S-100鈣結合蛋白P(S-100)重組蛋白

廣州健侖生物科技有限公司

S100蛋白是一組具有EF-手形的鈣依賴調節蛋白，參與一系列細胞內活動的調節，包括細胞增殖/分化、蛋白質磷酸化、酶活性、細胞內鈣穩態和轉錄因子活性等；S100家族成員的基因表達異常也與大多數人類腫瘤相關。S-100蛋白有3種亞型：S-100ao、S-100a、S-100b，主要存在神經組織、垂體、頸動脈體、腎上腺髓質、唾液腺和少數間葉組織中。主要用于星形膠質瘤、室管膜瘤、神經母細胞瘤、神經鞘瘤、惡黑、脂肪肉瘤和Langerhans細胞增生疾病的研究。

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S-100鈣結合蛋白P(S-100)重組蛋白

【產品介紹】

細胞定位：細胞漿/細胞核

克隆號：16/f5

同型：IgG

適用組織：石蠟/冰凍

陽性對照：胎盤/胰腺導管癌

抗原修復：熱修復（EDTA）

抗體孵育時間：30-60min

S-100鈣結合蛋白P(S-100)重組蛋白

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【公司名稱】 廣州健侖生物科技有限公司
【市場部】     歐

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【騰訊  】 
【公司地址】 廣州清華科技園創新基地番禺石樓鎮創啟路63號二期2幢101-103室

對從病人機體分離的肝臟及抗原抗體腫瘤組織進行分析，研究者發現，癌癥中ASPP2表達的欠缺和病人較低的生存率直接相關;蛋白ASPP2可以通過和E-鈣粘蛋白及β-連環蛋白的關聯來控制MET和EMT過程。zui后研究者Lu表示，近些年來我們已經對驅動EMT的過程研究地非常多了，但是對于MET過程的發生卻知之甚少，而MET過程對于機體的健康及癌癥的轉移又至關重要，而本文的zui大亮點就是我們鑒別出了MET的誘導子及守護者，這對于后期開發治療癌癥的新型靶向療法提供了新的研究思路和依據。
日本東京大學教授竹內昌治率領的研究小組24日宣布，通過把人工培養的肌肉組織安在人工關節上，他們成功制作出了能像人類手指那樣屈伸的人工手指。這一成果有望在再生醫療領域得到應用。
研究人員將大鼠的肌肉細胞植入特殊的凝膠層，然后將多個凝膠層放在一起進行培養，zui終培養出了長約8毫米、厚約1.5毫米的立體肌肉組織。
隨后，研究人員在長2厘米的塑料棒兩側分別安裝了人工培養出的大鼠肌肉組織，塑料棒正中安裝有關節。利用微弱的電流進行刺激后，肌肉就會收縮，而輪流刺激兩側的肌肉，就能使塑料棒像手指那樣屈伸。

Analysis of the liver and antigen-antibody-tumor tissue isolated from the patient's body revealed that the lack of ASPP2 expression in cancer was directly linked to the lower survival rate of the patient; the protein ASPP2 was directly linked to E-cadherin and β-catenin To control the MET and EMT processes. Last researcher Lu said that in recent years we have studied very much about the EMT driving process but have little knowledge of the occurrence of MET events that are crucial for the health of the body and the transfer of cancer, The highlight of this article is that we identified the elicitors and guardians of MET, which provided a new research idea and basis for the later development of new targeted therapies for the treatment of cancer.
A team led by Professor Takeuchi Masaharu of the University of Tokyo in Japan announced on the 24th that they successfully produced artificial fingers that flexed like human fingers by putting artificial muscle tissue in artificial joints. This result is expected to be applied in the field of regenerative medicine.
Researchers planted muscle cells from rats into a special gel layer and then placed multiple gel layers together to create a three-dimensional muscle tissue approximay 8 mm long and 1.5 mm thick.
Subsequently, the researchers in the 2 cm long plastic rods installed on both sides of the artificial culture of rat muscle tissue, plastic rods installed in the middle section. When stimulated with a weak electric current, the muscles contract, and in turn, stimulate the muscles on either side, making the plastic rod bend like a finger.