ABSTRACT
A system of randomly amplified polymorphic DNA (RAPD) markers was developed to facilitate the transfer of S. bulbocastanum (blb) genes into the S. tuberosum (tbr) genome by hybridization and backcrossing. DNA from tbr, blb and the hexaploid hybrid was used as a template for polymerase chain reaction (PCR) amplification. Polymorphic RAPD products, originating from 10-mer primers, specific for blb were cloned and sequenced at their ends to allow the synthesis of 18-mer primers. The 18-mer primers allowed a more reproducible assay than the corresponding RAPDs. Of eight 18-mer primer pairs, four amplified the expected products specific for blb. However, the stringency of the primer annealing conditions needed to be carefully optimized to avoid amplification of the homeologous tbr product, suggesting that the original RAPD polymorphisms were due to single base-pair changes rather than deletions or insertions. Two primers used for amplification of backcross 2 progeny segregated in a 1â¶1 (presence:absence) ratio; the other two were unexpectedly absent. The most likely explanation for the loss of these markers is irregular meiosis in the original hexaploid hybrid and subsequent elimination of chromosomes. Cytological analysis of the meiosis in the hybrid demonstrated widespread irregular pairing and the presence of lagging univalents. In addition, the first backcross individual used as the parent for the second backcross had 54 chromosomes instead of the predicted 60. In conclusion, our results demonstrate that PCR technology can be used for the efficient isolation of taxon-specific markers in Solanum. Furthermore, by the use of these markers we detected the loss of chromosomes that was subsequently shown by cytological analysis to be caused by irregular meiosis of the somatic hybrid.
ABSTRACT
Histone H2A mRNA is selectively expressed in scattered subpopulations of cells in the pea (Pisum sativum) root apical meristem. To study whether this specific expression was associated with the cell cycle, a double-labeling technique was used to identify cells replicating DNA during S phase and those expressing H2A mRNA. Cells in S phase were detected by [3H]thymidine incorporation and autoradiography, whereas cells containing H2A mRNA were identified by in situ hybridization using digoxigenin-labeled probes. Approximately 92% of the [3H]thymidine-labeled S-phase cells expressed H2A mRNA and 85% of cells that expressed H2A mRNA were in S phase. In root tissue located basal to the promeristem, synchronous co-located expression was observed in scattered packets of proliferating cells. Furthermore, neither H2A mRNA nor S-phase cells could be detected within the quiescent center or mature root cap. When DNA synthesis was inhibited with hydroxyurea, a commensurate and specific decrease in steady-state levels of H2A mRNA was found. We conclude that cell-specific expression of pea histone H2A mRNA is replication dependent and that H2A mRNA is transiently accumulated during a period of the cell cycle that mostly overlaps the S phase. We propose that the overlap between H2A expression and S phase could occur if H2A mRNA accumulation began in late G1 and abated in late S.
ABSTRACT
Histone H2A is a component of eukaryotic chromatin whose expression has not been studied in plants. We isolated and characterized a tomato and a pea cDNA encoding histone H2A. We found that in tomato H2A is encoded by a small gene family and that both the pea and the tomato mRNAs are polyadenylated. Tomato H2A has 82% amino acid residue identity to pea H2A, 83% to wheat, and 65% to human and yeast H2A. Plant H2As differ from fungal and animal H2As in their amino-terminal and carboxy-terminal regions. Carboxy-terminal plant H2A regions contain the motif SPKK, a peptide implicated in binding of A/T-rich DNA regions. By using RNA gel blot analysis, we determined that the steady-state mRNA level of these genes was abundant in apices and early developing fruit and very low in mature tissues. In situ RNA hybridization showed strong spatial regulation because the mRNA was abundant in some cells and not detectable in others. In tomato shoot tips, H2A-expressing cells were distributed irregularly in or near meristems. In tomato or pea root tips, expressing cells were concentrated near the apex, and their distribution was consistent with that expected of cycling cells. Other H2A transcripts were found in nondividing cortical cells that are known to undergo endoduplication during the late maturation phase of primary development.
