Project description:Meiotic recombination is carried out through a specialized pathway for the formation and repair of DNA double-strand breaks (DSBs) made by the Spo11 protein. The present study shed light on the functional role of Cyclin, CYC2, in Tetrahymena thermophila which has transcriptionally high expression level during meiosis process. Knocking out the CYC2 gene results in arrest of meiotic conjugation process at 2.5–3.5 h after conjugation initiation, before the meiosis division starts, and in company with the absence of DSBs. To investigate the underlying mechanism of this phenomenon, a complete transcriptome profile was performed between wild-type strain and CYC2 knock-out strain. Functional analysis of RNA-Seq results identifies related differentially expressed genes (DEGs) including SPO11 and these DEGs are enriched in DNA repair/mismatch repair (MMR) terms in homologous recombination (HR), which indicates that CYC2 could play a crucial role in meiosis by regulating SPO11 and participating in HR.

Project description:Meiosis occurs in all sexually reproducing unicellular and multicellular eukaryotes. Bouquet formation is indispensible for homologous pairing or recombination during meiotic prophase I, but the regulatory mechanism of this process remain largely unknown. Cyclins regulate the precise meiosis progression by activating cyclin-dependent kinases. We therefore investigated the functional contribution of cyclin Cyc2p during bouquet (named crescent in Tetrahymena) formation in Tetrahymena thermophila. As a conjugation specific gene, CYC2 expression is significantly upregulated at 2-4 h after the initiation of conjugation and Cyc2p mainly localized in cytoplasm as well as weakly in the meiotic micronucleus (Mic). CYC2 knockout mutants failed to form elongated crescent structure and aborted meiotic development. Mic DNA double-strand breakage (DSB) decreased in ΔCYC2 cells as shown by γ-H2A.X staining, consistent with the finding that expression level of SPO11, DMC1, and RAD51 decreased in ΔCYC2 cells. However, ΔCYC2 cells failed to form crescent structure when artificial DSBs were induced, indicating that the inability to enter crescent phase was not completely due to the lack of DSBs. The localization of tubulin showed that impaired structure of nuclei and nuclear membrane may contribute to the blocked Mic elongation. This is further supported by the observation that expression levels of two microtubule associated kinesin genes, KIN11 and KIN141, were significantly downregulated in ΔCYC2 cells. Interestingly, scnRNA accumulation seemed intact in ΔCYC2 cells whereas the intensity of the heterochromatin marker H3K23me3 was abnormally increased. Together, these results showed that cyclin Cyc2p is required for micronuclear meiosis by controlling meiotic prophase chromosome breakage and the microtubule movement of nuclei in Tetrahymena.

Project description:We present a comprehensive transcriptome of ciliate T. thermophila using the Illumina RNA-seq platform. The data was generated from the six mRNA samples of growth, starvation and conjugation of Tetrahymena. Despite an AT rich genome, there are about 124.6 million reads mapped to T. thermophila genome. Using these mapped reads, we have significantly improved the previous genome annotation and investigated the gene expression. Besides, our result also provided a comprehensive understanding of the alternative splicing in T. thermophila, and suggested the existence of the regulated unproductive splicing and translation (RUST) in the single-celled eukaryote. RNA-seq for six samples of Tetrahymena growth, starvation and conjugation.

Project description:Microarray analyses were performed to compare the gene expression profiles of wild-type and several mutant strains of the ciliated protozoan Tetrahymena thermophila. Elimination of H3K4 methylation (hht2-K4Q) and knockout of either of the ubiquitylation enzymes (delta-UBC2 and delta-BRE1) affects a broader spectrum of genes than elimination of H2B ubiquitylation (htb1-K115R). Cells at mid-logarithmic growing phase (cell density of 200,000 cells/ml) were collected. Then total RNAs were extracted and hybridized.

Project description:We present a comprehensive transcriptome of ciliate T. thermophila using the Illumina RNA-seq platform. The data was generated from the six mRNA samples of growth, starvation and conjugation of Tetrahymena. Despite an AT rich genome, there are about 124.6 million reads mapped to T. thermophila genome. Using these mapped reads, we have significantly improved the previous genome annotation and investigated the gene expression. Besides, our result also provided a comprehensive understanding of the alternative splicing in T. thermophila, and suggested the existence of the regulated unproductive splicing and translation (RUST) in the single-celled eukaryote.

Project description:A genome wide microarray platform containing the predicted coding sequences (putative genes) for the ciliated protozoan Tetrahymena thermophila is described, validated and used to study gene expression in growing, starved and conjugating cells. Of the ~27,400 predicted open reading frames in Tetrahymena, transcripts homologous to 5876 are not detectable in one or more of these life cycle stages, indicating that this organism does indeed contain a large number of functional genes. Transcripts from over 5000 predicted genes are expressed at levels 5X background and 95 genes are expressed at 250X background in all stages. Transcripts homologous to 94 predicted genes are specifically expressed and 155 more are highly up-regulated in growing cells, and 90 are specifically expressed and 616 are up-regulated during starvation. Strikingly, transcripts homologous to 1073 predicted genes are specifically expressed and 1753 are significantly up-regulated during conjugation. The patterns of gene expression during conjugation correlate well with the previously described developmental stages of meiosis, nuclear differentiation and DNA elimination. Genes encoding proteins known to be complexed show similar expression patterns, indicating that co-ordinate expression with putative genes of known function should identify new genes with related functions. Keywords: growth (three cell densities); Starvation (seven time points); Conjugation (ten time points)

Project description:Understanding the intricacies of homologous recombination during meiosis is crucial for reproductive biology. However, the role of alternative splicing (AS) in DNA double-strand breaks (DSBs) repair and synapsis remains elusive. In this study, we investigated the impact of conditional knockout (cKO) of the splicing factor gene Bcas2 in mouse germ cells, revealing impaired DSBs repair and synapsis, resulting in non-obstructive azoospermia (NOA). Employing crosslinking immunoprecipitation and sequencing (CLIP-seq), we globally mapped BCAS2 binding sites in the testis, uncovering its predominant association with 5' splice sites (5'SS) of introns and a preference for GA-rich regions. Integrating CLIP-seq with RNA-seq, we identified BCAS2 as a key player in the AS of pre-mRNAs, including Spo11, Six6os1, Sycp1, Msh5, Cdk2, Sun2, Stag3, and Spdya, crucial for DSBs repair and synapsis. Notably, BCAS2 exhibited direct binding and regulatory influence on Trp53bp1 and Six6os1 through AS, unveiling novel insights into DSBs repair and synapsis during meiotic prophase I. Furthermore, the interaction between BCAS2, hnRNPH1, and SRSF3 was discovered to orchestrate Trp53bp1 expression via AS, underscoring its role in meiotic prophase I DSBs repair. In summary, our findings delineate the indispensable role of BCAS2-mediated post-transcriptional regulation in DSBs repair and synapsis during male meiosis. This study provides a comprehensive framework for unraveling the molecular mechanisms governing the post-transcriptional network in male meiosis, contributing to the broader understanding of reproductive biology.

Project description:Understanding the intricacies of homologous recombination during meiosis is crucial for reproductive biology. However, the role of alternative splicing (AS) in DNA double-strand breaks (DSBs) repair and synapsis remains elusive. In this study, we investigated the impact of conditional knockout (cKO) of the splicing factor gene Bcas2 in mouse germ cells, revealing impaired DSBs repair and synapsis, resulting in non-obstructive azoospermia (NOA). Employing crosslinking immunoprecipitation and sequencing (CLIP-seq), we globally mapped BCAS2 binding sites in the testis, uncovering its predominant association with 5' splice sites (5'SS) of introns and a preference for GA-rich regions. Integrating CLIP-seq with RNA-seq, we identified BCAS2 as a key player in the AS of pre-mRNAs, including Spo11, Six6os1, Sycp1, Msh5, Cdk2, Sun2, Stag3, and Spdya, crucial for DSBs repair and synapsis. Notably, BCAS2 exhibited direct binding and regulatory influence on Trp53bp1 and Six6os1 through AS, unveiling novel insights into DSBs repair and synapsis during meiotic prophase I. Furthermore, the interaction between BCAS2, hnRNPH1, and SRSF3 was discovered to orchestrate Trp53bp1 expression via AS, underscoring its role in meiotic prophase I DSBs repair. In summary, our findings delineate the indispensable role of BCAS2-mediated post-transcriptional regulation in DSBs repair and synapsis during male meiosis. This study provides a comprehensive framework for unraveling the molecular mechanisms governing the post-transcriptional network in male meiosis, contributing to the broader understanding of reproductive biology.

Project description:Genome-Wide gene expression of Tetrahymena thermophila conjugation

Project description:Somatic macronucleus (MAC) and germline micronucleus (MIC) of Tetrahymena thermophila are different in chromosome numbers, sizes, functions and cohesin complex locations. Loss of cohesin complex resulted in genome-wide disappearance of topologically associating domains (TADs) and chromatin loops in mammalian cells. However, the higher-level chromatin organization in Tetrahymena thermophila which contains both cohesin free MAC and cohesin located MIC are largely unknown. Here, using the Hi-C and HiChIP methods, we reveal that, these two nuclei possess distinct three-dimensional genome structures. In the MAC, each chromosome occupies its own territory and there are no chromatin compartmentalization or chromatin domains. The chromatin loops in MAC are mainly related to chromatin structures rather than transcriptional regulation. The MIC also without chromatin compartmentalization, but with chromatin domains and the domain boundaries are consistent with chromatin breakage sites (CBSs) which indicates that each MIC chromatin domain developed to one MAC chromosome during conjugation. Besides, we found the MIC exhibits unique intra-arm and inter-chromosome interactions at the crescent stage of conjugation, when the MIC undergoes meiotic recombination.