Investigation of a Possible Multi-enzyme Complex Involved in Nicotine Biosynthesis in Roots of Tobacco (Nicotiana tabacum)

Heim, William

18 September 2003

N-methylputrescine oxidase (MPO) is a member of the diamine oxidase (DAO) class of enzymes believed to be responsible for synthesis of the alkaloid nicotine in the roots of Nicotiana tabacum (Mizusaki et al., 1972). A purportedly pure MPO protein from tobacco root culture extracts was used to generate immune antiserum in rabbits (McLauchlan et al., 1993). In an attempt to clone a cDNA encoding MPO, we used this antiserum to screen a tobacco cDNA expression library. Unexpectedly, two previously unreported genes with strong homology to members of a gene family encoding S-adenosylhomocysteine hydrolase (SAHH) in N. sylvestris and a gene encoding SAHH in N. tabacum were cloned instead. SAHH is an enzyme of the S-adenosylmethionine (SAM) recycling pathway, which also includes SAM synthetase (SAMS) and methionine synthase (MS). These results led to the hypothesis of a multi-enzyme complex, or metabolon, of at least one member of the nicotine biosynthesis pathway, i.e., MPO, and at least one member of the SAM recycling pathway, i.e., SAHH, during nicotine biosynthesis. Metabolons are stable noncovalent complexes in cells that ensure sufficient passage of the product of one enzyme reaction to the next enzyme in the pathway via a "channel" without equilibrating with the bulk solution (Ovádi, 1991). My research employed co-immunoprecipitation studies to determine if other SAM recycling enzymes are associated in a complex with MPO and SAHH, as well as Northern and Western blot analyses to determine if the genes encoding SAM recycling pathway enzymes are coordinately regulated during nicotine biosynthesis. Our results indicate that nicotine biosynthesis-inducing conditions result in differential mRNA accumulation patterns of the three enzymes of the SAM recycling pathway, although to different extents. However, protein levels of SAM recycling pathway members do not appear to reflect the differential mRNA accumulation patterns. We have firmly established an association of SAHH and an enzyme with DAO activity, purportedly MPO. If the enzyme is proven to be MPO, then our data would constitute the first documentation of an alkaloid metabolon. Finally, using a degenerate primer PCR approach, we have cloned a 986-bp gene fragment with homology to copper amine oxidases, the class to which MPO belongs. / Master of Science

diamine oxidase

Nicotiana tabacum

multi-enzyme complex

S-adenosylhomocysteine hydrolase

metabolon

N-methylputrescine oxidase

nicotine biosynthesis

Production de lipides et étude de la régulation métabolique chez la diatomée Asterionella formosa / Production of neutral lipids in Asterionella formosa and regulation of metabolism

Mekhalfi, Malika

17 December 2014

La diatomée d'eau douce A. formosa peut produire des lipides neutres en plus ou moins grandes quantités en fonction des conditions de culture. Ainsi, nous avons montré par exemple qu'une carence en silice stimule la production de triacylglycérols (TAGs) mais génère une diminution de la biomasse. En revanche, nous avons montré que l'addition de bicarbonate et de phytohormones augmente à la fois la biomasse et la production de TAGs. L'ajout de phytohormones dans les milieux de culture de cette diatomée résulte en une augmentation de l'activité d'enzymes dans les extraits et notamment celles du cycle de Benson-Calvin. Parmi ces enzymes, la GAPDH est une enzyme dont l'activité augmente significativement. Nous avons montré que chez A. formosa, cette enzyme forme un complexe ternaire avec la CP12 et la Férrédoxine NADP Réductase (FNR) et non pas avec la CP12 et la phosphoribulokinase comme chez la plupart des organismes photosynthétiques. La régulation de cette enzyme en est de fait modifiée. La phytohormone, 24-épibrassinolide conduit à une augmentation d'activité de la GAPDH qui résulte de la dissociation du complexe GAPDH-CP12 et la GAPDH n'est plus redox régulée. La GAPDH chez les diatomées est donc régulée par des interactions protéineprotéine. / A. formosa, a freshwater diatom, can produce different amounts of neutral lipids such as triacylglycerols (TAGs) under different growth conditions. We showed that as it is well-known for diatoms, starvation for silica increased the production of TAGs but decreased biomass. However, the addition of bicarbonate or phytohormones into the growth medium increased both biomass and TAGs. Addition of phytohormones increased the activities of enzymes in particular those of the Benson-Calvin cycle. Among the target enzymes of the Benson-Calvin cycle, GAPDH was strongly affected. We purified this enzyme and demonstrated that, in the diatom A. formosa, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from the Calvin cycle, forms a complex with the small chloroplast protein CP12 and Ferredoxin NADP Reductase (FNR), which is involved in the photochemical phase of photosynthesis. In cells treated with the phytohormone, 24-epibrassinolide, GAPDH was "free", not redox-regulated and not associated anymore with CP12. Therefore GAPDH from this diatom is regulated by protein-protein interaction but the GAPDH/CP12/FNR complex replaces the one formed between GAPDH, CP12 and phosphoribulokinase found in most photoautotrophs.

Micro-Algues

Phytohomones

Complexe multi-Enzymatique

Lipides neutres

Fnr

Gapdh

Microalgae

Phytohormones

Multi-Enzyme complex

Gapdh

Fnr

Neutral lipids