A plastid terminal oxidase associated with carotenoid desaturation during chromoplast differentiation

The Arabidopsis IMMUTANS gene encodes a plastid homolog of the mitochondrial alternative oxidase, which is associated with phytoene desaturation. Upon expression in Escherichia coli, this protein confers a detectable cyanide-resistant electron transport to isolated membranes. In this assay this activity is sensitive to n-propyl-gallate, an inhibitor of the alternative oxidase. This protein appears to be a plastid terminal oxidase (PTOX) that is functionally equivalent to a quinol:oxygen oxidoreductase. This protein was immunodetected in achlorophyllous pepper (Capsicum annuum) chromoplast membranes, and a corresponding cDNA was cloned from pepper and tomato (Lycopersicum esculentum) fruits. Genomic analysis suggests the presence of a single gene in these organisms, the expression of which parallels phytoene desaturase and zeta-carotene desaturase gene expression during fruit ripening. Furthermore, this PTOX gene is impaired in the tomato ghost mutant, which accumulates phytoene in leaves and fruits. These data show that PTOX also participates in carotenoid desaturation in chromoplasts in addition to its role during early chloroplast development

A plastid terminal oxidase associated with carotenoid desaturation during chromoplast differentiation

The Arabidopsis IMMUTANS gene encodes a plastid homolog of the mitochondrial alternative oxidase, which is associated with phytoene desaturation. Upon expression in Escherichia coli, this protein confers a detectable cyanide-resistant electron transport to isolated membranes. In this assay this activity is sensitive to n-propyl-gallate, an inhibitor of the alternative oxidase. This protein appears to be a plastid terminal oxidase (PTOX) that is functionally equivalent to a quinol:oxygen oxidoreductase. This protein was immunodetected in achlorophyllous pepper (Capsicum annuum) chromoplast membranes, and a corresponding cDNA was cloned from pepper and tomato (Lycopersicum esculentum) fruits. Genomic analysis suggests the presence of a single gene in these organisms, the expression of which parallels phytoene desaturase and ζ-carotene desaturase gene expression during fruit ripening. Furthermore, thisPTOX gene is impaired in the tomato ghostmutant, which accumulates phytoene in leaves and fruits. These data show that PTOX also participates in carotenoid desaturation in chromoplasts in addition to its role during early chloroplast development

Evidence for alternative electron sinks to photosynthetic carbon assimilation in the high mountain plant species Ranunculus glacialis

International audienceThe high mountain plant species Ranunculus glacialis has a low antioxidative scavenging capacity and a low activity of thermal dissipation of excess light energy despite its growth under conditions of frequent light and cold stress. In order to examine whether this species is protected from over-reduction by matching photosystem II (PSII) electron transport (ETR) and carbon assimilation, both were analysed simultaneously at various temperatures and light intensities using infrared gas absorption coupled with chlorophyll fluorescence. ETR exceeded electron consumption by carbon assimilation at higher light intensities and at all temperatures tested, necessitating alternative electron sinks. As photorespiration might consume the majority of excess electrons, photorespiration was inhibited by either high internal leaf CO2 molar ratio (C-i), low oxygen partial pressure (0.5% oxygen), or both. At 0.5% oxygen ETR was significantly lower than at 21% oxygen. At 21% oxygen, however, ETR still exceeded carbon assimilation at high C-i, suggesting that excess electrons are transferred to another oxygen consuming reaction when photorespiration is blocked. Nevertheless, photorespiration does contribute to electron consumption. While the activity of the water -water cycle to electron consumption is not known in leaves of R. glacialis, indirect evidence such as the high sensitivity to oxidative stress and the low initial NADP-malate dehydrogenase (NADP-MDH) activity suggests only a minor contribution as an alternative electron sink. Alternatively, the plastid terminal oxidase (PTOX) may transfer excess electrons to oxygen. This enzyme is highly abundant in R. glacialis leaves and exceeds the PTOX content of every other plant species so far examined, including those of transgenic tomato leaves overexpressing the PTOX protein. Finally, PTOX contents strongly declined during deacclimation of R. glacialis plants, suggesting their important role in photoprotection. Ranunculus glacialis is the first reported plant species with such a high PTOX protein content

Deletion of the tobacco plastid psbA gene triggers an upregulation of the thylakoid-associated NAD(P)H dehydrogenase complex and the plastid terminal oxidase (PTOX)

We have constructed a tobacco psbA gene deletion mutant that is devoid of photosystem II (PSII) complex. Analysis of thylakoid membranes revealed comparable amounts, on a chlorophyll basis, of photosystem I (PSI), the cytochrome b6f complex and the PSII light-harvesting complex (LHCII) antenna proteins in wild-type (WT) and DeltapsbA leaves. Lack of PSII in the mutant, however, resulted in over 10-fold higher relative amounts of the thylakoid-associated plastid terminal oxidase (PTOX) and the NAD(P)H dehydrogenase (NDH) complex. Increased amounts of Ndh polypeptides were accompanied with a more than fourfold enhancement of NDH activity in the mutant thylakoids, as revealed by in-gel NADH dehydrogenase measurements. NADH also had a specific stimulating effect on P700+ re-reduction in the DeltapsbA thylakoids. Altogether, our results suggest that enhancement of electron flow via the NDH complex and possibly other alternative electron transport routes partly compensates for the loss of PSII function in the DeltapsbA mutant. As mRNA levels were comparable in WT and DeltapsbA plants, upregulation of the alternative electron transport pathways (NDH complex and PTOX) occurs apparently by translational or post-translational mechanisms

Caractérisation d'une oxydase terminale plastidiale impliquée dans la biosynthèse des caroténoïdes et dans la réponse au stress.

The Arabidopsis mutant immutans displays a variegated phenotype and is accumulating phytoen, a carotenoid precursor.The IMMUTANS gene encodes a plastid homolog of the mitochondrial alternative oxidase, that can be detected in stroma lamellae of the thylakoid and in achlorophyllous chromoplast membranes. Upon expression in E. coli, this protein confers a detectable KCN-resistant electron transport to isolated membranes, this transport being sensitive to nPG. Thus, this protein appears to be a Plastid Terminal OXidase (PTOX), and its activity requires PQ and iron.PTOX also seems to be the terminal oxidase of the chlororespiration. When expressed in tobacco, PTOX accelerates the non-photochemical reoxidation of plastoquinols, and drives significant electron flow to O2, thus avoiding over-reduction of plastoquinones. PTOX strong accumulation in the high mountain plant Ranunculus glacialis is suggesting a specific involvment of PTOX in a resistance to photoinhibition mechanism.Le mutant immutans d'Arabidopsis présente un phénotype panaché et accumule du phytoène, précurseur des caroténoïdes.Le gène IMMUTANS code une protéine plastidiale, homologue à l'oxydase alterne mitochondriale, et loacalisée dans les lamelles stromatiques du thylacoïde et dans les membranes achlorophylliques des chromoplastes. Son expression chez E. coli permet l'établissement d'un transport d'électrons résisatn au KCN et inhibé par le n-PG.Cette protéine apparait être une oxydase terminale plastidiale (PTOX), dont l'activité dépend de la présence de PQ et de fer.PTOX semblerait églaement être l'oxydase terminale de la chlororespiration; exprimée chez le tabac, elle accélère la ré-oxydation non photochimique des PQ, et entraine un flux d'électrons vers l'O2, évitant ainsi la sur-réduction des PQ. La forte expression de PTOX chez le plante d'altitude Ranunculus glacialis pourrait indiquer un role particulièrement actif de PTOX dans les mécanismes de résistance à la photoinhibition

Skotomorphogenesis: The Dark Side of Light Signalling

SummaryThe ability to switch from skotomorphogenic to photomorphogenic development is essential for seedling survival. Central to this mechanism are the phytochrome interacting factors that are important for maintaining the skotomorphogenic state and regulating the switch to photomorphogenesis

Integration of Light and Auxin Signaling

Light is vital for plant growth and development: It provides energy for photosynthesis, but also reliable information on seasonal timing and local habitat conditions. Light sensing is therefore of paramount importance for plants. Thus, plants have evolved sophisticated light receptors and signaling networks that detect and respond to changes in light intensity, duration, and spectral quality. Environmental light signals can drive developmental transitions such as germination and flowering, but they also continuously shape development to allow adaptation to the local habitat and microclimate. The ability to respond to a changing and sometimes unfavorable environment underlies the huge success of plants. Much of this growth and developmental plasticity is achieved by light modulation of auxin signaling systems. In this article, we examine the connections between light and auxin that elicit local responses, long distance signaling, and coordinated growth between the shoot and root