Force relaxes before the fall of cytosolic calcium in the photomechanical response of rat sphincter pupillae

In the ratsphincter pupillae, as in other smooth muscles, the primary signaltransduction cascade for agonist activation is receptor  G protein phospholipase C  inositol trisphosphate  intracellularCa²⁺ concentration ([Ca²⁺]_i)  calmodulin  myosin light chain kinase  phosphorylated myosin  force development. Light stimulation of isolated sphincters pupillaecan be very precisely controlled, and precise reproducible photomechanical responses (PMRs) result. This precision makes the PMRideal for testing models of regulation of smooth muscle myosinphosphorylation. We measured force and[Ca²⁺]_i concurrently in sphincter pupillaefollowing stimulation by light flashes of varying duration andintensity. We sampled at unusually short (0.01-0.02 s) intervalsto adequately test a PMR model based on the myosin phosphorylationcascade. We found, surprisingly, contrary to the behavior of intestinalmuscle and predictions of the phosphorylation model, that during PMRsforce begins to decay while [Ca²⁺]_i is stillrising. We conclude that control of contraction in the sphincterpupillae probably involves an inhibitory process as well as activationby [Ca²⁺]_i.

     

Species differences in the effects of prostanoids on MAP kinase phosphorylation, myosin light chain phosphorylation and contraction in bovine and cat iris sphincter smooth muscle

There is evidence from our own laboratory and that of others that EP-receptor ligands are strong contractile agonists in bovine iris sphincter and that FP-receptor agonists are strong contractile agonists in cat iris sphincter. Here, we have investigated the effects of prostaglandin (PG) receptor agonists of the FP-, EP-, TP- and DP-class on myosin light chain (MLC) phosphorylation, p42/p44 MAP kinase phosphorylation and contraction in the iris sphincter of bovine and cat. Using three signal transduction mechanism assays, namely MLC phosphorylation, MAP kinase phosphorylation and contraction, we demonstrated that in bovine iris sphincter the rank order of potency of the PG agonists in the contractile and MLC phosphorylation assays is as follows: E2>U46619>F2alpha>D2, and in cat F2alpha>D2>E2>U46619. In the MAP kinase assay, in bovine iris sphincter the rank order of potency is E2>F2alpha and in cat F2alpha>E2. These conclusions are supported by the following findings: (1) In the contractile assay, in the bovine sphincter the EC50s for PGF2alpha, PGE2, U46619 and PGD2 were found to be 1.4x10(-7), 5.0x10(-9), 9.0x10(-9) and 1.3x10(-6)M, respectively, and the corresponding values in the cat were 1.9x10(-8), 2.3x10(-7), 1.5x10(-6) and 6.9x10(-8)M, respectively. (2) In the MLC phophorylation assay, in the bovine sphincter PGF2alpha, PGE2, U46619 and PGD2 increased MLC phophorylation by 118%, 165%, 153% and 72%, respectively, and the corresponding values in cat were 175%, 99%, 90% and 95%, respectively. (3) In the MAP kinase assay, in the bovine iris sphincter PGF2alpha and PGE2, increased MAP kinase phosphorylation by 276% and 328%, respectively, and the corresponding values in cat were 308% and 245%, respectively. The data presented demonstrate pronounced species differences in the effects of the prostanoids on the MLC kinase signaling pathway in bovine and cat irides and furthermore confirm the existence of FP-receptors in that of the bovine.     

Trigeminal nerve: the possible origin of substance p-nergic response in isolated rabbit iris sphincter muscle

We determined the effects of trigeminal nerve denervation on the noncholinergic, nonadrenergic response to electrical transmural stimulation of the isolated rabbit iris sphincter muscle. The left ophthalmic nerve (first branch of the trigeminal nerve) was cut at the intracranial, peripheral site of the trigeminal ganglion and five to ten days later, the iris sphincter muscle isolated from the left eye (operated side) was found to produce a fast cholinergic contraction in response to electrical transmural stimulation and there was no evidence of noncholinergic, nonadrenergic contractions. On the other hand, in the iris sphincter muscle isolated from the right eye (control side), electrical transmural stimulation produced both cholinergic and noncholinergic, nonadrenergic contractile responses. Capsaicin and bradykinin produced noncholinergic, nonadrenergic contractile responses in the muscle from the control side, while in the iris sphincter from the trigeminally denervated eye there was no such response to application of these drugs. Exogenous substance P (SP) and carbachol produced a strong contractile response in both the trigeminally innervated and denervated sphincter muscles. Somatostatin, vasoactive intestinal polypeptide (VIP) and enkephalin were without effects. These observations suggest that the noncholinergic, nonadrenergic responses to electrical transmural stimulation are derived from the trigeminal nerve and that the mediator involved is probably SP or a related peptide.     

Involvement of Ca2+ channels in endothelin-1-induced MAP kinase phosphorylation, myosin light chain phosphorylation and contraction in rabbit iris sphincter smooth muscle

The purpose of the present study was to investigate the role and type of Ca2+ channels involved in the stimulatory effects of endothelin-1 (ET-1) on the Ca2+-dependent functional responses, p42/p44 MAP kinase phosphorylation, 20-kDa myosin light chain (MLC) phosphorylation and contraction, in rabbit iris sphincter, a nonvascular smooth muscle. ET-1 induced inositol phosphates production, MAP kinase phosphorylation, MLC phosphorylation (MLC20-P plus MLC20-2P) and contraction in a concentration-dependent manner with EC50 values of 71, 8, 6 and 25 nM, respectively. ET-1-induced MAP kinase phosphorylation, MLC phosphorylation and contraction were not significantly affected by nifedipine (1-60 microM), an L-type Ca2+ channel blocker, or by LOE 908 (1-100 microM), a blocker of Ca2+-permeable nonselective cation channels. However, SKF96365, a receptor-operated Ca2+ channel (ROCC) blocker, inhibited MAP kinase phosphorylation, MLC phosphorylation and contraction in a concentration-dependent manner with IC50 values of 28, 30 and 42 microM, respectively. 2-APB, a store-operated Ca2+ channel (SOCC) blocker, inhibited ET-1-induced MLC phosphorylation and contraction in a concentration-dependent manner with IC50 values of 12.7 and 19 microM, respectively, but was without effect on MAP kinase phosphorylation. The combined effects of submaximal concentrations of SKF96365 and 2-APB on ET-1-induced MLC phosphorylation and contraction were not additive, implying that their inhibitory actions could be mediated through a common Ca2+ entry channel. PD98059, a MAP kinase inhibitor, had no effect on ET-1-induced MLC phosphorylation and contraction, suggesting that these ET-1 effects in the rabbit iris muscle are MAP kinase-independent. In conclusion, the present study demonstrated for the first time that in rabbit iris sphincter (a) ET-1, through the ETA receptor, stimulates MAP kinase phosphorylation, MLC phosphorylation and contraction in a concentration-dependent manner, (b) that these Ca2+-dependent functional responses are not significantly affected by nifedipine or LOE908, and (c) that ET-1-induced MLC phosphorylation and contraction are inhibited by SKF96365 and 2-APB, suggesting that these effects are mainly due to store- and/or receptor Ca2+ entry.     

Response of the isolated rat iris sphincter to cholinergic and adrenergic agents and electrical stimulation

In isolated rat iris sphincter muscle, there has been no attempt to measure mechanical tension changes, because of the small size of the preparation. In this study, responses of the isolated rat iris sphincter to some agents and electrical stimulation were examined. Acetylcholine and electrical stimulation produced powerful contractions of the iris sphincter. These contractile responses were suppressed by atropine and enhanced by physostigmine. 10 μM norepinephrine induced a weak contraction of the sphincter muscle and 1 mM isoproterenol induced a very weak relaxation. These responses were antagonized by phentolamine and propranolol, respectively. In the presence of 0.1 μM atropine, electrical stimulation produced a weak alpha-adrenergic contraction and a very weak beta-adrenergic relaxation. Electrically induced responses were abolished by tetrodotoxin. In conclusion, in the rat iris sphincter, powerful contraction is due to the activation of muscarinic receptors, and that there are weak alpha-adrenergic contraction and weak beta-adrenergic relaxation. Thus in rats, muscarinic contraction of the sphincter muscle plays major role in the regulation of pupil diameter.     

The rate of rhodopsin phosphorylation in isolated rentinas of frog and cattle.

Phosphorylation of rhodopsin has been measured in isolated retinas incubated with 32P-phosphate under physiological conditions. The half-time of the light-induced phosphorylation was found to be approximately 2 min with frog retinas at 21 degrees C, and in the order of 1--2 min with cattle retinas at 36 degrees C. It is suggested by this slow rate that the phosphorylation reaction is not directly involved in the chain of events which lead from absorption of a photon to excitation of the photoreceptor cells but may perhaps have a regulatory function in controlling light/dark adaptation.     

Simple model of smooth muscle myosin phosphorylation and dephosphorylation as rate-limiting mechanism.

A simple mathematical treatment of the model proposed by others in which a dynamic balance between Ca++ -dependent phosphorylation and Ca++-independent dephosphorylation of myosin controls the activation of smooth muscle contractility is presented. The parameters of the model can be computed from the experimentally observed stable force-[Ca++] relationship. A simple extension of the model to the case of time-dependent activation yields an expression that quantitatively predicts the measured dependence of the rate of isometric tension development on the activating free [Ca++]. The parameters of the mechanical model, which are derived from the rate constants for phosphorylating and dephosphorylating enzyme activities, are in reasonable agreement with the constants measured directly in purified protein systems. In addition, the model predicts values for several parameters that have not yet been experimentally measured, such as the ratio of kinase and phosphatase activities, the maximum extent of myosin phosphorylation, and the kinase turnover number.     

Structural properties of frog muscle myosin.

Frog myosin is a labile molecule, undergoing irreversible aggregation and rapid loss of ATPase; however, a procedure is described which provides highly purified myosin, with stable solubility and enzymatic properties, from skeletal muscle of Rana catesbeiana. Frog myosin contains heavy chains and light chains 1, 2, and 3. Light chain 3 is present in excess over light chain 1, and light chain 2 may occur as either, or both, of 2 closely migrating bands. On two-dimensional electrophoresis, light chain 1 generates an isoelectric component with pK 5.60; light chain 2 generates a complex pattern with 3 or 4 major components; and light chain 3 generates 2 major components with pK 5.00 and 4.92. The same subunit composition is obtained for frogs acclimated at 25 and 5 degrees C; however, proteolytic artifacts may occur in myosin preparations purified in the absence of protease inhibitors, especially in warm-acclimated frogs.     

The rate of rhodopsin phosphorylation in isolated retinas of frog and cattle

Phosphorylation of rhodopsin has been measured in isolated retinas incubated with ³²P-phosphate under physiological conditions. The half-time of the light-induced phosphorylation was found to be approximately 2 min with frog retinas at 21°C, and in the order of 1–2 min with cattle retinas at 36°C. It is suggested by this slow rate that the phosphorylation reaction is not directly involved in the chain of events which lead from absorption of a photon to excitation of the photoreceptor cells but may perhaps have regulatory function in controlling light/dark adaptation.     

A quantitative model of intersarcomere dynamics during fixed-end contractions of single frog muscle fibers.

A numerical model of a muscle fiber as 400 sarcomeres, identical except for their initial lengths, was used to simulate fixed-end tetanic contractions of frog single fibers at sarcomere lengths above the optimum. The sarcomeres were represented by a lumped model, constructed from the passive and active sarcomere length-tension curves, the force-velocity curve, and the observed active elasticity of a single frog muscle fiber. An intersarcomere force was included to prevent large disparities in lengths of neighboring sarcomeres. The model duplicated the fast rise, slow creep rise, peak, and slow decline of tension seen in tetanic contractions of stretched living fibers. Decreasing the initial non-uniformity of sarcomere length reduced the rate of rise of tension during the creep phase, but did not decrease the peak tension reached. Limitations of the model, and other processes that might contribute to the shape of the fixed end tetanic tension record are discussed. Taking account of model and experimental results, it is concluded that the distinctive features of the tension records of fixed end tetanic contraction at lengths beyond optimum can be explained by internal motion within the fiber.     

A structural model for phosphorylation control of Dictyostelium myosin II thick filament assembly

Deletion of the synapsin I genes, encoding one of the major groups of proteins on synaptic vesicles, in mice causes late onset epileptic seizures and enhanced experimental temporal lobe epilepsy. However, mice lacking synapsin I maintain normal excitatory synaptic transmission and modulation but for an enhancement of paired-pulse facilitation. To elucidate the cellular basis for epilepsy in mutants, we examined whether the inhibitory synapses in the hippocampus from mutant mice are intact by electrophysiological and morphological means. In the cultured hippocampal synapses from mutant mice, repeated application of a hypertonic solution significantly suppressed the subsequent transmitter release, associated with an accelerated vesicle replenishing time at the inhibitory synapses, compared with the excitatory synapses. In the mutants, morphologically identifiable synaptic vesicles failed to accumulate after application of a hypertonic solution at the inhibitory preterminals but not at the excitatory preterminals. In the CA3 pyramidal cells in hippocampal slices from mutant mice, inhibitory postsynaptic currents evoked by direct electrical stimulation of the interneuron in the striatum oriens were characterized by reduced quantal content compared with those in wild type. We conclude that synapsin I contributes to the anchoring of synaptic vesicles, thereby minimizing transmitter depletion at the inhibitory synapses. This may explain, at least in part, the epileptic seizures occurring in the synapsin I mutant mice.     

Origin of the iris sphincter muscle in chick embryo

The origin of the iridial sphincter muscle in chick embryo was investigated by means of immunohistochemistry. Desmin immunoreactive cells are shown in the mesenchymal stroma overlying the anterior epithelial layer of the iris in 4 1/2-day chick embryos. In 9-11-day chick embryos also some cells of the posterior epithelium near the pupillary margin, and of the iridial lamella show a slighter desmin-immunoreactivity. This finding agrees with a double origin of the iridial sphincter muscle: an early mesenchymal one and a later epithelial other.     

Directional and quantitative phosphorylation networks.

Directionality in protein signalling networks is due to modulated protein-protein interactions and is fundamental for proper signal progression and response to external and internal cues. This property is in part enabled by linear motifs embedding post-translational modification sites. These serve as recognition sites, guiding phosphorylation by kinases and subsequent binding of modular domains (e.g. SH2 and BRCT). Characterization of such modification-modulated interactions on a proteome-wide scale requires extensive computational and experimental analysis. Here, we review the latest advances in methods for unravelling phosphorylation-mediated cellular interaction networks. In particular, we will discuss how the combination of new quantitative mass-spectrometric technologies and computational algorithms together are enhancing mapping of these largely uncharted dynamic networks. By combining quantitative measurements of phosphorylation events with computational approaches, we argue that systems level models will help to decipher complex diseases through the ability to predict cellular systems trajectories.     

Kinetic model for isometric contraction in smooth muscle on the basis of myosin phosphorylation hypothesis.

A kinetic model was proposed to simulate an isometric contraction curve in smooth muscle on the basis of the myosin phosphorylation hypothesis. The Ca2+-calmodulin-dependent activation of myosin light-chain kinase and the phosphorylation-dephosphorylation reaction of myosin were mathematically treated. Solving the kinetic equations at a steady state, we could calculate the relationship between the Ca2+ concentration and the myosin phosphorylation. Assuming that two-head-phosphorylated myosin has an actin-activated Mg2+-ATPase activity and that this state corresponds to an active state, we computed the time courses of the myosin phosphorylation and the active state for various Ca2+ transients. The time course of the active state was converted into that of isometric tension by use of Sandow's model composed of a contractile element and a series elastic component. The model could simulate not only the isometric contraction curves for any given Ca2+ transient but also the following experimental results: the calmodulin-dependent shift of the Ca2+ sensitivity of isometric tension observed in skinned muscle fibers, the disagreement between the Ca2+ sensitivity of myosin phosphorylation and that of isometric tension at a steady state, and the disagreement between the time course of myosin phosphorylation and that of isometric tension development.