Abstract
We used pulsed-field gel electrophoresis and restriction fragment mapping to analyze the structure of Medicago truncatula chloroplast DNA (cpDNA). We find most cpDNA in genome-sized linear molecules, head-to-tail genomic concatemers, and complex branched forms with ends at defined sites rather than at random sites as expected from broken circles. Our data suggest that cpDNA replication is initiated predominantly on linear DNA molecules with one of five possible ends serving as putative origins of replication. We also used 4',6-diamidino-2-phenylindole staining of isolated plastids to determine the DNA content per plastid for seedlings grown in the dark for 3 d and then transferred to light before being returned to the dark. The cpDNA content in cotyledons increased after 3 h of light, decreased with 9 h of light, and decreased sharply with 24 h of light. In addition, we used real-time quantitative polymerase chain reaction to determine cpDNA levels of cotyledons in dark- and light-grown (low white, high white, blue, and red light) seedlings, as well as in cotyledons and leaves from plants grown in a greenhouse. In white, blue, and red light, cpDNA increased initially and then declined, but cpDNA declined further in white and blue light while remaining constant in red light. The initial decline in cpDNA occurred more rapidly with increased white light intensity, but the final DNA level was similar to that in less intense light. The patterns of increase and then decrease in cpDNA level during development were similar for cotyledons and leaves. We conclude that the absence in M. truncatula of the prominent inverted repeat cpDNA sequence found in most plant species does not lead to unusual properties with respect to the structure of plastid DNA molecules, cpDNA replication, or the loss of cpDNA during light-stimulated chloroplast development.
Highlights
IntroductionThe standard depiction of the chloroplast chromosome has been a genome-sized circular DNA molecule
For many years, the standard depiction of the chloroplast chromosome has been a genome-sized circular DNA molecule
Pulsed-field gel electrophoresis (PFGE) reveals several forms of M. truncatula chloroplast DNA (cpDNA) (Fig. 1A, lane 1): linear molecules at the size of the genome (124 kb) with the dimer and higher concatemers bunched together in the compression zone, a well-bound fraction that did not migrate into the gel, and a smear of linear DNA molecules less than the size of the genome
Summary
The standard depiction of the chloroplast chromosome has been a genome-sized circular DNA molecule. For most plants, such as maize (Zea mays), restriction fragment mapping shows the chloroplast genome as divided into large and small single copy regions separated by inverted repeat sequences (IRA and IRB; Heinhorst and Cannon, 1993; Kunnimalaiyaan and Nielsen, 1997a). Most of the chloroplast DNA (cpDNA) of maize seedlings as linear and branched molecules with defined ends and proposed that the inversion isomers of IRcontaining chloroplast genomes were produced during a recombination-dependent process of cpDNA replication (Oldenburg and Bendich, 2004a, 2004b) rather than the standard depiction of ‘‘flipping’’ recombination (without replication) within a circular molecule (Palmer, 1983, 1985). The rate of cpDNA degradation is dependent both on the intensity and the quality of the light
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