Analyses of Arabidopsis Yellow Stripe-Like (YSL) Family of Metal Transporters

Chu, Heng-Hsuan

01 February 2010

Iron is one of the most important micronutrients used by living organisms. Iron is frequently a limiting nutrient for plant growth, and plants are a major source of iron for human nutrition. The most prominent symptom of iron deficiency in plants is interveinal chlorosis, or yellowing between the veins, which appears first in the youngest leaves. Iron deficiency anemia (IDA) is the number one human nutritional deficiency worldwide. In order to solve the problem of iron deficiency, it is desirable to breed plants that have increased iron in those parts that are consumed by humans. To do this, we must first understand the molecular basis of Fe uptake, transport, and storage in plants. In soil, iron is quickly oxidized to Fe(III), and Fe(III) is relatively insoluble, thus difficult for plants to obtain. Our lab has been working on metal ion homeostasis mechanisms in plants and the ultimate goal of our research is to understand the mechanisms by which plants maintain the correct levels of iron, zinc and copper in each cell and tissue. The Yellow Stripe-like (YSL) family of proteins has been identified based on sequence similarity to maize Yellow stripe 1 (YS1). YS1 transports Fe(III) that is complexed by phytosiderophores (PS), strong Fe(III) chelators of the mugineic acid family of compounds. Non-grass species of plants neither make nor use PS, yet YSL family members are found in non-grass species including Arabidopsis thaliana. YSLs in non-grasses have been hypothesized to transport metals that are complexed by nicotianamine (NA), an iron chelator that is structurally similar to PS and which is found in all higher plants. In this dissertation, Arabidopsis YSL1 and YSL3 are demonstrated to be important in iron transport and also responsible for loading Fe, Cu, and Zn from leaves into seeds. Arabidopsis YSL4 and YSL6 are demonstrated to be involved in iron transport and metal mobilization into seeds. The transport function of Arabidopsis YSL1 and YSL2 are shown be partially overlapping to the function of Arabidopsis YSL3 in vegetative structures, but distinct in reproductive organs. Arabidopsis YSL3 and YSL6 are shown to have distinct functions in planta.

Metal transporters

Iron uptake

Yellow stripe-like proteins

Plant Sciences

Etude des HMAS A Zn2+/Cd2+/Co2+/Pb2+ chez Arabidopsis thaliana, du rôle physiologique à la structure / Study of the Zn2+/Cd2+/Co2+/Pb2+ HMAs of Arabidopsis thaliana, from the physiological role to the structure

Cun, Pierre

19 June 2013

Les travaux présentés ici portent sur les P1B-ATPases HMA2, HMA3 et HMA4 d'Arabidopsis thaliana, transporteurs de cations présents sur différentes membranes chez les plantes. L'étude du contenu cationique de plantes mutantes hma2 et hma4 a précisé le rôle important de HMA4 dans la translocation du Zn et du Cd vers les parties aériennes et sa forte affinité pour le Cd. La mesure du contenu cationique de graines de différents génotypes a montré un effet complexe des modulations de l'expression des gènes correspondants, la surexpression du gène HMA4 conduisant à une teneur en Zn de la graine similaire à celle du mutant perte de fonction. Ces résultats confirment l'importance de HMA4, et montrent la nécessité d'adapter la construction aux objectifs biotechnologiques visés. Afin de préciser le rôle de résidus conservés au sein de la famille des P1B-ATPases, j'ai étudié l'effet de l'expression d'un variant de HMA4 pour le domaine fortement conservé CPC. Les résultats obtenus in planta suggèrent une interaction avec la version native du transporteur entraînant une perte de l'activité de HMA4. Pour mener une approche structure/fonction sur ces transporteurs, L. lactis a été défini comme le meilleur candidat pour produire HMA3. Suite à l'expression de HMA3, un gain de tolérance au Cd a été observé et a permis de valider 3 variants de HMA3, mutés au niveau du pore ou du site d'hydrolyse de l'ATP, comme affectés dans l'activité de la protéine. Les membranes de L. lactis enrichies en transporteur HMA3 ou de ses variants ont permis une reconstitution in vitro en protéoliposomes permettant de mesurer une activité de transport du Cd compétitive avec le Zn et inhibée par le vanadate. / Work presented here is about Arabidopsis thaliana P1B-ATPases HMA2, HMA3 et HMA4, cation transporters found in different plant membranes. Cation content study of mutant plants hma2 and hma4 precised important role of HMA4 in upward translocation of Zn and Cd, and its high affinity for Cd. Cation content measure of seeds from different genotypes showed a complex effect of modulations of related genes expression levels, HMA4 overexpression leading to a seed Zn content similar the loss-of-function mutant one. These results confirm the importance of HMA4 and show the needs to adapt construction to biotechnological aims. To precise the role of residus conserved among the P1B-ATPases family, I studied the effect of the expression of a HMA4 variant for the highly conserved domain CPC. Obtained in planta results suggest an interaction with the native transporter leading to a loss of HMA4 activité. To perform a structure/function study on these transporters, L.lactis has been shown as the best candidate to produce HMA3. Due to HMA3 expression, a gain of Cd tolerance has been observed and allowed to validate three HMA3 variants, mutated in the pore or the ATP hydrolysis site, as affected in the protein activity. L.lactis membranes enriched with HMA3 or variants allowed an in vitro reconstitution in proteoliposomes and the measurement of a Cd transport activity competing with Zn and inhibited by vanadate.

Transporteurs de métaux

P-ATPases

Cadmium

Zinc

Phytoremediation

Biofortification

Metal transporters

P-ATPases

Cadmium

Zinc

Phytoremediation

Biofortification

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