Carole J. Coffee

Isolation of heat-stable glucocerebrosidase activators from the spleens of three variants of Gaucher's disease.

Abstract Heat-stable glycoprotein activator substances which stimulate the activity of human liver glucocerebroside:β-glucosidase have been purified extensively from the spleens of five patients representing the clinical extremes of Gauchers disease ranging from the acute neuropathic form (type 2) to the adult, chronic nonneuropathic form (type 1). Each preparation of Gaucher factor chromatographed as a single coincident peak of protein and activator activity on Sephadex G-150 and each electrophoresed as a single protein band of molecular weight approximately 10,000–12,000 on disc gels in the presence of sodium dodecyl sulfate. With the exception of one preparation, which contained 7.1% carbohydrate, the activator substances contained approximately 17% carbohydrate. The various factors have similar, but not identical, amino acid compositions and are rich in acidic and hydrophobic amino acids. The yield of activator substance ranged from 12.9 to 27.4 mg of protein per 100 g wet wt of tissue, with the highest and lowest yields being obtained from the spleens of two patients with the intermediate form of Gauchers disease. The amount of glucocerebroside:β-glucosidase-stimulating activity obtained from the spleens of adult and infantile patients was similar. In addition, the purified heat-stable factors from the Gaucher spleens were capable of stimulating the hydrolysis of the galactose-containing ganglioside, G M1 , by a partially purified preparation of human liver β-galactosidase. This study documents the presence of a factor that will stimulate the activity of glucocerebroside:β-glucosidase and β-galactosidase in Gaucher spleens but fails to indicate any correlation between the concentration or activity of the stimulatory substances and the extent of pathology or age of onset of the disease; the spleens of patients with the more severe forms of Gauchers disease do not contain the lowest amounts of stimulatory activity.

The Coordination of Calcium Ions by Carp Muscle Calcium Binding Proteins A, B and C

The white muscle of fish and amphibia contain a group of closely related, low molecular weight parvalbumins which bind two calcium ions per protein molecule. Because of this distinguishing property, they have been designated muscle calcium binding proteins (MCBP) (1,6,13,14,16). As can be seen in Table I, which summarizes their properties, they are quite acidic and contain relatively high proportions of alanine and phenylalanine. In addition, they possess acetylated amino termini and are highly antigenic.

Purification and characterization of a troponin C-like phosphodiesterase activator from bovine thyroid.

A troponin C-like phosphodiesterase activator from bovine thyroid has been purified to homogeneity. The overall purification was about 9,800-fold with a yield of 8%. Bovine thyroid activator protein is identical in biologic properties to that isolated from bovine brain. They have the same specific activity regarding stimulation of bovine brain cyclic nucleotide phosphodiesterase. Both proteins form a Ca2+-dependent complex with heart muscle troponin I which is stable in 6M urea-polyacrylamide gel and which is similar, but not identical, to the troponin C-troponin I complex. The physiochemical properties of bovine thyroid activator protein are identical with those of bovine brain and other phosphodiesterase activator proteins and are similar to heart muscle and skeletal muscle troponin C as follows: (A) they bind 3-4 exchangeable calcium ions/mol with dissociation constants between 10(-5) and 10(-6) M, (B) they are highly acidic with a high content of aspartic and glutamic acids and isoelectric points of approximately 4.1, (C) these proteins have an unusual ultraviolet absorption spectrum with six discrete maxima between 250 and 284 nm which are characteristic of phenylalanine and tyrosine, and (D) these proteins have a low content of cysteine, histidine, tyrosine and proline. The tryptic peptide maps of bovine thyroid and brain activator protein are very similar. However, despite a very similar amino acid composition, the peptide map of bovine heart muscle troponin C is significantly different from that of the other two proteins. The molecular weight of thyroid and brain activator protein is 16,500, while that of heart troponin C is 18,500. Thyroid and brain activator protein, as well as heart troponin C, appear to undergo significant Ca2+-dependent conformational changes, as measured by the difference in the circular dichroism spectrum and electrophoretic mobility observed in the presence and absence of calcium ion.

Preparation and properties of carp muscle parvalbumin fragments A (residues 1 å 75) and B (residues 76 å 108)

Abstract The calcium-binding protein (parvalbumin), isolated from carp (Cyprinus carpio) muscle, has been specifically fragmented into two polypeptides by tryptic hydrolysis at the single arginine residue at position 75. Fragment A contains residues 1 a 75 and fragment B is composed of residues 76 a 108 . The fragments have been characterized according to size, amino acid composition, carboxyl- and amino-terminal analysis. Both fragments appear to be homogeneous by these criteria. The intact protein is known to bind 2 mol of calcium per mol of parvalbumin, and although each fragment alone contains all of the essential ligands for the coordination of one Ca 2− , neither fragment displays calcium binding activity. Attempts to reconstitute the two fragments, under a variety of conditions, into a functional complex which can bind calcium have been unsuccessful. The side chain of Arg-75 is known to occupy an internal position in the crystalline structure of parvalbumin (Kretsinger, R.H. and Nockolds, C.E. (1973) J. Biol. Chem. 248, 3313), where it is stabilized by an intricate network of hydrogen bonding involving the side chain of Glu-81. Although this internal salt bridge is approx. 20 A from either calcium binding site, it has been suggested that this structural feature of the molecule plays an essential role in the reversible binding of Ca 2+ . That the side chain of Arg-75 likewise occupies an internal position in the solution structure is indicated by its unavailability for reaction with 1,2-cyclohexanedione under conditions of physiological pH and temperature. However in the presence of EDTA and at pH 8, it is readily modified by cyclohexanedione. This modification is accompanied by a concomitant loss in calcium binding activity. Reversal of the modification by treatment with hydroxylamine is accompanied by restoration of calcium binding activity. The sum of these data support the hypothesis that Arg-75 plays a critical role in the structural organization and calcium binding activity of the molecule, and in addition, suggests that the integrity of the peptide bond between Arg-75 and Ala-76 may be necessary for establishing the proper microenvironment required for formation of the internal salt bridge between Arg-75 and Glu-81.

The subcellular localization of calmodulin, cyclic AMP phosphodiesterase, and adenylate cyclase in bovine adrenal medulla.

The subcellular localization of calmodulin, cyclic nucleotide phosphodiesterase, and adenylate cyclase was studied in bovine adrenal medulla. Approximately 70% of the calmodulin and 90% of the cAMP phosphodiesterase activities were found colocalized in the cytoplasm. The subcellular distribution of adenylate cyclase closely paralleled the distribution of acetylcholinesterase, a marker for plasma membranes. The fraction of calmodulin which is particulate in nature has a distribution profile very similar to that of adenylate cyclase. The chromaffin granule fraction contained only 0.86% of the total cAMP phosphodiesterase, 0.41% of the total adenylate cyclase, and 1.4% of the total calmodulin.

Comparison of AMP deaminase from skeletal muscle of acidotic and normal rats

The deamination of AMP by AMP aminohydrolase (EC 3.5.4.6.) serves as the major source of ammonia production in skeletal muscle. It has been suggested that the ammonia may serve either in a buffering capacity to combat acidosis due to the accumulation of lactic acid produced during prolonged muscular activity, or as a substrate for glutamine formation which can ultimately be utilized by the kidney in adapting to metabolic acidosis. In view of this proposal, the properties of the enzyme obtained from skeletal muscle of acidotic rats have been compared with the enzyme from normal muscle. The specific activity of AMP deaminase in crude homogenates of acidotic muscle was not significantly different from normal levels. The enzyme from acidotic muscle was purified to homogeneity and was found to be identical to the enzyme obtained from normal muscle by the criteria of electrophoretic mobility, pH optimum, molecular weight, sedimentation coefficient, subunit composition, amino acid composition, monovalent cation requirement, substrate saturation, and inhibition by ATP, Pi and creatine-P. Thus, if the enzyme functions to prevent acidosis, the ability to respond to changes in the intracellular environment which accompany acidosis must be built into the structure of the enzyme normally found in skeletal muscle. Three lines of evidence strongly support this viewpoint: (a) the rate of deamination is approximately 2-fold higher at pH 6.5 than at pH 7.0, (b) the activity increases linearly with a decrease in the adenylate energy charge, and (c) within the normal physiological range of the adenylate energy charge, the enzyme is operating at only 10--20% of its maximum capacity.

Comparison of the carbohydrate and amino acid composition of normal and S-variant α-1-antitrypsin

alpha-1-Antitrypsin has been isolated and purified from the serum of an individual with the Pi S phenotype whose serum contains only 50--60% as much alpha-1-antitrypsin as normal M-type serum. The preparation was homogeneous by the criteria of sodium dodecyl sulfate polyacrylamide gel electrophoresis and sedimentation equilibrium ultracentrigufation. When analyzed in the ultracentrifuge, the S-type alpha-1-antitrypsin exhibited a molecular weight of 47,500 which was essentially the same as that of the M-type (47,300) and the Z-type (47,500) alpha-1-antitrypsin. The S-type alpha-1-antitrypsin contains 15.2% carbohydrate consisting of 16.4 residues/mol of N-acetylglucosamine, 7.8 residues/mol of mannose. 6.7 residues/mol of galactose and 7.1 residues/mol of sialic acid which is essentially the same as the carbohydrate composition of the M-type alpha-1-antitrypsin. In addition, M- and S-type alpha-1-antitrypsin have very similar amino acid compositions.

The identification and characterization of two cyclic nucleotide phosphodiesterases from bovine adrenal medulla

Two soluble cyclic nucleotide phosphodiesterase activities, designated Peak I (Mr = 216,000) and Peak II (Mr = 230,000), have been isolated from bovine adrenal medulla by DEAE-cellulose chromatography. Peak I has Ca2+-independent, cGMP-specific phosphodiesterase activity and Peak II has cGMP-stimulated cyclic nucleotide phosphodiesterase activity. Peak I hydrolyzes cGMP with hyperbolic kinetics and demonstrates a Km of 23 microM. Peak II hydrolyzes cGMP with hyperbolic kinetics but hydrolyzes cAMP with slightly sigmoidal kinetics and demonstrates Km values of 54 +/- 0.7 microM cGMP and 38 +/- 6 microM cAMP. Cyclic AMP and cGMP are competitive inhibitors of each others hydrolysis, suggesting that these nucleotides may be hydrolyzed at the same catalytic site. Micromolar concentrations of cGMP cause a 5-fold stimulation of the hydrolysis of subsaturating concentrations of cAMP by the Peak II phosphodiesterase. Half-maximal activation occurs at 0.5 microM cGMP and the result of activation is a decrease in the apparent Km for cAMP. Stimulation of the hydrolysis of subsaturating concentrations of cGMP by cAMP was also detected; however, cAMP is a less potent activator of the enzyme than cGMP. Cyclic AMP causes a 1.5-fold stimulation of cGMP hydrolysis and half-maximal activation occurs at 2.5 microM cAMP.

A continuous spectrophotometric assay for cyclic 3',5'-nucleotide phosphodiesterase.

Abstract In the course of studies on cyclic nucleotide phosphodiesterase, the need for an assay which was both sensitive and continuous was realized. Most of the methods available for monitoring phosphodiesterase either depend on the use of accessory enzymes, and are accordingly subject to intrinsic limitations, or are not capable of continuously monitoring the enzymatic reaction. The present paper describes a new spectrophotometric assay for cyclic nucleotide phosphotidesterase which is highly reproducible, rapid, simple, and more sensitive than many of the previously published assays for this enzyme. The method is sensitive enough to detect the enzymatic conversion of 75 pmol of cAMP to 5′-AMP per minute. This assay is based on the fact that the hydrolysis of cyclic nucleotides to the corresponding 5′-phosphate ester by phosphodiesterase makes available an additional titratable proton of the 5′-phosphate group. By incorporating phenol red into the assay mixture, the rate of proton production can be continuously measured by monitoring the decrease in absorbance of the basic chromophore of phenol red at 560 nm. The primary advantages of the spectrophotometric assay described here are: (a) it provides initial velocity measurements, and thus is ideally suited to studying the kinetic properties of partially purified preparations of enzyme, and (b) it does not require the tedious and time-consuming purification of commercially available substrates which is often required when radioisotopic assays are used in detailed kinetic studies. The chief limitations are: (a) the sensitivity is not sufficient to accurately monitor the “low Km” enzyme, and (b) the use of the assay to quantitate revoveries throughout extensive purification, where different buffer salts at different pH values are used, would require that the enzyme be dialyzed prior to assay.

Characterization of myosin light-chain kinase from bovine adrenal medulla

Partially purified bovine adrenal medullary myosin light-chain kinase (MLCK) possesses a Stokes radius of 79 A and a sedimentation coefficient of 3.95 +/- 0.45 S, yielding a native molecular weight of 150,000 +/- 17,000 g/mol and a frictional ratio of 2.24. It catalyzes the phosphorylation of the isolated light chain of skeletal muscle myosin and the light chain of intact adrenal medullary myosin, but not phosphorylase b or histone. The activation of MLCK by calmodulin is specific and dose dependent, yielding a K0.5 value of 9.0 nM; the dose response curve with respect to free Ca2+ is biphasic, exhibiting a stimulatory phase at low free Ca2+ concentrations (K0.5 = 0.17 microM) and an inhibitory phase at higher free Ca2+ concentrations (400-3000 microM). Michaelis-Menten kinetics are observed for ATP, yielding a Km for ATP of 25 microM and a Vmax of 23.2 nmol/min/mg. However, positive cooperative kinetics are observed for the skeletal muscle myosin light chain, yielding a Hill coefficient of 3.57, a K0.5 for light chain of 27 microM and a Vmax of 16.6 nmol/min/mg. A stoichiometry of phosphorylation of approximately 1 mol of phosphate/mol of skeletal muscle myosin light chain was observed. Therefore, adrenal medullary MLCK is similar in most, but not all, of its physical and kinetics properties to MLCKs isolated from other sources and may serve to regulate actin-myosin contractile activity in the adrenal medulla.