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Chaudhary Charan Singh Haryana Agricultural University, Hisar

Chaudhary Charan Singh Haryana Agricultural University popularly known as HAU, is one of Asia's biggest agricultural universities, located at Hisar in the Indian state of Haryana. It is named after India's seventh Prime Minister, Chaudhary Charan Singh. It is a leader in agricultural research in India and contributed significantly to Green Revolution and White Revolution in India in the 1960s and 70s. It has a very large campus and has several research centres throughout the state. It won the Indian Council of Agricultural Research's Award for the Best Institute in 1997. HAU was initially a campus of Punjab Agricultural University, Ludhiana. After the formation of Haryana in 1966, it became an autonomous institution on February 2, 1970 through a Presidential Ordinance, later ratified as Haryana and Punjab Agricultural Universities Act, 1970, passed by the Lok Sabha on March 29, 1970. A. L. Fletcher, the first Vice-Chancellor of the university, was instrumental in its initial growth.

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2011 - 20172
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Subject: Biochemistry × Author: Chawla, Shilpa × Start date: 1998 ×
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    ThesisItemOpen Access
    Biochemical and molecular analysis of postharvest chitosan treatments in guava (Psidium guajava L.) fruits
    (CCSHAU, 2017) Chawla, Shilpa; Jain, Veena
    During present investigations, guava fruits of variety Hisar Surkha harvested at mature stage and were analyzed for various physico-chemical, biochemical and molecular changes during storage. Pre-treatment of fruits with chitosan and CaCl2 alone and in combination significantly delayed decline in physiological loss in weight, total soluble solids and maintenance of fruit firmness, delay in loss of acidity, phenolics, ascorbic acid and total antioxidant activity during storage. Cell wall components viz. hemicellulose, cellulose and pectin decreased progressively throughout the storage at room temperature and low temperature. The decrease in cell wall components were in co-ordination with enhanced activities of cell wall degrading enzymes viz. PME, PG and cellulase. The storage of fruits at low temperature showed slow increase in their activities at all stages of storage thereby retaining the integrity of membrane. Oxidative stress indicies viz. superoxide radicals, hydrogen peroxide, malondialdehyde content and LOX activity increased progressively during storage at both conditions but fruit stored at low temperature showed lower oxidative stress. The activities of ROS scavenging enzymes viz. SOD, CAT, APX, POX and PPO and the content of antioxidative metabolite, ascorbic acid increased initially for few days of storage followed by decline at later stages of storage at both the temperatures. However, β-carotene content decreased continuously throughout the storage period. Ethylene production and ACC oxidase activity increased initially and decreased at later stages of storage. Pre-treatment of fruits with chitosan and CaCl2 alone and in combination resulted in significant inhibition of cell wall degrading enzymes, activation of ROS scavenging enzymes and reduction in ethylene production during storage. Transcript profiling of PG and ACO genes revealed the expression at 301 bp and 320 bp respectively. Fruits treated with combination of chitosan and CaCl2 was the most effective in inhibiting the expression of PG and ACO genes. The treatment of CaCl2 (1.5%)+chitosan (1.5%) was most effective treatment in modulating biochemical and molecular changes in guava fruits and enhancing keeping quality of guava during storage. Hence fruits given these treatments and stored at low temperature retained their quality for longer duration of time.
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    ThesisItemOpen Access
    Biochemical studies in wheat under zinc deficiency
    (CCSHAU, 2011) Chawla, Shilpa; Madan, Shashi
    The present investigation was conducted to study the effect of zinc deficiency on physiological, biochemical, yield and quality parameters. Two aestivum genotypes viz. WH-147 and WH-1061 and two durum genotypes viz. WH-896 and WH-912 were sown under varying levels of zinc i.e. T1- 100% Zn, T2- 50% Zn and T3- 25% Zn. Analysis of data revealed that activity of CAT, SOD, ADH, ALP decreased with the decreasing level of Zn while activity of LOX and POX increased with the decrease in zinc level. Protein profile studies revealed the appearance of new band of 34kD in bread wheat genotypes only. Also, one more band of 47kD appeared in all the genotypes at 25% zinc level. Zinc content decreased in leaves and grains but increased in roots under zinc deficiency. Physiological parameters like chlorophyll content, chlorophyll fluorescence, relative water content, chlorophyll stability index, photosynthetic rate, transpiration rate, stomatal conductance and water use efficiency declined with the decrease in zinc level. MDA content and electrolyte leakage increased under zinc deficiency. Yield parameters like plant height, biomass per plant, spike length, test weight, grain yield per plant and number of spikelet decreased with the decreasing level of zinc. Quality parameters like moisture, protein, fat, ash, crude fibre, starch content and sedimentation value declined with the decrease in zinc level. Bread wheat genotypes were found to be more tolerant under Zn deficit conditions than durum wheat. Among bread wheat WH-1061 was more tolerant.