The Expression of X-Linked Phosphoglycerate Kinase in the Early Mouse Embryo

Abstract. During early mouse embryogenesis, the activity of X-chromosomally linked maternal and paternal phosphoglycerate kinase (PGK-1) alleles was determined using electrophoretic separation of their gene products and a sensitive fluorometric enzyme assay. In the embryos collected from females homozygous for PGK-1^b mated with PGK-1^a males and vice versa, the paternally derived allozyme was first detected after implantation on day 6. Expression of the maternally inherited allele was studied in embryos from females heterozygous for PGK-1^b and PGK-1^a. From day 1 to day 4, the embryos maintained a constant ratio of enzyme activity of PGK-1B to PGK-1A. Prior to implantation of the embryos between day 4 and day 5, the activity ratio of the two PGK-1 allelic variants changed significantly due to the first appearance of newly synthesized PGK derived from the maternally inherited allele.
Our data demonstrate a temporal difference in the onset of PGK synthesis depending on whether this particular gene product is of maternal or paternal origin. Therefore, we conclude that the maternal PGK-1 locus is already activated during late preimplantation development whereas the paternally inherited gene locus remains silent at the preimplantation stage but is subsequently expressed at approximately the time of X-chromosomal inactivation.     

Non-random X-chromosome expression early in mouse development

We have used a sensitive electrophoretic technique for estimating the activity, or ratio, of two allozymes of the X-chromosome-linked enzyme phosphoglycerate kinase (PGK-1), in order to investigate the randomness of X-chromosome expression in the derivatives of the three primary cell lineages of the early mouse conceptus. The maternally derived Pgk-1 allele is preferentially expressed in the derivatives of the primitive endoderm and trophectoderm lineages at 6 1/2 days post coitum in Pgk-1^a/Pgk-1^b heterozygous conceptuses, and in the one informative 5 1/2-day heterozygous conceptus analysed. This evidence for preferential expression of the maternally derived X chromosome (X^m), so soon after the time of X-chromosome inactivation, favors the possibility that the preferential expression of X^m is a consequence of primary non-random X-chromosome inactivation, rather than a secondary selection phenomenon. The majority of embryos analysed at 4 1/2 and 5 1/2 days pc produced only a single PGK-1 band, corresponding to the allozyme produced by the Pgk-1 allele on X^m, although 50% of these embryos should have been heterozygous females. Possible explanations are discussed.     

Further evidence for the importance of parental source of the Xce allele in X chromosome inactivation

Using mice that were mosaics for both Xce and phosphoglycerate kinase (Pgk-1) alleles, we present further evidence that the parental source of the X chromosome may affect the probability of that X chromosome remaining active. The reciprocal cross differences in PGK-1 activity described here are intermediate between those published previously for other alleles of Xce.     

Electrophoretic variation for x-chromosome-linked phosphoglycerate kinase (pgk-1) in the mouse

Electrophoretic variation for X-chromosome-linked phosphoglycerate kinase (PGK-1) has been found as a polymorphism in feral mice in Denmark. Males from feral sampling or from a variety of genetic crosses have only a single-banded phenotype of the variant PGK-1A type or of the PGK-1B type commonly found among inbred mice. By contrast, three phenotypes were observed among females; two homozygous single-banded types and a heterozygous double-banded type. The X-chromosome linkage of the Pgk-1 locus was determined from the mode of inheritance in F₁ and backcross generations and confirmed by the linkage of Pgk-1 and the X-linked markers Hq, Ta and Mo. Pgk-1 showed 29/122 recombinations with Hq, 5/185 with Ta and 0/108 recombinants with Mo. Based on these recombination data, a gene order of Hq—Ta—Pgk-1—Mo is suggested.     

Fast and easy detection of mouse sex chimeras using electrophoretic polymorphism of phosphoglycerate kinase-1, an X chromosome-linked enzyme

About half of the chimeras produced by aggregation of two mouse embryos are sex chimeras composed of both XX and XY cells. We developed a fast and easy method to identify sex chimeras by using electrophoretic bimorphism of an X-linked enzyme, phosphoglycerate kinase-1 (PGK-1), as a marker. When embryos resulting from the crossing of a Pgk-1b/Pgk-1b female and a Pgk-1a/Y male are aggregated, the genotype of sex chimeras is Pgk-1b/Pgk-1a----Pgk-1b/Y. Most of these were identifiable from the PGK-1 electrophoretic pattern of blood cells (i.e., AB type) and the appearance of genitalia (male type or apparently abnormal). Genotypes of functional sperm in the testes of the male-type sex chimeras were also identifiable from the PGK-1 electrophoretic pattern of progenies. Examination of gonads of the sex chimeras revealed that a considerable proportion was hermaphorditic. With this method, reasonable numbers of male-type sex chimeras and hermaphrodites may be selected and used as material for investigating sexual differentiation.     

Sequential expression of maternally inherited phosphoglycerate kinase-1 in the early mouse embryo

Enzyme activities of X-linked phosphoglycerate kinase (PGK-1) and autosomal glucose phosphate isomerase (GPI-1) were determined in intact mouse blastocysts and isolated inner cell masses (ICMs). Blastocysts were recovered from the uterus on day 4 of gestation and cultured overnight in vitro. ICMs were isolated by treatment with calcium ionophore A23187. On day 4, approximately 35% of the total activity of both PGK-1 and GPI-1 was located in the ICM. After overnight culture, the PGK-1 activity of the whole blastocyst nearly doubled, due to the activation of only the maternally derived gene coding for PGK-1. In the ICM, however, a pronounced decrease of PGK-1 activity was measured: only 10% of the total PGK-1 activity was measured in the ICM on day 5. In contrast to PGK-1, GPI-1 activity of the intact blastocyst remained stable from day 4 to day 5. In the ICM, the GPI-1 activity did decline, but to a lesser extent than PGK-1 activity: 20% of total GPI-1 activity was found in the ICM on day 5. These results, when compared with the data of Handyside and Hunter, suggest that the decline in GPI-1 activity in the ICM is due to a change in the ratio of trophectoderm (TE) to ICM cells. The greater reduction of PGK-1 activity in the ICM cannot, however, be explained solely by this mechanism. To explain the observed additional decrease, we postulate that Pgk-1 is not activated in the ICM prior to day 6. This implies that on day 4 maternal Pgk-1 is activated in the TE exclusively.     

Developmental profile of glucose phosphate isomerase allozymes in parthenogenetic and tetraploid mouse embryos.

Glucose phosphate isomerase (GPI) allozymes were compared in eggs and embryos of the mouse strains C57BL/6-JHan (GPI-1BB) and 129/Sv (GPI-1AA) under different experimental conditions. The quantitative differences in eggs of the two strains disappeared by the blastocyst stage at day 4 to 5, both in fertilized and diploid parthenogenetic embryos. The degree of degradation of oocyte-coded enzyme molecules and the activation of the embryonic genome for GPI appeared to be equivalent in parthenogenetic embryos from heterozygous females when only one or other maternal allele type remained in the egg after meiosis. Also in tetraploid embryos, generated by electrofusion of homozygous fertilized eggs from the two strains, both genomes seemed to be activated at the same time at day 4; here, however, the GPI-1BB allozyme remained predominant up to day 6.     

Timing of paternal Pgk-1 expression in embryos of transgenic mice

In mouse development, the paternal allele of the X-linked gene Pgk-1 initiates expression on day 6, two days later than the maternal allele, which is activated on day 4. The different timing of expression of the maternal and paternal alleles may be determined by (i) imprinting of the chromosome region in which the gene resides, but not aimed specifically at the Pgk-1 gene; (ii) gene specific imprinting, acting on Pgk-1 irrespective of the chromosomal localization of the gene; (iii) an interplay between embryo cell differentiation, timing of X-inactivation and Pgk-1 expression, without the involvement of imprinting at the Pgk-1 locus itself (Fundele R., Illmensee, K., Jagerbauer, E. M., Fehlau, M. and Krietsch, W. K. (1987) Differentiation 35, 31-36). Our findings in transgenic mouse lines, carrying Pgk-1 on autosomes, indicate the importance of the X chromosomal location for the delayed expression of the paternal Pgk-1 allele, and are in agreement with the first of the explanations listed above. We propose that the late activation of the paternal Pgk-1 locus is a consequence of imprinting targeted at, and centered around, the X chromosome controlling element.     

Genetic control of X chromosome inactivation in mice: definition of the Xce candidate interval

In early mammalian development, one of the two X chromosomes is silenced in each female cell as a result of X chromosome inactivation, the mammalian dosage compensation mechanism. In the mouse epiblast, the choice of which chromosome is inactivated is essentially random, but can be biased by alleles at the X-linked X controlling element (Xce). Although this locus was first described nearly four decades ago, the identity and precise genomic localization of Xce remains elusive. Within the X inactivation center region of the X chromosome, previous linkage disequilibrium studies comparing strains of known Xce genotypes have suggested that Xce is physically distinct from Xist, although this has not yet been established by genetic mapping or progeny testing. In this report, we used quantitative trait locus (QTL) mapping strategies to define the minimal Xce candidate interval. Subsequent analysis of recombinant chromosomes allowed for the establishment of a maximum 1.85-Mb candidate region for the Xce locus. Finally, we use QTL approaches in an effort to identify additional modifiers of the X chromosome choice, as we have previously demonstrated that choice in Xce heterozygous females is significantly influenced by genetic variation present on autosomes (Chadwick and Willard 2005). We did not identify any autosomal loci with significant associations and thus show conclusively that Xce is the only major locus to influence X inactivation patterns in the crosses analyzed. This study provides a foundation for future analyses into the genetic control of X chromosome inactivation and defines a 1.85-Mb interval encompassing all the major elements of the Xce locus.     

Dictyate oocytes of a kangaroo (Macropus robustus) show paternal inactivation at the X-linked Gpd locus

Purified samples of large numbers of dictyate oocytes from 13 M. robustus pouch young heterozygous for glucose-6-phosphate dehydrogenase type and six homozygous controls were examined electrophoretically to determine activity states at the Gpd locus. Like somatic cortical and medullary cells, oocytes expressed only the maternal phenotype irrespective of the direction of the cross. No evidence was found of reactivation of the inactive (paternal) allele or inactivation of both maternal and paternal alleles. It was therefore concluded that unlike eutherian dictyate oocytes, only a single (maternal) allele is active in each dictyate oocyte in M. robustus. The stage of reactivation of the paternal allele remains to be determined.     

Preferential expression of the maternally inherited X-linked phosphoglycerate kinase allele in human erythrocytes

Summary The stability of allelic gene expression of X-linked phosphoglycerate kinase was studied in seven carriers of a rare genetic variant named PGK München. The enzymatic activities in erythrocytes of five heterozygous females and three hemizygous males were determined repeatedly over a period of 10 years (1975–1984) and shown to remain constant. As the phosphoglycerate kinase activity is lower in cells expressing the PGK München allele, the ratio of the two cell types in all heterozygous females of the PGK München kindred could be calculated from the PGK activity and from the known allozyme activities in erythrocytes of homozygous wild type or hemizygous PGK München carriers. Since the maternal or paternal origin of both alleles is known from the pedigree, the quantitative expression of the maternally derived allozyme in heterozygous women could be determined. In heterozygous carriers the cell pool expressing the maternally inherited allele was significantly increased, independently, of the PGK allele linked to the maternal X chromosome (P<0.001). Our data show that inactivation of one of the two X chromosomes in human female erythropoietic stem cell precursors may be non-random, at least in the kindred and cell populations described here. The results are discussed in the context of random X chromosome inactivation (Lyon hypothesis).Dedicated to J.S., the senior of the family studied, on the occasion of her 80th birthday     

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.     

Genetic Variation in the Strongly Canalized Sex Pheromone Communication System of the European Corn Borer, Ostrinia Nubilalis Hubner (Lepidoptera; Pyralidae)

The major difference in pheromone production between the so-called E and Z strains of the European corn borer Ostrinia nubilalis is controlled by two alleles at a single autosomal locus. E-strain females produce an (E)-11-tetradecenyl acetate pheromone with 1-3% of the Z isomer, whereas Z-strain females produce the opposite blend. In laboratory-reared insects we found that F(1) females produced, on average, a 71:29 E/Z ratio, but the distribution was clearly bimodal. The variability in pheromone blend produced by heterozygous females could be explained by the existence of two different alleles in the Z strain which in combination with the E-strain allele for the major production locus cause the production of a component mixture either high or low in the E isomer. In addition, evidence was found for an independently inherited factor, existing in the E strain, with a dominant effect on the amount of E isomer produced by females homozygous for Z-alleles at the major production locus. Thus, the low variability normally found in the pheromone mixture produced by O. nubilalis and other moth females may, by canalization, hide a considerable amount of underlying genetic variation.     

Biochemical evidence of haplodiploidy in the whiteflyBemisia tabaci

Polymorphic esterase and acetylcholinesterase alleles in the whiteflyBemisia tabaci were studied using electrophoretic and colorimetric assays. The segregation of these alleles between parental and F₁ generations provided unequivocal evidence of haplodiploidy in this pest species. Unmated females, heterozygous at a polymorphic locus, produced a 1:1 ratio of haploid males expressing either of the maternal alleles. Although male offspring were produced by both virgin and mated females, the segregation of alleles showed they were always haploid (hemizygous) for the marker enzymes. Females only arose from fertilized eggs and invariably expressed paternal and maternal alleles.     

RS46(DXS548) genotyping of reproductive cells: approaching preimplantation testing of the fragile-X syndrome

In order to approach preimplantation testing for the fragile-X syndrome, we used genotyping of the polymorphic RS46(DXS548) locus closely linked to the FMR1 gene, in single reproductive cells of females. The RS46(DXS548) amplification was adjusted to the single cell level by a two-round polymerase chain reaction (PCR) procedure. Unfertilized oocytes and extruded polar bodies were subjected to PCR. RS46(DXS548) genotyping at the single cell level was successful in 95% of the samples. In two-third of the metaphase II oocytes and first polar bodies obtained from women who were heterozygous at the RS46(DXS548) locus, both maternal RS46(DXS548) alleles were observed because of crossing over during the first meiotic division. This makes gamete selection by first polar body analysis inefficient. From the allele frequencies found in 56 unrelated individuals, a heterozygote frequency of 51% was estimated, whereas the observed heterozygote frequency was 56%. The whole PCR procedure can be performed within 16 h after blastomere biopsy. Consequently, the selection and transfer of the diagnosed embryos can be carried out within an acceptable time. Therefore, preimplantation testing for the fragile-X syndrome with the RS46(DXS548) AC-repeat may be an alternative choice for prenatal testing for those carrier females who are heterozygous (informative) at the RS46(DXS548) locus.     

Autonomy for a specific gene product in oocytes: Experimental evidence in the polychaetous annelid,Platynereis dumerilii

Oocytes of Platynereis dumerilii in early vitellogenesis were injected into female worms with oocytes of similar diameter. The donor oocytes were labeled by the or gene controlling eye pigmentation and, after some weeks of growth, were spawned together with the host oocytes. In most cases, a few donor progeny could be found among the offspring produced by the hosts. Donor progeny were examined with respect to an or gene-dependent maternal effect which normally causes wild-type eye color in homozygous ($\text{or}\text{or}$) larvae originating from the crossings of heterozygous ($\text{or}{}^{\mathrm{+}}\text{or}$) females and homozygous ($\text{or}\text{or}$) males. This maternal effect was absent from homozygous ($\text{or}\text{or}$) larvae derived from homozygous ($\text{or}\text{or}$) donor oocytes which had developed in heterozygous females. Conversely, this maternal effect was observed in homozygous ($\text{or}\text{or}$) larvae derived from heterozygous ($\text{or}{}^{\mathrm{+}}\text{or}$) donor oocytes which had developed in homozygous ($\text{or}\text{or}$) host females. It is concluded that the oocyte genome is active at the or⁺ locus during oogenesis and that the oocyte is autonomous with respect to the product of synthesis of the or⁺ locus. In the present case, the “maternal effect” is therefore caused by synthetic activity in the growing oocyte. The results are discussed with respect to current information on gene products from animal genomes.     

Differential expression of allelic carboxylesterase-2 genes in oocytes of loach (Misgurnus fossilis L.) and heterogeneity of loach oocytes and eggs for the expression of allelic carboxylesterase-2 genes

Tissue and cell differences have been found in the expression of allelic carboxylesterase-2 (E-2) (carboxylic ester hydrolase, E.C. 3.1. 1.1) genes of the loach. The relative activity of two allozymes in the brain and muscles of heterozygotes is similar, whereas in oocytes and eggs of the same fish the activity of one of the allozymes is considerably greater than that of the other. Oocytes and eggs of some heterozygotes were shown to be heterogeneous for the expression of E-2 alleles. The phenomenon implies that roe produced by a heterozygous female can contain two or more egg types: in some the alleles are equally expressed, while in others one of the alleles is predominantly expressed.     

Characterization of opsin gene alleles affecting color vision in a wild population of titi monkeys (Callicebus brunneus)

The color vision of most platyrrhine primates is determined by alleles at the polymorphic X-linked locus coding for the opsin responsible for the middle- to long-wavelength (M/L) cone photopigment. Females who are heterozygous at the locus have trichromatic vision, whereas homozygous females and all males are dichromatic. This study characterized the opsin alleles in a wild population of the socially monogamous platyrrhine monkey Callicebus brunneus (the brown titi monkey), a primate that an earlier study suggests may possess an unusual number of alleles at this locus and thus may be a subject of special interest in the study of primate color vision. Direct sequencing of regions of the M/L opsin gene using feces-, blood-, and saliva-derived DNA obtained from 14 individuals yielded evidence for the presence of three functionally distinct alleles, corresponding to the most common M/L photopigment variants inferred from a physiological study of cone spectral sensitivity in captive Callicebus.     

Evaluating the utility of microsatellites for investigations of autopolyploid taxa

Autopolyploid taxa present numerous challenges for population genetic analyses due to difficulties determining allele dosage. Dosage ambiguity hinders accurate assessment of allele frequencies, multilocus genotypes (MLGTs), as well as levels and patterns of clonality. The pervasiveness of polyploidy in the evolutionary history of plant taxa makes this a recurring problem. Whereas diploidization of loci may occur over time, duplication of at least some loci is still frequently evident. Fortunately, with high-quality allozyme gels, it is possible to accurately infer allele dosage and, thus, determine exact MLGTs. However, accurately assessing dosage of microsatellite peaks is nearly impossible when studying wild populations with a large number of alleles per locus. Even if precise knowledge of genotypes is not required, for comparable numbers of alleles per locus and loci, the number of "phenotypes" is always lower with microsatellites than allozymes due to the inability to assess allele dosage. Microsatellite loci typically have more alleles per locus relative to allozymes although fewer loci are generally employed. Here, we present a mathematical model for comparing the relative utility of simple sequence repeat (SSR) versus allozyme markers to discriminate MLGTs. For example, the average plant allozyme study (2.6 alleles per locus, 10 polymorphic loci) has better discriminating power than SSR markers with 10 alleles at each of 3 loci, 9 alleles at 4 loci, 6 alleles at 5 loci, 5 alleles at 6 loci, and 4 alleles at 8 loci, demonstrating the value of assessing the relative discriminating power of these markers.     

Growth rate correlates to individual heterozygosity in the European eel, Anguilla anguilla L

Heterozygosity-fitness correlations (HFCs) have been reported in populations of many species. We provide evidence for a positive correlation between genetic variability and growth rate at 12 allozyme loci in a catadromous marine fish species, the European eel (Anguilla anguilla L.). More heterozygous individuals show a significantly higher length and weight increase and an above average condition index in comparison with more homozygous individuals. To a lesser extent, six microsatellite loci show a similar pattern, with positive but not significant correlations between heterozygosity and growth rate. The HFCs observed could be explained by an effect of either direct allozyme over-dominance or associative overdominance. Selection affecting some of the allozyme loci would explain the greater strength of the HFCs found at allozymes in comparison with microsatellites and the lack of correlation between MLH at allozymes and MLH at microsatellites. Associative overdominance (where allozyme loci are merely acting as neutral markers of closely linked fitness loci) might provide an explanation for the HFCs if we consider that allozyme loci have a higher chance than microsatellites to be in linkage disequilibrium with fitness loci.