LEADER 04896nam 2201117z- 450 001 9910566469203321 005 20220506 035 $a(CKB)5680000000037688 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/81107 035 $a(oapen)doab81107 035 $a(EXLCZ)995680000000037688 100 $a20202205d2022 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aUnraveling the Mechanisms of Zn Efficiency in Crop Plants: From Lab to Field Applications 210 $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022 215 $a1 online resource (192 p.) 311 08$a3-0365-3427-X 311 08$a3-0365-3428-8 330 $aMany agricultural crops worldwide suffer from zinc (Zn) deficiency. Despite widespread interest in Zn, plant professionals often lack current information on this indispensable essential mineral nutrient. G. Hacisalihoglu, PhD, in Unraveling the Mechanisms of Zinc Efficiency in Crop Plants, and a host of recognized experts address this gap with the up-to-date importance of Zn nutrition. This book examines research aimed at understanding how plants uptake and utilize Zn. It has been peer-reviewed and multi-authored by expert plant biology scientists with related expertise. The editor provides a comprehensive overview of zinc (Zn) nutrition in plants, seeds, roots, and soil, which renders this book a good reference for plant biology professionals. Agricultural sustainability in the time of the growing world population will be one of the major challenges in the next 30 plus years. Zn is one of the most important essential mineral nutrients required for metabolic processes, so a shortage of Zn constrains crop yield and quality worldwide. Zinc efficiency and higher growth and yield under low Zn supply make it a promising sustainable solution for developing cultivars that are zinc efficient. Several articles are included in this book that provide an overview of current developments and trends in the times of high-throughput genomics and phenomics data analysis. Furthermore, this book presents research findings in various experimental models and areas ranging from maize to alfalfa, flax, and sorghum.Unraveling the Mechanisms of Zinc Efficiency in Crop Plants is a must read for researchers and plant biology professionals. 517 $aUnraveling the Mechanisms of Zn Efficiency in Crop Plants 606 $aBiology, life sciences$2bicssc 606 $aResearch & information: general$2bicssc 606 $aTechnology, engineering, agriculture$2bicssc 610 $a65Zn 610 $aAdsorption 610 $abarley 610 $abiofortification 610 $abioindication 610 $abryophytes 610 $acell shape 610 $acereal 610 $acrops 610 $adesorption 610 $aelevated CO2 610 $afood security 610 $aforage yield 610 $aforms 610 $afunctional genomics 610 $agluten free 610 $ahealth benefits 610 $aheavy metal transporters (HMA) 610 $ahomeostasis 610 $ahormonal regulation 610 $airon 610 $aisotherm 610 $alabile zinc pool 610 $alability 610 $alandscape position 610 $amaize 610 $amalnutrition 610 $ametal tolerance protein (MTP) 610 $amicronutrients 610 $amoss 610 $amulti minerals 610 $an/a 610 $anicotianamine 610 $anutrient dense 610 $anutrient uptake 610 $aparticulate matter 610 $apercent daily value 610 $aphotosynthesis 610 $aplant available Zn 610 $aplant nutrition 610 $apotential buffer capacity 610 $arainfed conditions 610 $aseed quality 610 $asilicon 610 $asodium selenate 610 $asoil 610 $asoil solution 610 $aspecific activity 610 $astaple foods 610 $asuperfood 610 $asustainability 610 $ayellow stripe-like protein (YSL) 610 $azinc 610 $azinc efficiency 610 $azinc sulfate 610 $azinc-induced facilitators (ZIF) 610 $aZIP transporters 610 $aZn re-fertilization 610 $aZn-deficiency 610 $aZn-sufficiency 615 7$aBiology, life sciences 615 7$aResearch & information: general 615 7$aTechnology, engineering, agriculture 700 $aHacisalihoglu$b Gokhan$4edt$01280992 702 $aHacisalihoglu$b Gokhan$4oth 906 $aBOOK 912 $a9910566469203321 996 $aUnraveling the Mechanisms of Zn Efficiency in Crop Plants: From Lab to Field Applications$93017803 997 $aUNINA