An in vivo approach has been developed for generation of artificial chromosomes, based on the induction of intrinsic, large-scale amplification mechanisms of mammalian cells. Here, we describe the ...successful generation of prototype human satellite DNA-based artificial chromosomes via amplification-dependent de novo chromosome formations induced by integration of exogenous DNA sequences into the centromeric/rDNA regions of human acrocentric chromosomes. Subclones with mitotically stable de novo chromosomes were established, which allowed the initial characterization and purification of these artificial chromosomes. Because of the low complexity of their DNA content, they may serve as a useful tool to study the structure and function of higher eukaryotic chromosomes. Human satellite DNA-based artificial chromosomes containing amplified satellite DNA, rDNA, and exogenous DNA sequences were heterochromatic, however, they provided a suitable chromosomal environment for the expression of the integrated exogenous genetic material. We demonstrate that induced de novo chromosome formation is a reproducible and effective methodology in generating artificial chromosomes from predictable sequences of different mammalian species. Satellite DNA-based artificial chromosomes formed by induced large-scale amplifications on the short arm of human acrocentric chromosomes may become safe or low risk vectors in gene therapy.
We have investigated the large-scale organization of the human chAB4-related long-range multisequence family, a low copy-number repetitive DNA located in the pericentromeric heterochromatin of ...several human chromosomes. Analysis of genomic clones revealed large-scale (∼100 kb or more) sequence conservation in the region flanking the prototype chAB4 element. We demonstrated that this low copy-number family is connected to another long-range repeat, the NF1-related (ΨNF1) multisequence. The two DNA types are joined by an ∼2 kb-long tandem repeat of a 48-bp satellite. Although the chAB4- and NF1-like sequences were known to have essentially the same chromosomal localization, their close association is reported here for the first time. It indicates that they are not two independent long-range DNA families, but are parts of a single element spanning ∼200 kb or more. This view is consistent both with their similar chromosomal localizations and the high levels of sequence conservation among copies found on different chromosomes. We suggest that the master copy of the linked chAB4–ΨNF1 DNA segment appeared first on the ancestor of human chromosome 17.
The Chinese hamster is one of the few mammalian species that are characterized by relatively poor heterochromatin content. It was intriguing to test whether or not the lack of large blocks of ...heterochromatin in the hamster chromosomes could be correlated with the absence or species-specific differences of the HP1 proteins, the main structural components of heterochromatin. To address this, we attempted to clone HP1 from the Chinese hamster. It is shown here that all three isoforms of HP1 known in mammals are present in hamster, and the amino acid sequences deduced from the cDNAs of the isoforms are 97-100% identical to those of the known mammalian homologues. All three isoforms are localized mainly in heterochromatic regions in the native chromosomes and nuclei. The hamster HP1 alpha gene was cloned, sequenced and mapped to the short arm of hamster chromosome 2. These data indicate that the Chinese hamster has all the HP1 components necessary for the establishment of heterochromatin. The limited amount of heterochromatin in hamster cells may probably be attributed to the unusual satellite DNA content of the hamster genome.
Damaged nucleotides are removed from the condensed non-coding, or transcriptionally inactive regions of the genome by the relatively slow global genome repair system. Since few data are available for ...the repair of the pericentric heterochromatin region our aim was to study the repair of a specific sequence, known to be located in this region. We applied a PCR based method to monitor UV damage and repair in chAB4, a human pericentromeric heterochromatin sequence in 10 human cell lines. We here present evidence that excision repair of a sequence in the pericentromeric heterochomatin also varies between cell lines in a manner inconsistent with the canonical model. In some cell lines repair rates were efficient in heterochromatin, comparable to transcription coupled repair, but in some tumour-derived and repair-deficient cell lines we have detected deficient repair.
We identified a P element insertional mutant of theDrosophilaglycogen phosphorylase (DGPH) gene. Glycogen phosphorylase protein concentration and enzyme activity are decreased while glycogen content ...is increased in flies homozygous for the mutant allele. TheDGPHgene has been cloned and sequenced; its open reading frame codes for a protein of 844 amino acids with a predicted molecular mass of 97 kDa. Comparison of the conceptual amino acid sequence of theDrosophilaglycogen phosphorylase with glycogen phosphorylase sequences from other organisms shows a high degree of homology to mammalian enzymes. All the residues of the allosteric effector binding sites, the active site, and the site of phosphorylation are exactly conserved, but some of the residues of the glycogen storage site are not.
We report here the isolation, cloning and characterization of two abundant centromeric satellite sequences (Rsat I and Rsat II) what are not related to each other, and that of a divergent subfamily ...(Rsat IIE) of rabbit (
Oryctolagus cuniculus). The Rsat I monomers had a 375 base pair (bp) average length, while repeat units Rsat II and Rsat IIE were ∼585 bp long. Variable amounts of Rsat I were detected by FISH at the centromeric region of 11 chromosome pairs of the complement. Rsat II hybridized to the centromere of 12 different chromosomes, and two of these were labeled also with the Rsat IIE probe. Two-color in situ hybridizations with the satellite probes and rDNA revealed that the NOR chromosomes carried different satellites. Rsat I was abundant on chromosome 20 and 21, but it was undetectable on chromosomes 13 and 16. Large Rsat II arrays were found on chromosomes 16, 20 and 21, but reduced amount was detected on chromosome 13. The variant Rsat IIE was prominent on chromosome 16, but was absent from the other rDNA-bearing chromosomes. The rDNA signal on chromosome 21 was localized to the 21q(ter) region, what can be a useful cytological marker in comparative cytological studies. These data show that rabbit chromosomes form at least four distinct groups based on the satellite composition of their centromeres. The differences in the chromosomal distribution of satellite families will help easy FISH identification of individual chromosomes, as well as to unveil the evolutionary history of the
Leporidae karyotype.
De novo Chromosome Formation in Rodent Cells PRAZNOVSZKY, T; KERESO, J; TUBAK, V ...
Proceedings of the National Academy of Sciences - PNAS,
12/1991, Letnik:
88, Številka:
24
Journal Article
Recenzirano
Odprti dostop
A hybrid cell line was produced by the fusion of an EC3/7 mouse cell with a Chinese hamster ovary cell. The EC3/7 cell carries a dicentric chromosome with a functional marker centromere. This marker ...centromere contains human, λ, and bacterial vector DNA sequences and a dominant selectable gene (aminoglycoside 3'-phosphotransferase type II; neo). In the hybrid, the marker centromere separated from the dicentric chromosome and formed a full-sized chromosome (λneo). The newly formed chromosome is stable, even under nonselective culture conditions. This functional chromosome, which is the result of an amplification process, is composed of seven large, different-sized amplicons. Each amplicon contains multiple copies of human, λ, neo, and mouse telomeric DNA sequences. Individual amplicons are separated from each other by mouse major satellite DNA sequences. The marker centromere was localized to a terminal amplicon by anticentromere immunostaining. The number of amplicons in the newly formed chromosome is remarkably consistent. This finding suggests that the length of the newly formed chromosome is highly constrained.
A protein family including the recently identified PIMT/Tgs1 (PRIP-interacting protein with methyltransferase domain/trimethylguanosine synthase) was identified by searching databases for homologues ...of a newly identified
Drosophila protein with RNA-binding activity and methyltransferase domain. Antibodies raised against a short peptide of the mammalian homologue show a 90-kDa isoform expressed specifically in rat brain and testis and a 55-kDa form expressed ubiquitously. In HeLa cells, the larger isoform of the protein is nuclear and associated with a 600-kDa complex, while the smaller isoform is mainly cytoplasmic and co-localizes to the tubulin network. Inhibition of PIMT/Tgs1 expression by siRNA in HeLa cells resulted in an increase in the percentage of cells in G2/M phases. In yeast two-hybrid and in vitro GST pull down experiments, the conserved C-terminal region of PIMT/Tgs1 interacted with the WD domain containing EED/WAIT-1 that acts as a polycomb-type repressor in the nucleus and also binds to integrins in the cytoplasm. Our experiments, together with earlier data, indicate that isoforms of the PIMT/Tgs1 protein with an RNA methyltransferase domain function both in the nucleus and in the cytoplasm and associate with both elements of the cytoskeletal network and nuclear factors known to be involved in gene regulation.
A 13,863-base-pair (bp) putative centromeric DNA fragment has been isolated from a human genomic library by using a probe obtained from metaphase chromosomes of human colon carcinoma cells. The ...abundance of this DNA was estimated to be 16-32 copies per genome. Cotransfection of mouse cells with this sequence and a selectable marker gene (aminoglycoside 3'-phosphotransferase type II, APH-II) resulted in a transformed cell line carrying an additional centromere in a dicentric chromosome. This centromere was capable of binding an anti-centromere antibody. In situ hybridization demonstrated that the human DNA sequence as well as the APH-II gene and vector DNA sequences were located only in the additional centromere of the dicentric chromosome. The extra centromere separated from the dicentric chromosome, forming a stable minichromosome. This functional centromere linked to a dominant selectable marker may be a step toward the construction of an artificial mammalian chromosome.