000 04976naaaa2201249uu 4500
001 https://directory.doabooks.org/handle/20.500.12854/56328
005 20220219201000.0
020 _abooks978-3-03928-127-5
020 _a9783039281275
020 _a9783039281268
024 7 _a10.3390/books978-3-03928-127-5
_cdoi
041 0 _aEnglish
042 _adc
100 1 _aFrugis, Giovanna
_4auth
245 1 0 _aPlant Development and Organogenesis: From Basic Principles to Applied Research
260 _bMDPI - Multidisciplinary Digital Publishing Institute
_c2020
300 _a1 electronic resource (246 p.)
506 0 _aOpen Access
_2star
_fUnrestricted online access
520 _aThe way plants grow and develop organs significantly impacts the overall performance and yield of crop plants. The basic knowledge now available in plant development has the potential to help breeders in generating plants with defined architectural features to improve productivity. Plant translational research effort has steadily increased over the last decade due to the huge increase in the availability of crop genomic resources and Arabidopsis-based sequence annotation systems. However, a consistent gap between fundamental and applied science has yet to be filled. One critical point often brought up is the unreadiness of developmental biologists on one side to foresee agricultural applications for their discoveries, and of the breeders to exploit gene function studies to apply to candidate gene approaches when advantageous on the other. In this book, both developmental biologists and breeders make a special effort to reconcile research on the basic principles of plant development and organogenesis with its applications to crop production and genetic improvement. Fundamental and applied science contributions intertwine and chase each other, giving the reader different but complementary perspectives from only apparently distant corners of the same world.
540 _aCreative Commons
_fhttps://creativecommons.org/licenses/by-nc-nd/4.0/
_2cc
_4https://creativecommons.org/licenses/by-nc-nd/4.0/
546 _aEnglish
653 _aHD-Zip transcription factors
653 _aPlant in vitro cultures
653 _aplant breeding
653 _arecalcitrant species
653 _aCLV
653 _awounding
653 _asemi-dwarf
653 _aphotoreceptors
653 _aArabidopsis thaliana
653 _aroot development
653 _amorphogenesis
653 _aembryogenesis
653 _acytokinin
653 _aauxin conjugation
653 _amolecular marker
653 _aDevelopment
653 _aboundaries
653 _atranslational research
653 _aproline biosynthesis
653 _aBrassicaceae
653 _ameristem formation
653 _aphytohormones
653 _astem cells
653 _ameristem
653 _acytoskeleton
653 _ahydrogen peroxide
653 _aligule
653 _agenetic improvement
653 _atree phase change
653 _aRht18
653 _ahairy roots
653 _aWUS
653 _aGRETCHEN HAGEN 3 (GH3) IAA-amido synthase group II
653 _aphotoperiod
653 _alinkage map
653 _aSAM
653 _aground tissue
653 _asignaling
653 _adifferentiation
653 _aprotoxylem
653 _aambient temperature
653 _agibberellins
653 _amolecular regulation
653 _aproximodistal patterning
653 _awheat-rye hybrids
653 _aRolD
653 _asomatic cell selection
653 _aflowering time
653 _aplant development and organogenesis
653 _agrass
653 _aroot
653 _awheat
653 _acrop productivity
653 _agenetic transformation
653 _aregulatory networks
653 _alight environment
653 _arol genes
653 _aroot plasticity
653 _amorphogenic
653 _astem apical meristem
653 _aauxin
653 _ashoot meristem
653 _aArabidopsis
653 _aorganogenesis
653 _atransformation
653 _aVasculature
653 _aOrganogenesis
653 _aradial patterning
653 _aplant development
653 _areduced height
653 _aroot apical meristem
653 _aAsteraceae
653 _avernalization
653 _aKNOX transcription factors
653 _alocule
653 _aplant cell and tissue culture
653 _aAgrobacterium rhizogenes
653 _agenes of reproductive isolation
653 _acell wall
653 _alateral root cap
653 _aCLE
653 _aauxin minimum
653 _aage
856 4 0 _awww.oapen.org
_uhttps://www.mdpi.com/books/pdfview/book/1979
_70
_zDOAB: download the publication
856 4 0 _awww.oapen.org
_uhttps://directory.doabooks.org/handle/20.500.12854/56328
_70
_zDOAB: description of the publication
999 _c40807
_d40807