PRTFDC1 is a genetic modifier of HPRT-deficiency in the mouse

Lesch-Nyhan disease (LND) is a severe X-linked neurological disorder caused by a deficiency of hypoxanthine phosphoribosyltransferase (HPRT). In contrast, HPRT-deficiency in the mouse does not result in the profound phenotypes such as self-injurious behavior observed in humans, and the genetic basis for this phenotypic disparity between HPRT-deficient humans and mice is unknown. To test the hypothesis that HPRT deficiency is modified by the presence/absence of phosphoribosyltransferase domain containing 1 (PRTFDC1), a paralog of HPRT that is a functional gene in humans but an inactivated pseudogene in mice, we created transgenic mice that express human PRTFDC1 in wild-type and HPRT-deficient backgrounds. Male mice expressing PRTFDC1 on either genetic background were viable and fertile. However, the presence of PRTFDC1 in the HPRT-deficient, but not wild-type mice, increased aggression as well as sensitivity to a specific amphetamine-induced stereotypy, both of which are reminiscent of the increased aggressive and self-injurious behavior exhibited by patients with LND. These results demonstrate that PRTFDC1 is a genetic modifier of HPRT-deficiency in the mouse and could therefore have important implications for unraveling the molecular etiology of LND.     

XY follicle cells in ovaries of XX----XY female mouse chimaeras

Oocytes with adhering follicle cells were sampled from ovaries obtained from 11 GPI-1A----GPI-1B chimaeras, comprising 10 females and 1 hermaphrodite. GPI analysis of individual oocytes revealed a marked bias towards the GPI-1B component in the germ line of this chimaeric combination. GPI-1B XY oocytes were identified in the ovary from the hermaphrodite, the bias towards the GPI-1B germ line perhaps helping to counterbalance the normally severe selection against XY oocytes. GPI analysis of follicle cells revealed a much more balanced contribution of the two components to this ovarian cell type. Importantly, GPI-1A follicle cells were identified in more than half the follicles from an XX----XY female in which the GPI-1A component was XY, supporting an earlier conclusion of Ford et al. (1974) that XY cells can contribute to the follicles of XX----XY female mice. It is suggested that XY cells can be recruited to form follicle cells in XX----XY chimaeras when there is a developmental mismatch between the two components, such that an ovary-determining signal produced by the XX component pre-empts the testis-determining action of the Y.     

Use of the HPRT gene and the HAT selection technique in DNA-mediated transformation of mammalian cells: first steps toward developing hybridoma techniques and gene therapy.

In 1956, I decided to apply my experience in microbial genetics to developing analogous systems for human cell lines, including the selection of mutants with either a loss or gain of a biochemical function. For instance, mutants resistant to azahypoxanthine showed a loss of the HPRT enzyme (hypoxanthine phosphoribosyl transferase), whereas gain of the same enzyme was accomplished by blocking de novo purine biosynthesis with aminopterin, while supplying hypoxanthine and thymine (HAT selection). Using HAT selection, we: (i) genetically transformed HPRT- mutant cells to HPRT+ wild type by using DNA extracted from HPRT+ cells, and (ii) selected HPRT+ hybrid cells by fusing HPRT- D98/AH2 cells with skin cells. These approaches, which we dubbed in 1962 as a 'first step toward gene therapy', contributed to the later development of (i) cell fusion techniques, (ii) the development of monoclonal antibodies, (iii) routine transformation of mammalian cells with cloned genes, and (iv) methods for creating transgenic organisms.     

Studies on cell communication with enucleated human fibroblasts

Metabolic cooperation, the correction of the mutant phenotype in cells deficient in hypoxanthine phosphoribosyltransferase (HPRT-) by intimate contact with normal cells (HPRT+), represents a form of cell communication that is easily studied with radioautography. In the present study it was found that the formation of cell junctions needed for communication does not require protein synthesis nor is it under the immediate control of the cell nucleus. Enucleated normal cells efficiently communicate with HPRT- mutant cells. The effectiveness of enucleated cells as donors in metabolic cooperation provides evidence that it is the transfer of small molecules, nucleotide, or nucleotide derivatives that is responsible for correction of the mutant phenotype. Karyoplasts (nuclei with small amounts of cytoplasm surrounded by a plasma membrane) are unable to efficiently communicate with intact cells. The utilization of [3H]hypoxanthine by communicating mixtures of HPRT+ and HPRT- human cells is not significantly different than in the normal cells alone. Metabolic cooperation, as studied involves a redistribution of purine-containing compounds among communicating cells.     

Regulation of purine de novo synthesis in cultured human fibroblasts: the role of P-ribose-PP.

Procedures for assaying the rate of purine de novo synthesis in cultured fibroblast cells have been compared. These were (i) the incorporation of [(14)C]-glycine or [(14)C]formate in alpha-N-formylglycinamide ribonucleotide (an intermediate in the purine synthetic pathway) and (ii) the incorporation of [(14)C]-formate into newly synthesised cellular purines and purines excreted by the cell into the medium. Fibroblast cells, derived from patients with a deficiency of hypoxanthine phosphoribosyltransferase (HPRT-) (EC 2.4.2.8) and increased rates of purine de novo synthesis, were compared with fibroblasts from healthy subjects (HPRT+). Fetal calf serum, which was used to supplement the assay and cell growth medium, was found to contain sufficient quantities of the purine base hypoxanthine to inhibit purine de novo synthesis in HPRT+ cells. This inhibition was the basis of differentiation between HPRT- and HPRT+ cells. In the absence of added purine base, both cell types had similar capacities for purine de novo synthesis. This result contrasts with the increased rates of purine de novo synthesis reported for a number of human HPRT- cells in culture but conforms recent studies made on human HPRT- lymphoblast cells. The intracellular concentration and utilisation of 5-phosphoribosyl-1-pyrophosphate (P-Rib-PP), a substrate and potential controlling factor for purine de novo synthesis, were determined in HPRT- and HPRT+ cells. The rate of utilisation of P-Rib-PP in the salvage of free purine bases was far greater than that in purine de novo synthesis. Although HPRT- cells had a 3-fold increase in P-Rib-PP content, the rate of P-Rib-PP generation was similar to HPRT+ cells. Thus, in fibroblasts, the concentration of P-Rib-PP appears to be critical in the control of de novo purine synthesis and its preferential utilisation in the HPRT reaction limits its availability for purine de novo synthesis. In vivo, HPRT+ cells, in contrast to HPRT- cells, may be operating purine de novo synthesis at a reduced rate because of their ability to reutilise hypoxanthine.     

Evidence for selection against tetraploid cells in tetraploid<-->diploid mouse chimaeras before the late blastocyst stage

Tetraploid (4n) cells do not contribute equally to all tissues of midgestation mouse chimaeras and mosaics. Our previous studies of early blastocysts showed that 4n cells are preferentially allocated to the mural trophectoderm of the early blastocyst and this may contribute to the restricted distribution pattern seen at later stages. In this study of later-stage blastocysts we found evidence for selection against 4n cells. The contribution of 4n cells to 4n<-->2n chimaeric blastocysts decreased between E3.5 and E4.5 days, whereas the composition of 2n<-->2n controls changed little over this period. These results suggest that, prior to implantation, blastocysts have already lost some tetraploid cells from their embryonic and extra-embryonic lineages due to a combination of preferential allocation of 4n cells to the mural trophectoderm and selection against 4n cells throughout the embryo.     

Decreased GTP-stimulated adenylyl cyclase activity in HPRT-deficient human and mouse fibroblast and rat B103 neuroblastoma cell membranes

Defect of the purine salvage enzyme, hypoxanthine phosphoribosyl transferase (HPRT), results in Lesch-Nyhan disease (LND). It is unknown how the metabolic defect translates into the severe neuropsychiatric phenotype characterized by self-injurious behavior, dystonia and mental retardation. There are abnormalities in GTP, UTP and CTP concentrations in HPRT-deficient cells. Moreover, GTP, ITP, XTP, UTP and CTP differentially support Gs-protein-mediated adenylyl cyclase (AC) activation. Based on these findings we hypothesized that abnormal AC regulation may constitute the missing link between HPRT deficiency and the neuropsychiatric symptoms in LND. To test this hypothesis, we studied AC activity in membranes from primary human skin and immortalized mouse skin fibroblasts, mouse Neuro-2a neuroblastoma cells and rat B103 neuroblastoma cells. In B103 control membranes, GTP, ITP, XTP and UTP exhibited profound stimulatory effects on basal AC activity that approached the effects of hydrolysis-resistant nucleotide analogs. In HPRT- membranes, the stimulatory effects of GTP, ITP, XTP and UTP were strongly reduced. Similarly, in human and mouse skin fibroblast membranes we also observed a decrease in GTP-stimulated AC activity in HPRT-deficient cells compared with the respective controls. In mouse Neuro-2a neuroblastoma membranes, AC activity in the presence of GTP was below the detection limit of the assay. We discuss several possibilities to explain the abnormalities in AC regulation in HPRT deficiency that encompass various species and cell types.     

The peripheral chimerism of bone marrow–derived stem cells after transplantation: regeneration of gastrointestinal tissues in lethally irradiated mice

Bone marrow–derived cells represent a heterogeneous cell population containing haematopoietic stem and progenitor cells. These cells have been identified as potential candidates for use in cell therapy for the regeneration of damaged tissues caused by trauma, degenerative diseases, ischaemia and inflammation or cancer treatment. In our study, we examined a model using whole-body irradiation and the transplantation of bone marrow (BM) or haematopoietic stem cells (HSCs) to study the repair of haematopoiesis, extramedullary haematopoiesis and the migration of green fluorescent protein (GFP⁺) transplanted cells into non-haematopoietic tissues. We investigated the repair of damage to the BM, peripheral blood, spleen and thymus and assessed the ability of this treatment to induce the entry of BM cells or GFP⁺lin⁻Sca-1⁺ cells into non-haematopoietic tissues. The transplantation of BM cells or GFP⁺lin⁻Sca-1⁺ cells from GFP transgenic mice successfully repopulated haematopoiesis and the haematopoietic niche in haematopoietic tissues, specifically the BM, spleen and thymus. The transplanted GFP⁺ cells also entered the gastrointestinal tract (GIT) following whole-body irradiation. Our results demonstrate that whole-body irradiation does not significantly alter the integrity of tissues such as those in the small intestine and liver. Whole-body irradiation also induced myeloablation and chimerism in tissues, and induced the entry of transplanted cells into the small intestine and liver. This result demonstrates that grafted BM cells or GFP⁺lin⁻Sca-1⁺ cells are not transient in the GIT. Thus, these transplanted cells could be used for the long-term treatment of various pathologies or as a one-time treatment option if myeloablation-induced chimerism alone is not sufficient to induce the entry of transplanted cells into non-haematopoietic tissues.     

Gonadal Effects of a Mouse Denys-Drash Syndrome Mutation

Gonadal effects of the Denys-Drash syndrome (DDS) mutation Wt1^tmT396 were examined in chimaeric and heterozygous mice. Since the only heterozygote was 41,XXY, Sertoli cell function was assessed by comparison with age-matched control XXY testes. Control XXY Sertoli cells showed immunoexpression of WT1 and androgen receptor (AR) indistinguishable from wild-type (40,XY), but expressed anti-Mullerian hormone (AMH). In contrast, DDS Sertoli cells showed only faint immunoexpression of WT1 and did not express AR or AMH. While XY↔XY DDS chimaeras were male, XX↔XY chimaeras were predominantly female. In the rare XX↔XY DDS males the Sertoli cell lineage was largely derived from Wt1 mutant XY cells. We conclude that DDS mutant cells can form Sertoli cells, that the dominant mutation does not cause male sex reversal in mice but distorts the sex ratio of XX↔XY chimaeras, and that there may be a link between WT1, AMH and AR expression by Sertoli cells in vivo.     

Transformation of Hprt gene with sperm DNA

Inactivation of the X chromosome during mammalian spermatogenesis has been postulated to occur by the same mechanism that controls female somatic X chromosome inactivation. We have used DNA-mediated transformation of HPRT- cells to test this idea, because it has been shown previously that inactive X chromosome DNA from somatic cells will not transform HPRT- cells. Isolated DNA from the mature sperm of five mammals (human, mouse, horse, bull, rabbit) were all capable of HPRT transformation, and transformants were confirmed electrophoretically. Measures were taken to ensure that the transformation frequencies observed could not be due to somatic contamination. The positive HPRT transformation result indicates that mature sperm X chromosomal DNA is not modified in the same manner as that of female inactive X chromosomal DNA. Since there is evidence for methylation of the somatic inactive X chromosome, it is possible that methylation, at least for the genes studied, is not involved in sperm X chromosome inactivation.     

Gene duplication and inactivation in the HPRT gene family

Hypoxanthine phosphoribosyltransferase (HPRT1) is a key enzyme in the purine salvage pathway, and mutations in HPRT1 cause Lesch-Nyhan disease. The studies described here utilized targeted comparative mapping and sequencing, in conjunction with database searches, to assemble a collection of 53 HPRT1 homologs from 28 vertebrates. Phylogenetic analysis of these homologs revealed that the HPRT gene family expanded as the result of ancient vertebrate-specific duplications and is composed of three groups consisting of HPRT1, phosphoribosyl transferase domain containing protein 1 (PRTFDC1), and HPRT1L genes. All members of the vertebrate HPRT gene family share a common intron-exon structure; however, we have found that the three gene groups have distinct rates of evolution and potentially divergent functions. Finally, we report our finding that PRTFDC1 was recently inactivated in the mouse lineage and propose the loss of function of this gene as a candidate genetic basis for the phenotypic disparity between HPRT-deficient humans and mice.     

Use of BRL-conditioned medium in combination with feeder layers to isolate a diploid embryonal stem cell line

Summary The derivation of a karyotypically normal embryonal stem (ES) cell line, E14, from inner cell masses (ICMs) isolated by immunosurgery from 129/Ola late mouse blastocysts is described. Disaggregated ICMs were cultured on mitotically-arrested fibroblast feeder layers in droplets of medium conditioned with Buffalo rat liver (BRL) cells under oil. BRL-conditioned medium inhibits the differentiation of established embryonal carcinoma (EC) and ES cell lines which can be maintained indefinitely in the complete absence of feeder cells (Smith and Hooper 1987). At clonal densities, however, a combination of BRL-conditioned medium and a feeder layer was most effective in preventing the differentiation of E14 cells. This effect was less pronounced at higher passage suggesting it may be particularly important to use a combination in the early stages of isolation. Once established, E14 has been maintained in BRL-conditioned medium alone. In non-conditioned medium on agarose, E14 cells formed embryoid bodies which when allowed to reattach differentiated into a wide variety of tissues. An HPRT-deficient sub line of E14, E14TG2a, has been demonstrated to form germline chimaeras with high efficiency after injection into blastocysts (Hooper et al. 1987). The modifications to the ES cell isolation procedure described here may improve the efficiency with which karyotypically normal lines can be derived.     

Marker Chromosome Analysis of Tetraparental AKR↔CBA-T6 Mouse Chimaeras

Marker chromosome analysis of 18 tetraparental AKR↔CBA/H-T6 chimaeras revealed a great excess of AKR mitoses over CBA mitoses in direct preparations from lymphomyeloid tissues, corneal epithelium, intestinal epithelium and skin (Table 1). The degree of AKR dominance was strongly influenced by anatomical site (Tables 2 and 3). The testes of three out of four XY/XY males contained a marked excess of AKR germ cells and produced a parallel excess of functional AKR gametes (Table 4). Mitotic spreads in mitogen-stimulated cultures of tail blood were overwhelmingly of AKR type in 1972, but less so in 1973 (Table 5).
The coat phenotypes, and breeding results from known or presumptive XX/XX females, suggest that AKR and CBA cells were numerically balanced when melanoblasts and oocytes were formed during embryonic development, and therefore that the striking deviations from equality observed in mitotic populations of adult chimaeras arose later by differential proliferation or survival of AKR cells, or both.
The low frequency of lymphomas, compared with normal AKR mice, previously reported in these chimaeras cannot therefore be accounted for by insufficiency of AKR cells in the thymus or elsewhere in the lymphomyeloid tissues. One of three lymphomas studied was CBA type. This suggests that the high risk of lymphomatous transformation is not an autonomous property of AKR cells.     

Experimental embryonic-somatic chimaerism in the sheep confirmed by random amplified polymorphic DNA assay

Developmental potencies of sheep somatic cells (foetal fibroblasts, FFs) in chimaeric animals were analysed. FFs from pigmented Polish Heatherhead (wrzosowka) breed were microsurgically injected into morulae or blastocysts of white Polish Merino breed (5 cells to each embryo). In one experiment the cells were stained with vital fluorescent dye PKH26, and chimaeric blastocysts were cultured in vitro to confirm the presence of fluorescent cells. In the majority of experiments the blastocysts were transferred to synchronized recipient ewes for development until term. Cultured embryonic cells (CEC), earlier known to produce chimaeras, were injected into blastocysts in control experiments. Seven young were born from FF-injected embryos and three were born from CEC-injected ones. All of them were white, but all three control lambs and three experimental lambs showed small areas of skin pigmentation, which indicated Heatherhead CEC or FF contribution. Tissue samples originating from three germ layers were taken from two FFs-originating presumably chimaeric lambs (male and female) at the age of one month for DNA analysis. The random amplified polymorphic DNA-PCR method supplied two markers of chimaerism, which were amplification products of 643 bp and 615 bp long DNA fragments, found in tissues of experimental lambs as well as in FFs, but not in the blood of parents of blastocysts. The 643 bp marker was found in the majority of tissues of both lambs. The 615 bp amplicon was detected in the skin and lungs of the female lamb and in the hooves of the male lamb. Our data show that foetal fibroblasts introduced to sheep blastocysts can participate in development and can contribute to all tissue lineages up to at least one month of age.     

Hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency: Identification of point mutations in Japanese patients with Lesch-Nyhan syndrome and hereditary gout and their permanent expression in an HPRT-deficient mouse cell line

Two different single nucleotide transitions of hypoxanthine-guanine phosphoribosyltransferase (HPRT) were identified in a Japanese patient with Lesch-Nyhan syndrome (LNS) and a patient with hereditary gout. HPRT enzyme activities in the two patients were severely deficient, but the size and amount of mRNA were normal according to Northern analysis. Entire coding regions of HPRT cDNAs were amplified by PCR and sequenced. A G-to-A substitution at base 208 in exon 3, which predicted glycine 70 to arginine, was detected in the LNS patient (identical mutation with HPRT_Utrecht). A C-to-A substitution at base 73 in exon 2, which predicted proline 25 to threonine, was detected in the gout patient (designated HPRT_Yonago). We transfected normal HPRT cDNA, mutant cDNA with HRPT_Utrecht or mutant cDNA with HPRT_Yonago, respectively, to HPRT-deficient mouse cells and isolated permanent expression cell lines. The HPRT-deficient mouse cells had no detectable HPRT activity and a very low amount of HPRT mRNA. When the HPRT-deficient mouse cells were transfected with normal human cDNA, HPRT enzyme activity increased to 21.8% that of normal mouse cells. The mouse cells transfected with HPRT_Utrecht showed no increase in HPRT activity; however, when the mouse cells were transfected with HPRT_Yonago, the activity increased to 2.4% that of normal activity. The proliferative phenotypes of these cells in HAT medium and in medium containing 6-thioguanine were similar to those of skin fibroblasts from the patients. This series of studies confirmed that each of the two point mutations was responsible for the decreases in HPRT enzyme activity, and the proliferative phenotypes in HAT medium and medium containing 6-thioguanine.     

Endogenous HPRT activity in mycoplasmas isolated from cell cultures

Five mycoplasma species most frequently isolated from cell cultures were tested for the presence of endogenous hypoxanthine phosphoribosyl-transferase (HPRT) activity. All of the five, cultured in cell-free medium, contained variable but significant levels of HPRT. Two strains of M. hyorhinis exhibited a 13-fold difference in their specific HPRT activity. When infected with any of these mycoplasma species, HPRT-deficient mouse cell mutants rapidly acquired a cell-associated HPRT activity; however, the cells remained sensitive to HAT medium and resistant to 6-thioguanine. On the other hand, normal HPRT-positive cells deliberately infected with the mycoplasmas uniformly became sensitive to HAT medium. The apparent transfer of mycoplasma-specific HPRT activity to HPRT-deficient cells may be used as a sensitive measure of cell infection by these mycoplasma strains. The HPRT activities of mycoplasmas share several common properties so that they can be distinguished easily from the mammalian HPRT isozymes. Compared to the animal cell enzymes, the mycoplasmal HPRT activities are less heat stable, more strongly inhibited by 6-thioguanine, and in general migrate more slowly in electrophoresis at a neutral pH.     

Use of double-replacement gene targeting to replace the murine alpha-lactalbumin gene with its human counterpart in embryonic stem cells and mice.

The mouse alpha-lactalbumin gene has been replaced with the human gene by two consecutive rounds of gene targeting in hypoxanthine phosphoribosyltransferase (HPRT)-deficient feeder-independent murine embryonic stem (ES) cells. One mouse alpha-lactalbumin allele was first replaced by an HPRT minigene which was in turn replaced by human alpha-lactalbumin. The end result is a clean exchange of defined DNA fragments with no other DNA remaining at the target locus. Targeted ES cells at each stage remained capable of contributing efficiently to the germ line of chimeric animals. Double replacement using HPRT-deficient ES cells and the HPRT selection system is therefore a powerful and flexible method of targeting specific alterations to animal genes. A typical strategy for future use would be to generate a null mutation which could then be used to produce multiple second-step alterations at the same locus.     

Use of triple tissue blastocyst reconstitution to study the development of diploid parthenogenetic primitive ectoderm in combination with fertilization-derived trophectoderm and primitive endoderm

Diploid mouse conceptuses lacking a paternal genome can form morphologically normal but small fetuses of up to 25 somites, but they invariably fail to develop beyond mid-gestation. Such conceptuses differ from normal most notably in the poor development of extra-embryonic tissues which are largely of trophectodermal and primitive endodermal origin. However, it is not clear whether the demise of diploid parthenogenetic (P) or gynogenetic (G) conceptuses is attributable entirely to the defective development of these two tissues or whether differentiation of the primitive ectoderm, the precursor of the foetus, extra-embryonic mesoderm and amnion, is also impaired by the absence of a paternal genome. Therefore, a new blastocyst reconstitution technique was used which enabled primitive ectoderm from P blastocysts to be combined with primitive endoderm and trophectoderm from fertilization-derived (F) blastocysts. One third of the 'triple tissue' reconstituted blastocysts that implanted yielded foetuses. However, all foetuses recovered on the 11th or 12th day of gestation were small and, with one exception, either obviously retarded or arrested in development. The exception was a living 44 somite specimen which is the most advanced P foetus yet recorded. Foetuses were invariably degenerating in conceptuses recovered on the 13th day. In contrast, at least 16% of control reconstituted blastocysts with primitive ectoderm as well as primitive endoderm and trophectoderm of F origin developed normally on the 13th day of gestation or to term. Hence, the presence of a paternal genome seems to be essential for normal differentiation of all 3 primary tissues of the mouse blastocyst. The P foetuses that developed from reconstituted blastocysts were so closely invested by their membranes that they often showed abnormal flexure of the posterior region of the body. Several also showed a deficiency of allantoic tissue. Therefore, the possibility that the defect in development of P primitive ectoderms resided in their extra-embryonic tissues was investigated by analysing a series of chimaeras produced by injecting them into intact F blastocysts. The foregoing anomalies were not discernible even when P cells made a large contribution to the extra-embryonic mesoderm or amnion plus umbilical cord. Furthermore, selection against P cells was no greater in extra-embryonic derivatives of the primitive ectoderm than in the foetus itself.     

Epitope insertion into the human hypoxanthine phosphoribosyltransferase protein and detection of the mutant protein by an anti-peptide antibody

The translational stop codon TAA of the human hypoxanthine phosphoribosyltransferase (HPRT) cDNA has been changed to GAA by site-specific mutagenesis. This modification extends the open reading frame to a downstream stop codon and results in the addition of a unique negatively charged hexapeptide to the C terminus of human HPRT protein. The mutated cDNA was transferred into HPRT-deficient rodent cells by retroviral vector infection, and the expressed enzyme was found to be fully active. An antibody against a synthetic octapeptide corresponding to the mutated HPRT C terminus precipitated the HPRT protein specifically from cells infected with the mutant virus and not infected with the wild-type HPRT virus. The technique of inserting a novel epitope into a protein by site-directed mutagenesis should be generally applicable in studies of the regulation of gene expression in vitro and in vivo.