Thrombomodulin-dependent protein C activation is required for mitochondrial function and myelination in the central nervous system.

Essentials The role of protein C (PC) activation in experimental autoimmune encephalitis (EAE) is unknown. PC activation is required for mitochondrial function in the central nervous system. Impaired PC activation aggravates EAE, which can be compensated for by soluble thrombomodulin. Protection of myelin by activated PC or solulin is partially independent of immune-modulation. SUMMARY: Background Studies with human samples and in rodents established a function of coagulation proteases in neuro-inflammatory demyelinating diseases (e.g. in multiple sclerosis [MS] and experimental autoimmune encephalitis [EAE]). Surprisingly, approaches to increase activated protein C (aPC) plasma levels as well as antibody-mediated inhibition of PC/aPC ameliorated EAE in mice. Hence, the role of aPC generation in demyelinating diseases and potential mechanisms involved remain controversial. Furthermore, it is not known whether loss of aPC has pathological consequences at baseline (e.g. in the absence of disease). Objective To explore the role of thrombomodulin (TM)-dependent aPC generation at baseline and in immunological and non-immunological demyelinating disease models. Methods Myelination and reactive oxygen species (ROS) generation were evaluated in mice with genetically reduced TM-mediated protein C activation (TMPro/Pro ) and in wild-type (WT) mice under control conditions or following induction of EAE. Non-immunological demyelination was analyzed in the cuprizone-diet model. Results Impaired TM-dependent aPC generation already disturbs myelination and mitochondrial function at baseline. This basal phenotype is linked with increased mitochondrial ROS and aggravates EAE. Reducing mitochondrial ROS (p66Shc deficiency), restoring aPC plasma levels or injecting soluble TM (solulin) ameliorates EAE in TMPro/Pro mice. Soluble TM additionally conveyed protection in WT-EAE mice. Furthermore, soluble TM dampened demyelination in the cuprizone-diet model, demonstrating that its myelin-protective effect is partially independent of an immune-driven process. Conclusion These results uncover a novel physiological function of TM-dependent aPC generation within the CNS. Loss of TM-dependent aPC generation causes a neurological defect in healthy mice and aggravates EAE, which can be therapeutically corrected.

Glucose metabolism and insulin secretion in a patient with ABCC8 mutation and Fanconi-Bickel syndrome caused by maternal isodisomy of chromosome 3.

Fanconi-Bickel syndrome (FBS) is a rare disorder of glucose transport caused by autosomal recessive mutations in GLUT2. Clinically, FBS results in growth failure, hepatomegaly, renal Fanconi syndrome, and abnormal glucose homeostasis. We report a 23 month old female with FBS characterized by more severe and refractory hypoglycemia than typically seen in this disorder. Although previous reports indicate that FBS patients have diminished insulin secretion, our patient showed evidence of hyperinsulinism (HI). Sequence analysis showed that the patient was homozygous for a known null mutation in GLUT2, confirming the clinical diagnosis of FBS. Parental genotyping showed that the mother was heterozygous for the GLUT2 mutation, while the father was wild type. Tandem repeat marker analysis showed that the patient inherited the GLUT2 mutation via maternal isodisomy of chromosome 3. Further molecular testing showed that the patient was heterozygous for a mutation in ABCC8, a known cause of congenital HI. We discuss the patient's biochemical responses in light of the molecular findings.

Stem cells from primordial germ cells can reenter the germ line.

Embryonic stem (ES) cells are totipotent cells derived from cultured preimplantation blastocysts. When injected into embryos, they can give rise to all somatic lineages as well as functional gametes. Embryonal carcinoma (EC) cells are pluripotent cells, derived from teratocarcinomas, which contribute to somatic lineages, but only rarely to the germ line. A novel source of pluripotent cells, remarkably similar to both ES and EC cells, has been identified. These are EG cells, derived by culturing primordial germ cells isolated from postimplantation embryos, but it is not known whether they resemble ES or EC cells in their ability to contribute to the germ line. Here we show that EG cells of both sexes can form functional gametes. The derivation of such cell lines offers a new route to deriving totipotent cells and also provides insights into the timing of X-chromosome inactivation/activation and genomic imprinting in the germ line.

Blastocyst implantation depends on maternal expression of leukaemia inhibitory factor.

A critical point during mammalian pregnancy is the implantation of the blastocyst when the embryo attaches to the wall of the uterus. The autonomously developing preimplantation embryo then becomes dependent on the maternal environment for its continued development. Little is known about the regulation of implantation, except that a complex interaction between peptide and steroid hormones synchronizes the preparation of the uterus for implantation with the development of the embryo. Whether the implantation event is under maternal or embryonic control is also unclear (reviewed in refs 1, 2). We have previously shown that a cytokine, leukaemia inhibitory factor (LIF), is expressed in the uterine endometrial glands specifically on the fourth day of pregnancy. This burst of expression is under maternal control and always precedes implantation of the blastocyst. Here we report that transient expression of LIF in mice is essential for implantation. Females lacking a functional LIF gene are fertile, but their blastocysts fail to implant and do not develop. The blastocysts, however, are viable and, when transferred to wild-type pseudopregnant recipients, they can implant and develop to term.

Androgenetic mouse embryonic stem cells are pluripotent and cause skeletal defects in chimeras: implications for genetic imprinting.

The inviability of diploid androgenetic and parthenogenetic embryos suggests imprinting of paternal and maternal genes during germ cell development, and differential expression of loci depending on parental inheritance appears to be involved. To facilitate identification of imprinted genes, we have derived diploid androgenetic embryonic stem (ES) cell lines. In contrast to normal ES cells, they form tumors composed almost entirely of striated muscle when injected subcutaneously into adult mice. They also form chimeras following blastocyst injection, although many chimeras die at early postnatal stages. Surviving chimeras develop skeletal abnormalities, particularly in the rib cartilage. These results demonstrate that androgenetic ES cells are pluripotent and point to stage- and cell-specific expression of developmentally important imprinted genes.

Homograft valve durability: host or donor influence?

Antibiotic sterilized valves have been shown to function longer than those chemically sterilized; however, the reason remains obscure. Current hypotheses cite either retention of donor fibroblasts capable of repairing the grafted valve, or host fibroblast ingrowth into and onto the leaflet ground substance. A cryopreserved aortic homograft from a male donor was explanted from a female recipient after 10 months, and subjected to immunocytochemistry, tissue culture, and karyotyping. The leaflet bases exhibited normal morphology with an intact endothelium. The distal one-third of the leaflets was devoid of fibroblasts from the leaflet bases showed them to be of host origin. This homograft seems to have been implanted with an intact ground substance which allowed for host cell repopulation of the inner one-third of the leaflets. Perhaps donor cell viability in itself is not as important to durability as is preservation of the leaflet ground substance, but rather the presence of viable cells may be an index of the structural integrity of the collagen and elastic matrix.

Spontaneous mutation rates of tumorigenic and nontumorigenic Chinese hamster embryo fibroblast cell lines.

The genomic stability of a series of nontumorigenic, tumorigenic, and tumor-derived Chinese hamster embryo fibroblastic (CHEF) cell lines was compared by examining their rates of spontaneous mutation at the hypoxanthine-guanine phosphoribosyl transferase (hprt) locus, using thioguanine resistance for selection of mutants. The spontaneous mutation rates were 1.1 x 10(-6) mutations/cell/generation in the non-tumor-forming CHEF/18 cell line and 4.9 x 10(-6) in the tumorigenic CHEF/16 cells. Three tumorigenic and tumor-derived CHEF cell lines derived from CHEF/18 (J132 3-2 T3L, focus 2, focus 3) and two lines (16-2 Tuk 4 and 204 Bu50 Tuk 2) derived from CHEF/16 were chosen on the basis of their karyotypes, which demonstrated a considerable level of chromosomal rearrangement. Mutation rates of four of these five lines ranged from 1.2 x 10(-6) to 8.9 x 10(-6) mutations per cell per generation. Only the fifth line, 16-2 Tuk 4, showed a significantly elevated rate of mutation as compared with the nontumorigenic CHEF/18 cell line. Thus, we have found no simple correlation between spontaneous mutation rate and the malignant phenotype, and we conclude that mutation rate per se is not a sensitive index of malignancy. In addition, we have compared three methods of calculating mutation rate and find that they rank the cell lines in the same order, but each stresses a different aspect of the distribution and therefore produces different estimates of the mutation rate.

Human and primate monoclonal antibodies for in vivo therapy.

Human monoclonal antibodies, owing to their decreased immunogenicity, are expected to be an improvement over mouse monoclonal antibodies for in vivo therapy. Human and primate monoclonal antibodies are best produced with a human x mouse heteromyeloma. Several human chromosomes are stable in the human x (human x mouse) hybrids. Chimpanzee anti-digoxin monoclonal antibodies were prepared and characterized. Because they are structurally very similar to human antibodies, they should be well tolerated in humans. The anti-digoxin antibodies can be used for therapy of extreme overdoses or as an in vivo diagnostic tool for slight overdoses. Because the advantage of using human monoclonal antibodies is their lack of immunogenicity, preparation of the antibody must be scrupulous so as not to introduce extraneous immunogens. Analysis to ensure the purity of the preparation can be complicated by the presence of high concentrations of the antibody and the low levels of contamination that must be detected. We describe a Western blot assay for Protein A that is sensitive even in the presence of human IgG.

High recombination between two physically close human basement membrane collagen genes at the distal end of chromosome 13q.

Two basement membrane collagen genes coding for the pro alpha 1 chain and pro alpha 2 chain of type IV collagen map to 13q34 and are linked with a maximum likelihood estimate of recombination of 0.028 at a logarithm of odds (lod) score of 19.98. The single-copy sequence that identifies the locus D13S3 is also closely linked to both collagen genes. Four enzymes reveal polymorphisms with COL4A1, and 10 haplotypes have been observed in Caucasoids. Within COL4A1 a nonrandom association of alleles exists only between alleles defined by Hae III and those defined by the other three enzymes. A random association of alleles of COL4A1 and COL4A2 is observed. Between the two collagen genes were detected three meiotic recombination events that contributed to the estimate of 2.8% recombination. This is higher than expected for two genes that lie within 650 kilobases of each other. The lack of linkage disequilibrium between COL4A1 and COL4A2 is in agreement with the relatively high recombination that is observed.

The genes coding for human pro alpha 1(IV) collagen and pro alpha 2(IV) collagen are both located at the end of the long arm of chromosome 13.

We have isolated and characterized a cDNA clone containing DNA sequences coding for the noncollagenous carboxy-terminal domain of human pro alpha 2(IV) collagen. Using this cDNA clone in both Southern blot analysis of DNA isolated from human-mouse somatic-cell hybrids and in situ hybridization of normal human metaphase chromosomes, we have demonstrated that the gene coding for human pro alpha 2(IV) collagen is located at 13q33----34, in the same position on chromosome 13 as the pro alpha 1(IV) collagen gene.

Genetic analysis of tumorigenesis. XXXI: Retention of short arm of chromosome 3 in suppressed CHEF cell hybrids containing c-Ha-ras (EJ) gene.

Hybrids between nontransformed Chinese hamster embryo fibroblast (CHEF) cells and their c-Ha-ras (EJ) -transformed derivatives are suppressed for tumor-forming ability when tested at early passage. Hybrid subclones with suppressed (fibroblastic) or transformed appearance have now been selected by multiple recloning. Morphology, but not serum or anchorage requirement, was a sensitive indicator of suppression: Subclones with normal morphology were nontumorigenic, subclones with transformed morphology were highly tumorigenic, and intermediate subclones (7-70% normal colonies) formed tumors with a frequency of 17-50%. Suppressed lines retained the short arm of chromosome 3, but transformed and tumor-derived lines had lost this region (greater than or equal to 1 copy). Transformed and tumor-derived cells exhibited additional chromosome changes, including the loss of at least one copy of chromosomes 7 and/or 8. These findings suggest that a tumor suppressor gene lies on the short arm of chromosome 3, consistent with prior studies from this laboratory. Other suppressor genes may be located on chromosomes 7 and 8.

Gene amplification: an example of accelerated evolution in tumorigenic cells.

During selection for methotrexate resistance, tumorigenic CHEF/16 cells and derivatives from CHEF/16 tumors underwent amplification of the dihydrofolate reductase gene (DHFR) at accelerated rates compared with closely related nontumorigenic CHEF/18 cells. "Dot blot" analysis showed that the CHEF/16 cells contained many more copies of the DHFR gene than did the CHEF/18 cells, when assayed at similar elevated levels of methotrexate resistance. Chromosome analysis of cell samples taken at several time points during amplification revealed large differences between the nontumorigenic CHEF/18 cells and the two tumorigenic cell lines. The tumorigenic cells developed few chromosome rearrangements over a 4-log increase in methotrexate resistance, other than increased length of a single chromosome, which was shown by in situ hybridization to contain most or all of the amplified DHFR gene copies. In contrast, the CHEF/18 cells underwent complex, progressive changes in almost every chromosome, and in situ hybridization suggested a dispersed pattern of gene amplification. The data support the hypothesis that unregulated amplification is a pathological process, occurring readily in neoplastic but rarely in normal cells, that together with other chromosomal disturbances contributes to the rapid evolution and progression of cancer.

Plasmid-induced "hit-and-run" tumorigenesis in Chinese hamster embryo fibroblast (CHEF) cells.

The Chinese hamster embryo fibroblast cell line CHEF/18 is readily transfected by plasmid DNA. In the present transfection studies with CHEF/18 cells, focus formation induced by plasmids containing the mutant human c-Ha-ras gene EJ was compared with that of control plasmids without the EJ insert. The focus-forming activity of the transfected plasmid J132, a recombinant of the Harvey murine sarcoma virus LTR and the normal human c-Ha-ras1 in pBR322, also was assessed. Foci were recovered after transfection with either pSV2gpt or pSV2neo at about 10% the frequency obtained with the EJ-containing plasmids, and J132 gave a similar frequency, all well above background obtained with salmon sperm DNA. Whereas foci from transfection with EJ-containing plasmids contained the EJ DNA, no plasmid DNA was detected in either tumorigenic or tumor-derived cells from foci transfected with pSVgpt, pSVneo, or J132. Evidence that genomic changes were induced by plasmid transfection is based on finding chromosomal aberrations in all expanded foci and tumor-derived cells examined. The results suggest the occurrence of "hit-and-run" tumorigenesis induced by transient plasmid transfection.

Genetic analysis of tumorigenesis: XVI. Chromosome changes in azacytidine- and insulin-induced tumorigenesis.

Chromosome changes accompanying differentiation and tumorigenesis in azacytidine- (azaC) and insulin-induced preadipocytes of the Chinese hamster embryo fibroblast cell line CHEF/18 are described. Karyotype analysis of 47 clones, subclones, and tumor-derived cells has shown that trisomy for chromosome 3q (mar 1) is characteristic of azaC preadipocytes but not of insulin preadipocytes. AzaC preadipocytes were consistently tumorigenic as well as trisomic for chromosome 3q, whereas most insulin preadipocytes were nontumorigenic and diploid. Only the few insulin preadipocytes that were tumorigenic were also trisomic for chromosome 3q. Among the tumor-derived cell lines recovered from azaC preadipocytes injected into nude mice, four had no additional chromosome changes except trisomy for 3q, as detected by karyotype analysis. Thus trisomy for 3q may be a sufficient chromosome change to induce tumor-forming ability in these cells. The rearrangements of chromosome 3 seen in this and other work pinpoint the trisomic region between the centromere and 3q5.

Azacytidine-induced tumorigenesis of CHEF/18 cells: correlated DNA methylation and chromosome changes.

5-Azacytidine (azaC), a drug that induces decreased methylation of DNA in mammalian cells, was shown previously to induce differentiation of mesenchymal cell types in CHEF/18 cells (Chinese hamster embryo fibroblasts). This paper describes the effectiveness of azaC in inducing tumorigenicity in CHEF/18 cells, previously shown to be nontumorigenic stable diploids. A short exposure of growing cells to 3 microM azaC induced tumor-forming ability in CHEF/18 stem cells. Pre-adipocyte clones and subclones derived from CHEF/18 by prior treatment with azaC were also found to be tumorigenic. Pre-adipocytes previously induced by insulin in the absence of azaC were mostly nontumorigenic, but one clone produced tumors and gave rise to both tumorigenic and nontumorigenic subclones. Karyotype analysis of 41 clones and subclones from azaC-induced and insulin-induced pre-adipocytes revealed a complete correlation between tumor-forming ability and the presence of trisomy for chromosome 3q. In addition, the tumorigenic and tumor-derived lines were demethylated at specific C-C-G-G sites in the preproinsulin, Ha-ras, and Ki-ras genes as revealed by blot hybridization to Msp I- and Hpa II-digested DNAs, whereas the nontumorigenic lines resembled the CHEF/18 controls. This three-way correlation between tumorigenicity, trisomy for 3q, and specific demethylation suggests that decreased DNA methylation may be involved both in differentiation and in tumorigenicity, and that azaC may induce chromosomal aberrations as well as altering DNA methylation.

Molecular cytogenetics of the equidae. II. purification and cytological localization of a (G + C)-rich satellite DNA from Equus hemionus onager and cross-species hybridization to E. asinus chromosomes.

A (G + C)-rich satellite DNA component (p = 1.716 g/ml) has been fractionated from the total DNA of the Iranian subspecies of the Asiatic wild ass, Equus hemionus onager, by successive dactinomycin-CsCl and netropsin sulfate-CsCl isopycnic gradients. Complementary 3H-RNA (cRNA) transcribed from the satellite DNA hybridized predominantly to the centromeric and telomeric constitutive heterochromatic regions of onager chromosomes. These studies have suggested that satellite DNA's with similar sequences are present in the centromeric, as well as telomeric, heterochromatic regions of some onager chromosomes. The centromeric region of the fusion metacentric t(23;24) of the onager is deficient in sequences homologous to the onager 1.716 g/ml satellite DNA, indicating a loss of satellite DNA during fusion or an amplification of the satellite DNA in the centromeric regions of the acrocentric chromosomes 23 and 24 subsequent to fission. Sequences complementary to onager 1.716 g/ml satellite DNA show extensive hybridization to the constitutive heterochromatin of the feral donkey (E. asinus) karyotype, consistent with a view of conservation and amplification of similar or identical sequences in the two species.

Genetic analysis of tumorigenesis: X. Chromosome studies of transformed mutants and tumor-derived CHEF/18 cells.

Chinese hamster embryo fibroblast cell line CHEF/18 is stably diploid, anchorage-dependent, has a high serum requirement, and a does not form tumors in nude mice. The chromosome constitutions of spontaneous and chemically induced anchorage-independent and/or low-serum CHEF/18 mutants and tumors produced in nude mice by some of these mutants are compared. We find a correlation between diploidy and nontumorigenicity among the anchorage-independent mutants but not in the low-serum mutants. One of the four spontaneous and six of the 15 chemically induced anchorage mutants have remained diploid. The remaining 12 mutants are pseudodiploid or aneuploid, and seven of them contain changes in chromosome 1, either a translocation or a deletion involving breakage at the same position (1q11-12). Each of the tumors induced by six mutants has a unique pattern of rearrangements; however five of the six have changes involving chromosome 3. This chromosome was also frequency rearranged in tumor-derived cells previously investigated.