1.
Genome-wide expression analysis of phospholipase A1 (PLA1) gene family suggests phospholipase A1-32 gene responding to abiotic stresses in cotton.
Zhang, H, Zhang, Y, Xu, N, Rui, C, Fan, Y, Wang, J, Han, M, Wang, Q, Sun, L, Chen, X, et al
International journal of biological macromolecules. 2021;:1058-1074
Abstract
Cotton is the most important crop for the production of natural fibres used in the textile industry. High salinity, drought, cold and high temperature represent serious abiotic stresses, which seriously threaten cotton production. Phospholipase AS has an irreplaceable role in lipid signal transmission, growth and development and stress events. Phospholipase A can be divided into three families: PLA1, PLA2 and pPLA. Among them, the PLA1 family is rarely studied in plants. In order to study the potential functions of the PLA1 family in cotton, the bioinformatics analysis of the PLA1 family was correlated with cotton adversity, and tissue-specific analysis was performed. Explore the structure-function relationship of PLA1 members. It is found that the expression of GbPLA1-32 gene is affected by a variety of environmental stimuli, indicating that it plays a very important role in stress and hormone response, and closely associates the cotton adversity with this family. Through further functional verification, we found that virus-induced GbPLA1-32 gene silencing (VIGS) caused Gossypium barbadense to be sensitive to salt stress. This research provides an important basis for further research on the molecular mechanism of cotton resistance to abiotic stress.
2.
Candidate reference genes for quantitative gene expression analysis in Lagerstroemia indica.
Chen, M, Wang, Q, Li, Y, Gao, L, Lv, F, Yang, R, Wang, P
Molecular biology reports. 2021;(2):1677-1685
Abstract
Quantitative gene expression analysis by qPCR requires reference genes for normalization. Lagerstroemia indica (crape myrtle) is a popular ornamental plant in the world, but suitable endogenous reference genes are lacking. To find suitable reference genes, we evaluated the stabilities of nine candidate genes in six experimental data sets: six different tissues, three leaf colors, nine flower colors, and under three abiotic stresses (salt, drought, cold) using four statistical algorithms. A target gene LiMYB56 (homolog of Arabidopsis MYB56) was used to verify the authenticity and accuracy of the candidate reference genes. The results showed that the combination of two stably expressed reference genes, rather than a single reference gene, improved the accuracy of the qPCR. LiEF1α-2 + LiEF1α-3 was best for the tissue, salt treatment, and drought treatment sets; LiEF1α-2 + LiEF1α-1 was optimal for leaf color; LiEF1α-2 + LiACT7 was optimal for cold treatment; and LiUBC + LiEF1α-1 was best for the flower color set. Notably, LiEF1α-2 had high expression stability in all six experimental sets, implying it may be a good reference gene for expression studies in L. indica. Our results will facilitate future gene expression studies in L. indica.
3.
The Arabidopsis Calcium-Dependent Protein Kinases (CDPKs) and Their Roles in Plant Growth Regulation and Abiotic Stress Responses.
Shi, S, Li, S, Asim, M, Mao, J, Xu, D, Ullah, Z, Liu, G, Wang, Q, Liu, H
International journal of molecular sciences. 2018;(7)
Abstract
As a ubiquitous secondary messenger in plant signaling systems, calcium ions (Ca2+) play essential roles in plant growth and development. Within the cellular signaling network, the accurate decoding of diverse Ca2+ signal is a fundamental molecular event. Calcium-dependent protein kinases (CDPKs), identified commonly in plants, are a kind of vital regulatory protein deciphering calcium signals triggered by various developmental and environmental stimuli. This review chiefly introduces Ca2+ distribution in plant cells, the classification of Arabidopsis thaliana CDPKs (AtCDPKs), the identification of the Ca2+-AtCDPK signal transduction mechanism and AtCDPKs’ functions involved in plant growth regulation and abiotic stress responses. The review presents a comprehensive overview of AtCDPKs and may contribute to the research of CDPKs in other plants.