Thumbnail Image

Govind Ballabh Pant University of Agriculture and Technology, Pantnagar

After independence, development of the rural sector was considered the primary concern of the Government of India. In 1949, with the appointment of the Radhakrishnan University Education Commission, imparting of agricultural education through the setting up of rural universities became the focal point. Later, in 1954 an Indo-American team led by Dr. K.R. Damle, the Vice-President of ICAR, was constituted that arrived at the idea of establishing a Rural University on the land-grant pattern of USA. As a consequence a contract between the Government of India, the Technical Cooperation Mission and some land-grant universities of USA, was signed to promote agricultural education in the country. The US universities included the universities of Tennessee, the Ohio State University, the Kansas State University, The University of Illinois, the Pennsylvania State University and the University of Missouri. The task of assisting Uttar Pradesh in establishing an agricultural university was assigned to the University of Illinois which signed a contract in 1959 to establish an agricultural University in the State. Dean, H.W. Hannah, of the University of Illinois prepared a blueprint for a Rural University to be set up at the Tarai State Farm in the district Nainital, UP. In the initial stage the University of Illinois also offered the services of its scientists and teachers. Thus, in 1960, the first agricultural university of India, UP Agricultural University, came into being by an Act of legislation, UP Act XI-V of 1958. The Act was later amended under UP Universities Re-enactment and Amendment Act 1972 and the University was rechristened as Govind Ballabh Pant University of Agriculture and Technology keeping in view the contributions of Pt. Govind Ballabh Pant, the then Chief Minister of UP. The University was dedicated to the Nation by the first Prime Minister of India Pt Jawaharlal Nehru on 17 November 1960. The G.B. Pant University is a symbol of successful partnership between India and the United States. The establishment of this university brought about a revolution in agricultural education, research and extension. It paved the way for setting up of 31 other agricultural universities in the country.

Browse

20131
Reset filters
Subject: Molecular Biology and Biotechnology × End date: 2013 × Start date: 2013 ×
Reset filters

Search Results

Now showing 1 - 1 of 1
  • Thumbnail Image
    ThesisItemOpen Access
    Transcriptomic approach for understanding the role of calcium signaling and transport genes in relation to grain calcium content and calcium responsiveness in finger millet
    (G.B. Pant University of Agriculture and Technology, Pantnagar - 263145 (Uttarakhand), 2013-08) Singh, Uma Maheshwar; Anil Kumar
    Finger millet is a plant with exceptionally high seed Ca content. Little is known about the genetic and epigenetic basis of calcium accumulation in seed. In order to understand the mechanisms of high seed Ca accumulation, two genotypes of finger millet differing in seed Ca content i.e. GPHCPB-1 (low Ca) and GPHCPB-45 (high Ca) were selected in present study. Through PCR based approach a total of 8 genes of Calcium regulated protein kinases were isolated, but these were quite few to be able to explain the exact mechanism of high seed Ca accumulation. Therefore, to cover all Ca signalling and transport genes expressed during seed development, the transcriptome of developing spike of both GPHCPB-1 and GPHCPB-45 genotypes were sequenced. A total of 55 and 52 Ca signaling and transport genes were identified in GPHCPB-1 and GPHCPB-45 genotype respectively. On the basis of phylogeny, per cent sequence identity, and conserved sequence analysis all the genes were classified into Ca sensor and transporter gene families. Differential expression analysis showed that 15 genes were highly expressed in GPHCPB-45, 7 were highly expressed in GPHCPB-1 and remaining 32 had very less (FPKM<1) expression value. Structural and functional analysis of these genes were also done and high level of sequence similarity among Ca sensor genes and low level of sequence similarity among Ca transporter genes of finger millet with their rice orthologues was found. Simultaneously effect of different levels of exogenously supplied Ca on both GPHCPB-1 and GPHCPB-45 genotypes were also studied. The responsiveness of both the genotypes towards increasing exogenous application of Ca was determined in terms of changes in Ca accumulation in different tissues and different morpho-physio-agro-biochemical parameters. During the spike development (S1, S2, S3 and S4) the effect of exogenous Ca (Ca deficient-0.1mM, Ca sufficient-5.0 mM, Ca excess-10 mM and Ca toxic- 20 mM) on Ca accumulation in root, stem, leaf and spike and also on root length, root dry matter accumulation, plant height, RWC, chlorophyll content, SPAD value, oxalate and phytate content was recorded. During Ca deficient conditions, genotype GPHCPB-45 performed better than GPHCPB-1; while at toxic level of Ca genotype GPHCPB-1 withstand that condition better than GPHCPB-45 in terms of Ca accumulation as well as different agro-morphophysio-biochemical parameters. Based on such studies it was revealed that threshold potential of Ca accumulation was high for GPHCPB-1 in even Ca toxic conditions, however GPHCPB-45 was efficient accumulator under Ca deficient conditions. The results of present study clearly suggest the differential responsiveness of genotypes towards exogenous application of Ca in different tissues, which is suggestive of genetic and epigenetic basis of seed Ca accumulation trait and induction of differential calcium signaling and transport machinery. The responsiveness of differentially expressed genes (highly expressed in GPHCPB-45; FPKM>4) were studied towards exogenous application of Ca in both GPHCPB-1 and GPHCPB-45 genotypes. The overall high expression of most of the Ca sensor genes i.e., EcCDPK16, EcCDPK19, EcCIPK2, EcCIPK9, and EcCIPK11 were observed in GPHCPB-45 genotype in later stages of spike development, in a concentration dependent manner. Similarly, the overall high expression of Ca transporter genes i.e., EcPM3ATPase2, EcPM4ATPase8, EcPM12ATPase4, EcER3ATPase3 and EcCaX3 were observed in GPHCPB-45 in later stages of spike development, in a concentration dependent manner. The expression of two genes EcCIPK19 and EcPM8ATPase was comparatively higher in GPHCPB-1 as compared to GPHCPB-45 genotype. The exceptionally higher expression of EcCaX3 in response to exogenous Ca and at later stages of spike development in high Ca containing genotype establishes this gene as a strong candidate for higher seed Ca accumulation and its further use for Ca biofortification. However, exploration of its spatial distribution within seed, over expression and knockout studies will help in understanding the exact role of this gene in high seed calcium accumulation. Finally, transcriptome based functional annotation provides a greater insight into the mechanisms related to seed calcium accumulation and would help to accelerate future research in this very important area of seed biology.