| 纯度 | >85%SDS-PAGE. |
| 种属 | Human |
| 靶点 | PHF11 |
| Uniprot No | Q9UIL8 |
| 内毒素 | < 0.01EU/μg |
| 表达宿主 | E.coli |
| 表达区间 | 1-331aa |
| 氨基酸序列 | MGSSHHHHHH SSGLVPRGSH MAQASPPRPE RVLGASSPEA RPAQEALLLP TGVFQVAEKM EKRTCALCPK DVEYNVLYFA QSENIAAHEN CLLYSSGLVE CEDQDPLNPD RSFDVESVKK EIQRGRKLKC KFCHKRGATV GCDLKNCNKN YHFFCAKKDD AVPQSDGVRG IYKLLCQQHA QFPIIAQSAK FSGVKRKRGR KKPLSGNHVQ PPETMKCNTF IRQVKEEHGR HTDATVKVPF LKKCKEAGLL NYLLEEILDK VHSIPEKLMD ETTSESDYEE IGSALFDCRL FEDTFVNFQA AIEKKIHASQ QRWQQLKEEI ELLQDLKQTL CSFQENRDLM SSSTSISSLS Y |
| 预测分子量 | 40 kDa |
| 蛋白标签 | His tag N-Terminus |
| 缓冲液 | PBS, pH7.4, containing 0.01% SKL, 1mM DTT, 5% Trehalose and Proclin300. |
| 稳定性 & 储存条件 | Lyophilized protein should be stored at ≤ -20°C, stable for one year after receipt. Reconstituted protein solution can be stored at 2-8°C for 2-7 days. Aliquots of reconstituted samples are stable at ≤ -20°C for 3 months. |
| 复溶 | Always centrifuge tubes before opening.Do not mix by vortex or pipetting. It is not recommended to reconstitute to a concentration less than 100μg/ml. Dissolve the lyophilized protein in distilled water. Please aliquot the reconstituted solution to minimize freeze-thaw cycles. |
以下是关于PHF11重组蛋白的3篇代表性文献及其简要摘要:
1. **"PHF11 interacts with the PRMT5–UHRF1 complex to regulate CD4+ T cell differentiation"**
- **作者**:Wang, Y. et al.
- **摘要**:研究发现PHF11通过结合PRMT5-UHRF1复合体,参与调控CD4+ T细胞的分化,揭示了其在免疫调节中的关键作用。重组PHF11蛋白实验表明其通过表观遗传机制影响基因表达。
2. **"Structural and functional analysis of the PHF11–UHRF1 interaction in DNA repair"**
- **作者**:Smith, L.M. et al.
- **摘要**:通过X射线晶体学解析PHF11重组蛋白与UHRF1的结合结构,发现PHF11通过其PHD结构域参与DNA损伤修复通路,为癌症治疗提供了潜在靶点。
3. **"PHF11 regulates neurodevelopmental genes by recruiting histone demethylases"**
- **作者**:Chen, Z. et al.
- **摘要**:利用重组PHF11蛋白进行体外实验,发现其通过招募组蛋白去甲基化酶(如KDM5B)调控神经发育相关基因的染色质重塑,提示其在神经退行性疾病中的可能作用。
注:以上文献为示例,实际文献需根据具体研究方向在PubMed或Google Scholar检索确认。
**Background of PHF11 Recombinant Protein**
PHF11 (PHD Finger Protein 11) is a nuclear protein encoded by the *PHF11* gene, which belongs to the PHD finger protein family. It is characterized by a plant homeodomain (PHD) zinc-finger motif, a structural feature often associated with chromatin remodeling and transcriptional regulation. PHF11 plays a multifaceted role in cellular processes, including DNA repair, transcriptional activation, and immune regulation. Studies suggest its involvement in the DNA damage response pathway, where it interacts with components of the CRL4-DDB1 ubiquitin ligase complex to facilitate nucleotide excision repair (NER).
In immunology, PHF11 has been linked to B-cell development and antibody diversification. It regulates class switch recombination (CSR) and somatic hypermutation (SHM) in activated B cells, processes critical for adaptive immunity. Genetic variations in *PHF11* are associated with autoimmune and inflammatory diseases, such as asthma and atopic dermatitis, highlighting its role in immune dysregulation. Additionally, PHF11 interacts with proteins like RuvB-like1 (RUVBL1) and histone modifiers, suggesting epigenetic regulatory functions.
Recombinant PHF11 protein is engineered for in vitro studies to dissect its molecular mechanisms. Produced via bacterial or mammalian expression systems, it retains functional domains for binding DNA, histones, or partner proteins. Purification methods often employ affinity tags (e.g., His-tag) for high yield and purity. Researchers utilize this tool to explore PHF11's roles in genome stability, immune responses, and disease pathways. Its applications extend to drug discovery, particularly in targeting DNA repair deficiencies or autoimmune disorders.
Overall, PHF11 recombinant protein serves as a critical reagent for unraveling the biological and pathological significance of PHF11 in cellular and disease contexts.
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