Physical differences between organelle genomes of the interfertile species Chlamydomonas reinharodt and Chlamydomonas smithii have been used to demonstrate that sexual zygotes transmit chloroplast and mitochondrial DNA from opposite mating types. Processes responsible can be separated functionally and genetically, although both are controlled by mating type. In vegetative diploids, chloroplast and mitochondrial genomes are transmitted biparentally, but a 1-kilobase insert present in the C. smithy mitochondrial genome spreads unidirectionally to all C. reinhardti genomes in a manner reminiscent of the intron found in the mitochondrial 21S rRNA gene of wA strains of yeast.
We examined the changes in the levels of indoleacetic acid (IAA), IAA esters, and a 22-kilodalton subunit auxin-binding protein (ABP1) in apical mesocotyl tissue of maize (Zea mays L.) during continuous red light (R) irradiation. These changes were compared with the kinetics of R-induced growth inhibition in the same tissue. Upon the onset of continuous irradiation, growth decreased in a continuous manner following a brief lag period. The decrease in growth continued for 5 hours, then remained constant at 25% of the dark rate. The abundance of ABP1 and the level of free IAA both decreased in the mesocotyl. Only the kinetics of the decrease in IAA within the apical mesocotyl correlated with the initial change in growth, although growth continued to decrease even after IAA content reached its final level, 50% of the dark control. This decrease in IAA within the mesocotyl probably occurs primarily by a change in its transport within the shoot since auxin applied as a pulse moved basipetally in Rirradiated tissue at the same rate but with half the area as dark control tissue. In situ localization of auxin in etiolated maize shoots revealed that R-irradiated shoots contained less auxin in the epidermis than the dark controls. Irradiated mesocotyl grew 50% less than the dark controls even when incubated in an optimal level of auxin. However, irradiated and dark tissue contained essentially the same amount of radioactivity after incubation in [14C]IAA indicating that the light treatment does not affect the uptake into the tissue through the cut end, although it is possible that a small subset of cells within the mesocotyl is affected. These observations support the hypothesis that R causes a decrease in the level of auxin in epidermal cells of the mesocotyl, consequently constraining the growth of the entire mesocotyl.R-causes the elongation rate of the cells in the apical 1 cm of the etiolated maize mesocotyl (e.g. 16, 29) and cell
Several properties of a 43-kilodalton (kDa) auxin-binding protein (ABP) having 22-kDa subunits are shared by a class of auxin binding designated Site I. The spatial distribution of the ABP in the maize (Zea mays L.) mesocotyl corresponds with the distribution of growth induced by naphthalene-1-acetic acid and with the distribution of Site I binding as previously shown by J.D. Walton and P.M. Ray (1981, Plant Physiol. 68, 1334-1338). The greatest abundance of both ABP and Site I activity is at the apical region of the mesocotyl. The ABP and Site I activity co-migrate in isopycnic centrifugation with the endoplasmic-reticulum marker, cytochrome-c reductase. Red light, at low and high fluence, far-red and white light were used to alter the elongation rate of apical 1-cm sections of etiolated maize mesocotyls, the amount of auxin binding, and the abundance of the ABP. Relative changes in auxin binding and the ABP were correlated, but the growth rate was not always correlated with the abundance of the ABP.
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