Synaptotagmin-1 is a bidirectional Ca2+ sensor for neuronal endocytosis

Exocytosis and endocytosis are tightly coupled. In addition to initiating exocytosis, Ca²⁺ plays critical roles in exocytosis–endocytosis coupling in neurons and nonneuronal cells. Both positive and negative roles of Ca²⁺ in endocytosis have been reported; however, Ca²⁺ inhibition in endocytosis remains debatable with unknown mechanisms. Here, we show that synaptotagmin-1 (Syt1), the primary Ca²⁺ sensor initiating exocytosis, plays bidirectional and opposite roles in exocytosis–endocytosis coupling by promoting slow, small-sized clathrin-mediated endocytosis but inhibiting fast, large-sized bulk endocytosis. Ca²⁺-binding ability is required for Syt1 to regulate both types of endocytic pathways, the disruption of which leads to inefficient vesicle recycling under mild stimulation and excessive membrane retrieval following intense stimulation. Ca²⁺-dependent membrane tubulation may explain the opposite endocytic roles of Syt1 and provides a general membrane-remodeling working model for endocytosis determination. Thus, Syt1 is a primary bidirectional Ca²⁺ sensor facilitating clathrin-mediated endocytosis but clamping bulk endocytosis, probably by manipulating membrane curvature to ensure both efficient and precise coupling of endocytosis to exocytosis.

Endocytosis and subsequent vesicle recycling are spatiotemporally coupled to exocytosis, which is critical for neurons and endocrinal cells to maintain the integrity of plasma membrane architecture, intracellular homeostasis, and sustained neurotransmission (1–3). In addition to triggering vesicular exocytosis, neural activity/Ca²⁺ also play an executive role in the coupling of endocytosis to exocytosis (1, 2, 4–6). Following a pioneering study 40 y ago (7), extensive studies have been conducted and showed that Ca²⁺ triggers and facilitates vesicle endocytosis in neurons and nonneuronal secretory cells (1, 8–11). Accumulating evidence also shows that intracellular Ca²⁺ may inhibit endocytosis (12–15), which has been challenged greatly due to the apparently lower occurrences in few preparations and the missing underlining mechanisms, making the endocytic role of Ca²⁺ a four-decades–long dispute (1, 2, 4, 6).Machineries and regulators involved in exocytosis–endocytosis coupling have been extensively studied for over 30 y. The soluble N-ethylmaleimide–sensitive factor attachment protein receptors (SNAREs) and synaptophysin play critical dual roles in exocytosis and endocytosis during neurotransmission (2, 3, 16, 17). Calmodulin and synaptotagmin-1 (Syt1) are currently known primary Ca²⁺ sensors facilitating endocytosis (1, 9, 16, 18, 19). Ca²⁺/calmodulin activate calcineurin, which dephosphorylates endocytic proteins (e.g., dynamin, synaptojanin, and amphiphysin) to facilitate clathrin-mediated endocytosis (CME) and clathrin-independent fast endocytosis (1, 2). Syt1 is a dual Ca²⁺ sensor for both exocytosis and endocytosis (5, 16, 18–20). It promotes CME through binding with the endocytic adaptors adaptor protein-2 (AP-2) and stonin-2 (21–24). In contrast to the well-established Ca²⁺ sensors that promote endocytosis, the mechanism of Ca²⁺-dependent inhibition in endocytosis remains unknown.CME is the classical but slow endocytosis pathway for vesicle retrieval under resting conditions or in response to mild stimulation, while the accumulated Ca²⁺ also triggers calmodulin/calcineurin-dependent bulk endocytosis, which takes up a large area of plasma membrane to fulfill the urgent requirement for high-speed vesicle exocytosis (1–3). They cooperate with kiss-and-run and ultrafast endocytosis to ensure both sufficient and precise membrane retrieval following exocytosis (3, 25–27). These endocytic pathways are all initiated from membrane invagination and are critically controlled by neural activity. However, how the switch between different endocytic modes is precisely determined remains largely unknown.Here, by combining electrophysiological recordings, confocal live imaging, superresolution stimulated emission depletion (STED) imaging, in vitro liposome manipulation, and electron microscope imaging of individual endocytic vesicles, we define Syt1 as a primary and bidirectional Ca²⁺ sensor for endocytosis, which promotes CME but inhibits bulk endocytosis, probably by mediating membrane remodeling. The balance between the facilitatory and inhibitory effects of Syt1 on endocytosis offers a fine-tuning mechanism to ensure both efficient and precise coupling of endocytosis to exocytosis. By including a non-Ca²⁺–binding Syt as the constitutive brake, this work also explains the four-decades–long puzzle about the positive and negative Ca²⁺ effects on endocytosis.     

From the Cover: 90Y-daclizumab,an anti-CD25 monoclonal antibody,provided responses in 50% of patients with relapsed Hodgkin’s lymphoma

Despite significant advances in the treatment of Hodgkin’s lymphoma (HL), a significant proportion of patients will not respond or will subsequently relapse. We identified CD25, the IL-2 receptor alpha subunit, as a favorable target for systemic radioimmunotherapy of HL. The scientific basis for the clinical trial was that, although most normal cells with exception of Treg cells do not express CD25, it is expressed by a minority of Reed–Sternberg cells and by most polyclonal T cells rosetting around Reed–Sternberg cells. Forty-six patients with refractory and relapsed HL were evaluated with up to seven i.v. infusions of the radiolabeled anti-CD25 antibody ⁹⁰Y-daclizumab. ⁹⁰Y provides strong β emissions that kill tumor cells at a distance by a crossfire effect. In 46 evaluable HL patients treated with ⁹⁰Y-daclizumab there were 14 complete responses and nine partial responses; 14 patients had stable disease, and nine progressed. Responses were observed both in patients whose Reed–Sternberg cells expressed CD25 and in those whose neoplastic cells were CD25⁻ provided that associated rosetting T cells expressed CD25. As assessed using phosphorylated H2AX (γ-H2AX) as a bioindicator of the effects of radiation exposure, predominantly nonmalignant cells in the tumor microenvironment manifested DNA damage, as reflected by increased expression of γ-H2AX. Toxicities were transient bone-marrow suppression and myelodysplastic syndrome in six patients who had not been evaluated with bone-marrow karyotype analyses before therapy. In conclusion, repeated ⁹⁰Y-daclizumab infusions directed predominantly toward nonmalignant T cells rosetting around Reed–Sternberg cells provided meaningful therapy for select HL patients.Treatment with combination chemotherapy, radiation, and hematopoietic stem cell transplantation has increased the disease-free survival in Hodgkin’s lymphoma (HL) from less than 5% in 1963 to more than 80% at present (1–6). Recently the US Food and Drug Administration approved brentuximab vedotin for the treatment of relapsed HL (7). Furthermore the anti-PD1 agent pembrolizumab has shown promising results in classic HL (8). Nevertheless, a significant fraction of patients do not respond to treatment or subsequently relapse. To date more than 30 different mAb preparations directed toward antigens expressed by malignant Reed–Sternberg cells have been studied (6). These include mAbs linked to drugs or toxins targeting CD25 or CD30 expressed on Reed–Sternberg cells (6–11). Brentuximab vedotin, an anti-CD30 antibody drug conjugate, has induced a significant number of responses in refractory HL (7, 11). Although other antibody immunotoxins have demonstrated some clinical efficacy, they have yielded few complete responses (CRs) (6, 9, 10). An alternative strategy has been to arm mAbs with radionuclides. Radioimmunotherapy using ⁹⁰Y–anti-ferritin and ¹³¹I–anti-CD30 antibodies has resulted in partial (PRs) and CRs in HL (12–15). Deficiencies with these approaches reflect the lack of tumor specificity of ferritin-targeted antibodies and the small number of CD30-expressing Reed–Sternberg cells in the tumor.As an alternative, we identified CD25, the IL-2 receptor alpha subunit (IL-2Rα), as a more favorable target for systemic radioimmunotherapy of HL (16–22). The scientific rationale is that, with the exception of Treg cells, CD25 is not expressed by normal resting lymphoid cells, but it is expressed on both a minority of Reed–Sternberg cells and, critically, on T cells rosetting around Reed–Sternberg cells in HL (6, 23, 24). ⁹⁰Y, an energetic β particle emitter with a mean tissue path length of 5 mm and a maximal path length of 11 mm, acts through “crossfire” throughout tumor masses, providing a strategy for killing tumor cells at a distance of several cell diameters, including Reed–Sternberg cells that lack CD25 expression provided that T cells in their vicinity express the target antigen (16, 23, 24). In the current phase II trial we treated 46 patients with recurrent or refractory HL with ⁹⁰Y-daclizumab every 6–10 wk for up to seven doses, depending on hematological recovery. The activity of ⁹⁰Y used in the present trial was determined on the basis of three previous phase I/II dose-escalation trials of ⁹⁰Y–anti-CD25 performed in patients with lymphoproliferative disorders (16).     

Loss of Miro1-directed mitochondrial movement results in a novel murine model for neuron disease

Defective mitochondrial distribution in neurons is proposed to cause ATP depletion and calcium-buffering deficiencies that compromise cell function. However, it is unclear whether aberrant mitochondrial motility and distribution alone are sufficient to cause neurological disease. Calcium-binding mitochondrial Rho (Miro) GTPases attach mitochondria to motor proteins for anterograde and retrograde transport in neurons. Using two new KO mouse models, we demonstrate that Miro1 is essential for development of cranial motor nuclei required for respiratory control and maintenance of upper motor neurons required for ambulation. Neuron-specific loss of Miro1 causes depletion of mitochondria from corticospinal tract axons and progressive neurological deficits mirroring human upper motor neuron disease. Although Miro1-deficient neurons exhibit defects in retrograde axonal mitochondrial transport, mitochondrial respiratory function continues. Moreover, Miro1 is not essential for calcium-mediated inhibition of mitochondrial movement or mitochondrial calcium buffering. Our findings indicate that defects in mitochondrial motility and distribution are sufficient to cause neurological disease.Motor neuron diseases (MNDs), including ALS and spastic paraplegia (SP), are characterized by the progressive, length-dependent degeneration of motor neurons, leading to muscle atrophy, paralysis, and, in some cases, premature death. There are both inherited and sporadic forms of MNDs, which can affect upper motor neurons, lower motor neurons, or both. Although the molecular and cellular causes of most MNDs are unknown, many are associated with defects in axonal transport of cellular components required for neuron function and maintenance (1–6).A subset of MNDs is associated with impaired mitochondrial respiration and mitochondrial distribution. This observation has led to the hypothesis that neurodegeneration results from defects in mitochondrial motility and distribution, which, in turn, cause subcellular ATP depletion and interfere with mitochondrial calcium ([Ca²⁺]_m) buffering at sites of high synaptic activity (reviewed in ref. 7). It is not known, however, whether mitochondrial motility defects are a primary cause or a secondary consequence of MND progression. In addition, it has been difficult to isolate the primary effect of mitochondrial motility defects in MNDs because most mutations that impair mitochondrial motility in neurons also affect transport of other organelles and vesicles (1, 8–11).In mammals, the movement of neuronal mitochondria between the cell body and the synapse is controlled by adaptors called trafficking kinesin proteins (Trak1 and Trak2) and molecular motors (kinesin heavy chain and dynein), which transport the organelle in the anterograde or retrograde direction along axonal microtubule tracks (7, 12–24). Mitochondrial Rho (Miro) GTPase proteins are critical for transport because they are the only known surface receptors that attach mitochondria to these adaptors and motors (12–15, 18, 25, 26). Miro proteins are tail-anchored in the outer mitochondrial membrane with two GTPase domains and two predicted calcium-binding embryonic fibroblast (EF) hand motifs facing the cytoplasm (12, 13, 25, 27, 28). A recent Miro structure revealed two additional EF hands that were not predicted from the primary sequence (29). Studies in cultured cells suggest that Miro proteins also function as calcium sensors (via their EF hands) to regulate kinesin-mediated mitochondrial “stopping” in axons (15, 16, 26). Miro-mediated movement appears to be inhibited when cytoplasmic calcium is elevated in active synapses, effectively recruiting mitochondria to regions where calcium buffering and energy are needed. Despite this progress, the physiological relevance of these findings has not yet been tested in a mammalian animal model. In addition, mammals ubiquitously express two Miro orthologs, Miro1 and Miro2, which are 60% identical (12, 13). However, the individual roles of Miro1 and Miro2 in neuronal development, maintenance, and survival have no been evaluated.We describe two new mouse models that establish the importance of Miro1-mediated mitochondrial motility and distribution in mammalian neuronal function and maintenance. We show that Miro1 is essential for development/maintenance of specific cranial neurons, function of postmitotic motor neurons, and retrograde mitochondrial motility in axons. Loss of Miro1-directed retrograde mitochondrial transport is sufficient to cause MND phenotypes in mice without abrogating mitochondrial respiratory function. Furthermore, Miro1 is not essential for calcium-mediated inhibition of mitochondrial movement or [Ca²⁺]_m buffering. These findings have an impact on current models for Miro1 function and introduce a specific and rapidly progressing mouse model for MND.     

Redox potential of the terminal quinone electron acceptor QB in photosystem II reveals the mechanism of electron transfer regulation

Photosystem II (PSII) extracts electrons from water at a Mn₄CaO₅ cluster using light energy and then transfers them to two plastoquinones, the primary quinone electron acceptor Q_A and the secondary quinone electron acceptor Q_B. This forward electron transfer is an essential process in light energy conversion. Meanwhile, backward electron transfer is also significant in photoprotection of PSII proteins. Modulation of the redox potential (E_m) gap of Q_A and Q_B mainly regulates the forward and backward electron transfers in PSII. However, the full scheme of electron transfer regulation remains unresolved due to the unknown E_m value of Q_B. Here, for the first time (to our knowledge), the E_m value of Q_B reduction was measured directly using spectroelectrochemistry in combination with light-induced Fourier transform infrared difference spectroscopy. The E_m(Q_B⁻/Q_B) was determined to be approximately +90 mV and was virtually unaffected by depletion of the Mn₄CaO₅ cluster. This insensitivity of E_m(Q_B⁻/Q_B), in combination with the known large upshift of E_m(Q_A⁻/Q_A), explains the mechanism of PSII photoprotection with an impaired Mn₄CaO₅ cluster, in which a large decrease in the E_m gap between Q_A and Q_B promotes rapid charge recombination via Q_A⁻.In oxygenic photosynthesis in plants and cyanobacteria, photosystem II (PSII) has an important function in light-driven water oxidation, a process that leads to the generation of electrons and protons for CO₂ reduction and ATP synthesis, respectively (1–3). Photosynthetic water oxidation also produces molecular oxygen as a byproduct, which is the source of atmospheric oxygen and sustains virtually all life on Earth. PSII reactions are initiated by light-induced charge separation between a chlorophyll (Chl) dimer (P680) and a pheophytin (Pheo) electron acceptor, leading to the formation of a P680⁺Pheo⁻ radical pair (4, 5). An electron hole on P680⁺ is transferred to a Mn₄CaO₅ cluster, the catalytic center of water oxidation, via the redox-active tyrosine, Y_Z (D1-Tyr161). At the Mn₄CaO₅ cluster, water oxidation proceeds through a cycle of five intermediates denoted S_n states (n = 0–4) (6, 7). On the electron acceptor side, the electron is transferred from Pheo⁻ to the primary quinone electron acceptor Q_A and then to the secondary quinone electron acceptor Q_B (8, 9). Q_A and Q_B have many similarities: they consist of plastoquinone (PQ), are located symmetrically around a nonheme iron center, and interact with D2 and D1 proteins, respectively, in a similar manner (Fig. 1) (10, 11). However, they play significantly different roles in PSII (8, 9). Q_A is only singly reduced to transfer an electron to Q_B, whereas Q_B accepts one or two electrons. When Q_B is doubly reduced, the resultant Q_B²⁻ takes up two protons to form plastoquinol (PQH₂), which is then released into thylakoid membranes. Differences between Q_A and Q_B could be caused by differences in the molecular interactions of PQ with surrounding proteins in Q_A and Q_B pockets, although the detailed mechanism remains to be clarified (12, 13).Open in a separate windowFig. 1.Redox cofactors in PSII and the electron transfer pathway (blue arrows). For the PSII structure, the X-ray crystallographic structure at 1.9-Å resolution (Protein Data Bank ID code 3ARC) (9) was used. The electron acceptor side is expanded, showing the arrangements of Q_A, Q_B, and the nonheme iron with their molecular interactions. Nearby carboxylic groups are also shown.Electron transfer reactions in PSII are highly regulated by the spatial localization of redox components and their redox potentials (E_m values). Both forward and backward electron transfers are important; backward electron transfers control charge recombination in PSII, and this serves as photoprotection for PSII proteins (5, 14–17). PSII involves specific mechanisms to regulate forward and backward electron transfer reactions in response to environmental changes. For instance, in strong light, some species of cyanobacteria increase the E_m of Pheo to facilitate charge recombination. Specifically, they exchange D1 subunits originating from different psbA genes to change the hydrogen bond interactions of Pheo (16–20). On the other hand, it was found that impairment of the Mn₄CaO₅ cluster led to a significant increase in the E_m of Q_A by ∼150 mV (21–27). This potential increase was thought to inhibit forward electron transfer to Q_B to promote direct relaxation of Q_A⁻ without forming triplet-state Chl, a precursor of harmful singlet oxygen (2, 5, 14, 15, 17, 23). In addition, charge recombination of Q_A⁻ with P680⁺ prevents oxidative damage by high-potential P680⁺ (5). However, the full mechanism of photoprotection by the regulation of the quinone electron acceptor E_m values remains to be resolved, because the E_m of Q_B has not been determined conclusively, and the effect of Mn₄CaO₅ cluster inactivation on it has not been examined (5).Although the E_m of the single reduction of Q_B has been estimated to be ∼80 mV higher than that of Q_A from kinetic and thermodynamic data (28–32), so far no reports have measured the E_m of Q_B directly. In contrast, the E_m of Q_A was measured extensively using chemical or electrochemical titrations and determined to be approximately −100 mV for oxygen-evolving PSII (21–27). The main reason for this difference is due to the fact that the Q_A reaction can be monitored readily by fluorescence measurement in that an increase in fluorescence indicates Q_A⁻ formation (8, 33–35). However, the fluorescence method cannot be used easily to monitor Q_B reduction. Although UV-Vis absorption and electron spin resonance have also been used to monitor Q_A⁻ in redox titration (summarized in ref. 22), so far these methods have not been used to monitor the titration of Q_B, likely because Q_A⁻ and Q_B⁻ give similar signals (36–39). Another spectroscopic method that can be used to monitor Q_A and Q_B reactions is Fourier transform infrared (FTIR) difference spectroscopy, which detects reaction-induced changes in the molecular vibrations of a cofactor and its environment in proteins (40–45). It was previously shown that comparison of FTIR difference spectra upon Q_A⁻ and Q_B⁻ formation showed some characteristic differences in spectral features (46). In particular, bands at 1,721 and 1,745 cm⁻¹, which were assigned to ester C=O vibrations of nearby Pheo molecules affected by the reduction of Q_A and Q_B, respectively, were suggested to be good markers for discriminating between Q_A and Q_B reactions (46).In this study, we directly measured the E_m of Q_B in PSII using spectroelectrochemistry and light-induced FTIR difference spectroscopy. The effect of Mn₄CaO₅ cluster depletion on the E_m value was also examined. Spectroelectrochemistry has been used to accurately measure the E_m values of cofactors in various redox proteins (47, 48) including redox cofactors in PSII (24, 25, 49, 50). FTIR spectroelectrochemistry, which has the additional merit of being able to provide structural information, has also been used to investigate redox reactions of biomolecules and proteins (48, 50–54). This method was recently applied to the nonheme iron center of PSII to examine the effect of Mn depletion on the E_m value and obtain structural information around the nonheme iron (50). The results in our study showed that the E_m of the first reduction of Q_B [E_m(Q_B⁻/Q_B)] was much higher than previously estimated, and the E_m of the second reduction [E_m(PQH₂/Q_B⁻)] was higher than the first reduction. Furthermore, we showed that Mn depletion hardly affected the E_m values of Q_B, in contrast to the large change in the E_m of Q_A (21–27). With these results, the mechanism of photoprotection of PSII when the Mn₄CaO₅ cluster is inactivated is now clearly explained.     

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.     

Thermodynamics of formation of coffinite,USiO4

Coffinite, USiO₄, is an important U(IV) mineral, but its thermodynamic properties are not well-constrained. In this work, two different coffinite samples were synthesized under hydrothermal conditions and purified from a mixture of products. The enthalpy of formation was obtained by high-temperature oxide melt solution calorimetry. Coffinite is energetically metastable with respect to a mixture of UO₂ (uraninite) and SiO₂ (quartz) by 25.6 ± 3.9 kJ/mol. Its standard enthalpy of formation from the elements at 25 °C is −1,970.0 ± 4.2 kJ/mol. Decomposition of the two samples was characterized by X-ray diffraction and by thermogravimetry and differential scanning calorimetry coupled with mass spectrometric analysis of evolved gases. Coffinite slowly decomposes to U₃O₈ and SiO₂ starting around 450 °C in air and thus has poor thermal stability in the ambient environment. The energetic metastability explains why coffinite cannot be synthesized directly from uraninite and quartz but can be made by low-temperature precipitation in aqueous and hydrothermal environments. These thermochemical constraints are in accord with observations of the occurrence of coffinite in nature and are relevant to spent nuclear fuel corrosion.In many countries with nuclear energy programs, spent nuclear fuel (SNF) and/or vitrified high-level radioactive waste will be disposed in an underground geological repository. Demonstrating the long-term (10⁶–10⁹ y) safety of such a repository system is a major challenge. The potential release of radionuclides into the environment strongly depends on the availability of water and the subsequent corrosion of the waste form as well as the formation of secondary phases, which control the radionuclide solubility. Coffinite (1), USiO₄, is expected to be an important alteration product of SNF in contact with silica-enriched groundwater under reducing conditions (2–8). It is also found, accompanied by thorium orthosilicate and uranothorite, in igneous and metamorphic rocks and ore minerals from uranium and thorium sedimentary deposits (2, 4, 5, 8–16). Under reducing conditions in the repository system, the uranium solubility (very low) in aqueous solutions is typically derived from the solubility product of UO₂. Stable U(IV) minerals, which could form as secondary phases, would impart lower uranium solubility to such systems. Thus, knowledge of coffinite thermodynamics is needed to constrain the solubility of U(IV) in natural environments and would be useful in repository assessment.In natural uranium deposits such as Oklo (Gabon) (4, 7, 11, 12, 14, 17, 18) and Cigar Lake (Canada) (5, 13, 15), coffinite has been suggested to coexist with uraninite, based on electron probe microanalysis (EPMA) (4, 5, 7, 11, 13, 17, 19, 20) and transmission electron microscopy (TEM) (8, 15). However, it is not clear whether such apparent replacement of uraninite by a coffinite-like phase is a direct solid-state process or occurs mediated by dissolution and reprecipitation.The precipitation of USiO₄ as a secondary phase should be favored in contact with silica-rich groundwater (21) [silica concentration >10⁻⁴ mol/L (22, 23)]. Natural coffinite samples are often fine-grained (4, 5, 8, 11, 13, 15, 24), due to the long exposure to alpha-decay event irradiation (4, 6, 25, 26) and are associated with other minerals and organic matter (6, 8, 12, 18, 27, 28). Hence the determination of accurate thermodynamic data from natural samples is not straightforward. However, the synthesis of pure coffinite also has challenges. It appears not to form by reacting the oxides under dry high-temperature conditions (24, 29). Synthesis from aqueous solutions usually produces UO₂ and amorphous SiO₂ impurities, with coffinite sometimes being only a minor phase (24, 30–35). It is not clear whether these difficulties arise from kinetic factors (slow reaction rates) or reflect intrinsic thermodynamic instability (33). Thus, there are only a few reported estimates of thermodynamic properties of coffinite (22, 36–40) and some of them are inconsistent. To resolve these uncertainties, we directly investigated the energetics of synthetic coffinite by high-temperature oxide melt solution calorimetry to obtain a reliable enthalpy of formation and explored its thermal decomposition.     

Symmetric activation and modulation of the human calcium-sensing receptor

The human extracellular calcium-sensing (CaS) receptor controls plasma Ca²⁺ levels and contributes to nutrient-dependent maintenance and metabolism of diverse organs. Allosteric modulation of the CaS receptor corrects disorders of calcium homeostasis. Here, we report the cryogenic-electron microscopy reconstructions of a near–full-length CaS receptor in the absence and presence of allosteric modulators. Activation of the homodimeric CaS receptor requires a break in the transmembrane 6 (TM6) helix of each subunit, which facilitates the formation of a TM6-mediated homodimer interface and expansion of homodimer interactions. This transformation in TM6 occurs without a positive allosteric modulator. Two modulators with opposite functional roles bind to overlapping sites within the transmembrane domain through common interactions, acting to stabilize distinct rotamer conformations of key residues on the TM6 helix. The positive modulator reinforces TM6 distortion and maximizes subunit contact to enhance receptor activity, while the negative modulator strengthens an intact TM6 to dampen receptor function. In both active and inactive states, the receptor displays symmetrical transmembrane conformations that are consistent with its homodimeric assembly.

Critical to the maintenance of Ca²⁺ homeostasis, the extracellular calcium-sensing (CaS) receptor was the first G protein–coupled receptor (GPCR) discovered to sense ions (1–3). The CaS receptor detects fluctuations in plasma Ca²⁺ at the parathyroid. In response to increases in Ca²⁺, it transmits signals to inhibit the release of parathyroid hormone, in turn preventing further rises in Ca²⁺ concentration (2, 3). In the cortical thick ascending limb of the renal nephron, the CaS receptor is also activated by surges in plasma Ca²⁺ and responds by inhibiting Ca²⁺ reabsorption. The excess urinary calcium excretion arising from CaS receptor activation lowers the plasma Ca²⁺ level. The CaS receptor is implicated in various pathologies associated with hypercalcemia and hypocalcemia (4). It has also been linked to the progression of diseases such as breast and colon cancer, in which the receptor modulates tumor growth (3, 5–7).The CaS receptor senses a diverse array of extracellular stimuli. During normal function, it activates multiple intracellular signaling pathways involving G_q/11, G_i/o, or G_12/13; in tumor cells, it is coupled to G_s (2, 3, 8, 9). In addition to the principal agonist Ca²⁺, the receptor is directly activated by aromatic l-amino acids (10, 11). Other CaS agonists include various divalent and trivalent cations (12), referred to as type I calcimimetics for mimicking the action of Ca²⁺ (13).The activity of the CaS receptor is also subject to allosteric modulation. Positive allosteric modulators (PAMs) are classified as type II calcimimetics for increasing the receptor sensitivity for Ca²⁺ (12–16). The prototypical PAM molecules share a phenylalkylamine structure, including cinacalcet and NPS R-568 (abbreviated as R-568). Cinacalcet was the first drug described to target a GPCR allosterically, and it is used clinically to treat hyperparathyroidism in patients with chronic kidney diseases (15). Negative allosteric modulators (NAMs) of the CaS receptor are referred to as calcilytics for suppressing the receptor response to Ca²⁺ (12–16). Synthetic calcilytics such as NPS-2143 and ronacaleret are also structurally related to phenylalkylamines. Recently, inorganic phosphate has been identified as an inhibitor of the receptor (11, 17).The CaS receptor rests within the class C family of GPCRs and functions as an obligate homodimer. Like other class C GPCRs, each CaS subunit contains a large extracellular domain (ECD) involved in orthosteric ligand binding, a seven-helix transmembrane (TM) domain responsible for G protein coupling, followed by an extended cytoplasmic tail (18–23). The conformations of the CaS ECDs in both the inactive and active states have been determined by X-ray crystallography (11, 24). The ECD structures also revealed how the receptor recognizes various extracellular ligands, including Ca²⁺, the amino acid l-Trp, and inorganic phosphate. Although the role of amino acids is still under debate (25), recent structural studies of full-length CaS receptor further confirmed that Ca²⁺ and amino acids cooperate to activate the receptor (26–28).The TM domain of the CaS receptor harbors the binding sites for PAM and NAM molecules according to previous mutagenesis studies (29–32). Recently reported modulator-bound CaS receptor structures revealed asymmetric TM configurations that are stabilized by PAM molecules binding in different poses within the separate subunits of the homodimer (33). We have determined PAM- and NAM-bound, as well as PAM-free, structures of a near–full-length CaS receptor using cryogenic-electron microscopy (cryo-EM) that display symmetric TM dimers and modulator poses, instead. This finding presents the possibility of receptor activation without requiring asymmetric conformational transition. Our structures also illustrate how distortion of TM6 provides the driving force for receptor activation. Furthermore, the presence of a PAM or NAM stabilizes distinct TM6 helix conformations to promote specific dimer arrangements and differentially modulate receptor function.     

Rab3-interacting molecules 2α and 2β promote the abundance of voltage-gated CaV1.3 Ca2+ channels at hair cell active zones

Ca²⁺ influx triggers the fusion of synaptic vesicles at the presynaptic active zone (AZ). Here we demonstrate a role of Ras-related in brain 3 (Rab3)–interacting molecules 2α and β (RIM2α and RIM2β) in clustering voltage-gated Ca_V1.3 Ca²⁺ channels at the AZs of sensory inner hair cells (IHCs). We show that IHCs of hearing mice express mainly RIM2α, but also RIM2β and RIM3γ, which all localize to the AZs, as shown by immunofluorescence microscopy. Immunohistochemistry, patch-clamp, fluctuation analysis, and confocal Ca²⁺ imaging demonstrate that AZs of RIM2α-deficient IHCs cluster fewer synaptic Ca_V1.3 Ca²⁺ channels, resulting in reduced synaptic Ca²⁺ influx. Using superresolution microscopy, we found that Ca²⁺ channels remained clustered in stripes underneath anchored ribbons. Electron tomography of high-pressure frozen synapses revealed a reduced fraction of membrane-tethered vesicles, whereas the total number of membrane-proximal vesicles was unaltered. Membrane capacitance measurements revealed a reduction of exocytosis largely in proportion with the Ca²⁺ current, whereas the apparent Ca²⁺ dependence of exocytosis was unchanged. Hair cell-specific deletion of all RIM2 isoforms caused a stronger reduction of Ca²⁺ influx and exocytosis and significantly impaired the encoding of sound onset in the postsynaptic spiral ganglion neurons. Auditory brainstem responses indicated a mild hearing impairment on hair cell-specific deletion of all RIM2 isoforms or global inactivation of RIM2α. We conclude that RIM2α and RIM2β promote a large complement of synaptic Ca²⁺ channels at IHC AZs and are required for normal hearing.Tens of Ca_V1.3 Ca²⁺ channels are thought to cluster within the active zone (AZ) membrane underneath the presynaptic density of inner hair cells (IHCs) (1–4). They make up the key signaling element, coupling the sound-driven receptor potential to vesicular glutamate release (5–7). The mechanisms governing the number of Ca²⁺ channels at the AZ as well as their spatial organization relative to membrane-tethered vesicles are not well understood. Disrupting the presynaptic scaffold protein Bassoon diminishes the numbers of Ca²⁺ channels and membrane-tethered vesicles at the AZ (2, 8). However, the loss of Bassoon is accompanied by the loss of the entire synaptic ribbon, which makes it challenging to distinguish the direct effects of gene disruption from secondary effects (9).Among the constituents of the cytomatrix of the AZ, RIM1 and RIM2 proteins are prime candidates for the regulation of Ca²⁺ channel clustering and function (10, 11). The family of RIM proteins has seven identified members (RIM1α, RIM1β, RIM2α, RIM2β, RIM2γ, RIM3γ, and RIM4γ) encoded by four genes (RIM1–RIM4). All isoforms contain a C-terminal C₂ domain but differ in the presence of additional domains. RIM1 and RIM2 interact with Ca²⁺ channels, most other proteins of the cytomatrix of the AZ, and synaptic vesicle proteins. They interact directly with the auxiliary β (Ca_Vβ) subunits (12, 13) and pore-forming Ca_Vα subunits (14, 15). In addition, RIMs are indirectly linked to Ca²⁺ channels via RIM-binding protein (14, 16, 17). A regulation of biophysical channel properties has been demonstrated in heterologous expression systems for RIM1 (12) and RIM2 (13).A role of RIM1 and RIM2 in clustering Ca²⁺ channels at the AZ was demonstrated by analysis of RIM1/2-deficient presynaptic terminals of cultured hippocampal neurons (14), auditory neurons in slices (18), and Drosophila neuromuscular junction (19). Because α-RIMs also bind the vesicle-associated protein Ras-related in brain 3 (Rab3) via the N-terminal zinc finger domain (20), they are also good candidates for molecular coupling of Ca²⁺ channels and vesicles (18, 21, 22). Finally, a role of RIMs in priming of vesicles for fusion is the subject of intense research (18, 21–27). RIMs likely contribute to priming via disinhibiting Munc13 (26) and regulating vesicle tethering (27). Here, we studied the expression and function of RIM in IHCs. We combined molecular, morphologic, and physiologic approaches for the analysis of RIM2α knockout mice [RIM2α SKO (28); see Methods] and of hair cell-specific RIM1/2 knockout mice (RIM1/2 cDKO). We demonstrate that RIM2α and RIM2β are present at IHC AZs of hearing mice, positively regulate the number of synaptic Ca_V1.3 Ca²⁺ channels, and are required for normal hearing.     

Conformational cycle and ion-coupling mechanism of the Na+/hydantoin transporter Mhp1

Ion-dependent transporters of the LeuT-fold couple the uptake of physiologically essential molecules to transmembrane ion gradients. Defined by a conserved 5-helix inverted repeat that encodes common principles of ion and substrate binding, the LeuT-fold has been captured in outward-facing, occluded, and inward-facing conformations. However, fundamental questions relating to the structural basis of alternating access and coupling to ion gradients remain unanswered. Here, we used distance measurements between pairs of spin labels to define the conformational cycle of the Na⁺-coupled hydantoin symporter Mhp1 from Microbacterium liquefaciens. Our results reveal that the inward-facing and outward-facing Mhp1 crystal structures represent sampled intermediate states in solution. Here, we provide a mechanistic context for these structures, mapping them into a model of transport based on ion- and substrate-dependent conformational equilibria. In contrast to the Na⁺/leucine transporter LeuT, our results suggest that Na⁺ binding at the conserved second Na⁺ binding site does not change the energetics of the inward- and outward-facing conformations of Mhp1. Comparative analysis of ligand-dependent alternating access in LeuT and Mhp1 lead us to propose that different coupling schemes to ion gradients may define distinct conformational mechanisms within the LeuT-fold class.Secondary active transporters harness the energy of ion gradients to power the uphill movement of solutes across membranes. Mitchell (1) and others (2, 3) proposed and elaborated “alternating access” mechanisms wherein the transporter transitions between two conformational states that alternately expose the substrate binding site to the two sides of the membrane. The LeuT class of ion-coupled symporters consists of functionally distinct transporters that share a conserved scaffold of two sets of five transmembrane helices related by twofold symmetry around an axis nearly parallel to the membrane (4). Ions and substrates are bound near the middle of the membrane stabilized by electrostatic interactions with unwound regions of transmembrane helix (TM) 1 and often TM6 (4). The recurrence of this fold in transporters that play critical roles in fundamental physiological processes (5, 6) has spurred intense interest in defining the principles of alternating access.Despite rapid progress in structure determination of ion-coupled LeuT-fold transporters (7–11), extrapolation of these static snapshots to a set of conformational steps underlying alternating access (4, 7, 9–12) remains incomplete, often hindered by uncertainties in the mechanistic identities of crystal structures. Typically, transporter crystal structures are classified as inward-facing, outward-facing, or occluded on the basis of the accessibility of the substrate binding site (7–11). In a recent spectroscopic analysis of LeuT, we demonstrated that detergent selection and mutations of conserved residues appeared to stabilize conformations that were not detected in the wild-type (WT) LeuT and concurrently inhibited movement of structural elements involved in ligand-dependent alternating access (13). Therefore, although crystal structures define the structural context and identify plausible pathways of substrate binding and release, development of transport models requires confirming or assigning the mechanistic identity of these structures and framing them into ligand-dependent equilibria (14).Mhp1, an Na⁺-coupled symporter of benzyl-hydantoin (BH) from Microbacterium liquefaciens, was the first LeuT-fold member to be characterized by crystal structures purported to represent outward-facing, inward-facing, and outward-facing/occluded conformations of an alternating access cycle (8, 15). In these structures, solvent access to ligand-binding sites is defined by the relative orientation between a 4-helix bundle motif and a 4-helix scaffold motif (8). In Mhp1, alternating access between inward- and outward-facing conformations, was predicted from a computational analysis based on the inverted repeat symmetry of the LeuT fold and is referred to as the rocking-bundle model (16). The conservation of the inverted symmetry prompted proposal of the rocking-bundle mechanism as a general model for LeuT-fold transporters (16). Subsequent crystal structures of other LeuT-fold transporters (7, 9, 10) tempered this prediction because the diversity of the structural rearrangements implicit in these structures is seemingly inconsistent with a conserved conformational cycle.Another outstanding question pertains to the ion-coupling mechanism and the driving force of conformational changes. The implied ion-to-substrate stoichiometry varies across LeuT-fold ion-coupled transporters. For instance, LeuT (17) and BetP (18) require two Na⁺ ions that bind at two distinct sites referred to as Na1 and Na2 whereas Mhp1 (15) and vSGLT (19) appear to possess only the conserved Na2 site. Molecular dynamics (MD) simulations (20, 21) and electron paramagnetic resonance (EPR) analysis (13, 22) of LeuT demonstrated that Na⁺ binding favors an outward-facing conformation although it is unclear which Na⁺ site (or both) is responsible for triggering this conformational transition. Similarly, a role for Na⁺ in conformational switching has been uncovered in putative human LeuT-fold transporters, including hSGLT (23). In Mhp1, the sole Na2 site has been shown to modulate substrate affinity (15); however, its proposed involvement in gating of the intracellular side (12, 21) lacks experimental validation.Here, we used site-directed spin labeling (SDSL) (24) and double electron-electron resonance (DEER) spectroscopy (25) to elucidate the conformational changes underlying alternating access in Mhp1 and define the role of ion and substrate binding in driving transition between conformations. This methodology has been successfully applied to define coupled conformational cycles for a number of transporter classes (13, 26–32). We find that patterns of distance distributions between pairs of spin labels monitoring the intra- and extracellular sides of Mhp1 are consistent with isomerization between the crystallographic inward- and outward-facing conformations. A major finding is that this transition is driven by substrate but not Na⁺ binding. Although the amplitudes of the observed distance changes are in overall agreement with the rocking-bundle model deduced from the crystal structures of Mhp1 (8, 15) and predicted computationally (16), we present evidence that relative movement of bundle and scaffold deviate from strict rigid body. Comparative analysis of LeuT and Mhp1 alternating access reveal how the conserved LeuT fold harnesses the energy of the Na⁺ gradient through two distinct coupling mechanisms and supports divergent conformational cycles to effect substrate binding and release.     

Cyclic nucleotide-gated channel 18 is an essential Ca2+ channel in pollen tube tips for pollen tube guidance to ovules in Arabidopsis

In flowering plants, pollen tubes are guided into ovules by multiple attractants from female gametophytes to release paired sperm cells for double fertilization. It has been well-established that Ca²⁺ gradients in the pollen tube tips are essential for pollen tube guidance and that plasma membrane Ca²⁺ channels in pollen tube tips are core components that regulate Ca²⁺ gradients by mediating and regulating external Ca²⁺ influx. Therefore, Ca²⁺ channels are the core components for pollen tube guidance. However, there is still no genetic evidence for the identification of the putative Ca²⁺ channels essential for pollen tube guidance. Here, we report that the point mutations R491Q or R578K in cyclic nucleotide-gated channel 18 (CNGC18) resulted in abnormal Ca²⁺ gradients and strong pollen tube guidance defects by impairing the activation of CNGC18 in Arabidopsis. The pollen tube guidance defects of cngc18-17 (R491Q) and of the transfer DNA (T-DNA) insertion mutant cngc18-1 (+/−) were completely rescued by CNGC18. Furthermore, domain-swapping experiments showed that CNGC18’s transmembrane domains are indispensable for pollen tube guidance. Additionally, we found that, among eight Ca²⁺ channels (including six CNGCs and two glutamate receptor-like channels), CNGC18 was the only one essential for pollen tube guidance. Thus, CNGC18 is the long-sought essential Ca²⁺ channel for pollen tube guidance in Arabidopsis.Pollen tubes deliver paired sperm cells into ovules for double fertilization, and signaling communication between pollen tubes and female reproductive tissues is required to ensure the delivery of sperm cells into the ovules (1). Pollen tube guidance is governed by both female sporophytic and gametophytic tissues (2, 3) and can be separated into two categories: preovular guidance and ovular guidance (1). For preovular guidance, diverse signaling molecules from female sporophytic tissues have been identified, including the transmitting tissue-specific (TTS) glycoprotein in tobacco (4), γ-amino butyric acid (GABA) in Arabidopsis (5), and chemocyanin and the lipid transfer protein SCA in Lilium longiflorum (6, 7). For ovular pollen tube guidance, female gametophytes secrete small peptides as attractants, including LUREs in Torenia fournieri (8) and Arabidopsis (9) and ZmEA1 in maize (10, 11). Synergid cells, central cells, egg cells, and egg apparatus are all involved in pollen tube guidance, probably by secreting different attractants (9–15). Additionally, nitric oxide (NO) and phytosulfokine peptides have also been implicated in both preovular and ovular pollen tube guidance (16–18). Thus, pollen tubes could be guided by diverse attractants in a single plant species.Ca²⁺ gradients at pollen tube tips are essential for both tip growth and pollen tube guidance (19–27). Spatial modification of the Ca²⁺ gradients leads to the reorientation of pollen tube growth in vitro (28, 29). The Ca²⁺ gradients were significantly increased in pollen tubes attracted to the micropyles by synergid cells in vivo, compared with those not attracted by ovules (30). Therefore, the Ca²⁺ gradients in pollen tube tips are essential for pollen tube guidance. The Ca²⁺ gradients result from external Ca²⁺ influx, which is mainly mediated by plasma membrane Ca²⁺ channels in pollen tube tips. Thus, the Ca²⁺ channels are the key components for regulating the Ca²⁺ gradients and are consequently essential for pollen tube guidance. Using electrophysiological techniques, inward Ca²⁺ currents were observed in both pollen grain and pollen tube protoplasts (31–36), supporting the presence of plasma membrane Ca²⁺ channels in pollen tube tips. Recently, a number of candidate Ca²⁺ channels were identified in pollen tubes, including six cyclic nucleotide-gated channels (CNGCs) and two glutamate receptor-like channels (GLRs) in Arabidopsis (37–40). Three of these eight channels, namely CNGC18, GLR1.2, and GLR3.7, were characterized as Ca²⁺-permeable channels (40, 41) whereas the ion selectivity of the other five CNGCs has not been characterized. We hypothesized that the Ca²⁺ channel essential for pollen tube guidance could be among these eight channels.In this research, we first characterized the remaining five CNGCs as Ca²⁺ channels. We further found that CNGC18, out of the eight Ca²⁺ channels, was the only one essential for pollen tube guidance in Arabidopsis and that its transmembrane domains were indispensable for pollen tube guidance.     

Rapid stimulus-evoked astrocyte Ca2+ elevations and hemodynamic responses in mouse somatosensory cortex in vivo

Increased neuron and astrocyte activity triggers increased brain blood flow, but controversy exists over whether stimulation-induced changes in astrocyte activity are rapid and widespread enough to contribute to brain blood flow control. Here, we provide evidence for stimulus-evoked Ca²⁺ elevations with rapid onset and short duration in a large proportion of cortical astrocytes in the adult mouse somatosensory cortex. Our improved detection of the fast Ca²⁺ signals is due to a signal-enhancing analysis of the Ca²⁺ activity. The rapid stimulation-evoked Ca²⁺ increases identified in astrocyte somas, processes, and end-feet preceded local vasodilatation. Fast Ca²⁺ responses in both neurons and astrocytes correlated with synaptic activity, but only the astrocytic responses correlated with the hemodynamic shifts. These data establish that a large proportion of cortical astrocytes have brief Ca²⁺ responses with a rapid onset in vivo, fast enough to initiate hemodynamic responses or influence synaptic activity.Brain function emerges from signaling in and between neurons and associated astrocytes, which causes fluctuations in cerebral blood flow (CBF) (1–5). Astrocytes are ideally situated for controlling activity-dependent increases in CBF because they closely associate with synapses and contact blood vessels with their end-feet (1, 6). Whether or not astrocytic Ca²⁺ responses develop often or rapidly enough to account for vascular signals in vivo is still controversial (7–10). Ca²⁺ responses are of interest because intracellular Ca²⁺ is a key messenger in astrocytic communication and because enzymes that synthesize the vasoactive substances responsible for neurovascular coupling are Ca²⁺-dependent (1, 4). Neuronal activity releases glutamate at synapses and activates metabotropic glutamate receptors on astrocytes, and this activation can be monitored by imaging cytosolic Ca²⁺ changes (11). Astrocytic Ca²⁺ responses are often reported to evolve on a slow (seconds) time scale, which is too slow to account for activity-dependent increases in CBF (8, 10, 12, 13). Furthermore, uncaging of Ca²⁺ in astrocytes triggers vascular responses in brain slices through specific Ca²⁺-dependent pathways with a protracted time course (14, 15). More recently, stimulation of single presynaptic neurons in hippocampal slices was shown to evoke fast, brief, local Ca²⁺ elevations in astrocytic processes that were essential for local synaptic functioning in the adult brain (16, 17). This work prompted us to reexamine the characteristics of fast, brief astrocytic Ca²⁺ signals in vivo with special regard to neurovascular coupling, i.e., the association between local increases in neural activity and the concomitant rise in local blood flow, which constitutes the physiological basis for functional neuroimaging.Here, we describe how a previously undescribed method of analysis enabled us to provide evidence for fast Ca²⁺ responses in a main fraction of astrocytes in mouse whisker barrel cortical layers II/III in response to somatosensory stimulation. The astrocytic Ca²⁺ responses were brief enough to be a direct consequence of synaptic excitation and correlated with stimulation-induced hemodynamic responses. Fast Ca²⁺ responses in astrocyte end-feet preceded the onset of dilatation in adjacent vessels by hundreds of milliseconds. This finding might suggest that communication at the gliovascular interface contributes considerably to neurovascular coupling.     

Mitigation of acute kidney injury by cell-cycle inhibitors that suppress both CDK4/6 and OCT2 functions

Acute kidney injury (AKI) is a potentially fatal syndrome characterized by a rapid decline in kidney function caused by ischemic or toxic injury to renal tubular cells. The widely used chemotherapy drug cisplatin accumulates preferentially in the renal tubular cells and is a frequent cause of drug-induced AKI. During the development of AKI the quiescent tubular cells reenter the cell cycle. Strategies that block cell-cycle progression ameliorate kidney injury, possibly by averting cell division in the presence of extensive DNA damage. However, the early signaling events that lead to cell-cycle activation during AKI are not known. In the current study, using mouse models of cisplatin nephrotoxicity, we show that the G1/S-regulating cyclin-dependent kinase 4/6 (CDK4/6) pathway is activated in parallel with renal cell-cycle entry but before the development of AKI. Targeted inhibition of CDK4/6 pathway by small-molecule inhibitors palbociclib (PD-0332991) and ribociclib (LEE011) resulted in inhibition of cell-cycle progression, amelioration of kidney injury, and improved overall survival. Of additional significance, these compounds were found to be potent inhibitors of organic cation transporter 2 (OCT2), which contributes to the cellular accumulation of cisplatin and subsequent kidney injury. The unique cell-cycle and OCT2-targeting activities of palbociclib and LEE011, combined with their potential for clinical translation, support their further exploration as therapeutic candidates for prevention of AKI.Cell division is a fundamental biological process that is tightly regulated by evolutionarily conserved signaling pathways (1, 2). The initial decision to start cell division, the fidelity of subsequent DNA replication, and the final formation of daughter cells is monitored and regulated by these essential pathways (2–6). The cyclin-dependent kinases (CDKs) are the central players that orchestrate this orderly progression through the cell cycle (1, 2, 6, 7). The enzymatic activity of CDKs is regulated by complex mechanisms that include posttranslational modifications and expression of activating and inhibitory proteins (1, 2, 6, 7). The spatial and temporal changes in the activity of these CDK complexes are thought to generate the distinct substrate specificities that lead to sequential and unidirectional progression of the cell cycle (1, 8, 9).Cell-cycle deregulation is a universal feature of human cancer and a long-sought-after target for anticancer therapy (1, 10–13). Frequent genetic or epigenetic changes in mitogenic pathways, CDKs, cyclins, or CDK inhibitors are observed in various human cancers (1, 4, 11). In particular, the G1/S-regulating CDK4/6–cyclin D–inhibitors of CDK4 (INK4)–retinoblastoma (Rb) protein pathway frequently is disrupted in cancer cells (11, 14). These observations provided an impetus to develop CDK inhibitors as anticancer drugs. However, the earlier class of CDK inhibitors had limited specificity, inadequate clinical activity, poor pharmacokinetic properties, and unacceptable toxicity profiles (10, 11, 14, 15). These disappointing initial efforts now have been followed by the development of the specific CDK4/6 inhibitors palbociclib (PD0332991), ribociclib (LEE011), and abemaciclib (LY2835219), which have demonstrated manageable toxicities, improved pharmacokinetic properties, and impressive antitumor activity, especially in certain forms of breast cancer (14, 16). Successful early clinical trials with these three CDK4/6 inhibitors have generated cautious enthusiasm that these drugs may emerge as a new class of anticancer agents (14, 17). Palbociclib recently was approved by Food and Drug Administration for the treatment of metastatic breast cancer and became the first CDK4/6 inhibitor approved for anticancer therapy (18).In addition to its potential as an anticancer strategy, CDK4/6 inhibition in normal tissues could be exploited therapeutically for wide-ranging clinical conditions. For example, radiation-induced myelosuppression, caused by cell death of proliferating hematopoietic stem/progenitor cells, can be rescued by palbociclib (19, 20). Furthermore, cytotoxic anticancer agents cause significant toxicities to normal proliferating cells, which possibly could be mitigated by the concomitant use of CDK4/6 inhibitors (20, 21). More broadly, cell-cycle inhibition could have beneficial effects in disorders in which maladaptive proliferation of normal cells contributes to the disease pathology, as observed in vascular proliferative diseases, hyperproliferative skin diseases, and autoimmune disorders (22, 23). In support of this possibility, palbociclib treatment recently was reported to ameliorate disease progression in animal models of rheumatoid arthritis through cell-cycle inhibition of synovial fibroblasts (24).Abnormal cellular proliferation also is a hallmark of various kidney diseases (25), and cell-cycle inhibition has been shown to ameliorate significantly the pathogenesis of polycystic kidney disease (26), nephritis (27), and acute kidney injury (AKI) (28). Remarkably, during AKI, the normally quiescent renal tubular cells reenter the cell cycle (29–34), and blocking cell-cycle progression can reduce renal injury (28). Here, we provide evidence that the CDK4/6 pathway is activated early during AKI and demonstrate significant protective effects of CDK4/6 inhibitors in animal models of cisplatin-induced AKI. In addition, we found that the CDK4/6 inhibitors palbociclib and LEE011 are potent inhibitors of organic cation transporter 2 (OCT2), a cisplatin uptake transporter highly expressed in renal tubular cells (35–37). Our findings provide a rationale for the clinical development of palbociclib and LEE011 for the prevention and treatment of AKI.     

Elastic mucus strands impair mucociliary clearance in cystic fibrosis pigs

Defective mucociliary transport contributes to infections and inflammation that destroy cystic fibrosis (CF) lungs. To better understand mechanisms that impair mucociliary transport, we tracked insufflated microdisks with X-ray computed tomography in spontaneously breathing CF pigs. Aerosolized saline increased microdisk movement toward the larynx. Surprisingly, forward progression was repeatedly interrupted as microdisks abruptly recoiled. Thus, although saline increased motion, it had minimal effects on microdisk clearance. To test if abnormally elastic mucus strands were responsible, we aerosolized Tris-carboxyethyl phosphine (TCEP), a reducing agent that breaks disulfide bonds linking mucins. TCEP largely eliminated retrograde movement and increased microdisk clearance. Ex vivo studies confirmed that TCEP broke CF mucus strands, unleashing them from submucosal gland ducts, and cilia carried them rostrally. These findings emphasize the role of abnormally elastic submucosal gland mucus strands in impairing CF mucociliary clearance and suggest that disrupting mucus strands may improve mucociliary clearance in CF.

Mucociliary transport (MCT) is an innate defense mechanism that protects lungs from inhaled and aspirated material (1–3). MCT depends on mucus, which traps particulates and pathogens, and motile cilia, which protrude from epithelia lining the airways and by their beating propel mucus up the airways and out of the lung. In the cartilaginous airways of humans, pigs, and likely other large mammals, submucosal glands (SMGs) are required for normal MCT (4, 5). SMGs expand the number of fluid- and mucus-producing cells beyond that in surface epithelia and secrete much of the airway mucus (5–7). The major structural component of mucus is mucins, and SMGs produce the mucin MUC5B, which is key for MCT (8–10). SMGs secrete mucus under basal conditions, and when the respiratory tract is challenged, they respond to neurohumoral signals by secreting copious amounts of mucus (5, 11–13).Mucus emerges from SMG ducts onto the airway surface in the form of mucus strands (10, 14–18). Beating cilia pull the mucus strands; they stretch, eventually break, and are then swept upward toward the larynx (14–16). Elasticity dominates the biophysical properties of the mucus (19, 20). Reducing agents break the disulfide bonds that link mucins and thereby disrupt the integrity of mucus strands (14, 21–24). As a result, when reducing agents were applied to the airway surface liquid (ASL), the mucus emerging from SMG ducts immediately fragmented, failed to generate strands, and thereby prevented normal MCT (14). Thus, mucus strands secreted from SMGs make key contributions to MCT. Consistent with this conclusion, when pigs lack the SMGs that produce mucus strands, MCT is disrupted (4).MCT is defective in cystic fibrosis (CF), a life-threatening genetic disease caused by mutations in the gene encoding the cystic fibrosis transmembrane conductance regulator (CFTR) anion channel (2, 25, 26). MCT is impaired, in part, by the altered biophysical properties of the mucus produced by CF SMGs (10, 15, 16, 20). Defective SMG mucus is apparent even before birth; histopathologic examination of lungs from human fetuses with CF revealed abnormal lamellated Periodic acid-Schiff positive material obstructing the lumen and ducts of airway SMGs (27, 28). Similar changes were observed in deceased infants with CF, although inflammation and infection occurring after birth may have contributed (17, 28–30). Studies in CF pigs and sheep immediately after birth also reveal mucus accumulation in SMG ducts and acini (10, 15, 16, 31). Mucus accumulation in SMGs also appears in CF ferrets and rats once they develop SMG glands postnatally (32, 33) and in older CF rabbits in Bowman glands of the olfactory epithelium (34). The abnormal mucus and impaired MCT contribute to the recurrent airway infections and inflammation in CF.Unlike mucus strands secreted from wild-type SMGs, mucus strands from CF SMGs often fail to break after emerging from their ducts. As a result, they accumulate and prevent particles from moving up the airways (10, 14–16). Defective HCO₃⁻ and Cl⁻ secretion in SMGs are responsible for the abnormal mucus strands (10, 15); without CFTR function, SMG liquid becomes abnormally acidic, and the protein concentration increases (20, 35). These abnormalities produce mucus with increased elasticity and tensile strength and reduced breakage when mucus strands are stretched (15, 20). In freshly excised non-CF airways, removing HCO₃⁻ and inhibiting Cl⁻ secretion with bumetanide reproduces CF-like conditions so that mucus strands emerging from SMGs often fail to break loose from the ducts and accumulate on the airway surface, preventing normal MCT (10, 15).The reducing reagent Tris-carboxyethyl phosphine (TCEP) breaks mucus strands (14, 21, 22). Because abnormal mucus strands impair MCT in CF, we asked if aerosolized TCEP would enhance MCT in CF pigs. The answer was of interest because TCEP has the opposite effect in non-CF pigs, decreasing MCT (14). We also wished to know the answer because reducing agents are being investigated as a potential therapy for CF (23, 24). However, before directly addressing this question, we needed to assess the effect of aerosolized saline, which is used to deliver the TCEP. We were encouraged to do that because in a previous in vivo study, we found that aerosolizing 0.5 mL of saline to non-CF pigs increased MCT (14). In other studies, isotonic physiologic salt solutions reversed the impairment in MCT induced by blocking Cl⁻ and HCO₃⁻ secretion in porcine tracheas (36), and in humans, inhalation of isotonic saline increased mucociliary clearance in normal and asthmatic lungs (37).Here, we took advantage of a model of CF in pigs, which like humans have abundant SMGs and replicate CF abnormalities. We also used a computed tomography (CT) imaging method with high spatial and temporal resolution that reveals the trajectories of individual microdisks as they are carried by mucus strands within intrapulmonary airways.