Archana Mukherjee

Effect of NaCl on in vitro propagation of sweet potato (Ipomoea batatas L.)

Abstractin vitro propagation protocols offer a better option for production of quality planting materials in a clonal crop such as sweet potato, which is a food crop of versatile uses. Propagation through axillary shoot proliferation and organogenic and embryogenic regeneration were studied in different genotypes of sweet potato. The addition of NaCl enhanced the rate of multiplication as well as yielded hardy somatic embryos. Optimal doses of NaCl in each mode of propagation were different. The hardy somatic embryos produced in NaCl medium could be stored at 8°C with or without a protective alginate covering. High-frequency germination of stored hardy somatic embryos could facilitate the production of artificial seeds. Plantlets produced with the addition of NaCl in regeneration medium were established in vivo at a high frequency (95–100%). Yield and quality of storage roots developed from artificial seed-propagated plants were comparable with those of source plants.

Growth and morphogenesis of immature embryos of sweet potato (Ipomoea batatas L.) in vitro

Sweet potato (Ipomoea batatas L.) embryos excised from the fertilized ovules of 6- to 12-day-old capsules were cultured on MS medium supplemented with NAA, BA, GA separately and in combinations. GA was found essential for initial morphogenesis of globular and heart stages. Seedlings were recovered from late globular stage onwards but recovery was best from advanced embryo stages. Differentiated embryos produced multiple shoots on MS medium +1μM NAA÷2μM BA +0.5μM GA.

Photosynthetic, physiological and biochemical events associated with polyethylene glycol-mediated osmotic stress tolerance in taro ( Colocasia esculenta L. Schott)

Six genotypes of taro (Colocasia esculenta L. Schott) were evaluated under in vitro and in vivo polyethylene glycol (PEG–6000)-mediated osmotic stress conditions. A significant variation in growth response was observed among the taro genotypes under in vitro-induced stress conditions. In vivo results indicated a significant effect of osmotic stress on photosynthetic parameters, such as net photosynthetic rate, transpiration rate, stomatal conductance, stomatal resistance, internal CO2 concentration, carboxylation efficiency, and transpiration efficiency on the tested genotypes at the tuberization stage. Lesser variations in photosynthesis and higher accumulation of proline, phenols, and antioxidative enzymes, namely, superoxide dismutase and guaiacol peroxidase, were associated with yield maintenance under osmotic stress conditions. The genotypes DP–89, IGCOL–4, and Ramhipur showed a higher degree of tolerance towards osmotic stress with a minimum variation in the studied parameters. These genotypes could be lines of interest for intensification of breeding strategies to develop drought-tolerant plants.