Interleukin-1α (IL-1α) production by alveolar macrophages in patients with acute lung diseases: the influence of zinc supplementation

In vertebrate retina, rod outer segment is the site of visual transduction. The inward cationic current in the dark-adapted outer segment is regulated by cyclic GMP. A light flash on the outer segment activates a cyclic GMP phosphodiesterase resulting in rapid hydrolysis of the cyclic nucleotide which in turn causes a decrease in the dark current. Restoration of the dark current requires inactivation of the phosphodiesterase and synthesis of cyclic GMP. The latter is accomplished by the enzyme guanylate cyclase which catalyzes the formation of cyclic GMP from GTP. Therefore, factors regulating the cyclase activity play a critcal role in visual transduction. But regulation of the cyclase by some of these factors — phosphodiesterase, ATP, the soluble proteins and metal cofactors (Mg and Mn) — is controversial. The availability of different types of cyclase preparations, dark-adapted rod outer segments with fully inhibited phosphodiesterase activity, partially purified cyclase without PDE contamination, cloned rod outer segment cyclase free of other rod outer segment proteins, permitted us to address these controversial issues. The results show that ATP inhibits the basal cyclase activity but enhances the stimulation of the enzyme by soluble activator, that cyclase can be activated in the dark at low calcium concentrations under conditions where phosphodiesterase activity is fully suppressed, and that greater activity is observed with manganese as cofactor than magnesium. These results provide a better understanding of the controls on cyclase activity in rod outer segments and suggest how regulation of this cyclase by ATP differs from that of other known membrane guanylate cyclases.This work was supported by the grants from the National Institutes of Health (EY07158, EY 05230, EY 10828, NS 23744) and the equipment grant from Pennsylvania Lions Eye Research Foundation.     

Biochemical aspects of the visual process XXIV. Adenylate cyclase and rod photoreceptor membranes: A critical appraisal

Adenylate cyclase was found to be present in rod outer segment preparations, but its specific activity was only about 1% of activities reported in earlier studies. In frog activities ranged from 0.015 to 1.1 nmoles 3′,5′ cyclic AMP/mg protein per 10 min depending on the method of preparation and homogenization. In cattle, the rod outer segment layer obtained after sucrose density gradient centrifugation, had an activity of 0.22 nmole 3′,5′ cyclic AMP/mg protein per 10 min. Furthermore a second (more dense) layer obtained in this procedure possessed a 10 times higher specific activity.Light decreased the adenylate cyclase activity in the rod outer segment suspensions of both frog and cattle, but the maximal inhibition was about 50% at extensive illumination. Light did not affect the activity in the second layer, unless rod outer segment layer material was present, indicating that an inhibitory diffusible factor is released from outer segments during illumination. Evidence that either Ca²⁺ or free all-trans retinaldehyde constitutes this factor could not be obtained.The activities of some marker enzymes in the two layers and in whole retina homogenates from cattle were determined. Comparison of some properties of the adenylate cyclase activities in the two layers and consideration of these enzyme activities do not exclude the possibilty that the activity in the rod outer segment material is due to contamination with other retinal material.The available evidence does not support a direct role for 3′,5′ cyclic AMP in the visual excitation process.     

Protein activator of cyclic AMP phosphodiesterase and cyclic nucleotide phosphodiesterase in bovine retina and bovine lens. Activity, subcellular distribution and kinetic parameters.

We have examined the activity of cyclic AMP phosphodiesterase, cyclic GMP phosphodiesterase and the protein activator of cyclic AMP phosphodiesterase in various anatomic and subcellular fractions of the bovine eye. Cyclic GMP hydrolysis was 1.6--12 times faster than hydrolysis of cyclic AMP in the subcellular fractions of the retina and in the precipitate of the rod outer segment. An opposite pattern was seen in the bovine lens, where the hyrolysis of cyclic AMP occurred 17 and 169 times faster than that of cyclic GMP in the supernatant and precipitate of lens, respectively. The activity of cyclic AMP phosphodiesterase was not affected by ethylene-glycol bis(beta-aminoethylether)-N,N'-tetraacetic acid in any fractions except in the retinal supernatant, suggesting that the phosphodiesterase exists primarily as a Ca2+-independent, activator-independent form. However, the protein activator of cyclic AMP phosphodiesterase existed in all fractions examine. A complex kinetic patternwas observed for both cyclic AMP and cyllic GMP hydrolysis by the 105000 times g lens supernatant. The Michaelis constants for both cyclic AMP (1.3-10(-6) and 9.I-10(-6) M) and cyclic GMP (1.04-10(6) AND 1.22 10(-5) M) appeared to be similar.     

Association of guanylate cyclase with the axoneme of retinal rods

Axonemes were isolated from purified bovine retinal rod outer segments by dissolving the outer segment membranes in detergent and separating the axonemes by centrifugation on a linear detergent-containing sucrose density gradient. Guanylate cyclase (GTP pyrophosphate-lyase (cyclizing), EC 4.61.2) activity was concentrated in the axoneme fraction. Guanylate cyclase eluted in the void volume when detergent-solubilized rod outer segments were subjected to exclusion chromatography on Sepharose 4B. Attempts to extract guanylate cyclase from isolated axonemes with salt, EDTA, base and other reagents were successful.     

Characterization of guanylate cyclase of rod outer segments of the bovine retina.

Guanylate cyclase (GTP pyrophosphate-lyse (cyclizing), EC 4.6.1.2.) of bovine retinal rod outer segments is almost completely particulate, i.e. associated with rod outer segment membranes. In contrast to particulate guanylate cyclase in other tissues, treatment of rod outer segments with Triton X-100 does not solublize the enzyme but inhibits it. Enzyme activity is dependent on the presence of divalent cation, especially Mn2+ with only poor activation by Mg2+ (10-fold lower) and no activation seen with other cation. Ezpression of maximal activity required Nm2+ and GTP in equimolar concentrations with an apparent Km of 8 . 10(-4) M and V of 10 nmol/min per mg protein. Excess of Mn2+ over that required for the formation of the Mn . GTP complex was inhibitory. Ca2+, Ba2+ and Co2+ inhibited enzyme activity when assayed with the Mn . GTP substrate complex. In the presence of a fixed concentration of 1mM Mn2+, the enzyme exhibited strong negative cooperative interactions with GTP, characterized by an intermediary plateau region in the substrate vs. enzyme activity curve, a curve of downward concavity in the double reciprocal plot and a Hill coefficient of 0.5. Nucleotides such as ITP, ATP and UTP at higher concentrations (1 mM) stimulates activity by 40%. NaN3 has no effect on the guanylate cyclase. It is thus possible that the guanylate cyclase may be regulated in vivo by both the metal : GTP substrate ratio and the free divalent cation concentration as well as by the ATP concentration and thus play an important but yet undefined role in the visual process.     

Genetic Expression of Cyclic GMP Phosphodiesterase Activity Defines Abnormal Photoreceptor Differentiation in Neurological Mutants of Inherited Retinal Degeneration

We have examined cyclic GMP concentrations, guanylate cyclase activities, and cyclic GMP phosphodiesterase (PDE) activities in developing retinas of congenic mice with different allelic combinations at the retinal degeneration (rd) and retinal degeneration slow (rds) loci. Although guanylate cyclase activities were found to be uniformly low in the mutant retinas, striking differences in PDE activity and cyclic GMP levels were observed in retinas of the various genotypes. Homozygous rds mice, which lack receptor outer segments, showed reduced retinal PDE activity and cyclic GMP concentration in comparison to normal animals. In heterozygous rds/+ mice with abnormal outer segments, the levels were intermediate. In retinas of homozygous rd mice, PDE activity was lower than in rds retinas and cyclic GMP levels were much higher. In mice homozygous for both rd and rds genes, retinal PDE activities were even lower than in single homozygous rd mice; the cyclic GMP level reached the same high value as in the rd animals, persisted for a longer time at this high level, and did not correlate with the rate of photoreceptor cell loss. Thus, a marked variation in PDE activity appears to be the major manifestation of abnormal outer segment differentiation and eventual degeneration of photoreceptor cells in these neurological mutants. An increased cyclic GMP level seems to be an essential corollary in the expression of the rd gene even in the absence of outer segments, but it appears unlikely that an abnormally high nucleotide level in itself causes photoreceptor cell death.     

Characterization of guanylate cyclase activity in single retinal rod outer segments

cGMP mediates vertebrate phototransduction by directly gating cationic channels on the plasma membrane of the photoreceptor outer segment. This second messenger is produced by a guanylate cyclase and hydrolyzed by a light-activated cGMP-phosphodiesterase. Both of these enzyme activities are Ca2+ sensitive, the guanylate cyclase activity being inhibited and the light-activated phosphodiesterase being enhanced by Ca2+. Changes in these activities due to a light-induced decrease in intracellular Ca2+ are involved in the adaptation of photoreceptors to background light. We describe here experiments to characterize the guanylate cyclase activity and its modulation by Ca2+ using a truncated rod outer segment preparation, in order to evaluate the enzyme's role in light adaptation. The outer segment of a tiger salamander rod was drawn into a suction pipette to allow recording of membrane current, and the remainder of the cell was sheared off with a probe to allow internal dialysis. The cGMP-gated channels on the surface membrane were used to monitor conversion of GTP, supplied from the bath, into cGMP by the guanylate cyclase in the outer segment. At nominal 0 Ca2+, the cyclase activity had a Km of 250 microM MgGTP and a Vmax of 25 microM cGMP s-1 in the presence of 1.6 mM free Mg2+; in the presence of 0.5 mM free Mg2+, the Km was 310 microM MgGTP and the Vmax was 17 microM cGMP s-1. The stimulation by Mg2+ had an EC50 of 0.2 mM Mg2+ for MgGTP at 0.5 mM. Ca2+ inhibited the cyclase activity. In a K+ intracellular solution, with 0.5 mM free Mg2+ and 2.0 mM GTP, the cyclase activity was 13 microM cGMP s-1 at nominal 0 Ca2+; Ca2+ decreased this activity with a IC50 of approximately 90 nM and a Hill coefficient of approximately 2.0.     

Photoreceptor GTP binding protein mediates fluoride activation of phosphodiesterase

In this report, we show that fluoride activates dark-adapted rod outer segment phosphodiesterase, and that this activation is mediated, in analogy with adenylate cyclase, through a GTP binding protein. The GTP binding protein is released from dark-adapted rod outer segment membranes by exposure to fluoride and subsequent centrifugation. The 39-kilodalton subunit of the GTP binding protein, released from the membrane by this procedure, exhibits altered susceptibility to limited trypsin proteolysis, identical to that seen when hydrolysis-resistant GTP analogs are bound to that subunit. Repeated exposure of dark-adapted rod outer segment membranes to fluoride and subsequent centrifugation results in maximal activation of the membrane-bound phosphodiesterase. Thus, activation of phosphodiesterase by fluoride in the dark appears similar to fluoride activation of adenylate cyclase.     

Isolation of an inhibitory protein for the cyclic guanosine 3','5'-monophosphate phosphodiesterase of bovine rod outer segments

Cyclic guanosine 3',5'-monophosphate phosphodiesterase in crude extracts from bovine rod outer segments can be activated by the addition of bleached rod outer segment membranes and GTP. In the absence of rhodopsin-containing membranes, the phosphodiesterase specific activity decreases with increasing concentration. A trypsin-sensitive inhibitor believed to be responsible for this phenomenon can be separated from the phosphodiesterase by DEAE-cellulose chromatography of the crude extract. Phosphodiesterase eluted from the DEAE-cellulose column shows considerably less concentration-dependence than in the crude extract. This partially purified phosphodiesterase was used as the substrate to assay for inhibitor. A GTPase which is active only in the presence of bleached rod outer segment membranes coelutes with the phosphodiesterase and is distinct from the phosphodiesterase inhibitor we have isolated.     

cGMP phosphodiesterase in rod and cone outer segments of the retina

Immunochemical, chromatographic, and sodium dodecyl sulfate gel electrophoresis studies suggest that immunologically related but distinct cyclic GMP phosphodiesterases are present in rod and cone outer segments of the retina. Immunocytochemical studies demonstrated that one monoclonal antibody (ROS-1) recognized a determinant present in both rod and cone outer segments, while another monoclonal antibody (ROS-2) only recognized rod outer segments. At least two peaks of phosphodiesterase activity could be separated by high-performance anion-exchange chromatography of retinal extracts. Both peaks were recognized by ROS-1. None of the first peak and only 80% of the second broad peak of activity were recognized by ROS-2. High-performance liquid chromatography profiles from human fovea and several other types of cone-enriched retina showed that most of the activity was contained in the first peak, suggesting that this activity was derived from cone outer segments. Conversely, the phosphodiesterase in rod-enriched preparations migrated predominately in the second peak. Sodium dodecyl sulfate-gel electrophoresis indicated that this first peak contained a single large immunoreactive polypeptide (alpha') that migrated with the same mobility as a phosphorylase b standard and was distinct from the more rapidly migrating large immunoreactive polypeptides (alpha and beta) present in a broad second peak. The second peak could be further separated into a first part that contained a doublet of two immunoreactive polypeptides (alpha and beta) that migrated faster than phosphorylase b and a later part that contained only the most rapidly migrating polypeptide (beta). All of the peaks could be activated by histone or transducin:GTP, implying that all contained a small 11-kDa inhibitory subunit (gamma) of the enzyme. Since the larger (alpha') and smaller (beta) immunoreactive polypeptides could be completely separated from the alpha polypeptide and from each other, yet still retain the ability to be activated by histone or transducin, the data suggest that only a single species of polypeptide-inhibitor complex (e.g. alpha' gamma, alpha gamma, or beta gamma) was required for histone or transducin:GTP activation.     

Binding of the delta subunit to rod phosphodiesterase catalytic subunits requires methylated, prenylated C-termini of the catalytic subunits

PDE6 (type 6 phosphodiesterase) from rod outer segments consists of two types of catalytic subunits, alpha and beta; two inhibitory gamma subunits; and one or more delta subunits found only on the soluble form of the enzyme. About 70% of the phosphodiesterase activity found in rod outer segments is membrane-bound, and is thought to be anchored to the membrane through C-terminal prenyl groups. The recombinant delta subunit has been shown to solubilize the membrane-bound form of the enzyme. This paper describes the site and mechanism of this interaction in more detail. In isolated rod outer segments, the delta subunit was found exclusively in the soluble fraction, and about 30% of it did not coimmunoprecipitate with the catalytic subunits. The delta subunit that was bound to the catalytic subunits dissociated slowly, with a half-life of about 3.5 h. To determine whether the site of this strong binding was the C-termini of the phosphodiesterase catalytic subunits, peptides corresponding to the C-terminal ends of the alpha and beta subunits were synthesized. Micromolar concentrations of these peptides blocked the phosphodiesterase/delta subunit interaction. Interestingly, this blockade only occurred if the peptides were both prenylated and methylated. These results suggested that a major site of interaction of the delta subunit is the methylated, prenylated C-terminus of the phosphodiesterase catalytic subunits. To determine whether the catalytic subunits of the full-length enzyme are methylated in situ when bound to the delta subunit, we labeled rod outer segments with a tritiated methyl donor. Soluble phosphodiesterase from these rod outer segments was more highly methylated (4.5 +/- 0.3-fold) than the membrane-bound phosphodiesterase, suggesting that the delta subunit bound preferentially to the methylated enzyme in the outer segment. Together these results suggest that the delta subunit/phosphodiesterase catalytic subunit interaction may be regulated by the C-terminal methylation of the catalytic subunits.     

Light-induced dephosphorylation of two proteins in frog rod outer segments: influence of cyclic nucleotides and calcium

Two minor proteins of frog rod outer segments become phosphorylated when retinas are incubated in the dark with 32Pi. The proteins, designated component I (13,000 daltons) and component II (12,000 daltons), are dephosphorylated when retinas are illuminated. The dephosphorylation is reversible; the two proteins are rephosphorylated when illumination ceases. Each outer segment contains approximately 10(6( molecules of components I and II. These remain associated with both fragmented and intact outer segments but dissociate from the outer segment membranes under hypoosmotic conditions. The extent of the light-induced dephosphorylation increases with higher intensities of illumination and is maximal with continuous illumination which bleaches 5.0 x 10(5) rhodopsin molecules/outer segment per second. Light which bleaches 5.0 x 10(3) rhodopsin molecules/outer segment per second causes approximately half-maximal dephosphorylation. This same intermediate level of illumination causes half-suppression of the light-sensitive permeability mechanism in isolated outer segments (Brodie and Bownds. 1976. J. Gen Physiol. 68:1-11) and also induces a half-maximal decrease in their cyclic GMP content (Woodruff et al. 1977. J. Gen. Physiol. 69:667-679). The phosphorylation of components I and II is enhanced by the addition of cyclic GMP or cyclic AMP to either retinas or isolated rod outer segments maintained in the dark. Several pharmacological agents which influence cyclic GMP levels in outer segments, including calcium, cause similar effects on the phosphorylation of components I and II and outer segment permeability. Although the cyclic nucleotide-stimulated phosphorylation can be observed either in retinas or isolated rod outer segments, the light-induced dephosphorylation is observed only in intact retinas.     

Protein complement of rod outer segments of frog retina

Rod outer segments (ROS) from frog retina have been purified by Percoll density gradient centrifugation, a procedure that preserves their form and intactness. One- and two-dimensional electrophoretic analysis reveals a smaller number of proteins than is observed in many cell organelles and permits quantitation of the 20 most abundant polypeptides. Rhodopsin accounts for 70% of the total protein (3 X 10(9) copies/outer segment), and approximately 70 other polypeptides are present at more than 6 X 10(4) copies/outer segment. Another 17% of the total protein is accounted for by the G-protein (3 X 10(8) copies/outer segment) that links rhodopsin bleaching and the activation of cyclic GMP phosphodiesterase (PDE). The phosphodiesterase accounts for 1.5% of the protein (1.5 X 10(7) copies/outer segment), and a 48,000-dalton component that binds to the membrane in the light accounts for a further 2.6%. The function of approximately 90% of the total protein in the outer segment is known, and two-thirds of the non-rhodopsin protein is accounted for by enzyme activities associated with cyclic GMP metabolism. The relative molar abundance of rhodopsin, G-protein, and PDE is 100:10:1. Apart from these major membrane-associated proteins, most of the other proteins are cytosolic. Thirteen other polypeptides are found at an abundance of one or more copies per 1000 rhodopsins, nine soluble and four membrane-bound, and their abundance relative to rhodopsin has been quantitated. ROS have been separated into subcellular fractions which resolve three classes of soluble, extrinsic membrane, and integral membrane proteins. A listing of the proteins that are phosphorylated and their subcellular localization is given. Approximately 25 phosphopeptides are detected, and most are in the soluble fraction. Fewer phosphorylated proteins are associated with the purified outer segments than with crude ROS. Distinct patterns of phosphorylation are associated with intact rods incubated with [32P]Pi and broken rods incubated with [gamma-32P]ATP.     

Molecular mechanisms of photoreception. IV. Ca2+-inhibited GTPase of rod outer segments of the frog retina

Ca2+-dependent GTPase activity is found to be present in the rod outer segments of frog retina. GTPase localization in rod outer segments is shown by fractionating the rod outer segment preparation in the sucrose density gradient. The enzyme is readily washed out of cells with isotonic NaCl solution. The Km is 0.6 mM for GTP. The activity is inhibited by 78 +/- 12% with the increase in Ca2+ concentration from 10(-9) to 10(-7) M. GTP hydrolysis is inhibited by the same concentrations of Ca2+ which block the sodium conductivity of the rod outer segment cytoplasmic membrane.     

The fine structure of the pigment epithelium and photoreceptor cells of the newt,Triturus viridescens dorsalis (Rafinesque)

The morphology of the retinal pigment epithelium and photoreceptor cells has been studied in the common newt Triturus viridescens dorsalis by light, conventional transmission and scanning electron microscopy. The pigment epithelium is formed by a single layer of low rectangular cells, separated by a multilayered membrane (Bruch's membrane) from the vessels of the choriocapillaris. The scleral border of the pigment epithelium is highly infolded and each epithelial cell contains smooth endoplasmic reticulum, myeloid bodies, mitochondria, lysosomes, phagosomes and an oval nucleus. Inner, pigment laden, epithelial processes surround the photoreceptor outer and inner segments. The three retinal photoreceptor types, rods, single cones and double cones, differ in both external and internal appearance. The newt, rod, outer segments appear denser than the cones in both light and electron micrographs, due to a greater number of rod lamellae per unit distance of outer segment and to the presence of electron dense intralamellar bands. The rod outer segments possess deep incisures in the lamellae while the cone lamellae lack incisures. Both rod and cone outer segments are supported by a peripheral array of dendritic processes containing longitudinal filaments which originate in the inner segment. The inner segment mitochondria, forming the rod ellipsoid, arelong and narrow while those in the cone are spherical to oval in shape. The inner segments of all three receptor cell types also contain a glycogen-filled paraboloid and a myoid region, just outside the nucleus, rich in both rough and smooth endoplasmic reticulum. The elongate, cylindrical nuclei differ in density. The rod nuclei are denser than those of the cones, contain clumped chromatin and usually extend further vitreally. Similarly, the cytoplasm of the rod synaptic terminal is denser than its cone counterpart and contains synaptic vesicles almost twice as large as those of the cones. Photoreceptor synapses in rods and cones are established by both superficial and invaginated contacts with bipolar or horizontal cells.     

Vanadate, tungstate and molybdate activate rod outer segment phosphodiesterase in the dark

Anionic activation of rod outer segment phosphodiesterase by vanadate, molybdate and tungstate is demonstrated. Comparisons are made to adenylate cyclase, which is known to be activated by vanadate and molybdate but not by tungstate. In view of the differences in anionic activation between these two important enzymatic regulators of intracellular cyclic nucleotide metabolism, it is possible that tungstate can be used as a selective probe for the effects of phosphodiesterase activity in photoreceptors and other cells. The known electrophysiological stimulation of Limulus photoreceptors by these anions is also interpreted in light of our results. If anionic production of quantum bumps in Limulus photoreceptors is mediated by changes in cyclic nucleotides, then the electrophysiological response of Limulus photoreceptors to tungstate may indicate a role for phosphodiesterase rather than adenylate cyclase in mediating light-induced cyclic nucleotide alterations in this cell.     

Immunologic characterization of the photoreceptor outer segment cyclic GMP phosphodiesterase

High affinity (KD approximately 1 X 10(-9) M) monoclonal antibodies (ROS-1 and ROS-2) were prepared to bovine photoreceptor outer segment cGMP phosphodiesterase. ROS-1 immunoadsorbed greater than 95% of the cGMP phosphodiesterase activity from a detergent-solubilized bovine retina extract while ROS-2 immunoadsorbed only a subfraction of the same activity. Sodium dodecyl sulfate gel analysis of these immunoadsorbates demonstrated that ROS-1 and ROS-2 specifically adsorbed only peptides that comigrated with purified rod outer segment phosphodiesterase. Limited trypsin digestion of purified rod outer segment phosphodiesterase greatly reduced its affinity for ROS-1 but not ROS-2. When a crude heat-stable inhibitor fraction was added back to the activated enzyme, the affinity for ROS-1 was restored, suggesting that the inhibitor was necessary for ROS-1 binding. ROS-1 but not ROS-2 was found to inhibit cGMP phosphodiesterase which had been activated either by dilution or guanyl nucleotide. The inhibitory property of ROS-1 may provide a useful probe for directly studying the effects of this phosphodiesterase on the phototransduction response in the retina. Sodium dodecyl sulfate gel analysis demonstrated that the ROS-1 immunoadsorbates from mammals, fish, and amphibia contained peptides of similar mobility. Immunocytochemistry performed with ROS-1 and fluorescein isothiocyanate-conjugated rabbit anti-mouse IgG localized the antigenic determinant to both rod and cone outer segments suggesting the presence of an antigenically similar phosphodiesterase in both types of photoreceptors.     

Inhibition by pertussis toxin of guanyl nucleotides exchange on transducin in bovine rod cell membranes

The effect of pertussis toxin on GTP-binding protein of bovine rod cell outer segments (transducin) was studied. Pertussis toxin was shown to ADP ribosylate either alpha subunit of free transducin or transducin-GDP complex, whereas GTP and its analogue Gpp(NH)p strongly inhibit ADP ribosylation of transducin. Pertussis toxin inhibits rod outer segment membrane GTPase and GTPase of homogeneous transducin by 40% and 70-80%, respectively. Activation of rod cell cyclic nucleotide phosphodiesterase by transducin is reduced after its preincubation with pertussis toxin. In transducin modified by pertussis toxin, 83% of GDP becomes tightly bound and cannot be exchanged with Gpp(NH)p. The stabilization of complex transducin-GDP after ADP ribosylation can explain the inhibitory effect of pertussis toxin on GTP hydrolysis by transducin, and on phosphodiesterase activation by guanyl nucleotides.     

Acute Effects of Soman, Sarin, and Tabun on Microsomal and Cytosolic Components of the Calmodulin System in Rat Striatum

Two hours after administration of Soman (120 micrograms/kg, s.c.), Sarin (150 micrograms/kg, s.c.), or Tabun (240 micrograms/kg, s.c.), microsomes and cytosol were prepared from rat striata. Microsomal and cytosolic calmodulin (CaM) levels, microsomal adenylate and guanylate cyclase activities, protein kinase activities, and Ca2+ + Mg2+-ATPase activities were determined while cytosolic phosphodiesterase (PDE) activities were determined. CaM levels in both cell fractions were significantly increased by Soman and Sarin. Cyclic AMP-PDE and adenylate cyclase activities were decreased by Soman and Sarin. All three agents decreased activities of cyclic GMP-PDE and guanylate cyclase. Sarin and Tabun administration caused significant increases in microsomal protein kinase activity and none of the agents affected activity of divalent cation ATPases. The intensity of effects of the three organophosphates roughly paralleled their observed neurotoxic potencies. The results indicate that components of the CaM system are implicated as either causative or adaptive changes induced by these agents.     

Adenylate Cyclases in the Vertebrate Retina: Distribution and Characteristics in Rabbit and Ground Squirrel

Adenylate cyclase activity and the effects of EGTA, 5'-guanylylimidodiphosphate (GPP(NH)P), and dopamine were measured in microdissected layers of rod-dominant (rabbit) and cone-dominant (ground squirrel) retinas, The distribution of basal enzyme activity was similar in both species, with the highest levels found in the inner plexiform and photoreceptor cell inner segment layers, EGTA inhibited adenylate cyclase in the inner retina of both species and stimulated activity in rabbit outer and inner segment layers, but had no effect in these layers from ground squirrel. Enzyme activity was stimulated in all regions by GPP(NH)P, except in the outer segments of the photoreceptors. Dopamine stimulated the enzyme in the outer and inner plexiform and inner nuclear layers in rabbit, but only in the inner plexiform layer in ground squirrel. These data demonstrate that the enzymatic characteristics of adenylate cyclase vary extensively from region to region in vertebrate retina and suggest that cyclic AMP may have multiple roles in this tissue. A model for the distribution of the different forms of adenylate cyclase in retina is proposed.