Cloning of Calmodulin Gene of Pea (Pisum sativum) by PCR and Comparison of Its Coding Sequences in Different Speices

Using the oligo nucleotides of both ends of barley (Hordeum vulgare L. ) calmodulin structural gene as primers, pea (Pisum sativurn L. ) calmodulin gene (CAM) was synthesized from RNA derived cDNA first strand through PCR before it was actually cloned and sequenced. Compared with CaMs of alfafa ( Medicago sativa L. ), rice ( Oryza sativa L. ), barley ( Hordeurn vulgate L. ), eel electroplax ( Electrophoridae ), Aspergillus nidulans and yeast ( Saccharomyces cerevisiae ), it has homology of 91.3% –60. 8%, while the change between C and T at corresponding position in pea CaM can often be observed. Analysis of the seven CaMs shows that some of them have one or two dominant nucleotide change pattern,their codon bias is also different.     

Biochemical properties of sodium channels in a wide range of excitable tissues studied with site-directed antibodies

Antibodies against a peptide (SP19) corresponding to a highly conserved, predicted intracellular region of the sodium channel alpha subunit bind rat brain sodium channels with a similar affinity as the peptide antigen, indicating that the corresponding segment of the alpha subunit is fully accessible in the intact channel structure. These antibodies recognize sodium channel alpha subunits from rat or eel brain, rat skeletal muscle, rat heart, eel electroplax, and locust nervous system. alpha subunits from all these tissues except rat skeletal muscle are substrates for phosphorylation by cAMP-dependent protein kinase. Disulfide linkage of alpha and beta 2 subunits was observed for both the RI and RII subtypes of rat brain sodium channels and for sodium channels from eel brain but not for sodium channels from rat heart, eel electroplax, or locust nerve cord. Treatment with neuraminidase reduced the apparent molecular weight of sodium channel alpha subunits from rat and eel brain and eel electroplax by 22,000-58,000, those from heart by 8000, and those from locust nerve cord by less than 4000. Our results provide the first identification of sodium channel alpha subunits from rat heart and locust brain and nerve cord and show that sodium channel alpha subunits are expressed with different subunit associations and posttranslational modifications in different excitable tissues.     

Isolation and purification of calcium-binding protein from electroplax of Electrophorus electricus.

An acidic calcium-binding phosphoprotein has been isolated from a cholinergic tissue, electroplax from Electrophorus electricus. The purification procedures included (NH4)2SO4 fractionation, boiling treatment, ECTEOLA-cellulose chromatography, and gel filtration on Sephadex G-100. Experiments were performed to compare this protein and a calcium-binding protein isolated from mammalian brain, adrenal medulla, and testis. These experiments showed that the two proteins were identical in terms of molecular weight (14 000), calcium-binding dissociation constant (kd=2.1-10(-5) M), electrophoretic mobility at pH 8.7 in 15% polyacrylamide gels, and phosphorus content (1 mol phosphorus per mol protein). In addition, the two proteins had similar amino acid compositions and peptide maps. Although the electroplax protein was not present in eel skeletal muscle, preliminary experiments indicated that small amounts of the protein were present in other eel tissues, namely brain, liver and spleen. These results suggest an identity between the electroplax and mammalian calcium-binding proteins and extend the findind of comparatively large amounts of the protein from mammalian nervous tissue to a cholinergic nervous tissue, electroplax. The close similarity of the proteins suggests a conservation of structure during evolution which may be required to fulfill a role in neuronal function.     

Fusion of native or reconstituted membranes to liposomes, optimized for single channel recording.

We here describe a protocol for fusing vesicles into large structures suitable for patch clamp recording. The method may be used with native membrane vesicles or with liposomes containing reconstituted/purified ion channels. The resulting unilamellar membranes exhibit high channel surface abundance, yielding multiple channels in the average excised patch. The procedure has been used to record voltage-sensitive Na channels from three native membrane preparations (eel electroplax, rat skeletal muscle, squid optic nerve), and from reconstituted protein purified from eel electroplax. Channels treated with batrachotoxin (BTX) displayed characteristic activation voltage dependence, conductances, selectivity, and sensitivity to saxitoxin (STX).     

A comparison of eel electroplax and snake venom acetylcholinesterase

The effects of some cholinergic ligands, harmala alkaloids and local anesthetics on the activity of eel electroplax and Naja naja siamensis venom acetylcholinesterase have been studied. In most cases, eel electroplax was found to be more susceptible towards inhibition than the venom acetylcholinesterase. No major difference was observed with respect to the type of inhibition in both enzymes. The activation of the two enzyme preparations by inorganic cations (Ca2+, Mg2+ and Na+) showed a similar pattern. In both preparations, the onset of activation was detectable at much lower concentration with the divalent metal ions than with the monovalent Na+. Antagonism between Ca2+ and decamethonium, tubocurarine and tetracaine in both enzymes approached competitive kinetics. The onset of substrate inhibition is delayed by Ca2+ (30 mM) in both enzymes. It is suggested that the Ca2+ binding site overlaps with the substrate inhibitory site. It is concluded that cobra venom acetylcholinesterase has similar allosteric binding sites to those of eel electroplax.     

Studies on a reconstituted acetylcholine receptor system: effect of agonists

An impure preparation of acetylcholinesterase from electroplax of the electric eel can be incorporated into a bimolecular lipid membrane. The acetylcholinesterase-modified bimolecular lipid membrane shows a concentration-dependent increase in membrane conductance elicited by several agonists (acetylcholine, carbamylcholine, phenyltrimethylammonium ion, tetraethylammonium ion, decamethonium ion, and nicotine) added to the compartment opposite that to which acetylcholinesterase was originally added. Affinity and efficacy of the various agonists in generating the conductance increase were measured from dose-response curves; these are in good quantitative agreement with corresponding values observed for depolarization of intact eel electroplax. The ion conduction pathways induced by agonists in the modified bimolecular lipid membrane show a slight cation selectivity, Na ? K > Cl (3:3:1), similar to that observed for the depolarized electroplax membrane. Evidence is presented that suggests that some components other than acetylcholinesterase induce the acetylcholine receptor response in the bimolecular lipid membrane.     

Isologous Oxygen,Sulfur, and Selenium Compounds as Probes of Acetylcholine Receptors

Evidence is presented that while the conformations of acetylcholine and acetylthiolcholine are different, acetylthiolcholine and acetylselenolcholine are structurally and conformationally very similar. Experiments with sulfur and selenium isologs of acetylcholine, choline, and local anesthetics suggest that the active sites of receptors of the electroplax and of electric eel acetylcholinesterase are different, but are compatible with the postulate that acetylcholine receptors of axonal and synaptic excitable membranes are similar.     

Neurotoxin-modulated uptake of sodium by highly purified preparations of the electroplax tetrodotoxin-binding glycopeptide reconstituted into lipid vesicles

Summary Using the dialysable detergent CHAPS (3-[(3-cholamidopropyl)-dimethylammonio]-1-propane sulfonate), the tetrodotoxin-binding protein from the electroplax of the electric eel has been purified to a high degree of both chemical homogeneity and toxin-binding activity. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the best preparations showed only a single microheterogeneous band atM _r approximately 260,000, despite attempts to visualize smaller bands by sample overloading. Upon dialysis, this material became incorporated into the membranes of small unilamellar vesicles, and in this form the purified protein exhibited tetrodotoxin-binding properties similar to the component in the original electroplax membrane. Furthermore, in the presence of activator neurotoxins the vesicles were able to accumulate isotopic sodium in a manner similar to that previously described for less active or less pure preparations of vesicles containing either mammalian or eel electroplax toxinbinding proteins. Quantitative consideration of the isotopic transport activity of this pure material, along with the high degree of purity of the protein, strongly suggests that the 260-kDa glycopeptide from electroplax is necessary and sufficient to account for the sodium channel function seen in these studies, and eliminates the possible involvement of smaller peptides in the channel phenomena observed.     

Abnormal expression of the calmodulin gene in muscle from the dystrophic chicken

Compared to that of genetically-related normal chickens, pectoralis muscle from the dystrophic chicken contained increased calmodulin measured by radioimmunoassay. Determined by the dot blot procedure, expression of the calmodulin gene was enhanced in muscle from affected animals. The bioactivity of the gene product was normal. Together with previous studies reporting increased cell Ca2+ content in dystrophic muscle, the current findings of increased sarcoplasmic calmodulin suggest the latter is a cellular response to defective Ca2+ transport at the level of cell efflux or intracellular organelle (sarcoplasmic reticulum) uptake.     

Alpha-(2----8)-polysialic acid immunoreactivity in voltage-sensitive sodium channel of eel electric organ

The voltage-sensitive sodium channel from eel electroplax is formed of a polypeptide of 208,321 Da, to which is attached ca. 85 kDa of carbohydrate. Sialic acid is a prominent constituent, contributing ca. 113 negative charges to the protein surface. We here demonstrate that antibodies raised against the bacterial antigen alpha-(2----8)-polysialic acid, specific for polymers of ten or more consecutive sialic acid residues, react specifically and with high affinity to the electroplax sodium channel. In extracts of electroplax membranes, the sodium channel is the only protein that demonstrates this immunoreactivity, suggesting the presence of a polysialosyl-sialyltransferase specifically committed to this unique post-translational modification of the sodium channel. Polysialic acid is rare in vertebrates, having previously been found only associated with neural-cell adhesion molecules, present in the developing neuromuscular system. The other prominent source is the capsular polysaccharide of highly pathogenic meningitis bacteria. Antibodies to the bacterial antigen thus provide highly specific affinity markers for the sodium channel. The high avidity of these antibodies and the ratio of sialic acid residues to consensus glycosylation sites suggest that the terminal chains are well over ten sialosyl residues in length, potentially extending 10-30 nm into the extracellular environment.     

Molecular Cloning and Characterization of a Calmodulin Gene from Arabidopsis thaliana

The calcium binding protein, calmodulin Is involved in regulating various cellular and biochemical processes. A gene tor calmodulin (CaM) has been Isolated from a genomic library of Arabidopsis thaliana constructed in ; EMBL-4 using a heterologous cDNA probe from electric eel. One of the positive clones was characterized and the region containing the calmodulin gene sequences was Identified, excised using appropriate restriction enzymes and subcloned Into a plasmid vector. The genomic clone contains a complete copy of the calmodulin gene. A comparison of the nucleotide sequence of the part of the clone with those of the other plant and animal systems confirms that the clone In fact contains the calmodulin gene sequences. Southern hybridization ulling the calmodulin gene sequences as a probe reveals the presence of more than one copy of the calmodulin gene. The results of this investigation taken together with those Iff the other. indicate that the calmodulin gene belongs to a small mutigene family consisting of atieast four member. In the Arabidopsis genome.     

Veratridine modification of the purified sodium channel alpha- polypeptide from eel electroplax

In the interest of continuing structure-function studies, highly purified sodium channel preparations from the eel electroplax were incorporated into planar lipid bilayers in the presence of veratridine. This lipoglycoprotein originates from muscle-derived tissue and consists of a single polypeptide. In this study it is shown to have properties analogous to sodium channels from another muscle tissue (Garber, S. S., and C. Miller. 1987. Journal of General Physiology. 89:459-480), which have an additional protein subunit. However, significant qualitative and quantitative differences were noted. Comparison of veratridine-modified with batrachotoxin-modified eel sodium channels revealed common properties. Tetrodotoxin blocked the channels in a voltage-dependent manner indistinguishable from that found for batrachotoxin-modified channels. Veratridine-modified channels exhibited a range of single-channel conductance and subconductance states. The selectivity of the veratridine-modified sodium channels for sodium vs. potassium ranged from 6-8 in reversal potential measurements, while conductance ratios ranged from 12-15. This is similar to BTX-modified eel channels, though the latter show a predominant single-channel conductance twice as large. In contrast to batrachotoxin-modified channels, the fractional open times of these channels had a shallow voltage dependence which, however, was similar to that of the slow interaction between veratridine and sodium channels in voltage-clamped biological membranes. Implications for sodium channel structure are discussed.     

Beta 1 subunits of sodium channels. Studies with subunit-specific antibodies

The purified Na+ channel from rat brain consists of alpha (260 kDa), beta 1 (36 kDa), and beta 2 (33 kDa) subunits. Pure beta 1 subunits were prepared from purified rat brain Na+ channels which had been adsorbed to hydroxylapatite resin and used to prepare specific anti-beta 1 subunit antiserum. Antibodies purified from this antiserum by antigen affinity chromatography immunoprecipitate 125I-labeled, purified beta 1 subunits and purified Na+ channels (measured as high affinity [3H] saxitoxin binding sites) and recognize beta 1 subunits on immunoblots of solubilized rat brain membranes. The affinity-purified anti-beta 1 antibodies recognize beta 1 subunits in rat spinal cord, heart, skeletal muscle, and sciatic nerve, but do not detect immunoreactive beta 1 subunits in eel electroplax or eel brain. The developmental time course of expression of immunoreactive beta 1 subunits in rat forebrain was measured by immunoprecipitation followed by immunoblotting with affinity-purified anti-beta 1 antibodies. The amount of immunoreactive beta 1 subunits increased steadily to adult levels during the first 21 days of postnatal development.     

Detection of 180 kDa proteins in electroplax sodium channel preparations

• 1.1. Co-isolating proteins (M_r 170,000–220,000) from sodium channel preparations made from the electric organ of the electric eel (Electrophorus electricus) were detected on Western blots using monoclonal a antibodies.
• 2.2. Similar protein patterns were seen on immunoblots containing immunoprecipitated protein from eel muscle and brain tissues but not heart.
• 3.3. These co-isolating proteins could be separated from the mature TTX-sensitive channel protein (M_r 280,000) using a lentil lectin-Sepharose column.
• 4.4. The 180 kDa proteins do not appear to be channel-related and can be detected as contaminants in electroplax sodium channel preparations using the monoclonal antibodies described here.

     

The large subunit of (sodium + potassium)-activated adenosine triphosphatase from the electroplax of Electrophorus electricus is a glycoprotein.

The large subunit of Na,K-ATPase purified from eel electroplax was found to contain amino sugars, neutral sugars and sialic acid. The concentration of these carbohydrates in the large subunit was 5–10% of that found in the smaller subunit and in total accounts for 2.6% of the mass of the large subunit. The periodic acid-Schiff's stain for glycoproteins on polyacrylamide gels is apparently not sufficiently sensitive to detect glycoproteins with these low levels of carbohydrates.     

Action of derivatives of mu-conotoxin GIIIA on sodium channels. Single amino acid substitutions in the toxin separately affect association and dissociation rates.

We have studied binding and block of sodium channels by 12 derivatives of the 22-residue peptide mu-conotoxin GIIIA (mu-CTX) in which single amino acids were substituted as follows: Arg or Lys by Gln, Gln-18 by Lys, Asp by Asn, and HO-Pro by Pro. Derivatives were synthesized as described by Becker et al. [(1989) Eur. J. Biochem. 185, 79]. Binding was measured by displacement of labeled saxitoxin from eel electroplax membranes (100 mM choline chloride, 10 mM HEPES-NaOH, pH 7.4). Blocking kinetics were evaluated from steady-state, single-channel recordings from rat skeletal muscle sodium channels incorporated into planar, neutral phospholipid/decane bilayers (200 mM NaCl, 10 mM HEPES-NaOH, pH 7.0). Blocking events generally appeared as periods of seconds to minutes in which current through the single channel was completely eliminated. A notable exception was seen for the substitution Arg-13-Gln for which the "blocked" events showed measurable conductances of about 20-40% of the open state. The substitution of Arg-13 reduced binding to electroplax membranes to undetectable levels and increased the apparent dissociation constant determined for skeletal muscle channels by greater than 80-fold compared with the native peptide. Other substitutions caused smaller decreases in affinity. The decreased potency of the toxin derivatives resulted both from increases in the rates of dissociation from the channel, and from decreases in association rates. Our data support the suggestion by Sato et al. [(1991) J. Biol. Chem. 265, 16989] that Arg-13 associates intimately with the binding site on the channel. In addition, our results suggest that certain residues affect almost exclusively the approach and docking of the toxin with its binding site, others appear to be important only to the strength of the association once binding has taken place, and yet others affect both.