LEADER 06811nam  2202137z- 450 
001 9910346666103321
005 20231214133559.0
010   $a3-03921-063-7
035   $a(CKB)4920000000095006
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/56353
035   $a(EXLCZ)994920000000095006
100   $a20202102d2019      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aPlant Proteomic Research 2.0
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2019
215   $a1 electronic resource (594 p.)
311   $a3-03921-062-9 
330   $aAdvancements in high-throughput ?Omics? techniques have revolutionized plant molecular biology research. Proteomics offers one of the best options for the functional analysis of translated regions of the genome, generating a wealth of detailed information regarding the intrinsic mechanisms of plant stress responses. Various proteomic approaches are being exploited extensively for elucidating master regulator proteins which play key roles in stress perception and signaling, and these approaches largely involve gel-based and gel-free techniques, including both label-based and label-free protein quantification. Furthermore, post-translational modifications, subcellular localization, and protein?protein interactions provide deeper insight into protein molecular function. Their diverse applications contribute to the revelation of new insights into plant molecular responses to various biotic and abiotic stressors.
610   $a14-3-3 proteins
610   $atargeted two-dimensional electrophoresis
610   $asomatic embryogenesis
610   $anitrogen metabolism
610   $asubtilase
610   $aSporisorium scitamineum
610   $anon-orthodox seed
610   $aantioxidant activity
610   $asweet potato plants infected by SPFMV
610   $aphotosynthesis
610   $aB. acuminata petals
610   $achlorophyll deficiency
610   $aseed proteomics
610   $aimbibition
610   $apollination
610   $aSarpo Mira
610   $aqRT-PCR
610   $aholm oak
610   $atuber phosphoproteome
610   $aisobaric tags for relative and absolute quantitation (iTRAQ)
610   $aQuercus ilex
610   $anucleotide pyrophosphatase/phosphodiesterase
610   $alettuce
610   $a?-subunit
610   $aprotein phosphatase
610   $agermination
610   $adrought stress
610   $apyruvate biosynthesis
610   $aweakening of carbon metabolism
610   $adifferential proteins
610   $aheterotrimeric G protein
610   $aorgan
610   $aLC-MS-based proteomics
610   $apotato proteomics
610   $asmut
610   $agel-free/label-free proteomics
610   $a? subunit
610   $ashotgun proteomics
610   $a2D
610   $achloroplast
610   $aproteome functional annotation
610   $aPhalaenopsis
610   $aClematis terniflora DC.
610   $awheat
610   $aDn1-1
610   $acarbon metabolism
610   $aphysiological responses
610   $aZea mays
610   $aphenylpropanoid biosynthesis
610   $aISR
610   $amass spectrometric analysis
610   $apatatin
610   $aleaf
610   $apea (Pisum sativum L.)
610   $amaize
610   $aergosterol
610   $aCamellia sinensis
610   $aseed storage proteins
610   $asilver nanoparticles
610   $aelevated CO2
610   $ametacaspase
610   $aSPV2 and SPVG
610   $aSnRK1
610   $aMALDI-TOF/TOF
610   $a(phospho)-proteomics
610   $aleaf spot
610   $arice isogenic line
610   $awheat leaf rust
610   $apathway analysis
610   $aphosphoproteome
610   $asugarcane
610   $asenescence
610   $aOryza sativa L.
610   $aArabidopsis thaliana
610   $aheat stress
610   $agene ontology
610   $ainnate immunity
610   $aPseudomonas syringae
610   $abolting
610   $achlorophylls
610   $ashoot
610   $aSimmondsia chinensis
610   $aRT-qPCR
610   $astresses responses
610   $aSolanum tuberosum
610   $aseeds
610   $aGC-TOF-MS
610   $asucrose
610   $aproteome
610   $aPuccinia recondita
610   $acultivar
610   $aZea mays L.
610   $asecondary metabolism
610   $aROS
610   $aRicinus communis L.
610   $aafter-ripening
610   $acadmium
610   $aStagonospora nodorum
610   $avirus induced gene silencing
610   $aquantitative proteomics
610   $asweet potato plants non-infected by SPFMV
610   $aaffinity chromatography
610   $apopulation variability
610   $aGS3
610   $afungal perception
610   $aammonium
610   $atranscriptome profiling
610   $amass spectrometry analysis
610   $apapain-like cysteine protease (PLCP)
610   $acold stress
610   $anitrate
610   $alate blight disease
610   $aearly and late disease stages
610   $aseed imbibition
610   $alesion mimic mutant
610   $aprotease
610   $aproteome map
610   $aseed dormancy
610   $apetal
610   $a2-DE proteomics
610   $a2D DIGE
610   $aroot
610   $aPhytophthora infestans
610   $adifferentially abundant proteins (DAPs)
610   $apolyphenol oxidase
610   $adegradome
610   $aflavonoid
610   $a14-3-3
610   $acaspase-like
610   $aproteomics
610   $aRGG4
610   $aco-infection
610   $aplasma membrane
610   $achlorotic mutation
610   $aMedicago sativa
610   $aRGG3
610   $aglycolysis
610   $abarley
610   $a2-DE
610   $aprotein phosphorylation
610   $awestern blotting
610   $aN utilization efficiency
610   $arice
610   $aplant pathogenesis responses
610   $ahigh temperature
610   $adata-independent acquisition
610   $apattern recognition receptors
610   $avegetative storage proteins
610   $aleaf cell wall proteome
610   $aplant-derived smoke
610   $aiTRAQ
610   $astarch
610   $aproteome profiling
610   $aMorus
700   $aKomatsu$b Setsuko$4auth$01284061
906   $aBOOK
912   $a9910346666103321
996   $aPlant Proteomic Research 2.0$93019248
997   $aUNINA