Volatiles produced by soil-borne endophytic bacteria increase plant pathogen resistance and affect tritrophic interactions

Volatile organic compounds (VOCs) released by soil microorganisms influence plant growth and pathogen resistance. Yet, very little is known about their influence on herbivores and higher trophic levels. We studied the origin and role of a major bacterial VOC, 2,3-butanediol (2,3-BD), on plant growth, pathogen and herbivore resistance, and the attraction of natural enemies in maize. One of the major contributors to 2,3-BD in the headspace of soil-grown maize seedlings was identified as Enterobacter aerogenes, an endophytic bacterium that colonizes the plants. The production of 2,3-BD by E. aerogenes rendered maize plants more resistant against the Northern corn leaf blight fungus Setosphaeria turcica. On the contrary, E. aerogenes-inoculated plants were less resistant against the caterpillar Spodoptera littoralis. The effect of 2,3-BD on the attraction of the parasitoid Cotesia marginiventris was more variable: 2,3-BD application to the headspace of the plants had no effect on the parasitoids, but application to the soil increased parasitoid attraction. Furthermore, inoculation of seeds with E. aerogenes decreased plant attractiveness, whereas inoculation of soil with a total extract of soil microbes increased parasitoid attraction, suggesting that the effect of 2,3-BD on the parasitoid is indirect and depends on the composition of the microbial community.

Carbon-11 Reveals Opposing Roles of Auxin and Salicylic Acid in Regulating Leaf Physiology, Leaf Metabolism, and Resource Allocation Patterns that Impact Root Growth in Zea mays

Auxin (IAA) is an important regulator of plant development and root differentiation. Although recent studies indicate that salicylic acid (SA) may also be important in this context by interfering with IAA signaling, comparatively little is known about its impact on the plant’s physiology, metabolism, and growth characteristics. Using carbon-11, a short-lived radioisotope (t 1/2 = 20.4 min) administered as 11CO2 to maize plants (B73), we measured changes in these functions using SA and IAA treatments. IAA application decreased total root biomass, though it increased lateral root growth at the expense of primary root elongation. IAA-mediated inhibition of root growth was correlated with decreased 11CO2 fixation, photosystem II (PSII) efficiency, and total leaf carbon export of 11C-photoassimilates and their allocation belowground. Furthermore, IAA application increased leaf starch content. On the other hand, SA application increased total root biomass, 11CO2 fixation, PSII efficiency, and leaf carbon export of 11C-photoassimilates, but it decreased leaf starch content. IAA and SA induction patterns were also examined after root-herbivore attack by Diabrotica virgifera to place possible hormone crosstalk into a realistic environmental context. We found that 4 days after infestation, IAA was induced in the midzone and root tip, whereas SA was induced only in the upper proximal zone of damaged roots. We conclude that antagonistic crosstalk exists between IAA and SA which can affect the development of maize plants, particularly through alteration of the root system’s architecture, and we propose that the integration of both signals may shape the plant’s response to environmental stress.

A Nicotiana attenuata cell wall invertase inhibitor (NaCWII) reduces growth and increases secondary metabolite biosynthesis in herbivore-attacked plants

Plant invertases are sucrolytic enzymes that are essential for the regulation of carbohydrate metabolism and source–sink relationships. While their activity has been well documented during abiotic and biotic stresses, the role of proteinaceous invertase inhibitors in regulating these changes is unknown. Here, we identify a putative Nicotiana attenuata cell wall invertase inhibitor (NaCWII) which is strongly up-regulated in a jasmonate (JA)-dependent manner following simulated attack by the specialist herbivore Manduca sexta. To understand the role of NaCWII in planta, we silenced its expression by RNA interference and measured changes in primary and secondary metabolism and plant growth following simulated herbivory. NaCWII-silenced plants displayed a stronger depletion of carbohydrates and a reduced capacity to increase secondary metabolite pools relative to their empty vector control counterparts. This coincided with the attenuation of herbivore-induced CWI inhibition and growth suppression characteristic of wild-type plants. Together our findings suggest that NaCWII may act as a regulatory switch located downstream of JA accumulation which fine-tunes the plant's balance between growth and defense metabolism under herbivore attack. Although carbohydrates are not typically viewed as key factors in plant growth and defense, our study shows that interfering with their catabolism strongly influences plant responses to herbivory.

Eficiencia de control de "orugas defoliadoras" en soja (Glycine max L.), con insecticidas neurotóxicos y reguladores del crecimiento de los insectos

Las "orugas defoliadoras" afectan la producción del cultivo de soja, sobre todo en años secos y con altas temperaturas que favorecen su desarrollo. El objetivo del presente trabajo fue evaluar la eficiencia de control de insecticidas neurotóxicos e IGRs sobre "orugas defoliadoras" en soja. Se realizaron ensayos en lotes comerciales en tres localidades de la provincia de Córdoba en las campañas agrícolas 2008/09 y 2009/10, bajo un diseño de bloques al azar, con seis tratamientos y tres repeticiones. Los tratamientos fueron: T1: Clorpirifos (384 g p.a.ha-1), T2: Cipermetrina (37,5 g p.a.ha-1), T3: Lufenuron+Profenofos (15 + 150 g p.a.ha-1), T4: Metoxifenocide (28,8 g p.a.ha-1), T5: Novaluron (10 g p.a.ha-1) y T6: Testigo. El tamaño de las parcelas fue de 12 surcos de 10 m de largo distanciados a 0,52 m. La aplicación se realizó con una mochila provista de boquillas de cono hueco (40 gotas.cm-2), cuando la plaga alcanzó el umbral de daño económico. En cada parcela se tomaron cinco muestras a los 0, 2, 7 y 14 días después de la aplicación (DDA) utilizando el paño vertical, identificando y cuantificando las orugas vivas mayores a 1,5 cm. A los 14 DDA se extrajeron 30 folíolos por parcela (estrato medio y superior de la planta) y se determinó el porcentaje de defoliación utilizando el software WinFolia Reg. 2004. Se estimó el rendimiento sobre 5 muestras de 1 m2 en cada parcela y se realizó ANOVA y test de comparación de medias LSD de Fisher. El Clorpirifos mostró el mayor poder de volteo y el Metoxifenocide la mayor eficiencia a los 7 DDA. En general los IGRs mostraron mayor poder residual.

The relevance of seed size in modulating leaf physiology and early plant performance in two tree species

he size of seeds and the microsite of seed dispersal may affect the early establishment of seedlings through different physiological processes. Here, we examined the effects of seed size and light availability on seedling growth and survival, and whether such effects were mediated by water use efficiency. Acorns of Quercus petraea and the more drought-tolerant Quercus pyrenaica were sowed within and around a tree canopy gap in a sub-Mediterranean forest stand. We monitored seedling emergence and measured predawn leaf water potential (Ψpd), leaf nitrogen per unit area (Na), leaf mass per area, leaf carbon isotope composition (δ13C) and plant growth at the end of the first summer. Survival was measured on the next year. Path analysis revealed a consistent pattern in both species of higher δ13C as Ψpd decreased and higher δ13C as seedlings emerged later in the season, indicating an increase in 13C as the growing season is shorter and drier. There was a direct positive effect of seed size on δ13C in Q. petraea that was absent in Q. pyrenaica. Leaf δ13C had no effect on growth but the probability of surviving until the second year was higher for those seedlings of Q. pyrenaica that had lower δ13C on the first year. In conclusion, leaf δ13C is affected by seed size, seedling emergence time and the availability of light and water, however, leaf δ13C is irrelevant for first year growth, which is directly dependent on the amount of seed reserves.

Growth dynamics and yield of melon as influenced by nitrogen fertilizer

Nitrogen (N) is an important nutrient for melon (Cucumis melo L.) production. However there is scanty information about the amount necessary to maintain an appropriate balance between growth and yield. Melon vegetative organs must develop sufficiently to intercept light and accumulate water and nutrients but it is also important to obtain a large reproductive-vegetative dry weight ratio to maximize the fruit yield. We evaluated the influence of different N amounts on the growth, production of dry matter and fruit yield of a melon ‘Piel de sapo’ type. A three-year field experiment was carried out from May to September. Melons were subjected to an irrigation depth of 100% crop evapotranspiration and to 11 N fertilization rates, ranging 11 to 393 kg ha –1 in the three years. The dry matter production of leaves and stems increased as the N amount increased. The dry matter of the whole plant was affected similarly, while the fruit dry matter decreased as the N amount was increased above 112, 93 and 95 kg ha –1 , in 2005, 2006 and 2007, respectively. The maximum Leaf Area Index (LAI), 3.1, was obtained at 393 kg ha –1 of N. The lowest N supply reduced the fruit yield by 21%, while the highest increased the vegetative growth, LAI and Leaf Area Duration (LAD), but reduced yield by 24% relative to the N93 treatment. Excessive applications of N increase vegetative growth at the expense of reproductive growth. For this melon type, rates about 90-100 kg ha –1 of N are sufficient for adequate plant growth, development and maximum production. To obtain fruit yield close to the maximum, the leaf N concentration at the end of the crop cycle should be higher than 19.5 g kg –1

Determination of the uptake and translocation of nitrogen applied at different growth stages of a melon crop (Cucumis melo L.) using 15N isotope.

In order to establish a rational nitrogen (N) fertilisation and reduce groundwater contamination, a clearer understanding of the N distribution through the growing season and its dynamics inside the plant is crucial. In two successive years, a melon crop (Cucumis melo L. cv. Sancho) was grown under field conditions to determine the uptake of N fertiliser, applied by means of fertigation at different stages of plant growth, and to follow the translocation of N in the plant using 15N-labelled N. In 2006, two experiments were carried out. In the first experiment, labelled 15N fertiliser was supplied at the female-bloom stage and in the second, at the end of fruit ripening. Labelled 15N fertiliser was made from 15NH415NO3 (10 at.% 15N) and 9.6 kg N ha−1 were applied in each experiment over 6 days (1.6 kg N ha−1 d−1). In 2007, the 15N treatment consisted of applying 20.4 kg N ha−1 as 15NH415NO3 (10 at.% 15N) in the middle of fruit growth, over 6 days (3.4 kg N ha−1 d−1). In addition, 93 and 95 kg N ha−1 were supplied daily by fertigation as ammonium nitrate in 2006 and 2007, respectively. The results obtained in 2006 suggest that the uptake of N derived from labelled fertiliser by the above-ground parts of the plants was not affected by the time of fertiliser application. At the female-flowering and fruit-ripening stages, the N content derived from 15N-labelled fertiliser was close to 0.435 g m−2 (about 45% of the N applied), while in the middle of fruit growth it was 1.45 g m−2 (71% of the N applied). The N application time affected the amount of N derived from labelled fertiliser that was translocated to the fruits. When the N was supplied later, the N translocation was lower, ranging between 54% at female flowering and 32% at the end of fruit ripening. Approximately 85% of the N translocated came from the leaf when the N was applied at female flowering or in the middle of fruit growth. This value decreased to 72% when the 15N application was at the end of fruit ripening. The ammonium nitrate became available to the plant between 2 and 2.5 weeks after its application. Although the leaf N uptake varied during the crop cycle, the N absorption rate in the whole plant was linear, suggesting that the melon crop could be fertilised with constant daily N amounts until 2–3 weeks before the last harvest.

Characterization of tomato Cycling Dof Factors reveals conserved and new functions in the control of flowering time and abiotic stress responses.

DNA binding with One Finger (DOF) transcription factors are involved in multiple aspects of plant growth and development but their precise roles in abiotic stress tolerance are largely unknown. Here we report a group of five tomato DOF genes, homologous to Arabidopsis Cycling DOF Factors (CDFs), that function as transcriptional regulators involved in responses to drought and salt stress and flowering-time control in a gene-specific manner. SlCDF1?5 are nuclear proteins that display specific binding with different affinities to canonical DNA target sequences and present diverse transcriptional activation capacities in vivo. SlCDF1?5 genes exhibited distinct diurnal expression patterns and were differentially induced in response to osmotic, salt, heat, and low-temperature stresses. Arabidopsis plants overexpressing SlCDF1 or SlCDF3 showed increased drought and salt tolerance. In addition, the expression of various stress-responsive genes, such as COR15, RD29A, and RD10, were differentially activated in the overexpressing lines. Interestingly, overexpression in Arabidopsis of SlCDF3 but not SlCDF1 promotes late flowering through modulation of the expression of flowering control genes such as CO and FT. Overall, our data connect SlCDFs to undescribed functions related to abiotic stress tolerance and flowering time through the regulation of specific target genes and an increase in particular metabolites

Characterization of four bifunctional plant IAM/PAM-amidohydrolases capable of contributing to auxin biosynthesis.

Amidases [EC 3.5.1.4] capable of converting indole-3-acetamide (IAM) into the major plant growth hormone indole-3-acetic acid (IAA) are assumed to be involved in auxin de novo biosynthesis. With the emerging amount of genomics data, it was possible to identify over forty proteins with substantial homology to the already characterized amidases from Arabidopsis and tobacco. The observed high conservation of amidase-like proteins throughout the plant kingdom may suggest an important role of theses enzymes in plant development. Here, we report cloning and functional analysis of four, thus far, uncharacterized plant amidases from Oryza sativa, Sorghum bicolor, Medicago truncatula, and Populus trichocarpa. Intriguingly, we were able to demonstrate that the examined amidases are also capable of converting phenyl-2-acetamide (PAM) into phenyl-2-acetic acid (PAA), an auxin endogenous to several plant species including Arabidopsis. Furthermore, we compared the subcellular localization of the enzymes to that of Arabidopsis AMI1, providing further evidence for similar enzymatic functions. Our results point to the presence of a presumably conserved pathway of auxin biosynthesis via IAM, as amidases, both of monocot, and dicot origins, were analyzed.

Variability of Arundo donax growth in dry-farming as a function of soil properties

Arundo donax L., commonly known as giant reed or arundo, is a perennial rhizomatous grass that has been studied since the decade of 1980 for bioenergy. In the Mediterranean region -characterised by dry and hot summers- arundo is usually grown with the support of irrigation. However, there is evidence that this plant species can tolerate dry-farming conditions once the crop is fully established. In this work the variation observed in plant growth of a 5-year-old arundo crop when the management changed from irrigated to dry-farming, is assessed. The hypothesis underlying this work was that punctual variations of soil properties might be responsible for the differences observed in plant growth

Estudio de la estabilidad genética asociada a los procesos de crioconservación de ápices de menta

La crioconservación se ha descrito como una técnica de conservación ex situ a largo plazo que ha sido aplicada con éxito a numerosas especies, y resulta especialmente importante en aquellas con propagación vegetativa, infértiles o amenazadas, en las que sistemas de conservación ex situ más sencillos, como los bancos de semillas, no son posibles. También presenta ventajas frente a la conservación in vitro, ya que logra disminuir o eliminar problemas como la excesiva manipulación del material, evitando los subcultivos periódicos y disminuyendo así el riesgo de contaminaciones y de aparición de variación somaclonal. Sin embargo, someter al material vegetal a los procedimientos que implica la crioconservación provoca distintos estreses. Entre ellos, el estrés oxidativo puede potencialmente producir daños en membranas, proteínas, carbohidratos y en el ADN. En este trabajo se han evaluado diversos sistemas de crioconservación en ápices de Mentha × piperita L., híbrido estéril entre Mentha aquatica L. y Mentha spicata L. Se han utilizado ápices de dos genotipos (‘MEN 186’y ‘MEN 198’) en los cuales se compararon dos técnicas de crioconservación, encapsulación-deshidratación y vitrificación-droplet. El análisis de la supervivencia y capacidad de regeneración del material sometido a los tratamientos de crioconservación, junto con el análisis de la estabilidad genética de dicho material mediante marcadores moleculares (RAPD y AFLP) han permitido comparar los distintos protocolos y tratamientos establecidos. El estudio sobre el tipo de protocolo empleado reveló una mayor variabilidad genética en la técnica de encapsulación-deshidratación, especialmente en el genotipo ‘MEN 186’, ya que ‘MEN 198’ resultó ser más estable en todos los análisis. La inestabilidad encontrada en esta técnica no fue exclusiva de aquellos explantos crioconservados, sino que los pasos previos a la inmersión en nitrógeno líquido (NL) también provocaron variaciones en el ADN. Según el tipo de muestra analizada se encontraron diferencias en la estabilidad: muestras provenientes de callos presentaron una mayor inestabilidad que aquellas de hojas (brotes). Se utilizaron tres medios para la recuperación de los ápices tras la crioconservación con el uso de diferentes combinaciones de reguladores de crecimiento: “Reed” (0,5 mgL-1 6-bencilaminopurina, BAP), “Senula” (0,5 mgL-1 6-dimetilalilamino-purina, 2-iP + 0,1 mgL-1 ácido α-naftalen-acético, ANA) y “Nudos” (0,5 mgL-1 BAP + 0,1 mgL-1ANA). El medio “Reed” produjo un aumento en la supervivencia y recuperación de los ápices en ambos genotipos y técnicas, y disminuyó la formación de callo. Sin embargo, no tuvo un efecto significativo en la estabilidad genética. El medio “Senula” provocó una mayor estabilidad genética en el genotipo más inestable, ‘MEN 186’. Para reducir el daño oxidativo producido durante la encapsulación-deshidratación, e incrementar la recuperación de los ápices manteniendo su estabilidad genética, se comparó el efecto de añadir sustancias antioxidantes en el precultivo de los ápices (ácido ascórbico, vitamina E y glutatión). No se obtuvo la respuesta esperada y estos tratamientos no presentaron efectos significativos tanto en la estabilidad como en la recuperación. Para entender mejor qué sucede durante todo el proceso de encapsulación-deshidratación, se evaluó cada paso del protocolo por separado y su efecto en la estabilidad y la recuperación. Además, se determinó el estado de oxidación en cada etapa mediante la cuantificación de malondialdehído y la detección de la formación de radicales libres (mediante el ensayo del ácido tiobarbitúrico, y sondas fluorescentes específicas, respectivamente). Se determinó que a partir de los primeros pasos se genera estrés oxidativo, el cual aumenta a medida que se avanza por el protocolo hasta la inmersión en nitrógeno líquido. Esto se ve reflejado en la disminución progresiva tanto de la recuperación como de la estabilidad genética. Con el uso de antioxidantes en el precultivo (ácido ascórbico y vitamina E) no se obtuvo un efecto positivo en el mantenimiento de la estabilidad genética, y tan sólo con el uso de vitamina E se observó una recuperación mayor en uno de los pasos estudiados (después de la desecación). Sin embargo, cuando se utilizó ácido ascórbico durante el precultivo o la deshidratación osmótica se consiguió disminuir de forma significativa la formación de MDA y la acumulación del radical superóxido (O2•-) en la mayoría los pasos analizados, aunque esta reducción no parece tener un efecto directo en la estabilidad genética del material recuperado. ABSTRACT Cryopreservation has been described as an effective technique for the long term of ex situ conservation that has been successfully applied to numerous species, and is of especial relevance for those with vegetative propagation, infertile or endangered, in which simpler systems of ex situ conservation, such as seed banking, are not feasible. It also has advantages over in vitro conservation, as it reduces or eliminates excessive material handling, avoids periodic subcultures and thus limits the risk of contamination and the appearance of somaclonal variation. However, plant material is subjected to different treatments involved in the cryopreservation procedures, which impose several stresses. Among them, oxidative stress can potentially cause damage to membranes, proteins, carbohydrates and DNA. In this work, two cryopreservation techniques have been evaluated in Mentha × piperita L. shoot tips, sterile hybrid between Mentha aquatica L. and Mentha spicata L. Two genotypes ('MEN 186' and 'MEN 198') were used to compare two techniques: encapsulation-dehydration and droplet-vitrification. The analysis of survival and recovery capacity of the material after the cryopreservation treatments, and the analysis of the genetic stability by molecular markers (RAPD and AFLP) have enabled the comparison between protocols and treatments. The study of the two cryopreservation procedures revealed a higher genetic variability in the encapsulation-dehydration technique, especially in genotype 'MEN 186', as 'MEN 198' was more stable in all analyses. The instability generated in this technique was not exclusive of cryopreserved explants, pretreatments prior to immersion in NL also caused DNA variations. The type of sampled plant material revealed also differences in the stability: callus samples showed greater instability than shoots. Three different culture media were used for the recovery of shoot tips after cryopreservation, using different combinations of growth regulators: "Reed" (0.5 mgL-1 6-benzylaminopurine, BAP), "Senula" (0.5 mgL-1 6-dimetilalilamino-purine, 2-iP + 0.1 mgL-1 α-naphthalene acetic acid, ANA) and "Nodes" (0.5 mgL-1 BAP + 0.1 mgL-1 ANA). "Reed" medium increased survival and recovery of shoot tips in both genotypes and techniques and decreased callus formation. However, it didn`t have a significant effect on genetic stability. "Senula" medium caused a higher genetic stability in the most unstable genotype, 'MEN 186'. To reduce oxidative damage during encapsulation-dehydration, and increase shoot tip recovery and maintain genetic stability, the effect of added antioxidants (ascorbic acid, vitamin E and glutathione) in the shoot tip preculture medium was studied. These treatments had no significant effect on both stability and recovery. To better understand the events during the encapsulation-dehydration process, the effect of each step of the protocol on stability and recovery was evaluated separately. Moreover, the oxidation level was determined by quantifying malondialdehyde (MDA) formation and detecting free radical accumulation (using the thiobarbituric acid assay, and specific fluorescent probes, respectively). The oxidative stress was detected from the first steps and increased throughout the protocol until the immersion in liquid nitrogen. This was also reflected in the gradual decline of recovery and genetic stability. The use of antioxidants (ascorbic acid and vitamin E) in the shoot tip preculture medium had no effect in maintaining genetic stability; only vitamin E increased recovery in one of the steps studied (after desiccation). However, when ascorbic acid was used during the preculture or during the osmotic dehydration, a significantly decrease was observed in MDA formation and superoxide radical accumulation in most of the steps analyzed, although this reduction did not seem to have a direct effect on the genetic stability of recovered material.

Identification of lumichrome as a Sinorhizobium enhancer of alfalfa root respiration and shoot growth

Sinorhizobium meliloti bacteria produce a signal molecule that enhances root respiration in alfalfa (Medicago sativa L.) and also triggers a compensatory increase in whole-plant net carbon assimilation. Nuclear magnetic resonance, mass spectrometry, and ultraviolet–visible absorption identify the enhancer as lumichrome, a common breakdown product of riboflavin. Treating alfalfa roots with 3 nM lumichrome increased root respiration 21% (P < 0.05) within 48 h. A closely linked increase in net carbon assimilation by the shoot compensated for the enhanced root respiration. For example, applying 5 nM lumichrome to young alfalfa roots increased plant growth by 8% (P < 0.05) after 12 days. Soaking alfalfa seeds in 5 nM lumichrome before germination increased growth by 18% (P < 0.01) over the same period. In both cases, significant growth enhancement (P < 0.05) was evident only in the shoot. S. meliloti requires exogenous CO2 for growth and may benefit directly from the enhanced root respiration that is triggered by lumichrome. Thus Sinorhizobium–alfalfa associations, which ultimately form symbiotic N2-reducing root nodules, may be favored at an early developmental stage by lumichrome, a previously unrecognized mutualistic signal. The rapid degradation of riboflavin to lumichrome under many physiological conditions and the prevalence of riboflavin release by rhizosphere bacteria suggest that events demonstrated here in the S. meliloti–alfalfa association may be widely important across many plant–microbe interactions.

From tropics to tundra: Global convergence in plant functioning

Despite striking differences in climate, soils, and evolutionary history among diverse biomes ranging from tropical and temperate forests to alpine tundra and desert, we found similar interspecific relationships among leaf structure and function and plant growth in all biomes. Our results thus demonstrate convergent evolution and global generality in plant functioning, despite the enormous diversity of plant species and biomes. For 280 plant species from two global data sets, we found that potential carbon gain (photosynthesis) and carbon loss (respiration) increase in similar proportion with decreasing leaf life-span, increasing leaf nitrogen concentration, and increasing leaf surface area-to-mass ratio. Productivity of individual plants and of leaves in vegetation canopies also changes in constant proportion to leaf life-span and surface area-to-mass ratio. These global plant functional relationships have significant implications for global scale modeling of vegetation–atmosphere CO2 exchange.

Gibberellin Dose-Response Regulation of GA4 Gene Transcript Levels in Arabidopsis1

The gibberellins (GAs) are a complex family of diterpenoid compounds, some of which are potent endogenous regulators of plant growth. As part of a feedback control of endogenous GA levels, active GAs negatively regulate the abundance of mRNA transcripts encoding GA biosynthesis enzymes. For example, Arabidopsis GA4 gene transcripts encode GA 3β-hydroxylase, an enzyme that catalyzes the conversion of inactive to active GAs. Here we show that active GAs regulate GA4 transcript abundance in a dose-dependent manner, and that down-regulation of GA4 transcript abundance is effected by GA4 (the product of 3β-hydroxylation) but not by its immediate precursor GA9 (the substrate). Comparison of several different GA structures showed that GAs active in promoting hypocotyl elongation were also active in regulating GA4 transcript abundance, suggesting that similar GA:receptor and subsequent signal transduction processes control these two responses. It is interesting that these activities were not restricted to 3β-hydroxylated GAs, being also exhibited by structures that were not 3β-hydroxylated but that had another electronegative group at C-3. We also show that GA-mediated control of GA4 transcript abundance is disrupted in the GA-response mutants gai and spy-5. These observations define a sensitive homeostatic mechanism whereby plants may regulate their endogenous GA levels.

From seed germination to flowering, light controls plant development via the pigment phytochrome.

Plant growth and development are regulated by interactions between the environment and endogenous developmental programs. Of the various environmental factors controlling plant development, light plays an especially important role, in photosynthesis, in seasonal and diurnal time sensing, and as a cue for altering developmental pattern. Recently, several laboratories have devised a variety of genetic screens using Arabidopsis thaliana to dissect the signal transduction pathways of the various photoreceptor systems. Genetic analysis demonstrates that light responses are not simply endpoints of linear signal transduction pathways but are the result of the integration of information from a variety of photoreceptors through a complex network of interacting signaling components. These signaling components include the red/far-red light receptors, phytochromes, at least one blue light receptor, and negative regulatory genes (DET, COP, and FUS) that act downstream from the photoreceptors in the nucleus. In addition, a steroid hormone, brassinolide, also plays a role in light-regulated development and gene expression in Arabidopsis. These molecular and genetic data are allowing us to construct models of the mechanisms by which light controls development and gene expression in Arabidopsis. In the future, this knowledge can be used as a framework for understanding how all land plants respond to changes in their environment.