Purification and characterization of cytoplasmic creatine kinase isozymes ofXenopus laevis

The soluble creatine kinase isozymes CK-II, CK-III, and CK-IV fromXenopus laevis have been purified to apparent homogeneity and their subunits characterized by means of molecular weight, peptide pattern, and dissociation-reassociation experiments. CK-III and CK-IV are homodimeric isozymes whose subunits are distinct in both molecular weight (42,000 and 41,000, respectively) andStaphylococcus aureus V₈ peptide pattern. In dissociation-reassociation experiments, those two subunits do form active heterodimeric isozymes with one another or with rabbit M-CK subunits. Hybrid CK-III/IV isozymes occur also during embryonic differentiation and in adult heart muscle, whereas most other adult tissues contain only homodimeric CK-III or CK-IV isozymes. The CK-II isozyme is a heterodimer composed of one CK-III subunit and another subunit specific to CK-II (M _r =41,000). Neitherin vivo norin vitro does this subunit seem able to form homodimers or heterodimers with CK-IV and rabbit M-CK subunits. If we take into account the apparent association of CK-I isozyme with cellular organelles, these results corroborate earlier statements and suggest that the CK isozyme system ofX. laevis is encoded by at least four differentially regulated genomic loci.     

Comparison of chorismate mutase isozyme patterns in selected plants

A wide variety of plants have been assayed to determine if they contain three isozymes of chorismate mutase (EC 5.4.99.5) as does alfalfa (Medicago sativa L.) or two isozymes, as does mung bean (Phaseolus aureus). The isozymes were separated by disc electrophoresis. All anthophyta with the exception of some closely related Leguminosae contained three isozymes of chorismate mutase. The one coniferophyta (a pine), and pterophyta (a fern) and one microphyllophyta (a Selaginella) assayed contained two isozymes of chorismate mutase. All plants assayed contained measurable chorismate mutase levels and at least two isozymes of chorismate mutase.     

Genetic basis of the major malate dehydrogenase isozymes in maize

The mitochondrial MDH isozymes in the scutellum of the mature maize (Zea mays L.) kernel are encoded by three independently inherited nuclear genes. Mdh1 is located on chromosome 8, close to the breakpoint (8L.35) of a waxy-marked reciprocal translocation between chromosomes 8 and 9. Mdh2 is located in the distal region of the long arm of chromosome 6. Mdh3 is on the long arm of chromosome 3, approximately 2.6 map units from sh2. A modifier of the mitochondrial MDH isozymes (Mmm) maps approximately 27.5 units proximal to Adh1 in the central portion of the long arm of chromosome 1. Independently assorting duplicate genes code for the soluble MDH isozymes. Mdh4 is located in the same region of chromosome 1 as Mmm, approximately 29 map units proximal to Adh1. Mdh5 maps approximately 20 units distal to a2 in the short arm of chromosome 5.——Intergenic and interallelic heterodimer formation occurs among gene products that occupy the same subcellular compartment. MDH isozymes were purified and analyzed by native-SDS two-dimensional polyacrylamide gel electrophoresis. The proposed mitochondrial MDH intergenic heterodimer bands were found to be composed of two subunits, which differ in their migrations on SDS gels; whereas, genetically defined homodimers contained only one type of subunit.——This evidence is discussed in terms of two genetic models proposed for the maize mitochondrial MDH isozymes.     

Human DNA topoisomerases IIα and IIβ can functionally substitute for yeastTOP2 in chromosome segregation and recombination

The ability of the human DNA topoisomerase IIα and IIβ isozymes to complement functional defects conferred by conditionaltop2 mutations inSaccharomyces cerevisiae has been investigated. At the restrictive temperature,top2 strains show multiple abnormalities, including an inability to complete mitotic and meiotic division owing to a defect in chromosome segregation, and hyper-recombination within the repetitive rDNA gene cluster. We show that the human topoisomerases IIα and IIβ can each support both vegetative growth and the production of viable spores in atop2-4 mutant at the restrictive temperature. Similarly, both human isozymes can rescue a strain carrying atop2 gene disruption, and suppress hyper-recombination within the rDNA gene cluster. We conclude that the human topoisomerase IIα and IIβ isozymes are functionally interchangeable with yeast topoisomerase II and suggest that any isozyme-specific roles in human cells are likely to be dependent upon factors other than inherent differences in catalytic ability between the α and β isozymes.     

Isolation and properties of chloroperoxidase isozymes

A new purification method for chloroperoxidase from Caldariomyces fumago is described. This method involves dialysis, alumina gel adsorption, DEAE-cellulose chromatography at pH 6, and then at pH 3.85 and crystallization. Two isozymes have been isolated and one has been crystallized. The MWs estimated by gel filtration are 46000 for chloroperoxidase A and 40000 for chloroperoxidase B. The guaiacol peroxidation catalysed by these isozymes is proportional to their chlorination activity.     

Properties of genetically polymorphic isozymes of alcohol dehydrogenase in Drosophila melanogaster

Studies of the isozymes produced by alternative alleles at the alcohol dehydrogenase locus of Drosophila melanogaster indicate that the ADH F enzyme is more active but less stable than the ADHS enzyme. The difference in stability is manifested in the responses to various conditions of temperature, pH, and protein concentration. The two enzymes also appear to differ in their substrate specificities. It is clear that the differences of primary structure involved in the ADH polymorphism can have profound effects on the biological activity of the molecule.     

Anisakis,Phocanema, Contracaecum, and Sulcascaris Spp.: Electrophoresis and thermostability of alcohol and malate dehydrogenases from larvae

Electrophoretic surveys were conducted on individual larvae of four anisakine nematode genera: Anisakis, Phocanema, Contracaecum, and Sulcascaris. The larval worms were obtained from a variety of fish and molluscan hosts from widely dispersed geographic regions. Of several enzymes detected, constant and apparently species-specific electrophoretic patterns were obtained for alcohol dehydrogenase (ADH, alcohol:NAD oxidoreductase, EC 1.1.1.1) and malate dehydrogenase (MDH, l-malate: NAD oxidoreductase, EC 1.1.1.37). ADH, in all but Sulcascaris sp., possessed two isozymes, the slower of which was sensitive to temperature and inhibitors. Failure of preelectrophoretic treatment with NAD to cause interconversion of these isozymes suggests that they are products of separate genetic loci. Both isozymes were maximally active with isopropanol, sec-butanol, and amyl alcohol. Within a given species, ADH showed negligible variation (i.e., apparent genetic polymorphism) with respect to individual larvae, site of larvae in the host, or geographical origin of the host. MDH from Anisakis, Sulcascaris, and Phocanema spp. possessed one, two, and three bands of activity, respectively; MDH is highly thermostable in Anisakis sp. but not in the other species.     

Dissociation, reassociation, and purification of plastid and cytosolic phosphoglucose isomerase isozymes

The plastid and cytosolic isozymes of the dimeric enzyme phosphoglucose isomerase (EC 5.3.1.9) from spinach (Spinacia oleracea) and cauliflower (Brassica oleracea) were purified to apparent homogeneity. The isozymes from sunflower (Helianthus annuus) and Clarkia xantiana were partially purified. When subunits from two electrophoretically distinguishable cytosolic isozymes, either from the same or from different species, were dissociated and allowed to reassociate in each other's presence, an active hybrid enzyme, consisting of one subunit of each type, was formed in addition to the two original homodimers. Active hybrid enzymes were also formed by dissociation and reassociation of plastid isozymes. Hybrid molecules were not produced between the plastid and cytosolic subunits, suggesting that they are not able to bind with each other. Additional differences between the plastid and cytosolic isozymes are described.     

Comparison of pyruvate decarboxylases from Saccharomyces cerevisiae and Komagataella pastoris (Pichia pastoris)

Pyruvate decarboxylases (PDCs) are a class of enzymes which carry out the non-oxidative decarboxylation of pyruvate to acetaldehyde. These enzymes are also capable of carboligation reactions and can generate chiral intermediates of substantial pharmaceutical interest. Typically, the decarboxylation and carboligation processes are carried out using whole cell systems. However, fermentative organisms such as Saccharomyces cerevisiae are known to contain several PDC isozymes; the precise suitability and role of each of these isozymes in these processes is not well understood. S. cerevisiae has three catalytic isozymes of pyruvate decarboxylase (ScPDCs). Of these, ScPDC1 has been investigated in detail by various groups with the other two catalytic isozymes, ScPDC5 and ScPDC6 being less well characterized. Pyruvate decarboxylase activity can also be detected in the cell lysates of Komagataella pastoris, a Crabtree-negative yeast, and consequently it is of interest to investigate whether this enzyme has different kinetic properties. This is also the first report of the expression and functional characterization of pyruvate decarboxylase from K. pastoris (PpPDC). This investigation helps in understanding the roles of the three isozymes at different phases of S. cerevisiae fermentation as well as their relevance for ethanol and carboligation reactions. The kinetic and physical properties of the four isozymes were determined using similar conditions of expression and characterization. ScPDC5 has comparable decarboxylation efficiency to that of ScPDC1; however, the former has the highest rate of reaction, and thus can be used for industrial production of ethanol. ScPDC6 has the least decarboxylation efficiency of all three isozymes of S. cerevisiae. PpPDC in comparison to all isozymes of S. cerevisiae is less efficient at decarboxylation. All the enzymes exhibit allostery, indicating that they are substrate activated.     

Enolase isozymes from Ricinus communis: Partial purification and characterization of the isozymes

The plastid and cytosolic isozymes of enolase from developing endosperm of castor oil seeds, Ricinus communis L. cv. Baker 296, were separated and partially purified. Each purified isozyme had a specific activity of approximately 200 μmol min^?1 mg protein. The isozymes have similar pH optima for the forward reaction, but different optima for the reverse reaction. The divalent metal specificity is the same for both isozymes. In addition to differences in charge, the isozymes can be distinguished by their different kinetic constants, thermostability and sensitivity to fluoride inhibition. Antibodies against yeast enolase isozyme I cross-react with Ricinus plastid enolase but not with the cytosolic isozyme.     

Expression of lactate dehydrogenase phenotypes in intraspecific and interspecific matings of two species of Xenopus

Starch gel electrophoresis has been used to examine lactate dehydrogenase phenotypes in two species of Xenopus and their hybrids obtained from reciprocal crosses. The patterns are complex, consisting of as many as 18 bands in some material. Differences between laevis and mulleri isozymes allow an evaluation of the contribution of both parents to the phenotypes of their hybrid offspring, and the determination of approximate times of paternal allele expression. The phenotype of early embryos resembles that of the maternal parent until hatching, when evidence of paternal influence is first apparent. Regardless of the early appearance of paternal enzyme, reciprocal hybrids bear a stronger resemblance to the maternal parent until well after tadpole growth begins. Once this maternal effect disappears, both laevis and mulleri appear to contribute to the LDH phenotype without predominance of the isozymes of either species. Evidence for the possible formation of “hybrid” enzymes consisting of subunits of both species in one active enzyme molecule is presented. Expression of LDH phenotype is variable in the unfertilized eggs of fertile hybrid females.     

Identification of amino acid residues responsible for different GTP preferences of human glutamate dehydrogenase isozymes

Human glutamate dehydrogenase isozymes (hGDH1 and hGDH2) differ markedly in their inhibition by GTP. These regulatory preferences must arise from amino acid residues that are not common between hGDH isozymes. We have constructed chimeric enzymes by reciprocally switching the corresponding amino acid segments 390-465 in hGDH isozymes that are located within or near the C-terminal 48-residue antenna helix, which is thought to be part of the regulatory domain of mammalian GDHs. These resulted in triple mutations in amino acid sequences at 415, 443, and 456 sites that are not common between hGDH1 and hGDH2. The chimeric enzymes did not change their enzyme efficiency (k_cat/K_m) and expression level. Functional analyses, however, revealed that the chimeric mutants almost completely acquired the different GTP regulatory preference between hGDH isozymes. These results suggest that the 415, 443, and 456 residues acting in concert are responsible for the GTP inhibitory properties of hGDH isozymes.     

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.     

Identification of a selective inhibitor of murine intestinal alkaline phosphatase (ML260) by concurrent ultra-high throughput screening against human and mouse isozymes

Alkaline phosphatase (AP) isozymes are present in a wide range of species from bacteria to man and are capable of dephosphorylation and transphosphorylation of a wide spectrum of substrates in vitro. In humans, four AP isozymes have been identified—one tissue-nonspecific (TNAP) and three tissue-specific—named according to the tissue of their predominant expression: intestinal (IAP), placental (PLAP) and germ cell (GCAP) APs. Modulation of activity of the different AP isozymes may have therapeutic implications in distinct diseases and cellular processes. For instance, changes in the level of IAP activity can affect gut mucosa tolerance to microbial invasion due to the ability of IAP to detoxify bacterial endotoxins, alter the absorption of fatty acids and affect ectopurinergic regulation of duodenal bicarbonate secretion. To identify isozyme selective modulators of the human and mouse IAPs, we developed a series of murine duodenal IAP (Akp3-encoded dIAP isozyme), human IAP (hIAP), PLAP, and TNAP assays. High throughput screening and subsequent SAR efforts generated a potent inhibitor of dIAP, ML260, with specificity for the Akp3-, compared to the Akp5- and Akp6-encoded mouse isozymes.     

Isozymes of beta-N-Acetylhexosaminidase from Pea Seeds (Pisum sativum L.)

Four isozymes of β-N-acetylhexosaminidase (β-NAHA) from pea seeds (Pisum sativum L.) have been separated, with one, designated β-NAHA-II, purified to apparent homogeneity by means of an affinity column constructed by ligating p-aminophenyl-N-acetyl-β-d-thioglucosaminide to Affi-Gel 202. The other three isozymes have been separated and purified 500- to 1750-fold by chromatography on Concanavalin A-Sepharose, Zn²⁺ charged immobilized metal affinity chromatography, hydrophobic chromatography, and ion exchange chromatography on CM-Sephadex. All four isozymes are located in the protein bodies of the cotyledons. The molecular weight of each isozyme is 210,000. β-NAHA-II is composed of two heterogenous subunits. The subunits are not held together by disulfide bonds, but sulfhydryl groups are important for catalysis. All four isozymes release p-nitrophenol from both p-nitrophenyl-N-acetyl-β-d-glucosaminide and p-nitrophenyl-N-acetyl-β-d-galactosaminide. The ratio of activity for hydrolysis of the two substrates is pH dependent. The K_m value for the two substrates and pH optima of the isozymes are comparable to β-NAHAs from other plant sources.     

Studies on adenosine triphosphate transphosphorylases. XVII. A physicochemical comparison of the ATP-creatine transphosphorylase (creatine kinase) isozymes from man,calf, and rabbit

All of the creatine kinase isozymes from human, calf, and rabbit brain and muscle are composed of two noncovalently linked polypeptide chains, based upon sedimentation equilibrium analyses in the presence and absence of disruptive agents. The brain-type isozymes of man, calf, and rabbit proved to be slightly heavier than the muscle types. Various physicochemical properties of the isozymes are recorded. Each group of isozymes, i.e., the muscle, hybrid (muscle-brain), and brain isozymes from man, calf, and rabbit, showed similar electrophoretic behavior, although isoelectric points were not precisely identical for the muscle and hybrid types. Theoretical titration curves constructed from amino acid compositions of the calf isozymes showed reasonable agreement between their calculated and measuredpI ₀ values (isoelectric point extrapolated to zero ionic strength). The three native muscle isozymes and brain isozymes all contain two reactive sulfhydryl groups per mole or one per polypeptide chain of their two-chain proteins, which may be titrated with 5,5′-dithiobis (2-nitrobenzoic acid); and under acidic conditions, quantitative titrations with 4,4′-dithiodipyridine yield a total of ten- SH groups per mole of each brain-type and eight- SH groups per mole of muscle-type isozyme in the case of man, calf, and rabbit. A comparison of their amino acid compositions and tryptic peptide maps shows that there is only a slightly greater degree of homology between the individual isozymes of the same type (muscle type or brain type) than between the muscle- and brain-type isozymes of the same species.     

Plant triose phosphate isomerase isozymes : purification, immunological and structural characterization, and partial amino Acid sequences

We report the first complete purifications of the cytosolic and plastid isozymes of triose phosphate isomerase (TPI; EC 5.3.1.1) from higher plants including spinach (Spinacia oleracea), lettuce (Lactuca sativa), and celery (Apium graveolens). Both isozymes are composed of two isosubunits with approximate molecular weight of 27,000; in spinach and lettuce the plastid isozyme is 200 to 400 larger than the cytosolic isozyme. The two isozymes, purified from lettuce, had closely similar amino acid compositions with the exception of methionine which was four times more prevalent in the cytosolic isozyme. Partial amino acid sequences from the N-terminus were also obtained for both lettuce TPIs. Nine of the 13 positions sequenced in the two proteins had identical amino acid residues. The partial sequences of the plant proteins showed high similarity to previously sequenced animal TPIs. Immunological studies, using antisera prepared independently against the purified plastid and cytosolic isozymes from spinach, revealed that the cytosolic isozymes from a variety of species formed an immunologically distinct group as did the plastid isozymes. However, both plastid and cytosolic TPIs shared some antigenic determinants. The overall similarity of the two isozymes and the high similarity of their partial amino acid sequences to those of several animals indicate that TPI is a very highly conserved protein.