Reprint
Plant Protein and Proteome Altlas--Integrated Omics Analyses of Plants under Abiotic Stresses
Edited by
May 2020
558 pages
- ISBN978-3-03921-960-5 (Paperback)
- ISBN978-3-03921-961-2 (PDF)
This book is a reprint of the Special Issue Plant Protein and Proteome Altlas--Integrated Omics Analyses of Plants under Abiotic Stresses that was published in
Biology & Life Sciences
Chemistry & Materials Science
Medicine & Pharmacology
Summary
Integrative omics of plants in response to stress conditions play more crucial roles in the post-genomic era. High-quality genomic data provide more deeper understanding of how plants to survive under environmental stresses. This book is focused on concluding the recent progress in the Protein and Proteome Atlas in plants under different stresses. It covers various aspects of plant protein ranging from agricultural proteomics, structure and function of proteins, and approaches for protein identification and quantification. A total of 27 papers including two timely reviews have contributed to this Special Issue. In the first part with the topic of “Comparative Proteomics of Different Plants”, six papers were included to describe the phenotypic changes and proteomic analyses of different plants under different conditions. Then, another six papers with the topic of “Proteomics of Plants under Osmotic Stress” were included to describe the recent comparative proteomics analyses of plants under osmotic stress, particularly the drought and salinity stresses in leaves of certain plant species. The other proteomics studies on several energy plants and economic crops were reported to demonstrate the recent omics studies on different plants during their development processes. More stress responsive genes and proteins in these plants were identified. These target genes and proteins are important candidates for further functional validation in economic plants and crops.
Format
- Paperback
License
© 2020 by the authors; CC BY-NC-ND license
Keywords
proteomic; postharvest freshness; ATP synthase; ATP synthase CF1 alpha subunit (chloroplast); chlorophyll fluorescence parameters; photosynthetic parameters; drought stress; Triticum aestivum L.; comparative proteomic analysis; iTRAQ; VIGS; Jatropha curcas; phosphoproteomics; seedling; chilling stress; regulated mechanism; Alternanthera philoxeroides; proteomic; stem; potassium; stress; Salinity stress; Dunaliella salina; isobaric tags for relative and absolute quantitation; differentially abundant proteins; proteomics; arbuscular mycorrhizal fungi; salt stress; E. angustifolia; proteomics; wheat; root; wood vinegar; drought stress; ROS; ABA; proteome; maize; AGPase; phosphorylation; brittle-2; phos-tagTM; MIPS; exon-intron structure diversity; Gossypium hirsutum; loss-of-function mutant; root cell elongation; CHA-SQ-1; cytomorphology; pollen abortion; proteomics; wheat; cotton; somatic embryogenesis; transdifferentiation; quantitative proteomics; regulation and metabolism; molecular basis; concerted network; maize; phosphoproteomics; salt tolerance; label-free quantification; root and shoot; sugar beet; salt stress; S-adenosylmethionine decarboxylase; ROS; antioxidant enzyme; cotton; somatic embryogenesis; transdifferentiation; widely targeted metabolomics; purine metabolism; flavonoid biosynthesis; molecular and biochemical basis; transcript-metabolite network; leaf sheath; maturation; transcriptional dynamics; transcriptome; abiotic stress; silicate limitation; diatom; iTRAQ; proteomics; photosynthesis; carbon fixation; natural rubber biosynthesis; mass spectrometry; rubber grass; rubber latex; shotgun proteomics; Taraxacum kok-saghyz; two-dimensional gel electrophoresis; visual proteome map; proteomics; wheat; drought; leaf; iTRAQ; micro-exons; constitutive splicing; alternative splicing; ancient genes; domain; radish; heat stress; transcriptome sequencing; lncRNA; miRNA; physiological response; Millettia pinnata; woody oilseed plants; seed development; miRNA; nitrogen fertilizer; rice; proteome; cultivars; nitrogen use efficiency (NUE); Nelumbo nucifera; phylogeny; genomics; molecular mechanisms; model plant; proteomes; iTRAQ; filling kernel; drought stress; heat shock proteins; Zea mays L.; wucai; low-temperature stress; high-temperature stress; proteomics; redox homeostasis; GLU1; glutathione; heat response; heat-sensitive spinach variety; proteomics; ROS scavenging; inositol; phosphatidylinositol; phosphatase; stress; signaling pathway; integrated omics; plants under stress; post-genomics era; proteome atlas; quantitative proteomics