, cytokines, growth factors, and retinoic acid (RA) (34, 35). TG2 is considered a significant disease-modifying factor in neurodegenerative diseases including HD, AD, and Parkinson’s diseases (PD) (34, 36–45) because TG2 might enzymatically stabilize aberrant aggregates of proteins implicated in these diseases—that is, mutant Htt, β-amyloid, and α-synuclein; however, the causal role of TG2 in Ca²⁺ signaling in brain pathogenesis has been unclear. Ablation of TG2 in HD mouse models is associated with increased lifespan and improved motor function (46, 47). However, TG2 knockout mice do not show impaired Htt aggregation, suggesting that TG2 may play a causal role in these disorders rather than TG2-dependent cross-links in aberrant protein aggregates (47, 48).In this study, we discovered a new mode of chronic and irreversible allosteric regulation in IP₃R1 in which covalent modification of the receptor at Gln2746 is catalyzed by TG2. We demonstrate that up-regulation of TG2 modifies IP₃R1 structure and function in HD models and propose an etiologic role of this modification in the reduction of neuronal signaling and subsequent processes during the prodromal state of the neurodegenerative disease.     

Caffeine acts through neuronal adenosine A2A receptors to prevent mood and memory dysfunction triggered by chronic stress

The consumption of caffeine (an adenosine receptor antagonist) correlates inversely with depression and memory deterioration, and adenosine A_2A receptor (A_2AR) antagonists emerge as candidate therapeutic targets because they control aberrant synaptic plasticity and afford neuroprotection. Therefore we tested the ability of A_2AR to control the behavioral, electrophysiological, and neurochemical modifications caused by chronic unpredictable stress (CUS), which alters hippocampal circuits, dampens mood and memory performance, and enhances susceptibility to depression. CUS for 3 wk in adult mice induced anxiogenic and helpless-like behavior and decreased memory performance. These behavioral changes were accompanied by synaptic alterations, typified by a decrease in synaptic plasticity and a reduced density of synaptic proteins (synaptosomal-associated protein 25, syntaxin, and vesicular glutamate transporter type 1), together with an increased density of A_2AR in glutamatergic terminals in the hippocampus. Except for anxiety, for which results were mixed, CUS-induced behavioral and synaptic alterations were prevented by (i) caffeine (1 g/L in the drinking water, starting 3 wk before and continued throughout CUS); (ii) the selective A_2AR antagonist KW6002 (3 mg/kg, p.o.); (iii) global A_2AR deletion; and (iv) selective A_2AR deletion in forebrain neurons. Notably, A_2AR blockade was not only prophylactic but also therapeutically efficacious, because a 3-wk treatment with the A_2AR antagonist {"type":"entrez-protein","attrs":{"text":"SCH58261","term_id":"1052882304","term_text":"SCH58261"}}SCH58261 (0.1 mg/kg, i.p.) reversed the mood and synaptic dysfunction caused by CUS. These results herald a key role for synaptic A_2AR in the control of chronic stress-induced modifications and suggest A_2AR as candidate targets to alleviate the consequences of chronic stress on brain function.Repeated stress elicits neurochemical and morphological changes that negatively affect brain functioning (1, 2). Thus, repeated stress is a trigger or a risk factor for neuropsychiatric disorders, namely depression, in both humans and animal models (2, 3). Given the absence of effective therapeutic tools, novel strategies to manage the impact of chronic stress are needed, and analyzing particular lifestyles can provide important leads. Notably, caffeine consumption increases in stressful conditions (4) and correlates inversely with the incidence of depression (5, 6) and the risk of suicide (7, 8). However, the molecular targets operated by caffeine to afford these beneficial effects have not been defined.Caffeine is the most widely consumed psychoactive drug. The only molecular targets for caffeine at nontoxic doses are the main adenosine receptors in the brain, namely the inhibitory A₁ receptors (A₁R) and the facilitatory A_2A receptors (A_2AR) (9). A_2AR blockade affords robust protection against noxious brain conditions (10), an effect that might result from the ability of neuronal A_2AR to control aberrant plasticity (11, 12) and synaptotoxicity (13–15) or from A_2AR’s impact on astrocytes (16) or microglia (17). The protection provided by A_2AR blockade prompts the hypothesis that A_2AR antagonism may underlie the beneficial effects of caffeine on chronic stress, in accordance with the role of synaptic (18, 19) or glial dysfunction (20) in mood disorders. Thus, A_2AR antagonists prolonged escape behavior in two screening tests for antidepressant activity (21–23) and prevented maternal separation-induced long-term cognitive impact (12). We combined pharmacological and tissue-selective A_2AR transgenic mice (24, 25) to test if neuronal A_2AR controlled the modifications caused by chronic unpredictable stress (CUS).     

Structural interactions of a voltage sensor toxin with lipid membranes

Protein toxins from tarantula venom alter the activity of diverse ion channel proteins, including voltage, stretch, and ligand-activated cation channels. Although tarantula toxins have been shown to partition into membranes, and the membrane is thought to play an important role in their activity, the structural interactions between these toxins and lipid membranes are poorly understood. Here, we use solid-state NMR and neutron diffraction to investigate the interactions between a voltage sensor toxin (VSTx1) and lipid membranes, with the goal of localizing the toxin in the membrane and determining its influence on membrane structure. Our results demonstrate that VSTx1 localizes to the headgroup region of lipid membranes and produces a thinning of the bilayer. The toxin orients such that many basic residues are in the aqueous phase, all three Trp residues adopt interfacial positions, and several hydrophobic residues are within the membrane interior. One remarkable feature of this preferred orientation is that the surface of the toxin that mediates binding to voltage sensors is ideally positioned within the lipid bilayer to favor complex formation between the toxin and the voltage sensor.Protein toxins from venomous organisms have been invaluable tools for studying the ion channel proteins they target. For example, in the case of voltage-activated potassium (Kv) channels, pore-blocking scorpion toxins were used to identify the pore-forming region of the channel (1, 2), and gating modifier tarantula toxins that bind to S1–S4 voltage-sensing domains have helped to identify structural motifs that move at the protein–lipid interface (3–5). In many instances, these toxin–channel interactions are highly specific, allowing them to be used in target validation and drug development (6–8).Tarantula toxins are a particularly interesting class of protein toxins that have been found to target all three families of voltage-activated cation channels (3, 9–12), stretch-activated cation channels (13–15), as well as ligand-gated ion channels as diverse as acid-sensing ion channels (ASIC) (16–21) and transient receptor potential (TRP) channels (22, 23). The tarantula toxins targeting these ion channels belong to the inhibitor cystine knot (ICK) family of venom toxins that are stabilized by three disulfide bonds at the core of the molecule (16, 17, 24–31). Although conventional tarantula toxins vary in length from 30 to 40 aa and contain one ICK motif, the recently discovered double-knot toxin (DkTx) that specifically targets TRPV1 channels contains two separable lobes, each containing its own ICK motif (22, 23).One unifying feature of all tarantula toxins studied thus far is that they act on ion channels by modifying the gating properties of the channel. The best studied of these are the tarantula toxins targeting voltage-activated cation channels, where the toxins bind to the S3b–S4 voltage sensor paddle motif (5, 32–36), a helix-turn-helix motif within S1–S4 voltage-sensing domains that moves in response to changes in membrane voltage (37–41). Toxins binding to S3b–S4 motifs can influence voltage sensor activation, opening and closing of the pore, or the process of inactivation (4, 5, 36, 42–46). The tarantula toxin PcTx1 can promote opening of ASIC channels at neutral pH (16, 18), and DkTx opens TRPV1 in the absence of other stimuli (22, 23), suggesting that these toxin stabilize open states of their target channels.For many of these tarantula toxins, the lipid membrane plays a key role in the mechanism of inhibition. Strong membrane partitioning has been demonstrated for a range of toxins targeting S1–S4 domains in voltage-activated channels (27, 44, 47–50), and for GsMTx4 (14, 50), a tarantula toxin that inhibits opening of stretch-activated cation channels in astrocytes, as well as the cloned stretch-activated Piezo1 channel (13, 15). In experiments on stretch-activated channels, both the d- and l-enantiomers of GsMTx4 are active (14, 50), implying that the toxin may not bind directly to the channel. In addition, both forms of the toxin alter the conductance and lifetimes of gramicidin channels (14), suggesting that the toxin inhibits stretch-activated channels by perturbing the interface between the membrane and the channel. In the case of Kv channels, the S1–S4 domains are embedded in the lipid bilayer and interact intimately with lipids (48, 51, 52) and modification in the lipid composition can dramatically alter gating of the channel (48, 53–56). In one study on the gating of the Kv2.1/Kv1.2 paddle chimera (53), the tarantula toxin VSTx1 was proposed to inhibit Kv channels by modifying the forces acting between the channel and the membrane. Although these studies implicate a key role for the membrane in the activity of Kv and stretch-activated channels, and for the action of tarantula toxins, the influence of the toxin on membrane structure and dynamics have not been directly examined. The goal of the present study was to localize a tarantula toxin in membranes using structural approaches and to investigate the influence of the toxin on the structure of the lipid bilayer.     

Electrochemical tuning of vertically aligned MoS2 nanofilms and its application in improving hydrogen evolution reaction

The ability to intercalate guest species into the van der Waals gap of 2D layered materials affords the opportunity to engineer the electronic structures for a variety of applications. Here we demonstrate the continuous tuning of layer vertically aligned MoS₂ nanofilms through electrochemical intercalation of Li⁺ ions. By scanning the Li intercalation potential from high to low, we have gained control of multiple important material properties in a continuous manner, including tuning the oxidation state of Mo, the transition of semiconducting 2H to metallic 1T phase, and expanding the van der Waals gap until exfoliation. Using such nanofilms after different degree of Li intercalation, we show the significant improvement of the hydrogen evolution reaction activity. A strong correlation between such tunable material properties and hydrogen evolution reaction activity is established. This work provides an intriguing and effective approach on tuning electronic structures for optimizing the catalytic activity.Layer-structured 2D materials are an interesting family of materials with strong covalent bonding within molecular layers and weak van der Waals interaction between layers. Beyond intensively studied graphene-related materials (1–4), there has been recent strong interest in other layered materials whose vertical thickness can be thinned down to less than few nanometers and horizontal width can also be reduced to nanoscale (5–9). The strong interest is driven by their interesting physical and chemical properties (2, 10) and their potential applications in transistors, batteries, topological insulators, thermoelectrics, artificial photosynthesis, and catalysis (4, 11–25).One of the unique properties of 2D layered materials is their ability to intercalate guest species into their van der Waals gaps, opening up the opportunities to tune the properties of materials. For example, the spacing between the 2D layers could be increased by intercalation such as lithium (Li) intercalated graphite or molybdenum disulfide (MoS₂) and copper intercalated bismuth selenide (26–29). The electronic structures of the host lattice, such as the charge density, anisotropic transport, oxidation state, and phase transition, may also be changed by different species intercalation (26, 27).As one of the most interesting layered materials, MoS₂ has been extensively studied in a variety of areas such as electrocatalysis (20–22, 30–36). It is known that there is a strong correlation between the electronic structure and catalytic activity of the catalysts (20, 37–41). It is intriguing to continuously tune the morphology and electronic structure of MoS₂ and explore the effects on MoS₂ hydrogen evolution reaction (HER) activity. Very recent studies demonstrated that the monolayered MoS₂ and WS₂ nanosheets with 1T metallic phase synthesized by chemical exfoliation exhibited superior HER catalytic activity to those with 2H semiconducting phase (35, 42), with a possible explanation that the strained 1T phase facilitates the hydrogen binding process during HER (42). However, it only offers two end states of materials and does not offer a continuous tuning. A systematic investigation to correlate the gradually tuned electronic structure, including oxidation state shift and semiconducting–metallic phase transition, and the corresponding HER activity is important but unexplored. We believe that the Li electrochemical intercalation method offers a unique way to tune the catalysts for optimization.In this paper, we demonstrate that the layer spacing, oxidation state, and the ratio of 2H semiconducting to 1T metallic phase of MoS₂ HER catalysts were continuously tuned by Li intercalation to different voltages vs. Li⁺/Li in nanofilms with molecular layers perpendicular to the substrates. Correspondingly, the catalytic activity for HER was observed to be continuously tuned. The lower oxidation state of Mo and 1T metallic phase of MoS₂ turn out to have better HER catalytic activities. The performance of MoS₂ catalyst on both flat and 3D electrodes was dramatically improved when it was discharged to low potentials vs. Li⁺/Li.     

Luminescence color switching of supramolecular assemblies of discrete molecular decanuclear gold(I) sulfido complexes

A series of discrete decanuclear gold(I) μ₃-sulfido complexes with alkyl chains of various lengths on the aminodiphosphine ligands, [Au₁₀{Ph₂PN(C_nH_2n+1)PPh₂}₄(μ₃-S)₄](ClO₄)₂, has been synthesized and characterized. These complexes have been shown to form supramolecular nanoaggregate assemblies upon solvent modulation. The photoluminescence (PL) colors of the nanoaggregates can be switched from green to yellow to red by varying the solvent systems from which they are formed. The PL color variation was investigated and correlated with the nanostructured morphological transformation from the spherical shape to the cube as observed by transmission electron microscopy and scanning electron microscopy. Such variations in PL colors have not been observed in their analogous complexes with short alkyl chains, suggesting that the long alkyl chains would play a key role in governing the supramolecular nanoaggregate assembly and the emission properties of the decanuclear gold(I) sulfido complexes. The long hydrophobic alkyl chains are believed to induce the formation of supramolecular nanoaggregate assemblies with different morphologies and packing densities under different solvent systems, leading to a change in the extent of Au(I)–Au(I) interactions, rigidity, and emission properties.Gold(I) complexes are one of the fascinating classes of complexes that reveal photophysical properties that are highly sensitive to the nuclearity of the metal centers and the metal–metal distances (1–59). In a certain sense, they bear an analogy or resemblance to the interesting classes of metal nanoparticles (NPs) (60–69) and quantum dots (QDs) (70–76) in that the properties of the nanostructured materials also show a strong dependence on their sizes and shapes. Interestingly, while the optical and spectroscopic properties of metal NPs and QDs show a strong dependence on the interparticle distances, those of polynuclear gold(I) complexes are known to mainly depend on the nuclearity and the internuclear separations of gold(I) centers within the individual molecular complexes or clusters, with influence of the intermolecular interactions between discrete polynuclear molecular complexes relatively less explored (34–38), and those of polynuclear gold(I) clusters not reported. Moreover, while studies on polynuclear gold(I) complexes or clusters are known (34–54), less is explored of their hierarchical assembly and nanostructures as well as the influence of intercluster aggregation on the optical properties (34–38). Among the gold(I) complexes, polynuclear gold(I) chalcogenido complexes represent an important and interesting class (44–51). While directed supramolecular assembly of discrete Au₁₂ (52), Au₁₆ (53), Au₁₈ (51), and Au₃₆ (54) metallomacrocycles as well as trinuclear gold(I) columnar stacks (34–38) have been reported, there have been no corresponding studies on the supramolecular hierarchical assembly of polynuclear gold(I) chalcogenido clusters.Based on our interests and experience in the study of gold(I) chalcogenido clusters (44–46, 51), it is believed that nanoaggegrates with interesting luminescence properties and morphology could be prepared by the judicious design of the gold(I) chalcogenido clusters. As demonstrated by our previous studies on the aggregation behavior of square-planar platinum(II) complexes (77–80) where an enhancement of the solubility of the metal complexes via introduction of solubilizing groups on the ligands and the fine control between solvophobicity and solvophilicity of the complexes would have a crucial influence on the factors governing supramolecular assembly and the formation of aggregates (80), introduction of long alkyl chains as solubilizing groups in the gold(I) sulfido clusters may serve as an effective way to enhance the solubility of the gold(I) clusters for the construction of supramolecular assemblies of novel luminescent nanoaggegrates.Herein, we report the preparation and tunable spectroscopic properties of a series of decanuclear gold(I) μ₃-sulfido complexes with alkyl chains of different lengths on the aminophosphine ligands, [Au₁₀{Ph₂PN(C_nH_2n+1)PPh₂}₄(μ₃-S)₄](ClO₄)₂ [n = 8 (1), 12 (2), 14 (3), 18 (4)] and their supramolecular assembly to form nanoaggregates. The emission colors of the nanoaggregates of 2−4 can be switched from green to yellow to red by varying the solvent systems from which they are formed. These results have been compared with their short alkyl chain-containing counterparts, 1 and a related [Au₁₀{Ph₂PN(C₃H₇)PPh₂}₄(μ₃-S)₄](ClO₄)₂ (45). The present work demonstrates that polynuclear gold(I) chalcogenides, with the introduction of appropriate functional groups, can serve as building blocks for the construction of novel hierarchical nanostructured materials with environment-responsive properties, and it represents a rare example in which nanoaggregates have been assembled with the use of discrete molecular metal clusters as building blocks.     

Microscopic identification of the order parameter governing liquid–liquid transition in a molecular liquid

A liquid–liquid transition (LLT) in a single-component substance is an unconventional phase transition from one liquid to another. LLT has recently attracted considerable attention because of its fundamental importance in our understanding of the liquid state. To access the order parameter governing LLT from a microscopic viewpoint, here we follow the structural evolution during the LLT of an organic molecular liquid, triphenyl phosphite (TPP), by time-resolved small- and wide-angle X-ray scattering measurements. We find that locally favored clusters, whose characteristic size is a few nanometers, are spontaneously formed and their number density monotonically increases during LLT. This strongly suggests that the order parameter of LLT is the number density of locally favored structures and of nonconserved nature. We also show that the locally favored structures are distinct from the crystal structure and these two types of orderings compete with each other. Thus, our study not only experimentally identifies the structural order parameter governing LLT, but also may settle a long-standing debate on the nature of the transition in TPP, i.e., whether the transition is LLT or merely microcrystal formation.Liquid-liquid transition (LLT) is an intriguing phenomenon in which a liquid transforms into another one via a first-order transition. This means that there can be more than two liquid states for a single-component substance. Despite its counterintuitive nature, there have recently been many pieces of experimental and numerical evidence for the existence of LLT, for various liquids such as water (1–5), aqueous solutions (6–8), triphenyl phosphite (9–12), l-butanol (13), phosphorus (14), silicon (15, 16), germanium (17), and Y₂O₃–Al₂O₃ (18, 19). This suggests that the LLT may be rather universally observed for various types of liquids. However, none of the LLTs reported so far is free from criticisms (20, 21), mainly because these LLTs take place under experimentally difficult conditions [e.g., at high temperature and pressure (14, 15, 17–19)] or in a supercooled state below the melting point (1–3, 5–7, 9, 10), where the transition is inevitably contaminated by microcrystal formation. The latter is not limited to experiments but arises in numerical simulations, often causing many controversies [LLT (22–25) vs. crystallization (26–28)]. For ST2 water, however, this issue has recently been settled by an extensive simulation study by Palmer et al. (4).One of the hottest and long-standing debates is on the nature of the transition found in a molecular liquid, triphenyl phosphite (TPP), by Kivelson and his coworkers (29). The transition is very easy to access experimentally, because it takes place at ambient pressure and at a temperature range between 230 and 210 K and the transformation speed is slow enough to follow the kinetics. Since the finding of this transition (29, 30), many researchers thus have been interested in this intriguing phenomenon and there have been hot discussions on the nature of the transition (20, 21). Some people interpreted this as a liquid-associated phenomenon (9, 10, 31, 32), but others interpret it differently. All of the controversies come from the fact that this transition accompanies microcrystal formation and thus the final state, which is called “glacial phase,” often contains microcrystallites. This led many researchers to explain the transition by non-LLT scenarios, which include a defect-ordered phase scenario predicted by a frustration limited domain theory (29, 30, 33, 34), a microcrystallization scenario (35–38), and a liquid-crystal or plastic-crystal phase scenario (39). Each scenario captures a certain feature of the glacial phase, but fails in explaining all of the experimental results in a consistent manner. Similar situations are often seen in other candidates of LLTs, such as l-butanol [LLT (13) vs. microcrystallization (40–43)], confined water [LLT (5) vs. other phenomena (44–46)], and aqueous solutions [LLT (6, 7) vs. microcrystallization (8, 28, 47, 48)]. For TPP, however, some pieces of experimental evidence supportive of the LLT scenario rather than the microcrystallization scenario have recently been reported (11, 12).We propose a two-order-parameter (TOP) model of a liquid to explain LLT (20, 49). The main point of this model is that it is necessary to consider the spatiotemporal hierarchical nature of a liquid to understand LLT. More specifically, we argue that in addition to density order parameter ρ describing a gas–liquid transition, we need an additional scalar order parameter S, which is the number density of locally favored structures (LFS). In this model, LLT is a consequence of the cooperative ordering of the scalar nonconserved order parameter S, i.e., the cooperative formation of LFS. In other words, LLT is regarded as a gas–liquid-like transition of LFS: one liquid is a gas state of LFS (low-S state), and the other is its liquid state (high-S state). Recently, it was proposed by Anisimov and coworkers (50, 51) that the thermodynamic ordering field conjugate to the order parameter is the conversion equilibrium constant, which further characterizes the nature of LLT. We explained our experimental observation of LLT in TPP in terms of this model (9, 10). We also studied the phase transition dynamics and the physical and chemical properties of the second liquid state (liquid II), which were also explained by the model (20, 21).However, we have not had any direct experimental evidence for the formation of such LFS up to now; thus, an open question is, what is the relevant order parameter governing LLT, although the link of the order parameter to the enthalpy (9, 10), the refractive index (or, density) (9, 10, 29, 30), and the polarity associated with local molecular ordering (12) has been suggested for LLT in TPP. There have been structural studies on LLT by X-ray and neutron scattering measurements, focusing on local liquid structures at an inter- and intramolecular scale (36, 38, 52–54) and mesoscopic structures (34, 55). However, there has been no experimental evidence for the presence of locally favored structures, which characterize the liquid state uniquely, or the order parameter has still not been identified from a microscopic viewpoint.Here we study the structural change of TPP during LLT by time-resolved small- and wide-angle X-ray scattering measurements, which cover a length scale from a single molecule size ( ～  1 nm) to more than tens of nanometers. We show, to our knowledge, the first direct evidence for the presence of LFS and the temporal increase upon the liquid I-to-liquid II transformation. Furthermore, we also find an indication of the formation of microcrystallites during LLT. However, we reveal that LFS and microcrystallites have different sizes and growth kinetics, indicating that although they sometimes appear simultaneously during the process of LLT, LLT itself is driven by the formation of LFS and not by that of microcrystallites. We also discover that LFS are destroyed upon crystallization, clearly indicating not only that these two types of orderings are competing with each other but also that LFS is a structure unique to the liquid state. Our findings provide a comprehensive view on the long-standing controversy on the origin of the glacial phase, which was discovered by Kivelson and his coworkers (29, 30), and show that the fraction of LFS may be the relevant order parameter of LLT. This suggests that a liquid can have a spatiotemporal hierarchical structure at a low temperature, contrary to the common picture of a high-temperature liquid where the structure is random and homogeneous beyond the molecular size.     

From the Cover: The point of no return in vetoing self-initiated movements

In humans, spontaneous movements are often preceded by early brain signals. One such signal is the readiness potential (RP) that gradually arises within the last second preceding a movement. An important question is whether people are able to cancel movements after the elicitation of such RPs, and if so until which point in time. Here, subjects played a game where they tried to press a button to earn points in a challenge with a brain–computer interface (BCI) that had been trained to detect their RPs in real time and to emit stop signals. Our data suggest that subjects can still veto a movement even after the onset of the RP. Cancellation of movements was possible if stop signals occurred earlier than 200 ms before movement onset, thus constituting a point of no return.It has been repeatedly shown that spontaneous movements are preceded by early brain signals (1–8). As early as a second before a simple voluntary movement, a so-called readiness potential (RP) is observed over motor-related brain regions (1–3, 5). The RP was found to precede the self-reported time of the “‘decision’ to act” (ref. 3, p. 623). Similar preparatory signals have been observed using invasive electrophysiology (8, 9) and functional MRI (7, 10), and have been demonstrated also for choices between multiple-response options (6, 7, 10), for abstract decisions (10), for perceptual choices (11), and for value-based decisions (12). To date, the exact nature and causal role of such early signals in decision making is debated (12–20).One important question is whether a person can still exert a veto by inhibiting the movement after onset of the RP (13, 18, 21, 22). One possibility is that the onset of the RP triggers a causal chain of events that unfolds in time and cannot be cancelled. The onset of the RP in this case would be akin to tipping the first stone in a row of dominoes. If there is no chance of intervening, the dominoes will gradually fall one-by-one until the last one is reached. This has been coined a ballistic stage of processing (23, 24). A different possibility is that participants can still terminate the process, akin to taking out a domino at some later stage in the chain and thus preventing the process from completing. Here, we directly tested this in a real-time experiment that required subjects to terminate their decision to move once a RP had been detected by a brain–computer interface (BCI) (25–31).     

Kinetics of nucleotide-dependent structural transitions in the kinesin-1 hydrolysis cycle

To dissect the kinetics of structural transitions underlying the stepping cycle of kinesin-1 at physiological ATP, we used interferometric scattering microscopy to track the position of gold nanoparticles attached to individual motor domains in processively stepping dimers. Labeled heads resided stably at positions 16.4 nm apart, corresponding to a microtubule-bound state, and at a previously unseen intermediate position, corresponding to a tethered state. The chemical transitions underlying these structural transitions were identified by varying nucleotide conditions and carrying out parallel stopped-flow kinetics assays. At saturating ATP, kinesin-1 spends half of each stepping cycle with one head bound, specifying a structural state for each of two rate-limiting transitions. Analysis of stepping kinetics in varying nucleotides shows that ATP binding is required to properly enter the one-head–bound state, and hydrolysis is necessary to exit it at a physiological rate. These transitions differ from the standard model in which ATP binding drives full docking of the flexible neck linker domain of the motor. Thus, this work defines a consensus sequence of mechanochemical transitions that can be used to understand functional diversity across the kinesin superfamily.Kinesin-1 is a motor protein that steps processively toward microtubule plus-ends, tracking single protofilaments and hydrolyzing one ATP molecule per step (1–6). Step sizes corresponding to the tubulin dimer spacing of 8.2 nm are observed when the molecule is labeled by its C-terminal tail (7–10) and to a two-dimer spacing of 16.4 nm when a single motor domain is labeled (4, 11, 12), consistent with the motor walking in a hand-over-hand fashion. Kinesin has served as an important model system for advancing single-molecule techniques (7–10) and is clinically relevant for its role in neurodegenerative diseases (13), making dissection of its step a popular ongoing target of study.Despite decades of work, many essential components of the mechanochemical cycle remain disputed, including (i) how much time kinesin-1 spends in a one-head–bound (1HB) state when stepping at physiological ATP concentrations, (ii) whether the motor waits for ATP in a 1HB or two-heads–bound (2HB) state, and (iii) whether ATP hydrolysis occurs before or after tethered head attachment (4, 11, 14–20). These questions are important because they are fundamental to the mechanism by which kinesins harness nucleotide-dependent structural changes to generate mechanical force in a manner optimized for their specific cellular tasks. Addressing these questions requires characterizing a transient 1HB state in the stepping cycle in which the unattached head is located between successive binding sites on the microtubule. This 1HB intermediate is associated with the force-generating powerstroke of the motor and underlies the detachment pathway that limits motor processivity. Optical trapping (7, 19, 21, 22) and single-molecule tracking studies (4, 8–11) have failed to detect this 1HB state during stepping. Single-molecule fluorescence approaches have detected a 1HB intermediate at limiting ATP concentrations (11, 12, 14, 15), but apart from one study that used autocorrelation analysis to detect a 3-ms intermediate (17), the 1HB state has been undetectable at physiological ATP concentrations.Single-molecule microscopy is a powerful tool for studying the kinetics of structural changes in macromolecules (23). Tracking steps and potential substeps for kinesin-1 at saturating ATP has until now been hampered by the high stepping rates of the motor (up to 100 s⁻¹), which necessitates high frame rates, and the small step size (8.2 nm), which necessitates high spatial precision (7). Here, we apply interferometric scattering microscopy (iSCAT), a recently established single-molecule tool with high spatiotemporal resolution (24–27) to directly visualize the structural changes underlying kinesin stepping. By labeling one motor domain in a dimeric motor, we detect a 1HB intermediate state in which the tethered head resides over the bound head for half the duration of the stepping cycle at saturating ATP. We further show that at physiological stepping rates, ATP binding is required to enter this 1HB state and that ATP hydrolysis is required to exit it. This work leads to a significant revision of the sequence and kinetics of mechanochemical transitions that make up the kinesin-1 stepping cycle and provides a framework for understanding functional diversity across the kinesin superfamily.     

STEP61 is a substrate of the E3 ligase parkin and is upregulated in Parkinson’s disease

Parkinson’s disease (PD) is characterized by the degeneration of dopaminergic neurons in the substantia nigra pars compacta (SNc). The loss of SNc dopaminergic neurons affects the plasticity of striatal neurons and leads to significant motor and cognitive disabilities during the progression of the disease. PARK2 encodes for the E3 ubiquitin ligase parkin and is implicated in genetic and sporadic PD. Mutations in PARK2 are a major contributing factor in the early onset of autosomal-recessive juvenile parkinsonism (AR-JP), although the mechanisms by which a disruption in parkin function contributes to the pathophysiology of PD remain unclear. Here we demonstrate that parkin is an E3 ligase for STEP₆₁ (striatal-enriched protein tyrosine phosphatase), a protein tyrosine phosphatase implicated in several neuropsychiatric disorders. In cellular models, parkin ubiquitinates STEP₆₁ and thereby regulates its level through the proteasome system, whereas clinically relevant parkin mutants fail to do so. STEP₆₁ protein levels are elevated on acute down-regulation of parkin or in PARK2 KO rat striatum. Relevant to PD, STEP₆₁ accumulates in the striatum of human sporadic PD and in 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-lesioned mice. The increase in STEP₆₁ is associated with a decrease in the phosphorylation of its substrate ERK1/2 and the downstream target of ERK1/2, pCREB [phospho-CREB (cAMP response element-binding protein)]. These results indicate that STEP₆₁ is a novel substrate of parkin, although further studies are necessary to determine whether elevated STEP₆₁ levels directly contribute to the pathophysiology of PD.Parkinson’s disease (PD) is a common motor disorder with clinical symptoms that include bradykinesia, resting tremor, rigidity, postural instability, and cognitive deficits (1–3). The pathophysiology of PD includes selective loss of dopaminergic neurons in the substantia nigra, with a progressive depletion of striatal dopamine and the presence of intraneuronal cytoplasmic inclusions known as Lewy bodies. Mutations of several genes are implicated in PD and are responsible for ∼10% of cases; the remaining cases are classified as sporadic PD. Although specific mutations in genes that include PARK2, PINK-1, LRRK2, and DJ-1 are known, the effects these mutations have on intracellular signaling and disease progression are not well understood and form an area of intense investigation (2, 4–6).STEP₆₁ (striatal-enriched protein tyrosine phosphatase) is a brain-specific phosphatase enriched in the striatum and in other regions, including cortex, hippocampus, and substantia nigra (7–9). STEP₆₁ levels are elevated in several disorders, including Alzheimer’s disease, schizophrenia, and fragile X syndrome (10–12). STEP₆₁ levels are normally regulated by the ubiquitin proteasome system, and disruption of this pathway leads to an accumulation of STEP₆₁ in both Alzheimer’s disease and schizophrenia (10, 11).Substrates of STEP₆₁ include ERK1/2, Pyk2, Fyn, the GluN2B subunit of the NMDA receptor, and the GluA2 subunit of the AMPA receptor. The current model of STEP₆₁ function is that it opposes the development of synaptic strengthening by dephosphorylating regulatory tyrosines on these substrates. In the case of the kinases, STEP₆₁-mediated dephosphorylation of the regulatory Tyr within the activation loop inactivates these enzymes (13–16). STEP-mediated dephosphorylation of Tyr residues in the glutamate receptor subunits results in internalization of GluN1/GluN2B and GluA1/GluA2 receptor complexes (17–20). As a result, STEP KO mice have an increase in the basal Tyr phosphorylation of its substrates, including ERK1/2 and its downstream target pCREB (21, 22).Overexpression of STEP disrupts synaptic function, and thereby contributes to cognitive and behavioral deficits (23). Consistent with this hypothesis, genetic or pharmacologic reduction of STEP activity in several disorders in which STEP levels are elevated reverses the biochemical and cognitive deficits that are present (19, 24), and STEP KO mice demonstrate enhanced hippocampal long-term potentiation and enhanced hippocampal- and amygdalar-dependent memory tasks (22, 25).Direct mutations of the E3 ligase parkin (PARK2) result in autosomal recessive juvenile parkinsonism (AR-JP), with early onset of PD symptoms (26, 27); disruption of parkin activity is also implicated in sporadic PD (28–30). Moreover, PD toxins such as MPTP, rotenone, paraquat, and 6-hydroxydopamine alter parkin levels or its ligase activity and result in the accumulation of parkin substrates (31–35). Identification of new parkin substrates and characterization of their role or roles in synaptic function should result in a better understanding the molecular basis of PD.Here we identify parkin as an E3 ligase that ubiquitinates STEP₆₁. STEP₆₁ levels are increased in human PD brains and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-induced PD models and are associated with a decrease in the phosphorylation of ERK1/2 and CREB. As an increase in STEP₆₁ expression disrupts synaptic function and contributes to the cognitive deficits in several disorders, these findings suggest that the increase in STEP₆₁ levels in PD may contribute to the pathophysiology of this disorder.     

Drosophila TRPA1 isoforms detect UV light via photochemical production of H2O2

The transient receptor potential A1 (TRPA1) channel is an evolutionarily conserved detector of temperature and irritant chemicals. Here, we show that two specific isoforms of TRPA1 in Drosophila are H₂O₂ sensitive and that they can detect strong UV light via sensing light-induced production of H₂O₂. We found that ectopic expression of these H₂O₂-sensitive Drosophila TRPA1 (dTRPA1) isoforms conferred UV sensitivity to light-insensitive HEK293 cells and Drosophila neurons, whereas expressing the H₂O₂-insensitive isoform did not. Curiously, when expressed in one specific group of motor neurons in adult flies, the H₂O₂-sensitive dTRPA1 isoforms were as competent as the blue light-gated channelrhodopsin-2 in triggering motor output in response to light. We found that the corpus cardiacum (CC) cells, a group of neuroendocrine cells that produce the adipokinetic hormone (AKH) in the larval ring gland endogenously express these H₂O₂-sensitive dTRPA1 isoforms and that they are UV sensitive. Sensitivity of CC cells required dTRPA1 and H₂O₂ production but not conventional phototransduction molecules. Our results suggest that specific isoforms of dTRPA1 can sense UV light via photochemical production of H₂O₂. We speculate that UV sensitivity conferred by these isoforms in CC cells may allow young larvae to activate stress response—a function of CC cells—when they encounter strong UV, an aversive stimulus for young larvae.Light is an important sensory cue that has a wide-ranging influence on animal physiology and behavior. In addition to its role in vision, light detection also contributes to circadian rhythm regulation, sleep, phototaxis, and even mood control (1–5). Animals of different species have evolved diverse light sensors and light-detection cells to regulate various light-dependent physiological processes. For example, whereas rods and cones in mammals are critical for detecting and relaying image-forming visual information to the visual cortex, the intrinsically light-sensitive melanopsin-expressing retinal ganglion cells relay nonimage-forming visual information primarily to the suprachiasmatic nucleus to regulate circadian rhythm (6, 7).Similar to the diversity of cell types that sense light, the molecular mechanisms for light detection also vary. For example, in mammalian rods and cones, light activates a Rhodopsin-dependent phototransduction pathway that hyperpolarizes the cells via closing a cyclic nucleotide-gated channel (5). In the intrinsically light-sensitive retinal ganglion cells, however, light activates a melanopsin-dependent pathway that depolarizes the cells via opening TRP channels (6, 8). Further, in Drosophila PDF neurons, light has been shown to activate cryptochrome signaling to depolarize the cells (9). And in the ASJ sensory neuron in Caenorhabditis elegans, UV and blue light have been shown to activate the cell via signaling a specific GPCR known as LITE-1 (high energy light unresponsive protein 1) (10, 11).It has been shown that short wavelength UV and blue light can trigger reactive oxygen species (ROS) and H₂O₂ production in cultured cells (12), and H₂O₂ can modulate ion channel activities directly or indirectly (13–15). We therefore reasoned that sensing H₂O₂ might constitute another light-sensing mechanism. Indeed, a recent finding has suggested that two specific GPCRs—GUR-3 and LITE-1—both of which play important roles in light sensing in C. elegans, may also be H₂O₂ sensitive (16). Moreover, TRPA1, an evolutionarily conserved TRP channel known for its role in sensing many chemical irritants, has been shown to sense H₂O₂ (17–24), thus TRPA1 may be activated by light via sensing light-induced H₂O₂ production. Some recent evidence has demonstrated a role for TRPA1 in light sensing. First, in human melanocyte, TRPA1 has been shown to act to increase melanin production in response to UV (25). Moreover, in Drosophila, TRPA1 has been shown to increase neuronal activities of a specific group of larval somatosensory neurons (also known as the C4da neurons) in response to UV (26). However, in both cases, GPCRs—rhodopsin in the case of human melanocyte and Gr28b in the case of C4da neurons—are thought to mediate light-dependent activation of TRPA1 (25, 26); thus, it is not clear whether TRPA1 can be activated by light through H₂O₂ production.Here, we show that two specific isoforms of Drosophila dTRPA1 are H₂O₂ sensitive and that their H₂O₂ sensitivity allows them to detect UV without relying on conventional phototransduction molecules. We found that ectopic expression of these H₂O₂-sensitive dTRPA1 isoforms conferred UV sensitivity to light-insensitive cultured HEK293 cells and a few types of light-insensitive Drosophila neurons. The light and H₂O₂ sensitivities are specific to certain dTRPA1 isoforms, consistent with previous findings that different dTRPA1 isoforms exhibit distinct thermal sensitivities (20, 21). Strikingly, the H₂O₂-sensitive dTRPA1 was as effective as channelrhodopsin-2 (ChR2) in triggering light-produced motor responses when expressed in a specific group of motor neurons that control proboscis extension in adult Drosophila. We further discovered that the corpus cardiacum (CC) cells, a group of adipokinetic hormone (AKH)-producing cells that reside in the Drosophila larval ring gland, expressed the H₂O₂-sensitive dTRPA1 isoforms endogenously, and that these cells were UV and H₂O₂ sensitive. Their sensitivity required dTRPA1 and H₂O₂ production: Reducing dual oxidase (DUOX) or increasing catalase (cat) expression in them reduced their UV sensitivity significantly. In contrast, reducing PLC or GR28b in CC cells had little impact. Our results suggest specific H₂O₂-sensitive TRPA1 isoforms can be activated by UV via a photochemical transduction cascade and that these isoforms may be exploited as a UV-dependent optogenetic tool for controlling neuronal activities.     

From the Cover: Ryanodine receptor fragmentation and sarcoplasmic reticulum Ca2+ leak after one session of high-intensity interval exercise

High-intensity interval training (HIIT) is a time-efficient way of improving physical performance in healthy subjects and in patients with common chronic diseases, but less so in elite endurance athletes. The mechanisms underlying the effectiveness of HIIT are uncertain. Here, recreationally active human subjects performed highly demanding HIIT consisting of 30-s bouts of all-out cycling with 4-min rest in between bouts (≤3 min total exercise time). Skeletal muscle biopsies taken 24 h after the HIIT exercise showed an extensive fragmentation of the sarcoplasmic reticulum (SR) Ca²⁺ release channel, the ryanodine receptor type 1 (RyR1). The HIIT exercise also caused a prolonged force depression and triggered major changes in the expression of genes related to endurance exercise. Subsequent experiments on elite endurance athletes performing the same HIIT exercise showed no RyR1 fragmentation or prolonged changes in the expression of endurance-related genes. Finally, mechanistic experiments performed on isolated mouse muscles exposed to HIIT-mimicking stimulation showed reactive oxygen/nitrogen species (ROS)-dependent RyR1 fragmentation, calpain activation, increased SR Ca²⁺ leak at rest, and depressed force production due to impaired SR Ca²⁺ release upon stimulation. In conclusion, HIIT exercise induces a ROS-dependent RyR1 fragmentation in muscles of recreationally active subjects, and the resulting changes in muscle fiber Ca²⁺-handling trigger muscular adaptations. However, the same HIIT exercise does not cause RyR1 fragmentation in muscles of elite endurance athletes, which may explain why HIIT is less effective in this group.It is increasingly clear that regular physical exercise plays a key role in the general well-being, disease prevention, and longevity of humans. Impaired muscle function manifesting as muscle weakness and premature fatigue development are major health problems associated with the normal aging process as well as with numerous common diseases (1). Physical exercise has a fundamental role in preventing and/or reversing these muscle problems, and training also improves the general health status in numerous diseases (2–4). On the other side of the spectrum, excessive muscle use can induce prolonged force depressions, which may set the limit on training tolerance and performance of top athletes (5, 6).Recent studies imply a key role of the sarcoplasmic reticulum (SR) Ca²⁺ release channel, the ryanodine receptor 1 (RyR1), in the reduced muscle strength observed in numerous physiological conditions, such as after strenuous endurance training (6), in situations with prolonged stress (7), and in normal aging (8, 9). Defective RyR1 function is also implied in several pathological states, including generalized inflammatory disorders (10), heart failure (11), and inherited conditions such as malignant hyperthermia (12) and Duchenne muscular dystrophy (13). In many of the above conditions, there is a link between the impaired RyR1 function and modifications induced by reactive oxygen/nitrogen species (ROS) (6, 8, 10, 12, 13). Conversely, altered RyR1 function may also be beneficial by increasing the cytosolic free [Ca²⁺] ([Ca²⁺]_i) at rest, which can stimulate mitochondrial biogenesis and thereby increase fatigue resistance (14–16). Intriguingly, effective antioxidant treatment hampers beneficial adaptations triggered by endurance training (17–19), and this effect might be due to antioxidants preventing ROS-induced modifications of RyR1 (20).A high-intensity interval training (HIIT) session typically consists of a series of brief bursts of vigorous physical exercise separated by periods of rest or low-intensity exercise. A major asset of HIIT is that beneficial adaptations can be obtained with much shorter exercise duration than with traditional endurance training (21–25). HIIT has been shown to effectively stimulate mitochondrial biogenesis in skeletal muscle and increase endurance in untrained and recreationally active healthy subjects (22, 26), whereas positive effects in elite endurance athletes are less clear (21, 27, 28). Moreover, HIIT improves health and physical performance in various pathological conditions, including cardiovascular disease, obesity, and type 2 diabetes (29, 30). Thus, short bouts of vigorous physical exercise trigger intracellular signaling of large enough magnitude and duration to induce extensive beneficial adaptations in skeletal muscle. The initial signaling that triggers these adaptations is not known.In this study, we tested the hypothesis that a single session of HIIT induces ROS-dependent RyR1 modifications. These modifications might cause prolonged force depression due to impaired SR Ca²⁺ release during contractions. Conversely, they may also initiate beneficial muscular adaptations due to increased SR Ca²⁺ leak at rest.     

Helical arrays of U-shaped ATP synthase dimers form tubular cristae in ciliate mitochondria

F₁F_o-ATP synthases are universal energy-converting membrane protein complexes that synthesize ATP from ADP and inorganic phosphate. In mitochondria of yeast and mammals, the ATP synthase forms V-shaped dimers, which assemble into rows along the highly curved ridges of lamellar cristae. Using electron cryotomography and subtomogram averaging, we have determined the in situ structure and organization of the mitochondrial ATP synthase dimer of the ciliate Paramecium tetraurelia. The ATP synthase forms U-shaped dimers with parallel monomers. Each complex has a prominent intracrista domain, which links the c-ring of one monomer to the peripheral stalk of the other. Close interaction of intracrista domains in adjacent dimers results in the formation of helical ATP synthase dimer arrays, which differ from the loose dimer rows in all other organisms observed so far. The parameters of the helical arrays match those of the cristae tubes, suggesting the unique features of the P. tetraurelia ATP synthase are directly responsible for generating the helical tubular cristae. We conclude that despite major structural differences between ATP synthase dimers of ciliates and other eukaryotes, the formation of ATP synthase dimer rows is a universal feature of mitochondria and a fundamental determinant of cristae morphology.F₁F_o-ATP synthases are ubiquitous, highly conserved energy-converting membrane protein complexes. ATP synthases produce ATP from ADP and inorganic phosphate (P_i) by rotary catalysis (1, 2) using the energy stored in a transmembrane electrochemical gradient. The ∼600-kDa monomer of the mitochondrial ATP synthase is composed of a soluble F₁ subcomplex and a membrane-bound F_o subcomplex (3). The main components of the F₁ subcomplex are the (αβ)₃ hexamer and the central stalk (4). The F_o subcomplex includes a rotor ring of 8–15 hydrophobic c subunits (5), the peripheral stalk, and several small hydrophobic stator subunits. Protons flowing through the membrane part of the F_o subcomplex drive the rotation of the c-ring (6–9). The central stalk transmits the torque generated by c-ring rotation to the catalytic head of the F₁ subcomplex, where it induces conformational changes of the α and β subunits that result in phosphate bond formation and the generation of ATP. The catalytic (αβ)₃ hexamer is held stationary relative to the membrane region by the peripheral stalk (10, 11). Several high-resolution structures of the F₁/rotor ring complexes have been solved by X-ray crystallography (12–16), and the structure of the complete assembly has been determined by cryoelectron microscopy (cryo-EM) (10, 17–20).In mitochondria, the ATP synthase forms dimers in the inner membrane. In fungi, plants, and metazoans, the dimers are V-shaped and associate into rows along the highly curved ridges of lamellar cristae (19–22). F_o subcomplexes of the two monomers in the dimer interact in the lipid bilayer via a number of hydrophobic stator subunits (20, 23–25). Coarse-grained molecular dynamics simulations have suggested that the V-shape of the ATP synthase dimers induces local membrane curvature, which in turn drives the association of ATP synthase dimers into rows (20). The exact role of the dimer rows is unclear, however rows of ATP synthase dimers have been proposed to promote the formation of lamellar cristae in yeast (20, 26).So far, all rows of ATP synthase dimers observed by electron cryotomography have been more or less straight (19–22, 27). However, an earlier deep-etch freeze-fracture study of mitochondria from the ciliate Paramecium multimicronucleatum revealed double rows of interdigitating 10-nm particles on helical tubular cristae (28). These particles were interpreted as ATP synthases, which, if correct, would suggest that the mitochondrial ATP synthase can assemble into rows that differ significantly from the standard geometry found in lamellar cristae (19, 21, 22).To investigate the helical rows in more detail, we performed electron cryotomography of isolated mitochondrial membranes from Paramecium tetraurelia. Using subtomogram averaging, we show that these helical rows do indeed consist of ATP synthase molecules, as suggested by Allen et al. (28). However, unlike the V-shaped dimers of metazoans, the ATP synthase of this species forms U-shaped dimers, which have new and unusual structural features. When assembled into the helical rows, the ATP synthase monomers interdigitate, whereas the U-shaped dimers align side by side. Thus, rows of ATP synthase dimers seem to be a universal feature of all mitochondria. We propose that the particular shape of the P. tetraurelia ATP synthase dimer induces its assembly into helical rows, which in turn cause the formation of the helical tubular cristae of ciliates.     

Quantum mechanical calculations suggest that lytic polysaccharide monooxygenases use a copper-oxyl,oxygen-rebound mechanism

Lytic polysaccharide monooxygenases (LPMOs) exhibit a mononuclear copper-containing active site and use dioxygen and a reducing agent to oxidatively cleave glycosidic linkages in polysaccharides. LPMOs represent a unique paradigm in carbohydrate turnover and exhibit synergy with hydrolytic enzymes in biomass depolymerization. To date, several features of copper binding to LPMOs have been elucidated, but the identity of the reactive oxygen species and the key steps in the oxidative mechanism have not been elucidated. Here, density functional theory calculations are used with an enzyme active site model to identify the reactive oxygen species and compare two hypothesized reaction pathways in LPMOs for hydrogen abstraction and polysaccharide hydroxylation; namely, a mechanism that employs a η¹-superoxo intermediate, which abstracts a substrate hydrogen and a hydroperoxo species is responsible for substrate hydroxylation, and a mechanism wherein a copper-oxyl radical abstracts a hydrogen and subsequently hydroxylates the substrate via an oxygen-rebound mechanism. The results predict that oxygen binds end-on (η¹) to copper, and that a copper-oxyl–mediated, oxygen-rebound mechanism is energetically preferred. The N-terminal histidine methylation is also examined, which is thought to modify the structure and reactivity of the enzyme. Density functional theory calculations suggest that this posttranslational modification has only a minor effect on the LPMO active site structure or reactivity for the examined steps. Overall, this study suggests the steps in the LPMO mechanism for oxidative cleavage of glycosidic bonds.Carbohydrates are the most diverse set of biomolecules, and thus, many enzyme classes have evolved to assemble, modify, and depolymerize carbohydrates, including glycosyltransferases, glycoside hydrolases, carbohydrate esterases, and polysaccharide lyases (1). Recently, a new enzymatic paradigm was discovered that employs copper-dependent oxidation to cleave glycosidic bonds in polysaccharides (2–13). These newly classified enzymes, termed lytic polysaccharide monooxygenases (LPMOs), broadly resemble other copper monooxygenases and some hydroxylation catalysts (14–21).The discovery that LPMOs use an oxidative mechanism has attracted interest both because it is a unique paradigm for carbohydrate modification that employs a powerful C–H activation mechanism, and also because LPMOs synergize with hydrolytic enzymes in biomass conversion to sugars because they act directly on the crystalline polysaccharide surface without the requirement for depolymerization (4, 22, 23), making them of interest in biofuels production. LPMOs were originally characterized as Family 61 glycoside hydrolases (GH61s, reclassified as auxiliary activity 9, AA9) or Family 33 carbohydrate-binding modules (CBM33s, reclassified as AA10), which are structurally similar enzymes found in fungi and nonfungal organisms (22), respectively. In 2005, Vaaje-Kolstad et al. described the synergism (24) of a chitin-active CBM33 (chitin-binding protein, CBP21) with hydrolases, but the mechanism was not apparent. Harris et al. demonstrated that a GH61 boosts hydrolytic enzyme activity on lignocellulosic biomass (2). Vaaje-Kolstad et al. subsequently showed that CBP21 employs an oxidative mechanism to cleave glycosidic linkages in chitin (4).Following these initial discoveries, multiple features of LPMOs have been elucidated. LPMOs use copper (5–7) and produce either aldonic acids or 4-keto sugars at oxidized chain ends, believed to result from hydroxylation at the C1 or C4 carbon, respectively. Hydroxylation at the C1 carbon is proposed to spontaneously undergo elimination to a lactone followed by hydrolytic ring opening to an aldonic acid, whereas hydroxylation and elimination at C4 yields a 4-keto sugar at the nonreducing end (5–12). The active site is a mononuclear type(II) copper center ligated by a “histidine brace” (5, 12), comprising a bidentate N-terminal histidine ligand via the amino terminus and an imidazole ring nitrogen atom and another histidine residue also via a ring nitrogen atom. Hemsworth et al. reported a bacterial LPMO structure wherein the active site copper ion was photoreduced to Cu(I) (12), and Aachmann et al. demonstrated that Cu(I) binds with higher affinity than Cu(II) in CBP21 (13). A structural study of a fungal LPMO revealed an N-terminal methylation on a nitrogen atom in the imidazole ring of unknown function (5), but some LPMOs are active without this modification (6, 11). LPMOs require reducing agents for activity such as ascorbate (2–8, 10–12), and cellobiose dehydrogenase (CDH), a common fungal secretome component, can potentiate LPMO activity in lieu of a small-molecule reducing agent (7, 8).Overall, many structural and mechanistic insights have been reported since the discoveries that LPMOs are oxidative enzymes (4–10). However, many questions remain regarding LPMO function (22, 25). Here, we examine the LPMO catalytic mechanism with density functional theory (DFT) calculations on an active site model (ASM) of a fungal LPMO. We seek to (i) understand the identity of the reactive oxygen species (ROS), (ii) compare two hypothesized catalytic mechanisms, and (iii) examine the role of N-terminal methylation in catalysis.     

Structural insights into the Ca2+ and PI(4,5)P2 binding modes of the C2 domains of rabphilin 3A and synaptotagmin 1

Proteins containing C2 domains are the sensors for Ca²⁺ and PI(4,5)P₂ in a myriad of secretory pathways. Here, the use of a free-mounting system has enabled us to capture an intermediate state of Ca²⁺ binding to the C2A domain of rabphilin 3A that suggests a different mechanism of ion interaction. We have also determined the structure of this domain in complex with PI(4,5)P₂ and IP₃ at resolutions of 1.75 and 1.9 Å, respectively, unveiling that the polybasic cluster formed by strands β3–β4 is involved in the interaction with the phosphoinositides. A comparative study demonstrates that the C2A domain is highly specific for PI(4,5)P₂/PI(3,4,5)P₃, whereas the C2B domain cannot discriminate among any of the diphosphorylated forms. Structural comparisons between C2A domains of rabphilin 3A and synaptotagmin 1 indicated the presence of a key glutamic residue in the polybasic cluster of synaptotagmin 1 that abolishes the interaction with PI(4,5)P₂. Together, these results provide a structural explanation for the ability of different C2 domains to pull plasma and vesicle membranes close together in a Ca²⁺-dependent manner and reveal how this family of proteins can use subtle structural changes to modulate their sensitivity and specificity to various cellular signals.C2 modules are most commonly found in enzymes involved in lipid modifications and signal transduction and in proteins involved in membrane trafficking. They consist of 130 residues and share a common fold composed of two four-stranded β-sheets arranged in a compact β-sandwich connected by surface loops and helices (1–4). Many of these C2 domains have been demonstrated to function in a Ca²⁺-dependent membrane-binding manner and hence act as cellular Ca²⁺ sensors. Calcium ions bind in a cup-shaped invagination formed by three loops at one tip of the β-sandwich where the coordination spheres for the Ca²⁺ ions are incomplete (5–7). This incomplete coordination sphere can be occupied by neutral and anionic (7–9) phospholipids, enabling the C2 domain to dock at the membrane.Previous work in our laboratory has shed light on the 3D structure of the C2 domain of PKCα in complex with both PS and PI(4,5)P₂ simultaneously (10). This revealed an additional lipid-binding site located in the polybasic region formed by β3–β4 strands that preferentially binds to PI(4,5)P₂ (11–15). This site is also conserved in a wide variety of C2 domains of topology I, for example synaptotagmins, rabphilin 3A, DOC2, and PI3KC2α (10, 16–19). Given the importance of PI(4,5)P₂ for bringing the vesicle and plasma membranes together before exocytosis to ensure rapid and efficient fusion upon calcium influx (20–23), it is crucial to understand the molecular mechanisms beneath this event.Many studies have reported different and contradictory results about the membrane binding properties of C2A and C2B domains of synaptotagmin 1 and rabphilin 3A providing an unclear picture about how Ca²⁺ and PI(4,5)P₂ combine to orchestrate the vesicle fusion and repriming processes by acting through the two C2 domains existing in each of these proteins (16, 20, 22, 24–28). A myriad of works have explored the 3D structure of the individual C2 domains of both synaptotagmins and rabphilin 3A (5, 26, 27, 29, 30). However, the impossibility of obtaining crystal structures of these domains in complex with Ca²⁺ and phosphoinositides has hindered the understanding of the molecular mechanism driving the PI(4,5)P₂–C2 domain interaction. Here, we sought to unravel the molecular mechanism of Ca²⁺ and PI(4,5)P₂ binding to the C2A domain of rabphilin 3A by X-ray crystallography. A combination of site-directed mutagenesis together with isothermal titration calorimetry (ITC), fluorescence resonance of energy transfer (FRET), and aggregation experiments has enabled us to propose a molecular mechanism of Ca²⁺/PI(4,5)P₂-dependent membrane interaction through two different motifs that could bend the membrane and accelerate the vesicle fusion process. A comparative analysis revealed the structural basis for the different phosphoinositide affinities of C2A and -B domains. Furthermore, the C2A domain of synaptotagmin 1 lacks one of the key residues responsible for the PI(4,5)P₂ interaction, confirming it is a non-PI(4,5)P₂ responder.