Temperature-dependent kinetic variation among phosphoglucose isomerase allozymes from the wing-polymorphic water strider, Limnoporus canaliculatus

Phosphoglucose isomerase (PGI) allozymes were isolated from the wing- polymorphic water strider, Limnoporus canaliculatus, and were characterized biochemically with respect to temperature-dependent kinetic and thermostability properties. At higher temperatures, the allozymes exhibited significant differences in Michaelis constant (Km) values for substrates of both the forward and reverse reaction directions. Results were consistent with expectations of adaptive kinetic differentiation based on the latitudinal variation of PGI allele frequencies. PGI genotypes also differed with regard to maximal velocity (Vmax)/Km ratios at higher temperatures. These differences were due primarily, if not exclusively, to allozyme-dependent variation in Km values. The allozymes also exhibited dramatic differences in thermostability. However, no thermostability differences were observed when the substrate analogue 6-phosphogluconate was present in the incubation medium. The data from this study, together with data from Mytilus edulis and Metridium senile on temperature-dependent kinetic variation among PGI allozymes, form a consistent picture of natural selection influencing the clinal variation of alleles at this locus in these three phylogenetically distant organisms. More definitive support of this hypothesis, however, must await additional studies on the physiological effects of the allozymic variation as well as direct measurements of fitness differences among the enzyme genotypes.      

Inheritance and linkage relationships of ten isozyme genes in hazelnut

Summary The inheritance of 6-phosphogluconate dehydrogenase (6PGD), malate dehydrogenase (MHD), aconitase (ACO), phosphoglucomutase (PGM), phosphoglucoisomerase (PGI), and glutamate-oxalacetate transaminase (GOT) polymorphic isozymes was studied in leaf extracts of nine hazelnut progenies using horizontal starch gel electrophoresis. Evidence of Mendelian inheritance was obtained for ten loci: 6-Pgd-2, Mdh-1, Aco-1, Aco-2, Pgm-1, Pgm-2, Pgm-3, Pgi-2, Pgi-3, and Got-2, which permitted the analysis of 28 alleles (2.8 per locus). The presence of null alleles was detected in Pgm-1 and Pgm-3. Joint segregation analysis of pairs of isozymes revealed four linkages: Mdh-1-Pgi-2, Aco-2-Pgm-2, Pgm-1-Pgm-3, and 6Pdg-2-Pgm-2.     

Adaptative features of enzymes from family sciaenidae--II. Studies on phosphoglucose isomerase (PGI) of fishes from the south coast of Uruguay

1. The electrokinetic and thermostability properties of phosphoglucose isomerase (PGI) in three species of temperate fishes (Perciformes, Acanthopterygii)--Cynoscion striatus, Macrodon ancylodon and Micropogonias furnieri--have been analyzed in order to study the adaptative 2. Unlike most diploid fishes the PGI of these species seemed to be encoded by three PGI loci. 3. The subunits encoded by these loci occurred at different levels in the different tissues and organs analyzed. 4. Genetic variants at two loci (Pgi-A and Pgi-B2) were detected in Cynoscion striatus, and at one (Pgi-A) in Micropogonias furnieri. 5. The product of these loci could be separated in three PGI regions based on their electrophoretic distribution and thermostability properties. 6. The more anodal region (including isozymes and allozymes) was more thermolabile than the less anodal one, which is predominant in a single tissue skeletal muscle. 7. Relative activities of PGI isozymes were compared by Klebe's method to determine pattern of divergence of duplicated gene expression in the three species studied.     

Duplicated phosphoglucose isomerase genes in avocado

Summary Avocado (Persea americana) cultivars were assayed for phosphoglucose isomerase (PGI) isozymes using starch gel electrophoresis. Three PGI genes were identified: one monomorphic locus, Pgi-I, coding for the plastid isozyme and two independently assorting loci, Pgi-2 and Pgi-3, coding for the cytosolic isozymes. The genetic analysis was based on comparisons of PGI zymograms from somatic and pollen tissue and on Mendelian analysis of progeny from selfed trees. The isozymic variability for PGI can be used for cultivar identification and for differentiating between hybrid and selfed progeny in avocado breeding.     

Glucosephosphate isomerase (GPI) of the teleostFundulus heteroclitus (linnaeus): Isozymes, allozymes and their physiological roles

Summary In order to evaluate the role of glucose-phosphate isomerase (GPI) inFundulus heteroclitus, the isozymes and allozymes were purified and some of their physical and kinetic properties determined.Isozymes were purified from both liver (GPI-B) and muscle (GPI-A) tissue (Tables 1, 2). Gel filtration of the native enzyme and SDS-polyacrylamide gel electrophoresis indicated that all forms are dimers of approximately 110,000 Daltons (Figs. 4, 5). Although thermal stability studies revealed no differences between the allozymes, the isozymes were clearly different (Figs. 6, 7). Kinetic analysis showed further differences between isozymes inK _m for substrate andK _I for 6-phosphogluconate (Figs. 8, 9; Table 3). No significant differences were found between the allozymes of the B-locus under the conditions employed in this study.Based on the tissue specificities and the functional differences between isozymes, we propose a possible regulatory role for GPI-B inF. heteroclitus. The sensitivity of this isozyme to 6-phosphogluconate inhibition may allow GPI-B to act as a regulatory enzyme in the partitioning of carbon flow between glycolysis and the hexose monophosphate shunt.Abbreviations me -mercaptoethanol - F6P fructose-6-phosphate - G1P glucose-1-phosphate - G6P glucose-6-phosphate - G6Pase glucose-6-phosphatase - G6PDH glucose-6-phosphate dehydrogenase - GPI glucosephosphate isomerase - HK hexokinase - HMP hexose monophosphate shunt - 6PG 6-phosphogluconate - PGM phosphoglucomutase Supported in part by: NSF grants DEB-76-19877 to D.A.P. and PCM 77-16838 to B.D.S., NIH Biomedical grant 5-50-7RR07-041 and a grant from the National Geographic Society. G.D.S. and R.V.B. are NIH trainees supported by a training grant (No. HD00139) to the Department of Biology, The Johns Hopkins University. This is contribution No. 1052 from the Department of Biology     

Central cell nuclear-cytoplasmic incongruity:a mechanism for segregation distortion in advanced backcross and selfed generations of (Allium cepa L. x Allium fistulosum L.) x A. cepa interspecific hybrid derivatives

A model is presented as an explanation for an anomaly observed in germination and establishment and isozyme segregation patterns in Allium cepa x A. fistulosum F2BC3 populations generated in an introgression-breeding program. The F1BC3 parent of these populations was selected for its heterozygous PGI phenotype, Pgi-1(2/3); Pgi-1(2) was inherited from an A. cepa (Ac) seed parent and Pgi-1(3) from an A. fistulosum (Af) pollen parent. Germination and establishment was recorded for the F2BC3 progeny population. Segregation of Ac and Af Pgi-1 alleles was investigated in F2BC3 seeds and embryo and endosperm tissue was isolated and tested for isozyme expression. A pooled goodness-of-fit test of the segregation of Pgi-1 alleles in the populations to the expected Mendelian 1:2:1 ratio using the chi-square statistic gave a chi2 = 185.9, well beyond the accepted limits at 2 degrees of freedom. The 1:2:1 ratio expected for simple Mendelian inheritance was rejected, while a pooled chi-square goodness-of-fit test of the segregation of Pgi-1 alleles in the populations fit a 1:1 ratio with a chi2 = 0.203, based on the incongruity model. We present here the central cell nuclear-cytoplasmic incongruity hypothesis to explain the observed anomalies.     

Effects of temperature on physiology and reproductive success of a montane leaf beetle: implications for persistence of native populations enduring climate change

Understanding how climate change impacts natural systems requires investigations of the effects of environmental variation on vulnerable species and documentation of how populations respond to change. The willow beetle Chrysomela aeneicollis is ideal for such studies. It lives in California's Sierra Nevada on the southern edge of its worldwide range. Beetles experience elevated air temperatures during summertime egg laying and larval development. Exposure to these temperatures causes physiological stress, which may reduce reproductive success and endanger populations. The glycolytic enzyme phosphoglucose isomerase (PGI) is a marker of temperature adaptation in C. aeneicollis. PGI allele frequency varies across a latitudinal gradient: allele 1 is common in Rock Creek (RC), which is cooler and to the north, and allele 4 is common in Big Pine Creek (BPC), which is warmer and to the south. In populations that are intermediate in geography and climate (e.g., Bishop Creek [BC]), PGI-4 frequency increases from north to south such that alleles 1 and 4 are in relatively equal frequency in southern BC. Over the past decade, Sierra Nevada beetle populations have colonized high elevations and have become extinct at lower elevations where they were once common. In BC, the magnitude of PGI allele frequency fluctuations among life-history stages is related to maximal air temperature, with the frequency of PGI-4 increasing after the hottest part of summer. To identify mechanisms that may cause shifts in PGI allele frequency, we measured metabolic rate and fecundity for beetles collected at BC. Metabolic rate of males and females was measured at 20 degrees and 36 degrees C using flow-through respirometry. To measure laboratory fecundity, mating pairs were acclimated for 4 h each afternoon at a control temperature (20 degrees C) or at mildly elevated temperatures (26 degrees or 32 degrees C) and number of eggs laid was counted daily for 24 d, after which tissue levels of 70-kD heat shock proteins (Hsp70) were determined. Previous studies had demonstrated differences in Hsp70 expression among PGI genotypes at these temperatures. To measure field fecundity, mating pairs from BC were transplanted to similar elevations in BPC, BC, and RC and were monitored in situ for 24 d. Metabolic rate was higher for PGI 4-4 genotypes than for PGI 1-4 or PGI 1-1 individuals at 36 degrees C but not at 20 degrees C. In contrast, laboratory fecundity was greatest for females possessing PGI-1, independent of acclimation temperature. At the end of the laboratory fecundity experiment, Hsp70 expression was positively related to fecundity, suggesting minimal reproductive cost of upregulation of heat shock proteins in response to mild heat stress. In the field, fecundity was highest for PGI 1-1 and PGI 1-4 individuals in RC and PGI 4-4 individuals in BPC and was similar for all genotypes in BC. Thus, fecundity in nature was greatest for the genotypes that were most common in each area. Taken together, data reported here suggest that hot, dry summers in the Sierra Nevada may result in an increase in frequency of the PGI-4 allele and shifts to higher elevations for C. aeneicollis populations.     

Balancing Selection on Electrophoretic Variation of Phosphoglucose Isomerase in Two Species of Field Cricket: Gryllus Veletis and G. Pennsylvanicus

Two species of crickets, Gryllus veletis and G. pennsylvanicus, share six electrophoretic mobility classes for the enzyme phosphoglucose isomerase (PGI), despite evidence from other genetic markers that the two species are not closely related within eastern North American field crickets. Moreover, the frequencies of the two most common PGI electrophoretic classes (PGI-100 and PGI-65) covary in sympatric populations of these species in the eastern United States, suggesting that PGI may be subject to trans-specific balancing selection. To determine the molecular basis of the electrophoretic variation, we characterized the DNA sequence of the Pgi gene from 29 crickets (15 G. veletis and 14 G. pennsylvanicus). Amino acid substitutions that distinguish the electrophoretic classes are not the same in the two species, and there is no evidence that specific replacement substitutions represent trans-specific polymorphism. In particular, the amino acids that diagnose the PGI-65 allele relative to the PGI-100 allele differ both between G. veletis and G. pennsylvanicus and within G. pennsylvanicus. The heterogeneity among electrophoretic classes that covary in sympatric populations coupled with analysis of patterns of nucleotide variation suggest that Pgi is not evolving neutrally. Instead, the data are consistent with balancing selection operating on an emergent property of the PGI protein.     

CHLOROPLASTIC AND CYTOSOLIC ISOZYMES OF THE HOMOSPOROUS FERN ATHYRIUM FILIX-FEMINA L

Intact chloroplasts isolated from mature leaf tissue of the homosporous fern Athyrium filixfemina were osmotically ruptured and subjected to starch gel electrophoresis in side by side comparisons with whole leaf extracts. The single enzyme activities of reportedly cytosolic [NADP]IDH and [NADP]ME were not expressed in the chloroplast fraction, and these were used as controls ensuring the cytosol-free quality of the chloroplast preparations. Isozymes F1,6DP-1, PGI-1, PGM-1, 6PGDH-1, ALDO-1, TPI-2, [NAD(P)]G3PDH-1, and [NAD(P)]G3PDH-2 are active in the chloroplast fraction, whereas Fl,6DP-2, PGI-2, PGM-2, 6PGDH-2, ALDO-2, and TPI-1 were lacking from the chloroplast fraction and are considered cytosolic. The single enzyme activities observed for AAT and SkDH, are chloroplastic. These data indicate that the two isozymes of certain enzymes in Athyrium filix-femina are not the products of duplicated loci resulting from polyploidy, but are distinct and subcellularly compartmentalized as demonstrated in heterosporous plants. Thus A. filix-femina is functionally diploid in spite of its high chromosome number of 2n = 80.     

Phosphoglucose isomerase gene duplication in the bony fishes: An evolutionary history

Electrophoretic patterns of phosphoglucose isomerase (PGI) in bony fishes provide strong evidence for a model of genetic control by two independent structural gene loci, most likely resulting from a gene duplication. This model is confirmed by a comparison of certain kinetic and molecular properties of the PGI homodimers (PGI-1 and PGI-2) isolated from extracts of the teleost Astyanax mexicanus. In addition, in most higher teleosts examined, the PGI enzymes show a regular pattern of tissue distribution, with PGI-2 predominant in muscle, the heterodimer often strongest in the heart, and PGI-1 predominant in liver and other organs. An examination of 53 species of bony fishes belonging to 38 families indicates a widespread occurrence of duplicate PGI loci and an early origin of the gene duplication, perhaps in the Leptolepiformes. The apparent presence of three PGI loci in trout and goldfish exemplifies how new loci can be incorporated into the genome through polyploidization.This research was supported in part by a NSF graduate traineeship to J.C.A., by the Clayton Foundation for Research in Biochemistry (G.B.K.), by NSF Grant GB-15644 and NIH Grant GM-15769 to Robert K. Selander, and by contract AT(38-1)-310 between the University of Georgia and the U.S. Atomic Energy Commission.     

云南松居群遗传学研究的等位酶分析方法

针对１５个云南松Ｐｉｎｕｓｙｕｎｎａｎｅｎｓｉｓ居群,开展了１４种酶系统的水平切片淀粉凝胶电泳实验,在谱带遗传分析的基础上确定了３３个等位酶位点及其等位基因。其中有３２个等位酶位点是多态的（有２个以上的等位基因）,只有一个单态位点Ｄｉａ－４。有３个等位基因的位点有Ｌａｐ－１、Ｌａｐ－２、Ａａ－３、Ｓｋｄ－１、Ｓｋｄ－２、Ａｄｈ－１、Ａｄｈ－３、Ｇｄｈ、Ｐｇｄ－１、Ｐｇｍ－１、Ｐｇｍ－３、Ｐｇｉ－１、Ｐｇｉ－３、Ｍｄｈ－１、Ｍｅ、Ｇ６ｐｄ、Ｄｉａ－１、Ｔｐｉ－１、Ｔｐｉ－２、Ｔｐｉ－３和Ｔｐｉ－４,有４个等位基因的位点有Ｓｋｄ－３、Ａｄｈ－２、Ｐｇｄ－２、Ｍｄｈ－２、Ｍｄｈ－３、Ｍｄｈ－４和Ｄｉａ－２,有５个等位基因的位点有Ａａｔ－１和Ｄｉａ－３。云南松居群的等位基因平均数Ａ＝２１,在松属中居于中上水平。本研究揭示了云南松居群酶位点及其等位基因带谱的变异式样,为松属植物的遗传多样性研究提供了一批酶位点及其等位基因的参考图谱     

Biochemical properties of duplicated isozymes of phosphoglucose isomerase in the plant Clarkia xantiana

The structural gene locus specifying subunits of the cytoplasmic isozymes of phosphoglucose isomerase (PGI) is present in duplicate in many diploid species of Clarkia (Onagraceae), a genus of annual plants native to California. We studied the kinetic properties and molecular weights of a large number of genetically defined and highly purified PGIs in C. xantiana, a species with the duplication, as a means of examining the biochemical consequences of the evolution of a new gene locus. This species is primarily outcrossing, but also includes several previously described predominantly self-pollinating populations. Both cytoplasmic PGI loci in the outcrossing populations are polymorphic and their enzyme products are readily separated by electrophoresis. The PGIs from the outcrossing populations were generally closely similar in molecular weight, pH optimum, heat sensitivity, energy of activation, and apparent K _m (fructose-6-phosphate). The PGI loci in the selfing populations are monomorphic and specify enzymes having identical electrophoretic mobilities to those coded by the most frequent alleles of the outcrosser. The PGI isozymes in the selfers differed fivefold in K _m , suggesting that they have a very different catalytic effectiveness. The high K _m of the PGI-3A isozyme (1.1mm) was anomalous among the examined and would likely be disadvantageous in a species which lacked other more normally functioning PGIs. But in the cytoplasm of the selfing plants, it is present with other PGIs that have low K _m values. The PGI-3A enzyme is a good candidate for a gene product coded by a forbidden mutation that could not have been established in the absence of the duplication. The rationale for this suggestion is described and it is also pointed out that the divergence of duplicated genes is influenced by many factors such as the breeding system and other population factors as well as the effect of particular mutations.This research was supported by NSF Grant DEB77-08448.     

The kinetics and thermal stability of phosphogluco-isomerase isozymes of ryegrasses (Lolium spp.)

The Michaelis constants (K_m) and activation energies (E_a) for allozymes of cytosolic phosphogluco-isomerase (PGI-2; EC 5.3.1.9) from ryegrasses ( Lolium perenne L., Lolium multiflorum Lam. and interspecific hybrids) have been investigated. Differences were found between the allelic isozymes, but intra-allelic variations were at least as large. The thermal stability of the isozymes also varied, with the most commonly occurring form (the b -allozyme) having the highest stability at 50°C. Some possible explanations for these findings are discussed and the implications for plant breeders outlined.     

Biochemical genetic differentiation between Pomatoschistus marmoratus and P. tortonesei

Several diagnostic genetic markers were identified in Pomatoschistus marmoratus and P. tortonesei using polyacrylamide gel electrophoresis (PAGE) of allozymes. Twenty-one loci were resolved, including the electrophoretic pattern of muscle proteins. The MDH*, PGM-,2*, EST-1,2*, FUM* and PGI-2* loci exhibited different alleles which were fixed for the two species being analysed. Genetic distance, as calculated by Nei's index, showed a value of 0·413. Environmental hypersalinity, could have influenced the geographical distribution of P. tortonesei .     

Genetic heterogeneity in adenosine deaminase (ADA) deficiency: five different mutations in five new patients with partial ADA deficiency.

Complete genetic deficiency of adenosine deaminase (ADA) results in a fatal syndrome of severe combined immunodeficiency (SCID). Genetic partial deficiency of ADA, with no detectable enzyme activity in erythrocytes but with variable amounts of enzyme activity detectable in other cells, is usually associated with normal immunologic function but can give rise to a late-onset, cellular immunodeficiency syndrome. We have previously described four different mutant alleles in four such partially ADA-deficient children. We have now examined ADA in lymphoid cells from five additional newly ascertained children with partial ADA deficiency with respect to electrophoretic mobility in starch gel, isoelectric point, heat-stability, and apparent Km and Vmax. These techniques identify at least five different abnormal alleles in these five additional unrelated subjects. Three of these abnormal alleles result in expression of abnormal allelic isozymes (allozymes) different from those previously described. These are: (1) an acidic allozyme that is less acidic than the acidic allozyme we have previously reported; (2) an allozyme that is even less acidic than (1); and (3) an allozyme with apparently normal charge but which is so heat sensitive that the lability to heat can easily be detected at physiologic to febrile temperatures. Two abnormal alleles detected in these five children could correspond with previously reported mutants. These are (4) a basic allozyme that could (but probably doesn't) correspond to the basic allozyme we have previously reported and (5) a "null" allele that cannot be differentiated by these methods from any other "null" allele seen in complete ADA- -SCIDs. Three of the five new patients are genetic compounds, identified either by the presence of two electrophoretically distinguishable allozymes or by family studies that demonstrate presence of a "null" allele in addition to an electrophoretically abnormal allozyme. In three patients, one or both allozymes are phenotypically indistinguishable from an abnormal allozyme also seen in a different individual. Determination of the nucleotide sequence will be required to determine whether or not the phenotypically indistinguishable mutations are indeed genotypically identical. The newly ascertained individuals appear to share a common ethnic West Indian background, out of proportion to the frequency of this ethnic background in the newborn population from which they were ascertained, suggesting that partial ADA deficiency may confer a selective advantage to the homozygous or heterozygous phenotype.     

Thermal kinetic differences between allelic isozymes of malate dehydrogenase (Mdh-B locus) of largemouth bass,Micropterus salmoides

Two alleles are encoded at the malate dehydrogenase locus in largemouth bass, Micropterus salmoides. Populations in the extreme northern areas of the range of this fish are fixed or nearly fixed for the B1 allele, whereas populations in Florida are fixed for the alternative allele, B2. The MDH-B1B1 and MDH-B2B2 allelic isozymes were isolated by preparative starch gel electrophoresis and subjected to in vitro kinetic analyses. The apparent Km (oxaloacetate) for each of these allelic isozymes was determined at 25, 30, and 35 degrees C. The Km values for both isozymes increased with increasing temperature and were not significantly different from each other at 25 and 35 degrees C. However, at 30 degrees C the Km value for the MDH-B1B1 allelic isozyme was higher than that for the MDH-B2B2 isozyme (i.e., 5.4 X 10(-5) vs 3.3 X 10(-5)). These results are consistent with the hypothesis that the different environmental temperatures at different latitudes may be at least partially responsible for the north-south cline in Mdh-B allele frequencies.     

Different functional and structural properties of lactate dehydrogenase isozymes at different stages of Danio rerio ontogenesis

We studied properties of lactate dehydrogenase isozymes expressed at different stages of Danio rerio ontogenesis. H4-LDH and a minor fraction H3M1 are expressed during embryonic development. The muscle isozyme (M4) appears after the beginning of muscle contractions in the embryo. H4 and M4 isozymes isolated from the heart and skeletal muscle of the adult fish, respectively, show significant differences in terms of Km, activation energy (AE), and inactivation temperature. H4-LDH isozymes isolated from unfertilized eggs, the skeletal muscle of larvae, and the heart of the adult fish differ in Km and activation energy, as well as in inactivation temperature. We propose that these differences may be associated with a ligand interacting with the H4 isozyme at different steps of ontogenesis.     

Linkage between an isozyme marker and a restorer gene in radish cytoplasmic male sterility of rapeseed (Brassica napus L.)

Summary Co-segregation studies of isozyme markers and male fertility restoration showed that a restorer gene from radish was introduced into rapeseed along with an isozyme marker (Pgi-2). The radish chromosome segment carrying these genes was introgressed into rapeseed through homoeologous recombination, substituting for some of the rapeseed alleles. By crossing heterozygous restored plants to male-sterile lines and to maintainers, tight linkage was found between the restorer gene and the marker. The recombination fraction was estimated at 0.25 ± 0.02%. Although few restored plants lacked the radish isozyme marker, it was still possible to distinguish male-fertile from male-sterile plants by their PGI-2 patterns. Furthermore, homozygous and heterozygous restored plants could be separated by specific PGI-2 phenotypes. Thus, the Pgi-2 marker is now currently used in restorer breeding programs.     

The crystal structure of mouse phosphoglucose isomerase at 1.6A resolution and its complex with glucose 6-phosphate reveals the catalytic mechanism of sugar ring opening

Phosphoglucose isomerase (PGI) is an enzyme of glycolysis that interconverts glucose 6-phosphate (G6P) and fructose 6-phosphate (F6P) but, outside the cell, is a multifunctional cytokine. High-resolution crystal structures of the enzyme from mouse have been determined in native form and in complex with the inhibitor erythrose 4-phosphate, and with the substrate glucose 6-phosphate. In the substrate-bound structure, the glucose sugar is observed in both straight-chain and ring forms. This structure supports a specific role for Lys518 in enzyme-catalyzed ring opening and we present a "push-pull" mechanism in which His388 breaks the O5-C1 bond by donating a proton to the ring oxygen atom and, simultaneously, Lys518 abstracts a proton from the C1 hydroxyl group. The reverse occurs in ring closure. The transition from ring form to straight-chain substrate is achieved through rotation of the C3-C4 bond, which brings the C1-C2 region into close proximity to Glu357, the base catalyst for the isomerization step. The structure with G6P also explains the specificity of PGI for glucose 6-phosphate over mannose 6-isomerase (M6P). To isomerize M6P to F6P requires a rotation of its C2-C3 bond but in PGI this is sterically blocked by Gln511.