Biochemical genetic comparison of the Chinese and European races of the common carp

An electrophoretic survey of the common carp revealed 33 loci. Nine were found to be polymorphic including two phosphoglucose isomerase loci, a phosphoglucomutase locus, three esterase loci, a lactate dehydrogenase locus, a malate dehydrogenase locus, and transferrin. Five of these polymorphic loci are reported for the first time, the two phosphoglucose isomerase loci, a phosphoglucomutase locus and two of the three esterase loci. Differences in allele frequencies between the European and Chinese races were found at most loci.     

Phosphoglucose isomerase and esterase phenotypes in Crassostrea angulata and C. gigas

The phenotype distributions and the allele frequencies of the phosphoglucose isomerase and esterase loci examined in the samples of Crassostrea angulata (Essex, England) and C. gigas (Brittany) do not differ significantly and the two populations as such are indistinguishable. The validity of the species C. angulata is questioned and it is postulated that the two samples may be geographic isolates of the same species, i.e. C. gigas. The hatchery reared population of C. gigas from Conway is distinguishable from the other samples of Crassostrea examined. The lack of phenotype diversity is attributed to founder effects of the small parental stock imported in 1965. The distributions of all phenotypes are in agreement with Hardy-Weinberg expectations. Phosphoglucose isomerase (E.C. 5.3.1.9.) is a dimer governed by at least four alleles in C. angulata and five alleles in C. gigas. The slower (Es-S) zone of the esterase electrophoretogram would appear, in both species to be governed by four alleles at a single locus. There was no esterase banding which was specific to either species of Crassostrea.     

Evolutionary genetics of Metridium senile. II. Geographic patterns of allozyme variation

Electrophoretic surveys have demonstrated that populations of the sea anemone Metridium senile along the northeast coast of the United States are polymorphic at four enzyme loci. Phosphoglucose isomerase (PGI) has two alleles in most populations, phosphoglucomutase (PGM) has three alleles, and two leucine aminopeptidase loci have two common alleles each. Phosphoglucose isomerase displays clinal variation and an apparent association with environmental temperature. Phosphoglucomutase shows clinal variation north of Cape Cod for two of the three alleles, while the two leucine aminopeptidase loci are not clinal. All loci show a great deal of variation in populations on Cape Cod, but there is no apparent systematic pattern to this variation. Temperature may be a selective agent in the maintenance of the PGI and PGM clines, although other possibilities cannot presently be completely excluded.Supported by Grant T-4 from the Health Research and Services Foundation, NSF DEB77-14442, NIH GM25809, and NIH GM28024.     

LEAF ISOZYMES AS GENETIC MARKERS IN DATE PALMS

The date palm (Phoenix dactylifera L.) is a long-lived, dioecious, arborescent monocotyledon which must be propagated vegetatively by offshoots to maintain clones. An extensive breeding program begun in 1948 at Indio, California, to obtain superior lines has resulted in the production of several seedling populations of known parents. These were used to study the genetic control of isozymes of alcohol dehydrogenase, esterase, glutamate oxaloacetate transaminase, phosphoglucose isomerase and phosphoglucose mutase from leaf tissue. The five enzyme systems are specified by seven polymorphic genes with 14 alleles. Additional polymorphism was found in two other species of Phoenix. Twenty-six female and 20 male date palm cvs. were genotyped to provide, insofar as is known, the first single-gene markers for the date palm and perhaps for any arborescent monocotyledon.     

ELECTROPHORETIC ANALYSIS OF GENETIC VARIATION IN THE CHAROPHYTA. I. GENE DUPLICATION VIA POLYPLOIDY1

Electrophoretic analysis of 12 species of Chara indicates that functional gene duplication via polyploidy has commonly occurred in the genus. Duplication has been followed by differentiation of the loci encoding phosphoglucose isomerase (PGI). This has led directly to generation of substantial levels of genie variation both within and between taxa. A simple genetic model is proposed to account for the large array of PGI phenotypes encountered in natural populations. Constraints imposed by the reproductive biology of members of the genus, such as selfing, appear to have resulted in selective premiums on intrinsic mechanisms of generating genetic variation. Levels of variation in PGI were higher than would be predicted on the basis of charophyte reproductive characteristics; haploid loci segregate approximately two alleles within each species.     

Linkage relationships among four enzyme loci in the predatory, treehole mosquito

Estimates are reported for the linkage distances between the isozyme loci for hydroxybutyrate dehydrogenase (HbDH), phosphoglucomutase (PGM), phosphoglucose isomerase (PGI), and esterase 8 (Est 8) in the predatory, treehole mosquito, Toxorhynchites rutilus rutilus. Measured linkage distances suggest that these four loci form a single autosomal linkage group approximately 47.4 linkage units in length. The estimates were measured with error because of small family sizes and, perhaps, because of different rates of recombination between males and females or the presence of a paracentric inversion associated with this linkage group. The four loci are tentatively placed in the following order: Est 8--HbDH--PGM--PGI.     

Isozyme electrophoresis patterns of the liver fluke, Clonorchis sinensis from Kimhae, Korea and from Shenyang, China

An enzyme analysis of the liver fluke, Clonorchis sinensis from Kimhae, Korea and from Shenyang, China was conducted using a horizontal starch gel electrophoresis in order to elucidate their genetic relationships. A total of eight enzymes was employed from two different kinds of buffer systems. Two loci from each enzyme of aconitase and esterase (alpha-Na and beta-Na); and only one locus each from six enzymes, glucose-6-phosphate dehydrogenase (G6PD), alpha-glycerophosphate dehydrogenase (GPD), 3-hydroxybutyrate dehydrogenase (HBDH), malate dehydrogenase (MDH), phosphoglucose isomerase (PGI), and phosphoglucomutase (PGM) were detected. Most of loci in two populations of C. sinensis showed homozygous monomorphic banding patterns and one of them, GPD was specific as genetic markers between two different populations. However, esterase (alpha-Na), GPD, HBDH and PGI loci showed polymorphic banding patterns. Two populations of C. sinensis were more closely clustered within the range of genetic identity value of 0.998-1.0. In summarizing the above results, two populations of C. sinensis employed in this study showed mostly monomorphic enzyme protein banding patterns, and genetic differences specific between two populations.     

Investigating hybridization in the parthenogenetic New Zealand stick insect Acanthoxyla (Phasmatodea) using single-copy nuclear loci

The New Zealand stick insect genus Acanthoxyla Uvarov is extremely unusual among higher taxa of animals in that all known species are obligate parthenogens. We have used a combination of the mitochondrial DNA genes cytochrome oxidase subunits I and II, 28S nuclear ribosomal RNA, and the two single-copy nuclear genes elongation factor 1alpha and phosphoglucose isomerase to test hypotheses on the role of hybridization in the evolution of this genus. Alleles at the single-copy nuclear loci in three sampled species of Acanthoxyla were resolved by cloning the PCR products. Analysis of multilocus genotypes shows that most sampled individuals of Acanthoxyla possess three alleles at the single-copy nuclear loci, which we have interpreted to indicate triploidy. Because most of the alleles from Acanthoxyla form a monophyletic group, including sets of alleles possessed by the putative triploids, we have inferred that the extant parthenogenetic lineages formed via hybridization between species of Acanthoxyla, at least one of which must have been sexual. More recently, there have been multiple introgression events from the related species Clitarchus hookeri White, although C. hookeri does not appear to be involved with the origin of parthenogenesis in Acanthoxyla. Our study demonstrates the utility of cloning alleles from multiple single-copy nuclear genes for resolving the origins of parthenogenetic lineages.     

Genetics of two colonies of Glossina pallidipes originating from allopatric populations in Kenya

Abstract Two large colonies, originating from allopatric populations of Glossina pallidipes Austen, in the Shimba Hills and Nguruman, Kenya, which differ biologically and with respect to vectorial competence, were compared at fourteen enzyme loci using polyacrylamide gel electrophoresis. The colonies had similar levels of genetic diversity with approximately half of the loci being polymorphic, an average of 1.6-1.7 alleles per locus, and a mean heterozygosity per locus of approximately 18.4%. However, the colonies differed significantly in allele frequencies at the loci for phosphoglucomutase, glucose-6-phosphate dehydrogenase, xanthine oxidase, octanol dehydrogenase and phosphoglucose isomerase. The results were compared with earlier studies on this species and no evidence was found for selection of specific alleles during establishment or maintenance of colonies of G.pallidipes , nor were specific chromosomes, or marker genes, associated with the biological differences between the two colonies.     

Phenotypes of Phosphoglucose isomerase,phosphoglucose mutase and general protein in some freshwater molluscs from Basrah,Iraq

Electrophoretic variants of phosphoglucose isomerase (EC.5.3.1.9) and phosphoglucose mutase (EC.2.7.5.1) have been studied in eight species of freshwater molluscs. Two phenotypes of phosphoglucose isomerase were observed in Melanopsis nodosa and one phenotype was observed in the rest of the species. One phenotype of phosphoglucose mutase was observed in all the species of molluscs studied. Phosphoglucose isomerase is inferred to be a dimer encoded at a single polymorphic locus in Melanoides nodosa. There are two alleles at this locus. Phosphoglucose mutase is inferred to be a monomer encoded at a single monomorphic locus in all species. The electrophoretic analysis revealed that phosphoglucose isomerase enzyme cannot be considered a good taxonomic criterion to differentiate the different members of the six families studied but, on the other hand, it is considered a good taxonomic criterion to differentiate Melanopsis nodosa and Theodoxus jordani. Phosphoglucose mutase is considered a good taxonomic criterion to differentiate the family Melanidae from the remaining five families studied. General protein can be considered a good taxonomic criterion to differentiate the family Corbicullidae from Melanidae, Viviparidae and Neritidae but, on the other hand, it seems to be a less useful taxonomic criterion to differentiate between the Viviparidae and Neritidae.     

Environmental variability at the phosphoglucose isomerase locus in the genus Chlamys

Two geographically and reproductively isolated populations each of Chlamys opercularis and of Chlamys varia are compared with respect to polymorphism at the phosphoglucose isomerase (PGI) locus. One population of C. varia is further sub-divided into sub-littoral and inter-tidal samples. From the results it is inferred that PGI is a dimeric molecule, controlled by five alleles in C. varia and by at least four alleles in C. opercularis. acting at a single locus. The alleles recognised for C. opercularis have identical electrophoretic mobility as four of those seen in C. varia. The two populations of C. varia are remarkably similar, as were their habitats. However, the sub-littoral sample does show a lesser degree of homozygosity than the inter-tidal sample of the same population. The two populations of C. opercularis differ significantly and represent two separate and identifiable ‘races’. C. varia exhibits a much greater degree of genetic variability than the deep sub-littoral species, C. opercularis indicating that a more stable environment regulates a more monomorphic species.     

Esterase and acid phosphatase polymorphism in the fig tree (Ficus carica L.)

The genetics of two enzymatic loci, esterase (Est-D) and acid phosphatase (AcP-A), were studied by means of polyacrylamide gel electrophoresis in the fig tree (Ficus carica L.). Two codominant alleles are described at the Est-D locus and four codominant alleles at the AcP-A locus. Heterozygotes at the AcP-A locus have a hybrid band, thus showing that the AcP-A allozymes, are at least dimer molecules. Both loci are independent of the male sterility factor in F. carica. The polymorphism in four natural populations was investigated for both loci. A significant deficiency of heterozygotes was observed.     

Variation of Genetic Expression During Development, Revealed by Esterase Patterns in Aedes aegypti (Diptera, Culicidae)

Polyacrylamide gel electrophoresis was used to analyze esterase patterns during development of Aedes aegypti from the cities of Marília and São José do Rio Preto (SJRP), Brazil. The zymograms showed a total of 23 esterase bands, 22 of which were in the specimens from Marília and 19 in those from SJRP. These esterase bands were considered to be the product of 23 alleles distributed tentatively in eight genetic loci. Most of the alleles were developmentally regulated. The larval stage expressed the greatest number of them (19 alleles, from the eight loci, in Marília; and 17 alleles, from seven loci, in SJRP). The pupal stage expressed 10 alleles from seven loci, in both populations, and the adult stage expressed 8 alleles from five and six loci in SJRP and Marília, respectively. Some alleles that were active in every stage were developmentally controlled at the level of expression (amount of product). A single allele was constitutively and highly expressed, in larvae, pupae, and adults, in both populations. Differences in esterase synthesis among stages are probably due to regulatory mechanisms acting in agreement with the requirements of a variable number of processes in which esterases are involved. The larval stage is the most active in developmental processes and shows very intense intake of food and very high mobility. These features may demand increased esterase production at that stage. Comparison of the two populations examined showed (besides the existence of alleles that they do not share) that they exhibit differences in the control of expression of other alleles. Such findings may reflect genetic differences between founders in each population, but the possibility of involvement of the intensive use of insecticides in SJRP is also discussed.     

Biochemical Identification of the Two Races of Radopholus similis by Starch Gel Electrophoresis

Analysis of genetic variation between the banana and the citrus races of Radopholus similis by starch gel eleclrophoresis demonstrated that 7 of 16 enzyme-encoding loci could be used for their diagnostic separation. The two races are closely related arid share approximately 75% of the enzymes evaluated. The level of dissimilarities o1 inherited bands indicates that no gene flow occurs between the races. Aldolase, α + β esterase, glucose-6-phosphate dehydrogenase, isocitrate dehydrogenase, lactate dehydrogenase, malate dehydrogenase, and phosphoglucose isomerase are diagnostic markers of the races.     

Biochemical genetics of rat esterases: Polymorphism,tissue expression,and linkage of four loci

Two alleles at each of four esterase loci in Rattus norvegicus are described with regard to tissue expression, electrophoretic characterization, and genetic linkage. A previously described dominant gene for prealbumin serum esterase is demonstrated to exist as two codominant alleles in the genetically determined absence of the characteristic albumin esterase. The allelic composition of 16 inbred strains for four esterase genes is provided, and the heretofore ambiguous nomenclature of rat esterase genetics is standardized. Linkage of Es-1, Es-2, and Es-3 is demonstrated. Es-2 and Es-3 are tightly linked in that no recombination has been observed in 55 offspring. The same offspring demonstrated 9% recombination between Es-1 and the other two loci.This work was supported by a grant from the Brown-Hazen Fund of Research Corporation.     

Adaptation at Specific Loci. IV. Differential Mating Success among Glycolytic Allozyme Genotypes of Colias Butterflies

Male mating success as a function of genotype is an important fitness component. It can be studied in wild populations, in species for which a given group of progeny has exactly one father, by determining genotypes of wildcaught mothers and of sufficient numbers of their progeny. Here, we study male mating success as a function of allozyme genotype at two glycolytic loci in Colias butterflies, in which sperm precedence is complete, so that the most recent male to mate fathers all of a female's subsequent progeny.--For the phosphoglucose isomerase, PGI, polymorphism, we predict mating advantage and disadvantage of male genotypes based on evaluation of their biochemical functional differences in the context of thermal-physiological-ecological constraints on the insects' flight activity. As predicted, we find major, significant advantage in mating success for kinetically favored genotypes, compared to the genotype distribution of males active with the sampled females in the wild. These effects are repeatable among samples and on different semispecies' genetic backgrounds.--Initial study of the phosphoglucomutase, PGM, polymorphism in the same samples reveals heterozygote advantage in male-mating success, compared to males active with the females sampled. This contrasts with a lack of correspondence between PGI and PGM genotypes in other fitness index or component differences.--Epistatic interactions in mating success between the two loci are absent.--There is no evidence for segregation distortion associated with the alleles of either primary locus studied, nor is there significant assortative mating.--These results extend our understanding of the specific variation studied and suggest that even loci closely related in function may have distinctive experience of evolutionary forces. Implications of the specificity of the effects seen are briefly discussed.     

The crystal structure of phosphoglucose isomerase/autocrine motility factor/neuroleukin complexed with its carbohydrate phosphate inhibitors suggests its substrate/receptor recognition

Phosphoglucose isomerase catalyzes the reversible isomerization of glucose 6-phosphate to fructose 6-phosphate. In addition, phosphoglucose isomerase has been shown to have functions equivalent to neuroleukin, autocrine motility factor, and maturation factor. Here we present the crystal structures of phosphoglucose isomerase complexed with 5-phospho-D-arabinonate and N-bromoacetylethanolamine phosphate at 2.5- and 2.3-A resolution, respectively. The inhibitors bind to a region within the domains' interface and interact with a histidine residue (His(306)) from the other subunit. We also demonstrated that the inhibitors not only affect the enzymatic activity of phosphoglucose isomerase, but can also inhibit the autocrine motility factor-induced cell motility of CT-26 mouse colon tumor cells. These results indicate that the substrate and the receptor binding sites of phosphoglucose isomerase and autocrine motility factor are located within close proximity to each other. Based on these two complex structures, together with biological and biochemical results, we propose a possible isomerization mechanism for phosphoglucose isomerase.     

Polymorphism and inheritance of serum esterases and beta-globulins in the paradise fish (Macropodus opercularis; Anabantidae)

Electrophoretic variants of serum esterases and beta-globulins in two subspecies of paradise fish (Macropodus opercularis) were studied. Four esterase loci (Est-1, Est-2, Est-3 and Est-4), a single transferrin (Tf) and another major beta-globulin locus (Bg) were identified by segregational analysis. Est-3 seems to be a monomorphic locus. Three alleles of Est-1, two of Est-2, two of Est-4, four of Tf and two alleles of Bg were found in the laboratory population. None of these loci were closely linked. Electrophoretic patterns of F1 hybrids confirmed the monomeric structures of each of the studied proteins. Allelic segregation at the Tf and Bg loci was normal in F2 and backcross populations. In crosses of the two Macropodus subspecies there were deviations from Mendelian ratios because of missing recombinant esterase phenotypes. Each of these would have been homozygous Est-2f/f. We suppose that Est-2f/f causes lethality in the early phase of development, except in the Est-1c/c, Est-2f/f combination characteristic of the parental subspecies M.o. concolor.     

Genetic Mapping of Mutations Affecting Phosphoglucose Isomerase and Fructose Diphosphatase in Escherichia coli

The loci on the Escherichia coli genome of mutations affecting phosphoglucose isomerase (pgi) and fructose diphosphatase (fdp) have been determined by conjugation and transduction experiments, chiefly three-factor crosses. The loci for these two constitutive enzymes of central intermediary metabolism lie in the same region of the chromosome, but they are not cotransducible. The order of some markers in this region of the chromosome is arg(ACFH) metA pgi malB uvrA fdp pyrB thr.     

Competitive inhibition of Trypanosoma brucei phosphoglucose isomerase by D-arabinose-5-phosphate derivatives

We report four new strong high energy intermediate analog competitive inhibitors of fructose-6-phosphate isomerization catalyzed by purified Trypanosoma brucei phosphoglucose isomerase: D-arabinonhydroxamic acid-5-phosphate, D-arabinonate-5-phosphate, D-arabinonamide-5-phosphate and D-arabinonhydrazide-5-phosphate. For comparison, the inhibitory properties of the corresponding non-phosphorylated analogues D-arabinonhydroxamic acid, D-arabinonate, D-arabinonamide and D-arabinonhydrazide were also evaluated. D-Arabinonhydroxamic acid-5-phosphate appears as the most potent competitive inhibitor ever evaluated on a phosphoglucose isomerase with an inhibition constant value of 50 nM and a Michaelis constant over inhibition constant ratio of about 2000. Our results show that anionic high energy intermediate analogues, and more particularly D-arabinonhydroxamic acid-5-phosphate, display a weak but significant specificity for Trypanosoma brucei phosphoglucose isomerase versus yeast phosphoglucose isomerase, while neutral high energy intermediate analogues are not selective at all. This would indicate the presence of more positively charged residues in the active site for Trypanosoma brucei phosphoglucose isomerase as compared to that of yeast phosphoglucose isomerase.