Genotypic difference in response of peroxidase and superoxide dismutase isozymes and activities to salt stress in barley

Difference in isozymes and activities of peroxidase (POD) and superoxide dismutase (SOD) in two barley (Hordeum vulgare L.) genotypes differing in salt tolerance (Gebeina, tolerant; Quzhou, sensitive) was investigated using a hydroponic experiment. The activities of both enzymes were significantly increased when the plants of the two barley genotypes were exposed to salt stress, with salt-tolerant genotype being generally higher than the sensitive one. The variation in the POD and SOD isozymes was dependent on barley genotype, salt level and exposure time. When the plants were exposed to salt stress for 10 days, two new POD isozymes were found, R _m0.26 (R _m, relative mobility of enzyme to dye) in Gebeina and R _m0.45 in Quzhou. Both isozymes disappeared after 20 days of salt stress, but R _m0.26 appeared again 30 days after the stress. Two new SOD isozymes of R _m0.19 and R _m0.46 were found in Gebeina when exposed to NaCl for 10 days, but only R _m0.46 in Quzhou. As the time of salt stress extended, more new SOD isozymes were detected, R _m0.35 in both genotypes in all different salt treatments and R _m0.48 in Gebeina under 200 mM NaCl stress. At 30 days after the stress, all the new SOD isozymes disappeared except for R _m0.48 in Gebeina under 200 mM NaCl stress. The results suggest that the increased POD and SOD activities could be partly due to the formation of some new isozymes and the tolerant variety had better ability to form new isozymes to overcome salt stress.     

An Accounting of Horseradish Peroxidase Isozymes Associated with the Cell Wall and Evidence that Peroxidase Does Not Contain Hydroxyproline

Isopycnic equilibrium centrifugation techniques were used to determine whether any horseradish (Amoracia lapathifolia) peroxidase isozymes were associated with hydroxyproline containing moieties. Purified peroxidase, horseradish root extracts, and peroxidase isozymes released from horseradish root cell walls were tested. In no case could any peak of peroxidase activity be found to band with hydroxyproline.     

Purification and biochemical properties of genetically defined malate dehydrogenase in maize

Malate dehydrogenase of maize exists in multiple molecular forms (isozymes). In strain W64A, two soluble forms (s-MDH), five mitochondrial forms (m-MDH), and two glyoxysomal forms (g-MDH) were found in etiolated seedlings. The s-MDHs and m-MDHs were prepared in highly purified form. Using these purified isozymes, experiments with reducing agents (100 mm mercaptoethanol), low pH (2.0), and high salt cocn (7.5 m guanidine-HCl), along with genetic data, have eliminated the possibility of conformational alterations as an explanation for MDH multiplicity in maize; the MDH isozymes are genetically determined. Biochemical properties for each of the seven MDH isozymes were examined. Molecular weight, pI, pH optimum, thermolability, and K_m for oxaloacetate, malate, NAD, and NADH at different pH values were determined for each isozyme. Different kinetics of substrate inhibition (oxaloacetate) and coenzyme inhibition (NAD) were observed for the different isozymes. Effects of NAD analogs, chelating agents, reducing agents, metal ions, and TCA cycle acids on the enzymatic activity of these isozymes were tested. Based on the physical and kinetic properties observed, the maize malate dehydrogenase isozymes can be classified into four groups: s-MDH¹; s-MDH²; the two most anodal m-MDHs; and the three most cathodal m-MDHs. Since strain W64A is highly inbred, our data along with our previous and simultaneous genetic analysis suggest that multiple genes are involved in the expression of maize malate dehydrogenase isozymes.     

Correlation between Chlorophyll and Chlorogenic Acid Content in Tobacco Leaves

Developmental stages of tobacco (Nicotiana tabacum L. cv. Burley 21) flower and capsule were correlated with tissue contents of polyphenols and activities of phenylalanine ammonialyase, polyphenoloxidase, and peroxidase. Chlorogenic acid, scopolin, and scopoletin were present in most tissues, whereas rutin and two dihydroxyphenolic glycosides concentrated primarily in the corolla and placenta, respectively. Ovules contained only chlorogenic acid. As development progressed, polyphenols accounted for nearly 15% of the dry weight in the green capsule of field-grown plants. Fertilization triggered a rapid increase of chlorogenic acid in the ovary. When l-phenylalanine-U-¹⁴C was fed to the detached green capsules and capsule parts, an incorporation of radioactivity into chlorogenic acid and dihydroxyphenolic glycosides occurred which suggested in situ synthesis of these compounds. This was subtantiated by a positive correlation between phenylalanine ammonia-lyase activity and polyphenol accumulation. High polyphenoloxidase activity was associated mainly with the ovary, whereas peroxidase activity was maximal during senescence of all tissues. Polyacrylamide gel slab electrophoresis revealed five cathodic bands and one diffuse zone with poly-phenoloxidase activity in flower extracts. Two anodic poly-phenoloxidase isozymes appeared only in the fertilized ovary. Among 17 peroxidase isozymes, six cathodic forms were present throughout floral development, and the anodic ones increased in number and activity at the later stages of capsule growth.     

Iaa oxidase and polyphenol oxidase activities of peanut peroxidase isozymes

Four anionic isozymes (A₁, A₂, A₄ and A₅) from peanut cells in suspension medium possessed IAA oxidase and polyphenol oxidase activities. The specific activities of each of the enzymes differed among the 4 isozymes. The pH optima established in these assays for peroxidase was acidic, for IAA oxidase neutral and for polyphenol oxidase alkaline. All 4 isozymes had different K_m and V_max for the enzyme activities of peroxidase and polyphenol oxidase. The sigmoid kinetics from the IAA oxidase assays for the isozymes probably indicates an allosteric nature.     

Silicification of developing internodes in the perennial scouring rush (Equisetum hyemale var. affine)

An electron microprobe (EMP) analysis of silica (SiO₂) deposition in the epidermis of developing internodes of the perennial scouring rush (Equisetum hyemale var. affine) indicates that SiO₂ is first detected in the stomatal apparatus beginning with internode 3, then the epidermal papillae (internode 8), and finally in radial cell walls of the long epidermal cells (internode 10). This process is initiated in the intercalary growth regions at the bases of the elongating internodes. The deposition of SiO₂ in long epidermal cell walls occurs after internodal extension has ceased and should therefore be considered as one of the final stages in internodal differentiation that involves strengthening the cellulosic framework of the cell wall. EMP measurements indicate that SiO₂ in stomata is equivalent to 30% of a pure SiO₂ standard and that SiO₂ in the radial walls of long epidermal cells averages twice that measured on the tangential walls of these same cells. This study supports the view that silicification plays a major role in strengthening the developing perennial scouring rush internodal system and that regulation of this process in this and other species of Equisetum, whose SiO₂ deposition patterns are markedly different, deserves further study.     

Purification and properties of neutral β-galactosidases from human liver

Two neutral β-galactosidase isozymes were purified from human liver. The initial step of purification was removal of the acidic β-galactosidases by adsorption on concanavalin A-Sepharose 4B conjugate. Subsequent purification steps included ammonium sulfate precipitation, diethylaminoethyl cellulose column chromatography, Sephadex G-100 gel filtration, and preparative polyacrylamide-gel isoelectric focusing. The final step of purification was affinity chromatography of the separated isoelectric forms on ?-aminocaproyl-β-d-galactosylamine-Sepharose 4B conjugate. The purified β-galactosidase isozymes had activity toward both β-d-galactoside and β-d-glucoside derivatives of 4-methylumbelliferone and p-nitrophenol with a pH optimum around 6.2. These enzyme forms were also found to possess lactosylceramidase II activity with a pH optimum in the range of 5.4 to 5.6, but not lactosylceramidase I activity and no activity toward galactosylceramide or GM₁-ganglioside. The molecular weight was found to be in the range of 37,500–39,500 for the two neutral isozymes and they had similar K_m and V values; the more acidic form (designated β-galactosidase N₁) was more heat stable than the other form (designated β-galactosidase N₂). Antibodies evoked against the N₁ and N₂ β-galactosidases gave identical precipitin lines retaining enzymatic activity. No cross-reactivity was observed between the neutral and the acidic isozymes when examined with the respective antisera.     

Lactate and malate dehydrogenase in the fan-shell associated shrimp, Pontonia pinnophylax (Otto): Effects of temperature and urea

In Pontonia pinnophylax (Otto), a crustacean decapod inhabiting the mantle cavity of Pinna nobilis L. (Bivalvia: Pteriomorpha), the lactate dehydrogenase (LDH) and malate dehydrogenase (MDH) activity, and their electrophoretic patterns, were compared in relation to heat and urea inactivation. Activity was higher in LDH than in MDH, and the electrophoretic patterns showed a predominance of LDH-A4 and the presence of both mitochondrial and cytosolic MDH. Heat incubation reduced both enzymatic activities, but more MDH. Also all isozymes showed different heat sensitivity, with anodic forms more heat-resistant than cathodic ones, either in LDH as in MDH. Urea treatment caused also a higher inactivation of the most cathodic isozymes, but MDH appeared more resistant than LDH at 2 M urea. The high polymorphism of these enzymes suggests an adaptation of Pontonia metabolism to hypoxic conditions; moreover, the different isozyme stability grade should be functional to contrast environmental variability.     

Kinetic properties of pig pyruvate kinases type A from kidney and type M from muscle.

Kinetic properties of homogeneous preparations of pig kidney and pig muscle pyruvate kinases (EC 2.7.1.40) were studied. Both isozymes showed a hyperbolic relationship to ADP with an apparent K_m of 0.3 mm. K⁺ and Mg²⁺ were necessary for the activity of both isozymes, and their dependences on these cations were similar. The muscle isozyme expressed Michaelis-Menten type of kinetics with respect to phosphoenolpyruvate, and the apparent K_m was the same (0.03 mm) from pH 5.5 to pH 8.0. In contrast, the dependence on phosphoenolpyruvate changed with pH for the kidney isozyme. It showed similar properties to the muscle isozyme at pH 5.5–7.0 (apparent K_m of 0.08 mm), while two apparent K_m values for this substrate were present at pH 7.5–8.0, one low (0.1 mm) and one high (0.3–0.6 mm). At pH 7.5, fructose 1,6-bisphosphate converted the kidney isozyme to a kinetical form where only the lower apparent K_m for phosphoenolpyruvate was detected. On the other hand, in the presence of alanine or phenylalanine the kidney pyruvate kinase showed only the higher K_m for this substrate. At low phosphoenolpyruvate levels both isozymes were inhibited by phenylalanine, and half-maximal inhibition was found at 0.3 and 2.2 mm for the kidney and muscle isozymes, respectively. At a 5 mm concentration of the substrate only the kidney isozyme was inhibited, the apparent K_i being the same. Alanine inhibited the kidney isozyme (apparent K_i at 0.3 mm, irrespective of substrate concentration). No effect was seen on the muscle isozyme. Fructose 1,6-bisphosphate was an activator of the kidney isozyme at phosphoenolpyruvate concentrations below 1.0 mm It also counteracted the inhibition by alanine or phenylalanine of this isozyme. ATP inhibited both isozymes, and this inhibition was not counteracted by fructose 1,6-bisphosphate. The kidney isozyme showed both a high and a low apparent K_m for phosphoenolpyruvate in the presence of ATP. The influence of the effectors on the activity of both isozymes varied markedly with pH, except for the action of ATP. At low substrate concentrations, however, the inhibitor action of ATP on the muscle enzyme was diminished around pH 7.5, in contrast to higher or lower pH values. Alanine or phenylalanine were more effective as inhibitors at higher pH values, and fructose 1,6-bisphosphate stimulated the kidney isozyme only at pH levels above pH 6.5. The influence of activators and inhibitors on the regulation of the kidney and muscle pyruvate kinases is discussed.     

Subcellular localization of the F1 and F2 isozymes of horse liver aldehyde dehydrogenase

The subcellular distribution and relative amounts of the two isozymes, F1 and F2, of aldehyde dehydrogenase (EC 1.2.1.3) which were recently purified to homogeneity from horse liver (Eckfeldt, J., et al. (1976) J. Biol. Chem.251, 236–240) have been investigated. A fresh horse liver homogenate was fractionated on DEAE-cellulose. The results indicate that approximately 60% of the total pH 7.0 acetaldehyde dehydrogenase activity is due to the F1 isozyme and 40% is due to the F2 isozyme. Several horse livers were then fractionated into subcellular components using a differential centrifugation method. Based on the disulfiram (Antabuse) inhibition and the aldehyde concentration dependence of the enzymatic activity, it appears that the disulfiram-sensitive F1 isozyme (K_m acetaldehyde ? 70 μm) is primarily cytosolic and the disulfiram-insensitive F2 isozyme (K_{m acetaldehyde} ? 0.2 μm) is primarily mitochondrial. Fluorescence studies showed that the acetaldehyde dehydrogenase of the intact mitochondria could utilize only the endogenous pyridine nucleotide pool and not externally added NAD. Also, the ethanol dehydrogenase activity was found to be nearly 10 times the total acetaldehyde dehydrogenase activity when assaying a horse liver homogenate at pH 7.0 and with saturating substrates. The significant differences between this work and the results reported in rat liver are discussed with respect to the physiological importance of the cytosolic and mitochondrial aldehyde dehydrogenase during the ethanol oxidation in vivo.     

χ alcohol dehydrogenase isozymes of horse liver

Horse liver contains previously unrecognized isozymes of alcohol dehydrogenase. In contrast to the molecular forms identified up to now, under the conditions employed these variants migrate toward the anode on starch gel electrophoresis and were separated from the cathodic isozymes by DEAE-cellulose chromatography. They were then purified on agarose-hexane-AMP. Their physicochemical and compositional characteristics are similar to those x alcohol dehydrogenases from human liver. Like these and similar ones from simian liver, they retain most of their activity in the presence of10 mm 4-methylpyrazole, oxidize short-chain primary alcohols very poorly, and appear to prefer longer chain primary alcohols and ω-hydroxy fatty acids as substrates.     

Die Lokalisation der Peroxidase-Isoenzymgruppe GI in der Zellwand von Tabak-Geweben

Summary By vacuum infiltration of intercellular spaces of tobacco tissues it is possible to extract substances from cell walls which move freely in the walls. The peroxidases (E.C. 1.11.1.7) contained in these extracts are predominantly isoenzymes of G_I (fast migrating anodic group) as was shown by discelektrophoresis of the extracts. As has been demonstrated previously G_I is not present in the protoplast; therefore G_I is the typical cell wall fraction of tobacco peroxidases. Different tissues of tobacco always differ in the isoenzyme pattern of G_I. This pattern also changes during tissue development. We can therefore say that there exists an enzymatic differentiation of plant cell walls during development. As G_I is not bound to the walls, it always appears in high amounts in crude extracts of plant material. Therefore G_I is always called the soluble cytoplasmic fraction, but our investigations clearly demonstrate that G_I is localized in cell walls only. Beside G_I there are much smaller amounts of G_III (slow migrating cathodic group) and if present in the tissue G_II (slow migrating anodic group) detectable in the infiltration fluids of intracellular spaces. G_III and G_II are localized mainly in the protoplast. But they are also bound to the walls, ionically in the case of G_III and covalently in the case of G_II.

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Abkürzungen MDH Malatdehydrogenase (E.C. 1.1.1.37) - G_I, G_II, G_III Enzymgruppen der Peroxydase - FG Frischgewicht     

Purification and Characterization of Two Forms of Glutamine Synthetase from the Pedicel Region of Maize (Zea mays L.) Kernels

Maize (Zea mays L.) kernel pedicels, including vascular tissues, pedicel parenchyma, placento-chalazal tissue, and the surrounding pericarp, contained two forms of glutamine synthetase (EC 6.3.1.2), separable by anion exchange chromatography under mildly acidic conditions. The earlier-eluting activity (GS_p1), but not the later-eluting activity (GS_p2), was chromatographically distinct from the maize leaf and root glutamine synthetases. The level of GS_p1 activity changed in a developmentally dependent manner while GS_p2 activity was constitutive. GS_p1 and GS_p2 exhibited distinct ratios of transferase to hydroxylamine-dependent synthetase activities (5 and 23, respectively), which did not change with kernel age. Purified pedicel glutamine synthetases had native relative molecular masses of 340,000, while the subunit relative molecular masses differed slightly at 38,900 and 40,500 for GS_p1 and GS_p2, respectively. Both GS forms required free Mg²⁺ with apparent K_ms = 2.0 and 0.19 millimolar for GS_p1 and GS_p2, respectively. GS_p1 had an apparent K_m for glutamate of 35 millimolar and exhibited substrate inhibition at glutamate concentrations greater than 90 millimolar. In contrast, GS_p2 exhibited simple Michaelis-Menten kinetics for glutamate with a K_m value of 3.4 millimolar. Both isozymes exhibited positive cooperativity for ammonia, with S_0.5 values of 100 and 45 micromolar, respectively. GS_p1 appears to be a unique, kernel-specific form of plant glutamine synthetase. Possible functions for the pedicel GS isozymes in kernel nitrogen metabolism are discussed.     

Ribonucleic acids from barley leaves

1. The total RNA and the RNA present in 27000g pellet (probably composed of chloroplasts, nuclei and mitochondria) and in 27000g supernatant (probably composed of microsomes and soluble proteins) fractions (separated by centrifugation at 27000g of a leaf homogenate prepared in 0·5m-sucrose–0·02m-tris–HCl, pH7·6) of barley leaves were extracted by phenol–sodium lauryl sulphate and their elution profiles on Sephadex G-200 and on ECTEOLA-cellulose anion-exchanger were examined and their nucleotide compositions and the melting curves were determined. 2. The pellet and the supernatant fractions contained respectively about 55% and 20% of the total RNA, whereas 25% of the total RNA was lost during homogenization of the leaf tissue with sucrose–buffer. 3. The total RNA or the RNA from pellet or supernatant fractions, which by its behaviour on Sephadex G-200 columns was found to be predominantly of high molecular weight (i.e. of ribosomal origin), produced about 13 peaks on ECTEOLA-cellulose columns. The RNA species in the pellet and supernatant fractions probably resembled each other in molecular size or secondary structure or both. However, they were present in relatively different amounts in these fractions. 4. The T_m (i.e. the temperature at which 50% of the maximal increase in extinction had occurred) of total RNA and of RNA from pellet fraction was 64·5° whereas T_m of RNA from the supernatant fraction was 73°. The total RNA and the RNA from pellet fraction also resembled each other in nucleotide composition, and the RNA from the supernatant fraction in accordance with its high T_m had a high GMP+CMP content.     

The Role of beta-Galactosidases in the Modification of Cell Wall Components during Muskmelon Fruit Ripening

The changes in activities of soluble β-galactosidase and two forms of wall-bound β-galactosidases extracted with NaCl and EDTA were investigated throughout the development of muskmelon (Cucumis melo L. cv Prince) fruits. DEAE-cellulose ion-exchange chromatography of soluble β-galactosidase revealed the presence of two isoforms. Soluble isoform I was detected in all stages throughout the fruit development, whereas soluble isoform II appeared around 34 d after anthesis when fruit ripening initiated. Both NaCl- and EDTA-released β-galactosidase activities also increased as ripening proceeded. The soluble and wall-bound forms behaved differently upon ion-exchange chromatography. Enzymological properties such as optimum pH, optimum temperature, K_m values for p-nitrophenyl β-d-galactopyranoside, and inhibition by metal ions were nearly similar in all forms. Molecular sizes of pectic polymers and hemicelluloses extracted from fruit mesocarp cell walls were shifted from larger to smaller polymers during ripening, as determined by gel filtration profiles. NaCl-released β-galactosidase from cell walls of ripe fruits had the ability to degrade in vitro the pectin extracted from preripe fruit cell walls to smaller sizes of pectin similar to those that were observed in ripe cell walls in situ. Both soluble isoform I and II were able to degrade in vitro the 5% KOH-extractable hemicellulose from preripe fruit cell walls to sizes of molecules similar to those that were observed in ripe cell walls in situ. Soluble isoform I and the NaCl-released form from ripe fruits were able to modify in vitro 24% KOH-extractable hemicellulose from preripe cell walls to sizes of molecules similar to those that were observed in ripe fruits in situ.     

Alfalfa Root Nodule Carbon Dioxide Fixation : II. Partial Purification and Characterization of Root Nodule Phosphoenolpyruvate Carboxylase

A nonphotosynthetic phosphoenolpyruvate carboxylase (EC 4.1.1.31) was partially purified from the cytosol of root nodules of alfalfa. The enzyme was purified 86-fold by ammonium sulfate fractionation, DEAE-cellulose, hydroxylapatite chromatography, and reactive agarose with a final yield of 32%. The enzyme exhibited a pH optimum of 7.5 with apparent K_m values for phosphoenolpyruvate and magnesium of 210 and 100 micromolar, respectively. Two isozymes were resolved by nondenaturing polyacrylamide disc gel electrophoresis. Subsequent electrophoresis of these isozymes in a second dimension by sodium dodecyl sulfate slab gel electrophoresis yielded identical protein patterns for the isozymes with one major protein band at molecular weight 97,000. Malate and AMP were slightly inhibitory (about 20%) to the partially purified enzyme. Phosphoenolpyruvate carboxylase comprised approximately 1 to 2% of the total soluble protein in actively N₂-fixing alfalfa nodules.     

Peroxidase isozyme patterns in the skin of maturing tomato fruit

The cessation of tomato fruit growth is thought to be induced by an increase in the activity of enzymes which rigidify cell walls in the fruit skin. Peroxidase could catalyse such wall‐stiffening reactions, and marked rises in peroxidase activity were recently reported in skin cell walls towards fruit maturity. Peroxidase isoforms in the fruit are here analysed using native gel electrophoresis. New isoforms of apparent M_r 44, 48 and 53 kDa are shown to appear in cell walls of the fruit skin at around the time of cessation of growth. It is inferred that these isozymes are present in the cell wall in vivo. Fruit from a range of non‐ripening mutants were also examined. Some of these do not soften or ripen for many weeks after achieving their final size. The new isozymes were found in skin cell walls of mature fruit in each of these mutants, as in the wild‐type and commercial varieties. It is concluded that the late‐appearing isozymes are not associated with fruit ripening or softening, and are probably not ethylene‐induced. They may act to control fruit growth by cross‐linking wall polymers within the fruit skin, thus mechanically stiffening the walls and terminating growth.     

Prunus serotina Amygdalin Hydrolase and Prunasin Hydrolase : Purification, N-Terminal Sequencing, and Antibody Production

In black cherry (Prunus serotina Ehrh.) seed homogenates, amygdalin hydrolase (AH) participates with prunasin hydrolase (PH) and mandelonitrile lyase in the sequential degradation of (R)-amygdalin to HCN, benzaldehyde, and glucose. Four isozymes of AH (designated AH I, I′, II, II′) were purified from mature cherry seeds by concanavalin A-Sepharose 4B chromatography, ion-exchange chromatography, and chromatofocusing. All isozymes were monomeric glycoproteins with native molecular masses of 52 kD. They showed similar kinetic properties (pH optima, K_m, V_max) but differed in their isoelectric points and N-terminal amino acid sequences. Analytical isoelectric focusing revealed the presence of subisozymes of each isozyme. The relative abundance of these isozymes and/or subisozymes varied from seed to seed. Three isozymes of PH (designated PH I, IIa, and IIb) were purified to apparent homogeneity by affinity, ion-exchange, and hydroxyapatite chromatography and by nondenaturing polyacrylamide gel electrophoresis. PH I and PH IIb are 68-kD monomeric glycoproteins, whereas PH IIa is dimeric (140 kD). The N-terminal sequences of all PH and AH isozymes showed considerable similarity. Polyclonal antisera raised in rabbits against deglycosylated AH I or a mixture of the three deglycosylated PH isozymes were not monospecific as judged by immunoblotting analysis, but also cross-reacted with the opposing glucosidase. Monospecific antisera deemed suitable for immunocytochemistry and screening of expression libraries were obtained by affinity chromatography. Each antiserum recognized all known isozymes of the specific glucosidase used as antigen.     

Studies on phosphorylase isozymes in lower vertebrates: evidence for the presence of two isozymes in elasmobranchs.

Two distinct phosphorylase isozymes, skeletal muscle phosphorylase b and liver phosphorylase b, have been purified from skate (Raja pulchra) in a homogeneous form as judged by electrophoretic and immunological criteria. Both isozymes were dependent on AMP for activity and converted to a forms by rabbit muscle phosphorylase kinase. Their subunit molecular weight determined by sodium dodecyl sulfate-gel electrophoresis was 94,000. These isozymes were distinctly different in affinities for glycogen and AMP, while they were very similar in sensitivities to SO₄^2?. Rabbit antibodies against each of the muscle and liver isozymes inhibited completely the respective specific antigens. No cross-reaction was observed in double diffusion tests, but some immunological relatedness of these isozymes was demonstrated by inhibition tests with antibodies. Their similarity was also shown by amino acid analyses. No evidence has been obtained that the skate possesses such an isozyme as mammalian phosphorylase L, the b form of which is inactive even in the presence of AMP. Electrophoretic studies on phosphorylases of crucian carp, toad, and snake revealed that these animals possess three isozymes which strikingly resemble mammalian isozymes in the organ-specific distribution and electrophoretic behavior.