Les récepteurs GPR91 et GPR99 et leur implication dans le développement du système nerveux visuel

Les récepteurs couplés aux protéines G (RCPG) démontrent de plus en plus de capacités à activer des mécanismes jusqu’alors associés à des facteurs de transcription ou des molécules d’adhésion. En effet, de nouvelles preuves rapportent qu’ils pourraient également participer au guidage axonal qui est le mécanisme permettant aux axones de cellules nerveuses de rejoindre leur cible anatomique. Le guidage axonal se fait par l’interaction entre les molécules de guidage et une structure particulière présente à l’extrémité de l’axone, le cône de croissance. Par exemple, les RCPGs participent au guidage des cellules ganglionnaires de la rétine (CGR), dont les axones s’étendent de la rétine jusqu’au noyaux cérébraux associés à la vision. Cet effet est observé avec des RCPGs tels que les récepteurs aux cannabinoïdes (CB1 et CB2) et celui du lysophosphatidylinositol, le GPR55. Les RCPGs GPR91 et GPRG99, respectivement récepteurs au succinate et à l’α-cétoglutarate, se trouvent à la surface de ces CGRs, ce qui en font des candidats potentiels pouvant participer au guidage axonal. Dans ce mémoire, l’effet des ligands de ces récepteurs sur la croissance et la navigation des axones des CGRs fut analysé. L’impact produit par ces récepteurs ainsi que leurs ligands sur la morphologie des cônes de croissance fut déterminé en mesurant leur taille et le nombre de filopodes présents sur ces cônes. Pour évaluer le rôle du succinate et de l’a-cétoglutarate sur la croissance globale des axones de CGRs, la longueur totale des projections axonales d’explants rétiniens a été mesurée. L’effet de ces ligands des récepteurs GPR91 et GPR99 sur le guidage axonal a également été évalué en temps réel à l’aide d’un gradient créé par un micro injecteur placé à 45° et à 100µm du cône de croissance. La distribution in vivo des récepteurs GPR91 et GPR99 sur la rétine a été étudié à l’aide d’expériences d’immunohistochimie. Les résultats obtenus indiquent que l’ajout de 100µM de succinate produit une augmentation de la taille des cônes de croissance et du nombre de filopodes présents à leur surface. Il augmente également la croissance des axones. Ce type de réponse fut également observé lorsque les cellules furent soumises à 200µM d’α-cétoglutarate. Fait à noter, les deux récepteurs n’ont pas d’impact sur le guidage axonal. Ces résultats indiquent donc que les agonistes des récepteurs GPR91 et GPR99 augmentent la croissance des cellules ganglionnaires lorsqu’ils sont présents lors du développement. Par contre, ils n’ont pas d’influence sur la direction prise par les cônes de croissance. Ces nouvelles données sont un pas de plus dans la compréhension des mécanismes qui gèrent et participent au développement et la croissance des CGRs, ce qui pourrait donner de nouvelles cibles thérapeutique pouvant mener à la régénération de nerfs optiques endommagés.

Tracking biochemical changes during adventitious root formation in olive (Olea europaea L.)

The activity of oxidative enzymes and the levels of free auxins were determined during adventitious root formation in olive explants. Rooting trials were performed both with in vitro-cultured micro shoots of the cultivar ‘Galega Vulgar’, treated with indole-3-butyric acid (IBA) and with salicylhydroxamic acid(SHAM) + IBA, as well as with semi-hardwood cuttings of the cultivars ‘Galega Vulgar’ (difficult-to-root)and ‘Cobrançosa’ (easy-to-root), treated with IBA. The auxin (IBA) was used in all experiments as a rooting promoter, while SHAM was used in micropropagation trials as rooting inhibitor, providing a negative control. Free indole-3-acetic acid (IAA) and IBA concentrations were determined in microshoots, as well as in semi-hardwood cuttings, throughout the rooting period at pre-established time-points. At the sametime-points, the enzymatic activity of polyphenol oxidases (PPO), peroxidases (POX), and IAA oxidase(IAAox) was evaluated in the microshoots. Microshoots treated with SHAM + IBA revealed higher POX and IAAox activity, as well as lower PPO activity, than those treated only with IBA. IAA levels were higher in IBA-treated microshoots during induction phase, but lower during early initiation phase. Incontrast, free IBA levels were higher in microshoots treated with SHAM + IBA during induction, but lower during initiation. A similar pattern of free auxin levels was observed in semi-hardwood cuttings of the two contrasting cultivars under evaluation. The similarities found on the auxin patterns of microshoots treated with SHAM and those of semi-hardwood cuttings of the difficult-to-root olive cultivar allow considering SHAM a reliable control for when simulation of a difficult-to-root behavior is necessary. The inhibitory effect of SHAM in root formation could be related with 1) the inhibition of alternative oxidase(AOX), leading to a down regulation of phenylpropanoid biosynthetic pathways, which would decrease the concentration of phenolic substrates for PPO; 2) an increase in IAAox activity resulting in lower free IAA levels or; 3) a defective conversion of IBA into IAA.

Quantification of free auxins in semi-hardwood plant cuttings and microshoots by dispersive liquid–liquid microextraction/microwave derivatization and GC/MS analysis

Several studies have suggested that differences in the natural rooting ability of plant cuttings could be attributed to differences in endogenous auxin levels. Hence, during rooting experiments, it is important to be able to routinely monitor the evolution of endogenous levels of plant hormones. This work reports the development of a new method for the quantification of free auxins in auxin-treated Olea europaea (L.) explants, using dispersive liquid–liquid microextraction (DLLME) and microwave assisted derivatization (MAD) followed by gas chromatography/mass spectrometry (GC/MS) analysis. Linear ranges of 0.5–500 ng mL 1 and 1–500 mg mL 1 were used for the quantification of indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA), respectively. Determined by serial dilutions, the limits of detection (LOD) and quantification (LOQ) were 0.05 ng mL 1 and 0.25 ng mL 1, respectively for both compounds. When using the calibration curve for determination, the LOQ corresponded to 0.5 ng mL 1 (IAA) and 0.5 mg mL 1 (IBA). The proposed method proved to be substantially faster than other alternatives, and allowed free auxin quantification in real samples of semi-hardwood cuttings and microshoots of two olive cultivars. The concentrations found in the analyzed samples are in the range of 0.131–0.342 mg g 1 (IAA) and 20–264 mg g 1 (IBA).

Simplificação do processo de multiplicação in vitro da oliveira "Olea europaea L."

A oliveira tem sido multiplicada ao longo dos tempos por métodos convencionais de propagação vegetativa como a enxertia e a estacaria lenhosa e semilenhosa. No entanto, estes métodos revelam-se lentos ou ineficientes para determinadas cultivares. No caso da cv. ‘Galega Vulgar’, ainda com grande expressão no olival português, e de difícil enraizamento por estacaria semilenhosa, tem sido usada a micropropagação de modo a contornar essas limitações e assim obter um elevado número de plantas em curto período de tempo. O custo final de produção por este processo ainda é elevado, podendo comprometer a sua aplicação a nível comercial. Grande parte dos custos estão relacionados com a fase de enraizamento in vitro que carece de ambiente estéril e condições de assépsia para a sua execução. Com vista a uma redução de custos associados a esta fase de produção, pretendeu-se com este trabalho testar a viabilidade do enraizamento ex vitro, na ausência de condições de assépsia. Este método poderá permitir uma significativa redução da mão-de-obra, ao mesmo tempo que facilitará a aclimatização das plantas e a obtenção de um sistema radicular de melhor qualidade. Compararam-se as taxas de enraizamento in vitro (controlo), com as obtidas ex vitro. Foram utilizados explantes provenientes de dois clones da cv. ‘Galega Vulgar’, (cl. 1441 e cl. 2022) cultivados e mantidos in vitro há vários anos no Laboratório de Melhoramento e Biotecnologia da Universidade de Évora. Para além do clone foi avaliada a influência do tipo de estaca (basal e apical), da hormona de enraizamento (AIB e ANA), da sua concentração (540 e 3000 ppm) e ainda de dois substratos, Preformas Jiffy® e pastilhas de fibra coco. Os melhores resultados foram obtidos com o clone 1441 em pastilhas de fibra de coco prensada, com o uso de estacas basais. Quanto à auxina, não se observaram diferenças significativas entre a utilização de ANA na concentração de 540 ppm e AIB na concentração de 3000 ppm. A aclimatização das plantas foi conseguida com taxas elevadas de sucesso, independentemente do tratamento utilizado. Conclui-se que a aplicação do método de enraizamento ex vitro simplifica procedimentos e mantém taxas de enraizamento elevadas, conduzindo assim a uma efetiva redução de tempo e custos associados; Simplifying procedures for in vitro propagation of olive “Olea europaea L.” Abstract: The olive tree has been multiplied throughout the ages by conventional methods of vegetative propagation such as grafting and wood or softwood cuttings. These propagation methods are somehow inefficient for certain cultivars. For the CV. ‘Galega Vulgar‘, still with great expression in Portuguese olive orchards, propagation has been attempted by in vitro culture in order to circumvent these limitations and so obtain a large number of plants in short time period. The final production fees associated to this process are still high which may compromise its application to a commercial level. Most of this process fees are related to the in vitro rooting phase which lacks sterile and aseptic conditions for its implementation. Aiming to reduce the costs associated with this production phase, this work tested the feasibility of the ex vitro rooting in the absence of aseptic conditions, which can allow a significant reduction of the manpower involved and an easier plant acclimatization due to its transplant with a balled-root system. In vitro rooting rates (control) were compared with those obtained with the ex vitro experiments. Explants from two clones of the cv. ‘Galega Vulgar‘ (cl. 1441 and cl. 2022), grown and maintained in vitro for several years in the Laboratory of Biotechnology and Plant Breeding of the University of Évora, were used in the trials. In addition to the clone, the effect of the cutting type (basal and apical), the rooting hormone (AIB and ANA), their concentration (540 and 3000 ppm) and two substrates, Preformas Jiffy ® and pressed coco fiber pellets, were also evaluated. The best results were obtained with the clone 1441, when rooted in pressed coco fiber pellets, using basal cuttings. Under this conditions no significant differences were observed between the use of ANA at 540 ppm or AIB in the 3000 ppm. Acclimatization of plants was achieved with high rates of success, regardless of the treatment used. It can be concluded that the application of the ex vitro rooting method allows to maintain high rooting rates, contributing for an effective reduction of time and fees of the rooting process.

Dedifferentiation of Leaf Cells and Growth Pattern of Calluses of Capsicum annuumcv. Etna.

Background:In vitrocell suspension cultivation systems have been largely reported assafe and standardized methods for production of secondary metabolites with medicinaland agricultural interest.Capsicum annuumis one of the most widely grown vegetablein the world and its biological activities have been demonstrated against insects, fungi,bacteria and other groups of organisms. The determination of procedures for thededifferentiation of cells into callus cells and the subsequent study of the callus growthpattern are necessary for the establishment of cellsuspensions and also to subsidizestudies regarding the bioactivity of its secondarymetabolites. To date, no study hasdescribed the development of protocols for callus induction inC. annuumL. cv. Etna. Objective:The objective of this study was to establish a protocol for dedifferentiationof leaf cells of the cultivarC. annuumcv. Etna and to determine the growth pattern ofthe calluses with a focus on the deceleration phase, when the callus cells must besubcultured into a liquid medium in order to establish cell suspension cultivationsaiming at the production of secondary metabolites.Results:The treatment that resultedin the highest %CI, ACCC and callus weight was thecombination of 4.52 μ M 2,4-D +0.44 μ M BA. The calluses produced were friable andwhitish and their growth patternfollowed a sigmoid shape. The deceleration phase started on the 23rdday of cultivation.Conclusion:Callus induction in leaf explants ofC. annuumcv. Etnacan be achieved inMS medium supplemented with 4.52 μ M 2,4-D + 0.44 μ MBA, which results in highcellular proliferation; in order to start a cell suspension culture, callus cells on the 23rdday of culture should be used.