The RNA N6-methyladenosine demethylase ALKBH9B modulates ABA responses in Arabidopsis

The mRNA modification N⁶-methyladenosine(m⁶A)plays vital roles in plant development and biotic and abiotic stress responses.The RNA m⁶A demethylase ALKBH9 B can remove m⁶A in alfalfa mosaic virus RNA and plays roles in alfalfa mosaic virus infection in Arabidopsis.However,it is unknown whether ALKBH9 B also exhibits demethylation activity and has a biological role in endogenous plant mRNA.We demonstrated here that mRNA m⁶A modification is in...     

水稻ECT基因家族的全基因组研究

真核生物mRNA转录后修饰可调控许多基因的遗传信息,植物m⁶A甲基化研究正成为关注的新热点。m⁶A结合蛋白 (m⁶A readers) 调节m⁶A修饰的特异性,通常具有YTH (YT521-B homology) 结构域,在拟南芥中被命名为ECT结构域 (evolutionarily conserved C-terminal region ECT domain) 。目前ECT基因已在拟南芥和水稻等植物中检测到,但该基因家族在水稻中的成员及生物学功能还缺乏研究。本研究通过水稻ECT基因家族的全基因组分析,鉴定出12个OsECT基因,具有1个保守的基序,多位于蛋白质氨基酸序列C-端。共线性分析表明,在水稻基因组内OsECT-c与OsECT-e发生了重复事件,在物种间ECT同源基因对可能是在双子叶和单子叶植物分化后形成。同源基因对OsECT的Ka/Ks < 1,表明OsECT基因家族在进化过程中可能经历了较强的纯化选择压力。表达模式分析显示,OsECT-b、OsECT-c、OsECT-e和OsECT-j在水稻生长初期各个组织均保持较高的表达水平,OsECT-g在干旱处理后表达量显著下调。因此,OsECT基因在水稻生长发育和逆境胁迫中可能发挥着重要作用。本研究为今后OsECT基因在水稻的节水抗旱机制研究和相关抗逆育种提供了重要的理论基础。     

Flavivirus RNA cap methyltransferase: structure,function, and inhibition

Many flaviviruses are significant human pathogens. The plus-strand RNA genome of a flavivirus contains a 5′ terminal cap 1 structure (m⁷GpppAmG). The flavivirus encodes one methyltransferase (MTase), located at the N-terminal portion of the NS5 RNA-dependent RNA polymerase (RdRp). Here we review recent advances in our understanding of flaviviral capping machinery and the implications for drug development. The NS5 MTase catalyzes both guanine N7 and ribose 2′-OH methylations during viral cap formation. Representative flavivirus MTases, from dengue, yellow fever, and West Nile virus (WNV), sequentially generate GpppA → m⁷GpppA → m⁷GpppAm. Despite the existence of two distinct methylation activities, the crystal structures of flavivirus MTases showed a single binding site for S-adenosyl-L-methionine (SAM), the methyl donor. This finding indicates that the substrate GpppA-RNA must be repositioned to accept the N7 and 2′-O methyl groups from SAM during the sequential reactions. Further studies demonstrated that distinct RNA elements are required for the methylations of guanine N7 on the cap and of ribose 2′-OH on the first transcribed nucleotide. Mutant enzymes with different methylation defects can trans complement one another in vitro, demonstrating that separate molecules of the enzyme can independently catalyze the two cap methylations in vitro. In the context of the infectious virus, defects in both methylations, or a defect in the N7 methylation alone, are lethal to WNV. However, viruses defective solely in 2′-O methylation are attenuated and can protect mice from later wild-type WNV challenge. The results demonstrate that the N7 methylation activity is essential for the WNV life cycle and, thus, methyltransferase represents a novel and promising target for flavivirus therapy.     

RNA中6-甲基腺嘌呤的研究进展

RNA酶促共价修饰研究, 尤其是m⁶A(6-甲基腺嘌呤), 是RNA生物学研究的一个新兴领域。m⁶A是真核生物mRNA内部序列中最常见的一种转录后修饰形式, 由包含3个独立组分的复合物mRNA: m⁶A甲基转移酶催化生成。最新研究发现肥胖相关蛋白FTO可以脱掉m⁶A上的甲基, 表明该甲基化过程是可逆的。抑制或敲除m⁶A甲基转移酶会引起重要的表型变化, 但是由于过去的检测方法受限, m⁶A确切的作用机制目前为止还不甚清楚。二代测序技术结合免疫沉淀方法为大规模检测m⁶A修饰并研究其作用机制提供了可能。文章主要综述了m⁶A的发现史、生成机制、组织和基因组分布、检测方法、生物学功能等及其最新研究进展, 并通过比较3种IP-seq技术和数据分析的异同及优缺点, 对m⁶A这种RNA表观修饰研究中尚未解决的问题进行了讨论。     

鳜鱼传染性脾肾坏死病毒的胞嘧啶5-甲基转移酶基因结构及其序列分析

对鳜鱼传染性脾肾坏死病毒（infectious spleen and kidney necrosis virus,ISKNV）的胞嘧啶5－甲基转移酶（MTase）基因的结构及序列进行了分析。序列比较分析表明,ISKNV MTase编码区全长684bp,编码长227个氨基酸的蛋白质,推测分子量为25855D。与一些细菌的MTase比较,ISKNV MTase也含有负责转移甲基的4个保守区,但缺乏识别靶序列的保守区。比较ISKNV与其它6种脊椎动物虹彩病毒的MTase序列并建立系统树,ISKNV显著不同于蛙病毒属和淋巴囊肿病毒属。7种脊椎动物虹彩病毒MTase具有高度保守区,可以此设计引物用PCR方法鉴定脊椎动物虹彩病毒。     

Refolding of a fully functional flavivirus methyltransferase revealed that S‐adenosyl methionine but not S‐adenosyl homocysteine is copurified with flavivirus methyltransferase

Methylation of flavivirus RNA is vital for its stability and translation in the infected host cell. This methylation is mediated by the flavivirus methyltransferase (MTase), which methylates the N7 and 2′‐O positions of the viral RNA cap by using S‐adenosyl‐l ‐methionine (SAM) as a methyl donor. In this report, we demonstrate that SAM, in contrast to the reaction by‐product S‐adenosyl‐l ‐homocysteine, which was assumed previously, is copurified with the Dengue (DNV) and West Nile virus MTases produced in Escherichia coli (E. coli). This endogenous SAM can be removed by denaturation and refolding of the MTase protein. The refolded MTase of DNV serotype 3 (DNV3) displays methylation activity comparable to native enzyme, and its crystal structure at 2.1 Å is almost identical to that of native MTase. We characterized the binding of Sinefungin (SIN), a previously described SAM‐analog inhibitor of MTase function, to the native and refolded DNV3 MTase by isothermal titration calorimetry, and found that SIN binds to refolded MTase with more than 16 times the affinity of SIN binding to the MTase purified natively. Moreover, we show that SAM is also copurified with other flavivirus MTases, indicating that purification by refolding may be a generally applicable tool for studying flavivirus MTase inhibition.     

DNA methylation impacts the cleavage activity of Chlorella virus topoisomerase II

Topoisomerase II from Paramecium bursaria chlorella virus-1 (PBCV-1) and chlorella virus Marburg-1 (CVM-1) displays an extraordinarily high in vitro DNA cleavage activity that is 30-50 times higher than that of human topoisomerase IIalpha. This remarkable scission activity may reflect a unique role played by the type II enzyme during the viral life cycle that extends beyond the normal control of DNA topology. Alternatively, but not mutually exclusively, it may reflect an adaptation to some aspect of the viral environment that differs from the in vitro conditions. To this point, the genomes of many chlorella viruses contain high levels of N6-methyladenine (6mA) and 5-methylcytosine (5mC), but the DNA employed in vitro is unmodified. Therefore, to determine whether methylation impacts the ability of chlorella virus topoisomerase II to cleave DNA, the effects of 6mA and 5mC on the PBCV-1 and CVM-1 enzymes were examined. Results indicate that 6mA strongly inhibits DNA scission mediated by both enzymes, while 5mC has relatively little effect. At levels of 6mA and 5mC methylation comparable to those found in the CVM-1 genome (10% 6mA and 42% 5mC), the level of DNA cleavage decreased approximately 4-fold. As determined using a novel rapid quench pre-equilibrium DNA cleavage system in conjunction with oligonucleotide binding and ligation assays, this decrease appears to be caused primarily by a slower forward rate of DNA scission. These findings suggest that the high DNA cleavage activity of chlorella virus topoisomerase II on unmodified nucleic acid substrates may reflect, at least in part, an adaptation to act on methylated genomic DNA.     

RNA m6A甲基化与神经发育

中枢神经系统控制高级神经活动,例如知觉、运动、语言和认知等。作为人体神经系统最重要的部分,其正常的发育及功能活动在人体发育过程中至关重要。更好地了解调节神经系统发育的基本分子途径以及对大脑的基本生物学理解,可以帮助诊断和治疗各种神经疾病。RNA分子m⁶A修饰状态的动态变化及其功能主要由m⁶A甲基转移酶、m⁶A去甲基化酶和m⁶A阅读蛋白等蛋白质复合物共同调控。本文对此进行了详细介绍,并详细概述m⁶A修饰对神经发育的影响,重点介绍表观转录组学在基因调控中的作用。此外,还强调m⁶A修饰在神经发育过程中的生物学意义,包括神经发生、神经分化、轴突导向、突触形成及突触可塑性等。根据不同的实验原理和实验技术,本文详细介绍了最近发展的几种检测m⁶A位点的技术,每种方法都有各自的优点,据此将能够更广泛和更深入地研究这一修饰,并选择合适的方法去研究课题。RNA m⁶A甲基化是神经科学领域的一个新前沿。近年来,随着m⁶A检测技术的发展,m⁶A甲基化在神经系统发育过程中及神经疾病发生中的作用研究逐渐成为热点,具有很大潜力,为神经发育和神经疾病的研究提供了新视角。     

Structural bases for substrate recognition and activity in Meaban virus nucleoside-2'-O-methyltransferase

Viral methyltransferases are involved in the mRNA capping process, resulting in the transfer of a methyl group from S-adenosyl-L-methionine to capped RNA. Two groups of methyltransferases (MTases) are known: (guanine-N7)-methyltransferases (N7MTases), adding a methyl group onto the N7 atom of guanine, and (nucleoside-2'-O-)-methyltransferases (2'OMTases), adding a methyl group to a ribose hydroxyl. We have expressed and purified two constructs of Meaban virus (MV; genus Flavivirus) NS5 protein MTase domain (residues 1-265 and 1-293, respectively). We report here the three-dimensional structure of the shorter MTase construct in complex with the cofactor S-adenosyl-L-methionine, at 2.9 angstroms resolution. Inspection of the refined crystal structure, which highlights structural conservation of specific active site residues, together with sequence analysis and structural comparison with Dengue virus 2'OMTase, suggests that the crystallized enzyme belongs to the 2'OMTase subgroup. Enzymatic assays show that the short MV MTase construct is inactive, but the longer construct expressed can transfer a methyl group to the ribose 2'O atom of a short GpppAC(5) substrate. West Nile virus MTase domain has been recently shown to display both N7 and 2'O MTase activity on a capped RNA substrate comprising the 5'-terminal 190 nt of the West Nile virus genome. The lack of N7 MTase activity here reported for MV MTase may be related either to the small size of the capped RNA substrate, to its sequence, or to different structural properties of the C-terminal regions of West Nile virus and MV MTase-domains.     

AdoMet-dependent methylation, DNA methyltransferases and base flipping

Twenty AdoMet-dependent methyltransferases (MTases) have been characterized structurally by X-ray crystallography and NMR. These include seven DNA MTases, five RNA MTases, four protein MTases and four small molecule MTases acting on the carbon, oxygen or nitrogen atoms of their substrates. The MTases share a common core structure of a mixed seven-stranded beta-sheet (6 downward arrow 7 upward arrow 5 downward arrow 4 downward arrow 1 downward arrow 2 downward arrow 3 downward arrow) referred to as an 'AdoMet-dependent MTase fold', with the exception of a protein arginine MTase which contains a compact consensus fold lacking the antiparallel hairpin strands (6 downward arrow 7 upward arrow). The consensus fold is useful to identify hypothetical MTases during structural proteomics efforts on unannotated proteins. The same core structure works for very different classes of MTase including those that act on substrates differing in size from small molecules (catechol or glycine) to macromolecules (DNA, RNA and protein). DNA MTases use a 'base flipping' mechanism to deliver a specific base within a DNA molecule into a typically concave catalytic pocket. Base flipping involves rotation of backbone bonds in double-stranded DNA to expose an out-of-stack nucleotide, which can then be a substrate for an enzyme-catalyzed chemical reaction. The phenomenon is fully established for DNA MTases and for DNA base excision repair enzymes, and is likely to prove general for enzymes that require access to unpaired, mismatched or damaged nucleotides within base-paired regions in DNA and RNA. Several newly discovered MTase families in eukaryotes (DNA 5mC MTases and protein arginine and lysine MTases) offer new challenges in the MTase field.     

Differential role of NADP+ and NADPH in the activity and structure of GDP-D-mannose 4,6-dehydratase from two chlorella viruses

GDP-D-mannose 4,6-dehydratase (GMD) is a key enzyme involved in the synthesis of 6-deoxyhexoses in prokaryotes and eukaryotes. Paramecium bursaria chlorella virus-1 (PBCV-1) encodes a functional GMD, which is unique among characterized GMDs because it also has a strong stereospecific NADPH-dependent reductase activity leading to GDP-D-rhamnose formation (Tonetti, M., Zanardi, D., Gurnon, J., Fruscione, F., Armirotti, A., Damonte, G., Sturla, L., De Flora, A., and Van Etten, J.L. (2003) J. Biol. Chem. 278, 21559-21565). In the present study we characterized a recombinant GMD encoded by another chlorella virus, Acanthocystis turfacea chlorella virus 1 (ATCV-1), demonstrating that it has the expected dehydratase activity. However, it also displayed significant differences when compared with PBCV-1 GMD. In particular, ATCV-1 GMD lacks the reductase activity present in the PBCV-1 enzyme. Using recombinant PBCV-1 and ATCV-1 GMDs, we determined that the enzymatically active proteins contain tightly bound NADPH and that NADPH is essential for maintaining the oligomerization status as well as for the stabilization and function of both enzymes. Phylogenetic analysis indicates that PBCV-1 GMD is the most evolutionary diverged of the GMDs. We conclude that this high degree of divergence was the result of the selection pressures that led to the acquisition of new reductase activity to synthesize GDP-D-rhamnose while maintaining the dehydratase activity in order to continue to synthesize GDP-L-fucose.     

The effect of processing of Chlorellavulgaris: K-5 on in vitro and in vivo digestibility in rats

Two experiments were done to clarify whether or not cell rupture is necessary to improve the digestibility of major components of Chlorella vulgaris: K-5. Chlorella was treated with or without high pressure homogenization (1 × 10⁸ N/m² at less than −20°C) after a heating process (100-120°C). Chlorella (air-dry matter) contained 934 g dry matter and 244 g essential amino acids (total)/kg. Chemical composition was hardly altered irrespective of the treatment. In the first experiment, pepsin digestibility of chlorella protein was determined in vitro. The cell rupture by high pressure homogenization caused a small but significant improvement in pepsin digestibility of chlorella protein compared with the control. In the second experiment, total tract apparent digestibilities of chlorella were determined in the rat. Digestibility of chlorella protein was significantly enhanced by high pressure homogenization, but the difference (88.6% vs. 87.4%, P < 0.01) due to treatment was small and similar to that observed in the in vitro experiment. These results suggested that Chlorella strain vulgaris: K-5 may be an efficient protein source even without cell rupture.     

Paramecium bursaria chlorella virus 1 proteome reveals novel architectural and regulatory features of a giant virus

The 331-kbp chlorovirus Paramecium bursaria chlorella virus 1 (PBCV-1) genome was resequenced and annotated to correct errors in the original 15-year-old sequence; 40 codons was considered the minimum protein size of an open reading frame. PBCV-1 has 416 predicted protein-encoding sequences and 11 tRNAs. A proteome analysis was also conducted on highly purified PBCV-1 virions using two mass spectrometry-based protocols. The mass spectrometry-derived data were compared to PBCV-1 and its host Chlorella variabilis NC64A predicted proteomes. Combined, these analyses revealed 148 unique virus-encoded proteins associated with the virion (about 35% of the coding capacity of the virus) and 1 host protein. Some of these proteins appear to be structural/architectural, whereas others have enzymatic, chromatin modification, and signal transduction functions. Most (106) of the proteins have no known function or homologs in the existing gene databases except as orthologs with proteins of other chloroviruses, phycodnaviruses, and nuclear-cytoplasmic large DNA viruses. The genes encoding these proteins are dispersed throughout the virus genome, and most are transcribed late or early-late in the infection cycle, which is consistent with virion morphogenesis.     

Cloning of CviPII nicking and modification system from chlorella virus NYs-1 and application of Nt.CviPII in random DNA amplification

The cloning and expression of the CviPII DNA nicking and modification system encoded by chlorella virus NYs-1 is described. The system consists of a co-linear MTase encoding gene (cviPIIM) and a nicking endonuclease encoding gene (cviPIINt) separated by 12 nt. M.CviPII possesses eight conserved amino acid motifs (I to VIII) typical of C5 MTases, but, like another chlorella virus MTase M.CviJI, lacks conserved motifs IX and X. In addition to modification of the first cytosine in CCD (D = A, G or T) sequences, M.CviPII modifies both the first two cytosines in CCAA and CCCG sites as well. Nt.CviPII has significant amino acid sequence similarity to Type II restriction endonuclease CviJI that recognizes an overlapping sequence (RG--CY). Nt.CviPII was expressed in Escherichia coli with or without a His-tag in a host pre-modified by M.CviPII. Recombinant Nt.CviPII recognizes the DNA sequence CCD and cleaves the phosphodiester bond 5' of the first cytosine while the other strand of DNA at this site is not affected. Nt.CviPII displays site preferences with CCR (R = A or G) sites preferred over CCT sites. Nt.CviPII is active from 16 to 65 degrees C with a temperature optimum of 30-45 degrees C. Nt.CviPII can be used to generate single-stranded DNAs (ssDNAs) for isothermal strand-displacement amplification. Nt.CviPII was used in combination with Bst DNA polymerase I large fragment to rapidly amplify anonymous DNA from genomic DNA or from a single bacterial colony.     

Characterization of Protein Methyltransferases Rkm1, Rkm4, Efm4, Efm7, Set5 and Hmt1 Reveals Extensive Post-Translational Modification

Protein methylation is one of the major post-translational modifications (PTMs) in the cell. In Saccharomyces cerevisiae, over 20 protein methyltransferases (MTases) and their respective substrates have been identified. However, the way in which these MTases are modified and potentially subject to regulation remains poorly understood. Here, we investigated six overexpressed S. cerevisiae protein MTases (Rkm1, Rkm4, Efm4, Efm7, Set5 and Hmt1) to identify PTMs of potential functional relevance. We identified 48 PTM sites across the six MTases, including phosphorylation, acetylation and methylation. Forty-two sites are novel. We contextualized the PTM sites in structural models of the MTases and revealed that many fell in catalytic pockets or enzyme–substrate interfaces. These may regulate MTase activity. Finally, we compared PTMs on Hmt1 with those on its human homologs PRMT1, PRMT3, CARM1, PRMT6 and PRMT8. This revealed that several PTMs are conserved from yeast to human, whereas others are only found in Hmt1. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium via the PRIDE partner repository with the dataset identifier PXD006767.