跳转至内容
Merck
CN

MABE647

抗-乙酰基组蛋白H3(Lys27)抗体,克隆RM172

clone RM172, from rabbit

别名:

Histone H3.3, Histone H3

登录 查看组织和合同定价。

选择尺寸

关于此项目

UNSPSC Code:
12352203
NACRES:
NA.41
eCl@ss:
32160702

主要文件

查看所有文档
技术服务
需要帮助?我们经验丰富的科学家团队随时乐意为您服务。
让我们为您提供帮助
技术服务
需要帮助?我们经验丰富的科学家团队随时乐意为您服务。
让我们为您提供帮助

产品名称

抗-乙酰基组蛋白H3(Lys27)抗体,克隆RM172, clone RM172, from rabbit

biological source

rabbit

antibody form

purified antibody

antibody product type

primary antibodies

clone

RM172, monoclonal

species reactivity

human

technique(s)

multiplexing: suitable
western blot: suitable

isotype

IgG

UniProt accession no.

P84243

shipped in

wet ice

target post-translational modification

acetylation (Lys27)

Quality Level

100

Gene Information

human ... H3F3B(3021)

相关类别

Analysis Note

通过蛋白质印迹法在未处理和丁酸钠处理的HeLa酸提取物中进行评价。

蛋白质印迹分析(WB):1 μg/mL该抗体可在丁酸钠处理的HeLa酸性提取物中检测到乙酰基组蛋白H3(Lys27)。

Application

多重分析(Mplex):使用一个代表性批次以0.1-0.5 μg/mL进行多重分析。
研究子类别
染色质生物学
研究类别
表观遗传学&核功能
经验证,该抗乙酰基组蛋白H3(Lys27)抗体(克隆RM172)可用于蛋白质印迹法(多重检测乙酰基组蛋白H3)。

Biochem/physiol Actions

该抗体可与赖氨酸27乙酰化的组蛋白H3(K27ac)反应。与组蛋白H3中的其他乙酰化赖氨酸无交叉反应性。

Disclaimer

除非我们的目录或产品随附的其他公司文件中另有说明,否则我们的产品预期仅用于研究用途,不得用于任何其他目的,包括但不限于未经授权的商业用途、体外诊断用途、离体或体内治疗用途或对人类或动物的任何类型的消费或应用。

General description

组蛋白H3,也称为组蛋白H3.1t (H3/t)、H3t、H3/g,由基因名称HIST3H3/H3FT编码,是核小体的核心组分。核小体将DNA包裹并压缩到染色质中,从而限制了DNA进入需要DNA作为模板的细胞机制的可及性。因此,组蛋白在转录调控、DNA修复、DNA复制和染色体稳定性中起着核心作用。H3具有一个主要的球状结构域和一个长N末端的尾巴,与串珠′结构上的′珠核小体结构有关。组蛋白H3的N末端尾巴从球状核小体核心突出,并且可以经历影响细胞过程的几种不同类型的表观遗传修饰。这些修饰包括甲基或乙酰基与赖氨酸和精氨酸氨基酸的共价连接以及丝氨酸或苏氨酸的磷酸化。组蛋白H3的高水平磷酸化与有丝分裂有关。
观测分子量〜17 kDa。 在某些裂解物中可以观察到未鉴定的条带。

Immunogen

对应于在Lys27乙酰化的人组蛋白H3的线性肽。

Other Notes

浓度:请参考特定批次的数据表。

Physical form

兔单克隆抗体,溶于含1% BSA和0.09%叠氮化钠的PBS中
形式:纯化
纯化蛋白A

Preparation Note

自接收之日起,在2-8°C下可稳定保存1年。
注意:冷冻箱温度变化至低于-20°C时可能导致含甘油的溶液在储存过程中冻结。

未找到合适的产品?  

试试我们的产品选型工具.

存储类别

12 - Non Combustible Liquids

wgk

WGK 2

flash_point_f

does not flash

flash_point_c

does not flash

分析证书(COA)

输入产品批号来搜索 分析证书(COA) 。批号可以在产品标签上"批“ (Lot或Batch)字后找到。

已有该产品?

在文件库中查找您最近购买产品的文档。

访问文档库

Michael S Hoetker et al.
Nature cell biology, 25(8), 1121-1134 (2023-07-18)
The epigenetic mechanisms that maintain differentiated cell states remain incompletely understood. Here we employed histone mutants to uncover a crucial role for H3K36 methylation in the maintenance of cell identities across diverse developmental contexts. Focusing on the experimental induction of
Chi Sun et al.
Scientific reports, 13(1), 12899-12899 (2023-08-10)
Enhancers function with a basal promoter to control the transcription of target genes. Enhancer regulatory activity is often studied using reporter-based transgene assays. However, unmatched results have been reported when selected enhancers are silenced in situ. In this study, using
Silvia Pomella et al.
Nature communications, 14(1), 8373-8373 (2023-12-16)
Rhabdomyosarcomas (RMS) are pediatric mesenchymal-derived malignancies encompassing PAX3/7-FOXO1 Fusion Positive (FP)-RMS, and Fusion Negative (FN)-RMS with frequent RAS pathway mutations. RMS express the master myogenic transcription factor MYOD that, whilst essential for survival, cannot support differentiation. Here we discover SKP2
Marit W Vermunt et al.
Molecular cell, 83(5), 715-730 (2023-03-04)
Transcriptional enhancers have been extensively characterized, but cis-regulatory elements involved in acute gene repression have received less attention. Transcription factor GATA1 promotes erythroid differentiation by activating and repressing distinct gene sets. Here, we study the mechanism by which GATA1 silences
Steven J Wu et al.
Nature biotechnology, 39(7), 819-824 (2021-04-14)
Methods for quantifying gene expression1 and chromatin accessibility2 in single cells are well established, but single-cell analysis of chromatin regions with specific histone modifications has been technically challenging. In this study, we adapted the CUT&Tag method3 to scalable nanowell and
查看所有相关文献

相关内容

White Paper: Further considerations of antibody validation and usage.
Characterization of Estrogen Receptor α Phosphorylation Sites in Breast Cancer Tissue Using the SNAP i.d® 2.0 System

A major focus of breast cancer research is to understand the mechanisms responsible for disease progression and drug resistance. Toward that end, it has been found that approximately two thirds of all human breast carcinomas overexpress the Estrogen Receptor α (ERα) protein and it remains the primary pharmacological target for endocrine therapy1,2. The normal cellular function of ERα is as a transcription factor that mediates a wide variety of physiological processes, many of which are dependent upon phosphorylation of the receptor at specific amino acid residues3,4. Indeed, ERα is known to be phosphorylated at a multitude of different sites, yet how these all correlate to disease remains unclear5. Here, we interrogated multiple sites of ERα for phosphorylation status by screening an extensive panel of different breast cancer patient samples and other non-breast cancer tissue microarray (TMA) slide samples to determine their relevance to disease.

我们的科学家团队拥有各种研究领域经验,包括生命科学、材料科学、化学合成、色谱、分析及许多其他领域.

联系客户支持