核仁进化研究取得进展

核仁(nucleolus)是普遍存在于真核细胞间期核中的最显著结构。它是rDNA转录和核糖体亚基组装的场所。如果说核糖体是合成蛋白质的“分子机器”,那么核仁便是制造这一机器的“母机”。中国科学院昆明动物研究所文建凡研究员领导的研究小组先是在一类低等的单细胞真核生物——贾第虫(Giardia)上证实了“不具核仁结构”的现象,那么这类生物是如何进行rDNA转录和核糖体亚基组装呢?     

细胞周期决定核糖体蛋白S6在真核细胞核仁中的聚积

核糖体蛋白S6（rpS6）是核糖体40S小亚基的核心组成蛋白之一。研究表明,rpS6可以通过核定位信号进入细胞核中,在核仁中参与核糖体的组装。在该研究中发现,rpS6在高等真核细胞核仁中的聚积与细胞周期有关,rpS6在S期中晚期开始在核仁中聚积,G2期含量达到最高,M期核仁分解时消失。推测,rpS6在核仁中的这种分布特性可能与核糖体的合成随细胞周期变化有关。     

SUMO化修饰的Apak对核糖体RNA合成的调控作用

核糖体是由核糖体RNA和核糖体蛋白组成的复合体,其功能是参与蛋白质合成.SUMO化修饰的底物蛋白对核糖体的形成有重要调控作用.前期研究发现,KRAB型锌指蛋白Apak能特异地抑制p53所介导的凋亡通路.进一步研究发现,在核仁应激及癌基因激活条件下,抑癌蛋白ARF促进Apak发生SUMO化修饰并促使其移位于核仁.为了进一步探讨SUMO化修饰的Apak对核糖体RNA合成的调控功能,本研究通过Northern blot检测SUMO化修饰的Apak对核糖体RNA合成的影响,实时定量PCR检测核糖体RNA转录水平,RNA-Ch IP方法检测核糖体RNA与Apak蛋白的相互作用,结果表明,SUMO化修饰的Apak抑制47S核糖体RNA前体的合成且抑制RNA聚合酶Ⅰ介导转录的18S和5.8S r RNA的合成;在放线菌素D以及癌基因诱导下,促进Apak与18S,5.8S r RNA相互作用.本研究对理解Apak的功能和作用机制提供了新的依据,为深入研究KRAB型锌指蛋白家族分子对核糖体RNA的调控奠定了基础.     

游仆虫重组核糖体蛋白L11与肽链释放因子的体外相互作用分析

核糖体蛋白L11(ribosome protein L11)是一种高度保守的蛋白质．为研究真核生物的核糖体蛋白L11的功能,从八肋游仆虫（Euplotes octocarinatus）大核基因组中克隆到核糖体蛋白L11基因,构建了重组表达质粒pGEX-6p1-L11,通过谷胱甘肽-Sepharose 4B亲和层析,纯化了重组融合蛋白GST-L11．Pull down 分析显示,八肋游仆虫的核糖体蛋白L11与第一类肽链释放因子eRF1a可以在体外相互作用．这一结果提示,与原核生物一样,低等真核生物的核糖体蛋白L11在肽链终止过程中可能起一定的作用．     

八肋游仆虫胞质核糖体蛋白基因序列特征分析

为了探讨八肋游仆虫(Euplotes octocarinatus)核糖体蛋白基因的数目及其结构的特殊性, 研究通过生物信息学方法, 对八肋游仆虫胞质核糖体蛋白进行了系统的分析。共鉴定得到98个基因编码78种不同的胞质核糖体蛋白。其中19种胞质核糖体蛋白基因发生了复制, 尽管都是有功能的, 但其中一个基因的表达受到限制。通过与高等真核生物比较, 我们发现: 八肋游仆虫核糖体蛋白eS30缺失了N端的类泛素结构域, eL6缺失了N端的Ribosomal_L6e_N结构域。另外, 不同于其他高等真核生物, 八肋游仆虫酸性核糖体磷酸化蛋白uL10为碱性蛋白。研究为进一步探讨低等真核生物核糖体的组装及功能奠定了基础。     

C2株贾第虫醛糖还原酶的原核表达与生物信息学分析北大核心

[目的]克隆、原核表达、纯化C2株蓝氏贾第鞭毛虫(Giardia lamblia,简称贾第虫)醛糖还原酶(Aldose reductase,AR)基因,并进行生物信息学分析。[方法]从C2株贾第虫基因组DNA中克隆贾第虫AR编码区,双酶切连入原核表达载体pET-28a(+),酶切和测序进行验证,并进行生物信息学分析;将构建成功的重组质粒pET-28a(+)-AR转化大肠杆菌Rosetta(DE3)并进行诱导表达,SDS-PAGE及Western Blot验证表达效果;镍亲和层析纯化AR蛋白,SDS-PAGE观察纯化效果。[结果]成功克隆了C2株贾第虫AR蛋白编码区并构建了原核表达载体,SDS-PAGE及Western Blot显示,AR表达载体转化的大肠杆菌经诱导可表达出相对分子量约37.2k Da的目的蛋白,与预期一致;重组蛋白通过亲和层析获得了高效纯化;生物信息学分析显示贾第虫AR蛋白主要二级结构为无规则卷曲,整体为一个NADPH依赖的氧化还原酶结构域。AR蛋白在真核生物中相当保守,贾第虫AR蛋白在进化上相对独立。[结论]证实了贾第虫AR蛋白的存在并明确了其结构和进化上的特征,为贾第虫AR抗体的制备和功能的研究提供了基础。     

无核仁原生动物蓝氏贾第虫rDNA的分布

过去的工作已表明,源真核生物（Archezoa)中的双滴虫类极其原始,核中尚无核仁发生,以蓝氏贾第虫（Giardia lamblia)作为双滴虫类的代表,用高度特异的核仁组织区银染法（改良的Ag-I法,李靖炎,1985）在电镜下检视其rDNA在核中的分布。结果发现,代表rDNA之所在的银粒并不集中形成任何类似核仁组织区或核仁纤维区的结构;在作为对照的小眼虫（Euglena gracilis)体内,银粒则完全集中在核仁纤维区中,因此,作者以为贾第虫rDNA的这种分布代表着核仁组织区进化形成以前的一种原始状态。     

八肋游仆虫酸性核糖体磷酸化蛋白P1有2个亚型

真核生物酸性核糖体磷酸化蛋白(P0、P1、P2)位于核糖体60S大亚基上,它们在核糖体上共同组成一个向外侧凸出的五聚体的柄状复合物［P0·(P1·P2)2］,该复合物在蛋白质合成延伸过程中起着重要作用．为了探讨单细胞真核生物核糖体柄状复合物的组成形式及在蛋白质合成中的作用,对八肋游仆虫（Euplotes octocarinatus）的P1进行了研究．通过生物信息学方法,分析八肋游仆虫基因组及转录组数据,找到2个酸性核糖体蛋白P1基因,从DNA 和cDNA中都扩增到这2个P1基因,表明八肋游仆虫酸性核糖体磷酸化蛋白P1确实存在2个亚型. 将2个基因克隆后分别构建重组表达质粒pET28a-P1A和pGEX-6P-1-P1B,在大肠杆菌BL21中获得高效表达.经镍柱和GST柱亲和层析后,获得较高纯度的八肋游仆虫酸性核糖体蛋白EoP1A和EoP1B,表达产物经Western印迹检测为阳性．Pull-down分析了EoP1A和EoP1B之间的相互作用．结果表明,游仆虫酸性核糖体磷酸化蛋白P1的2个亚型EoP1A和EoP1B之间存在相互作用.     

C2株贾第虫醛糖还原酶的原核表达与生物信息学分析

[目的]克隆、原核表达、纯化C2株蓝氏贾第鞭毛虫(Giardia lamblia,简称贾第虫)醛糖还原酶(Aldose reductase,AR)基因,并进行生物信息学分析。[方法]从C2株贾第虫基因组DNA中克隆贾第虫AR编码区,双酶切连入原核表达载体pET-28a(+),酶切和测序进行验证,并进行生物信息学分析;将构建成功的重组质粒pET-28a(+)-AR转化大肠杆菌Rosetta(DE3)并进行诱导表达,SDS-PAGE及Western Blot验证表达效果;镍亲和层析纯化AR蛋白,SDS-PAGE观察纯化效果。[结果]成功克隆了C2株贾第虫AR蛋白编码区并构建了原核表达载体,SDS-PAGE及Western Blot显示,AR表达载体转化的大肠杆菌经诱导可表达出相对分子量约37.2k Da的目的蛋白,与预期一致;重组蛋白通过亲和层析获得了高效纯化;生物信息学分析显示贾第虫AR蛋白主要二级结构为无规则卷曲,整体为一个NADPH依赖的氧化还原酶结构域。AR蛋白在真核生物中相当保守,贾第虫AR蛋白在进化上相对独立。[结论]证实了贾第虫AR蛋白的存在并明确了其结构和进化上的特征,为贾第虫AR抗体的制备和功能的研究提供了基础。     

源真核生物贾第虫与原细菌着丝粒／动粒蛋白的免疫印迹检查

以抗人着丝粒蛋白Ｂ的单抗和多抗以及抗ＣＨＯ细胞动粒蛋白的单抗对源真核生物（ａｒｃｈｅｚｏａ）蓝氏贾第虫（Ｇｉａｒｄｉａｌａｍｂｌｉａ）和分别代表原细菌的３个枝的３种原细菌（Ｈａｌｏｂａｃｔｅｒｉｕｍ、Ｔｈｅｒｍｏｐｌａｓｍａ、Ｓｕｌｆｏｓｐｈａｅｒｅｌｌｕｓ）作了免疫电泳检查,并以小眼虫和大肠杆菌作为对照。结果表明,３种原细菌都呈阳性反应;而且贾第虫的反应情况显然比纤毛虫、眼虫、典型涡鞭毛虫、尖尾虫（Ｏｘｙｒｒｈｉｓ）等单细胞后真核生物的更接近于原细菌的情况。这不仅从一个新的方面为真核细胞起源于古代的原细菌的学说提供了新的佐证,而且从着丝粒／动粒蛋白方面证明了源真核生物贾第虫的原始性。本工作还为认识着丝粒蛋白Ｂ和动粒蛋白的起源和演化提供了线索。     

Mutations in the nucleolar proteins Tma23 and Nop6 suppress the malfunction of the Nep1 protein

The nucleolar Saccharomyces cerevisiae protein Nep1 was previously shown to bind to a specific site of the 18S rRNA and to be involved in assembly of Rps19p into pre-40S ribosome subunits. Here we report on the identification of tma23 and nop6 mutations as recessive suppressors of a nep1(ts) mutant allele and the nep1 deletion as well. Green fluorescent protein fusions localized Tma23p and Nop6p within the nucleolus, indicating their function in ribosome biogenesis. The high lysine content of both proteins and an RNA binding motif in the Nop6p amino acid sequence suggest RNA-binding functions for both factors. Surprisingly, in contrast to Nep1p, Tma23p and Nop6p seem to be specific for fungi as no homologues could be found in higher eukaryotes. In contrast to most other ribosome biogenesis factors, Tma23p and Nop6p are nonessential in S. cerevisiae. Interestingly, the tma23 mutants showed a considerably increased resistance against the aminoglycoside G418, probably due to a structural change in the 40S ribosomal subunit, which could be the result of incorrectly folded 18S rRNA gene, missing rRNA modifications or the lack of a ribosomal protein.     

Elucidation of Motifs in Ribosomal Protein S9 That Mediate Its Nucleolar Localization and Binding to NPM1/Nucleophosmin

Biogenesis of eukaryotic ribosomes occurs mainly in a specific subnuclear compartment, the nucleolus, and involves the coordinated assembly of ribosomal RNA and ribosomal proteins. Identification of amino acid sequences mediating nucleolar localization of ribosomal proteins may provide important clues to understand the early steps in ribosome biogenesis. Human ribosomal protein S9 (RPS9), known in prokaryotes as RPS4, plays a critical role in ribosome biogenesis and directly binds to ribosomal RNA. RPS9 is targeted to the nucleolus but the regions in the protein that determine its localization remains unknown. Cellular expression of RPS9 deletion mutants revealed that it has three regions capable of driving nuclear localization of a fused enhanced green fluorescent protein (EGFP). The first region was mapped to the RPS9 N-terminus while the second one was located in the proteins C-terminus. The central and third region in RPS9 also behaved as a strong nucleolar localization signal and was hence sufficient to cause accumulation of EGFP in the nucleolus. RPS9 was previously shown to interact with the abundant nucleolar chaperone NPM1 (nucleophosmin). Evaluating different RPS9 fragments for their ability to bind NPM1 indicated that there are two binding sites for NPM1 on RPS9. Enforced expression of NPM1 resulted in nucleolar accumulation of a predominantly nucleoplasmic RPS9 mutant. Moreover, it was found that expression of a subset of RPS9 deletion mutants resulted in altered nucleolar morphology as evidenced by changes in the localization patterns of NPM1, fibrillarin and the silver stained nucleolar organizer regions. In conclusion, RPS9 has three regions that each are competent for nuclear localization, but only the central region acted as a potent nucleolar localization signal. Interestingly, the RPS9 nucleolar localization signal is residing in a highly conserved domain corresponding to a ribosomal RNA binding site.     

Ribosomal protein L35 is required for 27SB pre-rRNA processing in Saccharomyces cerevisiae

Ribosome synthesis involves the concomitance of pre-rRNA processing and ribosomal protein assembly. In eukaryotes, this is a complex process that requires the participation of specific sequences and structures within the pre-rRNAs, at least 200 trans-acting factors and the ribosomal proteins. There is little information on the function of individual 60S ribosomal proteins in ribosome synthesis. Herein, we have analysed the contribution of ribosomal protein L35 in ribosome biogenesis. In vivo depletion of L35 results in a deficit in 60S ribosomal subunits and the appearance of half-mer polysomes. Pulse-chase, northern hybridization and primer extension analyses show that processing of the 27SB to 7S pre-rRNAs is strongly delayed upon L35 depletion. Most likely as a consequence of this, release of pre-60S ribosomal particles from the nucleolus to the nucleoplasm is also blocked. Deletion of RPL35A leads to similar although less pronounced phenotypes. Moreover, we show that L35 assembles in the nucleolus and binds to early pre-60S ribosomal particles. Finally, flow cytometry analysis indicated that L35-depleted cells mildly delay the G1 phase of the cell cycle. We conclude that L35 assembly is a prerequisite for the efficient cleavage of the internal transcribed spacer 2 at site C₂.     

Formation and nuclear export of preribosomes are functionally linked to the small-ubiquitin-related modifier pathway

Ribosomal precursor particles are initially assembled in the nucleolus prior to their transfer to the nucleoplasm and export to the cytoplasm. In a screen to identify thermosensitive (ts) mutants defective in the export of pre-60S ribosomal subunit, we isolated the rix16-1 mutant. In this strain, nucleolar accumulation of the Rpl25-eGFP reporter was complemented by UBA2 (a subunit of the E1 sumoylation enzyme). Mutations in UBC9 (E2 enzyme), ULP1 [small-ubiquitin-related modifier (SUMO) isopeptidase] and SMT3 (SUMO-1) caused 60S export defects. A directed analysis of the SUMO proteome revealed that many ribosome biogenesis factors are sumoylated. Importantly, preribosomal particles along both the 60S and the 40S synthesis pathways were decorated with SUMO, showing its direct involvement. Consistent with this, early 60S assembly factors were genetically linked to SUMO conjugation. Notably, the SUMO deconjugating enzyme Ulp1, which localizes to the nuclear pore complex (NPC), was functionally linked to the 60S export factor Mtr2. Together our data suggest that sumoylation of preribosomal particles in the nucleus and subsequent desumoylation at the NPC is necessary for efficient ribosome biogenesis and export in eukaryotes.     

The path from nucleolar 90S to cytoplasmic 40S pre-ribosomes

Recent reports have increased our knowledge of the consecutive steps during 60S ribosome biogenesis substantially, but 40S subunit formation is less well understood. Here, we investigate the maturation of nucleolar 90S pre-ribosomes into cytoplasmic 40S pre-ribosomes. During the transition from 90S to 40S particles, the majority of non-ribosomal proteins (approximately 30 species) dissociate, and significantly fewer factors associate with 40S pre-ribosomes. Notably, some of these components are part of both early 90S and intermediate 40S pre-particles in the nucleolus (e.g. Enp1p, Dim1p and Rrp12p), whereas others (e.g. Rio2p and Nob1p) are found mainly on late cytoplasmic pre-40S subunits. Finally, temperature-sensitive mutants mapping either in earlier (enp1-1) or later (rio2-1) components exhibit defects in the formation and nuclear export of pre-40S subunits. Our data provide an initial biochemical map of the pre-40S ribosomal subunit on its path from the nucleolus to the cytoplasm. This pathway involves fewer changes in composition than seen during 60S biogenesis.     

Active regulator of SIRT1 is required for ribosome biogenesis and function

Active regulator of SIRT1 (AROS) binds and upregulates SIRT1, an NAD⁺-dependent deacetylase. In addition, AROS binds RPS19, a structural ribosomal protein, which also functions in ribosome biogenesis and is implicated in multiple disease states. The significance of AROS in relation to ribosome biogenesis and function is unknown. Using human cells, we now show that AROS localizes to (i) the nucleolus and (ii) cytoplasmic ribosomes. Co-localization with nucleolar proteins was verified by confocal immunofluorescence of endogenous protein and confirmed by AROS depletion using RNAi. AROS association with cytoplasmic ribosomes was analysed by sucrose density fractionation and immunoprecipitation, revealing that AROS selectively associates with 40S ribosomal subunits and also with polysomes. RNAi-mediated depletion of AROS leads to deficient ribosome biogenesis with aberrant precursor ribosomal RNA processing, reduced 40S subunit ribosomal RNA and 40S ribosomal proteins (including RPS19). Together, this results in a reduction in 40S subunits and translating polysomes, correlating with reduced overall cellular protein synthesis. Interestingly, knockdown of AROS also results in a functionally significant increase in eIF2α phosphorylation. Overall, our results identify AROS as a factor with a role in both ribosome biogenesis and ribosomal function.