The barley chloroplast mutator (cpm) is an allele of a nuclear gene that when homozygous induces several types of cytoplasmically inherited chlorophyll deficiencies. In this work, a plastome Targeting Induced Local Lesions in Genomes (TILLING) strategy based on mismatch digestion was used on families that carried the cpm genotype through many generations. Extensive scanning of 33 plastome genes and a few intergenic regions was conducted. Numerous polymorphisms were detected on both genic and intergenic regions. The detected polymorphisms can be accounted for by at least 61 independent mutational events. The vast majority of the polymorphisms originated in substitutions and small indels (insertions/deletions) in microsatellites. The rpl23 and the rps16 genes were the most polymorphic. Interestingly, the variation observed in the rpl23 gene consisted of several combinations of 5 different one nucleotide polymorphisms. Besides, 4 large indels that have direct repeats at both ends were also observed, which appear to be originated from recombinational events. The cpm mutation spectrum suggests that the CPM gene product is probably involved in plastome mismatch repair. The numerous subtle molecular changes that were localized in a wide range of plastome sites show the cpm as a valuable source of plastome variability for plant research and/or plant breeding. Moreover, the cpm mutant appears to be an interesting experimental material for investigating the mechanisms responsible for maintaining the stability of plant organelle DNA.
We have established two transgenic cell suspension culture lines of Nicotiana tabacum that express the catalytic antibody 14D9 as a secretory product (sec-Ab) or as a KDEL-tagged product in the endoplasmic reticulum (Ab-KDEL), respectively. After 3 years of culture, the performance improved to a production level of 0.15 ± 0.03 lg ml -1 on the seventh day of culture for the sec-Ab line and 0.48 ± 0.05 lg ml -1 on the third day for Ab-KDEL line. Analysis of the effect of osmotic stress using mannitol (90 g l -1 ) as an osmolite revealed that there was a 12-fold increase in antibody yield (1.96 ± 0.20 lg ml -1 ) on the seventh day of culture in line sec-Ab and a fivefold increase (2.31 ± 0.18 lg ml -1 ) on the seventh day for line Ab-KDEL. The concentration of the antibody in the culture medium was not significant. Dimethyl sulfoxide used as a permeabilizing agent was not effective in increasing 14D9 yield, but it did cause distinctive cell damage at all concentrations tested.
Previously, through a TILLING (Targeting Induced Local Lesions in Genomes) approach applied on barley chloroplast mutator ( cpm ) seedlings a high frequency of polymorphisms in the rpl23 gene was detected. All the polymorphisms corresponded to five differences already known to exist in nature between the rpl23 gene located in the inverted repeats (IRs) and the rpl23 pseudogene located in the large single copy region (LSC). In this investigation, polymorphisms in the rpl23 gene were verified and besides, a similar situation was found for the pseudogene in cpm seedlings. On the other hand, no polymorphisms were found in any of those loci in 40 wild type barley seedlings. Those facts and the independent occurrence of polymorphisms in the gene and pseudogene in individual seedlings suggest that the detected polymorphisms initially arose from gene conversion between gene and pseudogene. Moreover, an additional recombination process involving small recombinant segments seems to occur between the two gene copies as a consequence of their location in the IRs. These and previous results support the hypothesis that the CPM protein is a component of the plastome mismatch repair (MMR) system, whose failure of the anti-recombination activity results in increased illegitimate recombination between the rpl23 gene and pseudogene.
In a previous work, a polymorphism detection strategy based on mismatch digestion was applied to the chloroplast genome of barley seedlings that carried the chloroplast mutator (cpm) genotype through many generations. Sixty-two different one- or two-nucleotide- polymorphisms were detected along with four large indels: an insertion of 15 bp in the intergenic region between tRNAHis and rps19 genes, a deletion of 620 bp in the psbA gene, a deletion of 79 bp in the intergenic region between rpl33 and rps18 genes and a deletion of 45 bp in the rps3 gene. In the present investigation, we analyzed direct repeats located at the borders of those four large indels. Furthermore, we investigated the consequences of protein expression of large indels located in coding regions. The deletion of 620 bp in the psbA gene was lethal at the second leaf stage when homoplastomic. The deletion of 45 bp in the rps3 gene, which eliminates 15 amino acids, did not affect the viability of the seedlings in homoplastomy. Interestingly, the deleted segment is also lacking in the wild type version of the rps3 gene of maize and sorghum. The presence of direct repeats at the borders of the four large indels suggests that they could have originated by illegitimate recombination. This would be in agreement with a previous hypothesis that the Cpm gene product would correspond to a mismatch repair (MMR) protein devoted to maintain plastome stability by playing fundamental roles in mismatch repair during replication and avoiding illegitimate recombination.
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