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Not AvailableWith increasing population size, there is an urgent need to double the global food production by 2050, and the onus is on the agricultural scientists to develop new technologies and varieties to double the production. Development of new varieties in any crop varieties is time-consuming as it is dependent on generation period of a crop. Speed breeding or accelerated plant breeding is an emerging strategy among plant breeders to develop new cultivars in short span of time. Here, the plants are grown in controlled growth chambers or greenhouses using optimal light intensity and quality, particular day length and temperature, which accelerates various physiological processes in plants especially photosynthesis and flowering, thus shortening the generation time. Speed breeding can be used to achieve up to 4–6 generations per year instead of 2–3 generations under normal glasshouse conditions. Speed breeding approaches and protocols are well established and standardized for major crop species like wheat, barley and canola. This strategy is now being applied, and standardization protocols are in progress for other crops including perennial fruit crop like apple. Speed breeding could serve as a basic platform for integrating high-throughput phenotyping and genotyping techniques, marker-assisted/genomic selections and gene editing for improvement of the traits in crop species. The present chapter gives an overlook of speed breeding activities carried out in different crops and its importance in present situation of crop improvement under vagaries of environment due to climate change.Not Availabl

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Not AvailableIndia is the second largest producer of rice in the world and it is the most important staple food grain. All India Coordinated Rice Improvement Project (AICRIP) was initiated with objective of conducting multi-location trials to identify suitable genotypes of high yield potential along with appropriate crop management practices. Since its inception AICRIP contributed significantly in meeting the growing demand both within and outside India. Significant progress has been achieved through AICRIP in terms of varietal release thereby increasing the crop productivity and also meeting the food and nutritional security. This paper makes a sincere effort in bringing out the significant achievements/milestones achieved under the AICRIP program and also gives a few directions for widening the areas under AICRIPNot Availabl

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Not AvailableIndia is the second largest producer of rice in the world and it is the most important staple food grain. All India Coordinated Rice Improvement Project (AICRIP) was initiated with objective of conducting multi-location trials to identify suitable genotypes of high yield potential along with appropriate crop management practices. Since its inception AICRIP contributed significantly in meeting the growing demand both within and outside India. Significant progress has been achieved through AICRIP in terms of varietal release thereby increasing the crop productivity and also meeting the food and nutritional security. This paper makes a sincere effort in bringing out the significant achievements/milestones achieved under the AICRIP program and also gives a few directions for widening the areas under AICRIPNot Availabl

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Not AvailableAims: The main objective of the study is to combining the higher yield and micronutrient content along with good grain cooking quality in polished rice. Study Place and Duration of Study: The experiment was conducted in the farm of Indian Institute of Rice Research, Hyderabad, India. The duration of the study was two successive wet seasons 2013 and 2014. Methodology: The experiment was conducted in a randomized complete block design (RCBD). Four rice accessions consist of two parent lines (Samba Mahsuri and Chittimutyalu) and two derivatives (BPCM1 and BPCM2) were grown under normal agronomical conditions, evaluated for their yield, grain quality and nutritional properties. The four genotypes were profiled with RM markers. Results: Both the derivative lines BPCM1 and BPCM2 have shown higher yield advantage (4.5% and 8.8%) than the parent Samba Mahsuri along with quality parameters like amylose content(23.3%, 25%) and gel consistency (21.5, 23.7) as well as high zinc content (20.6 ppm, 24 ppm) moderate iron content (3.6 ppm, 4.3 ppm) in polished rice. High heritability (0.91%) was found for the all traits studied. The association of grain yield is significant with harvest index, test weight and straw yield. Grain zinc content was significantly and positively associated with iron content and negatively associated with total protein. The experiment result indicates that, the micronutrient enhancement could be possible along with grain yield and cooking qualityNot Availabl

Coordinated Rice Improvement Project in India: Its Significant Achievements and Future prospects

Not AvailableIndia is the second largest producer of rice in the world and it is the most important staple food grain. All India Coordinated Rice Improvement Project (AICRIP) was initiated with objective of conducting multi-location trials to identify suitable genotypes of high yield potential along with appropriate crop management practices. Since its inception AICRIP contributed significantly in meeting the growing demand both within and outside India. Significant progress has been achieved through AICRIP in terms of varietal release thereby increasing the crop productivity and also meeting the food and nutritional security. This paper makes a sincere effort in bringing out the significant achievements/milestones achieved under the AICRIP program and also gives a few directions for widening the areas under AICRIP.Not Availabl

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Not AvailableBacterial blight (BB) of rice caused by the pathogen Xanthomonas oryzae pv. oryzae and the insect gall midge (GM) (Orseolia oryzae) are two major constraints of rice production. The present study was carried out to improve RPHR-1005, a stable restorer line of the fine-grain-type rice hybrid DRRH-3, for BB and GM resistance through marker-assisted backcross breeding (MABB). Two major GM resistance genes, Gm4 and Gm8, and a major BB resistance gene, Xa21, were selected as target genes for transfer to RPHR-1005. Two sets of backcrosses were carried out to combine either Xa21 + Gm4 or Xa21+ Gm8 into RPHR-1005 using breeding lines in the genetic background of ISM possessing either Gm4 or Gm8 along with Xa21. Foreground selection was performed for Xa21, Gm4, Gm8, and the major fertility restorer genes Rf3 and Rf4 using gene-specific markers, while 61 polymorphic simple sequence repeat (SSR) markers were used for background selection and marker-assisted backcrossing was continued until BC2 generation. A promising homozygous backcross-derived plant at the BC2F2 generation possessing Xa21 + Gm4, and another possessing Xa21 + Gm8, were intercrossed to stack the target resistance genes. At ICF 4 (inter-crossed F4) , three promising lines possessing the three target resistance genes in a homozygous condition along with fine-grain type, complete fertility restoration, and better panicle exsertion than RPHR-1005 have been identified. Among these, a single line, # RPIC-16-65-125, showed better yield, was highly resistant to BB and GM, was of medium–slender grain type, and had complete fertility restoration along with better panicle exsertion and taller plant type than RPHR-1005. This is the first report of combining resistance against BB and GM in the genetic background of a hybrid rice parental line.Department of Biotechnology (DBT), Government of India # BT/PR11705/AGR/02/646/200

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