MicroRNAs (miRNAs) are small molecule RNAs widely involved in responses to plant abiotic stresses. We performed small RNA sequencing of cotton anthers at four developmental stages under normal and high temperature (NT and HT, respectively) conditions to investigate the stress response characteristics of miRNA to HT. A total of 77 miRNAs, including 33 known miRNAs and 44 novel miRNAs, were identified, and 41 and 28 miRNAs were differentially expressed under NT and HT stress conditions, respectively. The sporogenous cell proliferation (SCP), meiotic phase (MP), microspore release period (MRP), and pollen maturity (PM) stages had 10 (including 12 miRNAs), four (including six miRNAs), four (including five miRNAs), and seven (including 11 miRNAs) HT stress-responsive miRNA families, respectively, which were identified after removing the changes in genotype-specific miRNAs under NT condition. Seven miRNA families (miR2949, miR167, and miR160 at the SCP stage; miR156 and miR172 at the MP stage; miR156 at the MRP stage; and miR393 and miR3476 at the PM stage), which had expression abundance of more than 10% of the total expression abundance, served as the main regulators responding to HT stress with positive or negative regulation patterns. These miRNAs orchestrated the expression of the corresponding target genes and led to different responses in the HT-tolerant and the HT-sensitive lines. The results revealed that the HT stress response of miRNAs in cotton anthers were stage-specific and differed with the development of anthers. Our study may enhance the understanding of the response of miRNAs to HT stress in cotton anthers and may clarify the mechanism of plant tolerance to HT stress.
We have shown that Leishmania lipophosphoglycan (LPG) inhibits IL-1 beta gene expression in human monocytes. Here, we show that LPG can bind in a time-dependent manner and suppress endothelial cell activation, possibly via specific LPG domains. Endotoxin (10 ng/ml, 4 h) consistently caused endothelium to increase monocyte adhesion (approximately 20-fold). LPG pretreatment (2 microM, 2 h) completely blocked endotoxin-mediated monocyte adhesion. LPG did not grossly suppress endothelial functions because TNF-alpha- and IL-1 beta-mediated adhesion toward monocytes were not affected. Using four highly purified LPG fragments (namely, repeating phosphodisaccharide (PGM), phosphoglycan, phosphosaccharide core-lyso-alkyl-phosphatidylinositol (core-PI), and lyso-alkyl-phosphatidylinositol (lyso-PI)), we examined whether these fragments can independently inhibit endothelial adhesion. In contrast to that of intact LPG, neither the four LPG fragments (2 microM, 2 h) independently nor the co-addition of phosphoglycan and core-P1 fragments blocked the endotoxin-mediated adhesion to monocytes. To determine whether the fragments can reverse the effect of intact LPG, endothelial cells were first pretreated with the LPG fragments (10 microM, 15 min), followed by the addition of LPG (2 microM). All four LPG fragments fully reversed the effect of LPG. Simultaneous addition of LPG fragments and intact LPG caused only partial suppression (approximately 45%), while the addition of LPG fragments 14 min later had no reversal effect. Flow cytometry revealed that only core-P1 and lyso-P1 competitively inhibited (approximately 30%) LPG binding. Conversely, LPG competed with the binding of [3H]lyso-P1 (approximately 30%). Furthermore, mAb against the PGM reversed (approximately 70%) the effect of LPG. Thus, the lyso-P1 domain on LPG mediates binding to endothelial cells, whereas the PGM domain mediates the cell inhibitory effect.
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