Luigi De Carli

Induction and repression of alkaline phosphatase in human cultured cells by prednisolone, hydrocortisone and organic monophosphates

Abstract A series of human cell variants derived from the same strain and having greatly diverse constitutive alkaline phosphatase activity levels show a paradoxical response to prednisolone, hydrocortisone, and organic monophosphates. In those variants with very low constitutive levels of enzyme activity, alkaline phosphatase formation is induced by both classes of compounds. The same compounds repress enzyme formation in those variants with high constitutive levels.

Transfer of a Human Chromosomal Vector from a Hamster Cell Line to a Mouse Embryonic Stem Cell Line

Two transchromosomic mouse embryonic stem (ES) sublines (ESMClox1.5 and ESMClox2.1) containing a human minichromosome (MC) were established from a sample of hybrid colonies isolated in fusion experiments between a normal diploid mouse ES line and a Chinese hamster ovary line carrying the MC. DNA cytometric and chromosome analyses of ESMClox1.5 and ESMClox2.1 indicated a mouse chromosome complement with a heteroploid constitution in a subtetraploid range; the karyotypes showed various degrees of polysomy for different chromosomes. A single copy of the MC was found in the majority of cells in all the isolated hybrid colonies and was stably maintained in the established sublines for more than 100 cell generations either with or without the selective agent. No significant differences from the ES parental cells were observed in growth characteristics of the transchromosomic ES sublines. ESMClox1.5 cells were unable to grow in soft agar; when cultured in hanging drops, they formed embryoid bodies, and when inoculated in nude mice, they produced teratomas. They were able to express the early development markers Oct4 and Nanog, as demonstrated by reverse transcription‐polymerase chain reaction assay. All these features are in common with the ES parental line. Further research using the transchromosomic ES sublines described here may allow gene expression studies on transferred human minichromosomes and could shed light on the relationships among ploidy, pluripotency, cell transformation, and tumorigenesis.

Isolation from the horse genome of a new DNA transposon belonging to the Tigger family

Tigger elements are human DNA transposons homologous to the pogo element of Drosophila melanogaster. They contain an open reading frame for a transposase very similar to the major mammalian centromere protein CENP-B. We found in the horse genome a DNA element (Ecatig3) sharing 88% homology with human Tigger3. The presence of Tigger elements in the horse genome confirms previous data that date these elements before the divergence between Perissodactyla and Primates (80–90 Myr ago). Copy number evaluation indicates that the horse element is much more abundant than its human counterpart. Southern blot analysis demonstrates that Ecatig3 elements are extremely homogeneous; this may indicate that the evolution of this DNA transposon has been driven by some kind of selection and has not been neutral.

Increased number of chromosome 7 is related to overexpression of EGF receptor gene in human glioblastomas.

Karyotype and nucleic acid analyses have been performed on glioblastoma-derived primary cell lines at early passages. Four out of five cell lines displayed a significant increase in copy number of epidermal growth factor (EGF) receptor gene, which was related to polisomy of chromosome 7, where the gene is the been localized. Since EGF is a potent growth factor for human glial cells, and EGF receptor gene is the cellular homologue of the v-erb-B oncogene, we analyzed its expression in the tumor cell lines. Our results show that numerical alteration of chromosome 7 was constantly associated with overexpression of EGF receptor gene. Moreover, the high level of EGF receptor specific transcripts detected in two cell lines suggests that deregulation of the transcriptional activity of EGF receptor gene also occurred in these tumor cells.

Localization of DNA probes tightly linked to the Friedreich's ataxia locus by in situ hybridization in a case of pericentric inversion of chromosome 9

SummaryThe gene for Friedreichs ataxia (FA), an autosomal recessive neurodegenerative disorder, has been recently assigned to the long arm of chromosome 9. Linkage disequilibrium between FA and two diverse chromosome 9 markers, D9S5 and D9S15, has been detected in French, French-Canadian and Italian populations. Here, we report the physical localization of these loci by in situ hybridization of probes 26P and MCT112S identifying the D9S5 and D9S15 loci, respectively. Experiments performed on lymphocytes carrying a chromosome 9 pericentric inversion have allowed us to assign both the loci to band 9q21. Furthermore, in situ hybridization data and partial sequencing of the probe MCT112S indicate the presence of alphoid satellite DNA within this region. This suggests that MCT112S is more proximal to the centromere than 26P.

DNA fingerprint analysis for the detection of induced mutations in mammalian cells in culture.

A mutation assay in cultured mammalian cells based on the direct analysis of minisatellite DNA was developed. Band pattern variations reflect DNA alterations ranging from single base changes to complex rearrangements. By DNA fingerprinting a large number of autosomal loci throughout the human genome can be simultaneously checked, therefore minimizing the size of the samples of cell colonies to be scored in the absence of phenotypic selection. For the mutation assay chinese hamster cells (V79) were treated with Nitrosoguanidine and 14 independent colonies were isolated and expanded. DNA fingerprints were obtained after digestion of the DNA extracted from each clone with bothHinfI andHae III, and hybridisation with both 33.15 and 33.6 probes. Twelve colonies from untreated cells were also analysed. Several differences in the band pattern of treated colonies were observed when compared with untreated cells; digestion withHae III and hybridisation with 33.15 probe allowed the detection of the highest frequency of induced variants. The results suggest that minisatellite sequences are hypermutable sites that can be used to monitor the mutagenic potential of chemical agents directly at the DNA level, without phenotypic selection. Moreover, with the method herein decribed, it is possible to distinguish between true mutations and epimutations, such as those caused by changes in DNA methylation.

An improved method for chromosome banding after fluorescence in situ hybridization: Use of a tetramethylrodhamine-conjugated BrdU antibody

A method for high quality chromosome banding after in situ hybridization with biotinylated probes has been developed. Fluoresceine-conjugated avidin is used for probe detection, while chromosome banding is performed with a tetramethylrodhamine-conjugated anti-BrdU antibody. In this way probe localization and chromosome identification can be performed simultaneously simply by changing the incidental light wavelength.