A study of X chromosome regulation during oogenesis in the mouse

Mature oocytes of mammals, in contrast to somatic cells, have two active X chromosomes. This situation might arise through either of two possible mechanisms. The germ line might be differentiated from somatic cells prior to X inactivation. Alternatively, an X chromosome in germ cells would be reactivated after prior inactivation. This paper presents data compatible with reactivation of the X in germ cells. X-linked enzymes were compared in oocytes of XX and XO fetal mice. The activity of G6PD is similar in the two classes of cells at early meiotic stages, but an $\text{XX}\text{XO}$ ratio of 2:1 is approached at later times; this suggests reactivation of the G6PD locus. For HPRT, a 2:1 ratio is observed at all meiotic stages. HPRT shows a large increase in enzyme activity during early meiosis, while G6PD does not. Synthesis of this enzyme at early meiotic stages probably accounts for differences between these data and those obtained for G6PD, and places the time of X reactivation at the entry to meiosis.     

Biochemical studies of growing mouse oocytes: preparation of oocytes and analysis of glucose-6-phosphate dehydrogenase and lactate dehydrogenase activities.

Oocytes at several stages of growth were isolated by enzymatic digestion of ovaries from infant mice. These oocytes were free of follicle cells and were obtained in sufficient numbers to permit direct biochemical analysis of glucose-6-phosphate dehydrogenase (G6PD) and lactate dehydrogenase (LDH) activities. Both enzymes increase in total activity as the oocyte grows. However, while the specific activity of G6PD remains constant up to an oocyte diameter of 80–85 μm, the specific activity of LDH increases four-fold. The specific activity of G6PD and especially LDH declines in oocytes over 80–85 μm in diameter, suggesting that the synthesis of these enzymes is almost completed at this stage of growth.     

X chromosome expression during oogenesis in the mouse.

The activities of glucose-6-phosphate dehydrogenase (G6PD) and lactate dehydrogenase (LDH) have been assayed in mouse oocytes at several stages of follicle development isolated from XX and XO female mice. Throughout the entire growth period the activity of G6PD was proportional to the number of X chromosomes present in the oocyte, whereas no difference in LDH activity was detected between XX and XO oocytes. It is concluded, therefore, that both X chromosomes are functional throughout oogenesis.     

X linkage of phosphoglycerate kinase in the mouse

The levels of phosphoglycerate kinase (PGK), glucose 6-phosphate dehydrogenase (G6PD), and lactate dehydrogenase (LDH) were measured in one-cell embryos from X/0 and X/X females. Since the level of both PGK and G6PD was dependent on the number of X chromosomes present in the mother, these two enzymes are most likely coded for by X-linked genes. The level of LDH was the same in both types of embryos, indicating autosomal linkage. A search for an electrophoretic variant of PGK was not successful.     

The NADPH Metabolic Network Regulates Human αB-crystallin Cardiomyopathy and Reductive Stress in Drosophila melanogaster

Dominant mutations in the alpha-B crystallin (CryAB) gene are responsible for a number of inherited human disorders, including cardiomyopathy, skeletal muscle myopathy, and cataracts. The cellular mechanisms of disease pathology for these disorders are not well understood. Among recent advances is that the disease state can be linked to a disturbance in the oxidation/reduction environment of the cell. In a mouse model, cardiomyopathy caused by the dominant CryAB^R120G missense mutation was suppressed by mutation of the gene that encodes glucose 6-phosphate dehydrogenase (G6PD), one of the cell''s primary sources of reducing equivalents in the form of NADPH. Here, we report the development of a Drosophila model for cellular dysfunction caused by this CryAB mutation. With this model, we confirmed the link between G6PD and mutant CryAB pathology by finding that reduction of G6PD expression suppressed the phenotype while overexpression enhanced it. Moreover, we find that expression of mutant CryAB in the Drosophila heart impaired cardiac function and increased heart tube dimensions, similar to the effects produced in mice and humans, and that reduction of G6PD ameliorated these effects. Finally, to determine whether CryAB pathology responds generally to NADPH levels we tested mutants or RNAi-mediated knockdowns of phosphogluconate dehydrogenase (PGD), isocitrate dehydrogenase (IDH), and malic enzyme (MEN), the other major enzymatic sources of NADPH, and we found that all are capable of suppressing CryAB^R120G pathology, confirming the link between NADP/H metabolism and CryAB.     

Hepatic Overexpression of Steroid Sulfatase Ameliorates Mouse Models of Obesity and Type 2 Diabetes through Sex-specific Mechanisms

The steroid sulfatase (STS)-mediated desulfation is a critical metabolic mechanism that regulates the chemical and functional homeostasis of endogenous and exogenous molecules. In this report, we first showed that the liver expression of Sts was induced in both the high fat diet (HFD) and ob/ob models of obesity and type 2 diabetes and during the fed to fasting transition. In defining the functional relevance of STS induction in metabolic disease, we showed that overexpression of STS in the liver of transgenic mice alleviated HFD and ob/ob models of obesity and type 2 diabetes, including reduced body weight, improved insulin sensitivity, and decreased hepatic steatosis and inflammation. Interestingly, STS exerted its metabolic benefit through sex-specific mechanisms. In female mice, STS may have increased hepatic estrogen activity by converting biologically inactive estrogen sulfates to active estrogens and consequently improved the metabolic functions, whereas ovariectomy abolished this protective effect. In contrast, the metabolic benefit of STS in males may have been accounted for by the male-specific decrease of inflammation in white adipose tissue and skeletal muscle as well as a pattern of skeletal muscle gene expression that favors energy expenditure. The metabolic benefit in male STS transgenic mice was retained after castration. Treatment with the STS substrate estrone sulfate also improved metabolic functions in both the HFD and ob/ob models. Our results have uncovered a novel function of STS in energy metabolism and type 2 diabetes. Liver-specific STS induction or estrogen/estrogen sulfate delivery may represent a novel approach to manage metabolic syndrome.     

X-linked glucose-6-phosphate dehydrogenase deficiency inMus musculus

A mouse with X-linked glucose-6-phosphate dehydrogenase (G6PD) deficiency has been recovered in offspring of 1-ethyl-1-nitrosourea-treated male mice. The activity alteration was detected in blood but can also be observed in other tissue extracts. Hemizygous, heterozygous, and homozygous mutants have, respectively, about 15, 60, and 15% G6PD remaining activity in the blood as compared to the wild type. Erythrocyte indices did not show differences between mutants and wild types. The mutation does not affect the electrophoretic migration, the isoelectric point, or the thermal stability. Kinetic properties, such as theK _m for glucose-6-phosphate or for NADP and the relative utilization of substrate analogues, showed no differences between wild types and mutants with the exception of the relative utilization of deamino-NADP which was significantly lower in mutants. This is presently the only animal model for X-linked G6PD deficiency in humans.This research was supported in part by Contract BI6-156-D from the Commission of the European Communities.     

More Sex-Determination Mutants of CAENORHABDITIS ELEGANS

Sex determination in Caenorhabditis elegans is controlled by the X chromosome: autosome ratio, i.e. 2A;XX animals are hermaphrodite, and 2A;XO animals are male. A procedure for isolating 2A;XO animals that are transformed into hermaphrodites has been developed. Nine mutations causing this transformation have been obtained: eight are recessive, and all of these fall into a new autosomal complementation group, her-1 V. The remaining mutation (her-2) is dominant and has a genetic map location similar to that of tra-1 III. Recessive mutations of tra-1 cause the reverse transformation, transforming 2A;XX animals into males. Therefore, the her-2 mutation may result in constitutive expression of tra-1. Mutations in her-1 are without effect on XX animals, but the her-2 mutation prevents sperm production in both XX and XO animals, in addition to its effect on the sexual phenotype of XO animals. The epistatic relationships between tra and her genes are used to deduce a model for the action of these genes in controlling sex determination.     

Expression pattern of glucose metabolism genes in relation to development rate of buffalo (Bubalus bubalis) oocytes and in vitro–produced embryos

The expression pattern of glucose metabolism genes (hexokinase, phosphofructokinase, glucose-6-phosphate dehydrogenase [G6PDH], lactate dehydrogenase [LDH], and pyruvate dehydrogenase [PDH]) were studied in buffalo in vitro–matured oocytes and in vitro–produced embryos cultured under different glucose concentrations (0 mM, 1.5 mM, 5.6 mM, and 10 mM) during in vitro maturation of oocytes and culture of IVF produced embryos. The expression of the genes varied significantly over the cleavage stages under different glucose concentrations. Developmental rate of embryos was highest under a constant glucose level (5.6 mM) throughout during maturation of oocytes and embryo culture. Expression pattern of glucose metabolism genes under optimum glucose level (5.6 mM) indicated that glycolysis is the major pathway of glucose metabolism during oocyte maturation and early embryonic stages (pre-maternal to zygotic transition [MZT]) and shifts to oxidative phosphorylation during post-MZT stages in buffalo embryos. Higher glucose level (10 mM) caused abrupt changes in gene expression and resulted in shifting toward anaerobic metabolism of glucose during post-MZT stages. This resulted in decreased development rate of embryos during post-MZT stages. High expression of LDH and PDH in the control groups (0 mM glucose) indicated that in absence of glucose, embryos try to use available pyruvate and lactate sources, but succumb to handle the post-MZT energy requirement, resulting to poor development rate. Expression pattern of G6PDH during oocyte maturation as well early embryonic development was found predictive of quality and development competence of oocytes/ embryos.     

X-linked mutations that give rise to overproduction of glucose-6-phosphate dehydrogenase in Drosophila melanogaster

Two X-linked mutations that give rise to overproduction of glucose-6-phosphate dehydrogenase (G6PD) were found among the progenies of isogenic strains which had been subjected to selection for high G6PD activity. Mapping of the high-activity factor in these mutants was carried out using car Zw ^B sw males of low G6PD activity. As a result, the factor mapped 0.02–0.04 unit to the left of the Zw locus. The amount of the G6PD gene was also quantitated utilizing a cloned G6PD gene as a probe, but no significant difference was found between the mutants and low-G6PD activity flies which shared the same X, second, and third chromosomes with the mutants. These findings are consistent with our notion that the mutations might be regulatory mutations, possibly resulting from the insertion of a novel class of transposable genetic elements.This research was supported by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science and Culture, Japan.     

High-level regulated expression of the human G6PD gene in transgenic mice

The glucose-6-phosphate dehydrogenase-encoding gene (G6PD) belongs to a group with constitutive expression in all tissues. The regulation of these housekeeping genes is poorly understood, as compared to what is known about many genes whose expression is restricted to a particular tissue or stage of development, and which are often regulated by locus control regions (LCR) able to act over wide distances. In order to identify sequences in human G6PD which are necessary for its expression, we have generated transgenic mice carrying a 20-kb G6PD construct, including only 2.5 kb of upstream and 2.0 kb of downstream flanking sequence. All mice which carried the transgene (TG) expressed it, and the levels of expression detected in a range of tissues from three independent lines of mice were comparable to that of the endogenous murine G6PD. The variation in enzyme activity from tissue to tissue was remarkably similar for both the TG and the endogenous gene, and was shown to be due in both cases to variations in the steady-state mRNA levels.     

Human alpha B-crystallin mutation causes oxido-reductive stress and protein aggregation cardiomyopathy in mice

The autosomal dominant mutation in the human alphaB-crystallin gene inducing a R120G amino acid exchange causes a multisystem, protein aggregation disease including cardiomyopathy. The pathogenesis of cardiomyopathy in this mutant (hR120GCryAB) is poorly understood. Here, we show that transgenic mice overexpressing cardiac-specific hR120GCryAB recapitulate the cardiomyopathy in humans and find that the mice are under reductive stress. The myopathic hearts show an increased recycling of oxidized glutathione (GSSG) to reduced glutathione (GSH), which is due to the augmented expression and enzymatic activities of glucose-6-phosphate dehydrogenase (G6PD), glutathione reductase, and glutathione peroxidase. The intercross of hR120GCryAB cardiomyopathic animals with mice with reduced G6PD levels rescues the progeny from cardiac hypertrophy and protein aggregation. These findings demonstrate that dysregulation of G6PD activity is necessary and sufficient for maladaptive reductive stress and suggest a novel therapeutic target for abrogating R120GCryAB cardiomyopathy and heart failure in humans.     

Correction of Steroid Sulfatase Deficiency by Gene Transfer into Basal Cells of Tissue-Cultured Epidermis from Patients with Recessive X-Linked Ichthyosis

To develop an experimental model for somatic gene therapy we have tried to correct the steroid sulfatase (STS) deficiency in tissue-cultured primary epidermal keratinocytes from patients suffering from recessive X-linked ichthyosis. An efficient Epstein-Barr virus-based vector was constructed, in which full-length steroid sulfatase cDNA is located between an SV40 early promotor and processing signals. After STS gene transfer into cultured basal cells from ichthyotic skin, the cells produce large amounts of enzymatically active steroid sulfatase protein. The subpopulation of transfected cells can be made to produce approximately 100 times more STS activity than normal keratinocytes. Keratinocytes from patients suffering from recessive X-linked ichthyosis display an abnormal phenotype when developing a multilayered tissue in culture: Initially an extensive burst of keratinization is observed, followed by rapid, premature shedding and degradation of most suprabasal cell layers, leaving a culture with hyperproliferative relatively immature keratinocytes. Transfection of these immature ichthyotic cells with the functional STS construct led to an increase in the amount of retained cell material in the culture medium, indicating an increased cell maturation. It is possible to genetically label individual transfected epidermal cells with a reporter gene. Cotransfection experiments with STS and reporter gene vectors show that the cohort of transfected cells had a tendency to develop less rapidly since they became overrepresented in the smaller size classes at the same time the total population was somewhat shifted toward higher cell sizes. We interpret these results as an indication that restoration of the enzymatic activity induces a more normal maturation of the transfected keratinocytes.     

Differential increase of steroid sulfatase activity in XX and XY trophoblast cells from human term placenta with syncytia formation in vitro

Steroid sulfatase (STS, EC 3.1.6.2) catalyzes the hydrolysis of the sulfate ester bonds of a variety of sulfated steroids, such as cholesterol, dehydroepiandrosterone, and estrone sulfate, a reaction influencing fertility and breast cancer in mammals. The activity of the enzyme is substantially elevated in placental syncytiotrophoblasts and is lower in other somatic cells. The polypeptide sequence of the enzyme is encoded by a gene located on the distal short arm of the human X chromosome. Prior studies have shown that the STS gene escapes X-chromosome inactivation. We studied the expression of the STS gene in primary cultures of cytotrophoblasts from human term placentae and compared it with the expression of autosomally encoded placental alkaline phosphatase (PALP) and X-linked glucose-6-phosphate dehydrogenase (G6PD). During 90 h in culture, the mononucleated cytotrophoblast cells did not proliferate, but differentiated into multinucleated, syncytiotrophoblast-like cells. STS activity in freshly isolated cytotrophoblasts was low (about 17%), compared to placental tis- sue, and about 1.7-fold higher in female than in male cells. During cultivation, STS activity increased 2- to 3-fold in female, but not in male, cells. PALP activity was very low in freshly isolated cytotrophoblasts (about 5% of placental tissue), and no significant difference between female and male cells was detectable. Within 90 h in culture, PALP activity increased in all preparations about 2- to 4-fold. G6PD activity in freshly isolated cytotrophoblasts showed great variation among preparations, and no significant difference between female and male cells was detectable. In both male and female cells the activity declined to about 50% of initial activity during cultivation. We conclude that human cytotrophoblasts in primary culture show a sex-specific regulation of STS activity, perhaps as a unique feature of the STS gene. The cytotrophoblast system may offer a new possibility to study the regulation of STS gene expression.     

Quantification of Colonic Stem Cell Mutations

The ability to measure stem cell mutations is a powerful tool to quantify in a critical cell population if, and to what extent, a chemical can induce mutations that potentially lead to cancer. The use of an enzymatic assay to quantify stem cell mutations in the X-linked glucose-6-phosphate dehydrogenase gene has been previously reported.¹ This method requires the preparation of frozen sections and incubation of the sectioned tissue with a reaction mixture that yields a blue color if the cells produce functional glucose-6-phosphate dehydrogenase (G6PD) enzyme. If not, the cells appear whitish. We have modified the reaction mixture using Optimal Cutting Temperature Compound (OCT) medium in place of polyvinyl alcohol. This facilitates pH measurement, increases solubilization of the G6PD staining components and restricts diffusion of the G6PD enzyme. To demonstrate that a mutation occurred in a stem cell, the entire crypt must lack G6PD enzymatic activity. Only if a stem cell harbors a phenotypic G6PD mutation will all of the progeny in the crypt lack G6PD enzymatic activity. To identify crypts with a stem cell mutation, four consecutive adjacent frozen sections (a level) were cut at 7 µm thicknesses. This approach of making adjacent cuts provides conformation that a crypt was fully mutated since the same mutated crypt will be observed in adjacent sections. Slides with tissue samples that were more than 50 µm apart were prepared to assess a total of >10⁴ crypts per mouse. The mutation frequency is the number of observed mutated (white) crypts ÷ by the number of wild type (blue) crypts in a treatment group.     

African Glucose-6-Phosphate Dehydrogenase Alleles Associated with Protection from Severe Malaria in Heterozygous Females in Tanzania

X-linked Glucose-6-phosphate dehydrogenase (G6PD) A- deficiency is prevalent in sub-Saharan Africa populations, and has been associated with protection from severe malaria. Whether females and/or males are protected by G6PD deficiency is uncertain, due in part to G6PD and malaria phenotypic complexity and misclassification. Almost all large association studies have genotyped a limited number of G6PD SNPs (e.g. G6PD202 / G6PD376), and this approach has been too blunt to capture the complete epidemiological picture. Here we have identified 68 G6PD polymorphisms and analysed 29 of these (i.e. those with a minor allele frequency greater than 1%) in 983 severe malaria cases and controls in Tanzania. We establish, across a number of SNPs including G6PD376, that only female heterozygotes are protected from severe malaria. Haplotype analysis reveals the G6PD locus to be under balancing selection, suggesting a mechanism of protection relying on alleles at modest frequency and avoiding fixation, where protection provided by G6PD deficiency against severe malaria is offset by increased risk of life-threatening complications. Our study also demonstrates that the much-needed large-scale studies of severe malaria and G6PD enzymatic function across African populations require the identification and analysis of the full repertoire of G6PD genetic markers.     

Molecular characterization of glucose-6-phosphate dehydrogenase deficiency in Jeddah,Kingdom of Saudi Arabia

Background

The development of polymerase chain reaction (PCR)-based methods for the detection of known mutations has facilitated detecting specific red blood cell (RBC) enzyme deficiencies. We carried out a study on glucose-6-phosphate dehydrogenase (G6PD) deficient subjects in Jeddah to evaluate the molecular characteristics of this enzyme deficiency and the frequency of nucleotide1311 and IVS-XI-93 polymorphisms in the glucose-6-phosphate dehydrogenase gene.

Results

A total of 1584 unrelated Saudis (984 neonates and 600 adults) were screened for glucose-6-phosphate dehydrogenase deficiency. The prevalence of glucose-6-phosphate dehydrogenase deficiency was 6.9% (n = 110). G6PD Mediterranean mutation was observed in 98 (89.1%) cases, G6PD Aures in 11 (10.0%) cases, and G6PD Chatham in 1 (0.9%) case. None of the samples showed G6PD A￣ mutation. Samples from 29 deficient subjects (25 males and 4 females) were examined for polymorphism. The association of two polymorphisms of exon/intron 11 (c.1311T/IVS-XI-93C) was observed in 14 (42.4%) of 33 chromosomes studied. This association was found in 9 (31.0%) carriers of G6PD Mediterranean and in 4 (13.8%) carriers of G6PD Aures.

Conclusions

The majority of mutations were G6PD Mediterranean, followed by G6PD Aures and < 1% G6PD Chatham. We conclude that 1311T is a frequent polymorphism in subjects with G6PD Mediterranean and Aures variants in Jeddah.

     

Human mutations in glucose 6-phosphate dehydrogenase reflect evolutionary history.

Glucose 6-phosphate dehydrogenase (G6PD) is a cytosolic enzyme encoded by a housekeeping X-linked gene whose main function is to produce NADPH, a key electron donor in the defense against oxidizing agents and in reductive biosynthetic reactions. Inherited G6PD deficiency is associated with either episodic hemolytic anemia (triggered by fava beans or other agents) or life-long hemolytic anemia. We show here that an evolutionary analysis is a key to understanding the biology of a housekeeping gene. From the alignment of the amino acid (aa) sequence of 52 glucose 6-phosphate dehydrogenase (G6PD) species from 42 different organisms, we found a striking correlation between the aa replacements that cause G6PD deficiency in humans and the sequence conservation of G6PD: two-thirds of such replacements are in highly and moderately conserved (50-99%) aa; relatively few are in fully conserved aa (where they might be lethal) or in poorly conserved aa, where presumably they simply would not cause G6PD deficiency. This is consistent with the notion that all human mutants have residual enzyme activity and that null mutations are lethal at some stage of development. Comparing the distribution of mutations in a human housekeeping gene with evolutionary conservation is a useful tool for pinpointing amino acid residues important for the stability or the function of the corresponding protein. In view of the current explosive increase in full genome sequencing projects, this tool will become rapidly available for numerous other genes.