Cat-Nr. | 102-P53 |
Size | 100 µg |
Price | 235 € |
Category | Polyclonal Antibody |
Clone Nr. | Rabbit IgG |
Species Reactivity | Human |
Formulation | lyophilized from PBS |
Buffer | PBS |
Reconstitution | Centrifuge vial prior to opening. Reconstitute in sterile water to a concentration of 0.1-1.0 mg/ml. |
Stability and Storage | The lyophilized antibody is stable for at least 2 years from date of receipt at -20°C. The reconstituted antibody is stable for at least two weeks at 2-8°C. Frozen aliquots are stable for at least 6 months when stored at -20°C. |
Preparation | Produced from sera of rabbits pre-immunized with highly pure (>98%) recombinant hTPO. Anti-Human TPO specific antibody was purified by affinity chromatography employing immobilized hTPO matrix. |
Antigen | Recombinant Human TPO |
Application | ELISA, WB, N |
Synonyms | THPO; ML; TPO; MGDF; MKCSF; MPLLG; THCYT2 |
Description | Thrombopoietin (Tpo), is a key regulator of megakaryocytopoiesis and thrombopoiesis. It is principally produced in the liver and is bound and internalized by the receptor Tpo R/c-mpl. Defects in the Tpo-Tpo R signaling pathway are associated with a variety of platelet disorders. The 353 amino acid (aa) human Tpo precursor is cleaved to yield the 332 aa mature protein. Mature human Tpo shares approximately 70% aa sequence homology with mouse and rat Tpo. It is an 80 - 85 kDa protein that consists of an N-terminal domain with homology to Erythropoietin (Epo) and a C-terminal domain that contains multiple N-linked and O-linked glycosylation sites. Tissue specific alternate splicing of human Tpo generates multiple isoforms with internal deletions, insertions, and/or C-terminal substitutions. Tpo promotes the differentiation, proliferation, and maturation of MK and their progenitors. Several other cytokines can promote these functions as well but only in cooperation with Tpo. Notably, IL-3 independently induces MK development, although its effects are restricted to early in the MK lineage. Tpo additionally promotes platelet production, aggregation, ECM adhesion, and activation. It is cleaved by platelet-derived thrombin following Arg191 within the C-terminal domain and subsequently at other sites upon extended digestion. |
Uniprot ID | P40225 |
Protein RefSeq | NP_000451.1 |
mRNA RefSeq | NM_000460.2 |
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现在急需使用这个机器,补试验,不知道哪位能够提供重庆的Seahorse机器信息。非常感谢!
Seahorse细胞代谢分析
美国海马细胞能量代谢实时测定仪/生物能量代谢测定仪XF(SeahorseXFExtracellularFluxAnalyzers)——2009年全球创新技术产品Top10!
美国海马生物科学利用细胞外流量(ExtracellularFlux,XF)检测专利技术,发明了业界第一款海马细胞能量代谢实时测定仪/生物能量代谢测定仪XF24/96,是进行细胞代谢分析、氧呼吸测定、药物代谢分析、线粒体有氧代谢和糖酵解等功能的最佳分析工具。
美国海马细胞能量代谢实时测定仪/生物能量代谢测定仪XF24通过特殊的细胞培养微孔板设计,在测量时临时形成的约5ul微环境中,利用无创的专利光学传感器同步地实时探测溶解氧(OCR)和pH值变化,从而快速了解细胞内两大能量转换途径(线粒体的有氧代谢和糖酵解)的能量代谢状态。在使用XF24的检测过程中,研究人员可以通过预设程序控制在特定时间向待测细胞的培养基中添加多达四种药物,以便研究不同药物对细胞新陈代谢的影响,理解细胞的生物能量变化,快速解析细胞或组织的基础代谢率、ATP转换、膜的完整性、极限呼吸率、线粒体功能,产生氧自由基及超氧化物等有毒物的情况,省时省力,实验数据更科学,更具有说服力。
细胞质中有各种细胞器,细胞内的化学反应大多都是在细胞质中进行,因此是代谢中心.
细胞核中有DNA,是遗传信息库,是细胞代谢和遗传的控制中心.
productivitybyusingmannoseascarbonsource:Metabolicanalysisand
scale-upsimulation》
2.《Adetailedmetabolic?uxanalysisofanunderdeterminednetworkofCHOcells》
1-s2.0-S0009250911001771-main.pdf(328.24k)
1-s2.0-S016816561001878X-main.pdf(521.01k)
解析:1.细胞质基质(也叫胞质溶胶)是指除细胞器外细胞质的其余部分。细胞质基质是活细胞进行新陈代谢的主要场所。
2.细胞新陈代谢的次要场所是:细胞核、线粒体基质、叶绿体基质等基质。
康乃尔大学应用暨工程物理学(AppliedEngineeringPhysics)副教授KarlA.Kasischke等人成功利用多光子显微技术发现脑部神经细胞(neurons)和星状细胞(astrocytes)之间的如何地交互作用来燃烧氧气和葡萄糖进行糖解作用(glycosis)﹐以达到脑部特别能量的需求。其结果已发表于今年七月的《科学》(Science)杂志上。
该研究团队表示﹐他们根据大脑代谢的辅?烟碱醯胺腺嘌呤双核甘酸(NADH,nicotinamideadeninedinucleotide)两种不同能源状态的影像﹐将最具争议性脑细胞能量代谢的星状细胞—神经元乳酸穿梭(theastrocyte-neuronlactateshuttle)假设作确认与再定义。
KarlA.Kasischke说道﹐在过去十年当中﹐科学家们激烈争议讨论﹐被激活的大脑究竟是进行有氧代谢把葡萄糖彻底分解成水?还是进行无氧状态的糖解作用产生乳酸(lactate)?他表示﹐他们的研究已经发现星状细胞糖解作用伴随着神经活化引发神经性氧化代谢(NeuronalOxidativeMetabolism)将这两种目前对立的说法产生一致性并造成两派双赢的局面。由于他们所使用的多光子显微镜可以让NADH产生内生性荧光影像﹐显示出脑神经内早期氧化代谢终究是持续的﹐并且在约10秒后让星状细胞—神经元乳酸穿梭(theastrocyte-neuronlactateshuttle)作脑细胞晚期的活化作用。神经细胞甚至在休息的时候是不断代谢葡萄糖﹐并且当讯号开始穿越神经细胞时﹐代谢葡萄糖的现象会持续表达﹐然后星状细胞会将代谢葡萄糖所得到的乳酸﹐提供出来做为燃料。
目前医师所使用的脑神经影像技术﹐例如功能性磁共振影像(fMRI,functionalmagneticresonanceimaging)和正子造影系统(PET;positronemissiontomography)虽然可分别探测血流和血氧变化﹐提供医师了解大脑功能变化﹐但是在时间和空间的分辨率却无法满足研究人员的需求。而相较之下﹐多光子显微技术却能提供中枢神经系统(CNS;centralnervoussystem)高分辨率﹐3D立体的组织影像﹐强力地帮助研究人员探讨脑细胞代谢途径。
这场十多年来的争论﹐看来各持己见的双方都没有输。不过﹐最重要的意义是﹐多光子显微技术足以提供大脑代谢等研究功能性方面的应用﹐并且提供给医师较佳的方式来观察中风或阿兹海默症等脑部损害。
全文链接:http://www.sciencemag.org/cgi/reprint/305/5680/50.pdf
A.衰老的细胞新陈代谢速率加快
B.在衰老的细胞内有些酶的活性降低
C.衰老的细胞呼吸速率减慢
D.细胞膜通透性改变,使物质运输功能降低
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