Coupling of seagrass (Cymodocea nodosa) patch dynamics to subaqueous dune migratio

The coupling between patch dynamics - described by the patch growth (horizontal and vertical), patch mortality, and life-history of Cymodocea nodosa (Ucria) Aschers., and the disturbance caused by the migration of subaqueous dunes over the plants was examined in a shallow NW Mediterranean bay (Alfacs Bay) where this species maintains a patchy cover. C. nodosa shoots survived substantial burial rates (up to 2.4 mm/day) by growing vertically at rates proportional to, albeit four-fold slower than, burial rates. Patch death was caused by erosion as large subaqueous dunes migrated pass the plant patch. Patch growth was fastest over the progressing slope of the dunes ( similar to 2.5 m year super(-1)) and flowering was also stimulated by sand accretion. The time interval between the passage of consecutive dunes, which sets the time window available for patch development, ranged between 2 and 6 years. This time interval allowed C. nodosa to recolonize bare substrata, with patch formation occurring about half a year after the disturbance, and also allowed established shoots to complete their life-cycle and produce seeds and thus enable subsequent recolonization. The time windows available for patch development also set an upper limit to patch size of about 26 m. Significant cross correlations between dune topography and patch dynamics and plant flowering frequency provide evidence that the spatial heterogeneity in the vegetation is closely associated with the disturbance imposed by the migration of sand dunes. The migration of subaqueous dunes maintains C. nodosa in a continuous state of colonization involving spatially asynchronous patch growth and subsequent mortality, which is ultimately responsible for the characteristic patchy landscape of this Bay. 

Effect of elevated CO2 concentrations and irradiance on the photosynthetic performance of the seagrass Cymodocea nodosa

Dissertação de Mestrado, Biologia Marinha, Faculdade de Ciências e Tecnologia, Universidade do Algarve, 2015

Conservación ex situ de Cymodocea nodosa (Ucria) Ascherson. Propagación de semillas in vitro, y establecimiento de cultivos celulares.

[ES] El objetivo principal de esta tesis ha sido presentar soluciones a los problemas de conservación que afectan a la especie Cymodocea nodosa y su ecosistema en Canarias, llevando a cabo estrategias de conservación ex situ que incluyen el desarrollo de una técnica de propagación con la que obtener plántulas germinadas a partir de semillas, su aclimatación y trasplante al mar. Una vez desarrollada la técnica de propagación in vitro, nos planteamos abordar estrategias para optimizar el procedimiento establecido, interviniendo sobre la conservación de las semillas in vitro y sobre la mejora, previo al trasplante, del estatus nutritivo y del crecimiento de las plántulas. Con la experiencia adquirida se han establecido las bases del cultivo in vitro a partir de tejido embrionario, permitiendo el mantenimiento de cultivos celulares en condiciones asépticas. El protocolo desarrollado supone una herramienta nueva y fundamental para el futuro del cultivo in vitro de esta especie, ya que permite ensayar nuevas técnicas y protocolos de regeneración para poder obtener, en un futuro, embriones somáticos que se desarrollen hasta plantas completas aplicando la técnica de germinación y propagación desarrollada, y proveer, así, de material vegetal para llevar a cabo programas de restauración y trasplante sin recurrir a las praderas naturales.

Restoration of Cymodocea nodosa (Uchria) Ascherson seagrass prairies through seed propagation. Seed storage and growth of seedlings as affected by inorganic nutrients and plant hormones.

[EN] In the frame of the restoration of natural populations of Cymodocea nodosa of the Canary Islands, seeds are being collected at natural populations where germination is rather scarce and seasonal after dormancy. We have developed techniques of propagation in vitro of collected seeds, consisting in forced seed germination and seedlings propagation to obtain mature 20-30 cm plantlet, which eventually are being used for restoration. In order to improve the developed methodology, several experiments were conducted to adjust conditions for seed storage under different regimes of temperature without loosing germinative potential, fertilize during propagation with controlled released NPK fertilizers, and increase growth by dipping seedlings in solutions of the most common plant hormones.

Restoration of Cymodocea nodosa (Uchria) Ascherson seagrass prairies through seed propagation. Germination in vitro, plantlet acclimation and transplanting to natural meadows.

[EN] The seagrass Cymodocea nodosa (Ucria) Ascherson is the most abundant seagrass species in the Canary Islands (Spain), where it forms dense submerged, ecologically relevant communities as stable and protected habitats. As with other seagrasses, concern has arisen due to a decline in the number and extension of the communities as the result of adverse activities in coastal areas. Seed germination and planting are assumed as cost-effective method for restoration. In the frame of the restoration of natural populations of Cymodocea nodosa, pilot experiences not tested so far in the Canary Islands have been carried out to developed in vitro techniques to produce viable seedlings and its transference to the natural environment.

Axenic cell culture of the seagrass Cymodocea nodosa from cotyledonary tissue

[EN] Plant Tissue Culture, also called “micropropagation”, is the propagation of plants from different tissues (or explants) in a shorter time than conventional propagation, making use of the ability that many plant cells have to regenerate a whole plant (totipotency).There are two alternative mechanisms by which an explant can regenerate an entire plant, namely organogenesis and somatic embryogenesis. Since the last decades, the number of higher terrestrial plants species from which these techniques have been successfully applied has continually increased. However, few attempts have been carried out in marine plants. Previous seagrasses authors have focused their studies on i) vegetative propagation of rhizome fragments as explants in Ruppia maritima, Halophila engelmannii, Cymodocea nodosa and Posidonia oceanica; ii) culture of meristems in Heterozostera tasmanica, C. nodosa or P. oceanica; and iii) culture of germinated seeds on aseptic conditions, in Thalassia testudinum, H. ovalis, P. coriacea, P. oceanica, and H. decipiens. All these studies determine the most adequate culture medium for each species (seawater, nutrients, vitamins, carbon sources, etc...), often supplemented with different plant growth regulators and the necessary conditions for the culture maintenance, such as light and temperature. On the other hand, several studies have previously established protocols for cell or protoplast isolation in the species Zostera marina, Z. muelleri, P. oceanica, and C. nodosa, using shoots collected from natural meadows as original vegetal source, but further cell growth was never accomplished. Due to the absence of somatic embryogenesis or organogenetic studies in seagrasses we wonder: IS THE SUCCESSFUL APPLICATION OF TISSUE CULTURE TECHNIQUES POSSIBLE IN SEAGRASSES?

Repoblando nuestras costas: propagación in vitro de la fanerogama marina Cymodocea nodosa (Cymodoceae)

[ES] Cymodocea nodosa (Ucria) Ascherson es una fanerógama marina que crece en fondos arenosos bien iluminados, dando lugar a las praderas submarinas (sebadales), hábitat que tiene una importante función ecológica y repercusiones económicas, por su beneficio para las poblaciones de peces. Las actividades humanas en el litoral amenazan a las comunidades de fanerógamas marinas, lo que ha llevado a la regresión de estos ecosistemas y al detrimento de la calidad de sus aguas. De forma natural, la especie sólo responde mediante la propagación vegetativa a estas alteraciones, ya que, estudios sobre la germinación de las semillas en Cymodocea nodosa muestran que, en relación con el alto número de frutos generalmente encontrados en el sedimento, sólo son detectadas un bajo número de plántulas con un rizoma desarrollado, y la viabilidad natural de estas nuevas plántulas es, además, baja. Ante tal situación natural, el empleo de técnicas de micropropagación puede contribuir a las labores que se realizan para la restauración o reimplantación de sebadales. Habiéndose comprobado que existen limitaciones para la propagación in vitro a partir de fragmentos de la planta (ej. rizoma, se ha pensado en incrementar la capacidad germinativa, venciendo i) la dormancia que presenta la semilla, aclimatando en acuarios y transplantando al mar nuevas plántulas, como primera medida, y ii) la inducción de embriogénesis somática, como segunda medida estratégica que asegure la provisión permanente de nuevas plántulas.