Excitation-contraction coupling in airway smooth muscle

Excitation-contraction (EC) coupling in striated muscles is mediated by the cardiac or skeletal muscle isoform of voltage-dependent L-type Ca(2+) channel (Ca(v)1.2 and Ca(v)1.1, respectively) that senses a depolarization of the cell membrane, and in response, activates its corresponding isoform of intracellular Ca(2+) release channel/ryanodine receptor (RyR) to release stored Ca(2+), thereby initiating muscle contraction. Specifically, in cardiac muscle following cell membrane depolarization, Ca(v)1.2 activates cardiac RyR (RyR2) through an influx of extracellular Ca(2+). In contrast, in skeletal muscle, Ca(v)1.1 activates skeletal muscle RyR (RyR1) through a direct physical coupling that negates the need for extracellular Ca(2+). Since airway smooth muscle (ASM) expresses Ca(v)1.2 and all three RyR isoforms, we examined whether a cardiac muscle type of EC coupling also mediates contraction in this tissue. We found that the sustained contractions of rat ASM preparations induced by depolarization with KCl were indeed partially reversed ( approximately 40%) by 200 mum ryanodine, thus indicating a functional coupling of L-type channels and RyRs in ASM. However, KCl still caused transient ASM contractions and stored Ca(2+) release in cultured ASM cells without extracellular Ca(2+). Further analyses of rat ASM indicated that this tissue expresses as many as four L-type channel isoforms, including Ca(v)1.1. Moreover, Ca(v)1.1 and RyR1 in rat ASM cells have a similar distribution near the cell membrane in rat ASM cells and thus may be directly coupled as in skeletal muscle. Collectively, our data implicate that EC-coupling mechanisms in striated muscles may also broadly transduce diverse smooth muscle functions.     

Functional properties of a newly identified C-terminal splice variant of Cav1.3 L-type Ca2+ channels

An intramolecular interaction between a distal (DCRD) and a proximal regulatory domain (PCRD) within the C terminus of long Ca(v)1.3 L-type Ca(2+) channels (Ca(v)1.3(L)) is a major determinant of their voltage- and Ca(2+)-dependent gating kinetics. Removal of these regulatory domains by alternative splicing generates Ca(v)1.3(42A) channels that activate at a more negative voltage range and exhibit more pronounced Ca(2+)-dependent inactivation. Here we describe the discovery of a novel short splice variant (Ca(v)1.3(43S)) that is expressed at high levels in the brain but not in the heart. It lacks the DCRD but, in contrast to Ca(v)1.3(42A), still contains PCRD. When expressed together with α2δ1 and β3 subunits in tsA-201 cells, Ca(v)1.3(43S) also activated at more negative voltages like Ca(v)1.3(42A) but Ca(2+)-dependent inactivation was less pronounced. Single channel recordings revealed much higher channel open probabilities for both short splice variants as compared with Ca(v)1.3(L). The presence of the proximal C terminus in Ca(v)1.3(43S) channels preserved their modulation by distal C terminus-containing Ca(v)1.3- and Ca(v)1.2-derived C-terminal peptides. Removal of the C-terminal modulation by alternative splicing also induced a faster decay of Ca(2+) influx during electrical activities mimicking trains of neuronal action potentials. Our findings extend the spectrum of functionally diverse Ca(v)1.3 L-type channels produced by tissue-specific alternative splicing. This diversity may help to fine tune Ca(2+) channel signaling and, in the case of short variants lacking a functional C-terminal modulation, prevent excessive Ca(2+) accumulation during burst firing in neurons. This may be especially important in neurons that are affected by Ca(2+)-induced neurodegenerative processes.     

Coassembly of big conductance Ca2+-activated K+ channels and L-type voltage-gated Ca2+ channels in rat brain

Based on electrophysiological studies, Ca(2+)-activated K(+) channels and voltage-gated Ca(2+) channels appear to be located in close proximity in neurons. Such colocalization would ensure selective and rapid activation of K(+) channels by local increases in the cytosolic calcium concentration. The nature of the apparent coupling is not known. In the present study we report a direct coassembly of big conductance Ca(2+)-activated K(+) channels (BK) and L-type voltage-gated Ca(2+) channels in rat brain. Saturation immunoprecipitation studies were performed on membranes labeled for BK channels and precipitated with antibodies against alpha(1C) and alpha(1D) L-type Ca(2+) channels. To confirm the specificity of the interaction, precipitation experiments were carried out also in reverse order. Also, additive precipitation was performed because alpha(1C) and alpha(1D) L-type Ca(2+) channels always refer to separate ion channel complexes. Finally, immunochemical studies showed a distinct but overlapping expression pattern of the two types of ion channels investigated. BK and L-type Ca(2+) channels were colocalized in various compartments throughout the rat brain. Taken together, these results demonstrate a direct coassembly of BK channels and L-type Ca(2+) channels in certain areas of the brain.     

Homer proteins in Ca2+ signaling by excitable and non-excitable cells

Homers are scaffolding proteins that bind Ca(2+) signaling proteins in cellular microdomains. The Homers participate in targeting and localization of Ca(2+) signaling proteins in signaling complexes. However, recent work showed that the Homers are not passive scaffolding proteins, but rather they regulate the activity of several proteins within the Ca(2+) signaling complex in an isoform-specific manner. Homer2 increases the GAP activity of RGS proteins and PLCbeta that accelerate the GTPase activity of Galpha subunits. Homer1 gates the activity of TRPC channels, controls the rates of their translocation and retrieval from the plasma membrane and mediates the conformational coupling between TRPC channels and IP(3)Rs. Homer1 stimulates the activity of the cardiac and neuronal L-type Ca(2+) channels Ca(v)1.2 and Ca(v)1.3. Homer1 also mediates the communication between the cardiac and smooth muscle ryanodine receptor RyR2 and Ca(v)1.2 to regulate E-C coupling. In many cases the Homers function as a buffer to reduce the intensity of Ca(2+) signaling and create a negative bias that can be reversed by the immediate early gene form of Homer1. Hence, the Homers should be viewed as the buffers of Ca(2+) signaling that ensure a high spatial and temporal fidelity of the Ca(2+) signaling and activation of downstream effects.     

Intracellular Ca2+ regulation in rat motoneurons during development

Changes in intracellular Ca(2+) concentration ([Ca(2+)](i)) control the setting up of the neuro-muscular synapse in vitro and probably in vivo. Dissociated cultures of purified embryonic (E15) rat motoneurons were used to explore the molecular mechanisms by which endoplasmic reticulum Ca(2+) stores, via both ryanodine-sensitive and IP(3)-sensitive intracellular Ca(2+) channels control [Ca(2+)](i) homeostasis in these neurons during ontogenesis. Fura-2 microspectrofluorimetry monitorings in single neurons showed that caffeine-induced responses of [Ca(2+)](i) increased progressively from days 1-7 in culture. These responses were blocked by ryanodine and nicardipine but not by omega-conotoxin-GVIA or omega-conotoxin-MVIIC suggesting a close functional relationship between ryanodine-sensitive and L-type Ca(v)1 Ca(2+) channels. Moreover, after 6 days in vitro, neurons exhibited spontaneous or caffeine-induced Ca(2+) oscillations that were attenuated by nicardipine. In 1-day-old neurons, both thapsigargin or CPA, which deplete Ca(2+) stores from the endoplasmic reticulum, induced an increase in [Ca(2+)](i) in 75% of the neurons tested. The number of responding motoneurons declined to 25% at 5-6 days in vitro. Xestospongin-C, a membrane-permeable IP(3) receptor inhibitor blocked the CPA-induced [Ca(2+)](i) response in all stages. RT-PCR studies investigating the expression pattern of RYR and IP(3) Ca(2+) channels isoforms confirmed the presence of their different isoforms and provided evidence for a specific pattern of development for RYR channels during the first week in vitro. Taken together, present results show that the control of motoneuronal [Ca(2+)](i) homeostasis is developmentally regulated and suggest the presence of an intracellular ryanodine-sensitive Ca(2+) channel responsible for a Ca(2+)-induced Ca(2+) release in embryonic motoneurons following voltage-dependent Ca(2+) entry via L-type Ca(2+) channels.     

Alternans of cardiac calcium cycling in a cluster of ryanodine receptors: a simulation study

Mechanical alternans in cardiac muscle is associated with intracellular Ca(2+) alternans. Mechanisms underlying intracellular Ca(2+) alternans are unclear. In previous experimental studies, we produced alternans of systolic Ca(2+) under voltage clamp, either by partially inhibiting the Ca(2+) release mechanism, or by applying small depolarizing pulses. In each case, alternans relied on propagating waves of Ca(2+) release. The aim of this study is to investigate by computer modeling how alternans of systolic Ca(2+) is produced. A mathematical model of a cardiac cell with 75 coupled elements is developed, with each element contains L-type Ca(2+) current, a subspace into which Ca release takes place, a cytoplasmic space, sarcoplasmic reticulum (SR) release channels [ryanodine receptor (RyR)], and uptake sites (SERCA). Interelement coupling is via Ca(2+) diffusion between neighboring subspaces via cytoplasmic spaces and network SR spaces. Small depolarizing pulses were simulated by step changes of cell membrane potential (20 mV) with random block of L-type channels. Partial inhibition of the release mechanism is mimicked by applying a reduction of RyR open probability in response to full stimulation by L-type channels. In both cases, systolic alternans follow, consistent with our experimental observations, being generated by propagating waves of Ca(2+) release and sustained through alternation of SR Ca(2+) content. This study provides novel and fundamental insights to understand mechanisms that may underlie intracellular Ca(2+) alternans without the need for refractoriness of L-type Ca or RyR channels under rapid pacing.     

Ca2+ signaling in microdomains: Homer1 mediates the interaction between RyR2 and Cav1.2 to regulate excitation-contraction coupling

Excitation-contraction (E-C) coupling and Ca(2+)-induced Ca(2+) release in smooth and cardiac muscles is mediated by the L-type Ca(2+) channel isoform Ca(v)1.2 and the ryanodine receptor isoform RyR2. Although physical coupling between Ca(v)1.1 and RyR1 in skeletal muscle is well established, it is generally assumed that Ca(v)1.2 and RyR2 do not directly communicate either passively or dynamically during E-C coupling. In the present work, we re-examined this assumption by studying E-C coupling in the detrusor muscle of wild type and Homer1(-/-) mice and by demonstrating a Homer1-mediated dynamic interaction between Ca(v)1.2 and RyR2 using the split green fluorescent protein technique. Deletion of Homer1 in mice (but not of Homer2 or Homer3) resulted in impaired urinary bladder function, which was associated with higher sensitivity of the detrusor muscle to muscarinic stimulation and membrane depolarization. This was not due to an altered expression or function of RyR2 and Ca(v)1.2. Most notably, expression of Ca(v)1.2 and RyR2 tagged with the complementary C- and N-terminal halves of green fluorescent protein and in the presence and absence of Homer1 isoforms revealed that H1a and H1b/c reciprocally modulates a dynamic interaction between Ca(v)1.2 and RyR2 to regulate the intensity of Ca(2+)-induced Ca(2+) release and its dependence on membrane depolarization. These findings define the molecular basis of a "two-state" model of E-C coupling by Ca(v)1.2 and RyR2. In one state, Ca(v)1.2 couples to RyR2 by H1b/c, which results in reduced responsiveness to membrane depolarization and in the other state H1a uncouples Ca(v)1.2 and RyR2 to enhance responsiveness to membrane depolarization. These findings reveal an unexpected and novel mode of interaction and communication between Ca(v)1.2 and RyR2 with important implications for the regulation of smooth and possibly cardiac muscle E-C coupling.     

The involvement of voltage-operated calcium channels in somato-dendritic oxytocin release

Magnocellular neurons of the supraoptic nucleus (SON) secrete oxytocin and vasopressin from axon terminals in the neurohypophysis, but they also release large amounts of peptide from their somata and dendrites, and this can be regulated both by activity-dependent Ca(2+) influx and by mobilization of intracellular Ca(2+). This somato-dendritic release can also be primed by agents that mobilise intracellular Ca(2+), meaning that the extent to which it is activity-dependent, is physiologically labile. We investigated the role of different Ca(2+) channels in somato-dendritic release; blocking N-type channels reduced depolarisation-induced oxytocin release from SONs in vitro from adult and post-natal day 8 (PND-8) rats, blocking L-type only had effect in PND-8 rats, while blocking other channel types had no significant effect. When oxytocin release was primed by prior exposure to thapsigargin, both N- and L-type channel blockers reduced release, while P/Q and R-type blockers were ineffective. Using confocal microscopy, we found immunoreactivity for Ca(v)1.2 and 1.3 channel subunits (which both form L-type channels), 2.1 (P/Q type), 2.2 (N-type) and 2.3 (R-type) in the somata and dendrites of both oxytocin and vasopressin neurons, and the intensity of the immunofluorescence signal for different subunits differed between PND-8, adult and lactating rats. Using patch-clamp electrophysiology, the N-type Ca(2+) current density increased after thapsigargin treatment, but did not alter the voltage sensitivity of the channel. These results suggest that the expression, location or availability of N-type Ca(2+) channels is altered when required for high rates of somato-dendritic peptide release.     

Depolarization-induced Ca2+ release in ischemic spinal cord white matter involves L-type Ca2+ channel activation of ryanodine receptors

The mechanisms of Ca(2+) release from intracellular stores in CNS white matter remain undefined. In rat dorsal columns, electrophysiological recordings showed that in vitro ischemia caused severe injury, which persisted after removal of extracellular Ca(2+); Ca(2+) imaging confirmed that an axoplasmic Ca(2+) rise persisted in Ca(2+)-free perfusate. However, depletion of Ca(2+) stores or reduction of ischemic depolarization (low Na(+), TTX) were protective, but only in Ca(2+)-free bath. Ryanodine or blockers of L-type Ca(2+) channel voltage sensors (nimodipine, diltiazem, but not Cd(2+)) were also protective in zero Ca(2+), but their effects were not additive with ryanodine. Immunoprecipitation revealed an association between L-type Ca(2+) channels and RyRs, and immunohistochemistry confirmed colocalization of Ca(2+) channels and RyR clusters on axons. Similar to "excitation-contraction coupling" in skeletal muscle, these results indicate a functional coupling whereby depolarization sensed by L-type Ca(2+) channels activates RyRs, thus releasing damaging amounts of Ca(2+) under pathological conditions in white matter.     

Nitric oxide inhibits depolarization-evoked glutamate release from rat cerebellar granule cells.

Nitric oxide (NO) modulates the release of various neurotransmitters, some of these are considered to be involved in neuronal plasticity that includes long-term depression in the cerebellum. To date, there have been no reports on the modulation of the exocytotic release of neurotransmitters in the cerebellar granule cells (CGCs) by NO. The aim of this study was to investigate the effects of NO on the exocytotic release of glutamate from rat CGCs. Treatment with NO-related reagents revealed that NO inhibited high-K(+)-evoked glutamate release. Clostridium botulinum type B neurotoxin (BoNT/B) attenuated the enhancement of glutamate release caused by NO synthase (NOS) inhibition; this indicates that NO acts on the high-K(+)-evoked exocytotic pathway. cGMP-related reagents did not affect the high-K(+)-evoked glutamate release. NO-related reagents did not affect Ca(2+) ionophore-induced glutamate release, suggesting that NO inhibits Ca(2+) entry through voltage-dependent Ca(2+) channels (VDCC). Monitoring of intracellular Ca(2+) revealed that NO inhibited high-K(+)-evoked Ca(2+) entry. L-type VDCC blockers inhibited glutamate release and NO did not have an additive effect on the inhibition produced by the L-type VDCC blocker. The inhibition of the high-K(+)-evoked glutamate release by NO was abolished by a reducing reagent; this suggested that NO regulates the high-K(+)-evoked glutamate release from CGCs by redox modulation.     

Generation of dendritic Ca2+ oscillations as a consequence of altered ryanodine receptor function in AD neurons

Ryanodine receptor (RyR)-mediated Ca(2+) dysregulation is associated with Alzheimer's disease (AD) neuropathology. Using 2-photon Ca(2+) imaging and patch clamp recordings in brain slice preparations from young 3xTg-AD and NonTg control mice, we recently demonstrated that RyR-mediated Ca(2+) -induced Ca(2+) release (CICR) is substantially increased within dendrites from AD neurons, such that synaptic stimulation alone is sufficient to generate aberrant CICR. We also observed supra-additive Ca(2+) release upon coincident RyR activation with synaptic stimulation in 3xTg-AD mice. Here, we describe an additional observed phenomenon: generation of patterned Ca(2+) oscillations in the spines and dendrites from AD neurons upon coincident RyR and synaptic stimulation. As the temporal entrainment of Ca(2+) signals influences many downstream cellular and synaptic functions, these abnormal oscillatory patterns may be associated with the structural and functional breakdown of synapses in AD.     

L-type calcium channels in adrenal chromaffin cells: role in pace-making and secretion

Voltage-gated L-type (Cav1.2 and Cav1.3) channels are widely expressed in cardiovascular tissues and represent the critical drug-target for the treatment of several cardiovascular diseases. The two isoforms are also abundantly expressed in neuronal and neuroendocrine tissues. In the brain, Cav1.2 and Cav1.3 channels control synaptic plasticity, somatic activity, neuronal differentiation and brain aging. In neuroendocrine cells, they are involved in the genesis of action potential generation, bursting activity and hormone secretion. Recent studies have shown that Cav1.2 and Cav1.3 are also expressed in chromaffin cells but their functional role has not yet been identified despite that L-type channels possess interesting characteristics, which confer them an important role in the control of catecholamine secretion during action potentials stimulation. In intact rat adrenal glands L-type channels are responsible for adrenaline and noradrenaline release following splanchnic nerve stimulation or nicotinic receptor activation. L-type channels can be either up- or down-modulated by membrane autoreceptors following distinct second messenger pathways. L-type channels are tightly coupled to BK channels and activate at relatively low-voltages. In this way they contribute to the action potential hyperpolarization and to the pace-maker current controlling action potential firings. L-type channels are shown also to regulate the fast secretion of the immediate readily releasable pool of vesicles with the same Ca(2+)-efficiency of other voltage-gated Ca(2+) channels. In mouse adrenal slices, repeated action potential-like stimulations drive L-type channels to a state of enhanced stimulus-secretion efficiency regulated by beta-adrenergic receptors. Here we will review all these novel findings and discuss the possible implication for a specific role of L-type channels in the control of chromaffin cells activity.     

Caffeine-induced Ca(2+) sparks in mouse ventricular myocytes

Ca(2+) sparks are spatially localized intracellular Ca(2+) release events that were first described in 1993. Sparks have been ascribed to sarcoplasmic reticulum Ca(2+) release channel (ryanodine receptor, RyR) opening induced by Ca(2+) influx via L-type Ca(2+) channels or by spontaneous RyR openings and have been thought to reflect Ca(2+) release from a cluster of RyR. Here we describe a pharmacological approach to study sparks by exposing ventricular myocytes to caffeine with a rapid solution-switcher device. Sparks under these conditions have properties similar to naturally occurring sparks in terms of size and intracellular Ca(2+) concentration ([Ca(2+)](i)) amplitude. However, after the diffusion of caffeine, sparks first appear close to the cell surface membrane before coalescing to produce a whole cell transient. Our results support the idea that a whole cell [Ca(2+)](i) transient consists of the summation of sparks and that Ca(2+) sparks consist of the opening of a cluster of RyR and confirm that characteristics of the cluster rather than the L-type Ca(2+) channel-RyR relation determine spark properties.     

Sex differences in expression of calcium-handling proteins and beta-adrenergic receptors in rat heart ventricle

Human studies reveal sex differences in myocardial function as well as in the incidence and manifestation of heart disease. Myocellular Ca(2+) cycling regulates normal contractile function; whereas cardiac dysfunction in heart failure has been associated with alterations in Ca(2+)-handling proteins. Beta-adrenergic receptor (beta-AR) signaling regulates activity of several Ca(2+)-handling proteins and alterations in beta-AR signaling are associated with heart disease. This study examines sex differences in expression of beta(1)-AR, beta(2)-AR, and Ca(2+)-handling proteins including: L-type calcium channel (Ca(v)1.2) , ryanodine calcium-release channels (RyR), sarcoplasmic reticular Ca(2+) ATPase (SERCA2), phospholamban (PLB) and Na(+)-Ca(2+) exchange protein (NCX) in healthy hearts from male and female Sprague-Dawley rats. Protein levels were examined using Western blot analysis. Abundance of mRNA was determined by real time RT-PCR normalized to abundance of GAPDH mRNA. Contraction parameters were measured in right ventricular papillary muscle in the presence and absence of isoproterenol. Results demonstrate that female ventricle has significantly higher levels of Ca(v)1.2, RyR, and NCX protein compared to males. Messenger RNA abundance for RyR, and NCX protein was significantly higher in females whereas Ca(v)1.2 mRNA was higher in males. No differences were detected in beta-ARs, SERCA2 or PLB. Female right papillary muscle had a faster maximal rate of force development and decline (+/- dF/dt). There were no sex differences in response to isoproterenol. Results show significant sex differences in expression of key ventricular Ca(2+)-handling proteins that are associated with small functional differences in +/- dF/dt. Further studies will determine whether differences in the abundance of these key proteins play a role in sex disparities in the incidence and manifestation of heart disease.     

Modulation of voltage- and Ca2+-dependent gating of CaV1.3 L-type calcium channels by alternative splicing of a C-terminal regulatory domain

Low voltage activation of Ca(V)1.3 L-type Ca(2+) channels controls excitability in sensory cells and central neurons as well as sinoatrial node pacemaking. Ca(V)1.3-mediated pacemaking determines neuronal vulnerability of dopaminergic striatal neurons affected in Parkinson disease. We have previously found that in Ca(V)1.4 L-type Ca(2+) channels, activation, voltage, and calcium-dependent inactivation are controlled by an intrinsic distal C-terminal modulator. Because alternative splicing in the Ca(V)1.3 alpha1 subunit C terminus gives rise to a long (Ca(V)1.3(42)) and a short form (Ca(V)1.3(42A)), we investigated if a C-terminal modulatory mechanism also controls Ca(V)1.3 gating. The biophysical properties of both splice variants were compared after heterologous expression together with beta3 and alpha2delta1 subunits in HEK-293 cells. Activation of calcium current through Ca(V)1.3(42A) channels was more pronounced at negative voltages, and inactivation was faster because of enhanced calcium-dependent inactivation. By investigating several Ca(V)1.3 channel truncations, we restricted the modulator activity to the last 116 amino acids of the C terminus. The resulting Ca(V)1.3(DeltaC116) channels showed gating properties similar to Ca(V)1.3(42A) that were reverted by co-expression of the corresponding C-terminal peptide C(116). Fluorescence resonance energy transfer experiments confirmed an intramolecular protein interaction in the C terminus of Ca(V)1.3 channels that also modulates calmodulin binding. These experiments revealed a novel mechanism of channel modulation enabling cells to tightly control Ca(V)1.3 channel activity by alternative splicing. The absence of the C-terminal modulator in short splice forms facilitates Ca(V)1.3 channel activation at lower voltages expected to favor Ca(V)1.3 activity at threshold voltages as required for modulation of neuronal firing behavior and sinoatrial node pacemaking.     

Defective Ca(2+) handling proteins regulation during heart failure

Abnormal release of Ca(2+) from sarcoplasmic reticulum (SR) via the cardiac ryanodine receptor (RyR2) may contribute to contractile dysfunction in heart failure (HF). We previously demonstrated that RyR2 macromolecular complexes from HF rat were significantly more depleted of FK506 binding protein (FKBP12.6). Here we assessed expression of key Ca(2+) handling proteins and measured SR Ca(2+) content in control and HF rat myocytes. Direct measurements of SR Ca(2+) content in permeabilized cardiac myocytes demonstrated that SR luminal [Ca(2+)] is markedly lowered in HF (HF: DeltaF/F(0) = 26.4+/-1.8, n=12; control: DeltaF/F(0) = 49.2+/-2.9, n=10; P<0.01). Furthermore, we demonstrated that the expression of RyR2 associated proteins (including calmodulin, sorcin, calsequestrin, protein phosphatase 1, protein phosphatase 2A), Ca(2+) ATPase (SERCA2a), PLB phosphorylation at Ser16 (PLB-S16), PLB phosphorylation at Thr17 (PLB-T17), L-type Ca(2+) channel (Cav1.2) and Na(+)- Ca(2+) exchanger (NCX) were significantly reduced in rat HF. Our results suggest that systolic SR reduced Ca(2+) release and diastolic SR Ca(2+) leak (due to defective protein-protein interaction between RyR2 and its associated proteins) along with reduced SR Ca(2+) uptake (due to down-regulation of SERCA2a, PLB-S16 and PLB-T17), abnormal Ca(2+) extrusion (due to down-regulation of NCX) and defective Ca(2+) -induced Ca(2+) release (due to down-regulation of Cav1.2) could contribute to HF.