000			07360naaaa2201909uu 4500
001			https://directory.doabooks.org/handle/20.500.12854/76453
005			20220220103003.0
020			_abooks978-3-0365-1441-3
020			_a9783036514420
020			_a9783036514413
024	7		_a10.3390/books978-3-0365-1441-3 _cdoi
041	0		_aEnglish
042			_adc
072		7	_aGP _2bicssc
100	1		_aKhan, Naeem _4edt
700	1		_aKhan, Naeem _4oth
245	1	0	_aApplication of Plant Growth Promoting Microorganism and Plant Growth Regulators in Agricultural Production and Research
260			_aBasel, Switzerland _bMDPI - Multidisciplinary Digital Publishing Institute _c2021
300			_a1 electronic resource (470 p.)
506	0		_aOpen Access _2star _fUnrestricted online access
520			_aPlant growth-promoting microorganisms (PGPM) are groups of rhizosphere microorganisms capable of colonizing the root environment. Some of the microbes that inhabit this zone are bacteria and fungi that are capable of efficiently colonizing roots and rhizosphere soil. These microorganisms can be used as biofertilizers for improving agricultural production even under stressful environmental conditions. In contrast to PGPM, plant growth regulators (PGR) are chemical compounds that significantly affect the growth and differentiation of plant cells and tissues. They function as chemical messengers for intercellular communication and play a vital role in plant signaling networks as they are involved in the plant developmental process and a wide range of biotic and abiotic stress responses. The application of PGPM and plant growth regulators/hormones or the synthesis of PGR and signal transduction, perception, and cross-talk creates a complex network that plays an essential role in the regulation of plant physiological processes. A better understanding of the mechanism of action of PGPM and PGR and their roles in plant growth and development, interaction and independence in their action, and hormonal crosstalk under stresses is essential for agricultural production and research. Therefore, this book has contributions in the form of research and review papers from eminent scientists worldwide and discusses the role of PGPM and PGR in agriculture production and research, their potentials as biocontrol agents, their effects on physicochemical properties of soil, innovation for sustainable agriculture, their role in seed transplanting, and their role in mitigating biotic and abiotic stresses.
540			_aCreative Commons _fhttps://creativecommons.org/licenses/by/4.0/ _2cc _4https://creativecommons.org/licenses/by/4.0/
546			_aEnglish
650		7	_aResearch & information: general _2bicssc
653			_aPaecilomyces
653			_aPGPF
653			_atomato
653			_apepper
653			_aplant probiotic microorganisms
653			_aSpodoptera litura (Fabricius) (Lepidoptera: Noctuidae)
653			_aSolanum lycopersicum L.
653			_asecondary metabolites
653			_aplant insect interactions
653			_aseaweed extract
653			_aphytohormone profiling
653			_afertilizers
653			_aantioxidant
653			_aplant growth regulators
653			_abrown seaweed
653			_agreen algae
653			_aabiotic stresses
653			_acell membrane stability
653			_aclimate change
653			_aosmolytes
653			_apolyamines
653			_abacterial community composition
653			_aliquid food waste materials (LFM)
653			_aplant growth-promoting bacteria (PGPB)
653			_aplant growth-promoting (PGP) traits
653			_asalinity
653			_aPGPR
653			_awheat
653			_acompatible solutes
653			_aantioxidant enzymes
653			_aTrichoderma
653			_aplant growth promotion
653			_abiostimulant
653			_aaridity
653			_aBacillus sp.
653			_abiochar
653			_anutrient availability
653			_aorganic matter
653			_asoil health
653			_amVOCs
653			_aPlant growth promoting rhizobacteria
653			_aMentha piperita
653			_aBacillus amyloliquefaciens GB03
653			_asalt stress
653			_aMDA
653			_aDPPH
653			_aBradyrhizobium japonicum
653			_aPseudomonas putida
653			_aplant growth
653			_aplant nutrients
653			_asoil enzymes
653			_asoil nutrients
653			_asoybean
653			_asweet pepper
653			_aBacillus
653			_achitosan
653			_achlorophyll fluorescence
653			_afruit yield
653			_aplant growth promoting microorganisms
653			_aabiotic stress
653			_abiotic stress
653			_aflavonoids
653			_abiotic and abiotic stress
653			_asymbiosis
653			_asignaling
653			_arhizobium
653			_aAMF
653			_aallelopathy
653			_abiocontrol Aspergillus japonicus
653			_aroot-knot nematode
653			_afermentation filtrate
653			_abiological control
653			_aseed germination
653			_aα-Tocopherol
653			_aantioxidants
653			_adrought
653			_anutrient dynamics
653			_atissue specific response
653			_adeep N fertilization
653			_aperoxidase activity
653			_acatalase activity
653			_arice cultivation
653			_aABA biosynthesis
653			_adrought stress
653			_agene expression
653			_asignaling network
653			_atransporters
653			_aZea mays L.
653			_aenvironmental stresses
653			_aendophytic bacteria
653			_aplant growth promoting ability
653			_achromium
653			_aStaphylococcus aureus
653			_aoxidative stress
653			_aavailable phosphorus
653			_aenriched compost
653			_apoultry litter
653			_arock phosphate
653			_apear trees
653			_aPGR
653			_asustainable development
653			_acrop nutrition
653			_afertiliser
653			_aTimac Agro Italia
653			_aallelopathic bacteria
653			_aantimetabolites
653			_aphytotoxic metabolites
653			_arhizobacteria
653			_aweed invasion
653			_aanthocyanins
653			_acolor
653			_afruit size
653			_aphenolics
653			_aPunica granatum
653			_aPGPMs (plant growth-promoting microorganisms)
653			_atee tree oil
653			_aplant biostimulants
653			_asoil-borne phytopathogens
653			_aantagonistic fungi
653			_abiocontrol
653			_abiotic effect
653			_acrop production
653			_aRIDER
653			_adrylands
653			_awater conservation
653			_abiomass reduction
653			_acereal crops
653			_agrowth regulators
653			_ametal stress
653			_asugar beet
653			_anitrogen fertilizer
653			_agibberellic acid
653			_aTSS
653			_asugar yield
653			_an/a
856	4	0	_awww.oapen.org _uhttps://mdpi.com/books/pdfview/book/3889 _70 _zDOAB: download the publication
856	4	0	_awww.oapen.org _uhttps://directory.doabooks.org/handle/20.500.12854/76453 _70 _zDOAB: description of the publication
999			_c81402 _d81402