The cerebroside sulfate activator from pig kidney: Derivitization,cerebroside sulfate binding,and metabolic correction

Highly purified cerebroside sulfate activator from pig kidneys was characterized by a number of chemical and biological procedures. Methods for chemical modifications were evaluated in an attempt to obtain biologically active derivatives. Iodination, dabsylation, and to a lesser degree reductive methylation provided useful products with good retention of cerebroside sulfate activator activity. Other procedures resulted in largely inactive derivatives or losses in both protein and biological activities. Attempts at renaturation of cerebroside sulfate activator subjected to various denaturing conditions appeared to be successful in many instances, but it was uncertain if the protein structure had actually been disrupted. The binding of cerebroside sulfate by activator was estimated by gel filtration under conditions similar to those of its assay. The formation of a relatively stable 1:1 complex was observed, collaborating results with the human protein. The complex was stable enough to be isolated and shown to be an efficient substrate for arylsulfatase A. The effectiveness of the pig kidney cerebroside sulfate activator for correcting the metabolic defect in activator-deficient human fibroblasts was compared with human materials. The pig kidney protein was taken up more efficiently by the cells and resulted in a better metabolic correction than material from human liver, but was somewhat less effective than a preparation from human urine.     

Alkaline phosphatase from pig kidney. Method of purification and molecular properties

Alkaline phosphatase (EC 3.1.3.1) from pig kidney brush-border membranes was solubilized from membrane precipitates by butan-1-ol at a critical pH of 7.0. The 12000-fold purification procedure included (NH₄)₂SO₄ precipitation, DEAE-and TEAE-cellulose chromatography, Sephadex G-200 gel filtration and neuraminidase digestion followed by DEAE-cellulose chromatography. The purified protein contained 20% (w/w) carbohydrate and had mol.wt. 150000–156000 as estimated by Sephadex filtration and ultracentrifuge analysis. It was a tetrameric glycoprotein consisting of identical subunits, and it had a molecular activity at 25°C of 2600s⁻¹ per tetramer. Its concentration in kidney was estimated to be 8.5–8.8mg/kg.     

The organization of the gene for the human cerebroside sulfate activator protein

The organization of 14 exons covering 97% of the cDNA sequence of human cerebroside sulfate activator protein precursor has been determined from two overlapping EMBL-4 human genomic clones extending over 17kb. All exons and exon/intron splice junctions and five introns were sequenced. Exon 8 consists of only 9 bp and is involved in alternative splicing which generates three different mRNAs of cerebroside sulfate activator precursor.     

The activator of cerebroside sulphatase. Lysosomal localization.

1) An activator protein necessary for the enzymic hydrolysis of cerebroside sulphate could be partially purified from unfractionated rat liver. This activator, which is similar to that of human origin, proved to be a heat-stable, non-dialyzable, low molecular weight protein with an isoelectric point of 4.1. Its activity could be destroyed by pronase. 2) For elucidation of the subcellular localization of the activator, rat liver was fractionated by differential centrifugation. The intracellular distribution of the cerebroside sulphatase activator was compared to the distribution patterns of marker enzymes for different cell organelles and found to coincide with the lysosomal arylsulphatase, thus indicating a lysosomal localization. 3) This was confirmed using highly purified secondary, i.e. iron-loaded, lysosomes. After disruption by osmotic shock, these organelles hydrolyzed cerebroside sulphate when incubations were performed under physiological conditions with endogenous as well as exogenous sulphatase A as enzyme. 4) After subfractionation of the disrupted secondary lysosomes into membrane and lysosol fractions by high speed centrifugation, it was found that the activator protein was exclusively associated with the lysosol, whereas the acid hydrolases were distributed differently between the two fractions. 5) The lysosol was further fractionated by semi-preparative electrophoresis on polyacrylamide gels. Two protein fractions were obtained: a high molecular weight fraction, containing the activator-free acid hydrolases, and a low molecular weight fraction, containing the enzyme-free activator of cerebroside sulphatase. 6) The significance of these findings for the hydrolysis of sphingolipids in the lysosomes is discussed.     

The activator of cerebroside sulphatase. Purification from human liver and identification as a protein.

1) A heat-stable activator of human sulphatase A (cerebroside sulphatase) was purified from human liver. It is required for the enzymatic degradation of cerebroside sulphates (sulphatides) in buffers (ionic strength greater than or equal 0.2) with osmolarity in the physiological range. 2) The purification steps involve extraction, acetone precipitation, heat treatment, isoelectric focusing and gel filtration. 3) Based on the definition of a specific activator unit, the purification of the final preparation was approximately 2000-fold over the acetone precipitation and several thousand-fold in the overall procedure. 4) The purified activator migrated as a single protein band when subjected to gel electrophoresis. Its effect was abolished after treatement with pronase E. The apparent molecular weight as determined by gel filtration was 21 500 +/- 1500; the isoelectric point was 4.3. 5) The activating effect of this protein factor and of taurodeoxycholate on cerebroside sulphatase activity was compared on a weight and molar basis.     

Diamine oxidase from pig kidney: new purification method and amino acid composition

Several methods for the isolation of apparently homogeneous pig kidney diamine oxidase have been reported in recent years (1-7), but these procedures allow to obtain only little amounts of material making very difficult the study of the molecular properties of the enzyme. Drawing useful indication from the purification procedures previously reported, we were able to set up a new method which allows to obtain homogeneous enzyme samples in high yield and with good reproducibility. This procedure allowed to determine with greater accuracy the molecular weight of the enzyme that resulted to be 170,000 daltons by gel chromatography and 145,000 by ultracentrifuge. The enzyme is composed of two apparently identical subunits and contains two copper atoms per dimer. The amino acid composition of the protein has been also worked out and found similar to those already reported for other copper dependent amine oxidases. Pig kidney diamine oxidase is a glycoprotein containing about 20% sugars by weight.     

On the subunit structure of particulate aminopeptidase from pig kidney.

Solubilization of particulate aminopeptidase (EC 3.4.11.2) from pig kidney with Triton X-100 yields an aggregate (mol. wt. approx. 10(6)) that decomposes into "free" aminopeptidase (mol. wt. 280 000) either upon autolysis at pH 5 or after exposure to trypsin. Both procedures yield free enzymes that are identical with respect to electrophoretic mobility, enzymatic activity and zinc content. After dissociation, the enzyme resulting from autolysis yields a single subunit of 140 000 molecular weight while the trypsin-treated enzyme produces three fragments (140 000, 95 000 and 48 000 mol. wt.). As the aggregate is formed by subunits 10 000 daltons heavier than those of the free enzyme, the existence of a hydrophobic portion anchoring the enzyme to the membrane might be postulated. Reactivation experiments carried out on the three purified fragments of urea-denatured aminopeptidase show that the 140 000 molecular weight subunit is the only one able to yield an active enzyme (after spontaneous dimerization). It can be concluded that the smaller fragments are artefacts resulting from trypsin degradation during purification.     

Identification and partial purification of a cytosolic activator of vacuolar H(+)-ATPases from mammalian kidney.

A factor that activates affinity-purified vacuolar H(+)-ATPase from bovine kidney microsomes was identified and partially purified from bovine kidney cytosol. The activator is a heat-stable, trypsin-sensitive acidic protein with a Mr by gel filtration of approximately 35,000. The activator increased the activity of renal microsomal and brush border H(+)-ATPase by over 60% but stimulated lysosomal H(+)-ATPase activity by only 28%; it had little or no activity against the remaining N-ethylmaleimide-insensitive ATPase in kidney microsomes and other transport ATPases. Stimulation of ATPase activity appeared to result from binding of the activator to the H(+)-ATPase. Activation was saturable, with a Hill coefficient of 1 at low protein concentrations. Both activator binding and stimulation of H(+)-ATPase activity were enhanced at pH values less than or equal to 6.5. The activator has selective effects on different H(+)-ATPases and is poised to activate the enzyme at low physiologic values of cytosolic pH; this newly identified cytosolic proteins may participate in the physiologic regulation of the vacuolar H(+)-ATPase.     

Phosphodiesterase activator from rat kidney cortex.

Incubation of homogenates of rat renal cortex at 4 degrees resulted in increased cAMP phosphodiesterase activity; the increase was much more rapid in hypotonic medium than in one of physiological tonicity. cAMP phosphodiesterase activity did not increase with incubation of supernatant fractions (48,000 x g, 20 min) prepared from isotonic homogenates. Extraction of the isotonic particulate fraction with hypotonic buffer released an activator which increased cAMP phosphodiesterase activity of the supernatant fraction. The kidney phosphodiesterase activator differed from a heat-stable, calcium-dependent protein activator of phosphodiesterase in that it was destroyed by heating (90 degrees for 10 min) and was not inhibited by EGTA. The phosphodiesterases of rat renal cortex were partially resolved by chromatography on DEAE-Bio-Gel, and a cAMP phosphodiesterase that is sensitive to the kidney activator was identified. This phosphodiesterase was separable from that affected by a calcium-dependent phosphodiesterase activator from bovine brain and from cGMP-stimulated cAMP phosphodiesterase. As determined by sucrose density gradient centrifugation, after incubation with the kidney activator, the activated form of phosphodiesterase had a lower sedimentation velocity than did the unactivated form.     

The activator of cerebroside sulphatase. Binding studies with enzyme and substrate demonstrating the detergent function of the activator protein.

1. Sulphatase A (cerebroside sulphatase) (EC 3.1.6.1.) and a 12-fold excess of its physiological activator protein were chromatographed together on Sephadex G-75. The elution buffer was the same as that used in the enzymic degradation of sulphatides. The two proteins were eluted in different peaks indicating that no stable complex formed. 2. Activator protein was incubated with sulphatides under conditions used favouring the sulphatase activity. Incubation solutions were then examined by electrophoresis on a polyacrylamide gel gradient. An one-to-one complex between activator and sulphatides was observed. Half maximal binding occurred with 2.5 nmol of sulphatides together with 1 or 2 nmol of activator in 100 micronl. 3. Cerebrosides as the enzymic degradation products of sulphatides, bind also to the activator protein. A ratio of one-to-one could possibly be obtained at high cerebroside concentrations. The binding to cerebrosides is less specific than that to sulphatides. A 7-fold excess of cerebrosides was necessary for half maximal binding. 4. In a mixture of sulphatides and cerebrosides the formation of the complex with the activator protein is partly inhibited. The total amount of bound lipids changed as the composition of the lipid mixture was varied. In a one-to-one mixture of the two lipids 60% of the total bound lipids are sulphatides and 40% are cerebrosides.     

Possible involvement of cerebroside sulfate in opiate receptor binding.

Cerebroside sulfate (CS) appears to fulfill most of the structural requirements of a hypothetical opiate receptor. It possesses many of the properties that are thought to be necessary for the identification of an "opiate receptor," exhibiting high affinity and stereoselective binding to a number of narcotic drugs. Although these properties are insufficient to establish identity of the receptor, it is highly significant that the affinity of this binding can be correlated with the analgetic potency of these drugs in both man and rodents. CS is an endogenous component of brain tissue, and a partially purified opiate receptor from mouse brain has been found to be CS. Other experiments indicate that reduced availability of brain CS decreases the analgetic effects of morphine and this is accompanied by a reduction in number of binding sites, suggesting that the interaction of opiates with CS observed in vitro may also have importance in vivo. CS was also found to be a component of the opiate receptor after marking with 125I-labeled diazosulfanilic acid. The possibility that CS or the SO4-2 group of this lipid may be the "anionic site" of the opiate receptor should be considered.     

The activator of human cerebroside sulphatase. Activating effect on the acidic forms of the sulphatases from invertebrates.

1) Acidic forms of the sulphatase were partially purified from the following invertebrate species: Tethya aurantium (Porifera), Patella vulgata (mollusca), Maja squinado (Arthropoda), Marthasterias glacialis (Echinodermata) and Microcosmus sulcatus (Tunicata). Enzyme preparations thus obtained cleaved cerebroside sulphates (sulphatides) only in the presence of either specific detergents (e.g. taurodeoxycholate) or an activator protein isolated from human liver. This corresponds to the findings on purified sulphatase A of human origin. 2) At low concentrations, the activating effect was proportional to the amount of activator protein applied; at higher concentrations, proportionality was obtained only in some cases. On a molar basis, less of the activator protein was required to achieve the same activation as taurodeoxycholate. At optimum concentrations of the detergent however, the activation was much higher. 3) The enzyme specificity of the activator and some evolutionary implications are discussed.     

Molecular arrangements in sphingolipids. The crystal structure of cerebroside

The single crystal analysis of a complex, membrane glycolipid is described. Cerebroside (β-D-galactosyl-N-(2-D-hydroxyoctadecanoyl)-D-dihydrosphingosine, $\text{C}{}_{42}\text{H}{}_{32}\text{O}{}_9\text{N}\text{·}\text{1}\text{2}\text{C}{}_2\text{H}{}_5\text{OH}$) — an important constituent of plasma membranes — crystallizes in the monoclinic spacegroup P2, with a = 11.202, b = 9.262, c = 46.46 A and β = 99.00^°. There are two independent molecules in the asymmetric unit partly related by a non-crystallographic symmetry. The structure was determined by direct methods and refined to R = 0.116.The molecules pack in a typical bilayer arrangement with adjacent double layers separated by ethanol molecules of crystallization. The planes of the sugar rings are turned almost parallel to the layer interface which gives the molecules the shape of a shovel. Together with the polar ceramide part, the galactose head groups form an extensive lateral network of hydrogen bonds within the polar region of each layer. The chains tilt by an angle of 49^° towards this polar boundary. A parallel stacking of the chains is achieved by a bend of the sphingosine chain as far up as carbon atom 5 and 6 in the two independent molecules. The lateral hydrocarbon chain packing is of an earlier unknown hybrid type (HS2). Chains with parallel zigzag planes are arranged in pleated shoets. These sheets contain alternatively fatty acid and sphingosine chains which have a mutually perpendicular chain plane orientation.     

A novel mass spectrometric assay for the cerebroside sulfate activator protein (saposin B) and arylsulfatase A

A mass spectrometric method is described for monitoring cerebrosides in the presence of excess concentrations of alkali metal salts. This method has been adapted for use in the assay of arylsulfatase A (ASA) and the cerebroside sulfate activator protein (CSAct or saposin B). Detection of the neutral glycosphingolipid cerebroside product was achieved via enhancement of ionization efficiency in the presence of lithium ions. Assay samples were extracted into the chloroform phase as for the existing assays, dried, and diluted in methanol-chloroform-containing lithium chloride. Samples were analyzed by electrospray ionization mass spectrometry with a triple quadrupole mass spectrometer in the multiple reaction monitoring tandem mass spectrometric mode. The assay has been used to demonstrate several previously unknown or ambiguous aspects of the coupled ASA/CSAct reaction, including an absolute in vitro preference for CSAct over the other saposins (A, C, and D) and a preference for the non-hydroxylated species of the sulfatide substrate over the corresponding hydroxylated species. The modified assay for the coupled ASA/CSAct reaction could find applicability in settings in which the assay could not be performed previously because of the need for radiolabeled substrate, which is now not required.     

Electron-transfer flavoprotein-ubiquinone oxidoreductase from pig liver: purification and molecular, redox, and catalytic properties

Electron-transfer flavoprotein-ubiquinone oxidoreductase (ETF-QO) was purified to homogeneity from pig liver submitochondrial particles. It is comparable in molecular weight and general properties to ETF-QO from beef heart [Ruzicka, F. J., & Beinert, H. (1977) J. Biol. Chem. 252, 8440-8445], and the electron spin resonance signals of the reduced iron-sulfur cluster are essentially identical. ETF-QO catalyzes the transfer of electrons from electron-transfer flavoprotein (ETF) to nitro blue tetrazolium, with a sluggish reaction turnover number of about 10-30 min-1. In contrast, the enzyme rapidly disproportionates ETF semiquinone, with a turnover number of 200 s-1. The reverse reaction, comproportionation of oxidized and hydroquinone ETF, provides an enzymatic assay for ETF-QO with picomolar sensitivity. Equilibrium spectrophotometric titrations show that ETF-QO accepts a maximum of two electrons from ETF and accepts three electron equivalents from dithionite or by photochemical reduction. All electrons from the enzymatically or chemically reduced protein can be transferred to 2,3-dimethoxy-5-methyl-6-pentyl-1,4-benzoquinone (PB), and this reaction is readily reversible. Reduction of ETF-QO by 2,3-dimethoxy-5-methyl-6-pentyl-1,4-benzohydroquinone is pH dependent and indicates the enzyme to have a redox potential that decreases by 47 mV per pH unit. Therefore, ETF-QO binds one to two protons upon reduction. The EO' at pH 7.3 is 38 mV. The ability of ETF-QO to catalyze the equilibration of ETF redox states has been used to evaluate the equilibrium 2ETFsq + nH+ in equilibrium ETFox + ETFhq.(ABSTRACT TRUNCATED AT 250 WORDS)     

The sialate-pyruvate lyase from pig kidney. Elucidation of the primary structure and expression of recombinant enzyme activity.

The first complete primary structure of a mammalian sialate-pyruvate lyase, namely of the enzyme from porcine kidney, was elucidated by a combination of different PCR techniques followed by sequencing of the resulting fragments. The primers used were either deduced from four porcine lyase peptides or from an alignment of human and mouse expressed sequence tags (ESTs), which were found to be homologous to already known microbial lyase sequences, and cDNA alone or after ligation with a plasmid vector served as a template. The lyase primary structure consists of 319 amino acids with a calculated protein molecular mass of approximately 35 kDa, which fits well to the value determined for the native enzyme. The porcine lyase sequence made it possible to assemble several ESTs from mouse and man in order to obtain the complete putative lyase genes. The three mammalian sequences reveal a high degree of homology both on the nucleotide (83% of the nucleotides are identical between all three sequences) and on the amino-acid level (72% of the amino acids are identical between all three sequences), and thus form a tightly related group. In contrast, the identity between the lyase primary structures from pig kidney and the microbial enzyme from Clostridium perfringens is much less pronounced (25%). Thirty-one amino acids were found to be absolutely conserved in all lyase sequences. Among them are two amino acids (lysine 173 and tyrosine 143 in the porcine lyase) that are most important for the catalytic reaction. After expression cloning, recombinant enzyme activity was expressed in Escherichia coli BL21(DE3)pLysS, which confirms the identity of the cloned sequence and verifies one of the putative human and murine sequences. After SDS/PAGE of a cell extract of the expression clone, a band of 35kDa was stained on the gel.