Efecto del nitrato de plata (AgNO3) en el crecimiento in vitro de brotes de Anthurium magnificum Linden

Anthurium magnificum Linden es una importante planta ornamental perteneciente a la familia Araceae. Esta especie es muy demandada como planta de maceta para la decoración de interiores y jardines, así como follaje de corte. Los métodos de propagación tradicionales en esta especie presentan ciertas desventajas por lo que no permiten satisfacer la creciente demanda. Estas limitantes convierten al cultivo de tejidos vegetales en el método más eficiente para propagar plantas de Anthurium magnificum a un ritmo más rápido que los métodos de propagación convencionales. En el cultivo de tejidos vegetales el nitrato de plata adicionado a los medios de cultivo actúa como un inhibidor de la acción del etileno y desempeña un papel crucial en la regulación de procesos fisiológicos esenciales de las plantas. El presente trabajo tuvo como objetivo determinar el efecto de diferentes concentraciones de nitrato de plata en el crecimiento in vitro de brotes de Anthurium magnificum. Para ello, se cultivaron brotes in vitro de Anthurium magnificum en medios de cultivo enriquecidos con diferentes concentraciones de nitrato de plata. Los resultados mostraron que los mayores valores en las variables altura de la planta, número de raíces y longitud de las raíces se obtuvieron en un medio de cultivo con 1,0 mg L-1 de nitrato de plata. En la variable área foliar de la planta los mayores valores se presentaron en los medios de cultivo que contenían nitrato de plata independientemente de la concentración empleada.

Anthurium magnificum Linden is an important ornamental plant belonging to the Araceae family. This species is in great demand as a pot plant for interior and garden decoration, as well as cut foliage. The traditional propagation methods in this species have certain disadvantages, which is why they cannot satisfy the growing demand. These limitations make plant tissue culture the most efficient method to propagate Anthurium magnificum plants at a faster rate than conventional propagation methods. In the culture of plant tissues, silver nitrate added to the culture media acts as an inhibitor of the action of ethylene and plays a crucial role in the regulation of essential physiological processes in plants. The objective of this work was to determine the effect of different concentrations of silver nitrate on the in vitro growth of Anthurium magnificum shoots. For this, in vitro shoots of Anthurium magnificum were cultivated in culture media enriched with different concentrations of silver nitrate. The results showed that the highest values in the variables plant height, number of roots and length of the roots were obtained in a culture medium with 1.0 mg L-1 of silver nitrate. In the variable leaf area of the plant, the highest values were presented in the culture media that contained silver nitrate, regardless of the concentration used.

In Vitro Mass Propagation of Cymbopogon citratus Stapf., a Medicinal Gramineae.

Cymbopogon citratus (D.C.) Stapf. is a medicinal plant source of lemon grass oils with multiple uses in the pharmaceutical and food industry. Conventional propagation in semisolid culture medium has become a fast tool for mass propagation of lemon grass, but the production cost must be lower. A solution could be the application of in vitro propagation methods based on liquid culture advantages and automation. This chapter provides two efficient protocols for in vitro propagation via organogenesis and somatic embryogenesis of this medicinal plant. Firstly, we report the production of shoots using a temporary immersion system (TIS). Secondly, a protocol for somatic embryogenesis using semisolid culture for callus formation and multiplication, and liquid culture in a rotatory shaker and conventional bioreactors for the maintenance of embryogenic culture, is described. Well-developed plants can be achieved from both protocols. Here we provide a fast and efficient technology for mass propagation of this medicinal plant taking the advantage of liquid culture and automation.

Influencia de la 6-Bencilaminopurina y el agente gelificante en la reducción de la hiperhidricidad en Tectona grandis L / Influence of 6-Benzyladenine and gelling agent on the reduction of hyperhydricity in Tectona grandis L

The influence of different factors on shoot proliferation and the occurrence of hyperhydricity in teak (Tectona grandis L.) have been studied. Four concentrations of BA (2.22, 4.44, 6.66 and 8.88 µM) and a control treatment with 0 BA were examined. Aiming at reducing the costs during commercial propagation by using gelrite in stead of agar, the use of both gelling agent in the proliferation and hyperhydricity was tested. In order to evaluate if hyperhydricity can be reduced by increasing the gelrite concentration in the culture medium, three concentrations (2.0, 2.5 and 3.0 g L-1) were tested in combination with 4.44 µM BA. The proliferation and occurrence of hyperhydricity during 21 successive subcultures were evaluated. The highest proliferation was achieved in the treatments with 6.66 or 8.88 µM BA. They yielded 5.22 and 5.56 shoots/explant, respectively. But also, the highest percent of hyperhydric shoots was achieved in this treatment. Gelrite resulted in a higher proliferation, but also an almost two times higher hyperhydricity as compared to agar-solidified media. Satisfactory reduction in hyperhydricity (18%) was achieved with 3.0 g L-1 gelrite. However, the successive subcultures onto proliferation in this treatment favored hyperhydricity compromising shoot quality and it´s competence to proliferate. in vitro teak plants were ex vitro rooted and then transferred to greenhouse conditions for acclimatization; ten weeks after transfer they were ready for field plantation.

Se estudió la influencia de diferentes factores en la proliferación y la ocurrencia de la hiperhidricidad in teca (Tectona grandis L.). Se probaron cuatro concentraciones de BA (2,22; 4,44; 6,66 and 8,88 µM) y un control sin BA. Con el objetivo de reducir los costos durante la propagación comercial se experimentó sustituir el agar por el gelrite, para lo cual se estudió en efecto de ambos gelificantes en la proliferación y la hiperhidricidad de los brotes. Se estudiaron, tres concentraciones de gelrite (2,0; 2,5 and 3,0 g L-1) combinadas con 4,44 µM BA, con el objetivo de evaluar si la hiperhidricidad podía ser reducida incrementando la concentración de gelrite. Se evaluó la proliferación de brotes y la ocurrencia de la hiperhidricidad durante 21 subcultivos. Se logró una alta proliferación de brotes en los tratamientos con 6,66 y 8,88 µM BA (5,22 y 5,56 brotes), pero el porcentaje de brotes hiperhídricos también se incrementó. El gelrite resultó en una alta proliferación de brotes, pero con mayor incidencia de la hiperhidricidad que el medio gelificado con agar. Se obtuvo una reducción satisfactoria de la hiperhidricidad (18%), cuando la concentración de gelrite se incrementó hasta 3,0 g L-1. No obstante, la multiplicación de los brotes en este tratamiento más allá del 11no subcultivo favoreció la hiperhidricidad, lo que afectó la calidad de los brotes y su competencia para la proliferación. Las plantas fueron enraizadas ex vitro, transferidas a condiciones de invernadero para su aclimatización y diez semanas después de la transferencia estaban listas para la plantación en campo.

Proteomic profiling of Tectona grandis L. leaf.

Tectona grandis L. (teak) is one of the premier hardwood timbers in the world, ranking at present in the top five tropical hardwood species in terms of worldwide plantation area. Characterization of the proteins present in teak leaves will provide a basis for the development of new tools aimed at assisting tree selection, the monitoring of plant propagation, and the certification of clonal and phenotypic identities. In this paper, we describe the extraction, separation, and identification of leaf proteins from T. grandis using a TCA/acetone protocol, 2DE, and MALDI-TOF. After TCA/acetone protein extraction of leaves, 998 well-resolved spots were detected in Coomassie-stained gels within the 10-114 kDa relative molecular mass (Mr) range at a pH ranging from 3 to 11. A total of 120 spots were digested and subjected to MS. Of these, 100 nonredundant protein species were successfully identified. Functional classification of the identified proteins revealed that proteins involved in photosynthesis, protein translation, and energy production were the most abundant. This work is the first high-throughput attempt to study the T. grandis leaf proteome and represents a stepping stone for further differential expression proteomic studies related to growth, development, biomass production, and culture-associated physiological responses.