The encystment of many ciliates is an advanced survival strategy against adversity and the most important reason for ciliates existence worldwide. However, the molecular mechanism for the encystment of free-living ciliates is poorly understood. Here, we performed comparative transcriptomic analysis of dormant cysts and trophonts from Pseudourostyla cristata using transcriptomics, qRT-PCR and bioinformatic techniques. We identified 2565 differentially expressed unigenes between the dormant cysts and the trophonts. The total number of differentially expressed genes in GO database was 1752. The differential unigenes noted to the GO terms were 1993. These differential categories were mainly related to polyamine transport, pectin decomposition, cytoplasmic translation, ribosome, respiratory chain, ribosome structure, ion channel activity, and RNA ligation. A total of 224 different pathways were mapped. Among them, 184 pathways were upregulated, while 162 were downregulated. Further investigation showed that the calcium and AMPK signaling pathway had important induction effects on the encystment. In addition, FOXO and ubiquitin-mediated proteolysis signaling pathway jointly regulated the encystment. Based on these findings, we propose a hypothetical signaling network that regulates Pseudourostyla cristata encystment. Overall, these results provide deeper insights into the molecular mechanisms of ciliates encystment and adaptation to adverse environments.of Strepkiella histriomuscorum has been studied in the encystment and trophont stages through biochip technology, which suggested that cyst formation is associated with Ribosomal L7, Ribosomal acidic P2, Cathepsin B, Cathepsin H, Ubiquitin, Ca 2+ -ATPase and Actin1 7 . Other studies investigated the differential proteins of the cysts and the trophonts from Pseudourostyla cristata (P. cristata) using shotgun LC-MS/MS, finding the association of fibrillarin-like rRNA methylase, methylmalonyl-coenzyme mutase, ADP ribosylation factor, Rab12, MAPK-related kinase and KR multi-domain proteins with cyst formation 8 . However, the reports of systematically studying the genes and signaling pathways involved in the formation of ciliate cysts at the molecular level are rare 8 . In this study, we have investigated the molecular mechanism underlying the cyst formation in ciliates using comparative transcriptomic analysis, quantitative real-time PCR (qRT-PCR) and bioinformatic techniques. Furthermore, we have focused on the analysis of several important signaling pathways related to the encystment. Therefore, we have proposed a hypothetical network that regulates Pseudourostyla cristata encystment. Our study generates novel insights into the molecular mechanisms of the cyst formation in free-living ciliates.www.nature.com/scientificreports www.nature.com/scientificreports/ dormant cysts of P. cristata (Fig. 4). Validation of results by transcriptome sequencing showed that mRNA outcomes were consistent with the transcriptomic data of trophonts and dormant cysts in P. cristata (Fig. 4).
The transformation of a ciliate into cyst is an advance strategy against an adverse situation. However, the molecular mechanism for the encystation of free-living ciliates is poorly understood. A large-scale identification of the encystment-related proteins and genes in ciliate would provide us with deeper insights into the molecular mechanisms for the encystations of ciliate. We identified the encystment-related proteins and genes in Pseudourostyla cristata with shotgun LC-MS/MS and scale qRT-PCR, respectively, in this report. A total of 668 proteins were detected in the resting cysts, 102 of these proteins were high credible proteins, whereas 88 high credible proteins of the 724 total proteins were found in the vegetative cells. Compared with the vegetative cell, 6 specific proteins were found in the resting cyst. However, the majority of high credible proteins in the resting cyst and the vegetative cell were co-expressed. We compared 47 genes of the co-expressed proteins with known functions in both the cyst and the vegetative cell using scale qRT-PCR. Twenty-seven of 47 genes were differentially expressed in the cyst compared with the vegetative cell. In our identifications, many uncharacterized proteins were also found. These results will help reveal the molecular mechanism for the formation of cyst in ciliates.
Euplotes encysticus is a species of Hypotrich ciliates, which form cyst wall by secreting the special substances on encounter of adverse environment. It has critical significance to study the component and mechanism underlying resting cyst, during resisting unfavorable conditions in dormancy induction. The present study was aimed to investigate the effects of cyst wall proteins of Euplotes encysticus by using biochemical methods. Therefore, protein extracts were separated by SDSPAGE, identified and analyzed by MALDI-TOF MS and Bioinformatics tools. We detected 42 cyst wall proteins, 26 were functional proteins and 16 proteins consist of unknown function; which is consistent with cyst wall specificity. These results partially revealed the components of resting cyst wall formed after the cells differentiation of Euplotes encysticus. In addition, our data suggested that the function of cyst wall proteins are more likely involved in the mechanical protection, signal transduction, material transport, protein degradation and energy metabolism to survival, with potentially importance implications in the molecular mechanism of eukaryocyte dormancy under stress condition.
Ciliated protists are a large group of single-cell eukaryotes, leading to the resting cysts in unfavorable environmental condition. However, the underlying molecular mechanism of encystment in the free-living ciliates is poorly understood. Here we show that the resting cysts are better than the vegetative cells of Euplotes encysticus in adverse survivor with respect to energy metabolism. Therefore scale identification of encystment-related proteins in Euplotes encysticus was investigated by iTRAQ analysis. We analyzed a total of 130 proteins, in which 19 proteins involving 12 upregulated and 7 downregulated proteins were associated with encystment in the resting cysts in comparison with the vegetative cells. Moreover, direct fluorescent labeling analysis showed that the vegetative cells treated with shRNA-β-tubulin recombinant E. coli accumulated a large number of granular materials, and dramatic cell morphology changes. Importantly, the cell membrane rupture phenomenon was observed after three weeks of shRNA-β-tubulin interference as compared to the control group. These results revealed that different proteins might play an important role in the process of the vegetative cells into the resting cysts. These results will help to reveal the morphological changes and molecular mechanism of resting cyst formation of ciliates.
The transformation of a ciliate into cyst is an advance strategy against an adverse situation. However, the molecular mechanism for the encystation of free-living ciliates is poorly understood. A large-scale identification of the encystment-related proteins and genes in ciliate would provide us with deeper insights into the molecular mechanisms for the encystations of ciliate. We identified the encystment-related proteins and genes in Pseudourostyla cristata with shotgun LC-MS/MS and scale qRT-PCR, respectively, in this report. A total of 668 proteins were detected in the resting cysts, 102 of these proteins were high credible proteins, whereas 88 high credible proteins of the 724 total proteins were found in the vegetative cells. Compared with the vegetative cell, 6 specific proteins were found in the resting cyst. However, the majority of high credible proteins in the resting cyst and the vegetative cell were co-expressed. We compared 47 genes of the co-expressed proteins with known functions in both the cyst and the vegetative cell using scale qRT-PCR. Twenty-seven of 47 genes were differentially expressed in the cyst compared with the vegetative cell. In our identifications, many uncharacterized proteins were also found. These results will help reveal the molecular mechanism for the formation of cyst in ciliates.
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