Enzyme levels in pea seedlings grown on highly salinized media

The levels of 18 enzymes were determined in leaves, stems, and roots of 11-day-old pea seedlings grown in a liquid medium or in the same medium containing, in addition, 5 atmospheres of either NaCl, KCl, Na₂SO₄, or K₂SO₄. Though the plants grown in saline media were stunted, the specific activities of the enzymes were the same in the given tissues of all plants. Also, the electrophoretic pattern of isozymes of malate dehydrogenase was not altered by growth of the plants in a saline medium. However, the isozyme pattern of peroxidase from roots of salt-grown plants was altered in that two of the five detectable isozymes migrated a little more slowly than those in extracts from nonsaline plant tissues.     

Tissue specificity of tobacco peroxidase isozymes and their induction by wounding and tobacco mosaic virus infection

Peroxidases (EC 1.11.1.7) have been implicated in the responses of plants to physical stress and to pathogens, as well as in a variety of cellular processes including cell wall biosynthesis. Tissue samples from leaf, root, pith, and callus of Nicotiana tabacum were assayed for specific peroxidase isozymes by analytical isoelectric focusing. Each tissue type was found to exhibit a unique isozyme fingerprint. Root tissue expressed all of the detectable peroxidase isozymes in the tobacco plant, whereas each of the other tissues examined expressed a different subset of these isozymes. In an effort to determine which peroxidase isozymes from Nicotiana tabacum are involved in cell wall biosynthesis or other normal cellular functions and which respond to stress, plants were subjected to either wounding or infection with tobacco mosaic virus. Wounding the plant triggered the expression of several cationic isozymes in the leaf and both cationic and anionic isozymes in pith tissue. Maximum enzyme activity was detected at 72 hours after wounding, and cycloheximide treatment prevented this induction. Infection of tobacco with tobacco mosaic virus induced two moderately anionic isozymes in the leaves in which virus was applied and also systemically induced in leaves which were not inoculated with virus.     

Malate dehydrogenase (MDH; EC 1.1.1.37) isozymes in tissues and callus cultures ofCereus peruvianus (cactaceae)

Malate dehydrogenase (MDH; EC 1.1.1.37) isozymes were investigated in seeds and in seedlings and calli cultures ofC. peruvianus to determine if the changes in MDH isozyme banding patterns could be used as biochemical markers to identify the origin of regenerated plants from callus tissues. Four cytoplasmic MDH isozymes (sMDH), five mitochondrial MDH isozymes (mMDH), and one glyoxysomal MDH isozyme (gMDH) were detected and showed tissue- and stage-specific expression. A relationship of mMDH and gMDH isozyme patterns with callus tissues subcultured in three hormonal combinations and with the plants regenerated from these callus tissues was demonstrated. Furthermore, temperature and mechanical stress were found to be closely related to mMDH-1 activity in callus culture. Therefore, the different patterns of MDH isozymes in the various tissues ofC. peruvianus can be used as biochemical markers for the study of gene expression during development and as powerful tools in monitoring studies on callus cultures. This research was supported by the CNPq.     

Distribution of AMP-deaminase isozymes in rat tissues

1. The distribution of AMP deaminase isozymes in rat tissues was analyzed by electrophoresis on cellulose acetate membrane, by chromatography on phosphocellulose column, and by the application of immunological technique employing specific antisera against three parental AMP deaminases (isozymes A, B and C). Skeletal muscle extracts and diaphragm extracts contain a single identical isozyme, isozyme A. The major isozyme species of liver, kidney and testes are also identical and they are isozyme B. Heart extracts contains isozyme C exclusively. Extracts of brain, lung and spleen contain five isozymes, presumably a complete set of five B-C hybrids. 2. Developmental patterns of AMP deaminase isozyme were studied. In early postnatal life, extracts of heart, liver, kidney and lung contain five isozymes similar to those observed in adult brain. During postnatal development, a shift to isozyme C occurs in heart, whereas a shift to isozyme B occurs in liver and kidney. Five isozymes in lung remain throughout development. In brain a shift of B to five isozymes is observed during development. Isozyme A is the predominant form in muscle throughout postnatal development. 3. AMP deaminase in the regenerating liver was analyzed, but the data indicated that there was no change of isozyme distribution during hepatic regeneration.     

Glycolate oxidase isozymes are coordinately controlled by GLO1 and GLO4 in rice

Glycolate oxidase (GLO) is a key enzyme in photorespiratory metabolism. Four putative GLO genes were identified in the rice genome, but how each gene member contributes to GLO activities, particularly to its isozyme profile, is not well understood. In this study, we analyzed how each gene plays a role in isozyme formation and enzymatic activities in both yeast cells and rice tissues. Five GLO isozymes were detected in rice leaves. GLO1 and GLO4 are predominately expressed in rice leaves, while GLO3 and GLO5 are mainly expressed in the root. Enzymatic assays showed that all yeast-expressed GLO members except GLO5 have enzymatic activities. Further analyses suggested that GLO1, GLO3 and GLO4 interacted with each other, but no interactions were observed for GLO5. GLO1/GLO4 co-expressed in yeast exhibited the same isozyme pattern as that from rice leaves. When either GLO1 or GLO4 was silenced, expressions of both genes were simultaneously suppressed and most of the GLO activities were lost, and consistent with this observation, little GLO isozyme protein was detected in the silenced plants. In contrast, no observable effect was detected when GLO3 was suppressed. Comparative analyses between the GLO isoforms expressed in yeast and the isozymes from rice leaves indicated that two of the five isozymes are homo-oligomers composed of either GLO1 or GLO4, and the other three are hetero-oligomers composed of both GLO1 and GLO4. Our current data suggest that GLO isozymes are coordinately controlled by GLO1 and GLO4 in rice, and the existence of GLO isozymes and GLO molecular and compositional complexities implicate potential novel roles for GLO in plants.     

The subcellular location of isozymes of NADP-isocitrate dehydrogenase in tissues from pig, ox and rat

Antibodies against purified NADP-isocitrate dehydrogenase from pig liver cytosol and pig heart were raised in rabbits. The purified enzymes from these sources are different proteins, as demonstrated by differences in electrophoretic mobility and absence of crossreactivity by immunotitration and immunodiffusion. The NADP-isocitrate dehydrogenase in the soluble supernatant homogenate fraction from pig liver, kidney cortex, brain and erythrocyte hemolyzate was identical with the purified enzyme from pig liver cytosol, as determined by electrophoretic mobility and immunological techniques. The enzyme in extracts of mitochondria from pig heart, kidney, liver and brain was identical with the purified pig heart enzyme by the same criteria. However, the 'mitochondrial' isozyme was the major component also in the soluble supernatant fraction of pig heart homogenate. The 'cytosolic' isozyme accounted for only 1-2% of total NADP-isocitrate dehydrogenase in pig heart, as determined by separation of the isozymes with agarose gel electrophoresis and immunotitration. The mitochondrial isozyme was also the predominant NADP-isocitrate dehydrogenase in porcine skeletal muscle. The ratio of cytosolic/mitochondrial isozyme for porcine whole tissue extract, determined by immunotitration, was about 2 for liver and 1 for kidney cortex and brain. The distribution of isozymes in cell homogenate fractions from ox and rat tissues corresponded to that observed in organs of porcine origin. The mitochondrial and cytosolic isozymes from ox and rat tissues exhibited crossreactivity with the antibodies against the pig heart and pig liver cytosol enzyme, respectively, and the electrophoretic migration patterns were similar qualitatively to those found for the isozymes in porcine tissues. Nevertheless, there were species specific differences in the characteristics of each of the corresponding isozymes. NAD-isocitrate dehydrogenase was not inhibited by the antibodies, confirming that the protein is distinct from that of either isozyme of NADP-isocitrate dehydrogenase.     

Isozyme patterns in callus cultures and in plants regenerated from calli ofCereus peruvianus (Cactaceae)

Electrophoretic patterns for isocitrate dehydrogenase (IDH; EC 1.1.1.42), acid phosphatase (ACP; EC 3.1.3.2), peroxidase (PER; EC 1.11.1.7), and esterase (EST; EC 3.1.1.1) isozymes were determined inCereus peruvianus tissues and used as markers of genetic uniformity of calli and of the plants regenerated from callus cultures. One IDH, six ACP, six PER, and six EST isozymes were induced in cultured callus tissues in medium containing three 2,4-dichlorophenoxyacetic acid and kinetin combinations. Four ACP, two PER, and three EST isozymes were still present in all regenerated plantsin vitro and therefore can be used as markers of theC. peruvianus plants regenerated from callus tissues. The differential patterns of ACP and IDH isozymes and the similar zymograms for PER and EST isozymes presented by callus tissues were used in a comparison of callus tissues cultured for 2 years. The comparative analysis of zymograms within each enzyme system indicated a mean heterogeneity coefficient of 0.33 forC. peruvianus calli cultured for 2 years. Because of the isozyme variations, which developed in culture medium and were transferred to the regenerated plants, the IDH, ACP, PER, and EST enzyme systems can be considered to be good markers for investigating possible genetic variations in plant populations ofC. peruvianus obtainedin vitro from callus culture.This research was supported by the CNPq     

The role of peroxidase isozymes in resistance to wheat stem rust disease

In common with other disease situations, rust-resistant wheat leaves show a large increase in peroxidase activity during infection. Peroxidase isozymes from healthy or infected lines of wheat (Triticum aestivum L.) near isogenic for resistance and susceptibility to race 56 of Puccinia graminis tritici were separated by gel electrophoresis and the activity of each was estimated by photometric scanning. In order to ensure that the activity of isozymes observed on gels reflected the changes found in peroxidase enzymes assayed spectrophotometrically in extracts, a study was made of extraction procedures, substrates, and reaction conditions for both types of enzyme measurements. Of the 14 isozymes detected in both healthy and infected leaves, increases in only 1 (isozyme 9) were associated consistently with the development of resistant disease reaction at 20 C. Additional evidence was obtained to show that this isozyme can account for the increased peroxidase activity observed in extracts from resistant plants. When plants with high induced peroxidase activity due to resistance at 20 C were treated with ethylene or transferred to 25 C, they reverted to complete susceptibility. However, the disease-induced activity of isozyme 9 did not fall. The data suggest that, in this case, the association of peroxidase with resistance was a consequence of, not a determinant in, resistance.     

Alcohol dehydrogenase (EC 1.1.1.1) isozymes as markers at 2,4-dichlorophenoxyacetic acid × kinetin combinations in callus cultures ofCereus peruvianus (Cactaceae)

Alcohol dehydrogenase (ADH; EC 1.1.1.1) isozymes were investigated in tissue ofCereus peruvianus cultured in different concentrations of 2,4-dichlorophenoxyacetic acid (2,4-D) and kinetin. Five ADH isozymes were detected in starch gel and showed different patterns in seeds, seedlings, calli cultured at 32 and 22°C, and plants regenerated from calli cultured in three 2,4-D and kinetin combinations. Four phenotypes formed by different combinations of ADH-2, ADH-3, ADH-4, and ADH-5 were detected in calli cultured at 32°C and in plants regenerated from calli. ADH-1 isozyme was detected only in calli subcultured for 1 or 2 weeks at 22°C and was indicated as a marker of stress conditions that affect the growth ofC. peruvianus callus tissues in culture. ADH phenotypes with either a higher or a lower number of isozymes were detected in different proportions in the callus tissues cultured in media containing different 2,4-D and kinetin ratios. ADH isozyme patterns were found to be sensitive markers at the highest kinetin concentration or at high kinetin/2,4-D ratios. The results indicate a high correlation between the ADH isozyme patterns and the capacity for regeneration. Thus, ADH isozymes are indicated as good biochemical markers and as a powerful tool for monitoring studies ofC. peruvianus callus cultures.This research was supported by the CNPq.     

Pyruvate kinase isozymes in man

Anti human M2 type and anti human L type pyruvate kinase sera allowed us to distinguish two groups of pyruvate kinase in man. Erythrocyte and liver (L type) enzymes on the one hand were inhibited by anti L and not all by anti M2 serum; pyruvate kinase from all the other tissues on the other hand were inhibited by anti M2 and not at all by anti L serum. This latter group represent the M type pyruvate kinase isozymes. The M type isozymes have been studied by electrofocusing in thin layer acrylamide-ampholine gel. In adult tissues 4 types of isozymes were found, designated, from acid to alkaline pH, as M2 (predominant form in spleen, leukocytes, lung...), M3, M4 and M1 (predominant form in muscle and brain). In foetal tissues an extra band M2, called M2f, more anodic than M2, was added to the previously described isozymes. Except in brain (in which the isozymes M2, M3, M4 and M1 were found), the most anodic bands (M2f, M2 and M3) were predominant in all the foetal tissues. The isozymes M2f and M2 seem therefore to be the original M type pyruvate kinase forms from which the other isozymes issue. The rate of each isozyme seems to depend on tissue factors characterizing the state of differentiation of some tissues, as indicated by the ability of adult muscle extracts to change the isozymes M2 and M3 into more cathodic forms.     

The Two-Isozyme System of 3-Deoxy-d-arabino-Heptulosonate 7-Phosphate Synthase in Nicotiana silvestris and Other Higher Plants

Two isozymes of 3-deoxy-d-arabino-heptulosonate 7-phosphate (DAHP) synthase, denoted DS-Mn and DS-Co, were identified following DEAE-cellulose chromatography of crude extracts prepared from suspension-cultured cells of Nicotiana silvestris. The strikingly different properties of the isozymes allowed the development of assays for the selective detection of either isozyme in samples containing a mixture of the two. The DS-Mn isozyme required the sulfhydryl reductant, dithiothreitol, for activity and was stimulated by manganese. Activation by dithiothreitol was slow relative to catalysis, accounting for a hysteretic progress curve that was observed when reactions were started with inactive enzyme. The DS-Co isozyme was inhibited by dithiothreitol and required a divalent cation for activity. At optimal cation concentrations of 10 millimolar (magnesium), 0.5 millimolar (cobalt), and 0.5 millimolar (manganese), relative activities obtained were 100, 85, and 20, respectively. The substrate saturation curves with respect to erythrose 4-phosphate differed markedly when the two isozymes were compared. As little as 0.5 millimolar erythrose 4-phosphate saturated DS-Mn, whereas a 10-fold higher concentration was needed for saturation of DS-Co. The pH optimum of DS-Mn was 8.0, while that of the DS-Co isozyme was 8.6. Leaves of both N. silvestris and spinach also exhibited the DS-Mn/DS-Co isozyme arrangement, and the subcellular location of DS-Mn was shown to be the chloroplast compartment. By application of the differential assays for DAHP synthase isozymes, various monocotyledonous and dicotyledonous plants yielded data indicating the general presence of the DS-Mn/DS-Co isozyme pair in higher plants.     

Detection of cGMP dependent protein kinase isozymes by specific antibodies.

Two isozymes of cGMP-dependent protein kinase (cGMP kinase) have been identified. Polyclonal antibodies were developed which recognize both isozymes or specifically the I alpha and I beta isoform. The specificity of these antibodies was verified by using the recombinant or purified I alpha and I beta isozymes. The antibodies cross-reacted with the purified isozymes of cGMP kinase from bovine tracheal smooth muscle. The tissue concentration of cGMP kinase was determined by ELISA. High concentrations (greater than 10 pmol/g wet tissue) were present in bovine lung, rumen, trachea, aorta, uterus and stomach. The tissue distribution of the isozymes I alpha and I beta was investigated by immunoblots using crude extracts of the different tissues. The I beta-specific antibody yielded strong signals with extracts of trachea, aorta, stomach and uterus, whereas heart, cerebellum and lung apparently contain mainly the I alpha isozyme.     

AMP deaminase isozymes in human tissues

In human, there are four AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) isozymes: E1, E2, M and L. Chromatographic, electrophoretic and immunological studies showed the existence of isozymes E1 and E2 in erythrocytes, isozyme M in muscle and isozyme L in liver and brain. The tissues such as heart, kidney and spleen contained isozymes E1, E2 and L. Isozymes E1, M and L were isolated as apparently homogeneous preparations. The three isozymes were all tetramers composed of identical subunits, but differing slightly in molecular weight; isozyme E1 showed a subunit molecular weight of 80 000, isozyme M 72 000 and isozyme L 68 000. They were immunologically different from one another. The antisera precipitated only the corresponding enzyme and did not precipitate any other isozyme. The three isozymes were also different in kinetic and regulatory properties. Isozyme E2 was very similar to isozyme E1 in immunological and kinetic properties, although isozyme E2 could be separated from isozyme E1 by phosphocellulose chromatography, and zonal electrophoresis.     

A multilocus system for studying tissue and subcellular specialization. The pH and temperature dependence of the two major NADP-dependent isocitrate dehydrogenase isozymes of the fish Fundulus heteroclitus

In the teleost fish Fundulus heteroclitus, there are three NADP-dependent isocitrate dehydrogenase isozymes. IDH-B2 is the only cytoplasmic isozyme, and IDH-C2 dominates the mitochondria of all tissues other than liver, where IDH-A2 is expressed. Since fish are ectotherms, their intracellular temperature and pH change directly with environmental temperature. In order to evaluate the influence of these environmental parameters on a model fish NADP-isocitrate dehydrogenase system, the major cytoplasmic (IDH-B2) and mitochondrial (IDH-C2) isozymes were kinetically evaluated as a function of pH and temperature. Whereas Vfmax and KmISOCm (where ISOC is isocitrate) were pH-independent, the Km for NADP was pH-dependent for both isozymes. The cytoplasmic isozyme (IDH-B2) had smaller KmNADP values between pH 7.0 and pH 8.0 than the mitochondrial form (IDH-C2). Vfmax and Km for substrate and coenzyme were temperature-dependent. Energy of activation for IDH-B2 and IDH-C2 was 10.6 and 12.8 kcal/mol, respectively. Both proteins had delta G not equal to values of about 15.8 kcal/mol, with significantly different distributions between delta H not equal to and delta S not equal to. The cytoplasmic isozyme (IDH-B2) appears to have a greater rate of catalysis than the mitochondrial enzyme (IDH-C2) at temperatures less than 30 degrees C. Moreover, the IDH-B2 isozyme had lower KmNADP values than the IDH-C2 isozyme at all temperatures, whereas the KmISOC values for the two isozymes were indistinguishable. Our data suggest that the two major NADP-dependent isocitrate dehydrogenase isozymes have unique physiological and metabolic functions that are adapted to the tissues and cellular compartments in which they are expressed.     

Isolation and characterization of a soybean cDNA clone encoding the plastid form of aspartate aminotransferase

Five aspartate aminotransferase (EC 2.6.1.1; AAT) isozymes were identified in soybean seedling extracts and designated AAT1 to AAT5 based on their rate of migration on non-denaturing electrophoretic gels. AAT1 was detected only in extracts of cotyledons from dark-grown seedlings. AAT3 and AAT4 were detected in crude extracts of leaves and in cotyledons of seedlings grown in the light. AAT2 and AAT5 were detected in all tissues examined. A soybean leaf cDNA clone, pSAT17, was identified by hybridization to a carrot AAT cDNA clone at low stringency. pSAT17 had an open reading frame which could encode a 50 581 Da protein. Alignment of the deduced amino acid sequence from the pSAT17 open reading frame with mature AAT protein sequences from rat disclosed a 60 amino acid N-terminal extension in the pSAT17 protein. This extension had characteristics of a plastid transit peptide.A plasmid, pEXAT17, was constructed which encoded the mature protein lacking the putative chloroplast transit polypeptide. Transformed Escherichia coli expressed a functional soybean AAT isozyme, which comigrated with the soybean AAT5 isozyme during agarose gel electrophoresis. Differential sucrose gradient sedimentation of soybean extracts indicated that AAT5 specifically cofractionated with chloroplasts. Antibodies raised against the pEXAT17-encoded AAT protein specifically reacted with the AAT5 isozyme of soybean and not with any of the other isozymes, indicating that the soybean cDNA clone, pSAT17, encodes the chloroplast isozyme, AAT5.     

Adenylate kinase isoenzyme patterns in normal and neoplastic human lung, and in various adult as compared to fetal rat tissues

The isozyme pattern and total activity of adenylate kinase were studied in normal adult and fetal human and rat tissues using starch gel electrophoresis. Three adenylate kinase isoenzymes were identified in human tissues. Although normal adult lung exhibited higher adenylate kinase activity than did its fetal or neoplastic variant, isozyme patterns in the three types of tissues were indistinguishable from each other and from that in fetal human liver. The pattern of these three isozymes in rat lung (as in spleen) also did not change between fetal and adult life. However, adult kidney and heart of this species did appear to contain isozymes not present in fetal life. Brain (both adult and fetal) was striking different from all the other tissues in that it contained only one adenylate kinase isozyme. The total adenylate kinase activity per gram of adult rat liver, kidney and lung was significantly higher than in the cognate fetal organs, whereas that in brain or spleen did not change with age. The activity in adult heart (similar to the fetal one) was higher than in any other tissue examined.     

Genetic diversity and structure in a natural Elymus caninus population from Denmark based on microsatellite and isozyme analyses

 Genetic diversity in a natural Elymus caninus population from Denmark was assessed using isozyme and microsatellite markers. A total of 119 individuals from 46 maternal plants were assayed. Microsatellite loci are shown to display higher levels of variation than isozyme loci. The mean number of alleles per locus was 1.04 for isozymes and 1.38 for microsatellites. The percentage of polymorphic loci for isozymes and microsatellites was 4.7% and 23.6% across the maternal plant, respectively. The genetic diversity at population level was 0.1 for isozymes, and 0.63 for microsatellites. The mean genetic diversity at maternal plant level was 0.027 for isozyme loci and 0.117 for microsatellite loci. The average of total allozyme diversity (H_T) was 0.22. The average of total microsatellite diversity was 0.56. Isozyme and microsatellite variation showed the same pattern of differentiation between maternal plants. More than 75% total genetic diversity was found among maternal plants. About 25% total genetic diversity was detected within maternal plants. Ten (22.7%) maternal plants produced heterozygous offspring at allozyme loci, and 30 (68.2%) maternal plants gave heterozygous offspring at microsatellite loci. Both types of markers revealed a relatively high genetic diversity in this population. Received November 7, 2000 Accepted February 15, 2001     

Analysis of neuraminidase isozyme phenotypes in mammalian tissues: an electrophoretic approach

A simple cellulose acetate electrophoretic method for visualizing mammalian neuraminidase isozymes has been developed. Application of the method with rat and mouse liver extracts reveals the presence of two distinct isozymes in each species. Each isozyme exhibits tremendous variation in activity between inbred strains. The two isozymes vary independently of one another suggesting that their activities are controlled by different genes. The neuraminidase phenotypes detected in these inbred strains via electrophoresis are consistent with published accounts of neuraminidase phenotypes determined fluorometrically in whole liver homogenates, but also indicate the presence of a second isozyme not perceived by this other procedure.     

On the determination of isozyme levels in preparations containing cytoplasmic and mitochondrial aspartate aminotransferase.

A spectrophotometric assay has been developed for the determination of the content of each isozyme of aspartate transaminase (L-aspartate:2-oxoglutarate aminotransferase, EC 2.6.1.1) in physiological fluids or tissue extracts. The methods relies on the ability of adipate, at low pH and ionic strength to inhibit the cytoplasmic isozyme but not the one from mitochondria. Two assays are necessary, one at pH 8.0 which measures the content of both isozymes and another at low pH which measures primarily the amount of mitochondrial isozyme. Results obtained by this simple procedure match those in which each isozyme is inhibited by its antibody. The validity of the results obtained by the new method was tested at different ratios of cytoplasmic:mitochondrial isozyme and with tissue extracts. Since the amounts of each isozyme determined by radial immunodiffusion match those values gathered by following enzymatic activity, it is concluded that the quantity of each isozyme obtained from its respective catalytic activity must represent the total protein content of each isozyme in a given sample.