N2-Methylguanosine
(Synonyms: 2-甲鳥苷) 目录号 : GC65127
N2-Methylguanosine 是一种修饰的核苷,修饰发生在 tRNA 的几个特定位点。
Cas No.:2140-77-4
Sample solution is provided at 25 µL, 10mM.
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Quality Control & SDS
- View current batch:
- Purity: >98.00%
- COA (Certificate Of Analysis)
- SDS (Safety Data Sheet)
- Datasheet
N2-methylguanosine is a modified nucleoside that occurs at several specific locations in many tRNA's.
[1]. Ginell SL, et al. Conformation of N2-methylguanosine, a modified nucleoside of tRNA. Biochem Biophys Res Commun. 1978 Oct 30;84(4):886-94.
| Cas No. | 2140-77-4 | SDF | Download SDF |
| 别名 | 2-甲鳥苷 | ||
| 分子式 | C11H15N5O5 | 分子量 | 297.27 |
| 溶解度 | DMSO : 7.69 mg/mL (25.87 mM; Need ultrasonic)|Water : 1 mg/mL (3.36 mM; ultrasonic and warming and heat to 80°C) | 储存条件 | Store at -20°C |
| General tips | 请根据产品在不同溶剂中的溶解度选择合适的溶剂配制储备液;一旦配成溶液,请分装保存,避免反复冻融造成的产品失效。 储备液的保存方式和期限:-80°C 储存时,请在 6 个月内使用,-20°C 储存时,请在 1 个月内使用。 为了提高溶解度,请将管子加热至37℃,然后在超声波浴中震荡一段时间。 |
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| Shipping Condition | 评估样品解决方案:配备蓝冰进行发货。所有其他可用尺寸:配备RT,或根据请求配备蓝冰。 | ||
| 制备储备液 | |||
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1 mg | 5 mg | 10 mg |
| 1 mM | 3.3639 mL | 16.8197 mL | 33.6395 mL |
| 5 mM | 0.6728 mL | 3.3639 mL | 6.7279 mL |
| 10 mM | 0.3364 mL | 1.682 mL | 3.3639 mL |
| 第一步:请输入基本实验信息(考虑到实验过程中的损耗,建议多配一只动物的药量) | ||||||||||
| 给药剂量 | mg/kg |  |
动物平均体重 | g | |
每只动物给药体积 | ul | |
动物数量 | 只 |
| 第二步:请输入动物体内配方组成(配方适用于不溶于水的药物;不同批次药物配方比例不同,请联系GLPBIO为您提供正确的澄清溶液配方) | ||||||||||
| % DMSO % % Tween 80 % saline | ||||||||||
| 计算重置 | ||||||||||
计算结果:
工作液浓度: mg/ml;
DMSO母液配制方法: mg 药物溶于 μL DMSO溶液(母液浓度 mg/mL,
体内配方配制方法:取 μL DMSO母液,加入 μL PEG300,混匀澄清后加入μL Tween 80,混匀澄清后加入 μL saline,混匀澄清。
1. 首先保证母液是澄清的;
2.
一定要按照顺序依次将溶剂加入,进行下一步操作之前必须保证上一步操作得到的是澄清的溶液,可采用涡旋、超声或水浴加热等物理方法助溶。
3. 以上所有助溶剂都可在 GlpBio 网站选购。
RFhy-m2G: Identification of RNA N2-Methylguanosine modification sites based on random forest and hybrid features
Methods 2022 Jul;203:32-39.PMID:34033879DOI:10.1016/j.ymeth.2021.05.016.
N2-Methylguanosine is a post-transcriptional modification of RNA that is found in eukaryotes and archaea. The biological function of m2G modification discovered so far is to control and stabilize the three-dimensional structure of tRNA and the dynamic barrier of reverse transcription. To discover additional biological functions of m2G, it is necessary to develop time-saving and labor-saving calculation tools to identify m2G. In this paper, based on hybrid features and a random forest, a novel predictor, RFhy-m2G, was developed to identify the m2G modification sites for three species. The hybrid feature used by the predictor is used to fuse the three features of ENAC, PseDNC, and NPPS. These three features include primary sequence derivation properties, physicochemical properties, and position-specific properties. Since there are redundant features in hybrid features, MRMD2.0 is used for optimal feature selection. Through feature analysis, it is found that the optimal hybrid features obtained still contain three kinds of properties, and the hybrid features can more accurately identify m2G modification sites and improve prediction performance. Based on five-fold cross-validation and independent testing to evaluate the prediction model, the accuracies obtained were 0.9982 and 0.9417, respectively. The robustness of the predictor is demonstrated by comparisons with other predictors.
Identifying RNA minor groove tertiary contacts by nucleotide analogue interference mapping with N2-Methylguanosine
Biochemistry 1998 Sep 15;37(37):12933-42.PMID:9737873DOI:10.1021/bi980723j.
Nucleotide analogue interference mapping (NAIM) is a general biochemical method that rapidly identifies the chemical groups important for RNA function. In principle, NAIM can be extended to any nucleotide that can be incorporated into an in vitro transcript by an RNA polymerase. Here we report the synthesis of 5'-O-(1-thio)-N2-methylguanosine triphosphate (m2GalphaS) and its incorporation into two reverse splicing forms of the Tetrahymena group I intron using a mutant form of T7 RNA polymerase. This analogue replaces one proton of the N2 exocyclic amine with a methyl group, but is as stable as guanosine (G) for secondary structure formation. We have identified three sites of m2GalphaS interference within the Tetrahymena intron: G22, G212, and G303. All three of these guanosine residues are known to utilize their exocyclic amino groups to participate in tertiary hydrogen bonds within the ribozyme structure. Unlike the interference pattern with the phosphorothioate of inosine (IalphaS, an analogue that deletes the N2 amine of G), m2GalphaS substitution did not cause interference at positions attributable to secondary structural stability effects. Given that the RNA minor groove is likely to be widely used for helix packing, m2GalphaS provides an especially valuable reagent to identify RNA minor groove tertiary contacts in less well-characterized RNAs.
16S ribosomal RNA of Escherichia coli contains a N2-Methylguanosine at 27 nucleotides from the 3' end
Nucleic Acids Res 1981 Jun 25;9(12):2717-25.PMID:6792595DOI:10.1093/nar/9.12.2717.
The 49 nucleotides fragment derived from the 3' end of 16S rRNA by cloacin DF13, is not cleaved by ribonuclease T1 at a guanosine residue tha is present at 27 nucleotides from the 3' terminus (position 115 in 16S rRNA). Analysis of the isolated nucleotide indicates that it is a modified G residue. In vivo labeling with (3H)methionine shows that this G is methylated and co-chromatography with markers reveals that it is N2-Methylguanosine.
THUMPD3-TRMT112 is a m2G methyltransferase working on a broad range of tRNA substrates
Nucleic Acids Res 2021 Nov 18;49(20):11900-11919.PMID:34669960DOI:10.1093/nar/gkab927.
Post-transcriptional modifications affect tRNA biology and are closely associated with human diseases. However, progress on the functional analysis of tRNA modifications in metazoans has been slow because of the difficulty in identifying modifying enzymes. For example, the biogenesis and function of the prevalent N2-Methylguanosine (m2G) at the sixth position of tRNAs in eukaryotes has long remained enigmatic. Herein, using a reverse genetics approach coupled with RNA-mass spectrometry, we identified that THUMP domain-containing protein 3 (THUMPD3) is responsible for tRNA: m2G6 formation in human cells. However, THUMPD3 alone could not modify tRNAs. Instead, multifunctional methyltransferase subunit TRM112-like protein (TRMT112) interacts with THUMPD3 to activate its methyltransferase activity. In the in vitro enzymatic assay system, THUMPD3-TRMT112 could methylate all the 26 tested G6-containing human cytoplasmic tRNAs by recognizing the characteristic 3'-CCA of mature tRNAs. We also showed that m2G7 of tRNATrp was introduced by THUMPD3-TRMT112. Furthermore, THUMPD3 is widely expressed in mouse tissues, with an extremely high level in the testis. THUMPD3-knockout cells exhibited impaired global protein synthesis and reduced growth. Our data highlight the significance of the tRNA: m2G6/7 modification and pave a way for further studies of the role of m2G in sperm tRNA derived fragments.
Position-dependent effects of regioisomeric methylated adenine and guanine ribonucleosides on translation
Nucleic Acids Res 2017 Sep 6;45(15):9059-9067.PMID:28591780DOI:10.1093/nar/gkx515.
Reversible methylation of the N6 or N1 position of adenine in RNA has recently been shown to play significant roles in regulating the functions of RNA. RNA can also be alkylated upon exposure to endogenous and exogenous alkylating agents. Here we examined how regio-specific methylation at the hydrogen bonding edge of adenine and guanine in mRNA affects translation. When situated at the third codon position, the methylated nucleosides did not compromise the speed or accuracy of translation under most circumstances. When located at the first or second codon position, N1-methyladenosine (m1A) and m1G constituted robust blocks to both Escherichia coli and wheat germ extract translation systems, whereas N2-Methylguanosine (m2G) moderately impeded translation. While m1A, m2G and N6-methyladenosine (m6A) did not perturb translational fidelity, O6-methylguanosine (m6G) at the first and second codon positions was strongly and moderately miscoding, respectively, and it was decoded as an adenosine in both systems. The effects of methylated ribonucleosides on translation could be attributed to the methylation-elicited alterations in base pairing properties of the nucleobases, and the mechanisms of ribosomal decoding contributed to the position-dependent effects. Together, our study afforded important new knowledge about the modulation of translation by methylation of purine nucleobases in mRNA.