Differences and Similarities in Muscarinic Receptors of Rat Heart and Retina: Effects of Agonists, Guanine Nucleotides, and N-Ethylmaleimide

Muscarinic receptor stimulation inhibits cyclic AMP formation in rat atria but not in retina. We compared the properties of the muscarinic receptors in rat atrial and retinal membranes using the antagonist [3H]quinuclidinyl benzilate. In both atria and retina there is a single binding site for antagonists, while agonists appear to interact at two classes of binding sites. Muscarinic receptors in atria and retina have the same apparent affinities for several antagonists and for a series of muscarinic agonists. In both tissues N-ethylmaleimide decreases agonist affinity for the high-affinity binding sites. Muscarinic receptors in atria and retina differ, however, in several properties relating to the proportions of high- and low-affinity agonist sites. First, guanine nucleotides markedly increase the proportion of low-affinity binding sites in atria, but not in retina. Second, for all agonists there are fewer high-affinity binding sites in retina. Third, the "partial agonist" pilocarpine appears to interact with two classes of binding sites in atria, but with only a single class of sites in retina. Our data suggest that muscarinic receptors that inhibit cyclic AMP formation and those that do not share common properties that determine receptor affinity for agonists and classic antagonists. The differences between these receptors are manifest, however, in the effects of guanine nucleotides and the ability of agonists, especially those of low efficacy, to affect the proportion of high- and low-affinity sites and to effect a biological response.     

Effects of Cyclic Nucleotides and Calcium/Calmodulin on Protein Phosphorylation in the CNS of Hirudo medicinalis

Protein phosphorylation plays an important role in the regulation of neural functions. We have studied the phosphorylation of proteins in homogenates of segmental ganglia of the leech Hirudo medicinalis. We describe a number of proteins whose phosphorylation is dependent on calcium/calmodulin or cyclic nucleotides. Most of the proteins whose phosphorylation is increased in the presence of calcium seem to be substrates for cyclic nucleotide-dependent protein kinases. Only two of the phosphoproteins described appear to be specific substrates for calcium/calmodulin protein kinase(s), and at least six phosphoproteins appear to be specific substrates for cyclic nucleotide-dependent kinase(s). The leech nervous system, with large and identifiable neurons, provides a good tool for studies of neural functions, such as learning. The results are discussed in the context of the role of protein phosphorylation on learning processes.     

The effect of cyclic nucleotides and protein phosphorylation on calcium permeability and binding in the sarcoplasmic reticulum.

In the absence of cyclic nucleotides heart microsomes have two classes of calcium binding sites with binding constants of 0.69 and 0.071 micron-1 and capacities of 2.2 and 9.7 nmol/mg protein, respectively. Neither cyclic AMP nor monobutyryl cyclic AMP affect binding but cyclic GMP and monobutyryl cyclic GMP cause the complete loss of the high affinity calcium binding sites, Cyclic GMP (but not monobutyryl cyclic GMP) also causes a decrease in the binding constant of the low affinity binding sites. AMP, GMP and Tris-butyrate do not affect calcium binding. The effects of the cyclic nucleotides are direct and are not mediated by protein phosphorylation. Phosphorylation of microsomal proteins increases the binding constant but not the capacity of the high affinity calcium binding sites. The capacity and also, perhaps, binding constant of the low affinity sites is also increased by phosphorylation. In additon to their effects on calcium binding the cyclic nucleotides also affect the movements of calcium into and out of the microsomes. The effects are again direct and not mediated by protein phosphorylation. Cyclic GMP decreases the rate of Ca2+ efflux from preloaded cardiac microsomes and also appears to decrease the rate of uptake of Ca2+ by cardiac microsomes though this effect is less clear cut than the action on efflux. The cyclic nucleotide has a half maximal effect at a concentration of 100 microns. By contrast cyclic AMP increases the rate of influx of Ca2+ into heart microsomes and the rate of efflux of Ca2+ from preloaded preparations. The effect is, however, rather slight. It is suggested that the most obvious interpretation of these results is that cyclic GMP decreases the Ca2+ permeability of the cardiac microsomal membrane while cyclic AMP increases the permeability. In contrast to the results found with membrane preparations from certain other tissues phosphorylation of cardiac microsomal proteins does not appear to alter Ca2+ efflux or influx out of, or into, cardiac microsomal preparations. It is thus concluded that phosphorylation of cardiac microsomal proteins does not affect the Ca2+ permeability of the microsomal membrane.     

Somatic genetic analysis of cyclic AMP action: characterization of unresponsive mutants.

N-6,O-2'-dibutyryl adenosine 3',5'-monophosphate kills cultured mouse lymphosarcoma cells, but not resistant mutants derived by a single-step clonal selection. Resistant clones lack the cyclic AMP binding proteins present in wild type, cyclic AMP sensitive clones. Both endogenous cyclic AMP, accumulated in response to isoproterenol or cholera toxin, and exogenous dibutyryl cyclic AMP induce cyclic AMP phosphodiesterase, slow growth, and eventually kill wild type cells. In the resistant mutants, however, the endogenous and exogenous cyclic nucleotides appear to be completely inactive. These results indicate that an intracellular receptor for cyclic AMP, previously shown to be associated with a cyclic AMP-dependent protein kinase, mediates cyclic AMP's regulation of growth and phosphodiesterase synthesis.     

New messages from old messengers: cAMP and mycobacteria

Cyclic nucleotides are ancient second messengers, and the enzymes that synthesize cAMP and cGMP [cyclic nucleotide monophosphates (cNMPs)] are encoded in the genomes of several bacteria. We focus here on recent biochemical and structural information on the proteins that make and break cyclic nucleotides in mycobacteria, namely the nucleotide cyclases and phosphodiesterases, respectively. The presence of these enzymes along with putative cNMP-binding proteins suggests an intricate regulation of cAMP metabolism and utilization by these organisms. It is anticipated that future research will be directed towards identifying cellular processes that are regulated by cAMP in mycobacteria and deciphering the cross-talk between mycobacterial pathogens and their eukaryotic host.     

Probing the assembly of the 3' major domain of 16 S rRNA. Interactions involving ribosomal proteins S2, S3, S10, S13 and S14

We have used rapid probing methods to follow the changes in reactivity of residues in 16 S rRNA to chemical and enzymatic probes as ribosomal proteins S2, S3, S10, S13 and S14 are assembled into 30 S subunits. Effects observed are confined to the 3' major domain of the RNA and comprise three general classes. (1) Monospecific effects, which are attributable to a single protein. Proteins S13 and S14 each affect the reactivities of different residues which are adjacent to regions previously found protected by S19. S10 effects are located in two separate regions of the domain, the 1120/1150 stem and the 1280 loop; both of these regions are near nucleotides previously found protected by S9. Both S2 and S3 protect different nucleotides between positions 1070 and 1112. In addition, S2 protects residues in the 1160/1170 stem-loop. (2) Co-operative effects, which include residues dependent on the simultaneous presence of both proteins S2 and S3 for their reactivities to appear similar to those observed in native 30 S subunits. (3) Polyspecific effects, where proteins S3 and S2 independently afford the same protection and enhancement pattern in three distal regions of the domain: the 960 stem-loop, the 1050/1200 stem and in the upper part of the domain (nucleotides 1070 to 1190). Proteins S14 and S10 also weakly affect the reactivities of several residues in these regions. We believe that several of the protected residues of the first class are likely sites for protein-RNA contact while the third class is indicative of conformational rearrangement in the RNA during assembly. These results, in combination with the results from our previous study of proteins S7, S9 and S19, are discussed in terms of the assembly, topography and involvement in ribosomal function of the 3' major domain.     

Several GTP-binding proteins, including p21c-H-ras, are preferred substrates of Pseudomonas aeruginosa exoenzyme S

Pseudomonas aeruginosa exoenzyme S has appeared to be relatively indiscriminate in its choice of substrates, but in fact it ADP-ribosylates only a small subset of cellular proteins and exhibits a marked preference for several different membrane-associated proteins of apparent Mr = 23,000-25,000, at least some of which appear to bind GTP. One of these is the p21 product of the proto-oncogene c-H-ras, which can be labeled to completion. ADP-ribosylation does not alter the interaction of p21c-H-ras with guanyl nucleotides, but does cause a shift in electrophoretic mobility that implies a large conformational change. Exoenzyme S modifies all of its substrates at arginine residues.     

Filamentous protein model for cyclic AMP-mediated cell regulatory mechanisms.

A striking correlation exists in the literature between cell regulatory phenomena mediated by cyclic AMP and the presence of filamentous proteins. By filamentous proteins is meant microtubules, microfilaments, and actinlike protein, three general classes of proteins which can be grouped on structural and functional grounds. These proteins comprise a significant portion of the protein of all eucaryotic cells and appear to be evolutionary related and quite constant. The cell events discussed include regulation of growth, differentiation, responses to hormones, secretion, including neurotransmitter release, and membrane permeability. These phenomena share a role for cyclic AMP and an involvement of filamentous proteins. The filamentous protein model for cyclic AMP-mediated cell regulatory mechanisms is proposed, in which a common aspect of many cyclic AMP-mediated processes is the regulation by cyclic AMP of filamentous protein function. The filamentous proteins would, by controlling some aspect of motility in the cell, provide the necessary and sufficient means to effect the cell response regulated by cyclic nucleotide levels. A further aim of this article is to bring attention to the emerging importance of filamentous proteins in biological sciences.     

Solid-state NMR [13C,15N] resonance assignments of the nucleotide-binding domain of a bacterial cyclic nucleotide-gated channel

Channels regulated by cyclic nucleotides are key signalling proteins in several biological pathways. The regulatory aspect is conferred by a C-terminal cyclic nucleotide-binding domain (CNBD). We report resonance assignments of the CNBD of a bacterial mlCNG channel obtained using 2D and 3D solid-state NMR under Magic-angle Spinning conditions. A secondary chemical shift analysis of the 141 residue protein suggests a three-dimensional fold seen in earlier X-ray and solution-state NMR work and points to spectroscopic polymorphism for a selected set of resonances.     

INTERRELATIONSHIPS AMONG THE LEVELS OF ATP, ADENOSINE AND CYCLIC AMP IN INCUBATED SLICES OF GUINEA-PIG CEREBRAL CORTEX: EFFECTS OF DEPOLARIZING AGENTS, PSYCHOTROPIC DRUGS AND METABOLIC INHIBITORS

—Adenine nucleotides of guinea-pig cerebral cortical slices were labelled during a 40 min incubation with [¹⁴C]adenine. Subsequent incubation of cortical slices with depolarizing agents, such as veratridine, ouabain, batrachotoxin and high concentrations of potassium ions, or with certain psychotropic drugs such as chlorpromazine, chlorimipramine or prenylamine resulted in a reduction in both endogenous and radioactive ATP, accompanied by a marked increase in levels of both endogenous and radioactive cyclic AMP. Reduction of ATP levels during incubation with depolarizing agents, such as veratridine, is probably associated with increased activity of membranal Na⁺-K⁺-activated ATPase, while the reduction elicited by psychotropic drugs is proposed to be due to inhibition of mitochondrial synthesis of ATP. With both classes of compounds reduction of ATP levels results in enhanced formation and efflux of adenosine which stimulates formation of cyclic AMP from intracellular ATP in the compartments of brain slices which contain the cyclic AMP-generating systems. Certain classical metabolic inhibitors such as 2,4-dinitrophenol, azide, 1,2-naphthoquinone-8-sulfonate and cyanide also reduce ATP levels and in the case of 2,4-dinitrophenol, cyanide, and azide elicit small but significant accumulations of cyclic AMP. With certain metabolic inhibitors reduction of ATP within the cyclic AMP generating compartments would appear to prevent or reduce the accumulation of cyclic AMP elicited by amines, adenosine or veratridine.     

Cyclic nucleotide levels during carbachol-induced smooth muscle contractions.

Cyclic nucleotide levels and tension were measured at various times during carbachol-induced smooth muscle contractions. Cyclic GMP levels were markedly increased during contractions of rat vas deferens, guinea pig myometrium and guinea pig taenia coli, but were unchanged during contractions of rat uterus or guinea pig ileum. No significant changes in cyclic GMP levels could be detected in estrogen-primed rat uteri at any of the times or drug concentrations studied. Even in tissues in which large increases in cyclic GMP levels could be detected during carbachol-induced contractions (i.e. guinea pig myometrium and taenia coli) the contractions appeared to precede the cyclic GMP increases by several seconds. No significant changes in cyclic AMP levels were observed during carbachol-induced contractions in any of the smooth muscles studied. Thus, changes in tissue levels of the cyclic nucleotides do not appear to be responsible for the initiation of carbachol-induced smooth muscle contractions.     

Use of nucleotide photoaffinity probes to study hormone action

It has been clearly shown that the action of several hormones is differentially mediated intracellularly by nucleotides containing either adenosine or guanosine base units. To study the protein-nucleotide interactions involved in several complex biological systems our laboratory has synthesized several 8-azido-adenosine (8-N3 A) and 8-azidoguanosine (8-N3 G) derivatives of naturally occurring nucleotides. Modification of the nucleotides in the 8-position of the purine ring was done because: a) 8-substituted derivatives of cAMP and cGMP activated their respective protein kinases at physiological concentrations and were much less susceptible to hydrolysis by specific phosphodiesterases (PDE's) and b) substitution at the 8-position was much less likely to disturb the preferential and selective binding of adenosine versus guanosine nucleotides by enzymes that are specifically regulated by such interactions. This would allow studies of guanosine nucleotide specific binding in the presence of both adenosine nucleotides and adenosine nucleotide binding proteins, and vice-versa. In general, such has been the case and [32P] 8-N3 cAMP and [32P] 8-N3 cGMP have been used effectively to study their respectively activated protein kinases in several systems. Also, [32P] 8-N3 ATP has been used to study several ATPases and kinases while [gamma 32P] 8-N3 GTP has been shown effective for studies on tubulin and the G-regulatory protein (G/N) of adenylyl cyclase (A.C.). Several observations suggest that there must be important physical and energetic tie-ins between external hormone binding and the loading and unloading of specific internal nucleotide binding sites. These binding sites may be activator signals for protein kinases (e.g., cAMP protein kinase regulatory subunit), or cyclases (e.g., G/N proteins of A.C.) or catalytic sites involved in the production or hydrolysis of cyclic nucleotides. The thrust of this article is to detail the use of 8-azidopurine photoaffinity analogs of ATP, GTP, cAMP and cGMP as they may be used to study hormone-mediated events which may or may not involve cyclic nucleotides as a second messenger.     

Binding of cyclic AMP and cyclic GMP to renal cortical homogenates. Relationship with phosphorylation

This study examined the binding of both cyclic AMP and cyclic GMP to receptor proteins in particulate and soluble subfractions of renal cortical homogenates from the golden hamster. The binding of both nucleotides was compared to subsequent effects of both nucleotides on the phosphorylation of histone from identical fractions. Cyclic AMP binding and cyclic AMP-dependent protein kinase activity predominated in the cytosol, with some binding and enzyme activity also detected in particulate fractions. Cyclic GMP and cyclic GMP-dependent protein kinase activity could only be demonstrated in cytosolic fractions and represented only 20-30% of cyclic AMP-dependent activity in this fraction. Binding of both nucleotides was highly specific, however, cyclic AMP showed some interaction with cyclic GMP binding. Evidence suggesting that each nucleotide interacts with a specific protein kinase was as follows: both the binding activity of the cyclic nucleotides and their combined protein kinase activity show additivity; cyclic AMP and cyclic GMP binding activity could be separated on sucrose gradients; cyclic AMP and cyclic GMP protein kinase activity could be separated with Sephadex G-100 chromatography, after preincubation of homogenate supernatants with either cyclic AMP or cyclic GMP. The results demonstrate the presence of both cyclic AMP- and cyclic GMP-dependent protein kinase in renal cortex.     

Analysis of Chaperone Function and Formation of Hetero-oligomeric Complexes of Hsp18.1 and Hsp17.7, Representing Two Different Cytoplasmic sHSP Classes in Pisum sativum

Small heat shock proteins (sHSPs) are the most abundant stress proteins in plants. Usually not expressed under permissive conditions, they can accumulate to more than 2% of the total cellular protein content during heat stress. At present several points of evidence indicate that these proteins act as molecular chaperones by keeping partially denatured proteins in a folding-competent state. In plants sHSPs are encoded by a multigene family, which can be segregated into several classes according to their subcellular position and/or sequence homology. Curiously, two different classes appear in the cytoplasm. Their specific role during heat shock remains elusive. Here we present some evidence that both classes of sHSPs enhance recovery of reporter protein activity in the presence of HSP70. Applying peptide arrays prepared by SPOT synthesis and in situ analysis by confocal laser scanning microscopy, we could further show that the two classes of sHSP are attached to each other and are able to interact with non-native proteins both in vivo and in vitro. Although both of the sHSPs act similarly as molecular chaperones, immunohistochemistry experiments support the hypothesis that the two have different cellular functions in the development of heat-induced cytoplasmic heat shock granules under elevated temperatures. Daniela Wagner Deceased 24 Feburary 2004.     

Cyclic adenosine-3',5'-phosphate and guanosine-3',5'-phosphate in mouse plasma during administration of chemical compounds with different degrees of radioprotective effectiveness

A study was made of seven radioprotective agents of different chemical classes (sulfur-containing, indolylalkylamines, and imidazol, urea and pyridasine derivatives) and also of their six structural analogs without radioprotective properties on the content of cyclic nucleotides in blood plasma and on the postirradiation survival of mice. There was a correlation between the ability of the preparations to increase the level of cyclic adenosine-3',5'-monophosphate and their radioprotective properties; with guanosine-3',5'-monophosphate, this correlation was absent.     

Multiple protein kinases from Trypanosoma gambiense.

Three protein kinases were distinguished in Trypanosoma gambiense extract. The enzymes preferred phosvitin, histone, and protamine as acceptor proteins, respectively. The amino acid residues of the acceptor proteins which were phosphorylated by these protein-kinase activities were serine and- to less extent- threonine. The protein kinase activities were neither affected by cyclic nucleotides nor by cyclic AMP receptors. The molecular weights of these protein kinases were determined to be greater than 200,000, 95000 and 37000, respectively. The activities of all three protein kinases were affected to varying degrees by nucleotides and nucleosides.     

Separation of cyclic AMP and cyclic GMP from thymidine,electrolytes and polyvalent nucleotides in tissue samples

Cyclic AMP and cyclic GMP can be separated from thymidine and its possible metabolites, electrolytes, and polyvalent nucleotides using columns of acidic alumina. Electrolytes and thymidine are not adsorbed on acidic alumina at pH 4.4 while cyclic nucleotides and polyvalent nucleotides are adsorbed at this pH. Cyclic AMP and cyclic GMP are eluted together from acidic alumina with 0.2 M ammonium formate (pH 6.0) and the polyvalent nucleotides remain adsorbed. The cyclic nucleotides are separated by chromatography on Dowex AG 1 X 8 resin. Recovery is 60–64% for cyclic AMP and cyclic GMP isolated from renal tissue samples. This methodology permits the separation of tritiated thymidine from cyclic nucleotides which are present in tissue preparations used in studies on the role of cyclic nucleotides in cellular growth.     

Capturing cyclic nucleotides in action: snapshots from crystallographic studies

Fifty years ago, cyclic AMP was discovered as a second messenger of hormone action, heralding the age of signal transduction. Many cellular processes were found to be regulated by cAMP and the related cyclic GMP. Cyclic nucleotides function by binding to and activating their effectors - protein kinase A, protein kinase G, cyclic-nucleotide-regulated ion channels and the guanine nucleotide-exchange factor Epac. Recent structural insights have now made it possible to propose a general structural mechanism for how cyclic nucleotides regulate these proteins.     

Separation of cyclic AMP and cyclic GMP from thymidine, electrolytes and polyvalent nucleotides in tissue samples.

Cyclic AMP and cyclic GMP can be separated from thymidine and its possible metabolites, electrolytes, and polyvalent nucleotides using columns of acidic alumina. Electrolytes and thymidine are not adsorbed on acidic alumina at pH 4.4 while cyclic nucleotides and polyvalent nucleotides are adsorbed at this pH. Cyclic AMP and cyclic GMP are eluted together from acidic alumina with 0.2 M ammonium formate (pH 6.0) and the polyvalent nucleotides remain adsorbed. The cyclic nucleotides are separated by chromatography on Dowex AG 1 X 8 resin. Recovery is 60--64% for cyclic AMP and cyclic GMP isolated from renal tissue samples. This methodology permits the separation of tritiated thymidine from cyclic nucleotides which are present in tissue preparations used in studies on the role of cyclic nucleotides in cellular growth.     

Changes in cyclic nucleotide profiles in proliferating multi-cell spheroids

The intracellular concentration of cyclic adenosine 3':5'-mono-phosphate (cAMP) has been shown to be related to each developmental phase of the cell cycle. Highest levels of this nucleotide are evident during the S-phase (the DNA synthetic phase) which has also been shown to be radiation-sensitive. The relationship between the levels of cyclic nucleotides, cAMP and guanosine 3':5'-monophosphate (cGMP), and the proliferation of cells in a tumor model system was investigated using V79-171b Chinese hamster lung cells grown both as monolayer and as three dimensional cell clusters (spheroids). The spheroid which is more radiation-resistant than its monolayer counterpart, has been used by many radiobiologists as an in vitro tumor model. Our results indicate that the yin-yang hypothesis of a opposing regulatory relation between the two different classes of cyclic nucleotides only held true for monolayer cultures (both exponential and plateau phase) but could not be demonstrated in the tumor model where the levels of both nucleotides increased directly with the diameter of the growing spheroid mass.