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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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Subject: Genetics and Plant Breeding × Start date: 2023 × Type: Thesis × Thesis Type: Ph.D ×
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Now showing 1 - 6 of 6
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    ThesisItemOpen Access
    Morphological, biochemical and molecular characterization of Asiatic cotton (Gossypium arboreum L.)
    (CCSHAU, Hisar, 2023-01) Deepak Kumar; Sangwan, Omender
    The present investigation “Morphological, biochemical and molecular characterization of Asiatic cotton (Gossypium arboreum L.)” was carried out at Chaudhary Charan Singh Haryana Agricultural University, Hisar in kharif 2019-2020 and 2020-21 with the objective of estimating diversity of 150 genotypes of desi cotton. Variation among genotypes was present for hypocotyl pigmentation, leaf colour, leaf shape, leaf hairiness, flower stigma, leaf nectaries, stem hairiness, boll weight, petiole pigmentation, flower petal colour, boll shape, prominence of tip, plant height, boll opening, seed index, ginning percentage, fibre length, fibre strength and fibre fineness. Analysis of variance revealed presence of variability for all the quantitative traits among the genotypes other than number of locules per boll and seed index. GCV and PCV were high for number of bolls per plant and seed cotton yield, medium for plant height, number of monopods, single boll weight, gossypol content and these parameters were found low in days to first flower, seed index, GOT (%), oil content, fibre length, fibre strength), fibre uniformity, fibre maturity and fibre fineness. High heritability coupled with high genetic advance was observed for most of the traits viz. boll weight, plant height, number of monopods per plant, seed index, oil content, number of bolls per plant, fibre fineness, fibre strength and seed cotton yield per plant. This shows the dominance of additive gene action behind the traits hence direct selection will be effective for these traits. Correlation studies showed that seed cotton yield per plant was significantly and positively correlated with all the traits except days to first flower, plant height and negatively correlated with biochemical and fibre quality traits. Thus, improving other traits, seed cotton yield per plant will also increase. Fibre quality traits like fibre length is significantly positive correlated with fibre strength but negative correlated with seed cotton yield thus suggests that quality and quantity cannot be improved simultaneously one has to be compromised. Whereas, improving fibre length and fibre strength at a time is possible as they are in positive relationship. Genetic diversity analysis was done using 100 SSR markers out of which 66 were found polymorphic with average number of alleles as 2.73 per locus. FFS15 and HD 328 or HD 551 and HD 544 showed 98% similarity index, which means they are the most similar genotypes and have similar genetic background whereas genotypes namely Vira 6 and BHO 5 VIII were the most dissimilar genotypes.
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    ThesisItemOpen Access
    Stability and combining ability analysis in sunflower (Helianthus annuus L.)
    (CCSHAU, Hisar, 2023-06-26) Phan Thi Cam Nhung; Ram Avtar
    The present investigation entitled “Stability and combining ability analysis in sunflower (Helianthus annuus L.)” was carried out to identify the stable genotypes for seed yield and yield contributing traits, to investigate the combining ability of the parents and crosses and to evaluate the heterosis for seed yield and its attributes. The experimental material comprised of 90 genotypes including 72 hybrids developed from line x tester mating design by involving eight CMS lines and nine restorers with local check HFSH 848 was evaluated in four environments at Oilseed Research Area, Department of Genetics & Plant Breeding, College of Agriculture, CCS Haryana Agricultural University, Hisar during Spring 2018 Spring 2019 in timely and late conditions. The observations were recorded on following eleven characters: day to 50% flowering, day to maturity, plant height (cm), stem girth (cm), head diameter (cm), 100-seed weight (g), seed volume (g/100ml), seed yield per plant (g), hull content (%), oil content (%), protein content (%)in all environments. Based on the comparative studies of the Eberhart and Russell (1966) stability parameters, parents and crosses: CMS 103A, CMS 2A EC601879, EC601963, Morden (a)A, RHA 856 , CMS 103A x EC601879, CMS 300A x EC601879 were identified as promising genotypes because these exhibited high mean value, stable performance and average responsive to all environments and also stable performance for some particular characters. The lines and tester: CMS 103A, CMS 2A, CMS 44A, RHA 4-2, EC 601879, RHA 297 were found as good combiner for seed yield. The hybrids CMS 1A x EC601963, CMS 1A x EC601879, CMS 300A x RHA 4-2, CMS 300A x EC601879, CMS 44A x RHA 4-2 , CMSH 91A x RHA 4-2, CMSH 91A x EC601879 were found to highly significant positive heterosis over standard check for seed yield and yield contributing traits.
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    ThesisItemOpen Access
    Population structure and genetic diversity studies for terminal heat stress tolerance in Indian mustard “[Brassica juncea (L.) Czern & Coss.]
    (CCSHAU, Hisar, 2023-02-03) Choudhary, Raju Ram; Ram Avtar
    Indian mustard is one of the most important oilseed crops and contributes more than 30% to the Indian vegetable oil pool. Heat stress is one of the major yield-limiting factors under changing climate conditions. Its impact is most severe at the reproductive stage, resulting in low seed yield. Therefore, assessment of genetic diversity, population structure, and molecular marker-traits associated with terminal heat stress tolerance in Indian mustard germplasm is necessary to accelerate the breeding effort. In the present study, a set of advanced breeding lines and genetic stocks representing 154 genotypes of Indian mustard were phenotyped for various morpho-physiological traits under control and terminal heat stress conditions. Besides, these genotypes were genotyped using 237 SSR markers. The results of the present study revealed significant effects of year, sowing date, and genotypes on various morpho-physiological traits under investigation. For the majority of the traits studied, high heritability and genetic advance were estimated. Trait association results revealed that seed yield/plant was significantly and positively correlated with plant height, number of primary branches/plant, number of secondary branches/plant, main shoot length, number of siliquae on the main shoot, siliqua length, number of seeds/siliqua, 1000-seed weight, photosynthetic rate, stomatal conductance, total chlorophyll content, and carotenoid content. DNA was isolated from all 154 genotypes by the standard method and subjected to SSR marker analysis. Out of total of 237 SSR markers, 111 were polymorphic. PIC values for all polymorphic SSR markers ranged from 0.013 to 0.627, with an average PIC value of 0.31. Unweighted Neighbor Joining-based dendrogram and population structure analysis divided the 154 genotypes into three clusters and two sub-populations, respectively. A total of 29 SSRs under timely sown and 33 SSRs under late sown environment were found to be associated with morphological and physiological traits by the MLM (Q + K) method. Chromosome B06 harbored the maximum number of SSRs (12), followed by chromosomes A08 (11) and A07 (five SSRs). Under terminal heat conditions, a total of 20 SSRs were specifically detected that were not associated under normal sown conditions. This meant that these particular genomic regions and QTLs were linked under extreme heat conditions. Overall, the heat-tolerant genotypes identified in this study and the SSR markers associated with terminal heat stress tolerance attributes will be helpful for the development of a heat-tolerant cultivar of Indian mustard through marker-assisted selection.
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    ThesisItemOpen Access
    Identification and utilization of inter-specific diversity for wheat improvement
    (CCSHAU, Hisar, 2023-01-27) Antim; Vikram Singh
    Improvement in quality traits through biofortification along with grain yield is the major focus of researchers in this critical time of changing climate. Next major objective is developing wheat varieties which can fight changing climatic factors such as heat and drought stress and can provide higher yield to feed continuously expending population. Availability of genetic variability for improving modern day varieties further is present in crop wild relatives and can be introgressed in modern day varieties by creating amphidiploid and synthetic hexaploid wheat (pre-breeding material). The present study was therefore, planned to study the quality traits, grain yield and its component traits and physiological traits in SHW and amphidiploid wheat lines and the whole study was divided into three experiments. Another aim of the study was validation of SSR markers, selected from previous studies, associated with quality traits like Fe, Zn and grain protein content. With this regard 100 amphidiploid wheat lines along with 4 standard checks were sown at research area of ICAR-IIWBR, Karnal in augmented design for two consecutive years. One of the objective of the investigation was finding QTLs linked with heat and drought stress in wheat genotypes through SNP genotyping and for phenotyping 36 wheat genotypes (including SHW and elite lines) were sown at research area of ICAR-IIWBR, Karnal and Wheat and Barley Section, Department of Genetics and Plant Breeding, CCS HAU, Hisar during rabi 2019-20 and 2020-21. Nine thinopyrum accessions were also tested for heat and drought stress traits in the field under five differential sowing conditions for year 2019-20 and 2020-21. Significant genetic variability was observed for all the morphological and physiological traits. In experiment-1, highest Fe content was found to be 70.7ppm in amphidiploid of cross Ae. caudata/ Margarita36-15, highest Zn (48.17ppm) in cross Ae. mutica/ kundermiki39-1 and highest protein content (17.68%) in amphidiploid Ae. mutica/kundermiki14-8 was found. In experiment-2, based on grain yield performance under heat and drought stress conditions created by late sowing of lines in Rain-out-shelter (ROS) OS59, OS61 and OS55 were found to be best performer. Twenty-two stable SNPs located in the domain of genes were also found in this experiment. Marker trait association (MTA) between SNPs and phenotypic data revealed gene Iron-superoxide_distumase (associated with SNP AX-95249973) to play role in saving plants from oxidative stress under drought condition. Another gene P450, which expresses under drought stress to protect plant, was found to be associated with plant height under drought stress condition. In experiment-3 nine Thinopyrum accessions performed best under ROS facility (heat and drought stress) and EC531712 and EC787014 showed highest and stable performance in terms of grain yield/plot.
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    ThesisItemOpen Access
    Morphological, biochemical and molecular characterisation of Ashwagandha (Withania somnifera L. Dunal) genotypes
    (CCSHAU, Hisar, 2023-02) Koli, Ganesh Kumar; Arya, Rajesh Kumar
    The present experiment was carried out with sixty genotypes of ashwagandha for their twenty-seven quantitative and qualitative characteristics with the aim to characterize the sixty ashwagandha genotypes on the basis of morphological, biochemical, and molecular markers. The field studies were undertaken at the research field of Medicinal, Aromatic and Potential crop section, Department of Genetics and Plant Breeding, College of Agriculture, Chaudhary Charan Singh Haryana Agricultural University, Hisar, Haryana, during the Kharif seasons of 2020 and 2021. Analysis of variance revealed that the differences among the genotypes for maximum characters under study were highly significant. In correlation study, dry root yield per plant exhibited a significantly high and positive correlation with plant height, number of primary branches per plant, number of secondary branches per plant, root length per plant, the average diameter of root per plant, harvest index per plant, biological yield per plant, number of secondary roots per plant, root girth per plant, fresh root yield per plant, fresh stem yield per plant, dry stem yield per plant, and surface area of root per plant. Path analysis had shown maximum positive direct effects on dry root yield per plant by days to 50% flowering, plant height, number of primary branches per plant, number of secondary branches per plant, number of berries per plant, biological yield per plant, harvest index per plant, root girth per plant, root length per plant, average diameter of root per plant, number of primary roots per plant, number of secondary roots per plant, dry matter content of root per plant, fresh root yield per plant, dry root yield per plant, fresh stem yield per plant, dry stem yield per plant and surface area of root per plant. Using Tocher’s method, sixty ashwagandha genotypes grouped into five different clusters. Cluster 2 was the largest one with 22 genotypes, followed by cluster 3 with 14 genotypes, while cluster 4 was the smallest and included 7 genotypes. A dendrogram of molecular data analysed with DARWIN software classified 60 promising ashwagandha genotypes into three groups. The highest number of genotypes were grouped into cluster 1 with 35 genotypes, followed by cluster 2 with 24 genotypes, and the lowest number of genotypes were found in cluster 3 with 1 genotype. On the basis of per se performance, genotypes HWS-1201, HWS-1321, and HWS-205 were found to be the best for dry root yield and yield contributing traits. Therefore, these can be successfully utilized as parents in future breeding programmes for improvement of dry root yield performance. Genotypes RAS- 16, HWS-08-4, HWS-08-6, JA-134, HWS-137, HWS-110, and HWS-123 were found to be best for total alkaloid and withanolides production in ashwagandha.
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    ThesisItemOpen Access
    Morphological, biochemical and molecular characterization of different germplasm lines of faba bean [Vicia faba L.]
    (CCSHAU, Hisar, 2023-08) Kaushik, Deepak; Dahiya, Gajraj Singh
    The present investigation “Morphological, biochemical and molecular characterization of different germplasm lines of Faba Bean [Vicia faba L.]” was conducted at Chaudhary Charan Singh Haryana Agricultural University, Hisar during Rabi 2019-2020 and 2020-21 with an objective to characterize 150 faba bean germplasm lines alongside 2 check varieties i.e. HFB-1, Vikrant on the basis of 19 morpho-biochemical traits. The research revealed significant variation among the 150 germplasm lines studied, indicating the presence of valuable genetic diversity. Germplasm lines, such as HB-20, HB-42, HB-49, HB-53, HB-89, and EC-591864, displayed superior performance for yield-related traits, while lines like EC-249791, EC-267675, EC-34808, and EC-361485 exhibited reduced levels of anti-nutritional factors and higher protein content, making them potential candidates for nutritional quality improvement. Heritability estimates and genetic advance analysis highlighted traits with significant genetic potential for improvement. Seed yield per plant, biological yield per plant, harvest index, and tannin content demonstrated high genetic variability and heritability, suggesting that genetic gains can be achieved by focusing on these traits. Positive and significant correlations were observed between seed yield per plant and various yield-contributing traits such as biological yield per plant, hundred seed weight, harvest index, number of pods per plant etc. indicating their relevance for improving overall productivity. Cluster analysis grouped the germplasm lines into 8 distinct clusters based on their similarities, enabling the identification of potential parent lines for hybridization programs. Principal component analysis helped to transform correlated variables into 8 independent principal components and identify key traits contributing to the total variation, with seed yield per plant, biological yield per plant, hundred seed weight, and number of seeds per pod playing significant roles. The selection indices developed in this study emphasized the simultaneous improvement of multiple traits rather than solely focusing on seed yield per plant. The combination of traits like seed yield per plant, biological yield per plant, hundred seed weight, number of pods per plant, number of branches per plant etc. would be highly effective in increasing seed yield per plant. Germplasm lines such as HB-89, HB-42, EC-591864, NDFB-13, and EC-249791 showed promising performance based on these indices, exhibiting higher yields, improved yield-contributing traits, and reduced anti-nutritional factors. Molecular analysis using SSR markers provided insights into the genetic diversity and population structure of the faba bean germplasm lines. SSR markers viz. CAAS 6, CAAS 85, CAAS 82 etc. were had high PIC values, gene diversity and maximum heterozygosity. Selected lines were grouped into 4 populations and level of variation was observed highest among lines rather than among populations. Overall, this research provides valuable information for faba bean breeding programs, including the identification of high-performing germplasm lines, traits with genetic potential for improvement, and insights into the genetic diversity and structure of faba bean germplasm. These findings can guide future breeding efforts to develop improved varieties with enhanced yield, nutritional quality, and adaptability.