The framework of plant regeneration in duckweed (Lemna turonifera) comprises genetic transcript regulation and cyclohexane release

Regeneration is important for vegetative propagation of excellent variety, detoxification and the obtain of transgenic plant, but plant regeneration is time-consuming. Here, we found that duckweed regeneration could be enhanced by regenerating callus. Firstly, Genetic transcript regulation has been applied to study the molecular mechanism controlling regeneration. Auxin related genes have been significantly down-regulated in regenerating callus. Cytokinin signal pathway genes have been up-regulated in regenerating callus. Secondly, volatile organic compounds release has been analysised by gas chromatography/ mass spectrum during the stage of plant regeneration, and 11 kinds of unique volatile organic compounds in the regenerating callus were increased. Among them, cyclohexane treatment enhanced duckweed regeneration by initiating root. Moreover, Auxin signal pathway genes were down-regulated in callus treated by cyclohexane. All together, these results provide novel mechanistic insights into how regenerating callus promotes duckweed regeneration.

The Framework of Plant Regeneration In Duckweed (Lemna Turonifera) Comprises Genetic Transcript Regulation And Cyclohexane Release

Regeneration is essential for vegetative propagation of excellent variety, detoxification, and obtaining transgenic plant. However, plant regeneration is time-consuming. We found that duckweed regeneration could be enhanced by regenerating callus. The molecular and VOCs releasing mechanisms underlying that have been studied here. Firstly, Genetic transcript regulation has been applied to study the molecular mechanism controlling regeneration. Auxin-related genes have been significantly down-regulated in regenerating callus. Cytokinin signal pathway genes have been up-regulated in regenerating callus. Secondly, VOCs release has been analyzed by GC/MS during the stage of plant regeneration, and 11 kinds of unique VOCs in the regenerating callus were increased. Among them, cyclohexane treatment enhanced duckweed regeneration by initiating root. Moreover, Auxin signal pathway genes were down-regulated in callus treated by cyclohexane. Altogether, these results provide novel mechanistic insights into how regenerating callus promotes duckweed regeneration.

AGROBACTERIUM-MEDIATED TRANSFORMATION OF COTTON (GOSSYPIUM HIRSUTUM L.) USING DMO GENE FOR ENHANCED TOLERANCE AGAINST DICAMBA PESTICIDE

The agrobacterium based transformation of herbicide-resistant crops has modernized weed management in crops by producing cost-effective and ecosystem friendly transgenic plants. Cotton is one of the major crops which are grown worldwide due to its great economic value in textile industries. Dicamba is a commonly used herbicide in broadleaf plants to kill a wide range of weeds in many dicotyledonous crop fields since the 20th century. In this study, Eagle 2 cotton variety was transformed with the DMO gene which is responsible for the synthesis of the Dicamba monooxygenase enzyme that exhibits tolerance against the Dicamba herbicide. This entire study was conducted at Four Brothers Genetics Lab, Lahore. Transformed cultures of Agrobacterium Tumefaciens with the DMO gene were acquired. Cotton embryos were isolated and co-cultivated with transformed Agrobacterium cultures under sterile conditions. Transformed embryos were grown on an artificial growth medium and acclimatized under favorable conditions. Healthy and stable plants were shifted infield where they were grown into a mature plant. Leaf samples of these plants were collected and DNA was successfully isolated by the CTAB method. Transformed plants were confirmed by Polymerase chain reaction and gel electrophoresis. Variations in different traits among transformed cotton plants were found which indicated that the transgenic plant 4 showed higher plant height, monopodial and sympodial branches, leaf length, leaf width, number of bolls, and bolls weight. The better performance of plant 4 indicated that the yield potential of the transgenic plant was improved as compared with other transgenic cotton plants.