Plastidial carbonic anhydrase in cotton (Gossypium hirsutum L.): characterization, expression, and role in lipid biosynthesis

Hoang, Chau V.

08 1900

Recently, plastidial carbonic anhydrase (CA, EC 4.2.1.1) cDNA clones encoding functional CA enzymes were isolated from a nonphotosynthetic cotton tissue. The role of CA in photosynthetic tissues have been well characterized, however there is almost no information for the role of CA in nonphotosynthetic tissues. A survey of relative CA transcript abundance and enzyme activity in different cotton organs revealed that there was substantial CA expression in cotyledons of seedlings and embryos, both nonphotosynthetic tissues. To gain insight into the role(s) of CA, I examined CA expression in cotyledons of seedlings during post-germinative growth at different environmental conditions. CA expression in cotyledons of seedlings increased from 18 h to 72 h after germination in the dark. Seedlings exposed to light had about a 2-fold increase in CA activities when compared with seedlings kept in the dark, whereas relative CA transcript levels were essentially the same. Manipulation of external CO2 environments [zero, ambient (350 ppm), or high (1000 ppm)] modulated coordinately the relative transcript abundance of CA (and rbcS) in cotyledons, but did not affect enzyme activities. On the other hand, regardless of the external CO2 conditions seedlings exposed to light exhibited increase CA activity, concomitant with Rubisco activity and increased chlorophyll content. Our data revealed that steady-state levels of CA and rbcS transcripts are regulated at the transcriptional level in response to external CO2 conditions, while CA and Rubisco activities are modulated at the post-transcriptional level by light. Thus CA expression in cotyledons during post-germinative growth may be to “prime” cotyledons for the transition at the subcellular level for the transition from plastids to chloroplasts, where it provides CO2 for Rubisco during photosynthesis. Furthermore, CA expression increased during embryo maturation similar to oil accumulation. Specific sulfonamide inhibitors of CA activity significantly reduced the rate of [14C]-acetate incorporation into total lipids in cotton embryos and tobacco leaves and cell suspensions in vivo and in vitro. Similar results were obtained in chloroplasts isolated from leaves of transgenic CA antisense-suppressed tobacco plants (5% of wildtype activity). Collectively, these results support the notion that CA plays several physiological roles in nonphotosynthetic tissues.

Carbonic anhydrase.

Cotton -- Genetics.

Carbonic anhydrase enzymes

nonphotosynthetic tissue

post-germinative growth

Rôle du rétromère dans le développement des graines et la croissance des jeunes plantules chez Arabidopsis thaliana / Role of the retromer in seeds and seedling development in Arabidopsis thaliana

Thazar-Poulot, Nelcy

07 October 2011

Chez les eucaryotes, le rétromère est un complexe protéique composé d’un sous complexe SNX (Sorting Nexin) et d’une sous unité VPS (Vacuolar Protein Sorting) également appelé « core » rétromère. Le rétromère a été décrit comme un complexe régulant le transport des protéines membranaires au niveau de l’endosome. Chez Arabidopsis thaliana, les travaux de notre équipe ont démontré que ce complexe est impliqué dans différents processus développementaux tels que le développement de l’embryon, la maturation des protéines de réserves de la graine et l’initiation des racines secondaires. Dans ce travail, nous avons caractérisé la fonction du rétromère dans le développement des graines et des jeunes plantules d’Arabidopsis thaliana. D’une part, nous avons montré que VPS29 est nécessaire à la mise en place des réserves lipidiques de la graine. Nous avons identifié un nouveau « cargo » du complexe rétromère ; LTP6 (Lipid Transfer Protein 6) dont la perte de fonction engendre des phénotypes liés au métabolisme lipidique similaires à ceux du mutant vps29. Compte tenu de la localisation de LTP6 au niveau d’une structure intracellulaire spongieuse caractéristique du réticulum endoplasmique, le site de synthèse des corps lipidiques, nous supposons que le rétromère participe à la biogenèse des réserves lipidiques via sa fonction dans le trafic de ce nouveau « cargo ». D’autre part, nous avons mis en évidence que le « core » rétromère indépendamment de la sous-unité SNX est impliqué dans la mobilisation des réserves lipidiques, une fonction indispensable pour le développement des jeunes plantules. Nous avons montré que VPS29 est nécessaire à la translocalisation de la triacylglycérol lipase SDP1 (Sugar-Dependent 1) du peroxysome aux corps lipidiques, le compartiment de stockage des réserves lipidiques. Ces résultats nous ont permis d’envisager que le « core » rétromère pourrait emprunter de nouvelles voies de trafics intracellulaires entre des compartiments autre que l’endosome. / In eukaryotes, the retromer is a complex composed of the SNX (Sorting Nexin) subcomplex and the VPS (Vacuolar Protein Sorting) subcomplex also called the core retromer. To date, the retromer is described as a key regulator of proteins trafficking around endosomal compartment. In Arabidopsis thaliana, our group has previously demonstrated that this complex is involved in several developmental pathways, as embryo development, seed storage protein maturation and lateral root emergence. In this work, we characterised the function of the retromer in seeds and seedling development in Arabidopsis thaliana. Firstly, we found that VPS29 is required for the formation of seeds storage lipid. We identified a new cargo of this complex; Lipid Transfer Protein 6 (LTP6). LTP6 lost of function induces similar phenotype than vps29 linked to lipid metabolism. Based on LTP6 localisation on an intracellular structure characteristic of endoplasmic reticulum, the site of OBs formation, we supposed that the retromer may act on oil bodies biogenesis by its function on LTP6 trafficking. Secondly, we demonstrated that the core retromer have a SNX-independent function in lipid reserves breakdown, which is essential for seedling establishment. We showed that VPS29 is required for translocation of the triacylglycerol lipase SDP1 (Sugar-Dependent-1) from the peroxisome to oil bodies, the lipid storage compartment. Altogether, these results allowed us to propose new intracellular route trafficking for VPS sub-complex between compartments other than the endosome.

Rétromère

Arabidopsis thaliana

Développement de la graine

Croissance post-germinative

Réserves lipidiques

Corps lipidiques

Transport protéique

Lipase

Retromer

Arabidopsis thaliana

Seed development

Seedling development

Post-germinative growth

Sugar-dependent phenotype

Lipid storage

Oil bodies

Lipase

Proteins trafficking