过表达周期蛋白Cyc28影响四膜虫的有性生殖进程北大核心CSCD

真核生物的细胞周期通过连续的激活和失活特定的周期蛋白/周期蛋白依赖性激酶复合物活性进行调控。嗜热四膜虫含有34种周期蛋白,有性生殖期特异表达的周期蛋白Cyc2和Cyc17在四膜虫小核减数分裂中发挥重要功能。本研究从嗜热四膜虫中鉴定出一种新的周期蛋白CYC28(TTHERM_00082190)基因,预测编码266个氨基酸。实时荧光定量PCR表明,CYC28在有性生殖时期特异表达,且在4 h表达水平最高。通过同源重组构建获得MTT1启动子调控下的HA-CYC28突变体细胞。免疫荧光定位表明,HA-Cyc28定位在细胞质和凋亡的亲本大核中。分别构建CYC28敲除突变株和RNA干扰细胞株,对CYC28敲减突变体细胞的分析发现,营养生长和有性生殖期突变细胞发育正常。然而,过表达株Cyc28突变体引起原核染色体排列异常,原核不能完成有丝分裂形成配子核,有性生殖进程终止。结果表明,Cyc28参与细胞的有性生殖进程,它的正常表达和降解对原核有丝分裂的完成是必需的。     

周期蛋白Cyc2的过量表达及突变抑制嗜热四膜虫有性生殖发育

周期蛋白在细胞增殖过程中呈现周期性表达变化,不同的周期蛋白通过结合周期蛋白激酶(cyclin-dependent kinase,CDKs)及靶向特定蛋白质参与细胞有丝分裂和减数分裂过程的精确调控。嗜热四膜虫有性生殖期特异表达的B3型周期蛋白Cyc2(cyclin 2,Cyc2)对减数分裂的启始是必需的,但Cyc2蛋白的分子调控机制并不清楚。本研究通过0.1μg/mL和0.3μg/mL镉离子诱导突变细胞株OE-CYC2-B2086和OE-CYC2-CU428中CYC2基因在金属硫蛋白1基因(metallothionein gene 1,MTT1)启动子调控下上调表达。实时荧光定量PCR检测突变株OE-CYC2-B2086和OE-CYC2-CU428中CYC2的转录水平分别上调7.8倍和9.8倍。细胞有性生殖发育进程的荧光显微观察发现CYC2的表达上调并不影响有性生殖前期减数分裂的启始,但是干扰四膜虫有性生殖后期中新大核和新小核的正确形成。同时突变株OE-CYC2-B2086和OE-CYC2-CU428交配后,在镉离子诱导下不能产生有性生殖后代,但是该突变株分别和两种不同野生型细胞或CYC2敲除的突变细胞株交配能够恢复产生3%,15%或32%的有性生殖后代,有性生殖发育异常程度与CYC2的表达水平成正相关。进一步突变Cyc2第312位磷酸化位点丝氨酸为丙氨酸,获得CYC2单位点突变细胞株CYC2-S312A-B和CYC2-S312A-C。丝氨酸单位点突变阻止了四膜虫有性生殖期小核减数第1次分裂起始。结果表明周期蛋白2的表达水平和磷酸化修饰影响了不同阶段细胞核的功能,周期蛋白2对四膜虫有性生殖发育的正常进行是必需的。     

自噬相关蛋白Atg4.1过表达促进嗜热四膜虫亲本大核程序化降解

细胞核自噬在真核生物进化过程中具有重要作用,然而不同生物中的自噬分子调控机制并不完全清楚。嗜热四膜虫有性生殖过程中亲本大核的程序化降解是一种独特的细胞核选择性自噬。该研究从嗜热四膜虫中鉴定出一种自噬相关基因Tt ATG4.1(TTHERM_00526270),编码677个氨基酸。Tt ATG4.1在营养生长期和饥饿期不表达,在有性生殖期2 h特异表达,亲本大核开始降解的anlagen时期表达量最高。通过同源重组构建获得MTT1启动子调控表达的ATG4.1突变株,免疫荧光定位显示, Atg4.1定位在细胞质和降解的亲本大核上。过量表达Atg4.1导致anlagen时期亲本大核未能正常凝缩,且细胞核膨大。通过自噬体和溶酶体荧光探针标记发现过量表达Atg4.1不影响亲本大核的酸化,但相比于野生型细胞,过表达Atg4.1细胞株中,亲本大核的降解更快。研究表明自噬相关蛋白Atg4.1参与调控嗜热四膜虫有性生殖中亲本大核程序化降解。     

错配修复蛋白Mlh3对四膜虫有性生殖是必需的

DNA错配修复(mismatch repair, MMR)是一种进化中保守的机制,它校正DNA复制过程中产生的错误,维持基因组的稳定性。MMR家族蛋白同时也参与多种DNA相关的生物学功能。本研究从嗜热四膜虫鉴定了一种新的错配修复蛋白MLH3基因,该基因预测编码 319 个氨基酸,在有性生殖期特异表达。免疫荧光定位表明,HA-Mlh3定位在有性生殖期减数分裂的小核和新发育的大核中。MLH3 敲除的突变体细胞株,在有性生殖发育期停滞在两大核和两小核阶段,新大核DNA复制受阻。γ-H2A.X 检测表明,新大核和小核有性生殖后期断裂的基因组不能正常修复,发育中的细胞裂解,不能形成有性生殖后代。结果表明,Mlh3参与四膜虫新大核发育过程基因组的断裂修复和复制,对四膜虫的有性生殖是必需的。     

驱动蛋白Kin11调控嗜热四膜虫生殖系小核的减数分裂

驱动蛋白(kinesin)是分子马达蛋白质超家族成员,主要参与囊泡与细胞器的运输、纺锤体组装、有丝分裂和减数分裂等过程。在减数分裂期,不同驱动蛋白发挥功能的调控机制并不十分清楚。嗜热四膜虫(Tetrahymena thermophila)中含有14个驱动蛋白家族成员。其中,kinesin-6家族的唯一成员Kin11(TTHERM_00637750),在营养生长期低表达,饥饿期不表达,有性生殖期表达上调。Kin11编码1608个氨基酸,包含1个N端保守的马达蛋白结构域,C端卷曲螺旋(coiled-coil)结构域,并在N端和C端分别含有核定位信号NLS1和NLS2。Kin11在营养生长期和有性生殖期,定位在有丝分裂和减数分裂的小核和纺锤体上,并在有性生殖后期alignment阶段定位于小核上。Kin11与微管蛋白共定位于有丝分裂和减数分裂的纺锤体上。将Kin11的N端含有NLS1的1~400位氨基酸序列截短后,截断突变体定位在有性生殖减数分裂期的小核和纺锤体上。而将其C端含有NLS2的1008~1608位氨基酸残基截短后,截断突变体只能定位在有丝分裂和减数分裂后期的小核及有丝分裂的纺锤体上。敲除KIN11导致减数分裂过程中的纺锤体结构发生异常变化,小核染色体不均等分离与丢失,有性生殖发育停滞。结果表明,嗜热四膜虫驱动蛋白Kin11通过影响纺锤体结构,参与调控四膜虫生殖系小核在减数分裂过程中的正常分离。     

嗜热四膜虫胱硫醚γ-裂解酶Cgl1的表达、定位及功能分析

含硫氨基酸在不同的生物体中具有重要调节功能,转硫途径相关酶促进半胱氨酸的生成和硫化氢产生。本研究从嗜热四膜虫中鉴定一种胱硫醚γ-裂解酶（cystathionine γ-lyase 1,CGL1,TTHERM_00052400）基因。CGL1在营养生长期高水平表达,而在饥饿阶段和有性生殖期,维持在较低的表达水平。通过密码子优化,人工合成CGL1基因,构建重组表达质粒pGEX-CGL1,转化大肠杆菌BL21(DE3)。E.coli/pGEX-CGL1表达重组蛋白质GST-Cgl1,并通过亲和层析获得纯化。GST-Cgl1裂解胱硫醚产生半胱氨酸,也具有裂解半胱氨酸和同型半胱氨酸产生H2S的活性。进一步构建重组质粒pNEO4-3HA-CGL1和pSMC1hpNEO-CGL1,转化四膜虫细胞,获得带有HA标签和干扰CGL1的突变体细胞株。免疫荧光定位表明,HA-Cgl1生长期定位在亲本大核,饥饿期定位在细胞质,有性生殖前期定位在亲本大核,而在后期定位在胞质中。CGL1干扰的突变体细胞株在有性生殖过程中不能形成合子核,发育中的小核异常降解,产生仅有大核的异常单细胞。结果表明,嗜热四膜虫含有进化中保守的胱硫醚γ-裂解酶Cgl1。Cgl1具有产生和裂解半胱氨酸的活性。Cgl1定位在细胞质和细胞核中,参与了有性生殖过程细胞核的发育。     

嗜热四膜虫两类不同金属硫蛋白的功能补偿分析

为了分析嗜热四膜虫两类金属硫蛋白之间的关系,研究分别构建了MTT1-MTT3和MTT2-MTT4的基因敲除载体,通过同源重组获得敲除大核MTT1-MTT3和MTT2-MTT4的两种嗜热四膜虫突变体细胞株△MTT1-MTT3和△MTT2-MTT4。两种突变体细胞株暴露在Cd2+、Cu2+和H2O2的生长表现出显著不同,△MTT1-MTT3突变体细胞对Cd2+的耐受性显著下降,而△MTT2-MTT4突变体细胞对Cu2+和H2O2的耐受性均显著下降。实时荧光定量PCR分析不同突变体中其他MTT基因的表达变化,在△MTT2-MTT4突变体细胞株中,MTT5的表达水平下调,在500 mol/L Cu2+处理后,△MTT2-MTT4突变体细胞中MTT1、MTT3和MTT5表达相对野生型分别上调6.1、9.5和8.5倍。在△MTT1-MTT3突变体细胞中,MTT2、MTT4和MTT5的表达水平下调,当5 mol/L Cd2+处理后,△MTT1-MTT3突变体细胞株MTT5表达水平相对野生型上调2.9倍,而MTT2和MTT4表达水平相对野生型分别下降了4.9倍和2.5倍。结果表明嗜热四膜虫中的金属硫蛋白MTT1、MTT3和MTT5主要参与细胞的重金属解毒功能;而MTT2和MTT4主要参与细胞内正常的新陈代谢功能,不同的金属硫蛋白基因之间的表达存在相互调控和功能补偿。       

嗜热四膜虫两类不同金属硫蛋白的功能补偿分析简

为了分析嗜热四膜虫两类金属硫蛋白之间的关系,研究分别构建了MTT1-MTT3和MTT2-MTT4的基因敲除载体,通过同源重组获得敲除大核MTT1-MTT3和MTT2-MTT4的两种嗜热四膜虫突变体细胞株△MTT1-MTT3和△MTT2-MTT4。两种突变体细胞株暴露在Cd2+、Cu2+和H2O2的生长表现出显著不同,△MTT1-MTT3突变体细胞对Cd2+的耐受性显著下降,而△MTT2-MTT4突变体细胞对Cu2+和H2O2的耐受性均显著下降。实时荧光定量PCR分析不同突变体中其他MTT基因的表达变化,在△MTT2-MTT4突变体细胞株中,MTT5的表达水平下调,在500μmol/L Cu2+处理后,△MTT2-MTT4突变体细胞中MTT1、MTT3和MTT5表达相对野生型分别上调6.1、9.5和8.5倍。在△MTT1-MTT3突变体细胞中,MTT2、MTT4和MTT5的表达水平下调,当5μmol/L Cd2+处理后,△MTT1-MTT3突变体细胞株MTT5表达水平相对野生型上调2.9倍,而MTT2和MTT4表达水平相对野生型分别下降了4.9倍和2.5倍。结果表明嗜热四膜虫中的金属硫蛋白MTT1、MTT3和MTT5主要参与细胞的重金属解毒功能;而MTT2和MTT4主要参与细胞内正常的新陈代谢功能,不同的金属硫蛋白基因之间的表达存在相互调控和功能补偿。     

嗜热四膜虫Ran结合蛋白1的表达对大小核分裂的影响

Ran是细胞内的一种具有GTP酶活性的功能蛋白,可以调节染色体稳定性、细胞核组建以及核质运输等多种细胞进程．Ran结合蛋白1（Ran-binding protein 1, Rbp1p ）是Ran的必要调控因子,促进Ran-GTP水解为Ran-GDP．本研究从嗜热四膜虫大核基因组中鉴定出1个保守的Ran结合蛋白基因RBP1(TTHERM_00158040, http://www.ciliate.org)．实时荧光定量PCR表明,RBP1在四膜虫营养生长和有性生殖过程中都有表达,且在有性生殖过程中表达水平提高．免疫荧光定位表明,在营养 生长期Rbp1p定位于细胞质中．过表达RBP1或敲减RBP1后,细胞生长速率下降,大核的无丝分裂异常,细胞分裂末期产生了无大核的异常细胞,同时过表达RBP1导致了多小核的产生．结果表明,Rbp1p影响四膜虫细胞核的分裂进程,它的正常表达对细胞增殖过程起到重要的调节作用．     

Cyc17, a meiosis-specific cyclin,is essential for anaphase initiation and chromosome segregation in Tetrahymena thermophila

Although the role of cyclins in controlling nuclear division is well established, their function in ciliate meiosis remains unknown. In ciliates, the cyclin family has undergone massive expansion which suggests that diverse cell cycle systems exist, and this warrants further investigation. A screen for cyclins in the model ciliate Tetrahymena thermophila showed that there are 34 cyclins in this organism. Only 1 cyclin, Cyc17, contains the complete cyclin core and is specifically expressed during meiosis. Deletion of CYC17 led to meiotic arrest at the diakinesis-like metaphase I stage. Expression of genes involved in DNA metabolism and chromosome organization (chromatin remodeling and basic chromosomal structure) was repressed in cyc17 knockout matings. Further investigation suggested that Cyc17 is involved in regulating spindle pole attachment, and is thus essential for chromosome segregation at meiosis. These findings suggest a simple model in which chromosome segregation is influenced by Cyc17.     

Cdk3, a conjugation-specific cyclin-dependent kinase,is essential for the initiation of meiosis in Tetrahymena thermophila

Meiosis is an important process in sexual reproduction. Meiosis initiation has been found to be highly diverse among species. In yeast, it has been established that cyclin-dependent kinases (Cdks) and cyclins are essential components in the meiosis initiation pathway. In this study, we identified 4 Cdks in the model ciliate, Tetrahymena thermophila, and we found one of them, Cdk3, which is specifically expressed during early conjugation, to be essential for meiosis initiation. Cdk3 deletion led to arrest at the pair formation stage of conjugation. We then confirmed that Cdk3 acts upstream of double-strand break (DSB) formation. Moreover, we detected that Cdk3 is necessary for the expression of many genes involved in early meiotic events. Through proteomic quantification of phosphorylation, co-expression analysis and RNA-Seq analyses, we identified a conjugation-specific cyclin, Cyc2, which most likely partners with Cdk3 to initiate meiosis.     

Autoradiographic evidence for self-fertilization in Tetrahymena thermophila

Conjugation in Tetrahymena thermophila consists of a sequence of nuclear events, including meiosis and reciprocal cross-fertilization, which result in biparental genetic endowment of the sexual progeny. Genetic evidence was recently provided that the normal exchange of gametic nuclei between conjugating cells can be efficiently blocked by hyperosmotic shock. In this paper we confirm this finding autoradiographically. We also report that the inhibitor of microtubule assembly, vinblastine, also blocks this step, as well as the subsequent fusion of gametic nuclei. The ability of conjugating cells to survive and continue more or less normally after blocks of self-fertilization and pro-nuclear fusion demonstrates a surprisingly high degree of developmental regulation during conjugation. Self-fertilization has proven useful for the isolation of recessive mutants in T. thermophila.     

Abortive conjugation induced by UV-B irradiation at meiotic prophase in Tetrahymena thermophila

Conjugating Tetrahymena were irradiated by ultraviolet-B (UV-B) at various stages of conjugation. When the conjugants were exposed to the UV-B at late meiotic prophase (the stage from pachytene to diplotene), abortive conjugation was induced at high frequencies. After completing meiosis, a significant number of the conjugants showed marked anomalies, i.e., failure of nuclear selection after meiosis, and abortion of the subsequent conjugation process such as a postmeiotic division to form gametic nuclei, nuclear exchange, synkaryon formation, and postzygotic development. The conjugating pairs retained the parental macronucleus and separated earlier as compared with a control. The resultant exconjugants degenerated meiotic products and became amicronucleates. These observations strongly suggest the presence of a UV-sensitive molecule that is expressed specifically at the meiotic prophase and that directs the subsequent development after meiosis. Dev. Genet. 23:151–157, 1998. © 1998 Wiley-Liss, Inc.     

Two distinct classes of mitotic cyclin homologues, Cyc1 and Cyc2, are involved in cell cycle regulation in the ciliate Paramecium tetraurelia

The eukaryotic cell cycle is regulated by the sequential activation of different CDK/cyclin complexes. Two distinct classes of mitotic cyclin homologues, CYC1 and CYC2, have been identified and cloned for the first time in the ciliate Paramecium. Cyc1 is 324 amino acids long with a predicted molecular mass of 38 kDa, whereas Cyc2 is 336 amino acids long with a predicted molecular mass of 40 kDa. They display 42-51% sequence identity to other eukaryotic mitotic cyclins within the 'cyclin box' region. The conserved 'cyclin box' and 'destruction box' elements can be identified within each of the sequences. Genomic Southern blot analysis indicated that the CYC1 gene has two isoforms, with 92.3% and 85.9% identify at the amino acid level and at the nucleotide level, respectively. Both Cyc1 and Cyc2 proteins showed characteristic patterns of accumulation and destruction during the vegetative cell cycle, with Cyc1 peaking at the point of commitment to division (PCD), and Cyc2 reaching the maximal level late in the cell cycle. Immunoprecipitation experiments with antibodies specific to Cyc1 and Cyc2 indicated that Cyc1 and Cyc2 associate with distinct CDK homologues. Both immunoprecipitates exhibited histone H1 kinase activity that oscillated in the cell cycle in parallel with the respective amount of cyclins present. Histone H1 kinase activity associated with Cyc1 reached a peak at PCD while Cyc2 showed maximal activity when about 75% cells have completed cytokinesis. We propose that Cyc1 may be involved in commitment to division, in association with the CDK that binds to p13suc1, Cdk3, and that the Cyc2/Cdk2 complex may regulate cytokinesis. PCR-amplification revealed similar sequences in Tetrahymena, Sterkiella, Colpoda and Blepharisma, suggesting the conservation of the cyclin genes within ciliates. Although cell cycle regulation in ciliates differs in some respects from that of other eukaryotes, the cyclin motifs have clearly been conserved during evolution.