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Kerala Agricultural University, Thrissur

The history of agricultural education in Kerala can be traced back to the year 1896 when a scheme was evolved in the erstwhile Travancore State to train a few young men in scientific agriculture at the Demonstration Farm, Karamana, Thiruvananthapuram, presently, the Cropping Systems Research Centre under Kerala Agricultural University. Agriculture was introduced as an optional subject in the middle school classes in the State in 1922 when an Agricultural Middle School was started at Aluva, Ernakulam District. The popularity and usefulness of this school led to the starting of similar institutions at Kottarakkara and Konni in 1928 and 1931 respectively. Agriculture was later introduced as an optional subject for Intermediate Course in 1953. In 1955, the erstwhile Government of Travancore-Cochin started the Agricultural College and Research Institute at Vellayani, Thiruvananthapuram and the College of Veterinary and Animal Sciences at Mannuthy, Thrissur for imparting higher education in agricultural and veterinary sciences, respectively. These institutions were brought under the direct administrative control of the Department of Agriculture and the Department of Animal Husbandry, respectively. With the formation of Kerala State in 1956, these two colleges were affiliated to the University of Kerala. The post-graduate programmes leading to M.Sc. (Ag), M.V.Sc. and Ph.D. degrees were started in 1961, 1962 and 1965 respectively. On the recommendation of the Second National Education Commission (1964-66) headed by Dr. D.S. Kothari, the then Chairman of the University Grants Commission, one Agricultural University in each State was established. The State Agricultural Universities (SAUs) were established in India as an integral part of the National Agricultural Research System to give the much needed impetus to Agriculture Education and Research in the Country. As a result the Kerala Agricultural University (KAU) was established on 24th February 1971 by virtue of the Act 33 of 1971 and started functioning on 1st February 1972. The Kerala Agricultural University is the 15th in the series of the SAUs. In accordance with the provisions of KAU Act of 1971, the Agricultural College and Research Institute at Vellayani, and the College of Veterinary and Animal Sciences, Mannuthy, were brought under the Kerala Agricultural University. In addition, twenty one agricultural and animal husbandry research stations were also transferred to the KAU for taking up research and extension programmes on various crops, animals, birds, etc. During 2011, Kerala Agricultural University was trifurcated into Kerala Veterinary and Animal Sciences University (KVASU), Kerala University of Fisheries and Ocean Studies (KUFOS) and Kerala Agricultural University (KAU). Now the University has seven colleges (four Agriculture, one Agricultural Engineering, one Forestry, one Co-operation Banking & Management), six RARSs, seven KVKs, 15 Research Stations and 16 Research and Extension Units under the faculties of Agriculture, Agricultural Engineering and Forestry. In addition, one Academy on Climate Change Adaptation and one Institute of Agricultural Technology offering M.Sc. (Integrated) Climate Change Adaptation and Diploma in Agricultural Sciences respectively are also functioning in Kerala Agricultural University.

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20212
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Subject: Plant Biotechnology × Author: Anjala, K × Author: KAU × End date: 2022 × Start date: 2021 ×
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    ThesisItemOpen Access
    Editing of rice transcription factor OsMADS26 for drought tolerance through CRISPR/Cas9 system
    (Department of Plant Biotechnology, College of Horticulture, Vellanikkara, 2021) Anjala, K; KAU; Rehna, Augustine
    Rice (Oryza sativa L.) is the most widely consumed staple food of world’s human population belonging to Asia and Africa. Being a semi-aquatic annual plant, rice is highly prone to losses due to various environmental stresses. Many studies regarding this had revealed the need for developing varieties tolerant to abiotic and biotic stresses. Various methods like Marker Assisted Breeding, mutation breeding, RNAi, Antisense technology, ZFNs and TALENs were in use to develop elite traits for abiotic stress tolerance in crops like rice. But very recently, CRISPR/Cas9 system had come into the limelight as an efficient tool for the genetic manipulations of crops. Studies have identified OsMADS26 transcription factor as a negative regulator of drought tolerance in rice. Hence the current study, ‘Editing of rice transcription factor OsMADS26 for drought tolerance through CRISPR/Cas9 system’ was undertaken during the period from 2019 to 2021 at the Centre for Plant Biotechnology and Molecular Biology, CoA, Vellanikkara, Thrissur with an objective to develop drought tolerance in rice. The rice cultivar Nipponbare was selected for the study due to its competence in genetic transformation and regeneration. For CRISPR/Cas9 mediated targeted editing of OsMADS26 gene, guide RNAs (gRNAs) were designed using online software CRISPR-P v2. Genome sequence information of OsMADS26 gene available from rice genome annotation project was used for the study. Genomic region of OsMADS26 gene, flanking the gRNA target (~ 450 bp) was amplified using gene specific primers and sequence of the target region was confirmed using BLASTn and ClustalW analysis. The CRISPR/Cas9 binary vector pRGEB32 was used to clone the guide RNAs using BsaI restriction sites. Three gRNAs were selected for cloning based on features like on score value (higher the value better the editing efficiency), GC content, (40-60%), no. of off-target sites (Minimum number of off-target sites preferred), presence of secondary structure, location on the genome (towards 5' end of gene in exonic region is preferred) etc. The CRISPR/Cas9 construct for cloning was developed by annealing and ligating the gRNAs to the pRGEB32 vector followed by cloning in E. coli strain DH5α. The putative positive clones were identified by colony PCR and further confirmed by Sanger sequencing. The plasmids isolated from PCR positive colonies were sequenced using universal M13 Reverse primer which is present on pRGEB32 vector. The sequences of the clones were confirmed using multiple sequence alignment tool ClustalW. One colony of gRNA 1 construct (OsMADS26 #G1-1) and two colonies of gRNA 3 (OsMADS26 #G3-3 and OsMADS26 #G3-4) were found positive. The CRISPR/Cas9 constructs of OsMADS26 were then mobilized into Agrobacterium tumefaciens strain EHA105 following the Freeze-thaw method. The positive clones were identified using plasmid PCR using hygromycin gene specific primers. Positive colonies of OsMADS26 #G1-1 and OsMADS26 #G3-3 constructs in EHA105 were then used for rice genetic transformation. The seeds of Oryza sativa sub species japonica cultivar Nipponbare were inoculated into N6 medium supplemented with 3.0 mgL-1 2,4-D for callus induction. After five days, the calli were infected with Agrobacterium cultures harboring desired gRNA constructs for 1.5-2 min. Along with the gRNA constructs, an empty vector was also transformed to rice as vector control and a set of untransformed culture were also maintained. After around two days of co-cultivation, the excess Agrobacterium growth was washed-off thoroughly from the calli using the bacteriostatic agent Augmentin. The calli were then placed on selection medium containing Augmentin and Hygromycin. The hygromycin resistant calli showed proliferation after 14 days of incubation. The proliferating microcalli were then transferred to regeneration medium after 21 days. Proliferation of microcalli was observed in vector control, wild type as well as OsMADS26 #G1-1 and OsMADS26 #G3-3 co-transformed plates. The vector control and untransformed calli showed greening and shoot primordia initiation in regeneration medium. The regenerated shoots will be analyzed for mutation in future. Hence, in the current study, gRNA constructs for targeted editing of OsMADS26 gene was successfully developed and transformed in to rice cultivar Nipponbare. Rice genetic transformation suitable to our lab conditions were also optimized. Rice plants with mutations in the OsMADS26 gene is expected in future which can confer drought tolerance.
  • Thumbnail Image
    ThesisItemOpen Access
    Editing of rice transcription factor OsMADS26 for drought tolerance through CRISPR/Cas9 system
    (Department of Plant Biotechnology, College of Horticulture, Vellanikkara, 2021) Anjala, K; KAU; Rehna, Augustine
    Rice (Oryza sativa L.) is the most widely consumed staple food of world’s human population belonging to Asia and Africa. Being a semi-aquatic annual plant, rice is highly prone to losses due to various environmental stresses. Many studies regarding this had revealed the need for developing varieties tolerant to abiotic and biotic stresses. Various methods like Marker Assisted Breeding, mutation breeding, RNAi, Antisense technology, ZFNs and TALENs were in use to develop elite traits for abiotic stress tolerance in crops like rice. But very recently, CRISPR/Cas9 system had come into the limelight as an efficient tool for the genetic manipulations of crops. Studies have identified OsMADS26 transcription factor as a negative regulator of drought tolerance in rice. Hence the current study, ‘Editing of rice transcription factor OsMADS26 for drought tolerance through CRISPR/Cas9 system’ was undertaken during the period from 2019 to 2021 at the Centre for Plant Biotechnology and Molecular Biology, CoA, Vellanikkara, Thrissur with an objective to develop drought tolerance in rice. The rice cultivar Nipponbare was selected for the study due to its competence in genetic transformation and regeneration. For CRISPR/Cas9 mediated targeted editing of OsMADS26 gene, guide RNAs (gRNAs) were designed using online software CRISPR-P v2. Genome sequence information of OsMADS26 gene available from rice genome annotation project was used for the study. Genomic region of OsMADS26 gene, flanking the gRNA target (~ 450 bp) was amplified using gene specific primers and sequence of the target region was confirmed using BLASTn and ClustalW analysis. The CRISPR/Cas9 binary vector pRGEB32 was used to clone the guide RNAs using BsaI restriction sites. Three gRNAs were selected for cloning based on features like on score value (higher the value better the editing efficiency), GC content, (40-60%), no. of off-target sites (Minimum number of off-target sites preferred), presence of secondary structure, location on the genome (towards 5' end of gene in exonic region is preferred) etc. The CRISPR/Cas9 construct for cloning was developed by annealing and ligating the gRNAs to the pRGEB32 vector followed by cloning in E. coli strain DH5α. The putative positive clones were identified by colony PCR and further confirmed by Sanger sequencing. The plasmids isolated from PCR positive colonies were sequenced using universal M13 Reverse primer which is present on pRGEB32 vector. The sequences of the clones were confirmed using multiple sequence alignment tool ClustalW. One colony of gRNA 1 construct (OsMADS26 #G1-1) and two colonies of gRNA 3 (OsMADS26 #G3-3 and OsMADS26 #G3-4) were found positive. The CRISPR/Cas9 constructs of OsMADS26 were then mobilized into Agrobacterium tumefaciens strain EHA105 following the Freeze-thaw method. The positive clones were identified using plasmid PCR using hygromycin gene specific primers. Positive colonies of OsMADS26 #G1-1 and OsMADS26 #G3-3 constructs in EHA105 were then used for rice genetic transformation. The seeds of Oryza sativa sub species japonica cultivar Nipponbare were inoculated into N6 medium supplemented with 3.0 mgL-1 2,4-D for callus induction. After five days, the calli were infected with Agrobacterium cultures harboring desired gRNA constructs for 1.5-2 min. Along with the gRNA constructs, an empty vector was also transformed to rice as vector control and a set of untransformed culture were also maintained. After around two days of co-cultivation, the excess Agrobacterium growth was washed-off thoroughly from the calli using the bacteriostatic agent Augmentin. The calli were then placed on selection medium containing Augmentin and Hygromycin. The hygromycin resistant calli showed proliferation after 14 days of incubation. The proliferating microcalli were then transferred to regeneration medium after 21 days. Proliferation of microcalli was observed in vector control, wild type as well as OsMADS26 #G1-1 and OsMADS26 #G3-3 co-transformed plates. The vector control and untransformed calli showed greening and shoot primordia initiation in regeneration medium. The regenerated shoots will be analyzed for mutation in future. Hence, in the current study, gRNA constructs for targeted editing of OsMADS26 gene was successfully developed and transformed in to rice cultivar Nipponbare. Rice genetic transformation suitable to our lab conditions were also optimized. Rice plants with mutations in the OsMADS26 gene is expected in future which can confer drought tolerance.