Titlebook: Genomic Designing for Biotic Stress Resistant Technical Crops; Chittaranjan Kole Book 2022 The Editor(s) (if applicable) and The Author(s)

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Food Engineering — From Arts to Science(. L.). Production of premium silk in the sericulture industry is directly associated with quality mulberry leaves production. However, mulberry is affected by various pathogens and pests like fungi, bacteria, virus, nematodes and cause considerable crop loss. Mulberry genetic improvement through tr

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冰河期

Pluralism and Pressure Politicses and parasitic weeds infect tobacco from seedling stage to leaf harvest and during post-harvest leaf management there-by severely affecting its leaf yield and quality. Development and deployment of host plant resistance is a sustainable option to minimize these losses. A number of varieties resist

流利圓滑

E. K. Pathan,S. G. Tupe,M. V. Deshpande.) and abiotic stresses (drought, low soil fertility, etc.) substantially impact the productivity and quality of yam crop in regions where it is majorly cultivated. Developing and deploying resilient cultivars is a cost-effective and environmentally sound approach to enhance productivity in stressfu

吊胃口

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綠州

Genomic Designing for Biotic Stress Resistant Cocoa Tree,lecular and omics resources currently available, and of the new biotechnology approaches—including genome edition and nanotechnologies—that are used at basic and applied research levels. We also described the main germplasm and collections worldwide as well as the use of the cocoa diversity as main source of disease resistance.

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p improvement of 13 important technical crops and 2 technica.Biotic stresses cause yield loss of 31-42% in crops in addition to 6-20% during post-harvest stage. Understanding interaction of crop plants to the biotic stresses caused by insects, bacteria, fungi, viruses, and? oomycetes, etc. is import

Myelin

Bodhaswar TJ Maharaj,Babatunde Seun Awoyemig to genomic selections and other new breeding technologies such as genetic engineering and genome editing. This chapter outlines the most significant biotic stresses in cassava, their prevalence, and impact on yield as well as different technologies being utilized towards the development of biotic stress-resistant cassava.

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Genomic Designing for Biotic Stress Resistant Cassava,g to genomic selections and other new breeding technologies such as genetic engineering and genome editing. This chapter outlines the most significant biotic stresses in cassava, their prevalence, and impact on yield as well as different technologies being utilized towards the development of biotic stress-resistant cassava.