In the last century, climate changes have become a major concern for scientists, where global Climatic change factors threaten plant growth and crop production, affecting sustainable agriculture. It is predicted that climate change will increase the occurrence and intensity of abiotic stress impact on plants and cause a severe threat to crop yield and sustainable agriculture. Although several studies at the omics levels have been done to discover the mechanism of plant response to destructive stresses, the mechanism of plant resistance to environmental stress is still not clearly understood. Plants respond to the effect of changes in climate by modulating the regulations of specific genes and metabolic pathways through several steps during plant growth, development, and reproduction. Plants produce a vast array of metabolites and regulate thousands of genes with up and down regulations that affect plant growth and development and plant rejoinders to stress. This call has been directed at understanding the relation between the plants' phenotype and genotype in response to environmental stresses using the integration of functional genomics with other omics applications. In this call, we aim to answer how plants modulate their genome, metabolome, and proteome structure to cope with destructive stresses.
Researchers are invited to submit their manuscripts discussing the integration of multi-omics to understand the plant complex traits regulations under destructive stresses. The outcome of this research topic could be used for future crop improvements to cope with climatic changes.
We welcome article submissions that contain the following scientific themes on omics-based plant traits improvements
1. Novel Plant genome, transcriptome, metabolome, and proteome that provide the pathways lead to understanding the mechanism of response to destructive stresses.
2. Functional characterization studies of the stress-responsive genes that lead to improving the plant traits under destructive stresses
3. Plant diversity and genomics, metabolomics, transcriptomics, and proteomics using data analysis methods
4. Comparative analysis of conventional plant diversity, and plant breeding using omics approaches.
5. Omics related traits such as genome-traits, proteome-traits, transcriptome-traits, and metabolome- traits.
In the last century, climate changes have become a major concern for scientists, where global Climatic change factors threaten plant growth and crop production, affecting sustainable agriculture. It is predicted that climate change will increase the occurrence and intensity of abiotic stress impact on plants and cause a severe threat to crop yield and sustainable agriculture. Although several studies at the omics levels have been done to discover the mechanism of plant response to destructive stresses, the mechanism of plant resistance to environmental stress is still not clearly understood. Plants respond to the effect of changes in climate by modulating the regulations of specific genes and metabolic pathways through several steps during plant growth, development, and reproduction. Plants produce a vast array of metabolites and regulate thousands of genes with up and down regulations that affect plant growth and development and plant rejoinders to stress. This call has been directed at understanding the relation between the plants' phenotype and genotype in response to environmental stresses using the integration of functional genomics with other omics applications. In this call, we aim to answer how plants modulate their genome, metabolome, and proteome structure to cope with destructive stresses.
Researchers are invited to submit their manuscripts discussing the integration of multi-omics to understand the plant complex traits regulations under destructive stresses. The outcome of this research topic could be used for future crop improvements to cope with climatic changes.
We welcome article submissions that contain the following scientific themes on omics-based plant traits improvements
1. Novel Plant genome, transcriptome, metabolome, and proteome that provide the pathways lead to understanding the mechanism of response to destructive stresses.
2. Functional characterization studies of the stress-responsive genes that lead to improving the plant traits under destructive stresses
3. Plant diversity and genomics, metabolomics, transcriptomics, and proteomics using data analysis methods
4. Comparative analysis of conventional plant diversity, and plant breeding using omics approaches.
5. Omics related traits such as genome-traits, proteome-traits, transcriptome-traits, and metabolome- traits.