Agrobacterium rhizogenes mediated transformation combined with a visual selection for green fluorescent protein (GFP) has been applied effectively in carrot (Daucus carota L.) transformation. Carrot root discs were inoculated with A4, A4T, LBA1334 and LBA9402 strains, all bearing gfp gene in pBIN-m-gfp5-ER. The results indicate that transformed adventitious roots can be visually selected solely based on GFP fluorescence with a very high accuracy. The method requires no selection agents like antibiotics or herbicides and enables a reduction of labour and time necessary for tissue culture. Moreover, individual transformants can be easily excised from the host tissue and cultured separately. All of the 12 used carrot cultivars produced transformed adventitious roots and the frequency of discs producing GFP expressing adventitious roots varied from 13 to 85%. The highest transformation rate was found for A4T and LBA1334 strains possessing chromosomal background of A. tumefaciens C58. The results encourage that visual selection of transformed, fluorescing adventitious roots can be highly effective and applied routinely for the production of carrot transgenic plants.
Species with holocentric chromosomes are often characterized by a rapid karyotype evolution. In contrast to species with monocentric chromosomes where acentric fragments are lost during cell division, breakage of holocentric chromosomes creates fragments with normal centromere activity. To decipher the mechanism that allows holocentric species an accelerated karyotype evolution via chromosome breakage, we analyzed the chromosome complements of irradiated Luzula elegans plants. The resulting chromosomal fragments and rearranged chromosomes revealed holocentromere-typical CENH3 and histone H2AThr120ph signals as well as the same mitotic mobility like unfragmented chromosomes. Newly synthesized telomeres at break points become detectable 3 weeks after irradiation. The presence of active telomerase suggests a telomerase-based mechanism of chromosome healing. A successful transmission of holocentric chromosome fragments across different generations was found for most offspring of irradiated plants. Hence, a combination of holokinetic centromere activity and the fast formation of new telomeres at break points enables holocentric species a rapid karyotype evolution involving chromosome fissions and rearrangements.
The centromere is the chromosome region where microtubules attach during cell division. In contrast to monocentric chromosomes with one centromere, holocentric species usually distribute hundreds of centromere units along the entire chromatid. We assembled the chromosome-scale reference genome and analyzed the holocentromere and (epi)genome organization of the lilioid Chionographis japonica. Remarkably, each of its holocentric chromatids consists of only 7 to 11 evenly spaced megabase-sized centromere-specific histone H3-positive units. These units contain satellite arrays of 23 and 28 bp-long monomers capable of forming palindromic structures. Like monocentric species, C. japonica forms clustered centromeres in chromocenters at interphase. In addition, the large-scale eu- and heterochromatin arrangement differs between C. japonica and other known holocentric species. Finally, using polymer simulations, we model the formation of prometaphase line-like holocentromeres from interphase centromere clusters. Our findings broaden the knowledge about centromere diversity, showing that holocentricity is not restricted to species with numerous and small centromere units.
Mesophyll protoplasts of Brassica oleracea var. botrytis were successfully transformed using polyethylene glycol (PEG). The success of plant transformation depended on both gene transfer and plant regeneration. Parameters, such as PEG and vector concentrations and heat shock conditions were tested in experiments on transient expression of the beta-glucuronidase (EC 3.2.1.31) gene and the most suitable conditions for DNA uptake were determined. Two antibiotic resistance marker genes for neomycin phosphotransferase (EC 2.7.1.95) and hygromycin phosphotransferase (EC 2.7.1.104), and three vector plasmids with different lengths were used to obtain stable transformants.
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