Tünde Praznovszky

Mass isolation of plant chromosomes and nuclei

A method is presented for mass isolation of metaphase chromosomes and nuclei from plant protoplasts. The isolation procedure was developed for both monocotyledonous and dicotyledonous species using wheat (Triticum monococcum) and poppy (Papaver somniferum) cell cultures. Metaphase chromosomes were isolated from partially synchronized mitotic protoplasts, while for the isolation of nuclei unsynchronized protoplasts were used. Light and electron-microscopic studies revealed that isolated chromosomes and nuclei preserved their intact morphology. A preliminary biochemical study of chromosomal proteins was made by polyacrylamide-gel electrophoresis. Because of the purity and high quantity of isolated chromosomes and nuclei, the given isolation procedure can supply useful material for structural and biochemical studies, and for genetic manipulation.

De novo chromosome formations by large-scale amplification of the centromeric region of mouse chromosomes

Chromosomes formedde novo which originated from the centromeric region of mouse chromosome 7, have been analysed. These new chromosomes were formed by apparently similar large-scale amplification processes, and are organized into amplicons of ∼30 Mb. Centromeric satellite DNA was found to be the constant component of all amplicons. Satellite DNA sequences either bordered the large euchromatic amplicons (E-type amplification), or made up the bulk of the constitutive heterochromatic amplicons (H-type amplification). Detailed analysis of a heterochromatic megachromosome formedde novo by an H-type amplification revealed that it is composed of a tandem array of 10–12 large (∼30 Mb) amplicons each marked with integrated ‘foreign’ DNA sequences at both ends. Each amplicon is a giant palindrome, consisting of two inverted doublets of ∼7.5-Mb blocks of satellite DNA. Our results indicate that the building units of the pericentric heterochromatin of mouse chromosomes are ∼7.5-Mb blocks of satellite DNA flanked by nonsatellite sequences. We suggest that the formationde novo of various chromosome segments and chromosomes seen in different cell lines may be the result of large-scale E- and H-type amplification initiated in the pericentric region of chromosomes.

Stability of a functional murine satellite DNA-based artificial chromosome across mammalian species.

A 60-Mb murine chromosome consisting of murine pericentric satellite DNA and two bands of integrated marker and reporter genes has been generated de novo in a rodent/human hybrid cell line (mM2C1). This prototype mammalian artificial chromosome platform carries a normal centromere, and the expression of its β-galactosidase reporter gene has remained stable under selection for over 25 months. The novel chromosome was transferred by a modified microcell fusion method to mouse [L-M(TK−)], bovine (P46) and human (EJ30) cell lines. In all cases, the chromosome remained structurally and functionally intact under selection for periods exceeding 3 months from the time of transfer into the new host. In addition, the chromosome was retained in three first- generation tumours when L-M(TK−) cells containing the chromosome were xenografted in severe combined immunodeficiency mice. These data support that a murine satellite DNA-based artificial chromosome can be used as a functional mammalian artificial chromosome and can be maintained in vivo and in cells of heterologous species in vitro.

Evidence for a megareplicon covering megabases of centromeric chromosome segments.

We have analysed the replication of the heterochromatic megachromosome that was formedde novo by a large-scale amplification process initiated in the centromeric region of mouse chromosome 7. The megachromosome is organized into amplicons ∼30 Mb in size, and each amplicon consists of two large inverted repeats delimited by a primary replication initiation site. Our results suggest that these segments represent a higher order replication unit (megareplicon) of the centromeric region of mouse chromosomes. Analysis of the replication of the megareplicons indicates that the pericentric heterochromatin and the centromere of mouse chromosomes begin to replicate early, and that their replication continues through approximately three-quarters of the S-phase. We suggest that a replication-directed mechanism may account for the initiation of large-scale amplification in the centromeric regions of mouse chromosomes, and may also explain the formation of new, stable chromosome segments and chromosomes.

Structure of Isolated Protein-depleted Chromosomes of Plants

Chromosomes from poppy (Papaver somniferum L.) and wheat (Triticum monococcum L.) were obtained from cell suspension cultures using a mass isolation procedure. Protein-depleted isolated chromosomes were produced using different modes of extraction (e.g., sodium chloride, dextran sulphate-heparin) and examined by protein electrophoresis as well as light and electron microscopy. The results are discussed as they relate to the reported structure of protein-depleted animal chromosomes. With respect to the scaffold model of mitotic chromosomes we conclude that i) nonhistone proteins seem to play a fundamental role in plant chromosome architecture; ii) DNA is a structural component of protein-depleted chromosomes; iii) centromeric regions may be of structural importance for the higher order organization of chromosomes; iv) the existence of a 2M NaCl “resistant” scaffold appears not to be a common feature to both plant and animal chromosomes; v) despite the absence of a typical scaffold in plant chromosomes our results suggest that the higher order organization of plant and animal chromosomes is similar if not the same.

Centromere proteins - I. Mitosis specific centromere antigen recognized by anti-centromere autoantibodies

Human anti-centromere sera from scleroderma patients were used to detect centromere antigens of mouse fibroblast cells. An Mr=59000 centromere protein was localized exclusively on mitotic chromosomes. The association of this protein with the mitotic chromosomes proved to be DNase I sensitive. In interphase nuclei, this centromere antigen was not detectable by immunoblot techniques. The results suggest that the Mr=59000 mitosis specific protein may be necessary for the structural stability of kinetochores during mitosis.

Alignment of biological microparticles by a polarized laser beam

The optical alignment of biological samples is of great relevance to microspectrometry and to the micromanipulation of single particles. Recently, Bayoudh et al. (J. Mod. Opt. 50:1581–1590, 2003) have shown that isolated, disk-shaped chloroplasts can be aligned in a controlled manner using an in-plane-polarized Gaussian beam trap, and suggested that this is due to their nonspherical shape. Here we demonstrate that the orientation of various micrometer-sized isolated biological particles, trapped by optical tweezers, can be altered in a controlled way by changing the plane of linear polarization of the tweezers. In addition to chloroplasts, we show that subchloroplast particles of small size and irregular overall shape, aggregated photosynthetic light-harvesting protein complexes as well as chromosomes can be oriented with the linearly polarized beam of the tweezers. By using a laser scanning confocal microscope equipped with a differential polarization attachment, we also measured the birefringence of magnetically oriented granal chloroplasts, and found that they exhibit strong birefringence with large local variations, which appears to originate from stacked membranes. The size and sign of the birefringence are such that the resulting anisotropic interaction with the linearly polarized laser beam significantly contributes to the torque orienting the chloroplasts.

A combined artificial chromosome-stem cell therapy method in a model experiment aimed at the treatment of Krabbe’s disease in the Twitcher mouse

Abstract.Mammalian artificial chromosomes (MACs) are safe, stable, non-integrating genetic vectors with almost unlimited therapeutic transgene-carrying capacity. The combination of MAC and stem cell technologies offers a new strategy for stem cell-based therapy, the efficacy of which was confirmed and validated by using a mouse model of a devastating monogenic disease, galactocerebrosidase deficiency (Krabbe’s disease). Therapeutic MACs were generated by sequence-specific loading of galactocerebrosidase transgenes into a platform MAC, and stable, pluripotent mouse embryonic stem cell lines were established with these chromosomes. The transgenic stem cells were thoroughly characterized and used to produce chimeric mice on the mutant genetic background. The lifespan of these chimeras was increased twofold, verifying the feasibility of the development of MAC-stem cell systems for the delivery of therapeutic genes in stem cells to treat genetic diseases and cancers, and to produce cell types for cell replacement therapies.

Novel method to load multiple genes onto a mammalian artificial chromosome.

Mammalian artificial chromosomes are natural chromosome-based vectors that may carry a vast amount of genetic material in terms of both size and number. They are reasonably stable and segregate well in both mitosis and meiosis. A platform artificial chromosome expression system (ACEs) was earlier described with multiple loading sites for a modified lambda-integrase enzyme. It has been shown that this ACEs is suitable for high-level industrial protein production and the treatment of a mouse model for a devastating human disorder, Krabbe’s disease. ACEs-treated mutant mice carrying a therapeutic gene lived more than four times longer than untreated counterparts. This novel gene therapy method is called combined mammalian artificial chromosome-stem cell therapy. At present, this method suffers from the limitation that a new selection marker gene should be present for each therapeutic gene loaded onto the ACEs. Complex diseases require the cooperative action of several genes for treatment, but only a limited number of selection marker genes are available and there is also a risk of serious side-effects caused by the unwanted expression of these marker genes in mammalian cells, organs and organisms. We describe here a novel method to load multiple genes onto the ACEs by using only two selectable marker genes. These markers may be removed from the ACEs before therapeutic application. This novel technology could revolutionize gene therapeutic applications targeting the treatment of complex disorders and cancers. It could also speed up cell therapy by allowing researchers to engineer a chromosome with a predetermined set of genetic factors to differentiate adult stem cells, embryonic stem cells and induced pluripotent stem (iPS) cells into cell types of therapeutic value. It is also a suitable tool for the investigation of complex biochemical pathways in basic science by producing an ACEs with several genes from a signal transduction pathway of interest.

The chAB4 and NF1-related long-range multisequence DNA families are contiguous in the centromeric heterochromatin of several human chromosomes

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 ( approximately 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 (PsiNF1) multisequence. The two DNA types are joined by an approximately 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 approximately 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-PsiNF1 DNA segment appeared first on the ancestor of human chromosome 17.