Chromosomal variation in dividing protoplasts derived from cell suspensions of barley (Hordeum vulgare L.)

An evolutionary view of plant tissue culture: somaclonal variation and selection

Plants regenerated from in vitro cultures possess an array of genetic and epigenetic changes. This phenomenon is known as 'somaclonal variation' and the frequency of somaclonal variation (SV) is usually elevated far beyond that expected in nature. Initially, the relationship between time in culture and detected SV was found to support the widespread belief that SV accumulates with culture age. However, a few studies indicated that older cultures yielded regenerants with less SV. What leads to this seemed contradiction? In this article, we have proposed a novel in vitro callus selection hypothesis, differentiation bottleneck (D-bottleneck) and dedifferentiation bottleneck (Dd-bottleneck), which consider natural selection theory to be fit for cell population in vitro. The results of multiplication races between the cells with the true-to-type phenotype and the deleterious cells determine the increase/decrease of SV frequencies in calli or regenerants as in vitro culture time goes on. The possibility of interpreting the complex situation of time-related SV by the evolutionary theory is discussed in this paper. In addition, the SV threshold, space-determined hypothesis and D-bottleneck are proposed to interpret the loss of the regenerability through a long period of plant tissue culture (PTC).

Primary callus as source of totipotent barley (Hordeum vulgare L.) protoplasts

Primary callus of barley (Hordeum vulgare L.) derived from scutella (cv. 'Dissa') and anthers (cv. 'Igri') was used for protoplast isolation and plant regeneration. The protoplasts were embedded in agarose and cultured with nurse cells. The plating efficiency varied from 0.1% to 0.7%. Shoots regenerated from the developing callus. Plantlets were transferred to soil and cultivated in the greenhouse three to five months after protoplast isolation. All plants were normal in morphology, and most of them flowered and set seeds.

Structural changes in the plastid DNA of rice (Oryza sativa L.) during tissue culture

To investigate the rearrangement of the plastid genome during tissue culture, DNA from rice callus lines, which had been derived individually from single protoplasts isolated from seed or pollen callus (protoclones), was analyzed by Southern hybridization with rice chloroplast DNA (ctDNA) clones as probes. Among 44 long-term cultured protoclones, maintained for 4, 8 or 11 years, 28 contained plastid DNA (ptDNA) from which portions had been deleted. The ptDNA of all protoclones that had been maintained for 11 years had a deletion that covered a large region of the plastid genome. The deletions could be classified into 15 types from their respective sizes and positions. By contrast, no deletions were found in the ptDNA of 38 protoclones that had been maintained for only 1 month. These results indicate that long-term culture causes deletions in the plastid genome. Detailed hybridization experiments revealed that plastid genomes with deletions in several protoclones were organized as head-to-head or tail-to-tail structures. Furthermore, ptDNAs retained during long-term culture all had a common terminus at one end, where extensive rearrangement is known to have occurred during the speciation of rice and tobacco. Morphological analysis revealed the accumulation of starch granules in plastids and amyloplasts in protoclones in which the plastid genome had undergone deletion. Our observations indicated that novel structural changes in the plastid genome and morphological changes in the plastid had occurred in rice cells during long-term tissue culture. Moreover, the morphological changes in plastids were associated with deletions in the plastid genome.

Genome analysis of the moss Physcomitrella patens (Hedw.) B.S.G

A wild-type (WT) strain of the moss Physcomitrella patens (Hedw.) B.S.G., two mutants derived from it (PC22 and P24), and a somatic hybrid, PC22(+)P24, were analysed. Staining of metaphases revealed 54 +/- 2 chromosomes in the somatic hybrid and 27 chromosomes in the wild type and the two mutants. Using flow cytometry (FCM), DNA contents were calculated to be 0.6 pg (WT, PC22), 1.2 pg (P24), and 1.6 pg (PC22(+)P24) per nucleus, respectively. Southern hybridization provided evidence for at least one family of highly repetitive DNA and, furthermore, revealed different amounts of repetitive DNA in the four genotypes. However, these sequences cannot account for the 100% increase in the nuclear DNA amount in mutant P24, relative to wild type. In FCM analyses every moss genotype generated just one single peak of fluorescence, indicating an arrest in the cell cycle during the daytime. Thermal denaturation of wild-type DNA revealed a G+C content of 34.6% for total DNA and 38.6% for plastid DNA. A cDNA library of 1.2 x 10(6) independent clones was established, from which sequences homologous to cab and rbcS, respectively, were isolated. These genes show significant homologies to those of higher plants, and, likewise, comprise multigene families. No restriction fragment length polymorphisms could be detected between the four moss genotypes using these cDNA probes.