Phosphoglucose isomerase (PGI) variants in the Netherlands

Summary Six hundred individuals of pure Dutch ancestry have been typed for their erythrocyte phosphoglucose isomerase phenotypes by starch gel and cellulose acetate electrophoresis. In two individuals a variant phenotype was discovered. One phenotype was found to be indistinguishable from PGI-Phillips. The other variant would appear to be a new phenotype and has been designated PGI-Jager.     

Genetics of glucosephosphate isomerase in Aedes togoi (Diptera: Culicidae)

The genetics of glucosephosphate isomerase (E.C. 5.3.1.9) in two strains (Malaysian and Taiwan) of Aedes togoi is reported. Three electrophoretic phenotypes were present in both sexes. The zymogram patterns were identical in both strains of A. togoi. The phenotypes were governed by a pair of codominant alleles. The allele frequency of the slow-moving band was 0.63 in the Malaysian strain and was 0.86 and 0.82 in F161 and F169 generations, respectively, of the Taiwan strain. The sample studied was in good accord with Hardy-Weinberg expectations.     

Polymorphism of erythrocyte glucosephosphate isomerase in sheep

An electrophoretic analysis of glucosephosphate isomerase (GPI) in seven Italian sheep populations suggests that this locus is more polymorphic than previously supposed. The observed phenotype distributions are in agreement with the hypothesis of the existence of three codominant alleles, GPI*F, GPI*S and GPI*N, GPI*S being the most frequent (0.935 ÷ 1.000).     

Multiple forms of glucosephosphate isomerase in maize

Three apparently different glucosephosphate isomerases are found in the developing seeds of maize (Zea mays L.). Glucosephosphate isomerase I is found in both the endosperm and embryo. It is separable by column chromatography from glucosephosphate isomerase II of the developing endosperm and glucosephosphate isomerase III of the developing embryo and is further distinguished from them by heat stability, temperature activation, and relative insensitivity to the presence of zinc ions in the reaction mixture. Glucosephosphate isomerases II and III elute in the same fractions from diethylaminoethyl cellulose columns but are distinguished by electrophoretic mobility and reaction to the presence of adenosine 5′-triphosphate in the reaction mixture. All three isomerases give multiple banding patterns on electrophoresis. An extensive investigation of the conditions generating additional electrophoretic species and chromatographically separable minor activity peak (Ia) from glucosephosphate isomerase I has shown that these transformations are enhanced by dialysis, column chromatography, ammonium sulfate fractionation, and treatment with urea. The transformations are retarded by the presence of mercaptoethanol during these operations. We concluded that the multiple banding pattern seen on electrophoresis of glucosephosphate isomerase I prepared by certain procedures is artifactual. In germinating seeds of maize, glucosephosphate isomerases I and III are detectable, but II is not. It is possible that glucosephosphate isomerase II specifically catalyzes a step in starch biosynthesis.     

The adaptive significance of electrophoretic mobility in phosphoglucose isomerase (PGI)

Sexual dimorphism in size and plumage was investigated in the lek-breeding Jackson's widowbird Euplectes jacksoni. Size dimorphism was evident from the sexual difference in tarsus length, reflecting skeletal body size. The long tail and the wide collar of breeding plumaged males were obvious secondary sex traits, but the wing was also longer than in subadults and might likewise be sexually selected (i.e. not merely a byproduct of body size). Possibly, the increased wingspan functions to save energy during the jump display. To reveal intrasexual selection, courtholders were compared with floaters (nuptial males captured off the leks), and were found to be larger in body size, wing length, collar and tail. The roles of inter-and intrasexual selection are discussed with reference to previously demonstrated female choice, and new results indicating competition for access to leks: quick reoccupation of deserted display courts, frequent observations of intruders and a finding that central males were more aggressive than peripherals. Observations imply that the collar is an agonistic signal that is neutral with respect to female choice. Possible contributions of natural selection to the sexual dimorphism are also considered.     

Genetic control of two electrophoretic variants of glucosephosphate isomerase in the mouse (Mus musculus)

The autosomal variation and the genetic control of GPI has been determined by a comparison of electrophoretic patterns of F₁ and backcross progeny of three inbred strains of mice. The locus controlling the production of GPI in the mouse has been designated Gpi-1. Two alleles at this locus have been described and designated Gpi-1 ^a and Gpi-1 ^b, which represent, respectively, the slow and fast electrophoretic forms. Twenty-seven inbred strains of mice have been classified for these two alleles. The absence of close linkage of Gpi-1 to seven other genetic loci has been determined. It has been demonstrated that the polymorphism of Gpi-1 is widely distributed in feral mice. GPI was expressed in vitro and in four types of malignant tumors.Supported by U.S. Public Health Service Grants GM-09966, from General Medical Sciences, and GY 4193.     

Genetic control of glucosephosphate isomerase (GPI) in common carp (Cyprinus carpio L.)

In common carp, a freshwater fish species of tetraploid origin, GPI enzymes are present in two variants: GPI-A and GPI-B. GPI-A is coded by two loci segregating for two (GPI-A 1*) and six (GPI-A2*) alleles. Experimental crosses of the ornamental (Koi) variety of common carp revealed that GPI-B is coded by only one locus (GPI-B*). Another GPI-B* locus must have been silenced in the process of functional diploidization. It was also shown that the GPI-A2* locus segregated independently from the GPI-B* locus, demonstrating that the loci are located on different chromosomes.     

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.     

Unique phenotypic expression of glucosephosphate isomerase deficiency.

Studies of a Mexican kindred present evidence for a unique phenotype of erythrocyte glucosephosphate isomerase, GPI Valle Hermoso. The proband was apparently the homozygous recipient of a mutant autosomal allele governing production of an isozyme characterized by decreased activity, marked thermal instability, normal kinetics and pH optimum, and normal starch gel electrophoretic patterns. Unlike previously known cases, leukocyte and plasma GPI activities were unimpaired. This suggested that the structural alteration primarily induced enzyme instability without drastically curtailing catalytic effectiveness, thereby allowing compensation by cells capable of continued protein synthesis. Age-related losses of GPI, however, were not evident by density-gradient fractionation of affected erythrocytes.     

Immunoreactivity of the two common allozymes of murine glucosephosphate isomerase

There are two common electrophoretic variants (allozymes) of murine glucosephosphate isomerase (GPI). In order to develop immunocytochemical procedures that are allozyme-specific, the two variants (GPI-1A and GPI-1B) were purified from skeletal muscle of several mouse strains and used as antigens for the elicitation of antibodies. The allozymes were purified to a specific activity of 800 units/mg by substrate elution from cellulose phosphate. When the purified allozymes were presented as antigens to goats, rabbits, and mice (both syngeneically and allogeneically), the goats and rabbits produced high titers of anti-GPI antibody, but no humoral antibody was detected in the mice, as determined by radioimmunoassays. Antisera specific for the GPI-1B variant were enriched by absorbing selected sera with GPI-1A conjugated to Sepharose 4B. No antisera specific for GPI-1A were detected following the immunizations. The specificity of the anti-GPI-1B antisera provides a unique opportunity for the development of immunocytochemical procedures for studying the distribution of this allozyme in chimeric mouse tissues.This research was supported by grants from the Public Health Service (HD 12685) and the National Science Foundation (PCM 7923065). J.G. is the recipient of a Basil O'Connor Award from the March of Dimes-Birth Defects, and M.L.O.G. is a Fellow of the Alfred Sloan Foundation.     

A new variant of glucosephosphate isomerase deficiency.

A new variant of glucose-6-phosphate isomerase deficiency is described. The enzyme kinetics and properties were studied. Genetic and electrophoretic data pointed to a double heterozygous state in the patient. These data are compared to the other variants described in the literature until now.     

Intracellular ATP in a glucosephosphate isomerase mutant ofSaccharomyces cerevisiae

The degree of ATP depletion caused by glucose in a glucosephosphate isomerase-deficient strain of Saccharomyces cerevisiae was determined. Even in the presence of a sugar normally fermentable by the mutant, the addition of glucose can decrease the intracellular ATP, depending on the competition of the sugars for transport and subsequent phosphorylation. For both parent and mutant cells, a correlation exists between the calculated velocity of ATP formation or ATP consumption during the utilization of different concentrations of sugars and the experimental intracellular ATP level. For initially resting yeast cells, a rate increase of 35 mumol per min per g ATP was calculated to increase the intracellular level of this nucleotide by 1 mumol per g cell mass.     

Affinity labeling of human glucosephosphate isomerase with N-bromoacetylethanolamine phosphate

N-Bromoacetylethanolamine phosphate rapidly and irreversibly inactivates glucosephosphate isomerase in a pseudo first-order fashion. Ratesaturation effects are observed with a minimum half-life of 4.5 minutes and a half-maximal rate of inactivation at 0.056 mM. Substrates, as well as competitive inhibitors, protect the isomerase from inactivation. Using ¹⁴C-labeled N-bromoacetylethanolamine phosphate, the incorporation of approximately one equivalent of inactivator per subunit of isomerase is indicated. After acid hydrolysis, the only modification appears to be the formation of carboxymethyl histidine. These studies indicate that the substrate analogue N-bromoacetylethanolamine phosphate is a specific affinity label that can be used to probe the active site of glucosephosphate isomerase.     

Characterization of Neurospora crassa mutants deficient in glucosephosphate isomerase.

Two independent mutants of Neurospora crassa lacking glucosphosphate isomerase activity (gpi) were isolated. These mutants were obtained as double mutants containing the pp or T9 mutation in addition to the gpi mutation located on linkage group IV; the pp mutation caused the inability to form protoperithecium and the loss of ascospore germination, and the T9 mutation caused the alteration in glucoamylase and several growth characteristics. The gpi mutants did not grow on fructose but grew on glucose or sucrose. Growth of these mutants on glucose was stimulated by addition of fructose. The gpi mutants showed restricted colonial growth on agar media containing glucose in contrast to the normal filamentous growth of the wild-type stain.     

Biochemical genetics of a new glucosephosphate isomerase allele (Gpi-1 c) from wild mice

We have found a new allele at the structural locus for glucosephosphate isomerase (called Gpi-1 ^c ) in a population of wild mice. The Gpi-1 ^c allele codes for an enzyme of greater cathodal electrophoretic mobility than either the Gpi-1 ^a or Gpi-1 ^b alleles found in the wild and in the SM/J and C57BL/6J inbred strains. Mice homozygous for Gpi-1 ^c have erythrocyte enzyme activity reduced to 33% of normal levels, altered pH profile, lowered heat stability, and normal K _m 's when compared with SM/J and C57BL/6J mice. The activity of the enzyme in brain, liver, and kidney is not so markedly lowered, although the electrophoretic mobility, pH profile, and heat stability are altered in these tissues. Deficiencies of erythrocyte glucosephosphate isomerase in man, to this level, can cause severe hemolytic anemia. Homozygotes for Gpi-1 ^c show only mild hematological symptoms. The frequency of Gpi-1 ^c in wild populations of mice is discussed and the occurrence of a further rare allele Gpi-1 ^d is reported.This work was supported by M.R.C. grants to Professor R. J. Berry and Dr. H. Kacser, whom we should also like to thank for much help and useful discussion.