Biosynthèse d'hydrocarbures dérivés des acides gras chez les microalgues / Biosynthesis of fatty acid-derived hydrocarbons in microalgae

Sorigue, Damien

06 December 2016

Les alcanes et les alcènes sont des hydrocarbures non cycliques important dans l’industrie. Ils sont synthétisés à partir d'acides gras par une grande variété d’organismes mais les connaissances à ce sujet sont très limitées chez les microalgues. Le but de ces travaux était donc de rechercher la présence d’alcanes ou d’alcènes dans diverses microalgues modèles, et d’essayer d’identifier la ou les enzymes responsables de la synthèse de ces composés. Nous avons mis en évidence la présence d’hydrocarbures linéaires en C15-C17 chez les microalgues Chlorella et Chlamydomonas. Ces composés étaient synthétisés uniquement en présence de lumière. L’absence dans le génome de ces microalgues d’homologues de gènes codant pour des enzymes connues de synthèse d’alcanes/alcènes a permis de conclure à la présence d’un nouveau système de synthèse d’hydrocarbures. Des purifications enzymatique et des analyses protéomique ont permis d’identifier une enzyme candidate qui exprimée chezE. coli est suffisante à la synthèse d’hydrocarbures. L'étude de cette enzyme révella qu'il s'agissait d'une photoenzyme utilisant l'énergie des photons bleue pour décarboxyler les acides grass en alca(e)ne. La structure de cette photoenzyme montre la présence un tunnel hydrophobe contenant l’acide gras et le cofacteur FAD. Cette nouvelle enzyme nommée « alcane photosynthase » amène de nombreuses question: qu'elle est la fonction des hydrocarbures chez ces microorganismes? Quel est le mécanisme catalytique de l’alcane photosynthase? Enfin, elle offre de nouvelles possibilités pour la production de biocarburants utilisant directement l’énergie solaire. / Alkanes and alkenes are important in industry. Alkanes and alkenes are synthesized from fatty acids by a variety of organisms, such as plants and insects. However, the presence in microalgae of enzymes converting fatty acids into hydrocarbons has been poorly studied. The aim of this work was to investigate the presence of alkanes and alkenes in various microalgae models, and try to identify the enzymes responsible for the synthesis of these compounds.We have first demonstrated the presence of linear hydrocarbons C15-C17 in microalgae Chlorella and Chlamydomonas. Then we have shown that the main hydrocarbon formed in Chlorella and Chlamydomonas was derived from cis-vaccenic acid and was synthesized only in the presence of light. Absence of homologues of genes coding for known alkane/alkene biosynthetic enzymes in the genome of Chlorella and Chlamydomonas indicate the presence of an unknown pathway. Enzymatic purification and proteomic analysis allowed to identify a candidate enzyme which, expressed in E. coli lead to the formation of hydrocarbons with variable chain lengths, thus demonstrating that it was really an synthase alkane. Characterization showed that the enzyme was a photoenzyme, which used blue light to catalyse the decarboxylation of fatty acid to an alka(e)ne. The three-dimensional structure of this enzyme revealed a hydrophobic tunnel containing the fatty acid and the FAD cofactor.

Alkanes

Alkenes

Bioénergies

Photoenzyme

Microalgae

Alkanes

Alkenes

Biofuels

Photoenzyme

Microalgae

570

Ultrafast Catalytic Mechanism and Molecular Dynamics of Fatty Acid Photodecarboxylase

Wu, Ruiqi

January 2022

No description available.

Biophysics

Physical Chemistry

Molecular Biology

Fatty acid photodecarboxylase

photoenzyme

flavin

femtosecond dynamics

radical intermediates

photochemical mechanism

Mechanistic studies on the light-dependent NADPH:Protochlorophyllide Oxidoreductase and animal cryptochromes

Archipowa, Nataliya

January 2018

Nature uses sunlight either as energy source or as information carrier. Photoreception is achieved by two groups of specialised proteins: photo-enzymes that catalyse photoreactions and photosensors that initiate physiological functions. In the present work mechanistic studies were conducted on one representative of each group by using site-directed mutagenesis as well as stationary and time-resolved spectroscopy. The photo-enzyme NADPH:Protochlorophyllide Oxidoreductase (POR) catalyses the light-dependent C17-C18 double bond reduction of protochlorophyllide, including a hydride and a proton transfer, to produce chlorophyllide, the immediate precursor of chlorophyll. POR provides a unique opportunity to study the hydride transfer mechanism in detail. Three distinct intermediates, prior to product formation, were observed that were interpreted as electron and proton-coupled electron transfer reactions from NADPH indicating a sequential hydride transfer mechanism. An active-site mutant, POR-C226S, yields distinct different intermediates compared to POR wild type but ends in the same chlorophyllide stereoisomer most likely due to an altered protochlorophyllide binding. This work provides the first direct observation of a stepwise hydride transfer mechanism in a biological system. Cryptochromes (CRY) are so far defined as flavoprotein blue-light photosensors that regulate the circadian clock throughout nature and are suggested as the candidate magnetoreceptor in animals. Animal CRY are subdivided into two classes of proteins: the light-responsive Type I (invertebrates) and the light-independent Type II (mainly vertebrates). The molecular basis of their different roles in the circadian clock is still unknown. Animal Type I CRY are suggested to undergo conformational changes - required for induction of subsequent signalling cascades - induced by the change in the FAD redox state due to light absorption. The study shows that in contrast to Type I animal Type II CRY do not bind tightly FAD as a cofactor due to the lack of structural features and therefore provide the molecular basis for their different biological roles ruling out a direct photomagnetoreceptor function. Further, detailed studies on a fruit fly (Dm)CRY reveal that it does not undergo a photocycle as FAD release and Trp decomposition were observed. Thus, it is suggested that light is a negative regulator of DmCRY stability linking the initial photochemistry to subsequent dark processes leading to signal transduction on a molecular level.

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