Resorption Protection. Anthocyanins Facilitate Nutrient Recovery in Autumn by Shielding Leaves from Potentially Damaging Light Levels

Hoch, William A.; Singsaas, Eric L.; McCown, Brent H.

doi:10.1104/pp.103.027631

Cited by 195 publications

(164 citation statements)

References 41 publications

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“…Our conclusion is reinforced by the fact that the leaves of A. faxoniana from interspecific competition displayed a higher maximal PSII quantum yield and higher effective quantum yield of PSII than did plants growing alone, resulting in a high foliar N resorption. Shading facilitates the recovery of foliar nutrients by shielding photosynthetic tissues from excess light under ET, because resorption is dependent on a competent photosynthetic system to supply the energy needed for the catabolic activity (Hoch et al, 2003). In contrast, in B. albo-sinensis, A 1400 , relative height growth rate and relative diameter growth rate were negatively affected by interspecific competition under ET.…”

Section: Discussionmentioning

confidence: 87%

Ecophysiological responses of two dominant subalpine tree species Betula albo-sinensis and Abies faxoniana to intra- and interspecific competition under elevated temperature

Duan

Dong

Zhang

et al. 2014

Forest Ecology and Management

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Section: Discussionmentioning

confidence: 87%

Ecophysiological responses of two dominant subalpine tree species Betula albo-sinensis and Abies faxoniana to intra- and interspecific competition under elevated temperature

Duan

Dong

Zhang

et al. 2014

Forest Ecology and Management

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“…Carotenoids are not the only pigments responsible for autumn colors; anthocyanins often accumulate (Lee et al, 2003), giving rise to dark-reddish leaf colors, and have been proposed to function as light protectants during the nutrient recycling of senescing leaves (Feild et al, 2001;Hoch et al, 2003). Therefore, we quantified anthocyanin levels to see whether they changed during autumn senescence in aspen leaves.…”

Section: Dynamic Changes In Carotenoid and Anthocyanin Metabolismmentioning

confidence: 99%

A Cellular Timetable of Autumn Senescence

et al. 2005

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We have studied autumn leaf senescence in a free-growing aspen (Populus tremula) by following changes in pigment, metabolite and nutrient content, photosynthesis, and cell and organelle integrity. The senescence process started on September 11, 2003, apparently initiated solely by the photoperiod, and progressed steadily without any obvious influence of other environmental signals. For example, after this date, senescing leaves accumulated anthocyanins in response to conditions inducing photooxidative stress, but at the beginning of September the leaves did not. Degradation of leaf constituents took place over an 18-d period, and, although the cells in each leaf did not all senesce in parallel, senescence in the tree as a whole was synchronous. Lutein and b-carotene were degraded in parallel with chlorophyll, whereas neoxanthin and the xanthophyll cycle pigments were retained longer. Chloroplasts in each cell were rapidly converted to gerontoplasts and many, although not all, cells died. From September 19, when chlorophyll levels had dropped by 50%, mitochondrial respiration provided the energy for nutrient remobilization. Remobilization seemed to stop on September 29, probably due to the cessation of phloem transport, but, up to abscission of the last leaves (over 1 week later), some cells were metabolically active and had chlorophyllcontaining gerontoplasts. About 80% of the nitrogen and phosphorus was remobilized, and on September 29 a sudden change occurred in the d 15 N of the cellular content, indicating that volatile compounds may have been released.

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“…They give color to flowers and fruits (Winkel-Shirley, 2001) and are important antioxidants (Gould et al, 2002). Their antioxidant properties have nutritional value for humans and help to protect plants from oxidative damage (Nagata et al, 2003), allowing nutrient recovery in aging and senescing leaves (Hoch et al, 2003). Synthesis of flavonoids and especially anthocyanins, which are responsible for purple coloration of leaves, is stimulated by abiotic and biotic stresses (Dixon and Paiva, 1995), including cold, high irradiance, excess sugar (Tsukaya et al, 1991), or limitation of inorganic macronutrients like phosphorous (P) and N Morcuende et al, 2007).…”

Section: Nitrogen (N) and Nitrate (Nomentioning

confidence: 99%

Members of theLBDFamily of Transcription Factors Repress Anthocyanin Synthesis and Affect Additional Nitrogen Responses inArabidopsis

Rubin

Tohge

Mizutani³

et al. 2009

The Plant Cell

529

454

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Nitrogen (N) and nitrate (NO 32 ) per se regulate many aspects of plant metabolism, growth, and development. N/NO 3 2 also suppresses parts of secondary metabolism, including anthocyanin synthesis. Molecular components for this repression are unknown. We report that three N/NO 3 2 -induced members of the LATERAL ORGAN BOUNDARY DOMAIN (LBD) gene family of transcription factors (LBD37, LBD38, and LBD39) act as negative regulators of anthocyanin biosynthesis in Arabidopsis thaliana. Overexpression of each of the three genes in the absence of N/NO 3 2 strongly suppresses the key regulators of anthocyanin synthesis PAP1 and PAP2, genes in the anthocyanin-specific part of flavonoid synthesis, as well as cyanidinbut not quercetin-or kaempferol-glycoside production. Conversely, lbd37, lbd38, or lbd39 mutants accumulate anthocyanins when grown in N/NO 3 2 -sufficient conditions and show constitutive expression of anthocyanin biosynthetic genes. The LBD genes also repress many other known N-responsive genes, including key genes required for NO 3 2 uptake and assimilation, resulting in altered NO 3 2 content, nitrate reductase activity/activation, protein, amino acid, and starch levels, and N-related growth phenotypes. The results identify LBD37 and its two close homologs as novel repressors of anthocyanin biosynthesis and N availability signals in general. They also show that, besides being developmental regulators, LBD genes fulfill roles in metabolic regulation. INTRODUCTION Nitrogen (N) and nitrate (NO 32 ) itself regulate many aspects of plant metabolism, growth, and development. These include NO 3 2 uptake and assimilation (Crawford, 1995;Lejay et al., 1999), starch and organic acid metabolism (Scheible et al., 1997a), secondary metabolism (e.g., anthocyanin production) Fritz et al., 2006), germination (Alboresi et al., 2005), root architecture (Zhang et al., 1999), root and shoot development (Scheible et al., 1997b), leaf expansion (Walch-Liu et al., 2000), stomatal opening (Guo et al., 2003), flowering (Bernier et al., 1993), seed set, and senescence (Crawford, 1995;Stitt, 1999;Crawford and Forde, 2002). Some molecular components involved in regulation of these N/NO 3 2 responses in Arabidopsis thaliana have been described. The MADS box transcription factor (TF) ARABIDOPSIS NITRATE REGULATED1 (ANR1) was found to act as regulator of systemic NO 3 2 repression and localized NO 3 2 stimulation of lateral root growth (Zhang and Forde, 1998). NITRATE TRANSPORTER1.1 (NRT1.1) was subsequently shown to act upstream of ANR1 in the signaling pathway triggering lateral root growth and root colonization of NO 3 2 -rich patches (Remans et al., 2006) and to regulate expression of the high-affinity NO 3 2 transporter NRT2.1 (Muñ os et al., 2004). Also, NRT2.1 is suspected to repress lateral root initiation in response to nutritional cues by acting either as a NO 3 2 sensor or signal transducer (Little et al., 2005). Recently, a CBL-interacting protein kinase, CIPK8, was shown to regulate parts of the primary NO 3 2 response, incl...

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Resorption Protection. Anthocyanins Facilitate Nutrient Recovery in Autumn by Shielding Leaves from Potentially Damaging Light Levels

Cited by 195 publications

References 41 publications

Ecophysiological responses of two dominant subalpine tree species Betula albo-sinensis and Abies faxoniana to intra- and interspecific competition under elevated temperature

Ecophysiological responses of two dominant subalpine tree species Betula albo-sinensis and Abies faxoniana to intra- and interspecific competition under elevated temperature

A Cellular Timetable of Autumn Senescence

Members of theLBDFamily of Transcription Factors Repress Anthocyanin Synthesis and Affect Additional Nitrogen Responses inArabidopsis

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