Abstract
Drought is the one of the most important environment stresses that restricts crop yield worldwide. Cassava (Manihot esculenta Crantz) is an important food and energy crop that has many desirable traits such as drought, heat and low nutrients tolerance. However, the mechanisms underlying drought tolerance in cassava are unclear. Ethylene signaling pathway, from the upstream receptors to the downstream transcription factors, plays important roles in environmental stress responses during plant growth and development. In this study, we used bioinformatics approaches to identify and characterize candidate Manihot esculenta ethylene receptor genes and transcription factor genes. Using computational methods, we localized these genes on cassava chromosomes, constructed phylogenetic trees and identified stress-responsive cis-elements within their 5’ upstream regions. Additionally, we measured the trehalose and proline contents in cassava fresh leaves after drought, osmotic, and salt stress treatments, and then it was found that the regulation patterns of contents of proline and trehalose in response to various dehydration stresses were differential, or even the opposite, which shows that plant may take different coping strategies to deal with different stresses, when stresses come. Furthermore, expression profiles of these genes in different organs and tissues under non-stress and abiotic stress were investigated through quantitative real-time PCR (qRT-PCR) analyses in cassava. Expression profiles exhibited clear differences among different tissues under non-stress and various dehydration stress conditions. We found that the leaf and tuberous root tissues had the greatest and least responses, respectively, to drought stress through the ethylene signaling pathway in cassava. Moreover, tuber and root tissues had the greatest and least reponses to osmotic and salt stresses through ethylene signaling in cassava, respectively. These results show that these plant tissues had differential expression levels of genes involved in ethylene signaling in response to the stresses tested. Moreover, after several gene duplication events, the spatiotemporally differential expression pattern of homologous genes in response to abiotic and biotic stresses may imply their functional diversity as a mechanism for adapting to the environment. Our data provide a framework for further research on the molecular mechanisms of cassava resistance to drought stress and provide a foundation for breeding drought-resistant new cultivars.
Highlights
Drought is the one of the major environmental stresses which reduce yield and constrain crop production
Genes involved in ethylene transduction pathways play important roles in plant responses to stresses, they have not been fully investigated in cassava
To examine the phylogenetic relationships among ethylene receptors and transcription factors and group them within the established subfamilies, we constructed a phylogenetic tree from alignments of their amino acid sequences in cassava and Arabidopsis (Fig 1 and S2 Table)
Summary
Drought is the one of the major environmental stresses which reduce yield and constrain crop production. Cassava (Manihot esculenta Crantz) is a perennial crop native to tropical America [1, 2] that is widely cultivated for its tuberous roots (starchy storage roots) and is a staple food for humans and animals [3]. The high starch content makes cassava an excellent candidate for energy production [4,5,6]. Cassava ranks sixth in terms of global crop production. Cassava shares many traits in common with other tropical crops, such as high drought and heat tolerance, and reduced requirement for agricultural fertilizers. The mechanisms underlying drought tolerance in cassava remain unclear
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