A New Class of Ethylene Response Mutants

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The isolation of ethylene-response mutants in Arabidopsis has led to substantial insights into the components and mechanisms of ethylene signal transduction. Most of the ethylene mutant screens to date have utilized saturating levels of ethylene or no added ethylene. In this issue, Larsen and Chang (pp. 1061-1073) announce their discovery of enhanced ethylene-response (eer) mutants, a new class of ethylene response mutants that were isolated by screening for the induction of triple-response phenotypes in the presence of subthreshold levels of ethylene. The eer1 mutation causes a profound enhancement in both the sensitivity and amplitude of response to ethylene. In dark-grown eer1 seedlings, the mutant phenotype is typified by the swelling of the lower portion of the hypocotyl.

There is no change in response in the apical hook or in the number of root hairs. The alleviation of the eer1 phenotype by ethylene synthesis inhibitors, and its suppression by the ethylene-insensitive mutant etr1-1, indicate that ethylene production and binding is necessary for the expression of the eer1 phenotype. The authors propose that the EER1 product acts to oppose ethylene responses in an organ-specific manner in the hypocotyl and stem of Arabidopsis.

	No Circadian Rhythm in Nuclear Calcium

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Endogenous biological rhythms entrained by daily changes in the light regimen are known to cause numerous circadian rhythms in the physiological processes of plants. A previous study employing transgenic tobacco plants expressing the Ca²⁺-sensitive photoprotein aequorin (Fig. 1) indicated that cytosolic free Ca²⁺ levels ([Ca²⁺]_cyt) also undergo strong circadian oscillations. Since the transcription rates of many nuclear genes are under circadian regulation, including some that are also regulated by nuclear free Ca²⁺ ([Ca²⁺]_n), it is of interest to determine whether [Ca²⁺]_n also oscillates with a circadian rhythm. By means of transgenic plants in which aequorin has been targeted to the nucleus, Wood et al. (pp. 787-796) conclude that [Ca²⁺]_n does not oscillate in a circadian manner. However, the authors do find that the [Ca²⁺]_cyt of particular cells and tissues within the same plant may oscillate with distinct differences in phase, suggesting the possibility of manifold control mechanisms.

View larger version (41K): [in this window] [in a new window]   Figure 1.   Transgenic tobacco plants expressing the photoprotein aequorin reveal the complexity of circadian rhythms in [Ca2+]cyt.

	Advances in Understanding Tracheary Differentiation

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The last stage of tracheary differentiation in Zinnia elegans culture cells involves secondary cell wall formation and programmed cell death (PCD). Previous studies have shown that uniconazole, an inhibitor of brassinosteroid synthesis, specifically inhibits the last stage of tracheary differentiation. In this issue, Yamamoto et al. (pp. 556-563) examine the questions of whether brassinosteroids actually do increase in differentiating tracheids and, if so, what types of brassinosteroids are they? Gas chromatography-mass spectrometry analysis revealed that five different species of brassinosteroids accumulate in Zinnia during differentiation and that there are marked differences in the proportions of these brassinosteroids in the culture medium versus the cells themselves. This suggests that specific brassinosteroids are selectively secreted into the medium and may function outside the cells. In a second contribution in this issue, Obara et al. (pp. 615-626) present their results of a vital staining and a confocal laser scanning microscopical study of PCD during the last stage of tracheary differentiation in Zinnia cultured cells. Their observations indicate that nuclear degeneration is complete within 20 min after the irreversible rupture of the central vacuole and consequent release of hydrolytic enzymes into the cytoplasm (Fig. 2). A loss of tonoplast semi-permeability precedes vacuolar rupture. In these aspects, PCD in differentiating tracheids is similar to the PCD that occurs during aerenchyma formation in maize roots and during senescence of unpollinated ovaries. However, the PCD of tracheids is markedly different from other types of plant cell senescence in which macromolecular digestion precedes tonoplast rupture and nuclear degeneration occurs at a very late stage. Thus, there appears to be more than one road to plant cell death.

View larger version (34K): [in this window] [in a new window]   Figure 2.   Confocal microscopy reveals the rapid degeneration of the nucleus following vacuolar rupture during tracheary differentiation in Zinnia.

	Ozone Hole Affects Plant Growth in Antarctica

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Stratospheric ozone depletion, which is especially pronounced over Antarctica, leads to increases in solar UV-B irradiation (UV-B) reaching the Earth's surface. Relatively few studies have examined the influence of solar UV-B on Antarctica biota, and the vast majority of these have focused on marine phytoplankton; increases in solar UV-B levels in Antarctica depress photosynthesis in these microorganisms, thereby reducing marine productivity. In this issue, Xiong and Day (pp. 738-751) examine the effects of natural variations in solar UV-B levels on the growth and photosynthesis of Colobanthus quitensis and Deschampsia antarctica, two vascular plants native to Antarctica. Specimens were potted and grown under filters that either absorbed or transmitted solar UV-B. Solar UV-B absorption was found to lead to an 11% to 22% decrease in biomass production and a 24% to 31% decrease in total leaf area. Surprisingly, the rates of photosynthetic gas exchange per leaf area were unaffected by UV-B irradiation. How then does one explain the decrease in biomass production? Xiong and Day observed that the leaves on plants exposed to UV-B were denser and thicker and had higher concentrations of photosynthetic and UV-B-absorbing pigments. The authors hypothesize that the development of thicker and pigment-rich leaves may allow these plants to maintain their photosynthetic rates per unit leaf area at rates comparable to those under reduced UV-B conditions. However, the additional costs associated with the construction of these modified leaves may account for the reduction in growth and biomass production that stems from UV-B exposure.

	Insect Saliva and Plant Response to Attack

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Plants respond differentially to mechanical damage as compared to herbivore damage even when the herbivore attack is carefully mimicked. For example, the feeding of the specialist lepidopteran herbivore Manduca sexta upon its natural host Nicotiana attenuata, unlike purely mechanical damage to the host, elicits a burst of jasmonic acid (JA) production. The addition of M. sexta oral secretions to mechanical damage mimics the natural attack and also elicits the JA burst. In this issue, a trilogy of papers offers the first glimpse into the large transcriptional changes that occur in N. attenuata after herbivore attack. In the first contribution, Hermsmeier et al. (pp. 683-700) report, in an analysis of only 5% of the insect-responsive transcriptome of N. attenuata, the occurrence of 27 transcripts that accumulate differentially after herbivore attack. Extrapolation of this finding indicates that the transcription of more than 500 N. attenuata genes are affected by herbivore damage. The authors estimate that about one-half of these genes may be related to plant-pathogen interactions, a not-too-surprising fact given that the mechanical damage resulting from herbivory greatly increases the susceptibility of plants to pathogen entrance. A comparison of these findings to another laboratory's research concerning the responses of Arabidopsis to attack by the herbivore Pieris napae reveals little commonality, suggesting a high degree of species specificity. More than one-half of the 27 differentially regulated transcripts were identified. Overall, transcripts involved in photosynthesis were strongly down-regulated, whereas those responding to stress, wounding, and pathogens and involved in shifting carbon and nitrogen to defense were strongly up-regulated. In the second paper, Schittko et al. (pp. 701-710) examine how a subset of the genes identified by mRNA differential display in the first paper are affected by mechanical wounding with or without the addition of regurgitant-derived cues. They report that some wound-induced transcripts are systemically down-regulated by the addition of regurgitant, whereas others are locally up-regulated. In the third contribution, Halitschke et al. (pp. 711-717) identify several fatty acid-amino acid conjugates in the regurgitants of M. sexta which, when applied to mechanical wounds at concentrations comparable to those found in regurgitant, are sufficient to activate three herbivore-specific plant defense responses (JA accumulation, changes in transcript accumulation, and volatile release). The authors propose that fatty acid-amino acid conjugates may serve as emulsifiers during insect digestion, but that plants use these compounds to "identify" and respond appropriately to the insect type that is feeding upon them.