Relative mobility and activity of leaf malate dehydrogenase in flax(Linum usitatissimum) genotrophs and genotypes

Malate dehydrogenase (MDH) band relative mobility (R _m) and activity were examined in leaf extracts of Durrant's flax genotrophs, L and S, and flax genotypes, R and M. MDH activity in leaves from just below the inflorescence was higher in the two smaller, sparsely branched plant types, S and M, than in the larger, more branched plant types, L and R. The MDH electrophoretic banding pattern in flax leaf extracts consisted of three major anionic bands, MDH-1, MDH-2, and MDH-3. NoR _m differences were detected between corresponding isozymes of genotypes R and M. For the genotrophs, however, all three bands of S migrated faster than the corresponding bands of L. Codominance was absent in F₁ hybrids; SR _m was dominant for MDH-2 and MDH-3 and LR _m was dominant for MDH-1. The observations suggest that MDHR _m in L and S may be controlled by a modifier locus (or loci). Previous studies indicate that a modifier locus may also control heritable genotrophic differences in peroxidase (PER) and acid phosphates (AP)R _m. The three enzyme systems are compared.The financial assistance of the Natural Sciences and Engineering Research Council of Canada is acknowledged with thanks.     

Rm Differences in Leaf Malate Dehydrogenases of Flax (Linum usitatissimum) Genotrophs: Apparent Developmental Effects

Fieldes, M. A. and Gray, T. J. 1988. R_m differences in leafmalate dehydrogenases of flax (linum usitatissimum) genotrophs:apparent developmental effects.—J. exp. Bot. 39: 499–509. Malate dehydrogenase (MDH) isozyme relative mobility (R_m) wasexamined in leaf extracts of Durrant's large (L) and small (S)flax genotrophs. Within both L and S there were differencesin R_m between leaves sampled from different positions down themain stem and between leaves sampled from plants of differentages. For leaves sampled from plants which were at the onsetof flowering, the R_m differences from the apex to the base ofthe stem showed similar trends in L and S. However, the neteffect of the trend for L was a linear increase in R_m from apexto base, which did not occur in S. The changes in R_m which occurredin apical leaves as the plants aged were also different in Land S; R_mdecreased in L and increased in S during the growthperiod just prior to flowering. The possible relationship betweenthese differences in the changes in MDH R_m within L and S, previouslyreported differences in the changes in peroxidase (PER) isozymeR_m and the morphological/developmental differences between Land S is discussed. In addition, the experimentation demonstratedthat ‘negative’ bands detected in MDH-stained gelsunder certain staining conditions appear to correspond to PERisozymes and effectively mean that PER and MDH isozyme R_m'scan be obtained from the same electrophoretic gels. Key words: Malate dehydrogenase, peroxidase, relative mobility, flax     

Segregation of the isozymes of flax genotrophs

The segregation of isozymes of peroxidase and acid phosphatase in progenies of crosses between large (L) and small (S and L₆) flax genotrophs has been determined. The peroxidase isozymes segregated as expected on a simple Mendelian model with a dominant and a recessive allele and with the L genotroph being a homozygous dominant. All the peroxidase isozymes which differed segregated together, so the isozymes are controlled by either a single locus or closely linked loci. The acid phosphatase isozymes in the F₁ were all L type, but the segregations observed in the F₂ were not always consistent with a simple Mendelian model.     

Relative shifts in mobility in anionic peroxidase isoenzymes between stem base and apex of flax genotrophs

Anionic peroxidase isoenzymes, separated on acrylamide gels, were examined in two flax genotrophs and in their reciprocal F₂ hybrids. Isoenzyme 1 exhibited a significant difference in R_m between stem base and apex and there was a gradient of decreasing R_m and activity between base and apex. Isoenzyme 2 displayed only the activity gradient. The parents differed significantly in the R_m's and activities of isoenzymes 1 and 2, and the F₂'s showed complete dominance of the L parent for R_m, with activities being approximately intermediate.     

Molecular weight and net charge of peroxidase isozymes in F1 hybrids between L and S flax genotrophs

In the F₁ hybrids between Durrant's L and Durrant's S flax genotrophs, the relative mobilities of the anionic peroxidase isozymes were essentially the same as those in the L parent. The isozymes in both parents and their F₁'s were compared over a range of acrylamide gel concentrations, with plots of log relative mobility against gel concentration. Plots of comparative mobility, relative to the internal standard hemoglobin, against concentration were also examined. Both approaches provided evidence that apparent molecular weight modifications underlay the shift in mobility between the parents and the resemblance of the F₁'s to L, the parent which was homozygous for the dominant alleles controlling the mobility shift for at least two of the isozymes.     

Variation in the isozymes of flax (Linum usitatissimum) genotrophs

Peroxidase, esterase, and acid phosphatase isozymes of environmentally induced L and S genotrophs, nuclear DNA reversion types, and the orginal plastic (Pl) type of the flax variety Stormont Cirrus have been compared by polyacrylamide gel electrophoresis. Differences were observed in particular line was not correlated with the nuclear DNA amount. The relationship between the isozyme pattern and the phenotypes of the lines in which they are expressed is discussed.     

Possible posttranslational modification,and its genetic control,in flax genotroph isozymes

Environmentally induced flax genotrophs L and S show heritable shifts in the relative mobilities of peroxidase, esterase, and acid phosphatase isozymes, plus a number of nonspecific glycoproteins. All L isozymes migrated faster than corresponding S isozymes in 10% acrylamide gels. Various aspects of these shifts are reviewed here; it is proposed that posttranslational modification, probably of the carbohydrate moieties of these glycoproteins, underlies the shifts. This proposal is discussed in relation to the switch model for genotroph induction.The financial assistance of the Natural Sciences and Engineering Research Council of Canada is acknowledged with thanks.     

Genetic and biochemical aspects of lactate dehydrogenase isozymes in the salmonid eye

Polyacrylamide gel electrophoresis reveals similar differences between the retinal-specific lactate dehydrogenase (LDH) isozymes of the salmon (Salmo salar L.) and the sea-trout (Salmo trutta forma trutta L.) as those previously described for the salmon and the brown trout (Salmo trutta L.). F₁ salmon × sea-trout hybrids give a classic hybrid isozyme pattern, but the F₂ hybrids all possess the parental sea-trout type pattern. Loss of part of the salmon genome in these latter hybrids is the most likely explanation. It was observed that when the individual eye isozymes of the salmon, the sea-trout, and the rainbow trout (Salmo gairdneri Richardson) were eluted from preparative polyacrylamide gels and re-electrophoresed, an apparent interconversion of certain isozyme bands occurred. This phenomenon was also evident using starch gel. However, the major cathodally migrating isozyme in each case (presumably the E4 isozyme) re-electrophoresed pure. The reasons for these interconversions are, as yet, unclear. Attempts to produce in vitro hybridization between the various isolated individual isozymes were unsuccessful. K_m pyruvate values for the different salmon isozymes were of the order expected from results already published for other teleosts.     

Isozyme expression in F1 hybrids between carp and goldfish

Interspecific genetic differences in malate dehydrogenase (MDH), lactate dehydrogenase (LDH), superoxide dismutase (SOD), and esterase (EST) isozymes in carp (Cyprinus carpio) and goldfish (Carassius auratus) were used to examine the allelic expressions in the hybrid between these species. A unique liver SOD and muscle LDH phenotype unambiguously identifies all presumed hybrid individuals. There was no evidence of F₂ or backcross phenotypes in hybrid individuals. Liver MDH and EST phenotypes in hybrids show a preferential expression of goldfish isozymes. Variation in the levels of carp liver MDH isozymes may result from the polymorphism of a regulatory mutation affecting isozyme expression, leading to gene silencing after duplication.This work was supported through NSERC (Canada) grants to James P. Bogart and John F. Leatherland.     

Indoleacetic acid oxidase activity in main stem homogenates of flax genotrophs and genotypes

The IAA-oxidase and peroxidase capabilities along the length of the main stem tissues of two flax genotrophs L and S and two flax genotypes R and M were examined in vitro. Stem gradients for peroxidase activity increased basipetally in all plant types, as did IAA-oxidase activity gradients at non-rate-limiting concentrations of Mn²⁺. Correlations between peroxidase activity and non-rate-limited IAA-oxidase activity supported the contention of dual activities on the same molecule. At rate-limiting concentrations of Mn²⁺, IAA-oxidase activity did not correlate with peroxidase activity. Plant type differences were detected in rate-limited IAA-oxidase activity. This activity was higher in the stem region immediately above the cotyledons (axillary buds) of the more branched types, L and R, than in the sparsely branched types, S and M.     

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.     

Evolution of the Vertebrate Cytosolic Malate Dehydrogenase Gene Family: Duplication and Divergence in Actinopterygian Fish

Abstract A general correlation between neural expression and negative charge in isozymes suggests charge represents an adaptation to the neural environment. Interestingly, a notable exception exists in teleost fish. Two cytosolic malate dehydrogenase (MDH) isozymes have different spatial expression patterns in certain fishes: one is expressed in all tissues and the second is expressed primarily in the eye and skeletal muscle. While the neural MDH isozyme is negatively charged, the difference in charge between the two isozymes is not as pronounced as that observed in other gene families (e.g., triosephosphate isomerase and lactate dehydrogenase). Most tetrapods express a single cytosolic MDH isozyme, and it has been demonstrated recently that the pair of isozymes found in teleosts results from a gene duplication sometime after the separation of teleosts and tetrapods, although the exact timing of this duplication has not been inferred. Phylogenetic analyses suggest that the duplication of teleost isozymes occurred during the radiation of actinopterygian fish, consistent with the timing of duplication at other loci. Using inferred amino acid sequences, we examine the pattern of change following the duplication and across the rest of the MDH gene tree. Comparison between the MDH gene family and another gene family that shows a larger charge differential among members (triosephosphate isomerase) indicates that the smaller charge difference between MDH isozymes is best explained by greater constraint on amino acid change directly following the duplication, not greater constraint across the entire gene tree. This difference in constraint might result from the wider pattern of expression of the “neural” MDH isozyme.     

Two forms of NADP-dependent malic enzyme in expanding maize leaves

Etiolated maize leaves (Zea mays L.) contain a major isozyme of NADP-dependent malic enzyme (L-malate dehydrogenase, decarboxylating, EC 1.1.1.40) having an isoelectric point of 5.28±0.03, a K_m (L-malate) 0.3–0.6 mM at pH 7.45; a broad pH optimum around pH 6.9 under the conditions of assay; a molecular weight of 280,000 (sometimes accompanied by a minor component of 150,000); and an NAD-dependent activity about 1/50 the NADP-dependent activity. This isozyme, resembling the NADP-malic enzyme of vertebrates, is labeled type 1. The dominant isozyme of young green leaves (type 2) has, however, a pI 4.90±0.03, a K_m (L-malate) 0.10–0.15 mM, a pH optimum of 8, and a molecular weight of 280,000. It is also more stable and exhibits an appreciable NAD-dependent activity (1/5–1/7 the NADP activity). Both isozymes show linear kinetics, dependence on Mn or Mg ions, similar K_m (NADP⁺), and the typical increase of K_m for L-malate with increasing pH values. Type 1 isozyme of maize is assumed to be cytosolic. Type 2 corresponds in each property to the chloroplast enzyme of bundle-sheath cells. It is present at a low level in etiolated leaves and develops to a high specific activity (up to 100 nmol min^-1 mg protein^-1 by 150 h illumination) during photosynthetic differentiation, replacing the type 1 form.Abbreviation MES 2 (N-morpholino)ethane sulfonic acid Work supported by grants from the Consiglio Nazionale delle Ricerche for years 1975 and 1976     

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.     

Differential expression of esterase and MDH isozymes during in vitro culture in maize (Zea mays L.)

Isozyme patterns of esterase and malate dehydrogenase were analyzed at different stages of in vitro culture of immature embryos and glumes of Zea mays L. viz. explant, callus formation, root formation and shoot formation. Significant changes in isoenzyme patterns of esterase and MDH were observed besides the appearance of specific and new isozymes. Specific fast migrating isozymes were noted in differentiating calli of embryo and glume calli which were absent at other stages suggesting a possible association of these isozyme patterns with in vitro differentiation.     

Isozyme gene markers in Vicia faba L.

Summary This study was conducted to assess the genetic basis of the variability observed for the glutamate oxaloacetate transaminase (GOT), Superoxide dismutase (SOD), esterase (EST), and malate dehydrogenase (MDH) isozyme systems in different open-pollinated Vicia faba varieties. Individual plants showing contrasting zymogram patterns were simultaneously selfed and cross-combined. Crossing was unsuccessful in producing progeny, and only selfed progenies were suitable for genetical analysis of isozyme variability. Three zones of GOT activity were made visible. The isozyme of GOT-2 and GOT-3 zones were dimeric and under the control of three alleles at the Got-2 locus and two alleles at the Got-3 locus, respectively. The isozymes of the GOT-1 zone did not show any variability. Three zones of SOD isozyme activity were made visible. The isozymes occurring in the SOD-1 (chloroplastic isozyme form) and SOD-2 (cytosol isozyme form) zones were dimeric and under the control of two alleles at the Sod-1 and Sod-2 loci. The isozyme visualized in the SOD-3 zone (mitochondrial isozyme form) were tetrameric and under the control of two alleles at the Sod-3 locus. Apparently the isozymes made visible in the most anodal esterase zones EST-1, EST-2, and EST-3 were monomeric, and the occurrence of two alleles at each of two different loci explained the variability observed in the EST-2 and EST-3 zones. For MDH, only two five-banded zymogram pattern types were found, and every selfed progeny showed only one of the two zymogram type, indicating that each individual possessed fixed alleles at the loci controlling MDH isozyme. Got-2, Got-3, Sod-1, Sod-2, and Sod-3 appear to be five new isozyme gene markers that can be useful in Vicia faba breeding for linkage study, varietal fingerprinting, outcrossing rate estimate, and indirect selection for quantitative characters.     

Malate Dehydrogenase Isozymes (MDH; EC 1.1.1.37) in Long-Term Callus Culture of Cereus peruvianus (Cactaceae) Exposed to Sugar and Temperature Stress

Malate dehydrogenase (MDH; EC 1.1.1.37) isozymes in long-term callus tissue culture of Cereus peruvianus were studied in starch gel electrophoresis to investigate the control of differential Mdh gene expression under sugar and temperature stress. While two cytosol MDH isozymes showed an unchanged phenotype when the callus tissues were transferred to medium maintained at 22 or 37°C and containing different concentrations of sucrose, glucose, and fructose, the different combinations of five mitochondrial MDH (mtMDH) and two microbody MDH (mbMDH) showed different MDH isozyme patterns in the callus populations. Differential expression of mtMDH isozymes seems to be modulated at the posttranslational level in callus tissues exposed to different concentrations and types of sugar and to high-temperature and low-temperature stress. An inductor effect on the expression of mbMDH isozymes was observed under stress conditions and in long-term callus tissue, and they may also present different responses.     

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.     

Differences in thermal properties of NAD malate dehydrogenase in genotypes of Lathyrus japonicus Willd (Leguminosae) from maritime and continental sites

Abstract The response of the kinetic properties of NAD malate dehydrogenase (MDH) was compared for two clones of Lathy rus japonicus Willd. collected in two contrasting climatic sites in Eastern North America. MDH from the cold adapted maritime genotype (Hudson Bay, Québec) had lower thermostability, reduced apparent (E_a) and free (ΔG^?) energy of activation and lower specific activity when compared to MDH of plants from the warm summer continental site (Lake Michigan). Electrophoretic analyses show little differentiation in the isozyme profiles of the two genotypes. Thermostability differences were primarily associated with the mitochondrial isozymes which, however, were not differentiated electrophoretically Substrate binding ability of MDH, as measured by apparent Km, was more sensitive to high assay temperature in the cold adapted maritime genotype.     

Direct response of peroxidase isozyme relative mobility to short-term environmental temperature changes in flax (Linum usitatissimum)

Abstract Flax plants were transferred from 30°C to 15°C temperatures, and then back to 30°C during their vegetative growth phase. Reciprocal transfers were also made from 15°C to 30°C, and then back to 15°C for an identical period at the same time. Plants were also retained in a constant 30°C or 15°C in growth chambers with identical lighting conditions. The reciprocal transfer period lasted 6 d. The relative mobility (R_m) of an anionic leaf peroxidase isozyme, reflecting its molecular weight/conformation and/or net charge, was monitored over a period starting before the reciprocal transfers and finishing after the return to original temperatures. Two of the four flax types which were studied showed isozyme relative mobility responses related either to the different constant temperatures, or to the transfer from 15°C to 30°C. The responses were not reversible on return to the original lower temperature. Thus, exposure to 30°C, even for a transient 6 d period, produced a one way R_m shift. This suggests a developmental switch-over in the particular form of peroxidase glycoprotein being synthesized, rather than an adaptive response triggered by external environmental changes.