Advances of N6-methyladenosine modification on circular RNA in hepatocellular carcinoma

N6-methyladenosine(m6A)is a reversible epigenetic modification, which is one of the most abundant modifiers in eukaryotic cells and has been commonly reported in messenger RNAs and non-coding RNAs. The processing modification of m6A regulates RNA transcription, processing, splicing, degradation, and translation, and plays an important role in the biological process of tumors. Circular RNA, which lacks the 5' cap structure, has been mistakenly regarded as a "junk sequence" generated by accidental shearing during the transcription process. However, it has been found that circRNAs can be involved in tumor invasion and metastasis through microRNAs, binding proteins, translated peptides, and m6A modifications. In this paper, we reviewed the role of m6A modifications in circRNA regulation and their functions in hepatocellular carcinoma and discussed their potential clinical applications and future development in this field.

Dysregulation of RNA modification systems in clinical populations with neurocognitive disorders

The study of modified RNA known as epitranscriptomics has become increasingly relevant in our understanding of disease-modifying mechanisms.Methylation of N6 adenosine(m^(6)A)and C5 cytosine(m^(5)C)bases occur on mRNAs,tRNA,mt-tRNA,and rRNA species as well as non-coding RNAs.With emerging knowledge of RNA binding proteins that act as writer,reader,and eraser effector proteins,comes a new understanding of physiological processes controlled by these systems.Such processes when spatiotemporally disrupted within cellular nanodomains in highly specialized tissues such as the brain,give rise to different forms of disease.In this review,we discuss accumulating evidence that changes in the m^(6)A and m^(5)C methylation systems contribute to neurocognitive disorders.Early studies first identified mutations within FMR1 to cause intellectual disability Fragile X syndromes several years before FMR1 was identified as an m^(6)A RNA reader protein.Subsequently,familial mutations within the m^(6)A writer gene METTL5,m^(5)C writer genes NSUN2,NSUN3,NSUN5,and NSUN6,as well as THOC2 and THOC6 that form a protein complex with the m^(5)C reader protein ALYREF,were recognized to cause intellectual development disorders.Similarly,differences in expression of the m^(5)C writer and reader effector proteins,NSUN6,NSUN7,and ALYREF in brain tissue are indicated in individuals with Alzheimer's disease,individuals with a high neuropathological load or have suffered traumatic brain injury.Likewise,an abundance of m^(6)A reader and anti-reader proteins are reported to change across brain regions in Lewy bodies diseases,Alzheimer's disease,and individuals with high cognitive reserve.m^(6)A-modified RNAs are also reported significantly more abundant in dementia with Lewy bodies brain tissue but significantly reduced in Parkinson's disease tissue,whilst modified RNAs are misplaced within diseased cells,particularly where synapses are located.In parahippocampal brain tissue,m^(6)A modification is enriched in transcripts associated with psychiatric disorders including conditions with clear cognitive deficits.These findings indicate a diverse set of molecular mechanisms are influenced by RNA methylation systems that can cause neuronal and synaptic dysfunction underlying neurocognitive disorders.Targeting these RNA modification systems brings new prospects for neural regenerative therapies.

Recent progress in N6-methyladenosine modification in ocular surface diseases

N6-methyladenosine(m6A)modification is a reversible process promoted by“writers”,inhibited by“erasers”,and processed by“readers”.During the last decade,increasing emphasis has been placed on the underlying roles of m6A modification owing to their great importance in biological significance.The abnormal regulation of m6A modification will lead to aberrant cellular behavior and various diseases.Recently,studies have demonstrated that m6A modification is closely associated with the genesis and progression of ocular surface diseases(OSDs).This review focus on the role of m6A modification and research progress in OSDs including fungal keratitis,herpes simplex keratitis,immunerelated keratoconjunctival diseases,pterygium,ocular chemical burns,and Graves’ophthalmopathy,which may provide new insights into and prospective applications for OSDs.

A Novel β-1,4-N, 6-O-Diacetylmuramidase from Streptomyces griseus and its Chemical Modification

A novel lysozyme named β-1, 4-N, 6-O-diacetylmuramidase R2 was purified and characterized from Streptomyces griseus. The molecular weight of the enzyme was determined by MALDI-TOF-MS as 23.5 kDa. The N-terminal amino acid sequence was DTSGVQGIDVSHWQG. Chemical modification of β-1, 4-N, 6-O-diacetylmuramidase R2 indicated that sulfhydryl group and carbamidine of arginine residues are not essential for the activity of the enzyme, but lysine residues and imidazole of histidine residues are essential for the activity. The number of essential tryptophan and carboxyl groups was found that only one tryptophan residue and three carboxyl groups in the active site.

N^(6)-甲基腺苷修饰在动脉粥样硬化中的作用及药物干预的研究进展

N^(6)-甲基腺苷(m 6A)修饰是真核生物mRNA中最常见的表观转录组修饰形式之一,具有动态可逆性。该修饰过程由甲基转移酶、去甲基化酶和与m 6A结合的蛋白质协同作用,影响mRNA的代谢和功能。越来越多的研究表明,m 6A RNA修饰在动脉粥样硬化(As)等多种疾病的发生和发展中扮演重要角色。文章综述了m 6A RNA修饰与As的关系。全文对m 6A RNA修饰机制以及在As相关细胞(如内皮细胞、巨噬细胞和平滑肌细胞)中的作用进行了全面总结,并探讨了m 6A RNA修饰与As危险因素,如高脂饮食、缺血缺氧、振荡应力及高血压的关联。最后,文章还对药物干预m 6A RNA甲基化以实现延缓As的研究进行了综述,为探索As早期诊断和治疗的新靶点提供了重要参考。

RNA m^(6)A甲基化修饰在脏器纤维化中的研究进展

脏器纤维化是器官慢性炎症过程中常见的病理改变,主要特征为细胞外基质过度沉积引起组织损伤,形成永久性瘢痕,导致器官功能障碍,目前该类疾病治疗手段有限,预后较差。表观遗传学参与了纤维化进程,其中RNA N^(6)-甲基腺苷(m^(6)A)甲基化修饰作为真核生物中最常见的RNA转录后修饰通过参与信使RNA核输出、剪接、翻译和稳定等调控基因表达,从而影响生物学功能。m^(6)A甲基化修饰通过关键修饰酶调控相关通路参与脏器纤维化的形成和发展,这为脏器纤维化的治疗提供了新方向。

Learning Sequential and Structural Dependencies Between Nucleotides for RNA N6-Methyladenosine Site Identification

N6-methyladenosine(m6A)is an important RNA methylation modification involved in regulating diverse biological processes across multiple species.Hence,the identification of m6A modification sites provides valuable insight into the biological mechanisms of complex diseases at the post-transcriptional level.Although a variety of identification algorithms have been proposed recently,most of them capture the features of m6A modification sites by focusing on the sequential dependencies of nucleotides at different positions in RNA sequences,while ignoring the structural dependencies of nucleotides in their threedimensional structures.To overcome this issue,we propose a cross-species end-to-end deep learning model,namely CR-NSSD,which conduct a cross-domain representation learning process integrating nucleotide structural and sequential dependencies for RNA m6A site identification.Specifically,CR-NSSD first obtains the pre-coded representations of RNA sequences by incorporating the position information into single-nucleotide states with chaos game representation theory.It then constructs a crossdomain reconstruction encoder to learn the sequential and structural dependencies between nucleotides.By minimizing the reconstruction and binary cross-entropy losses,CR-NSSD is trained to complete the task of m6A site identification.Extensive experiments have demonstrated the promising performance of CR-NSSD by comparing it with several state-of-the-art m6A identification algorithms.Moreover,the results of cross-species prediction indicate that the integration of sequential and structural dependencies allows CR-NSSD to capture general features of m6A modification sites among different species,thus improving the accuracy of cross-species identification.

Long non-coding RNA GATA6-AS1 is mediated by N6-methyladenosine methylation and inhibits the proliferation and metastasis of gastric cancer

BACKGROUND Through experimental research on the biological function of GATA6-AS1,it was confirmed that GATA6-AS1 can inhibit the proliferation,invasion,and migration of gastric cancer cells,suggesting that GATA6-AS1 plays a role as an anti-oncogene in the occurrence and development of gastric cancer.Further experi-ments confirmed that the overexpression of fat mass and obesity-associated protein(FTO)inhibited the expression of GATA6-AS1,thereby promoting the occurrence and development of gastric cancer.AIM To investigate the effects of GATA6-AS1 on the proliferation,invasion and migration of gastric cancer cells and its mechanism of action.METHODS We used bioinformatics methods to analyze the Cancer Genome Atlas(https://portal.gdc.cancer.gov/.The Cancer Genome Atlas)and download expression data for GATA6-AS1 in gastric cancer tissue and normal tissue.We also constructed a GATA6-AS1 lentivirus overexpression vector which was transfected into gastric cancer cells to investigate its effects on proliferation,migration and invasion,and thereby clarify the expression of GATA6-AS1 in gastric cancer and its biological role in the genesis and development of gastric cancer.Next,we used a database(http://starbase.sysu.edu.cn/starbase2/)to analysis GATA6-AS1 whether by m6A methylation modify regulation and predict the methyltransferases that may methylate GATA6-AS1.Furthermore,RNA immunoprecipitation experiments confirmed that GATA6-AS1 was able to bind to the m6A methylation modification enzyme.These data allowed us to clarify the ability of m6A methylase to influence the action of GATA6-AS1 and its role in the occurrence and development of gastric cancer.RESULTS Low expression levels of GATA6-AS1 were detected in gastric cancer.We also determined the effects of GATA6-AS1 overexpression on the biological function of gastric cancer cells.GATA6-AS1 had strong binding ability with the m6A demethylase FTO,which was expressed at high levels in gastric cancer and negatively correlated with the expression of GATA6-AS1.Following transfection with siRNA to knock down the expression of FTO,the expression levels of GATA6-AS1 were up-regulated.Finally,the proliferation,migration and invasion of gastric cancer cells were all inhibited following the knockdown of FTO expression.CONCLUSION During the occurrence and development of gastric cancer,the overexpression of FTO may inhibit the expression of GATA6-AS1,thus promoting the proliferation and metastasis of gastric cancer.

N^(6)-甲基腺苷修饰及其调控蛋白在脑缺血中的表达变化及意义

目的本研究通过探讨N^(6)-甲基腺苷(N^(6)-methyladenosine,m^(6)A)修饰及其调控蛋白在脑缺血小鼠中的表达变化,为脑缺血治疗的分子靶点研究提供参考。方法取60只雄性C57BL/6J小鼠,随机分为假手术组、脑缺血1 d组、脑缺血3 d组和脑缺血7 d组,每组各15只,采用线栓法制作右侧大脑中动脉梗死模型,于缺血1 h进行拔栓再灌注。通过RNA提取及斑点印迹实验检测小鼠缺血侧脑组织RNA m^(6)A水平;使用荧光定量逆转录PCR检测小鼠缺血侧脑组织甲基转移酶3(methyltransferase 3,Mettl3)、甲基转移酶14(methyltransferase 14,Mettl14)、FTOα-酮戊二酸酯依赖性双加氧酶(FTO alpha-ketoglutarate dependent dioxygenase,Fto)、RNA去甲基化酶alkB同源基因5(alkB homolog 5,RNA demethylase;Alkbh5)、YTH N^(6)-甲基腺苷RNA结合蛋白1(YTH N^(6)-methyladenosine RNA binding protein 1,Ythdf1)、Ythdf2和Ythdf3的mRNA表达水平;利用免疫印迹实验检测缺血侧脑组织Mettl3、Mettl14、Fto、Alkbh5、Ythdf1、Ythdf2和Ythdf3蛋白的表达水平;借助免疫荧光染色观察缺血侧脑组织梗死周边区神经元中Mettl3、Fto、Ythdf1、Ythdf2和Ythdf3蛋白的表达变化情况。结果与假手术组相比,脑缺血3 d组脑组织RNA的m^(6)A水平升高(1.620±0.339 vs.1.000±0.192,P=0.0343)。(1)甲基转移酶表达情况:脑缺血7 d组Mettl3mRNA水平降低(0.675±0.059 vs.1.000±0.131,P=0.0331);脑缺血1 d组Mettl3(0.548±0.107 vs.1.000±0.056,P=0.0398)、Mettl14(0.534±0.218 vs.1.000±0.018,P=0.0108)蛋白表达水平降低;脑缺血3 d组Mettl3(0.410±0.341 vs.1.000±0.056,P=0.0084)、Mettl14(0.429±0.283 vs.1.000±0.018,P=0.0026)蛋白表达水平也均下降;免疫荧光染色显示脑缺血3 d组梗死周边区神经元中Mettl3蛋白表达减少。(2)去甲基化酶表达情况:脑缺血1 d组(0.405±0.209 vs.1.000±0.142,P=0.0108)、脑缺血3 d组(0.530±0.125 vs.1.000±0.142,P=0.0412)Fto蛋白表达水平降低;免疫荧光染色显示脑缺血3 d组梗死周边区神经元中Fto表达减少。(3)m^(6)A结合蛋白表达情况:脑缺血1 d组Ythdf1mRNA水平降低(0.708±0.046 vs.1.000±0.117,P=0.0331),Ythdf3mRNA水平升高(1.473±0.093 vs.1.000±0.142,P=0.0012);脑缺血3 d组Ythdf1(0.593±0.240 vs.1.000±0.117,P=0.0034)、Ythdf2(0.664±0.177 vs.1.000±0.200,P=0.0100)mRNA水平降低,Ythdf3 mRNA水平升高(1.451±0.281 vs.1.000±0.142,P=0.0018);脑缺血1 d组Ythdf1(0.486±0.177 vs.1.000±0.091,P=0.0197)、Ythdf3(0.536±0.107 vs.1.000±0.125,P=0.0400)蛋白表达水平降低;脑缺血3 d组Ythdf1(0.404±0.299 vs.1.000±0.091,P=0.0079)、Ythdf2(0.279±0.189 vs.1.000±0.261,P=0.0136)、Ythdf3(0.450±0.220 vs.1.000±0.125,P=0.0157)蛋白表达水平均降低;免疫荧光染色显示脑缺血3 d组梗死周边区神经元中m6A结合蛋白Ythdf1、Ythdf2、Ythdf3表达均减少。结论小鼠脑缺血后可能由Fto表达下调导致m^(6)A水平升高,Ythdf1、Ythdf2、Ythdf3蛋白表达水平趋势基本一致,可能存在功能冗余。

mRNA N^(6)-甲基腺嘌呤修饰调控与动物脂肪沉积的研究进展

脂肪组织发育和沉积与动物的生长、生产效率、繁殖以及产品品质密切相关,同时,脂肪的过度沉积也直接与人类肥胖和代谢性疾病紧密关联。因此,如何调控脂肪沉积对提高动物生产性能、改善动物产品品质和保障人类生命健康都具有重要的意义。N^(6)-甲基腺嘌呤(N^(6)-methyladenosine,m^(6)A)修饰是一种重要的表观遗传学修饰,在脂肪干细胞分化聚酯与代谢过程中发挥重要功能。本文在概述了脂肪组织种类和mRNA m^(6)A修饰及其生物学功能的基础上,重点论述了mRNA m^(6)A修饰对动物脂肪沉积的影响及其调控机制,并阐述了营养素通过mRNA m^(6)A修饰调控动物脂肪沉积等方面的研究进展,为精准调控动物脂肪沉积进而促进畜牧业高质量发展提供一定的理论依据和参考。

N^(6)-甲基腺苷修饰(m^(6)A)在乳腺癌中的研究进展

乳腺癌是女性最常见的癌症之一,也是导致女性癌症死亡的最主要原因.尽管早期乳腺癌的治疗已经取得了极大进展,但晚期伴转移乳腺癌治疗效果较差,具有高复发率和高死亡率.因此,鉴定新的用于诊断和预测乳腺癌转移的分子标记、开发新的治疗策略成为迫切需要.近年来,mRNA的异常N^(^(6))-甲基腺苷修饰(N^(6)-methyladenosine,m^(6)A)对癌基因功能和表达水平的表观遗传学调控逐渐成为恶性乳腺癌研究的焦点.本文分析和总结了m^(6)A甲基化修饰及其调节蛋白参与调控乳腺癌发生发展的最新研究进展,以期为乳腺癌中m^(6)A甲基化修饰研究提供新的思路和参考,进一步为乳腺癌的诊断、治疗、预后及监测提供新的有效策略.

m^6A RNA甲基化在非小细胞肺癌中的研究进展

m^6A修饰是真核生物mRNA中最丰富的修饰之一,该过程受m^6A甲基转移酶和去甲基化酶的共同调控。m^6A修饰后的RNA能够被m^6A识别蛋白特异性识别并结合,进而介导RNA的剪接、成熟、出核、降解和翻译等。目前国内外对于m^6A修饰及其相关蛋白如何参与非小细胞肺癌发生发展的研究,主要集中于细胞恶性增殖、迁移、侵袭、转移和耐药等方面。m^6A修饰相关蛋白在肺癌组织标本和血液循环肿瘤细胞(circulating tumor cell, CTC)中表达异常,有望成为肺癌诊断和预后判断的潜在分子标志物。本文围绕m^6A修饰相关蛋白的组成、作用方式、在非小细胞肺癌恶性进展中的生物学功能,以及针对m^6A修饰的靶向治疗等方面的研究进展进行综述,旨在为非小细胞肺癌的早期临床诊断和靶向药物的开发提供新思路。

乙醇-盐酸辅助脱模制备Ni/Al-KIT-6介孔催化剂及其正庚烷异构性能

采用乙醇-盐酸萃取辅助高温焙烧法(萃取-焙烧两步法)脱除模板剂(聚环氧乙烷(PEO)-聚环氧丙烷(PPO)-聚环氧乙烷聚合物,P123),经金属Al原位掺杂改性,水热晶化法合成了一种具有蠕虫状形貌的Al-KIT-6介孔分子筛,使用浸渍法制备了不同镍负载量的Ni/Al-KIT-6金属-酸双功能催化剂。采用XRD、N2吸附-脱附、NH_(3)-TPD、IR、SEM和TEM等表征手段对Al-KIT-6分子筛及催化剂样品进行物化性能分析,并以正庚烷为反应原料,对Ni/Al-KIT-6催化剂样品进行正庚烷异构化反应性能评价。结果表明:采用萃取-焙烧两步法可以有效脱除模板剂,相比于常规焙烧法和萃取法脱除模板剂制备的分子筛样品,萃取-焙烧两步法脱除模板剂制备的KIT-6分子筛样品具有更大的比表面积、孔体积,同时孔径分布更加均一;分子筛骨架中掺杂Al原子增加了分子筛的酸性;在氢气流速30 mL/min、重时空速7.6 h^(-1)、反应温度190℃、反应时间3 h,常压的条件下,镍负载质量分数为5%的Ni/Al-KIT-6催化剂作用下进行庚烷异构化反应,正庚烷转化率最高为26.8%,异庚烷选择性高于99.5%。

N^6-腺苷酸甲基化RNA修饰在免疫调控中的作用

N^6-腺苷酸甲基化(N6-methyladenosine,m6A)是真核细胞中最常见、最丰富的信使RNA(message RNA,mRNA)内部修饰,在甲基转移酶和去甲基酶的作用下,形成一种动态、可逆的甲基化过程,参与多种细胞基因表达调控与生物学过程。近年来,研究发现m6A修饰在免疫细胞分化与调控功能中具有重要作用,这为免疫系统相关性疾病的研究和治疗提供了新思路。文章就近年来m6A修饰在免疫调控中的作用相关研究进展作一综述。

RNA m^(6)A修饰在膀胱癌中的作用

近年来,RNA表观修饰引起了全球学者的重视。在所有已知的RNA修饰中,N^(6)-甲基腺苷(N^(6)-methyladenosine,m^(6)A)修饰是主要的RNA修饰。作为一种动态且可逆的修饰,m^(6)A被"作家蛋白"(RNA甲基转移酶)催化,被"橡皮擦蛋白"(去甲基酶)去除,并与"阅读蛋白"(m^(6)A结合蛋白)相互作用,从而影响RNA的剪接、易位、稳定性和翻译,进而调节细胞的多种生理进程,尤其是在癌症的发展方面具有重要作用。

m^(6)A RNA甲基化修饰在昆虫生长发育、免疫和抗药性中的作用

N^(6)-腺苷酸甲基化(N^(6)-methyladenosine,m^(6)A)修饰是真核生物中含量最丰富的RNA修饰,通过参与RNA的选择性剪接、稳定性、出核、翻译和降解等分子过程从而调控动物、植物和微生物的多项重要生物学功能。本文总结归纳了m^(6)A修饰在果蝇Drosophila、家蚕Bombyx mori、意大利蜜蜂Apis mellifera和烟粉虱Bemisia tabaci等昆虫生长发育、免疫和抗药性中的作用,并分析了当前研究中的不足与空白,为进一步研究m^(6)A修饰在昆虫中的生理功能提供参考。

RNA m^(6)A修饰在肺部疾病中的研究进展

N^(6)-甲基腺苷(N^(6)-methyladenosine,m^(6)A)修饰是指RNA中腺苷的第6位氮原子处发生的甲基化修饰。在已发现的RNA修饰中,m^(6)A修饰被认为是真核生物mRNA中最常见的修饰类型。此外,这种甲基化修饰也可发生在rRNA、tRNA、miRNA、circRNA和lncRNA[1]。

m^(6)A RNA甲基化修饰在脊柱结核发病中的研究进展

脊柱结核(STB)是发展中国家肺外结核导致脊柱畸形的常见因素,严重影响患者生活质量。STB起病隐匿,临床症状不典型、发病机制不明,使得STB难以诊治。近年来,N^(6)-甲基腺苷(m^(6)A)甲基化修饰作为肺结核重要的发病机制受到广泛关注,但其在STB发病中相关报道较少。m^(6)A是信使RNA和非编码RNA中最丰富的转录后修饰因素,修饰动态可逆,且受到甲基化酶、去甲基化酶以及阅读蛋白的调控。m^(6)A甲基化修饰参与对病毒、肿瘤、细胞免疫、新陈代谢和生长发育等的调节,然而其在STB发病过程中的作用机制尚不明确。

昆虫N^(6)-甲基腺嘌呤的研究进展

RNA修饰在真核生物的基因表达调控中具有重要意义,N^(6)-甲基腺嘌呤(N^(6)-methyladenosine,m^(6)A)是RNA修饰中最常见的一种,可通过影响信使RNA(mRNA)的代谢过程来调控一系列生命活动。本文主要根据近年来在昆虫方面的相关研究成果,归纳了m^(6)A调控酶和识别蛋白的作用机制和m^(6)A动态调控的过程,分析了m^(6)A在mRNA中的分布规律,总结了m^(6)A在昆虫中的典型生物学功能。并从当前研究存在的空白与不足、有待进一步探索的科学问题等方面,对m^(6)A未来在昆虫领域的研究前景进行了展望,以期为后续的研究与探索提供参考。

RNA m^(6)A甲基化修饰在动脉粥样硬化中的作用

动脉粥样硬化(AS)是以动脉粥样硬化斑块形成为特征的慢性炎症性疾病,可导致急性心血管事件的发生。N^(6)-甲基腺苷(m^(6)A)RNA甲基化修饰是真核生物细胞内最普遍的转录后修饰方式,很多证据表明m^(6)A甲基化修饰在动脉粥样硬化的形成和发展过程中发挥了重要作用。本文就m^(6)A甲基化修饰的生物学功能及其在动脉粥样硬化相关细胞及危险因素中的调控作用进行综述。