A bacterial mannitol-1-phosphate dehydrogenase (mtlD) gene driven by the constitutive cauliflower mosaic virus (CaMV) 35S promoter was transferred into tomato plants using an Agrobacterium tumefaciens-mediated transformation protocol in an attempt to improve abiotic stress tolerance in the transformed plants. Transgene integration was confirmed by PCR analysis and Southern blot analysis, and transgene expression was confirmed by reverse transcription (RT)-PCR and direct mtlD (EC 1.1.1.17) activity. Upon exposure to low temperature stress (4°C) in a cold chamber, transgenic plants survived up to 48 h, while nontransformed plants were unable to survive and gradually died. Transgenic plants subjected to the chilling stress showed a significant decrease in electrolyte leakage and increased lipid peroxidation, as assessed by measuring malondialdehyde (MDA) content. Under the cold condition, transgenic plants also showed a significant increase in the activities of antioxidant enzymes (superoxide dismutase and catalase) and in relative water content (RWC) in comparison to non-transformed plants. Drought (polyethylene glycol in medium) and salinity (sodium chloride in medium) tolerance tests revealed that transgenic lines exhibited a higher tolerance for abiotic stresses than non-transformed plants. These findings indicate that the introduction of a bacterial mtlD gene into tomato conferred tolerance to abiotic stresses to the transformed tomato plants.
Weedy rice, a menace in rice growing areas globally, is biosimilar having attributes similar to cultivated and wild rice, and therefore is difficult to manage. A study was initiated to characterize the functional traits of 76 weedy rice populations and commonly grown rice cultivars from different agro-climatic zones for nine morphological, five physiological, and three phenological parameters in a field experiment under an augmented block design. Comparison between weedy and cultivated rice revealed a difference in duration (days) from panicle emergence to heading as the most variable trait and awn length as the least variable one, as evidenced from their coefficients of variation. The results of principal component analysis revealed the first three principal components to represent 47.3% of the total variation, which indicates an important role of transpiration, conductance, leaf-air temperature difference, days to panicle emergence, days to heading, flag leaf length, SPAD (soil-plant analysis development), grain weight, plant height, and panicle length to the diversity in weedy rice populations. The variations existing in weedy rice population are a major reason for its wider adaptability to varied environmental conditions and also a problem while trying to manage it.
Grain legumes, the important constituents of sustainability-based cropping systems and energy-limited vegetarian diets have long been the subject of scientific research. Tremendous technological strides were made in the so-called orphan crops, in terms of both varietal improvement and generation of basic information. Despite recalcitrancy and high genotype dependency, in vitro culture techniques such as organogenesis, in vitro mutagenesis, embryo rescue and in vitro gene transfer have been deployed for improvement of several grain legumes and these played an important role in introgression of desirable genes from related and distant species and creation of additional genetic variability. Stable and reproducible regeneration protocols resulted in the development of genetically modified chickpea, pigeon pea, cowpea, mungbean, etc., while embryo rescue was deployed successfully for recovery of interspecific recombinants, a few of them exploited for the development of commercial cultivars. Nevertheless, doubled haploidy witnessed limited success and protoplast regeneration and in vitro mutagenesis remained of academic interest.The present review focuses on the progress, achievements, constraints and perspectives of using in vitro technology in grain legume improvement.
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