| WB | 咨询技术 | Human,Mouse,Rat |
| IF | 咨询技术 | Human,Mouse,Rat |
| IHC | 咨询技术 | Human,Mouse,Rat |
| ICC | 技术咨询 | Human,Mouse,Rat |
| FCM | 咨询技术 | Human,Mouse,Rat |
| Elisa | 咨询技术 | Human,Mouse,Rat |
| Aliases | Vesicle-fusing ATPase; EC=3.6.4.6; N-ethylmaleimide-sensitive fusion protein; Short name=NEM-sensitive fusion protein; Vesicular-fusion protein NSF |
| Entrez GeneID | 4905; |
| WB Predicted band size | 75kDa |
| Host/Isotype | Rabbit IgG |
| Antibody Type | Primary antibody |
| Storage | Store at 4°C short term. Aliquot and store at -20°C long term. Avoid freeze/thaw cycles. |
| Species Reactivity | Human,Mouse,Rat |
| Immunogen | Synthesized peptide derived from internal of human NSF. |
| Formulation | Purified antibody in PBS with 0.05% sodium azide. |
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以下是关于NSF抗体的3-4篇参考文献及其摘要概括:
1. **文献名称**:*N-ethylmaleimide-sensitive factor (NSF) function in SNARE complex disassembly*
**作者**:Whiteheart SW, Rossnagel K, et al.
**摘要**:通过特异性NSF抗体抑制实验,揭示了NSF在SNARE复合体解离中的关键作用。研究发现抗体阻断NSF后,体外膜融合能力显著下降,证实NSF通过ATP酶活性调控囊泡运输。
2. **文献名称**:*Subcellular localization of NSF in synaptic vesicle recycling*
**作者**:Hanson PI, Heuser JE, et al.
**摘要**:利用NSF抗体的免疫荧光技术,定位NSF蛋白在神经元突触小泡和高尔基体膜上的分布,表明其参与突触囊泡循环及神经递质释放的调控。
3. **文献名称**:*Antibody microinjection reveals NSF's role in Golgi trafficking*
**作者**:Graham ME, Burgoyne RD
**摘要**:通过显微注射NSF抗体至哺乳动物细胞,观察到高尔基体膜运输过程受阻,证明NSF在维持细胞器膜融合及分泌途径中的必要性。
4. **文献名称**:*Monoclonal antibodies targeting NSF ATPase domain disrupt ER-Golgi transport*
**作者**:Müller JM, Tagaya M, et al.
**摘要**:开发针对NSF ATP酶结构域的单克隆抗体,实验表明抗体抑制其酶活性后,内质网至高尔基体的蛋白质运输中断,提示NSF酶活对胞内运输的直接影响。
这些研究均通过抗体干预实验,阐明了NSF在膜融合、细胞器运输及神经分泌中的分子机制。
**Background of NSF Antibody**
The N-ethylmaleimide-sensitive factor (NSF) is a conserved AAA+ ATPase critical for intracellular membrane trafficking and fusion. Initially identified for its role in vesicle transport, NSF facilitates the disassembly of SNARE complexes—protein assemblies that mediate membrane fusion between vesicles and target membranes. By hydrolyzing ATP, NSF ensures the recycling of SNAREs, maintaining the continuity of secretory and endocytic pathways.
NSF antibodies are essential tools in studying these processes. They enable the detection and localization of NSF in various experimental models, including immunoprecipitation, Western blotting, and immunofluorescence. Research using NSF antibodies has elucidated its involvement in neurotransmission, organelle dynamics, and cellular homeostasis. Dysregulation of NSF has been linked to neurological disorders, such as Alzheimer’s disease, and impaired insulin secretion in diabetes.
Additionally, NSF antibodies help investigate protein interactions within the SNARE cycle, shedding light on regulatory mechanisms in exocytosis and endocytosis. Their application extends to exploring NSF’s non-canonical roles, such as in viral entry pathways or autophagy. As NSF is ubiquitously expressed, these antibodies are valuable across cell biology, neuroscience, and pathology, providing insights into both basic mechanisms and disease-related dysfunction.
Developed against specific NSF epitopes (e.g., human NSF residues), such antibodies are validated for species cross-reactivity and functional assays, ensuring reliability in diverse research contexts.
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