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Physiological, molecular, and geneti...

Wani, Shabir H.

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Physiological, molecular, and genetic perspectives of wheat improvement

紀錄類型:	書目-電子資源 : Monograph/item
正題名/作者:	Physiological, molecular, and genetic perspectives of wheat improvement/ edited by Shabir H. Wani, Amita Mohan, Gyanendra Pratap Singh.
其他作者:	Wani, Shabir H.
出版者:	Cham :Springer International Publishing : : 2021.,
面頁冊數:	x, 293 p. :ill., digital ;24 cm.
內容註:	1. Food production: Global challenges to mitigate climate change -- 2. Reduced-immunogenicity wheat now coming to age -- 3. Wheat quality improvement for micronutrients -- 4. Changing Nutrition Scenario: Color wheat- a new perspective -- 5. Genetics and Breeding of Fe and Zn improvement in wheat -- 6. Membrane Fluidity and Compositional Changes in Response to High Temperature Stress in Wheat -- 7. Current understanding of thermo-tolerance in Wheat -- 8. Advances in molecular markers and their use in genetic improvement of wheat -- 9. Genomic selection for wheat improvement -- 10. Genetic Dissection for Yield and Yield Related Traits in Bread Wheat (Triticum aestium L.) -- 11. Marker-assisted breeding for resistance against wheat rusts -- 12. Genome Editing and Trait Improvement in Wheat.
Contained By:	Springer Nature eBook
標題:	Wheat - Breeding. -
電子資源:	https://doi.org/10.1007/978-3-030-59577-7
ISBN:	9783030595777

Physiological, molecular, and genetic perspectives of wheat improvement
Physiological, molecular, and genetic perspectives of wheat improvement[electronic resource] /edited by Shabir H. Wani, Amita Mohan, Gyanendra Pratap Singh. - Cham :Springer International Publishing :2021. - x, 293 p. :ill., digital ;24 cm.

1. Food production: Global challenges to mitigate climate change -- 2. Reduced-immunogenicity wheat now coming to age -- 3. Wheat quality improvement for micronutrients -- 4. Changing Nutrition Scenario: Color wheat- a new perspective -- 5. Genetics and Breeding of Fe and Zn improvement in wheat -- 6. Membrane Fluidity and Compositional Changes in Response to High Temperature Stress in Wheat -- 7. Current understanding of thermo-tolerance in Wheat -- 8. Advances in molecular markers and their use in genetic improvement of wheat -- 9. Genomic selection for wheat improvement -- 10. Genetic Dissection for Yield and Yield Related Traits in Bread Wheat (Triticum aestium L.) -- 11. Marker-assisted breeding for resistance against wheat rusts -- 12. Genome Editing and Trait Improvement in Wheat.

World population is growing at an alarming rate and may exceed 9.7 billion by 2050, whereas agricultural productivity has been negatively affected due to yield limiting factors such as biotic and abiotic stresses as a result of global climate change. Wheat is a staple crop for ~20% of the world population and its yield needs be augmented correspondingly in order to satisfy the demands of our increasing world population. "Green revolution", the introduction of semi-dwarf, high yielding wheat varieties along with improved agronomic management practices, gave rise to a substantial increase in wheat production and self-sufficiency in developing countries that include Mexico, India and other south Asian countries. Since the late 1980's, however, wheat yield is at a standoff with little fluctuation. The current trend is thus insufficient to meet the demands of an increasing world population. Therefore, while conventional breeding has had a great impact on wheat yield, with climate change becoming a reality, newer molecular breeding and management tools are needed to meet the goal of improving wheat yield for the future. With the advance in our understanding of the wheat genome and more importantly, the role of environmental interactions on productivity, the idea of genomic selection has been proposed to select for multi-genic quantitative traits early in the breeding cycle. Accordingly genomic selection may remodel wheat breeding with gain that is predicted to be 3 to 5 times that of crossbreeding. Phenomics (high-throughput phenotyping) is another fairly recent advancement using contemporary sensors for wheat germplasm screening and as a selection tool. Lastly, CRISPR/Cas9 ribonucleoprotein mediated genome editing technology has been successfully utilized for efficient and specific genome editing of hexaploid bread wheat. In summary, there has been exciting progresses in the development of non-GM wheat plants resistant to biotic and abiotic stress and/or wheat with improved nutritional quality. We believe it is important to highlight these novel research accomplishments for a broader audience, with the hope that our readers will ultimately adopt these powerful technologies for crops improvement in order to meet the demands of an expanding world population.

ISBN: 9783030595777

Standard No.: 10.1007/978-3-030-59577-7doiSubjects--Topical Terms:

2059076
Wheat
--Breeding.

LC Class. No.: SB191.W5

Dewey Class. No.: 633.112

Physiological, molecular, and genetic perspectives of wheat improvement
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520 $a World population is growing at an alarming rate and may exceed 9.7 billion by 2050, whereas agricultural productivity has been negatively affected due to yield limiting factors such as biotic and abiotic stresses as a result of global climate change. Wheat is a staple crop for ~20% of the world population and its yield needs be augmented correspondingly in order to satisfy the demands of our increasing world population. "Green revolution", the introduction of semi-dwarf, high yielding wheat varieties along with improved agronomic management practices, gave rise to a substantial increase in wheat production and self-sufficiency in developing countries that include Mexico, India and other south Asian countries. Since the late 1980's, however, wheat yield is at a standoff with little fluctuation. The current trend is thus insufficient to meet the demands of an increasing world population. Therefore, while conventional breeding has had a great impact on wheat yield, with climate change becoming a reality, newer molecular breeding and management tools are needed to meet the goal of improving wheat yield for the future. With the advance in our understanding of the wheat genome and more importantly, the role of environmental interactions on productivity, the idea of genomic selection has been proposed to select for multi-genic quantitative traits early in the breeding cycle. Accordingly genomic selection may remodel wheat breeding with gain that is predicted to be 3 to 5 times that of crossbreeding. Phenomics (high-throughput phenotyping) is another fairly recent advancement using contemporary sensors for wheat germplasm screening and as a selection tool. Lastly, CRISPR/Cas9 ribonucleoprotein mediated genome editing technology has been successfully utilized for efficient and specific genome editing of hexaploid bread wheat. In summary, there has been exciting progresses in the development of non-GM wheat plants resistant to biotic and abiotic stress and/or wheat with improved nutritional quality. We believe it is important to highlight these novel research accomplishments for a broader audience, with the hope that our readers will ultimately adopt these powerful technologies for crops improvement in order to meet the demands of an expanding world population.
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