Expression of a Chimeric Gene Encoding Insecticidal Crystal Protein Cry1Aabc of in Chickpea ( L.) Confers Resistance to Gram Pod Borer ( Hubner.)

Overview

Journal Front Plant Sci

Date 2017 Sep 6

PMID 28871265

Citations 14

Authors

Alok Das

Subhojit Datta

Shallu Thakur

Alok Shukla

Jamal Ansari

G K Sujayanand

Sushil K Chaturvedi

P A Kumar

N P Singh

Affiliations

Soon will be listed here.

Abstract

Domain swapping and generation of chimeric insecticidal crystal protein is an emerging area of insect pest management. The lepidopteran insect pest, gram pod borer ( H.) wreaks havoc to chickpea crop affecting production. Lepidopteran insects were reported to be controlled by () genes. We designed a plant codon optimized chimeric gene () using three domains from three different genes (domains I, II, and III from , , and , respectively) and expressed it under the control of a constitutive promoter in chickpea (. DCP92-3) to assess its effect on gram pod borer. A total of six transgenic chickpea shoots were established by grafting into mature fertile plants. The regenerated (organogenetic) shoots were selected based on antibiotic kanamycin monosulfate (100 mg/L) with transformation efficiency of 0.076%. Three transgenic events were extensively studied based on gene expression pattern and insect mortality across generations. Protein expression in pod walls, immature seeds and leaves (pre- and post-flowering) were estimated and expression in pre-flowering stage was found higher than that of post-flowering. Analysis for the stable integration, expression and insect mortality (detached leaf and whole plant bioassay) led to identification of efficacious transgenic chickpea lines. The chimeric expressed in chickpea is effective against gram pod borer and generated events can be utilized in transgenic breeding program.

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