Differential Accumulation of Dimethylallyl Diphosphate in Leaves and Needles of Isoprene- and Methylbutenol-Emitting and Nonemitting Species

Rosenstiel, Todd N.; Fisher, Alison J.; Fall, Ray; Monson, Russell K.

doi:10.1104/pp.002717

Cited by 72 publications

(63 citation statements)

References 59 publications

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“…Correspondingly the k cat , being a direct measure of the catalytic efficiency, was found to be relatively low for isoprene synthase, similar to those of other allylic diphosphate-utilizing enzymes (Table 2). In mature oak leaves (Quercus robur) the calculated chloroplastidic DMAPP concentrations were found to be close to the apparent K m value of oak isoprene synthase (Lehning et al 1999;Rosenstiel et al 2002), supporting the hypothesis that the availability of DMAPP can be one of the major driving forces of isoprene synthase activity in mature leaves. The production of the intermediates is light-induced and a positive correlation between leaf DMAPP levels (as substrate for isoprene synthase) and photosynthate flux led to the hypothesis that the lightdependence of isoprene emission is in part due to controls over DMAPP production and content (Brüggemann & Schnitzler 2002a, b;Rosenstiel et al 2002).…”

Section: Link Between Isoprene Emission Capacity and Gross Photosynthmentioning

confidence: 53%

“…On the other hand the demand for DMAPP is very high during leaf expansion by simultaneous investment in growth and greening, as DMAPP is one of the essential precursors of all plant terpenoids (about 30 000 have been identified in leaves), among them those needed for the assembly of the photosynthetic apparatus. Indeed Rosenstiel et al (2002) found that young leaves of cotton wood contained significantly lower levels of DMAPP than mature leaves. Due to the high K m value of isoprene synthase, poor substrate availability due to partitioning to competing pathways may prevent isoprene synthase to be active.…”

Section: Link Between Isoprene Emission Capacity and Gross Photosynthmentioning

confidence: 99%

“…For monoterpenes similar physiological functions as for isoprene were postulated, namely the protection of the photosynthetic apparatus against high temperatures episodes (Sharkey & Singsaas 1995;Loreto et al 1998;Delfine et al 2000) and against oxidative damage (O 3 , OH, H 2 O 2 , HO 2 ) Loreto & Velikova 2001). In extension to the hypothesis of Rosenstiel et al (2002), stating that the availability of DMAPP may explain part of the ontogenetic delay of isoprene emission versus photosynthesis (which could not be shown for H. courbaril), low DMAPP availability may also confer a reasonable explanation for the observed change between monoterpene and isoprene biosynthesis/emission in H. courbaril. For monoterpene biosynthesis DMAPP must be converted to geranylpyrophosphate (GPP) by the enzyme GPP synthase (GPPS).…”

Section: Physiological Constraints (Supply Side Control)mentioning

confidence: 99%

“…Previous studies have emphasized the essential function of isoprene synthase enzyme activation in regulating isoprene biosynthesis and emission Lehning et al 1999;Lichtenthaler 1999;Lehning et al 2001). More recent investigations focused on the regulatory role of the availability of its substrate DMAPP (Brüggemann & Schnitzler 2002a, b;Rosenstiel et al 2002), or other intermediates and enzymes of this biosynthetic pathway (Brüggemann & Schnitzler 2002c;Wolfertz et al 2003). Isoprene synthase seems to have relatively poor catalytic efficiency, usually expressed in terms of the Michaels constant (K m ), which is the substrate DMAPP concentration that produces onehalf maximal reaction rate, and the turnover number (k cat ), which is the number of substrate molecules that each enzyme processes per unit time under optimum conditions (substrate saturated).…”

Section: Link Between Isoprene Emission Capacity and Gross Photosynthmentioning

confidence: 99%

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Strong correlation between isoprene emission and gross photosynthetic capacity during leaf phenology of the tropical tree species Hymenaea courbaril with fundamental changes in volatile organic compounds emission composition during early leaf development

Kühn

Rottenberger

Biesenthal

et al. 2004

Plant Cell & Environment

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Changes of the volatile organic compounds (VOC) emission capacity and composition of different developmental stages of the tropical tree species Hymenaea courbaril were investigated under field conditions at a remote Amazonian rainforest site. The basal emission capacity of isoprene changed considerably over the course of leaf development, from young to mature and to senescent leaves, ultimately spanning a wide range of observed isoprene basal emission capacities from 0.7 to 111.5 m m m m g C g ---during the course of the year. By adjusting the standard emission factors for individual days, the diel courses of instantaneous isoprene emission rates could nevertheless adequately be modelled by a current isoprene algorithm. The results demonstrate the inadequacy of using one single standard emission factor to represent the VOC emission capacity of tropical vegetation for an entire seasonal cycle. A strong linear correlation between the isoprene emission capacity and the gross photosynthetic capacity (GP max ) covering all developmental stages and seasons was observed. The present results provide evidence that leaf photosynthetic properties may confer a valuable basis to model the seasonal variation of isoprenoid emission capacity; especially in tropical regions where the environmental conditions vary less than in temperate regions. In addition to induction and variability of isoprene emission during early leaf development, considerable amounts of monoterpenes were emitted in a light-dependent manner exclusively in the period between bud break and leaf maturity. The fundamental change in emission composition during this stage as a consequence of resource availability ( supply side control ) or as a plant's response to the higher defence demand of young emerging leaves ( demand-side control ) is discussed. The finding of a temporary emergence of monoterpene emission may be of general interest in understanding both the ecological functions of isoprenoid production and the regulatory processes involved.

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Section: Link Between Isoprene Emission Capacity and Gross Photosynthmentioning

confidence: 53%

Section: Link Between Isoprene Emission Capacity and Gross Photosynthmentioning

confidence: 99%

Section: Physiological Constraints (Supply Side Control)mentioning

confidence: 99%

Section: Link Between Isoprene Emission Capacity and Gross Photosynthmentioning

confidence: 99%

See 2 more Smart Citations

Strong correlation between isoprene emission and gross photosynthetic capacity during leaf phenology of the tropical tree species Hymenaea courbaril with fundamental changes in volatile organic compounds emission composition during early leaf development

Kühn

Rottenberger

Biesenthal

et al. 2004

Plant Cell & Environment

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show abstract

“…In Populus sp. a link between low NO 3 − and isoprene has been established (7) and other work indicates that DMAPP levels may govern the rate of emission (31,32).…”

Section: Raɵo M/z 640/( 577+640)mentioning

confidence: 99%

Metabolomic analysis ofArabidopsisreveals hemiterpenoid glycosides as products of a nitrate ion-regulated, carbon flux overflow

Ward

Baker

Llewellyn

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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An understanding of the balance between carbon and nitrogen assimilation in plants is key to future bioengineering for a range of applications. Metabolomic analysis of the model plant, Arabidopsis thaliana, using combined NMR-MS revealed the presence of two hemiterpenoid glycosides that accumulated in leaf tissue, to ∼1% dry weight under repeated nitrate-deficient conditions. The formation of these isoprenoids was correlated with leaf nitrate concentrations that could also be assayed in the metabolomic data using a unique flavonoid-nitrate mass spectral adduct. Analysis of leaf and root tissue from plants grown in hydroponics with a variety of root stressors identified the conditions under which the isoprenoid pathway in leaves was diverted to the hemiterpenoids. These compounds were strongly induced by root wounding or oxidative stress and weakly induced by potassium deficiency. Other stresses such as cold, saline, and osmotic stress did not induce the compounds. Replacement of nitrate with ammonia failed to suppress the formation of the hemiterpenoids, indicating that nitrate sensing was a key factor. Feeding of intermediates was used to study aspects of 2-C-methyl-D-erythritol-4-phosphate pathway regulation leading to hemiterpenoid formation. The formation of the hemiterpenoids in leaves was strongly correlated with the induction of the phenylpropanoids scopolin and coniferin in roots of the same plants. These shunts of photosynthetic carbon flow are discussed in terms of overflow mechanisms that have some parallels with isoprene production in tree species.F or centuries mankind has relied on carbon, prehistorically fixed from the atmosphere by plants and algae, as a source of fuel and other materials. This is a dwindling resource and, to develop renewable sources of chemicals, knowledge of the biochemical pathways that link photosynthesis to the accumulation of useful materials will be paramount. Terpenoids (isoprenoids) are examples of carbon-rich products that occur prolifically across the plant kingdom. They are not only end products of chloroplast assimilation of photosynthetic carbon but also, by virtue of the phytyl side chains of chlorophyll, key elements of the machinery of photosynthesis. Some terpenoids are ubiquitous and are classed as primary metabolites (sterols, carotenoids, and phytyl side chains of chlorophyll); others are hormones (gibberellins, abscisic acid, brassinosteroids, and strigolactones). However, the majority of terpenoids, especially those that can accumulate to high levels in plants, are classed as secondary metabolites, although many have roles in chemical ecology. Manipulation of flux through the primary terpenoid pathways and the accumulation of terpenoids via the secondary pathways both have potential for exploitation. Arabidopsis, the model plant, was, until recently, considered to be poorly endowed with terpenoids. For example, this species does not appear to contain oxidized sesqui-and diterpenes, compounds that are widespread in plants (1). There are some 30 terpene synt...

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Biosynthesis and Emission of Isoprene, Methylbutanol and Other Volatile Plant Isoprenoids

Lichtenthaler

2010

The Chemistry and Biology of Volatiles

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Differential Accumulation of Dimethylallyl Diphosphate in Leaves and Needles of Isoprene- and Methylbutenol-Emitting and Nonemitting Species

Cited by 72 publications

References 59 publications

Strong correlation between isoprene emission and gross photosynthetic capacity during leaf phenology of the tropical tree species Hymenaea courbaril with fundamental changes in volatile organic compounds emission composition during early leaf development

Strong correlation between isoprene emission and gross photosynthetic capacity during leaf phenology of the tropical tree species Hymenaea courbaril with fundamental changes in volatile organic compounds emission composition during early leaf development

Metabolomic analysis ofArabidopsisreveals hemiterpenoid glycosides as products of a nitrate ion-regulated, carbon flux overflow

Biosynthesis and Emission of Isoprene, Methylbutanol and Other Volatile Plant Isoprenoids

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