Fructose-1,6-biphosphatase of the small intestine. Purification and comparison with liver and muscle fructose-1,6-bisphosphatases.

The occurrence of specific fructose-1,6-bisphosphatase [D-fructose-1,6-bisphosphate 1-phosphohydrolase, EC 3.1.3.11] (Fru-1,6-P2ase) in the small intestine was confirmed. 1. Fru-1,6-P2ase was isolated from mouse small intestine by a simple method. The isolated enzyme preparation was an electrophoretically homogeneous protein. 2. The molecular weight and subunit molecular weight were 140,000 and 38,000, respectively. 3. The intestinal enzyme was electrophoretically distinct from the liver enzyme. 4. The kinetic properties of the purified intestinal enzyme were compared with those of the mouse liver and muscle enzymes. 5. Mouse intestinal and muscle Fru-1,6-P2ases hydrolyzed ribulose-1,5-bisphosphate in addition to fructose-1,6-bisphosphate and sedoheptulose-1,7-bisphosphate.     

Purification and properties of rabbit liver phosphorylase phosphatase.

A procedure for the purification of rabbit liver phosphorylase phosphatase is described. The specific activity of the preparation is 2,100 units/mg of protein, representing a 25,000-fold purification. During the initial steps of the purification a large activation of enzyme activity was observed. The molecular weight of the purified enzyme was estimated by Sephadex G-75 chromatography to be 35,000, and by sucrose density ultracentrifugation to be 34,000 (2.9 S). On Na dodecyl-SO4 polyacrylamide disc gel electrophoresis a single component with a molecular weight of 34,000 was observed. The pH optimum is 6.9 to 7.4, and the Km for rabbit muscle phosphorylase alpha is 2 muM. The same procedure is also applicable to the extensive purification of phosphorylase phosphatase from rabbit muscle.     

Heterogeneity of glycogen synthesis upon refeeding following starvation.

1. Starvation of rats for 40 hr decreased the body weight, liver weight and blood glucose concentration. The hepatic and skeletal muscle glycogen concentrations were decreased by 95% (from 410 mumol/g tissue to 16 mumol/g tissue) and 55% (from 40 mumol/g tissue to 18.5 mumol/g tissue), respectively. 2. Fine structural analysis of glycogen purified from the liver and skeletal muscle of starved rats suggested that the glycogenolysis included a lysosomal component, in addition to the conventional phosphorolytic pathway. In support of this the hepatic acid alpha-glucosidase activity increased 1.8-fold following starvation. 3. Refeeding resulted in liver glycogen synthesis at a linear rate of 40 mumol/g tissue per hr over the first 13 hr of refeeding. The hepatic glycogen store were replenished by 8 hr of refeeding, but synthesis continued and the hepatic glycogen content peaked at 24 hr (approximately 670 mumol/g tissue). 4. Refeeding resulted in skeletal muscle glycogen synthesis at an initial rate of 40 mumol/g tissue per hr. The muscle glycogen store was replenished by 30 min of refeeding, but synthesis continued and the glycogen content peaked at 13 hr (approximately 50 mumol/g tissue). 5. Both liver and skeletal muscle glycogen synthesis were inhomogeneous with respect to molecular size; high molecular weight glycogen was initially synthesised at a faster rate than low molecular weight glycogen. These observations support suggestions that there is more than a single site of glycogen synthesis.     

Skeletal muscle glycogen content, structure, and metabolism are normal in rats with hepatic glycogen phosphorylase kinase deficiency

Skeletal muscle glycogen content and structure, and the activities of several enzymes of glycogen metabolism are reported for the hepatic glycogen phosphorylase b kinase deficient (gsd/gsd) rat. The skeletal muscle glycogen content of the fed gsd/gsd rat is 0.50 +/- 0.11% tissue wet weight, and after 40 hours of starvation this value is lowered 40% to 0.30 +/- 0.05% tissue wet weight. In contrast the gsd/gsd rat liver has an elevated glycogen content which remains high after starvation. The skeletal muscle phosphorylase b kinase, glycogen phosphorylase, glycogen synthase and acid alpha-glucosidase activities are 17.2 +/- 2.9 units/g tissue, 119.9 +/- 6.4 units/g tissue, 12.2 +/- 0.4 units/g tissue and 1.4 +/- 0.4 milliunits/g tissue, respectively, with approx. 20% of phosphorylase and approx. 24% of synthase in the active form (at rest). These enzyme activities resemble those of Wistar skeletal muscle, and again this contrasts with the situation in the liver where there are marked differences between the Wistar and the gsd/gsd rat. Fine structural analysis of the purified glycogen showed resemblance to other glycogens in branching pattern. Analysis of the molecular weight distribution of the purified glycogen indicated polydispersity with approx. 66% of the glycogen having a molecular weight of less than 250 X 10(6) daltons and approx. 25% greater than 500 X 10(6) daltons. This molecular weight distribution resembles those of purified Wistar liver and skeletal muscle glycogens and differs from that of the gsd/gsd liver glycogen which has an increased proportion of the low molecular weight material.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biochemical and structural characterization of actin from Dictyostelium discoideum.

Actin has been purified from amoebae of Dictyostelium discoideum by a procedure which is notable in that proteolysis has been diminished to undetectable levels and "selective" purification steps have been avoided. The overall yield of this procedure is 5- to 10- fold greater than that of a previous report (Spudich, J. A. (1974) J. Biol. Chem. 249, 6013-6020). The detailed biochemical and structural properties of this new preparation (preparation B) have been compared to those of Dictyostelium actin prepared by the previous procedure (preparation A) as well as to rabbit skeletal muscle actin. Preparation B actin is similar to muscle actin in its molecular weight, ability to activate myosin, filament structure, and polymerization properties. Preparation B actin has the same molecular weight and isoelectric point as preparation A actin, which is more acidic than that of skeletal muscle actin. However, preparation B actin and muscle actin form longer filaments than preparation A actin, as judged by viscometry and electron microscopy.     

Purification and properties of pig liver and muscle enolases

Enolases (2-phospho-d-glycerate hydrolase, EC 4.2.1.11) were purified from both pig liver and muscle. Graphs of InC vs.r ² from sedimentation equilibrium experiments are linear, which suggests homogeneous preparations of liver and muscle enolases. From these data the molecular weight of liver enolase is calculated to be approximately 92,000 D and that of muscle enolase to be approximately 85,000 D. SDS-PAGE experiments give a molecular weight value of 46,000 D for liver enolase and a value of 44,000 D for muscle enolase. These molecular weight values for liver and muscle enzymes are within the range for other enolases and show that both of these pig enolases are dimers. Amino acid composition data support the sedimentation equilibrium data and also give a smaller molecule weight (84,968 D) for muscle enolase compared to that of the liver enzyme (89,021 D). The two enzymes differ in their content of lysine [liver enolase (L)=94 residues, muscle enolase (M)=68 residues], histidine (L=13, M=21), serine (L=53, M=36), proline (L=52, M=34), and cysteine (L=4, M=21). Partial specific volumes of 0.737 ml/g for liver enolase and 0.735 ml/g for muscle enolase were calculated from the amino acid composition data. Pig liver and muscle enolases differ radically in their isoelectric points (pI=6.4–6.5 for liver enolase, and pI=8.8–9.0 for muscle enolase), and in their degree of inactivation by 750 mM LiCI (liver enolase is inactivated to a greater degree than the muscle enolase). Despite these physical and chemical differences, the kinetic constantsK _M values for Mg²⁺, 2-phosphoglyceric acid, and phospho(enol)pyruvate appear not to be significantly different for these two forms of enolase. The physical, chemical, and kinetic data for pig liver and muscle enolases are compared to similar data for pig kidney enolase.     

Further purification and characterization of the acid α-glucosidase

1. Centrifugation of rat liver acid glucosidase, which had been purified by adsorption on dextran gel, on a density gradient of sucrose showed the enzyme to be impure. 2. Preliminary purification of the enzyme before the gel filtration improved the final degree of purity of this preparation. Disc gel electrophoresis of this preparation showed a single band of protein. 3. The sedimentation co-efficient and the molecular weight determined on a sucrose gradient were 4.9-5.1s and 76000-83000 respectively for the rat liver enzyme, and 5.6s and 97000 for the acid alpha-glucosidase purified by means of the same procedure from the human kidney. 4. The Michaelis constants of rat liver and human kidney enzyme were 4.7x10(-3)m and 13.6x10(-3)m respectively with maltose as substrate. 5. The enzyme from both tissues was inhibited by tris and by erythritol. The inhibition of the rat liver acid glucosidase by erythritol was competitive.     

Caldesmon from rabbit liver: molecular weight and length by analytical ultracentrifugation

Although smooth muscle caldesmon migrates as a 140- to 150-kDa protein during sodium dodecyl sulfate-gel electrophoresis, its molecular mass is around 93 kDa as determined by sedimentation equilibrium (P. Graceffa, C-L. A. Wang, and W. F. Stafford, 1988, J. Biol. Chem. 263, 14,196-14,202). Nonmuscle caldesmon migrates during electrophoresis with a molecular mass close to 77 kDa, about half that of the muscle isoform. However, it is controversial whether the molecular weight of nonmuscle caldesmon is the same or much less than that of the muscle protein. Therefore we have now determined the molecular mass of rabbit liver caldesmon by sedimentation equilibrium and found a value of 66 +/- 2 kDa, a value much smaller than that of muscle caldesmon. This new value of the molecular weight, together with a sedimentation coefficient of 2.49 +/- 0.02 S. yields an apparent length of 53 +/- 2 nm and a diameter of 1.7 nm for the liver protein. We previously estimated a length of 74 nm and a diameter of 1.7 nm for the muscle caldesmon. We have also determined the amino acid composition of liver caldesmon and found it to be similar to that of the muscle protein. In conclusion, muscle and nonmuscle caldesmons appear to have similar overall amino acid composition and tertiary structure with the smaller nonmuscle protein having a correspondingly smaller length. The difference in molecular weight between the two caldesmons is consistent with the nonmuscle protein lacking a central peptide of the muscle isoform, as suggested by E. H. Ball, and T. Kovala, (1988, Biochemistry 27, 6093-6098).     

Characterization of rat muscle fructose 1,6-bisphosphatase

Fructose 1,6-bisphosphatase has been purified from rat muscle. Although the specific activity of the enzyme in the crude extract of rat muscle was extremely low, purification by the present procedure is highly reproducible. The purified enzyme showed a single band in SDS-polyacrylamide gel electrophoresis. The subunit molecular weight of the muscle enzyme was 37,500 in contrast to 43,000 in the case of the liver enzyme. Immunoreactivity of the muscle enzyme to anti-muscle and anti-liver fructose 1,6-bisphosphatase sera was clearly distinct from that of the liver enzyme. All one-dimensional peptide mappings of the muscle enzyme with staphylococcal V8 protease, chymotrypsin, and papain showed different patterns from those of the liver enzyme. When incubated with subtilisin, the extent of activation of muscle fructose 1,6-bisphosphatase at pH 9.1 was smaller than that of the liver enzyme. The subtilisin digestion pattern of the muscle enzyme on SDS-polyacrylamide gel electrophoresis was distinct from that of the liver enzyme. The AMP-concentration giving 50% inhibition of the muscle enzyme was 0.54 microM, whereas that of the liver enzyme was 85 microM. The concentrations of fructose 2,6-bisphosphate that gave 50% inhibition of rat muscle and liver enzymes were 6.3 and 1.5 microM, respectively. Fructose 1,6-bisphosphatase protein was not detected in soleus muscle by immunoelectroblotting with anti-muscle fructose 1,6-bisphosphatase serum.     

Phosphoprotein phosphatase inhibitor-2. Identification as a species of molecular weight 31,000 in rabbit muscle, liver, and other tissues

Specific antibodies, raised to purified rabbit skeletal muscle inhibitor-2, were used to analyze for the presence of inhibitor-2 in extracts of rabbit skeletal, cardiac, and diaphragm muscles, liver, kidney, brain, and lung. Direct analyses of the extracts by "Western blotting" revealed several immunoreactive species, apparent molecular weights in the range 26,000-136,000, as well as species with the electrophoretic mobility of inhibitor-2, apparent molecular weight 31,000. When supernatants from boiled extracts were similarly analyzed, most of the immunoreactive material was lost and the species corresponding to inhibitor-2 became prominent. Liver and muscle were studied in more detail; immunoprecipitates from either boiled or unboiled extracts were analyzed by Western blotting. The dominant polypeptide now was the species of apparent molecular weight 31,000, corresponding to inhibitor-2. Higher molecular weight species (115,000 in muscle and 136,000 in liver) were also detectable. The amount of inhibitor-2 detected in immunoprecipitates was not greatly different whether unboiled or boiled tissue extracts were used. In addition, extraction of the precipitates by boiling released material that inhibited purified type 1 protein phosphatase. The results suggest that inhibitor-2 is widely distributed in rabbit tissues and is found predominantly as a form of apparent molecular weight 31,000. In particular, the study provides direct demonstration of a species in rabbit liver with similar properties to rabbit muscle inhibitor-2.     

The heterogeneity of the protein content of liver and muscle glycogens

The portions of both liver and muscle glycogen that have a high protein content have been investigated. In liver the high molecular weight protions of glycogen may be rendered insoluble by treatment with trichloroacetic acid. This shows that reported desmo- (or insoluble) glycogen is an artefact of the extraction process and therefore of no physiological significance. In contrast, muscle glycogen isolubility is not associated with any specific molecular size range. Insolubility of muscle glycogen is shown to be related to partial degradation of the polysaccharide and to the high protein content remaining after the gentle extraction procedure. Since the molecular weight profile is unaltered by the removal of the insoluble glycogen it does not interfere with the interpretation of metabolic studies.     

Mercury binding proteins in liver and muscle of flat fish from the northern Tyrrhenian sea

1. The subcellular distribution of mercury and possible presence of Hg binding proteins of low molecular weight were investigated by ultracentrifugation and gel filtration in liver and muscle of the flat fish Citharus linguatula and Lepidorhombus boscii from the northern Tyrrhenian sea, heavily contaminated by the metal.2. For both tissues, Hg contents were higher in the pellet than in the supernatant.3. In the eluate of supernatant from Sephadex G-75 of both tissues, Hg was mainly bound to high molecular weight ligands.4. Differently from the muscle eluate, that from liver also contained a consistent amount of Hg bound to low molecular weight ligands.     

Purification and characterization of cytochromes P-450 from liver microsomes of 3-methylcholanthrene-treated crab-eating monkeys

Two forms of cytochrome P-450 (P-450MC1 and P-450MC2) were purified from liver microsomes of crab-eating monkeys (Macaca irus) treated with 3-methylcholanthrene (MC). Monkey P-450MC1 preparation had a specific content of 14.0 nmol/mg protein and showed a main protein band with a minimum molecular weight of 52,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Monkey P-450MC2 preparation had a specific content of 12.1 nmol/mg protein and a minimum molecular weight of 54,000. The carbon monoxide-reduced difference spectral peaks of monkey P-450MC1 and P-450MC2 were at 448 and 447 nm, respectively. In the reconstituted system, monkey P-450MC2 had high activities for benzo[a]pyrene 3-hydroxylation and 7-ethoxycoumarin O-deethylation. Monkey P-450MC1 had low activities toward these two substrates and a high activity for benzphetamine N-demethylation. Monkey P-450MC1 and P-450MC2 were detected by immunoblotting using an antibody prepared against rat cytochrome P-450c, which is a major form of cytochrome P-450 in liver microsomes of MC-treated rats. These results suggested that the molecular properties of cytochrome P-450 in liver microsomes of crab-eating monkeys treated with MC are similar to those in rats.     

Isolation and partial characterization of rat muscle fructose bisphosphatase

Fructose bisphosphatase (D-fructose-1,6-bisphosphate 1-phosphohydrolase, EC 3.1.3.11) has been isolated in homogeneous form from rat muscle by a simple and convenient procedure, including adsorption on carboxymethylcellulose and substrate elution. The resultant enzyme preparation has a specific activity comparable to that of the enzymes isolated from rabbit liver, rabbit muscle and rat liver. The native relative molecular mass of the enzyme was estimated by sedimentation equilibrium centrifugation to be approx. 138 000, and the enzyme appears to be a tetramer containing subunits of Mr approx. 34 500. The amino acid composition is distinctly different from that of the rabbit muscle, rabbit liver and rat liver enzymes. The purified enzyme contains no tryptophan and has a blocked amino terminal.     

Development of radioimmunoassay for thromboxane B2

A simple method for the preparation of rat liver urate oxidase is described. The enzyme was purified from rat liver homogenate by cell fractionation, detergent treatment, alkali treatment, and affinity chromatography on 8-aminoxanthine-bound Sepharose 4B. This enzyme preparation had a specific activity of 9.1 U/mg of protein and was purified about 1000-fold from the liver homogenate. After sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis followed by staining with Coomassie brilliant blue, this preparation yielded one protein band at a position corresponding to a molecular weight of 33,000.     

Glycogen of high molecular weight from mammalian muscle

Glycogen of high molecular weight has been isolated from mammalian muscle, in contrast to the material of low molecular weight commonly described. The large polysaccharide is similar to liver glycogen in the structure of its individual beta-particles and also, partially, in the mode of assembly into the gross alpha-particles. The large particles may be disrupted by 2-mercaptoethanol, but not to the same extent as their liver counterparts.     

Subunit structure and properties of the glycogen-bound phosphoprotein phosphatase from skeletal muscle

A high molecular weight phosphoprotein phosphatase was purified approximately 11,000-fold from the glycogen-protein complex of rabbit skeletal muscle. Polyacrylamide gel electrophoresis of the preparation in the absence of sodium dodecyl sulfate showed a major protein band which contained the activity of the enzyme. Gel electrophoresis in the presence of sodium dodecyl sulfate also showed a major protein band migrating at 38,000 daltons. The sedimentation coefficient, Stokes radius, and frictional ratio of the enzyme were determined to be 4.4 S, 4.4 nm, and 1.53, respectively. Based on these values the molecular weight of the enzyme was calculated to be 83,000. The high molecular weight phosphatase was dissociated upon chromatography on a reactive red-120 agarose column. The sedimentation coefficient, Stokes radius, and frictional ratio of the dissociated enzyme (termed monomer) were determined to be 4.1 S, 2.4 nm, and 1.05, respectively. The molecular weight of the monomer enzyme was determined to be 38,000 by polyacrylamide gel electrophoresis. Incubation of the high molecular weight phosphatase with a cleavable cross-linking reagent, 3,3'-dithiobis(sulfosuccinimidyl propionate), showed the formation of a cross-linked complex. The molecular weight of the cross-linked complex was determined to be 85,000 and a second dimension gel electrophoresis of the cleaved cross-linked complex showed that the latter contained only 38,000-dalton bands. Limited trypsinization of the enzyme released a approximately 4,000-dalton peptide from the monomers and dissociated the high molecular weight phosphatase into 34,000-dalton monomers. It is proposed that the catalytic activity of the native glycogen-bound phosphatase resides in a dimer of 38,000-dalton subunits.     

Purification and Properties of Beef Liver Phosphoglucomutase

A procedure is described for purification of phosphoglucomutase [EC 2.7.5.1] from beef liver. The purified enzyme preparation was homogeneous on the analysis of ultracentrifugation and zone electrophoresis. The molecular weight was determined to be 64,000 by the meniscus depletion method.

The amino acid composition of liver phosphoglucomutase was very similar to that of the rabbit muscle enzyme.

The reaction mechanism of liver phosphoglucomutase was examined kinetically. The results of kinetical experiments strongly suggested that the reaction of liver phosphoglucomutase proceeds via “ping-pong” mechanism.

Liver phosphoglucomutase activity was remarkably inhibited by Fru-1,6-P₂, glycerate-2,3-P₂ and glycerate-1,3-P₂. Role of the bisphosphate compounds on the control of carbohydrate metabolism is discussed.     

Post mortem glycogenolysis is a combination of phosphorolysis and hydrolysis

1. Glycogen, glucose, lactate and glycogen phosphorylase concentrations and the activities of glycogen phosphorylase a and acid 1,4-alpha-glucosidase were measured at various times up to 120 min after death in the liver and skeletal muscle of Wistar and gsd/gsd (phosphorylase b kinase deficient) rats and Wistar rats treated with the acid alpha-glucosidase inhibitor acarbose. 2. In all tissues glycogen was degraded rapidly and was accompanied by an increase in tissue glucose and lactate concentrations and a lowering of tissue pH. In the liver of Wistar and acarbose-treated Wistar rats and in the skeletal muscle of all rats glycogen loss proceeded initially very rapidly before slowing. In the gsd/gsd rat liver glycogenolysis proceeded at a linear rate throughout the incubation period. Over 120 min 60, 20 and 50% of the hepatic glycogen store was degraded in the livers of Wistar, gsd/gsd and acarbose-treated Wistar rats, respectively. All 3 types of rat degraded skeletal muscle glycogen at the same rate and to the same extent (82% degraded over 2 hr). 3. In Wistar rat liver and skeletal muscle glycogen phosphorylase was activated soon after death and the activity of phosphorylase a remained well above the zero-time level at all later time points, even when the rate of glycogenolysis had slowed significantly. Liver and skeletal muscle acid alpha-glucosidase activities were unchanged after death. 4. The decreased rate and extent of hepatic glycogenolysis in both the gsd/gsd and acarbose-treated rats suggests that this process is a combination of phosphorolysis and hydrolysis. 5. Glycogen was purified from Wistar liver and skeletal muscle at various times post mortem and its structure investigated. Fine structural analysis revealed progressive shortening of the outer chains of the glycogen from both tissues, indicative of random, lysosomal hydrolysis. Analysis of molecular weight distributions showed inhomogeneity in the glycogen loss; in both tissues high molecular weight glycogen was preferentially degraded. This material is concentrated in lysosomes of both skeletal muscle and liver. These results are consistent with a role for lysosomal hydrolysis in glycogen degradation.     

大鳞大马哈鱼垂体生长激素的分离、纯化与鉴定

应用ConA-Sepharose 4B亲和层析、凝胶过滤及离子交换层析等技术从大鳞大马哈鱼(Oncorhynchus tshawytscha)垂体中分离纯化了具有生物活性的生长激素(sGH)。用放射受体测定法(RRA)检测sGH组分的生物活性,结果表明纯化的8GH制品具有与兔肝细胞GH受体结合的生物活性。用放射免疫测定法(RIA)和酶联免疫吸附测定法(ELISA)分别检测了另两种垂体激素-催乳激素(PRL)和促性腺激素(GTH)在纯化的sGH制品中的残留量均在0.5％以下。用SDS-聚丙烯酰胺凝胶电泳SDS-PAGE评价sGH制品的电泳纯度并测定了其分子量为22000左右。等电聚焦电泳表明该种鱼GH由等电点分别为6.3和6.6的两种形式的分子组成。